advertisement
▼
Scroll to page 2
of 208
AX3500 Dual Channel High Power Digital Motor Controller User’s Manual v1.9b, June 1, 2007 visit www.roboteq.com to download the latest revision of this manual ©Copyright 2003-2007 Roboteq, Inc. 2 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Revision History Revision History Date Version Changes June 1, 2007 1.9b Added Output C active when Motors On Fixed Encoder Limit Switches Protection in case of Encoder failure in Closed Loop Speed Added Short Circuit Protection (with supporting hardware) Added Analog 3 and 4 Inputs (with supporting hardware) Added Operating Mode Change on-the-fly Changeable PWM frequency Selectable polarity for Dead Man Switch Modified Flashing Pattern Separate PID Gains for Ch1 and C2, changeable on-the-fly Miscellaneous additions and correction Added Amps Calibration option January 10, 2007 1.9 Changed Amps Limit Algorithm Miscellaneous additions and correction Console Mode in Roborun March 7, 2005 1.7b Updated Encoder section. February 1, 2005 1.7 Added Position mode support with Optical Encoder April 17, 2004 1.6 Added Optical Encoder support March 15, 2004 1.5 Added finer Amps limit settings Miscellaneous additions and corrections Enhanced Roborun utility August 25, 2003 1.3 Added Closed Loop Speed mode Added Data Logging support Removed RC monitoring August 15, 2003 1.2 April 15, 2003 1.1 Modified to cover AX3500 controller design Changed Power Connection section Added analog mode section Added position mode section Added RCRC monitoring feature Updated Roborun utility section Modified RS232 watchdog March 15, 2003 1.0 Initial Release The information contained in this manual is believed to be accurate and reliable. However, it may contain errors that were not noticed at time of publication. User’s are expected to perform their own product validation and not rely solely on data contained in this manual. AX3500 Motor Controller User’s Manual 3 4 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Revision History 3 SECTION 0 Important Safety Warnings 13 This product is intended for use with rechargeable batteries 13 Avoid Shorts when Mounting Board against Chassis 13 Do not Connect to a RC Radio with a Battery Attached 13 Beware of Motor Runaway in Improperly Closed Loop 13 SECTION 1 AX3500 Quick Start 15 What you will need 15 Locating the Switches and Connectors 15 Connecting to the Batteries and Motors 17 Connecting to the 15-pin Connector Connecting the R/C Radio 18 19 Powering On the Controller 19 Button Operation 20 Default Controller Configuration 21 Connecting the controller to your PC using Roborun Obtaining the Controller’s Software Revision Number 22 23 Exploring further 24 SECTION 2 AX3500 Motor Controller Overview 25 Product Description 25 Technical features 26 SECTION 3 Connecting Power and Motors to the Controller Power Connections Controller Power 29 29 30 Controller Powering Schemes 32 Powering the Controller from a single Battery 32 Powering the Controller Using a Main and Backup Battery 33 Connecting the Motors 34 Single Channel Operation 35 Converting the AX3500 to Single Channel 35 Power Fuses 36 Wire Length Limits 37 Electrical Noise Reduction Techniques 37 Power Regeneration Considerations 37 Overvoltage Protection 38 Undervoltage Protection 38 Using the Controller with a Power Supply 39 AX3500 Motor Controller User’s Manual 5 SECTION 4 General Operation 41 Basic Operation 41 Input Command Modes 41 Selecting the Motor Control Modes 42 Open Loop, Separate Speed Control 42 Open Loop, Mixed Speed Control 42 Closed Loop Speed Control 43 Close Loop Position Control 43 User Selected Current Limit Settings 44 Temperature-Based Current Limitation Battery Current vs. Motor Current 44 45 Regeneration Current Limiting 46 Programmable Acceleration 47 Command Control Curves 48 Left / Right Tuning Adjustment 49 Activating Brake Release or Separate Motor Excitation 51 Emergency Shut Down Using Controller Switches 51 Emergency Stop using External Switch 51 Inverted Operation 52 Special Use of Accessory Digital Inputs 52 Using the Inputs to Activate the Buffered Output 52 Using the Inputs to turn Off/On the Power MOSFET transistors 53 Self-Test Mode SECTION 5 53 Connecting Sensors and Actuators to Input/Outputs 55 AX3500 Connections 55 AX3500’s Inputs and Outputs I/O List and Pin Assignment 56 58 Connecting devices to Output C 59 Connecting Switches or Devices to Input F 60 Connecting Switches or Devices to EStop/Invert Input Analog Inputs 61 62 Connecting Position Potentiometers to Analog Inputs 62 Connecting Tachometer to Analog Inputs 63 Connecting External Thermistor to Analog Inputs 65 Using the Analog Inputs to Monitor External Voltages 66 Connecting User Devices to Analog Inputs 67 Internal Voltage Monitoring Sensors 67 Internal Heatsink Temperature Sensors 6 AX3500 Motor Controller User’s Manual 67 Version 1.9b. June 1, 2007 SECTION 6 RC Pulses Output 71 RC Pulse Output Overview 71 Connector Location and Pinout 72 Connecting Servos and Slave Controllers 72 Pulse Timing Information 73 RC Channel Testing Using the PC Utility SECTION 7 74 Connecting and Using the Encoder Function 77 Optical Incremental Encoders Overview 77 Recommended Encoder Types 78 Connecting the Encoder 79 Cable Length and Noise Considerations 80 Motor - Encoder Polarity Matching 80 Voltage Levels, Thresholds and Limit Switches Wiring Optional Limit Switches 82 Wiring Limit Switches Without Encoders Effect of Limit Switches 81 83 83 Using the Encoder Module to Measure Distance 84 Using the Encoder to Measure Speed 84 Using the Encoder to Track Position 85 RS232 Communication with the Encoder Module Encoder Testing and Setting Using the PC Utility SECTION 8 Closed Loop Position Mode Mode Description 87 87 89 89 Selecting the Position Mode 89 Position Sensor Selection Sensor Mounting 90 90 Feedback Potentiometer wiring 91 Feedback Potentiometer wiring in RC or RS232 Mode 91 Feedback Potentiometer wiring in Analog Mode 92 Analog Feedback on Single Channel Controllers 93 Feedback Wiring in RC or RS232 Mode on Single Channel Controllers 93 Feedback Wiring in Analog Mode on Single Channel Controllers 93 Using Optical Encoders in Position Mode Sensor and Motor Polarity 94 94 Encoder Error Detection and Protection 95 Adding Safety Limit Switches 95 Using Current Limiting as Protection 97 Control Loop Description 97 AX3500 Motor Controller User’s Manual 7 PID tuning in Position Mode 98 SECTION 9 Closed Loop Speed Mode 101 Mode Description 101 Selecting the Speed Mode 101 Tachometer or Encoder Mounting 102 Tachometer wiring 102 Speed Sensor and Motor Polarity 103 Adjust Offset and Max Speed 104 Control Loop Description 104 PID tuning in Speed Mode SECTION 10 105 Normal and Fault Condition LED Messages 107 Use of the LED Display 107 Motor Direction Status 108 Fault Messages 109 No Control 109 Temporary Faults 110 Permanent Faults 110 Self-Test Display SECTION 11 110 R/C Operation 113 Mode Description 113 Selecting the R/C Input Mode 114 Connector I/O Pin Assignment (R/C Mode) 114 R/C Input Circuit Description 115 Supplied Cable Description 115 Powering the Radio from the controller 116 Connecting to a Separately Powered Radio 118 Operating the Controller in R/C mode 118 Reception Watchdog 119 R/C Transmitter/Receiver Quality Considerations Joystick Deadband Programming Command Control Curves 120 121 122 Left/Right Tuning Adjustment 122 Joystick Calibration 122 Automatic Joystick Calibration 123 SECTION 12 Data Logging in R/C Mode 124 Analog Control and Operation 127 Mode Description 8 AX3500 Motor Controller User’s Manual 127 Version 1.9b. June 1, 2007 Connector I/O Pin Assignment (Analog Mode) 128 Connecting to a Voltage Source Connecting a Potentiometer 129 129 Selecting the Potentiometer Value 130 Analog Deadband Adjustment Power-On Safety 131 132 Under Voltage Safety 132 Data Logging in Analog Mode 132 SECTION 13 Serial (RS-232) Controls and Operation 135 Use and benefits of RS232 135 Connector I/O Pin Assignment (RS232 Mode) 136 Cable configuration 137 Extending the RS232 Cable 137 Communication Settings 138 Establishing Manual Communication with a PC 138 RS232 Communication with the Encoder Module 139 Entering RS232 from R/C or Analog mode 140 Data Logging String in R/C or Analog mode 140 RS232 Mode if default 141 Commands Acknowledge and Error Messages 141 Character Echo 141 Command Acknowledgement 141 Command Error 141 Watchdog time-out 141 RS-232 Watchdog 142 Controller Commands and Queries 142 Set Motor Command Value 143 Set Accessory Output 143 Query Power Applied to Motors 144 Query Amps from Battery to each Motor Channel Query Analog Inputs 145 Query Heatsink Temperatures 145 Query Battery Voltages 146 Query Digital Inputs 146 Reset Controller 146 144 Accessing & Changing Configuration Parameter in Flash 147 Apply Parameter Changes 147 Flash Configuration Parameters List 148 Input Control Mode 149 Motor Control Mode 149 Amps Limit 150 Acceleration 150 Input Switches Function 151 AX3500 Motor Controller User’s Manual 9 RC Joystick or Analog Deadband 152 Exponentiation on Channel 1 and Channel 2 152 Left/Right Adjust 152 Default Encoder Time Base 1 and 2 153 Default Encoder Distance Divider 153 Default PID Gains 154 Joystick Min, Max and Center Values 154 Reading & Changing Operating Parameters at Runtime Operating Modes Registers 156 Read/Change PID Values 156 PWM Frequency Register 157 Controller Status Register 157 Controller Identification Register 158 Current Amps Limit Registers 158 155 RS232 Encoder Command Set 159 Read Encoder Counter 159 Set/Reset Encoder Counters and Destination Registers 159 Read Speed 160 Read Distance 161 Read Speed/Distance 161 Read Encoder Limit Switch Status 161 Read / Modify Encoder Module Registers and Parameters 162 Register Description 164 Encoder Hardware ID code 164 Switch Status 164 Speed or Distance 1 or 2 165 Counter Read/Write Mailbox 165 Counter 1 and 2 165 Destination Register 1 and 2 165 Distance 1 and 2 166 Speed 1 and 2 166 Time Base 1 and 2 166 Encoder Threshold 166 Distance Divider 166 RC Pulse Outputs Activation 167 Counter Read Data Format 167 Encoder Testing and Setting Using the PC Utility 168 Automatic Switching from RS232 to RC Mode 169 Analog and R/C Modes Data Logging String Format Data Logging Cables 170 Decimal to Hexadecimal Conversion Table SECTION 16 170 171 Configuring the Controller using the Switches 175 Programming Methods 175 Programming using built-in Switches and Display 175 10 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Entering Programming Mode 176 Changing parameters 177 The Special Case of Joystick Calibration 177 Restoring factory defaults 178 Exiting the Parameter Setting Mode 178 Programmable Parameters List 178 SECTION 17 Using the Roborun Configuration Utility 181 System Requirements 181 Downloading and Installing the Utility 181 Connecting the Controller to the PC 182 Roborun Frame, Tab and Menu Descriptions 183 Getting On-Screen Help 184 Loading, Changing Controller Parameters Control Settings 185 Power Settings 186 Analog or R/C Specific Settings 187 Closed Loop Parameters 188 185 Encoder Setting and Testing 188 Encoder Module Parameters Setting 189 Exercising the Motors 190 Viewing Encoder Data 190 RC Output Testing 190 Running the Motors 191 Logging Data to Disk 194 Connecting a Joystick 195 Using the Console 196 Viewing and Logging Data in Analog and R/C Modes 197 Loading and Saving Profiles to Disk 197 Operating the AX3500 over a Wired or Wireless LAN 198 Updating the Controller’s Software 199 Updating the Encoder Software 200 Creating Customized Object Files SECTION 18 Mechanical Specifications Mechanical Dimensions 200 203 203 Mounting Considerations 204 Thermal Considerations 204 Attaching the Controller Directly to a Chassis Precautions to observe 206 205 Wire Dimensions 207 Weight 207 AX3500 Motor Controller User’s Manual 11 12 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 SECTION 0 Important Safety Warnings Read this Section First The AX3500 is a high power electronics device. Serious damage, including fire, may occur to the unit, motors, wiring and batteries as a result of its misuse. Transistors may explode and require the use of safety glasses when operated in direct view. Please review the User’s Manual for added precautions prior to applying full battery or full load power. This product is intended for use with rechargeable batteries Unless special precautions are taken, damage to the controller and/or power supply may occur if operated with a power supply alone. See“Power Regeneration Considerations” on page 37 of the Users Manual. Always keep the controller connected to the Battery. Use the Power Control input to turn On/Off. Avoid Shorts when Mounting Board against Chassis Use precautions to avoid short circuits when mounting the board against a metallic chassis with the heat sink on or removed. See “Attaching the Controller Directly to a Chassis” on page 205. Do not Connect to a RC Radio with a Battery Attached Without proper protection, a battery attached to an RC Radio may inject its voltage directly inside the controller’s sensitive electronics. See Beware of Motor Runaway in Improperly Closed Loop Wiring or polarity errors between the feedback device and motor in position or closed loop position mode may cause the controller to runaway with no possibility to stop it until power is turned off. AX3500 Motor Controller User’s Manual 13 Important Safety Warnings 14 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 SECTION 1 AX3500 Quick Start This section will give you the basic information needed to quickly install, setup and run your AX3500 controller in a minimal configuration. What you will need For a minimal installation, gather the following components: • • • • • One AX3500 Controller and its provided cables 12V to 40V high capacity, high current battery One or two brushed DC motors One R/C to DB15 connector (provided) Miscellaneous wires, connectors, fuses and switch Locating the Switches and Connectors Take a moment to familiarize yourself with the controller’s switches and connectors. AX3500 Motor Controller User’s Manual 15 AX3500 Quick Start The front side (shown in Figure 1) contains the buttons and display needed to operate and monitor the controller. The 15-pin connector provides the connection to the R/C radio, joystick or microcomputer, as well as connections to optional switches and sensors. Connector to Receiver/Controls and sensors RC Outputs connectors Controller Configuration buttons Connector to Optical Encoders Operating Status and Program LED Display FIGURE 1. Controller Front View At the back of the controller (shown in the figure below) are located all the Fast-on tabs that must be connected to the batteries and the motors. Note: Both VMot tabs are connected to each other in the board and must be wired to the same voltage. VMot M2+ M2- Motor 2 3 x Gnd Pwr Ctrl M1+ M1- VMot Motor 1 FIGURE 2. Controller Rear View 16 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Connecting to the Batteries and Motors Connecting to the Batteries and Motors Connection to the batteries and motors is shown in the figure below and is done by connecting wires to the Fast-on tabs on the controller wires. Motor2 Optional Diode Power switch + Fuse On - Off + - Optional Emergency Disconnect VMot M1M1+ PwrCtrl GND GND GND M2M2+ VMot Motor1 Controller 12V to 24V Motor Battery Notes: - The Battery Power connection are doubled in order to provide the maximum current to the controller. If only one motor is used, only one set of motor power cables needs to be connected. - Typically, 1, 2 or 3 x 12V batteries are connected in series to reach 12, 24 or 36V respectively. - The Power Control wire MUST be used to turn On and Off the controller. FIGURE 3. AX3500 Electrical Power Wiring Diagram 1- Connect each motor to one of the two M+ and M- tabs pairs. Make sure to respect the polarity, otherwise the motor(s) may spin in the opposite direction than expected 2- Connect two of the three Ground tabs to the minus (-) terminal of the battery that will be used to power the motors. Connect the two VMot tabs to the plus (+) terminal of the battery. The motor battery may be of 12 to 40 Volts. There is no need to insert a separate switch on Power cables, although one is suggested for Emergency disconnect. See “Controller Power” on page 30 for a detailed discussion and more wiring options. Avoid extending the length of wires from the battery to the controller as the added inductance may cause damage to the controller when operating at high currents. Try extending the motor wires instead since the added inductance on the motor side of the controller is not harmful. The two VMot tabs are connected to each other inside the controller. The same is true for the tabs. You should wire each pair together as shown in the diagram above. 3- The Power control tab MUST be connected to Ground to turn the Controller Off. For turning the controller On, even though the Power Control may be left floating, whenever possible pull it to an unfused12V or higher voltage to keep the controller logic solidly On. You may use a separate battery to keep the controller alive as the main Motor battery discharges. Refer to the chapter “Connecting Power and Motors to the Controller” on AX3500 Motor Controller User’s Manual 17 AX3500 Quick Start page 29 for more information about batteries and other connection options. Important Warn- ing Do not rely on cutting power to the controller for it to turn off if the Power Control is left floating. If motors are spinning because the robot is pushed are pushed or because of inertia, they will act as generators and will turn the controller, possibly in an unsafe state. ALWAYS ground the Power Control wire to turn the controller Off and keep it Off. Important Warning The controller includes large capacitors. When connecting the Motor Power Cables, a spark will be generated at the connection point. This is a normal occurrence and should be expected. Connecting to the 15-pin Connector The controller’s I/O are located on it’s standard 15-pin D-Sub Connector. The functions of some pins varies depending on controller model and operating mode. Pin assignment is found in the table below. Signal Pin RC Mode RS232 Mode Analog Mode 1 2A Digital Output C (same as pin 9) 2 TxData 3 RC Ch1 RxData Unused 4 RC Ch 2 Digital Input F 5 Ground Out 6 Ground In (Unused on RevB Hardware) 7 +5V In (Unused on RevB Hardware) 8 Digital Input E (Not available when Encoder module is present) and Analog Input 4 (on RevB hardware only) 18 9 2A Digital Output C (same as pin 1) 10 Analog Input 2 11 Analog Input 1 12 Analog Input 4 (on RevB hardware) 13 Ground Out 14 +5V Out (100mA max.) 15 Emergency Stop or Invert Switch input AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Connecting the R/C Radio Connecting the R/C Radio Connect the R/C adapter cables to the controller on one side and to two or three channels on the R/C receiver on the other side. When operating the controller in “Separate” mode, the wire labelled Ch1 controls Motor1, and the wire labelled Ch2 controls Motor2. When operating the controller in “Mixed” mode, Ch1 is used to set the robot’s speed and direction, while Ch2 is used for steering. See “R/C Operation” on page 113 of the User’s Manual for a more complete discussion on R/C commands, calibration and other options. Channel 3 Channel 2 3: 4: 6: 7: 8: Channel 1 Channel 1 Command Pulses Channel 2 Command Pulses Radio battery (-) Ground Radio battery (+) Channel 3 Command Pulses 8 9 Pin 1 Wire loop bringing power from controller to RC radio 15 FIGURE 4. R/C connector wiring for 3 channels and battery elimination (BEC) This wiring - with the wire loop uncut - assumes that the R/C radio will be powered by the AX3500 controller. Other wiring options are described in “R/C Operation” on page 113 of the User’s Manual. Important Warning Do not connect a battery to the radio when the wire loop is uncut. The RC battery voltage will flow directly into the controller and cause permanent damage if its voltage is higher than 5.5V. Powering On the Controller Important reminder: There is no On-Off switch on the controller. You must insert a switch on the controller’s power tab as described in section“Connecting to the Batteries and Motors” on page 17. AX3500 Motor Controller User’s Manual 19 AX3500 Quick Start To power the controller, center the joystick and trims on the R/C transmitter. Then turn on the switch that you have placed on the Battery Power wire or on the Power Control input. If the R/C transmitter and/or receiver is powered off, the display on the controller will alternate the letters spelling “no ctrl” to indicate that it is On but is not receiving a control signal. FIGURE 5. “no control” scroll message indicates no valid R/C signal is present Turn the R/C transmitter On. The “no ctrl” scrolling message will disappear and the display will show steady patterns depending on the motor’s selected direction. Move the joystick on the transmitter to activate the motors to the desired speed and direction. See “R/C Operation” on page 113 of the User’s Manual for a detailed description of the many features and options available in the R/C mode. Button Operation The AX3500 has three buttons: Set, Program and Reset. These buttons are not needed for normal operation, as the controller is immediately operational upon power up. The Reset button will restart the controller. This button is recessed and you will need a paper clip to press it. Reset is also accomplished by turning the controller’s power Off and back On. The Set and Program buttons have the following functions depending how and when they are pressed: TABLE 1. AX3500 Buttons Function 20 Prog and Set button status Function Press and hold Program alone during reset or power up Enter the Programming Mode. Press and hold Set alone during reset of power up Enter Self-Test mode. See “Self-Test Mode” on page 53 of the User’s Manual Press and hold Program and Set together during reset or power up Reset configuration parameters to factory default Press Program while Programming Mode Accept previous parameter change and select next parameter Press Set while in Programming mode Change value of selected parameter Press Program pressed alone during normal operation No effect AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Default Controller Configuration TABLE 1. AX3500 Buttons Function Prog and Set button status Function Press Set alone during normal operation No effect Press Program and Set together during normal operation Emergency stop Default Controller Configuration Version 1.9b of the AX3500 software is configured with the factory defaults shown in the table below. Although Roboteq strives to keep the same parameters and values from one version to the next, changes may occur from one revision to the next. Make sure that you have the matching manual and software versions. These may be retrieved from the Roboteq web site. See “Configuring the Controller using the Switches” on page 175 of the User Manual for a complete configuration parameter list and their possible values. TABLE 2. AX3500 Default Settings Parameter Default Values Input Command mode: (0) = R/C Radio mode Letter I Motor Control mode (0) = Separate A, B, speed control, open loop C Amp limit (5) = 52.5A A Acceleration (2) = medium-slow S Input switch function (3) = no action U Joystick Deadband (2) = 16% d Exponentiation on channel 1 (0) = Linear (no exponentiation) E Exponentiation on channel 2 (0) = Linear (no exponentiation) F Left / Right Adjust (7) = no adjustment L Any one of the parameters listed in Table 2, and others not listed, can easily be changed either using the controller’s buttons or the PC with the Roboteq Configuration Utility. See “Using the Roborun Configuration Utility” on page 181. The example below shows how to use the buttons to select and change the Motor Control mode from “separate” to “mixed”. See “Configuring the Controller using the Switches” on page 175 of the User’s Manual for a complete list of all the AX3500’s parameters and their meanings. AX3500 Motor Controller User’s Manual 21 AX3500 Quick Start Restart Press & hold Prog Program mode entered after 10 seconds Press Prog to select next parameter Press Set to select next value for parameter Press Prog to store change and select next parameter Reset controller to exit Press and hold the Prog button for 10 seconds while resetting or powering on the controller After 10 seconds, the controller will enter the programming mode and flash alternatively the current parameter (I= Input Mode) and its value (0= R/C mode). Press the Prog button to move to the next parameter (C= Motor Control Mode) and its value (0= Separate) Press the Set button to change the parameter’s value (1= Combined) Press the Prog button record the change and move to the next parameter (A= Amps limit) and it’s value (2= 75A) Press the Reset button or power off/on the control to restart the controller using the new parameters. Connecting the controller to your PC using Roborun Connecting the controller to your PC is not necessary for basic R/C operation. However, it is a very simple procedure that is useful for the following purposes: 22 • to Read and Set the programmable parameters with a user-friendly graphical interface • • • • • to obtain the controller’s software revision and date to send precise commands to the motors to read and plot real-time current consumption value Save captured parameters onto disk for later analysis to update the controller’s software AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Obtaining the Controller’s Software Revision Number FIGURE 6. Roborun Utility screen layout To connect the controller to your PC, use the provided cable. Connect the 15-pin connector to the controller. Connect the 9-pin connector to your PC’s available port (typically COM1) use a USB to serial adapter if needed. Apply power to the controller to turn it on. Load your CD or download the latest revision of Roborun software from www.Roboteq.com, install it on your PC and launch the program. The software will automatically establish communication with the controller, retrieve the software revision number and present a series of buttons and tabs to enable its various possibilities. The intuitive Graphical User Interface will let you view and change any of the controller’s parameters. The “Run” tab will present a number of buttons, dials and charts that are used for operating and monitoring the motors. Obtaining the Controller’s Software Revision Number One of the unique features of the AX3500 is the ability to easily update the controller’s operating software with new revisions downloaded from Roboteq’s web site at www.roboteq.com. This is useful for adding features and/or improving existing ones. Each software version is identified with a unique number. Obtaining this number can be done using the PC connection discussed previously. AX3500 Motor Controller User’s Manual 23 AX3500 Quick Start It is also possible to get the controller to display the software version number by following these simple steps • Disconnect the power from the motor batteries. Power the controller only via the Power Control input. • Press and hold the Set button while powering or resetting the controller. The LED will display a sequence of two numerical digits and an optional letter separated by dashes as shown in the examples below. = Software version 1.9b FIGURE 7. Press and hold “Set” to display version number and enter self-test After these digits are displayed, the controller will attempt to power the motors as part of the self test mode (see “Self-Test Mode” on page 53 of the User’s Manual for a more detailed explanation). This is why the motor’s battery must be disconnected. After about 30 seconds, the software revision number will be displayed again the cycle will repeat. You will need to reset, or power down and up, the controller to exit and resume normal operation. Now that you know your controller’s software version number, you will be able to see if a new version is available for download and installation from Roboteq’s web site and which features have been added or improved. Installing new software is a simple and secure procedure, fully described in “Updating the Controller’s Software” on page 199 of the User’s Manual. Exploring further By following this quick-start section, you should have managed to get your controller to operate in its basic modes within minutes of unpacking. Each of the features mentioned thus far has numerous options which are discussed further in the complete User’s Manual, including: • • • • • • • • 24 Self test mode Emergency stop condition Joystick calibration Using Inputs/Outputs Current limiting Closed Loop Operation Software updating and much more AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 SECTION 2 AX3500 Motor Controller Overview Congratulations! By selecting Roboteq’s AX3500 you have empowered yourself with the industry’s most versatile, and programmable DC Motor Controller for mobile robots. This manual will guide you step by step through its many possibilities. Product Description The AX3500 is a highly configurable, microcomputer-based, dual-channel digital speed or position controller with built-in high power drivers. The controller is designed to interface directly to high power DC motors in computer controlled or remote controlled mobile robotics and automated vehicle applications. The AX3500 controller can accept speed or position commands in a variety of ways: pulse-width based control from a standard Radio Control receiver, Analog Voltage commands, or RS-232 commands from a microcontroller or wireless modem. The controller's two channels can be operated independently or can be combined to set the forward/reverse direction and steering of a vehicle by coordinating the motion on each side of the vehicle. In the speed control mode, the AX3500 can operate in open loop or closed loop. In closed loop operation, actual speed measurements from tachometers or optical encoders are used to verify that the motor is rotating at the desired speed and direction and to adjust the power to the motors accordingly. The AX3500 can also be configured to operate as a precision, high torque servo controller. When connected to a potentiometer coupled to the motor assembly, the controller will command the motor to rotate up to a desired angular position. Depending on the DC motor's power and gear ratio, the AX3500 can be used to move or rotate steering columns or other physical objects with very high torque. The AX3500 is fitted with many safety features ensuring a secure power-on start, automatic stop in case of command loss, over current protection on both channels, and overheat protection. AX3500 Motor Controller User’s Manual 25 AX3500 Motor Controller Overview The motors are driven using high-efficiency Power MOSFET transistors controlled using Pulse Width Modulation (PWM) at 16kHz. The AX3500 power stages can operate from 12 to 40VDC and can sustain up to 60A of controlled current, delivering up to 2400W (approximately 3 HP) of useful power to each motor. The many programmable options of the AX3500 are easily configured using the supplied PC utility or one-touch Program and Set buttons and a 7-segment LED display. Once programmed, the configuration data are stored in the controller's non-volatile memory, eliminating the need for cumbersome and unreliable jumpers. Optical Encoders allow precise motor speed and position measurement and enable advance robotic applications. Technical features Fully Digital, Microcontroller-based Design • • Multiple operating modes • • • Non-volatile storage of user configurable settings Fully programmable using either built-in switches and 7 segment display or through connection to a PC Simple operation Software upgradable with new features Multiple Command Modes • • • Radio-Control Pulse-Width input Serial port (RS-232) input 0-5V Analog Command input Multiple Advanced Motor Control Modes • • • • • Independent operation on each channel Mixed control (sum and difference) for tank-like steering Open Loop or Closed Loop Speed mode Position control mode for building high power position servos Modes selectable independently for each channel Automatic Joystick Command Corrections • • • Joystick min, max and center calibration Selectable deadband width Selectable exponentiation factors for each joystick Special Function Inputs/Outputs • 2 Analog inputs. Used as: • • 26 Tachometer inputs for closed loop speed control Potentiometer input for position (servo mode) AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Technical features • • • • User defined purpose (RS232 mode only) Potentiometer input for position while in analog command mode User defined purpose (RS232 mode only) One Switch input configurable as • • • • • External voltage sensors 2 Extra analog inputs (on RevB hardware). Used as: • • • Motor temperature sensor inputs Emergency stop command Reversing commands when running vehicle inverted General purpose digital input One general purpose 24V, 2A output for accessories Up to 2 general purpose digital inputs Optical Encoder Inputs • • • • Inputs for two Quadrature Optical Encoders up to 250khz Encoder frequency per channel two 32-bit up-down counters Inputs may be shared with four optional limit switches per channel Internal Sensors • • • • Voltage sensor for monitoring the main 12 to 40V battery system operation Voltage monitoring of internal 12V Temperature sensors on the heat sink of each power output stage Sensor information readable via RS232 port Low Power Consumption • • On board DC/DC converter for single 12 to 40V battery system operation • • Max 200mA at 12V or 100mA at 24V idle current consumption • • No power consumed by output stage when motors are stopped Optional backup power input for powering safely the controller if the motor batteries are discharged Power Control wire for turning On or Off the controller from external microcomputer or switch Regulated 5V output for powering R/C radio. Eliminates the need for separate R/C battery High Efficiency Motor Power Outputs • • • • • • • • Two independent power output stages Optional Single Channel operation at double the current Dual H bridge for full forward/reverse operation Ultra-efficient 2.5mOhm ON resistance (RDSon) MOSFET transistors Synchronous Rectification H Bridge 12 to 40 V operation High current Fast-on power connection tabs for power stage AX3500 Motor Controller User’s Manual 27 AX3500 Motor Controller Overview • Temperature-based Automatic Current Limitation • • • • • • • • • 60A up to 15 seconds (per channel) 50A up to 30 seconds 40A extended High current operation may be extended with forced cooling 250A peak Amps per channel 16kHz Pulse Width Modulation (PWM) output Auxiliary output for brake, clutch or armature excitation Heat sink on PCB Optional Bottom Aluminum place for conduction cooling (BP version) Advanced Safety Features • • • Safe power on mode • • • Overvoltage and Undervoltage protection • • • • Large, bright run/failure diagnostics on 7 segment LED display Optical isolation on R/C control inputs Automatic Power stage off in case of electrically or software induced program failure Regeneration current limiting Watchdog for automatic motor shutdown in case of command loss (R/C and RS232 modes) Programmable motor acceleration Built-in controller overheat sensor Emergency Stop input signal and button Data Logging Capabilities • 13 internal parameters, including battery voltage, captured R/C command, temperature and Amps accessible via RS232 port • Data may be logged in a PC, PDA or microcomputer Compact Open Frame PCB Design • • • • • 28 Surface mount PCB design Efficient heat sinking. Operates without a fan in most applications. 6.75” (171.5mm) long x 4.20” (106.7mm) wide -20o to +85o C heatsink operating environment 7.5oz (220g) AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Power Connections SECTION 3 Connecting Power and Motors to the Controller This section describes the AX3500 Controller’s connections to power sources and motors. Important Warning Please follow the instructions in this section very carefully. Any problem due to wiring errors may have very serious consequences and will not be covered by the product’s warranty. Power Connections The AX3500 has three Ground, two Vmot Fast-on tabs and a Power Control tab. The power cables tabs are located at the back end of the controller. The various power tabs are identified by markings on the PCB.The power connections to the batteries and motors are shown in the figure below. AX3500 Motor Controller User’s Manual 29 Connecting Power and Motors to the Controller Note: Both VMot tabs are connected to each other in the board and must be wired to the same voltage. VMot M2+ M2- 3 x Gnd Motor 2 Pwr Ctrl M1+ M1- VMot Motor 1 FIGURE 8. Controller Rear View and Power Connector Tabs Controller Power The AX3500 uses a flexible power supply scheme that is best described in Figure 9. In this diagram, it can be seen that the power for the Controller’s microcomputer is separate from this of the motor drivers. The microcomputer circuit is connected to a DC/DC converter which takes power from either the Power Control wire or the VMot input. The diode circuit is designed to automatically select one power source over the other, letting through the source that is higher than the other. 30 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Controller Power Mot1(-) Mot1(+) 5Vmin 40V max Channel 1 MOSFET Power Stage 9.5V min 13V max DC/DC 10.5V min 40V max Channel 2 MOSFET Power Stage GND Power Control &Backup ENABLE Microcomputer & MOSFET Drivers VBatt Vmot GND 5Vmin 40V max GND VBatt Vmot Mot2(+) Mot2(-) FIGURE 9. Representation of the AX3500’s Internal Power Circuits When powered only via the Power Control input, the controller will turn On but motors will not be able to turn until power is also present on the VMot tabs The Power Control input also serves as the Enable signal for the DC/DC converter. When floating or pulled to above 1V, the DC/DC converter is active and supplies the AX3500’s microcomputer and drivers, thus turning it On. When the Power Control input is pulled to Ground, the DC/DC converter is stopped and the controller is turned Off. The Power control tab MUST be connected to Ground to turn the Controller Off. For turning the controller On, even though the Power Control may be left floating, whenever possible pull it to an unfused12V or higher voltage to keep the controller logic solidly On. You may use a separate battery to keep the controller alive as the main Motor battery discharges. The table below shows the state of the controller depending on the voltage applied to Power Control and Vmot. TABLE 3. Controller Status depending on Power Control and VMot Power Control input is connected to And Main Battery Voltage is Action Ground Any Voltage from 0V to 40V Controller is Off Floating 0V Controller is Off. Not Recommended Off Configuration. Floating Between 8V and 10.5V Controller Logic is On Power Stage is Disabled (undervoltage condition) Floating Between 10.5 and 40V Controller is On. Power Stage is Active AX3500 Motor Controller User’s Manual 31 Connecting Power and Motors to the Controller TABLE 3. Controller Status depending on Power Control and VMot Power Control input is connected to And Main Battery Voltage is Action 10.5V to 40V 0V Controller is On. 10.5V to 40V 1V to 40V Controller is On. Power Stage is Off Power Stage is Active All 3 ground (-) are connected to each other inside the controller. The two main battery wires are also connected to each other internally. However, you must never assume that connecting one wire of a given battery potential will eliminate the need to connect the other. Controller Powering Schemes Powering the Controller from a single Battery The diagram on Figure 12 show how to wire the controller to a single battery circuit and how to turn power On and Off. Motor2 Power on/off Fuse switch + - Optional Emergency Disconnect + VMot M1+ M1VCon GND GND GND M2M2+ VMot Motor1 Controller 12V to 24V Motor Battery Notes: - The Battery Power connection are doubled in order to provide the maximum current to the controller. If only one motor is used, only one set of motor power cables needs to be connected. - Typically, 1, 2 or 3 x 12V batteries are connected in series to reach 12V, 24V or 36V respectively. FIGURE 10. Powering the AX3500 from a single battery Connect two of the three Ground tabs to the minus (-) terminal of the battery that will be used to power the motors. Connect the two VMot tabs to the plus (+) terminal of the battery. The motor battery may be of 12 to 40 Volts. 32 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Controller Powering Schemes There is no need to insert a separate switch on Power cables, although for safety reasons, it is highly recommended that a way of quickly disconnecting the Motor Power be provided in the case of loss of control and all of the AX3500 safety features fail to activate. The two VMot tabs are connected to each other inside the controller. The same is true for the Ground tabs. You should wire each pair together as shown in the diagram above. The Power control tab MUST be connected to Ground to turn the Controller Off. When the controller is Off, the output transistors are in the Off position and no power is drawn on VMot. For turning the controller On, even though the Power Control may be left floating, whenever possible pull it to an unfused12V or higher voltage to keep the controller logic solidly On. In applications where the motors could be made to run through external force (electric vehicle going downhill, for example), and generate 40V or more, a diode should be placed across the fuse & emergency switch to provide a path, under all circumstances, for the regeneration current. See “Power Regeneration Considerations” on page 37. Important Warning Do not rely on cutting power to the controller for it to turn off if the Power Control is left floating. If motors are spinning because the robot is pushed are pushed or because of inertia, they will act as generators and will turn the controller On, possibly in an unsafe state. ALWAYS ground the Power Control wire to turn the controller Off and keep it Off. Powering the Controller Using a Main and Backup Battery In typical applications, the main motor batteries will get eventually weaker and the voltage will drop below the level needed for the internal microcomputer to properly operate. For all professional applications it is therefore recommended to add a separate 12V (to 40V) power supply to ensure proper powering of the controller under any conditions. This dual battery configuration is highly recommended in 12V systems. AX3500 Motor Controller User’s Manual 33 Connecting Power and Motors to the Controller Motor2 Power switch + On - Off + - VMot M1M1+ PwrCtrl GND GND GND M2M2+ VMot Motor1 Controller 12V to 40V 12V to 40V Motor Battery Backup Battery FIGURE 11. Powering the AX3500 with a Main and Backup Supply Important Warning Unless you can ensure a steady 12V to 40V voltage in all conditions, it is recommended that the battery used to power the controller’s electronics be separate from the one used to power the motors. This is because it is very likely that the motor batteries will be subject to very large current loads which may cause the voltage to eventually dip below 12V as the batteries’ charge drops. The separate backup power supply should be connected to the Power Control input. Connecting the Motors Connecting the motors is simply done by connecting each motor terminal to the M1+ (M2+) and M1- (M2-) tabs. Which motor terminal goes to which of the + or - controller output is typically determined empirically. After connecting the motors, apply a minimal amount of power using the Roborun PC utility with the controller configured in Open Loop speed mode. Verify that the motor spins in the desired direction. Immediately stop and swap the motor wires if not. In Closed Loop Speed or Position mode, beware that the motor polarity must match this of the feedback. If it does not, the motors will runaway with no possibility to stop other than switching Off the power. The polarity of the Motor or off the feedback device may need to be changed. Important Warning Make sure that your motors have their wires isolated from the motor casing. Some motors, particularly automotive parts, use only one wire, with the other connected to the motor’s frame. 34 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Single Channel Operation If you are using this type of motor, make sure that it is mounted on isolators and that its casing will not cause a short circuit with other motors and circuits which may also be inadvertently connected to the same metal chassis. Single Channel Operation The AX3500’s two channel outputs can be paralleled as shown in the figure below so that they can drive a single load with twice the power. To perform in this manner, the controller’s Power Transistor that are switching in each channel must be perfectly synchronized. Without this synchronization, the current will flow from one channel to the other and cause the destruction of the controller. The controller may be ordered with the -SC (Single Channel) suffix. This version incorporates a hardware setting inside the controller which ensures that both channels switch in a synchronized manner and respond to commands sent to channel 1. Warning: + Use this wiring only with -SC versions (Single Channel) of the controller - Pwr Ctrl 12V to 40V VMot M1M1+ VCon GND GND GND M2M2+ VMot GND Controller FIGURE 12. Wiring for Single Channel Operation Converting the AX3500 to Single Channel The AX3500 can be easily modified into a Single Channel version by placing a jumper on the PCB. This step must be undertook only if you have the proper tooling and technical skills. • • • • Disconnect the controller from power Open the controller’s case by removing the front bracket and sliding the cover off Place a drop of solder on the PCB jumper pads show in Place the cover and bracket back Before paralleling the outputs, • Place the load on channel 1 and verify that it is activated by commands on channel 1. AX3500 Motor Controller User’s Manual 35 Connecting Power and Motors to the Controller • Then place the load on channel 2 and verify that is also activated to commands on channel 1. • Commands on channel 2 should have no effects on either output. It will be safe to wire in parallel the controller’s outputs only after you have verified that both outputs react identically to channel 1 commands. Jumper "open" Xilinx MCU Place solder ball to close jumper and enable single channel mode Single Channel FIGURE 13. Jumper setting for Single Channel Operation MCU Xilinx Jumper In for Single Channel FIGURE 14. Jumper setting for Single Channel Operation - RevB Hardware Power Fuses For low Amperage applications (below 30A per motor), it is recommended that a fuse be inserted in series with the main battery circuit as shown in the Figure 10 on page 32. The fuse will be shared by the two output stages and therefore must be placed before the Y connection to the two power wires. Fuse rating should be the sum of the expected current on both channels. Note that automotive fuses are generally slow will be of limited effectiveness in protecting the controller and may be omitted in high current application. The fuse will mostly protect the wiring and battery against after the controller has failed. Important Warning Fuses are typically slow to blow and will thus allow temporary excess current to flow through them for a time (the higher the excess current, the faster the fuse will blow). This characteristic is desirable in most cases, as it will allow motors to draw surges 36 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Wire Length Limits during acceleration and braking. However, it also means that the fuse may not be able to protect the controller. Wire Length Limits The AX3500 regulates the output power by switching the power to the motors On and Off at high frequencies. At such frequencies, the wires’ inductance produces undesirable effects such as parasitic RF emissions, ringing and overvoltage peaks. The controller has built-in capacitors and voltage limiters that will reduce these effects. However, should the wire inductance be increased, for example by extending the wire length, these effects will be amplified beyond the controller’s capability to correct them. This is particularly the case for the main battery power wires. Important Warning Avoid using long cable lengths (beyond 2 feet) from the main power battery to the controller as the added inductance may cause damage to the controller when operating at high currents. Try extending the motor wires instead since the added inductance is less harmful on this side of the controller. If the controller must be located at a longer distance, the effects of the wire inductance may be reduced by using one or more of the following techniques: • • Twisting the power and ground wires over the full length of the wires • Add a capacitor (5,000uF or higher) near the controller Use the vehicle’s metallic chassis for ground and run the positive wire along the surface Electrical Noise Reduction Techniques As discussed in the above section, the AX3500 uses fast switching technology to control the amount of power applied to the motors. While the controller incorporates several circuits to keep electrical noise to a minimum, additional techniques can be used to keep the noise low when installing the AX3500 in an application. Below is a list of techniques you can try to keep noise emission low: • • • • Keep wires as short as possible Loop wires through ferrite cores Add snubber R/C circuit at motor terminals Keep controller, wires and battery enclosed in metallic body Power Regeneration Considerations When a motor is spinning faster than it would normally at the applied voltage, such as when moving downhill or decelerating, the motor acts like a generator. In such cases, the current will flow in the opposite direction, back to the power source. AX3500 Motor Controller User’s Manual 37 Connecting Power and Motors to the Controller It is therefore essential that the AX3500 be connected to rechargeable batteries. If a power supply is used instead, the current will attempt to flow back in the power supply during regeneration, potentially damaging it and/or the controller. Regeneration can also cause potential problems if the battery is disconnected while the motors are still spinning. In such a case, and depending on the command level applied at that time, the regenerated current will attempt to flow back to the battery. Since none is present, the voltage will rise to potentially unsafe levels. The AX3500 includes an overvoltage protection circuit to prevent damage to the output transistors (see “Overvoltage Protection” on page 38). However, if there is a possiblity that the motor could be made to spin and generate a voltage higher than 40V, a path to the battery must be provided, even after a fuse is blown. This can be accomplished by inserting a diode across the fuse as shown in Figure 10 on page 32. Please download the Application Note “Understanding Regeneration” from the www.roboteq.com for an in-depth discussion of this complex but important topic. Important Warning Use the AX3500 only with a rechargeable battery as supply to the Motor Power wires (VMot tabs). If a transformer or power supply is used, damage to the controller and/or power supply may occur during regeneration. See “Using the Controller with a Power Supply” on page 39 for details. Important Warning Avoid switching Off or cutting open the main power cables (VMot tabs) while the motors are spinning. Damage to the controller may occur. Overvoltage Protection The AX3500 includes a battery voltage monitoring circuit that will cause the output transistors to be turned Off if the main battery voltage rises above 43V. This protection is designed to prevent the voltage created by the motors during regeneration to be “amplified” to unsafe levels by the switching circuit. The controller will resume normal operation when the measured voltage drops below 43V. Undervoltage Protection In order to ensure that the power MOSFET transistors are switched properly, the AX3500 monitors the internal 12V power supply that is used by the MOSFET drivers. If the internal voltage drops below 10V, the controller’s output stage is turned Off. The rest of the controller’s electronics, including the microcomputer, will remain operational as long as the internal voltage is above 8V. The internal voltage will be the output of the DC/DC converter which will be a solid 12V as long as either of the main battery or backup voltage is higher than 12.5V. If the main and 38 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Using the Controller with a Power Supply backup voltage drop below 12.V, the DC/DC converter’s output will be approximately 0.5V lower than the highest input. Using the Controller with a Power Supply Using a transformer or a switching power supply is possible but requires special care, as the current will want to flow back from the motors to the power supply during regeneration. As discussed in “Power Regeneration Considerations” on page 37, if the supply is not able to absorb and dissipate regenerated current, the voltage will increase until the overvoltage protection circuit cuts off the motors. While this process should not be harmful to the controller, it may be to the power supply, unless one or more of the protective steps below is taken: • Use a power supply that will not suffer damage in case a voltage is applied at its output that is higher than the transformer’s own output voltage. This information is seldom published in commercial power supplies, so it is not always possible to obtain positive reassurance that the supply will survive such a condition. • Avoid deceleration that is quicker than the natural deceleration due to the friction in the motor assembly (motor, gears, load). Any deceleration that would be quicker than natural friction means that braking energy will need to be taken out of the system, causing a reverse current flow and voltage rise. See “Programmable Acceleration” on page 47. • Place a battery in parallel with the power supply output. This will provide a reservoir into which regeneration current can flow. It will also be very helpful for delivering high current surges during motor acceleration, making it possible to use a lower current power supply. Batteries mounted in this way should be connected for the first time only while fully charged and should not be allowed to discharge. The power supply will be required to output unsafe amounts of current if connected directly to a discharged battery. Consider using a decoupling diode on the power supply’s output to prevent battery or regeneration current to flow back into the power supply. • Place a resistive load in parallel with the power supply, with a circuit to enable that load during regeneration. This solution is more complex but will provide a safe path for the braking energy into a load designed to dissipate it. To prevent current from flowing from the power supply into the load during normal operation, an active switch would enable the load when the voltage rises above the nominal output of the power supply. AX3500 Motor Controller User’s Manual 39 Connecting Power and Motors to the Controller 40 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Basic Operation General Operation SECTION 4 This section discusses the controller’s normal operation in all its supported operating modes. Basic Operation The AX3500’s operation can be summarized as follows: • • • Receive commands from a radio receiver, joystick or a microcomputer Activate the motors according to the received command Perform continuous check of fault conditions and adjust actions accordingly Multiple options are available for each of the above listed functions which can be combined to produce practically any desired mobile robot configuration. Input Command Modes The controller will accept commands from one of the following sources • • • R/C radio Serial data (RS232) Analog signal (0 to 5V) A detailed discussion on each of these modes and the available commands is provided in the following dedicated chapters: “R/C Operation” on page 113, “Serial (RS-232) Controls and Operation” on page 135, and “Analog Control and Operation” on page 127. The controller’s factory default mode is R/C radio. The mode can be changed using any of the methods described in “Programming using built-in Switches and Display” on page 175 and “Loading, Changing Controller Parameters” on page 185. AX3500 Motor Controller User’s Manual 41 General Operation Selecting the Motor Control Modes For each motor, the AX3500 supports multiple motion control modes. The controller’s factory default mode is Open Loop Speed control for each motor. The mode can be changed using any of the methods described in “Programming using built-in Switches and Display” on page 175 and “Loading, Changing Controller Parameters” on page 185. Open Loop, Separate Speed Control In this mode, the controller delivers an amount of power proportional to the command information. The actual motor speed is not measured. Therefore the motors will slow down if there is a change in load as when encountering an obstacle and change in slope. This mode is adequate for most applications where the operator maintains a visual contact with the robot. In the separate speed control mode, channel 1 commands affect only motor 1, while channel 2 commands affect only motor 2. This is illustrated in Figure 15 below. Controller FIGURE 15. Examples of effect of commands to motors in separate mode Open Loop, Mixed Speed Control This mode has the same open loop characteristics as the previously described mode. However, the two commands are now mixed to create tank-like steering when one motor is used on each side of the robot: Channel 1 is used for moving the robot in the forward or reverse direction. Channel 2 is used for steering and will change the balance of power on each side to cause the robot to turn. Figure 16 below illustrates how the mixed mode works. 42 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Selecting the Motor Control Modes Controller FIGURE 16. Effect of commands to motors examples in mixed mode Closed Loop Speed Control In this mode, illustrated in Figure 18, an analog tachometer or an optical encoder is used to measure the actual motor speed. If the speed changes because of changes in load, the controller automatically compensates the power output. This mode is preferred in precision motor control and autonomous robotic applications. Details on how to wire the tachometer can be found in “Connecting Tachometer to Analog Inputs” on page 63. Closed Loop Speed control operation is described in “Closed Loop Speed Mode” on page 101. FIGURE 17. Motor with tachometer or Encoder for Closed Loop Speed operation Close Loop Position Control In this mode, illustrated in Figure 18, the axle of a geared down motor is coupled to a potentiometer that is used to compare the angular position of the axle versus a desired position. This AX3500 feature makes it possible to build ultra-high torque “jumbo servos” that can be used to drive steering columns, robotic arms, life-size models and other heavy loads. Details on how to wire the position sensing potentiometers and operating in this mode can be found in “Closed Loop Position Mode” on page 89. AX3500 Motor Controller User’s Manual 43 General Operation Position Feedback Position Sensor Gear box FIGURE 18. Motor with potentiometer assembly for Position operation User Selected Current Limit Settings The AX3500 has current sensors at each of its two output stages. Every 16 ms, this current is measured and a correction to the output power level is applied if higher than the user preset value. The current limit may be set using the controller’s switches or the supplied PC utility. Using the switches, 7 limits may be selected as shown in the table below. TABLE 4. Current limit settings using the switches Setting Continuous High Amps 0 15A 1 22.5A 2 30A 3 37.5A 4 45A 5 - default 52.5A 6 60A Using the PC utility is it possible to set the limit with a 0.5A granularity from 7.5A to 60A During normal operation, current limiting is further enhanced by the techniques described in the following sections. Temperature-Based Current Limitation The AX3500 features active current limitation that uses a combination of a user defined preset value (discussed above) which in turn may be reduced automatically based on measured operating temperature. This capability ensures that the controller will be able to work safely with practically all motor types and will adjust itself automatically for the various load conditions. 44 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Battery Current vs. Motor Current When the measured temperature reaches 80oC, the controller’s maximum current limit begins to drop to reach 0A at 100oC. Above 100oC, the controller’s power stage turns itself off completely. TABLE 5. Temperature Max Amps Below 80 oC 60A 80 oC 60A 85 oC 40A 90 oC 30A 95 oC 10A 100 oC 0 Above 100 oC Both Power Stages OFF The numbers in the table are the max Amps allowed by the controller at a given temperature point. If the Amps limit is manually set to a lower value, then the controller will limit the current to the lowest of the manual and temperature-adjusted max values. This capability ensures that the controller will be able to work safely with practically all motor types and will adjust itself automatically for the various load and environmental conditions. The time it takes for the heat sink’s temperature to rise depends on the current output, ambient temperature, and available air flow (natural or forced). Note that the measured temperature is measured on the PCB near the Power Transistors and will rise and fall faster than the outside surface. Battery Current vs. Motor Current The controller measures and limits the current that flows from the battery. Current that flows through the motor is typically higher. This counter-intuitive phenomenon is due to the “flyback” current in the motor’s inductance. In some cases, the motor current can be extremely high, causing heat and potentially damage while battery current appears low or reasonable. The motor’s power is controlled by varying the On/Off duty cycle of the battery voltage 16,000 times per second to the motor from 0% (motor off) to 100 (motor on). Because of the flyback effect, during the Off time current continues to flow at nearly the same peak and not the average - level as during the On time. At low PWM ratios, the peak current and therefore motor current - can be very high as shown in Figure 20, “Instant and average current waveforms,” on page 46. The relation between Battery Current and Motor current is given in the formula below: Motor Current = Battery Current / PWM ratio Example: If the controller reports 10A of battery current while at 10% PWM, the current in the motor is 10 / 0.1 = 100A. AX3500 Motor Controller User’s Manual 45 General Operation Vbat On Motor Off FIGURE 19. Current flow during operation On Off I mot Avg I bat Avg FIGURE 20. Instant and average current waveforms The relation between Battery Current and Motor current is given in the formula below: Motor Current = Battery Current / PWM Ratio Example: If the controller reports 10A of battery current while at 10% PWM, the current in the motor is 10 / 0.1 = 100A. Important Warning Do not connect a motor that is rated at a higher current than the controller. While the battery current will never exceed the preset Amps limit, that limit may be reached at a PWM cycle lower than 100% resulting in a higher and potentially unsafe level through the motor and the controller. Regeneration Current Limiting The AX3500’s current sensor is capable of measuring current in the reverse flow (regeneration). Using this capability, the controller will automatically relax the braking effect of the power output stage to keep the regeneration current within safe values. Because of the controller’s high current handling capabilities, this protection mechanism activates only when abrupt deceleration are applied to high-inertia, ultra-low impedance motors. 46 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Programmable Acceleration Programmable Acceleration When changing speed command, the AX3500 will go from the present speed to the desired one at a user selectable acceleration. This feature is necessary in order to minimize the surge current and mechanical stress during abrupt speed changes. This parameter can be changed by using the controller’s front switches or using serial commands. When configuring the controller using the switches (see “Configuring the Controller using the Switches” on page 175), acceleration can be one of 6 available preset values, from very soft(0) to very quick (6). The AX3500’s factory default value is medium soft (2). When using the serial port, acceleration can be one of 24 possible values, selectable using the Roborun utility or entering directly a value in the MCU’s configuration EEPROM. Table 6 shows the corresponding acceleration for all Switch and RS232 settings. Numerically speaking, each acceleration value corresponds to a fixed percentage speed increment, applied every 16 milliseconds. The value for each setting is shown in the table below. TABLE 6. Acceleration setting table Acceleration Setting Using RS232 Acceleration Setting Using Switches %Acceleration per 16ms Time from 0 to max speed 30 Hex 0.78% 2.05 seconds 20 Hex 1.56% 1.02 seconds 10 Hex 2.34% 0.68 second 00 Hex 3.13% 0.51 second 31 Hex 0 3.91% 0.41 second 21 Hex 4.69% 0.34 second 11 Hex 5.47% 0.29 second 01 Hex 1 6.25% 0.26 second 32 Hex - 7.03% 0.23 second 22 Hex - 7.81% 0.20 second 12 Hex - 8.59% 0.19 second 02 Hex 2 (default) 9.38% 0.17 second 33 Hex - 10.16% 0.16 second 23 Hex - 10.94% 0.15 second 13 Hex - 11.72% 0.14 second 03 Hex 3 12.50% 0.128 second 34 Hex - 13.28% 0.120 second 24 Hex - 14.06% 0.113 second 14 Hex - 14.84% 0.107 second 04 Hex 4 15.63% 0.102 second 35 Hex - 16.41% 0.097 second 25 Hex - 17.19% 0.093 second AX3500 Motor Controller User’s Manual 47 General Operation TABLE 6. Acceleration setting table Acceleration Setting Using RS232 Acceleration Setting Using Switches %Acceleration per 16ms Time from 0 to max speed 15 Hex - 17.97% 0.089 second 05 Hex 5 18.75% 0.085 second When configuring the acceleration parameter using the Roborun utility, four additional acceleration steps can be selected between the six ones selectable using the switch, extending the slowest acceleration to 2.04 seconds from 0 to max speed. See “Power Settings” on page 186 for details on how to configure this parameter using Roborun. Important Warning Depending on the load’s weight and inertia, a quick acceleration can cause considerable current surges from the batteries into the motor. A quick deceleration will cause an equally large, or possibly larger, regeneration current surge. Always experiment with the lowest acceleration value first and settle for the slowest acceptable value. Command Control Curves The AX3500 can also be set to translate the joystick or RS232 motor commands so that the motors respond differently whether or not the joystick is near the center or near the extremes. The controller can be configured to use one of 5 different curves independently set for each channel. The factory default curve is a “linear” straight line, meaning that after the joystick has moved passed the deadband point, the motor’s speed will change proportionally to the joystick position. Two “exponential’ curves, a weak and a strong, are supported. Using these curves, and after the joystick has moved past the deadband, the motor speed will first increase slowly, increasing faster as the joystick moves near the extreme position. Exponential curves allow better control at slow speed while maintaining the robot’s ability to run at maximum speed. Two “logarithmic” curves, a weak and a strong, are supported. Using these curves, and after the joystick has moved past the deadpoint, the motor speed will increase rapidly, and then increase less rapidly as the joystick moves near the extreme position. The graph below shows the details of these curves and their effect on the output power as the joystick is moved from its center position to either extreme. The graph is for one joystick only. The graph also shows the effect of the deadband setting. 48 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Left / Right Tuning Adjustment % Forward (Motor Output) 100 80 Logarithmic Strong Logarithmic Weak 60 Linear (default) Exponential Weak Exponential Strong 100 80 60 20 0 40 - 20 - 40 - 60 20 - 80 - 100 40 % Command Input 20 Deadband 40 60 80 100 % Reverse FIGURE 21. Exponentiation curves The AX3500 is delivered with the “linear” curves selected for both joystick channels. To select different curves, the user will need to change the values of “E” (channel 1) and “F” (channel 2) according to the table below. Refer to the chapter “Configuring the Controller using the Switches” on page 175 or “Using the Roborun Configuration Utility” on page 181 for instructions on how to program parameters into the controller. TABLE 7. Exponent selection table Exponentiation Parameter Value Selected Curve E or F = 0 Linear (no exponentiation) - default value E or F = 1 strong exponential E or F = 2 normal exponential E or F = 3 normal logarithmic E or F = 4 strong logarithmic Left / Right Tuning Adjustment By design, DC motors will run more efficiently in one direction than the other. In most situations this is not noticeable. In others, however, it can be an inconvenience. When operating in open loop speed control, the AX3500 can be configured to correct the speed in one direction versus the other by as much as 10%. Unlike the Joystick center trimming tab that AX3500 Motor Controller User’s Manual 49 General Operation is found on all R/C transmitters, and which is actually an offset correction, the Left/Right Adjustment is a true multiplication factor as shown in Figure 22 100 80 60 60 40 40 20 40 40 60 60 80 5.25% 3% 100 % Reverse 0% % Forward (Motor Output) 100 80 0 20 60 % Command Input - 20 - 40 - 60 20 - 80 - 100 100 80 60 20 0 40 - 20 - 40 - 60 - 80 20 40 80 - 100 % Forward (Motor Output) 0% -3% -5.25% 100 20 % Forward (Motor Output) 80 100 % Reverse FIGURE 22. Left Right adjustment curves The curves on the left show how a given forward direction command value will cause the motor to spin 3 or 5.25% slower than the same command value applied in the reverse direction. The curves on the right show how the same command applied to the forward direction will case the motor to spin 3 to 5.25% faster than the same command applied in the reverse direction. Note that since the motors cannot be made to spin faster than 100%, the reverse direction is the one that is actually slowed down. In applications where two motors are used in a mixed mode for steering, the Left/Right Adjustment parameter may be used to make the robot go straight in case of a natural tendency to steer slightly to the left or to the right. The Left/Right adjustment parameter can be set from -5.25% to +5.25% in seven steps of 0.75%. See “Programmable Parameters List” on page 178 and “Loading, Changing Controller Parameters” on page 185 for details on how to adjust this parameter. The Left/Right adjustment is performed in addition to the other command curves described in this section. This adjustment is disabled when the controller operates in any of the supported closed loop modes. TABLE 8. Left/Right Adjustment Parameter selection Parameter Value 50 Speed Adjustment Parameter Value Speed Adjustment 7 None (default) 0 -5.25% 8 0.75% 1 -4.5% 9 1.5% 2 -3.75% 10 2.25% 3 -3% 11 3% 4 -2.25% 12 3.75% AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Activating Brake Release or Separate Motor Excitation TABLE 8. Left/Right Adjustment Parameter selection Parameter Value Speed Adjustment Parameter Value Speed Adjustment 5 -1.5% 12 4.5% 6 -0.75% 14 5.25% Activating Brake Release or Separate Motor Excitation The controller may be configured so that the Output C will turn On whenever one of the two motors is running. This feature is typically used to activate the mechanical brake release sometimes found on motors for personal mobility systems. Likewise, this output can be used to turn on or off the winding that creates the armature’s magnetic field in a separate excitation motor. This function is disabled by default and may be configured using the Roborun PC utility. See “Loading, Changing Controller Parameters” on page 185. See “Connecting devices to Output C” on page 59 for details on how to connect to the output. Emergency Shut Down Using Controller Switches In case of emergency, it is possibly to cause the controller to cut off the power to the motors by depressing the Program and Set buttons simultaneously as shown in the figure below. The controller will stop immediately without delay. Program Set Reset Press the two buttons simultaneously to cause an emergency stop FIGURE 23. Activating an Emergency Stop After and Emergency Stop condition, the controller must be reset or powered Off and On to resume normal operation. Emergency Stop using External Switch An external switch can be added to the AX3500 to allow the operator to stop the controller’s output in case of emergency. This controller input can be configured as the “Inverted” detection instead of Emergency Stop. The factory default for this input is “No Action”. AX3500 Motor Controller User’s Manual 51 General Operation The switch connection is described in “Connecting Switches or Devices to EStop/Invert Input” on page 61. The switch must be such that it is in the open state in the normal situation and closed to signal an emergency stop command. After and Emergency Stop condition, the controller must be reset or powered Off and On to resume normal operation. Inverted Operation For robots that can run upside-down, the controller can be configured to reverse the motor commands using a gravity activated switch when the robot is flipped. This feature is enabled only in the mixed mode and when the switch is enabled with the proper configuration of the “Input switch function” parameter. See “Programmable Parameters List” on page 178. The switch connection is described in “Connecting Switches or Devices to EStop/Invert Input” on page 61. The switch must be such that it is in the open state when the robot is in the normal position and closed when inverted. When the status of the switch has changed, the controller will wait until the new status has remained stable for 0.5s before acknowledging it and inverting the commands. This delay is to prevent switch activation triggered by hits and bounces which may cause the controller to erroneously invert the commands. Special Use of Accessory Digital Inputs The AX3500 includes one general purpose digital inputs identified as Input F. The location of this input on the DB15 connector can be found in the section “I/O List and Pin Assignment” on page 58, while the electrical signal needed to activate it is shown on “Connecting Switches or Devices to Input F” on page 60. Note that other members of the Roboteq family of controllers have an additional digital input, Input E, which is not present on the AX3500 By default, these inputs are ignored by the controller. However, the AX3500 may be configured to cause either of the following actions: • • Activate the buffered Output C Turn Off/On the power MOSFET transistors These alternate modes can only be selected using the Roborun Utility (see “Control Settings” on page 185. Each of these modes is detailed below. Using the Inputs to Activate the Buffered Output When this setting is selected, the buffered Output C will be On when the Input line is pulled to Ground (0V). The Output will be Off when the Input is pulled high. This function makes it possible to drive solenoids or other accessories up to 2A at 24V using a very low current switch, for example. Using the Inputs to turn Off/On the Power MOSFET transistors When this setting is selected, the controller’s Power MOSFET transistors will be active, and the controller will be operating normally, only when the input is pulled to ground. 52 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Self-Test Mode When the input is pulled high, all the power MOSFETs are turned Off so that the motors are effectively disconnected from the controller. This function is typically used to create a “dead man switch” when the controller is driven using an analog joystick. The motors will be active only while the switch is depressed. If the switch is left off for any reason, the motors will be disconnected and allowed to freewheel rather than coming to an abrupt stop. Self-Test Mode The AX3500 incorporates a simple Self-Test mode that performs the following functions: • • • Display the software revision number on the LED display Ramp each motor up and down in both directions Internal parameters on the serial port output The Self Test mode can be conveniently initiated using only the controller’s switches so that no radio or computer is needed. To enter the Self Test mode, press and hold the Set button while resetting or powering up the controller. After a few seconds, the LEDs will display a sequence of two numerical digits and an optional letter separated by dashes as shown in the examples below. = Software version 1.9b FIGURE 25. Press and hold “Set” to display version number and enter self-test After these digits are displayed, the controller will attempt to power the motors. Motor 1 will be ramped from stop to full speed forward to full speed reverse and back to stop. Then the same operation will repeat on motor 2. After both motors have completed their ramps, the software revision will be displayed again and the motors will be ramped again. This sequence will repeat itself indefinitely until the controller is powered off or reset. While in the Self Test mode, the AX3500 will continuously send a string of characters on the RS232 output line. This string will contain 13 two-digits hexadecimal number representing the 13 following operating parameters. • • • • • • • Captured R/C Command 1 and 2 Power Applied to Controller’s output stage Values applied to Analog inputs 1 and 2 Amps on channel 1 and 2 Internal Heat Sink temperatures 1 and 2 Main Battery voltage Internal 12V voltage AX3500 Motor Controller User’s Manual 53 General Operation • Encoder Speed or Position The entire string is repeated every 224 milliseconds with the latest internal parameter values. This information can be logged using the Roborun Utility (see “Viewing and Logging Data in Analog and R/C Modes” on page 197). The string and data format is described in “Analog and R/C Modes Data Logging String Format” on page 170. Important Warning Disconnect the Motor Power (Vmot tabs) from the battery and power the controller by applying 12V on the Power Control input if you do not wish the motors to be activated while in Self Test mode. This could be the case if you only wish to use the Self Test sequence to read the software revision number or to monitor the joystick capture. 54 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 AX3500 Connections SECTION 5 Connecting Sensors and Actuators to Input/Outputs This section describes the various inputs and outputs and provides guidance on how to connect sensors, actuators or other accessories to them. AX3500 Connections The AX3500 uses a set of power wires (located on the back of the unit) and a DB15 connector for all necessary connections. The diagram on the figure below shows a typical wiring diagram of a mobile robot using the AX3500 controller. The wires are used for connection to the batteries and motors and will typically carry large current loads. Details on the controller’s power wiring can be found at “Connecting Power and Motors to the Controller” on page 29 The DB15 connector is used for all low-voltage, low-current connections to the Radio, Microcontroller, sensors and accessories. This section covers only the connections to sensors and actuators. For information on how to connect the R/C radio or the RS232 port, see “R/C Operation” on page 113 and “Serial (RS-232) Controls and Operation” on page 135. AX3500 Motor Controller User’s Manual 55 Connecting Sensors and Actuators to Input/Outputs 2 1 4 3 3 6 5 7 9 8 1- DC Motors 2- Optional sensors: - Optical Encoder (all closed loop modes) - Tachometers (Closed loop Speed mode) - Potentiometers (Servo mode) 3- Motor Power supply wires 4- Power Control wire5- Controller 6- R/C Radio Receiver, microcomputer, or wireless modem 7- Command: RS-232, R/C Pulse 8- Miscellaneous I/O 9- Running Inverted, or emergency stop switch FIGURE 26. Typical controller connections AX3500’s Inputs and Outputs In addition to the RS232 and R/C channel communication lines, the AX3500 includes several inputs and outputs for various sensors and actuators. Depending on the selected oper- 56 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 AX3500’s Inputs and Outputs ating mode, some of these I/Os provide feedback and/or safety information to the controller. When the controller operates in modes that do not use these I/O, these signals become available for user application. Below is a summary of the available signals and the modes in which they are used by the controller or available to the user. TABLE 9. AX3500 IO signals and definitions Signal I/O type Use Activated Out C 2A Digital Output User defined Activated using R/C channel 3 (R/C mode), or serial command (RS232 mode) Activated when any one motor is powered (when enabled) Inp F Digital Input User defined Active in RS232 mode only. Read with serial command (RS232) Activate Output C When Input is configured to drive Output C Turn FETs On/Off When Input is configured as “dead man switch” input Inp E Digital Input Unused EStop/Invert Digital Input Emergency stop When Input is configured as Emergency Stop switch input. Invert Controls When Input is configured as Invert Controls switch input. User defined When input is configured as general purpose. Read with serial command (RS232). Tachometers input When Channel 1 is configured in Closed Loop Speed Control with Analog feedback Position sensing When Channel 1 is configured in Closed Loop Position Control with RC or RS232 command and Analog feedback User defined Read value with serial command (RS232). Analog In 1 Analog Input Analog In 2 Analog Input 2 Same as Analog 1 but for Channel 2 Analog In 3 Analog Input 2 Position sensing When Channel 1 is configured in Closed Loop Position Control with Analog command and Analog feedback User defined Read value with serial command (RS232). Analog In 4 Analog Input 2 Same as Analog 3 but for Channel 4 AX3500 Motor Controller User’s Manual 57 Connecting Sensors and Actuators to Input/Outputs I/O List and Pin Assignment The figure and table below lists all the inputs and outputs that are available on the AX3500. 9 15 Pin1 8 FIGURE 27. Controller’s DB15 connector pin numbering TABLE 10. DB15 connector pin assignment Pin Number Input or Output Signal Description 1 and 9 Output Output C 2A Accessory Output C R/C: RS232 data RS232 Data Logging Output RS232: Data Out RS232 Data Out Analog: RS232 Out RS232 Data Logging Output R/C: Ch 1 R/C radio Channel 1 pulses RS232: Data In RS232 Data In (from PC/MCU) Analog: Unused Unused 2 Output 3 R/C: Ch 2 R/C radio Channel 2 pulses RS232/Analog: Input F Digital Input F readable RS232 mode Dead man switch activation Power Out Ground Controller ground (-) 4 Input 5 and 13 6 7 58 Input GND In Ground Optocoupler GND Input, Connect to pin 5** Unused in RevB Hardware Unused in RevB Hardware Unused in RevB Hardware +5V In +5V Optocoupler +5V Input. Connect to pin 14** Unused in RevB Hardware Unused in RevB Hardware Unused in RevB Hardware AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Connecting devices to Output C TABLE 10. DB15 connector pin assignment Pin Number 8 Input or Output Digital In and Analog In Signal Description R/C: Ch 3 R/C radio Channel 3 pulses - (Not available onAX3500) RS232: Input E / Ana in 4 Analog Input 4 in RevB Hardware Ana: Input E / Ana in 4 Channel 2 speed or position feedback input in RevB Hardware RC/RS232: Ana in 2 Channel 2 speed or position feedback input 10 Analog in Analog: Command 2 Analog command for channel 2 11 Analog in RC/RS232: Ana in 1 Channel 1 speed or position feedback input Analog: Command 1 Analog command for channel 1 12 RC: Unused RS232: Ana in 3 Analog input 3 Ana: Ana in 3 Channel 1 speed or position feedback input in RevB Hardware 14 Power Out +5V +5V Power Output (100mA max.) 15 Input Input EStop/Inv Emergency Stop or Invert Switch input **These connections should only be done in RS232 mode or R/C mode with radio powered from the controller. Connecting devices to Output C Output C is a buffered, Open Drain MOSFET output capable of driving over 2A at up to 24V. The diagrams on Figure 28 show how to connect a light or a relay to this output: AX3500 Motor Controller User’s Manual 59 Connecting Sensors and Actuators to Input/Outputs Relay, Valve Motor, Solenoid or other Inductive Load Lights, LEDs, or any other non-inductive load + + 5 to 24V DC - Output C 1,9 Internal Transistor 5 to 24V DC - Ground 5 Output C 1,9 Internal Transistor Ground 5 FIGURE 28. Connecting inductive and resistive loads to Output C This output can be turned On and Off using the Channel 3 Joystick when in the R/C mode. See “Note: Channel 3 is not available on the controllers equipped with encoder inputs.” on page 124 for more information. When the controller is used in RS232 mode, this output can be turned On and Off using the !C (On) and !c (Off) command strings. See “Controller Commands and Queries” on page 142 for more information. Important warning: Overvoltage spikes induced by switching inductive loads, such as solenoids or relays, will destroy the transistor unless a protection diode is used. Connecting Switches or Devices to Input F Input F is a general purpose digital input. This input is only active when in the RS232 or Analog modes. In R/C mode, this line is used as the radio channel 2 input. When left open, Input F is in an undefined stage. As shown in the figure below, a pull down or pull up resistor must be inserted when used with a single pole switch. The resistor may be omitted when used with a dual pole switch. 60 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Connecting Switches or Devices to EStop/Invert Input On controllers prior to RevB, Input F is an opto-coupled input and requires the buffer to be powered with a connection between pin 14 and 7, and between 13 and 6, to operate.This power connection in not needed on RevB hardware. +5V Out 14 +5V Out 14 +5V In 7 10kOhm Input F 4 10kOhm 10kOhm Input F 4 +5V In 7 Internal Buffer GND In 6 Internal Buffer 10kOhm GND In 6 GND Out 5 GND Out 5 FIGURE 29. Switch wiring to Input F The status of Input F can be read in the RS232 mode with the ?i command string. The controller will respond with three sets of 2 digit numbers. The status of Input F is contained in the second set of numbers and may be 00 to indicate an Off state, or 01 to indicate an On state. Connecting Switches or Devices to EStop/Invert Input This input is used to connect various switches or devices depending on the selected controller configuration. The factory default for this input is “No Action”. This input can also be configured to be used with an optional “inverted” sensor switch. When activated, this will cause the controls to be inverted so that the robot may be driven upside-down. When neither Emergency Stop or Inverted modes are selected, this input becomes a general purpose input like the other two described above. This input is a high impedance input with a pull-up resistor built into the controller. Therefore it will report an On state (no emergency stop, or not inverted) if unconnected. A simple switch as shown on Figure 30 is necessary to activate it. Note that to trigger an Emergency Stop, or to detect robot inversion this input must be pulled to ground. Figure 30 show how to wire the switch to this input. AX3500 Motor Controller User’s Manual 61 Connecting Sensors and Actuators to Input/Outputs +5V 14 AX2500 Internal Buffer and Resistor 10kOhm Input EStop/Inv 15 Ground 5 FIGURE 30. Emergency Stop / Invert switch wiring The status of the EStop/Inv can be read at all times in the RS232 mode with the ?i command string. The controller will respond with three sets of 2 digit numbers. The status of the ES/Inv Input is contained in the last set of numbers and may be 00 to indicate an Off state, or 01 to indicate an On state. Analog Inputs The controller has (2 on pre-RevB hardware) 4 Analog Inputs that can be used to connect position, speed, temperature, voltage or most other types of analog sensors. These inputs can be read at any time using the ?p query for Analog inputs 1 and 2 and the ?r query for Inputs 3 and 4. The following section show the various uses for these inputs. Connecting Position Potentiometers to Analog Inputs When configured in the Position mode, the controller’s analog inputs are used to obtain position information from a potentiometer coupled to the motor axle. This feature is useful in order to create very powerful servos as proposed in the figure below: Position Feedback Potentiometer Gear box FIGURE 31. Motor and potentiometer assembly for position servo operation 62 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Connecting Tachometer to Analog Inputs Connecting the potentiometer to the controller is as simple as shown in the diagram on Figure 32. +5V 14 Ana 1: Ana 2: Ana 3: Ana 4: 11 10 12 8 Internal Resistors and Converter 47kOhm A/D 10kOhm 10kOhm 47kOhm Ground 5 FIGURE 32. Potentiometer wiring in Position mode The potentiometer must be attached to the motor frame so that its body does not move in relationship with the motor. The potentiometer axle must be firmly connected to the gear box output shaft. The gearbox must be as tight as possible so that rotation of the motor translates into direct changes to the potentiometers, without slack, at the gearbox’s output. TABLE 11. Analog Position Sensor connection depending on operating mode Operating Mode RC or RS232 - Dual Channel Analog - Dual Channel RC or RS232 - Single Channel RC or RS232 - Dual Channel Ana 1 (p11) Ana2 (p10) Ana 3 (p12) Ana 4 (p8) Position 1 Position 2 Unused Unused Command 1 Command 2 Position 1 Position 2 Position Unused Unused Unused Command Unused Position Unused See “Closed Loop Position Mode” on page 89 for complete details on Position Mode wiring and operation. Important Warning Beware that the wrong + and - polarity on the potentiometer will cause the motor to turn in the wrong direction and not stop. The best method to figure out the right potentiometer is try one way and change the polarity if incorrect. Note that while you are doing these tests, the potentiometer must be loosely attached to the motor’s axle so that it will not be forced and broken by the motor’s uncontrolled rotation in case it was wired wrong. Connecting Tachometer to Analog Inputs When operating in closed loop speed mode, tachometers must be connected to the controller to report the measured motor speed. The tachometer can be a good quality brushed DC motor used as a generator. The tachometer shaft must be directly tied to that of the motor with the least possible slack. Since the controller only accepts a 0 to 5V positive voltage as its input, the circuit shown in Figure 33 must be used between the controller and the tachometer: a 10kOhm potentiom- AX3500 Motor Controller User’s Manual 63 Connecting Sensors and Actuators to Input/Outputs eter is used to scale the tachometer output voltage to -2.5V (max reverse speed) and +2.5V (max forward speed). The two 1kOhm resistors form a voltage divider that sets the idle voltage at mid-point (2.5V), which is interpreted as the zero position by the controller. The voltage divider resistors should be of 1% tolerance or better. To precisely adjust the 2.5V midpoint value it is recommended to add a 100 ohm trimmer on the voltage divider. With this circuitry, the controller will see 2.5V at its input when the tachometer is stopped, 0V when running in full reverse, and +5V in full forward. +5V 14 1kOhm Max Speed Adjust 10kOhm pot Zero Adjust 100 Ohm pot Tach Ana 1: Ana 2: Ana 3: Ana 4: 11 10 12 8 Internal Resistors and Converter 47kOhm A/D 10kOhm 47kOhm 1kOhm Ground 5 FIGURE 33. Tachometer wiring diagram The tachometers can generate voltages in excess of 2.5 volts at full speed. It is important, therefore, to set the potentiometer to the minimum value (cursor all the way down per this drawing) during the first installation. Since in closed loop control the measured speed is the basis for the controller’s power output (i.e. deliver more power if slower than desired speed, less if higher), an adjustment and calibration phase is necessary. This procedure is described in “Closed Loop Speed Mode” on page 101. TABLE 12. Analog Speed Sensor connection depending on operating mode Operating Mode RC or RS232 - Dual Channel Analog - Dual Channel RC or RS232 - Single Channel RC or RS232 - Dual Channel Ana 1 (p11) Ana2 (p10) Ana 3 (p12) Ana 4 (p8) Speed 1 Speed 2 Unused Unused Command 1 Command 2 Speed 1 Speed 2 Speed Unused Unused Unused Command Unused Speed Unused Important Warning The tachometer’s polarity must be such that a positive voltage is generated to the controller’s input when the motor is rotating in the forward direction. If the polarity is inverted, this will cause the motor to run away to the maximum speed as soon as the controller is powered with no way of stopping it other than pressing the emergency stop button or disconnecting the power. 64 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Connecting External Thermistor to Analog Inputs Connecting External Thermistor to Analog Inputs Using external thermistors, the AX3500 can be made to supervise the motor’s temperature and adjust the power output in case of overheating. Connecting thermistors is done according to the diagram show in Figure 34. The AX3500 is calibrated using a 10kOhm Negative Coefficient Thermistor (NTC) with the temperature/resistance characteristics shown in the table below. TABLE 13. Recommended NTC characteristics Temp (oC) -25 0 25 50 75 100 Resistance (kOhm) 86.39 27.28 10.00 4.16 1.92 0.93 +5V 14 10kOhm Ana 1: 11 Ana 2: 10 Ana 3: 12 Ana 4: 8 Internal Resistors and Converter 47kOhm A/D 10kOhm 10kOhm NTC Thermistor 47kOhm Ground 5 FIGURE 34. NTC Thermistor wiring diagram Thermistors are non-linear devices. Using the circuit described on Figure 34, the controller will read the following values (represented in signed binary) according to the temperature. AX3500 Motor Controller User’s Manual 65 Connecting Sensors and Actuators to Input/Outputs 100 Analog Input Reading 50 0 -50 -100 11 0 10 0 90 80 70 60 50 40 30 20 10 0 -1 0 -2 0 -150 Temperature in Degrees C FIGURE 35. Signed binary reading by controller vs. NTC temperature To read the temperature, use the ?p command to have the controller return the A/D converter’s value. The value is a signed 8-bit hexadecimal value. Use the chart data to convert the raw reading into a temperature value. Using the Analog Inputs to Monitor External Voltages The analog inputs may also be used to monitor the battery level or any other DC voltage. In this mode, the controller does not use the voltage information but merely makes it available to the host microcomputer via the RS232 port. The recommended schematic is shown in Figure 36. To Battery + Terminal +5V 14 47kOhm Ana 1: 11 Ana 2: 10 Ana 3: 12 Ana 4: 8 Internal Resistors and Converter 47kOhm A/D 10kOhm 4.7kOhm 47kOhm Ground 5 FIGURE 36. Battery voltage monitoring circuit Using these resistor values, it is possible to measure a voltage ranging from -5V to +60V with a 0.25V resolution. The formula for converting the A/D reading into a voltage value is as follows. 66 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Connecting User Devices to Analog Inputs Measured volts = ((controller reading + 128) * 0.255) -5 Note: The A/D converter’s reading is returned by the ?p command and is a signed 8-bit hexadecimal value. You must add 128 to bring its range from -127/+127 to 0/255. Connecting User Devices to Analog Inputs The two analog inputs can be used for any other purpose. The equivalent circuit for each input is shown in Figure 37. The converter operates with an 8-bit resolution, reporting a value of 0 at 0V and 255 at +5V. Care should be taken that the input voltage is always positive and does not exceed 5V. The converter’s intrinsic diodes will clip any negative voltage or voltage above 5V, thus providing limited protection. The value of the analog inputs can be read through the controller’s RS232 port. +5V 14 Ana 1: Ana 2: Ana 3: Ana 4: 11 10 12 8 47kOhm A/D 10kOhm 47kOhm Ground 5 FIGURE 37. AX3500 Analog Input equivalent circuit Internal Voltage Monitoring Sensors The AX3500 incorporates voltage sensors that monitor the Main Battery voltage and the Internal 12V supply. This information is used by the controller to protect it against overvoltage and undervoltage conditions (see “Overvoltage Protection” on page 38 and “Undervoltage Protection” on page 38). These voltages can also be read from the RS232 serial port using the ?e query. The returned value are numbers ranging from 0 to 255. To convert these numbers into a Voltage figure, the following formulas must be used: Measured Main Battery Volts = 55 * Read Value / 256 Measured Internal Volts = 28.5 * Read Value / 256 Internal Heatsink Temperature Sensors The AX3500 includes temperature sensors near the transistor of each of the two output stages. AX3500 Motor Controller User’s Manual 67 Connecting Sensors and Actuators to Input/Outputs These sensors are used to automatically reduce the maximum Amps that the controller can deliver as it overheats. However, the temperature can be read using the RS232 port using the ?m query, or during data logging (see “Analog and R/C Modes Data Logging String Format” on page 170) The analog value that is reported will range from 0 (warmest) to 255 (coldest). Because of the non-linear characteristics of NTC thermistors, the conversion from measured value to temperature must be done using the correction curve below. It should be noted that the temperature is measured inside the controller and that it may be temporarily be different than the temperature measured outside the case. 300 Reported Analog Value 250 200 150 100 50 15 0 14 0 13 0 12 0 11 0 90 10 0 80 70 60 50 40 30 20 0 10 -1 0 -2 0 -3 0 -4 0 0 Temperature in Degrees C FIGURE 38. Analog reading by controller vs. internal heat sink temperature Temperature Conversion C Source Code The code below can be used to convert the analog reading into temperature. It is provided for reference only. Interpolation table is for the internal thermistors. int ValToHSTemp(int AnaValue) { // Interpolation table. Analog readings at -40 to 150 oC, in 5o intervals int TempTable[39] ={248, 246, 243, 240, 235, 230, 224, 217, 208, 199, 188, 177, 165, 153, 140, 128, 116, 104,93, 83, 74, 65, 58, 51, 45, 40, 35, 31, 27, 24, 21, 19, 17, 15, 13, 12, 11, 9, 8}; int LoTemp, HiTemp, lobound, hibound, temp, i; i = 38; while (TempTable[i] < AnaValue && i > 0) i--; if (i < 0) i = 0; if (i == 38) return 150; 68 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Internal Heatsink Temperature Sensors else { LoTemp = i * 5 - 40; HiTemp = LoTemp + 5; lobound = TempTable[i]; hibound = TempTable[i+1]; temp = LoTemp + (5 * ((AnaValue - lobound)*100/ (hibound - lobound)))/100; return temp; } } AX3500 Motor Controller User’s Manual 69 Connecting Sensors and Actuators to Input/Outputs 70 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 RC Pulse Output Overview RC Pulses Output SECTION 6 This section describes the Pulse outputs on the AX3500. RC Pulse Output Overview The AX3500 is equipped with an RC pulse output port for driving RC servos or additional Roboteq controllers. Up to 8 devices can be controlled in this way by a single AX3500, as shown in Figure 39. Slave 1 Master tes eR teS Slave 2 Servo Power Supply Servo FIGURE 39. Example of AX3500 driving multiple slave controllers and servos AX3500 Motor Controller User’s Manual 71 RC Pulses Output Connector Location and Pinout Figure 40 below shows the location of the RC Output connector and its pin assignment. Three pins are provided for each output, matching the pinout of standard Futaba RC connectors. Pulse Out 5V Out GND 8 7 6 5 4 3 2 1 FIGURE 40. RC Output Connector Connecting Servos and Slave Controllers Special care must be used when connecting the AX3500 to servos or to slave controller.The 5V power output has very limited current driver capability of approximately 100mA for all 8 channels and can therefore be used to drive directly, as shown in Figure 41, only the most efficient servos with very little load. In most applications, however, a separate power supply must be provided to power the servos., as shown in Figure 42. To RC Output of Master AX3500 FIGURE 41. AX3500 to Low-Power Servo Connection External 5-6V Supply To RC Output of Master AX3500 FIGURE 42. AX3500 to Standard or Heavy Duty Servo Connection 72 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Pulse Timing Information Note: When attempting to supply power from the AX3500 to a standard or heavy duty servo, the current will surge every time the servo attempts to move will cause the controller to reset. When connecting the AX3500 to other Roboteq slave controllers, care must be taken that the 5V outputs that is present on the Master’s RC Output connector, and on the 5V output of the Slave connectors (pin 14), are not physically connected to one another. Otherwise, when a controller is powered On, it will be supplying 5V, and thus be powering other controllers. This will stress and possibly damage the DC/DC converter of the powering controller. The figures below show two alternate ways to make this connection depending whether Optical Isolation is desired or not. To RC Outputs of Master AX3500 8 1 Input connector of Slave Controller 9 15 FIGURE 43. AX3500 to Slave Controller Connection without Optical Isolation To RC Outputs of Master AX3500 8 1 9 Input connector of Slave Controller 15 FIGURE 44. AX3500 to Slave Controller Connection with Optical Isolation A more detailed description of the AX3500 RC Input and Optical Isolation circuit can be found at “R/C Input Circuit Description” on page 115. Pulse Timing Information The RC Output port sends 8 pulses of programmable width ranging from 1ms to 2ms at minimum and maximum position, respectively. Figure 46 shows the pulse’s waveform at various command values. An RC Servo will be centered and a Slave Controller will be Off when the pulse it at half width (1.5ms). A pulse is output on each channel sequentially as show in Figure 47. As a result, the pulse train repeat every 8ms (if all pulses are 1ms wide) to 16ms (if all pulses are 2ms wide) AX3500 Motor Controller User’s Manual 73 RC Pulses Output Command Value Pulse Width 0 127 255 1.00ms 1.50ms 2.00ms FIGURE 46. RC Pulse Output waveform and timing Ch 1 Ch 2 Ch 3 Ch 4 Ch 5 Ch 6 Ch 7 Ch 8 FIGURE 47. Pulse is output sequentially on each channel Important Warning The *mm command is also used to access the Encoder module’s registers. Do not alter any random locations as this may cause program execution failure inside the encoder module. See “Register Description” on page 164 for a description of the other registers accessible with this command. RC Channel Testing Using the PC Utility A simple test and diagnostic function is provided in the Roborun PC utility. Basic instructions on how to install and run the PC utility can be found in “Using the Roborun Configuration Utility” on page 181. Once the utility is up and running and the controller found and identified, click on the “RC Out” tab to bring up the test screen show in Figure 48 below. 74 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 RC Channel Testing Using the PC Utility FIGURE 48. Encoder setup and test screen on Roborun From this screen, moving the cursor on any of the 8 sliders will cause the PC to send RC positioning command to the controller via the RS232 port to its respective output. AX3500 Motor Controller User’s Manual 75 RC Pulses Output 76 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Optical Incremental Encoders Overview SECTION 7 Connecting and Using the Encoder Function This section describes the Encoder input module that is built into the AX3500. Optical Incremental Encoders Overview Optical incremental encoders are a means for capturing speed and travelled distance on a motor. Unlike absolute encoders which give out a multi-bit number (depending on the resolution), incremental encoders output pulses as they rotate. Counting the pulses tells the application how many revolutions, or fractions of, the motor has turned. Rotation velocity can be determined from the time interval between pulses or by the number of pulses within a given time period. Because they are digital devices, incremental encoders will measure distance and speed with perfect accuracy. Since motors can move in forward and reverse directions, it is necessary to differentiate the manner that pulses are counted so that they can increment or decrement a position counter in the application. Quadrature encoders have dual channels, A and B, which are electrically phased 90° apart. Thus, direction of rotation can be determined by monitoring the phase relationship between the two channels. In addition, with a dual-channel encoder, a four-time multiplication of resolution can be achieved by counting the rising and falling edges of each channel (A and B). For example, an encoder that produces 250 Pulses per Revolution (PPR) can generate 1,000 Counts per Revolution (CPR) after quadrature. AX3500 Motor Controller User’s Manual 77 Connecting and Using the Encoder Function A Channel 1 Pulse = 4 Transitions = 4 Counts B Channel Quadrature Signal Count Down Count Up FIGURE 49. Quadrature encoder output waveform The figure below shows the typical construction of a quadrature encoder. As the disk rotates in front of the stationary mask, it shutters light from the LED. The light that passes through the mask is received by the photo detectors. Two photo detectors are placed side by side at so that the light making it through the mask hits one detector after the other to produces the 90o phased pulses. LED light source Rotating encoder disk Stationary mask Photodetector FIGURE 50. Typical quadrature encoder construction Unlike absolute encoders, incremental encoders have no retention of absolute position upon power loss. When used in positioning applications, the controller must move the motor until a limit switch is reached. This position is then used as the zero reference for all subsequent moves. Recommended Encoder Types The module may be used with most incremental encoder module as long as they include the following features: • • • Two quadrature outputs (Ch A, Ch B), single ended signal 2.5V minimum swing between 0 Level and 1 Level on quadrature output 5VDC operation. 100mA or less current consumption per encoder More sophisticated incremental encoders with differential outputs, index, and other features may be used, however these additional capabilities will be ignored. The choice of encoder resolution is very wide and is constrained by the module’s maximum pulse count at the high end and measurement resolution for speed at the low end. 78 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Connecting the Encoder Specifically, the encoder module can process 250,000 counts per seconds. As discussed in the previous section, a count is generated for each transition on the Channel A and Channel B. Therefore the module will work with encoders outputting up to 62,500 pulses per second. Commercial encoders are rated by their numbers of “Pulses per Revolution” (also sometimes referred as “Cycles per Revolution). Carefully read the manufacturer’s datasheet to understand whether this number represents the number of pulses that are output by each channel during the course of a 360o revolution rather than the total number of transitions on both channels during a 360o revolution. The second number is 4 times larger than the first one. The formula below gives the pulse frequency at a given RPM and encoder resolution in Pulses per Revolution. Pulse Frequency in Hz = RPM / 60 * PPR * 4 Example: a motor spinning at 10,000 RPM max, with an encoder with 200 Pulses per Revolution would generate: 10,000 / 60 * 200 * 4 = 133.3 kHz which is well within the 250kHz maximum supported by the encoder module. An encoder with a 200 Pulses per Revolutions is a good choice for most applications. A higher resolution will cause the counter to count faster than necessary and possibly reach the encoder module’s maximum frequency limit. An encoder with a much lower resolution will cause speed to be measured with less precision. Connecting the Encoder The Encoder module uses a widely available 8-pin RJ45 connector identical to those found on all Ethernet devices. The connector provides 5V power to the encoders and has inputs for the two quadrature signals from each encoder. Using multi-level signaling, it is also possible to share the quadrature inputs with limit switches. The figure and table below describe the connector and its pin assignment. 1 8 8 1 FIGURE 51. Encoder connector AX3500 Motor Controller User’s Manual 79 Connecting and Using the Encoder Function TABLE 14. Cable Color Pin Name (when using standard network cable) 1 Encoder 2 - Channel B. Optional Limit Switch 4 Orange/White 2 Encoder 2 - Channel A. Optional Limit Switch 3 Orange 3 Ground (same as pin 7) Green/White 4 5V Out (same as pin 8) Blue 5 Encoder 1 - Channel B. Optional Limit Switch 2 Blue/White 6 Encoder 1 - Channel A. Optional Limit Switch 1 Green 7 Ground (same as pin 3) Brown/White 8 5V Out (same as pin 4) Brown Cable Length and Noise Considerations Cable should not exceed one 3’ (one meter) to avoid electrical noise to be captured by the wiring. A ferrite core filter must be used for length beyond 2’ (60 cm). For longer cable length use an oscilloscope to verify signal integrity on each of the pulse channels and on the power supply. Ferrite Core Encoder FIGURE 52. Use ferrite core on cable length beyond 2’ or 60cm Important Warning Excessive cable length will cause electrical noise to be captured by the controller and cause erratic functioning that may lead to failure. In such situation, stop operation immediately. Motor - Encoder Polarity Matching When using the Encoder module for closed loop speed control, it is imperative that when the motor is turning in the forward direction, the counter increments its value and a positive speed value is measured. 80 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Voltage Levels, Thresholds and Limit Switches Using the PC utility, it is possible to exercise the motors and view the encoder readings. See “Encoder Testing and Setting Using the PC Utility” on page 87. If the Encoder counts backwards when the motor moves forward, correct this by either: 1- Swapping Channel A and Channel B on the encoder connector. This will cause the encoder module to reverse the count direction, or 2- Swapping the leads on the motor. This will cause the motor to rotate in the opposite direction. Voltage Levels, Thresholds and Limit Switches The encoder module’s input uses a comparator to reshape the encoder’s output signal. If the signal is below a fixed 2.5V threshold level, then it is considered to be 0. If above, it is considered to be 1. The output of this comparator feeds the quadrature detector and counters. Another set of comparators on the same input signals detects pulses that are above and below a fixed 0.5V threshold. Using a special circuitry for creating multi-level signaling (see next section below), the output of these comparators serves to detect the status of optional limit switches. Figure 54 and Figure 53 show the conditioned signals as seen by the encoder. In Figure 54, the encoders are connected directly to the Channel A and B inputs. In this case, it will cause a Switch Detection condition because the encoder’s 0 level is below 0.5V, which should be ignored. 2.5V Signal on Channel A or B 0.5V Quadrature Signal Switch Detect Signal (Not meaningful) FIGURE 53. Signals seen by encoder using direct connection and no limit switches In Figure 53, the encoder and switches are wired to the encoder module using a set of resistors designed to create a multi-level signal combining both pieces of information. Details on the necessary wiring is provided in the next section. Since the encoder output signal is “shifted-up” by a few volts, it always stays above the Limit Switch comparator’s threshold, and no Switch Detection condition is generated. However, since the limit switches connect to ground when On, the level will dip below the 0.5V and generate a Switch Detection condition. AX3500 Motor Controller User’s Manual 81 Connecting and Using the Encoder Function 2.5V Signal on Channel A or B 0.5V Quadrature Signal Switch Detect Signal FIGURE 54. Signals seen by encoder using multi-levels and limit switches Important Warning When a limit switch is activated, the encoder signal that is shared with the switch is no longer visible by the encoder module, and pulse counting and speed measurement stops. Wiring Optional Limit Switches If limit switches are needed by the application, additional circuitry is required in order to create a multi-level signal that shares the encoder and the switch information. The figure below shows the electrical diagram of the required wiring. 5V Out 4.7kOhm 4.7kOhm 1kOhm 5V Ch A In Ch A Encoder GND Encoder Module Ch B Ch B In 1kOhm SW1 SW2 GND FIGURE 55. Signals seen by encoder using multi-levels and limit switches Using this circuit when the switch is open, a 0V (low-level) output from the encoder goes through a 1k and 4.7k voltage divider, thus creating a voltage that will never be below 0.8V at the encoder module’s input. 82 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Wiring Limit Switches Without Encoders When the switch is activated, the module’s input is pulled to 0V. It is recommended that a voltmeter and/or oscilloscope be used to verify that the right voltage levels are created as the encoder rotates and the switches activate. You may also use the Encoder setup/test function in the Roborun utility (see “Encoder Testing and Setting Using the PC Utility” on page 87). If the wiring is correct, the counters should increment/decrement as the motor rotate. The switch indicators should be always off unless the switches are actually activated. Wiring Limit Switches Without Encoders If no encoder is used, the Encoder Module’s inputs can be used to wire limit switches directly with solely a pull-up resistor as shown in the diagram below. 5V Out 4.7kOhm 4.7kOhm 4.7kOhm 4.7kOhm Ch B In SW1 SW2 SW3 8-4 5 Ch A In 6 Ch B In 1 Ch A In 2 Encoder Input SW4 GND 7-3 FIGURE 56. Signals seen by encoder using multi-levels and limit switches Effect of Limit Switches Each pair of limit switches will stop the motion of a given motor in a given direction. This will have the effect of stopping the motor when a limit is reached while allowing motion in the other direction, away for that limit. TABLE 15. Effects of Limit Switches 1 and 2 on Motor 1 SW1 SW2 Motor 1 Fwd Motor 1 Rev OFF OFF Allowed Allowed ON OFF Stopped Allowed OFF ON Allowed Stopped ON ON Stopped Stopped AX3500 Motor Controller User’s Manual 83 Connecting and Using the Encoder Function TABLE 16. Effects of Limit Switches 3 and 4 on Motor 2 SW3 SW4 Motor 2 Fwd Motor 2 Rev OFF OFF Allowed Allowed ON OFF Stopped Allowed OFF ON Allowed Stopped ON ON Stopped Stopped In Single Channel Mode, limit switches 3 and 4 are used. This is to allow direct connection of an encoder on the inputs for channel 1 and direct connection of switches on the inputs for channel 2 TABLE 17. Effects of Limit Switches 3 and 4 on Motor 2 in Single Channel Configuration SW3 SW4 Motor Fwd Motor Rev OFF OFF Allowed Allowed ON OFF Stopped Allowed OFF ON Allowed Stopped ON ON Stopped Stopped Using the Encoder Module to Measure Distance As the encoders rotate, their quadrature outputs is automatically processed and increments/decrements two 32-bit counter inside the Encoder Module. There is one 32-bit counter for each of the encoders. The counter values are stored as a signed binary numbers, ranging from -2,147,836,648 to +2,147,836,647 (Hexadecimal format of value 80000000 to 7FFFFFFF respectively. When the maximum or minimum counter values are reached, the counters automatically roll over to zero. The counters can be read and set using the commands described in “The AX3500 contains its own Microcontroller and firmware in Flash. When present, it responds to a large set of dedicated commands and queries via the controller’s serial port. See “RS232 Encoder Command Set” on page 161.” on page 87. Using the Encoder to Measure Speed The encoder module will automatically compute rotation speed for each encoder. The resulting measured speed is a value ranging from 0 to + 127 and 0 to -127, where 127 represent a relative ratio of a maximum speed value chosen by the user. For example, if the encoder module is configured so that the highest measured speed value is 3,000 RPM, then a reading of 63 (127/2) would be 1,500 RPM. 84 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Using the Encoder to Track Position The relationship between the measured speed and the actual speed is a factor of two variable parameters: a Time Based period value stored inside the Encoder module and the Encoder’s number of Pulses per Revolution. Note: the Encoder’s number of Pulses per Revolution is not stored in the controller. The Time Base is a number of 256us time intervals between two counter reads. A simple procedure is included in the Roborun PC utility to easily determine and set these parameters. For information, the exact formula is shown below: Measured Speed Value = RPM * PPR * 4 * (Time Base+1) * 256 / (60 * 1000000) or Measured Speed Value = RPM * PPR * (Time Base + 1) / 58593.75 Example: a motor spinning at 1,000 RPM, with an encoder with 200 Pulses per Revolution, and a Time Base set at 4 will produce the following measurement: 1000 *200 * (4 + 1) / 58593.75 = 17 The same formula modified to show the actual RPM at a given Measure Speed Value is as follows: RPM = Measured Speed Value * 60 * 1000000 / (PPR * 4 * 256 * (Time Base+1)) or RPM = Measured Speed Value * 58593.75 /((Time Base + 1) * PPR) In our example, a measured speed value of 127 corresponds to the following measurable max actual RPM values. RPM at Max Measurable Speed Value = 127 * 58593.75 / ((4 + 1) * 200) = 7441 RPM A measured speed value of 1 corresponds to the following measurable min. actual RPM values. RPM at Min. Measurable Speed Value = 1 * 58593.75 / ((4 + 1) * 200) = 58.6 RPM The Roborun Utility automatically makes the above calculations when setting up the encoder. Important Notice The time base value should not exceed 63 so that a new speed value can be measured at every 16ms loop. The roborun utility automatically limits the time base value that can be entered. Using the Encoder to Track Position The encoder module can be used to report the distance between the actual motor position and a desired destination. The resulting measured “distance” can then be used by the controller in the position mode to move the motor in the right direction until the destination is AX3500 Motor Controller User’s Manual 85 Connecting and Using the Encoder Function reached. This movement is controlled by the PID position algorithm inside the controller and is therefore best suited at tracking position. Since the controller uses a signed 8-bit value (-127 to +127) for the distance measurement in the Position Mode, a special algorithm is used to convert the real distance which can be much higher than -127 to +127, as both the counter and destination registers are 32-bit wide. The actual formula is as follows: Distance = (Destination - Counter value) / Divider Where: divider is a configurable parameter of value 1, 2, 4, 8, 16, 32, 64 or 127 If computed distance is less than -127, then reported distance is -127 If computed distance is larger than +127, then reported distance is +127 Destination= 50,050 Counter= 50,000 distance 50 25 12 6 3 1 0 0 at divider 1 2 4 8 16 32 64 128 FIGURE 57. Small distance computation example Destination= 50,000 Counter= 45,000 distance 127 127 127 127 127 127 78 39 at divider 1 2 4 8 16 32 64 128 FIGURE 58. Large distance computation example Important Notice Encoders do not report an absolute position value but a count that is relative to the point where the motor shaft was at power up. It is typically necessary to have the motors moved to a “home” position and reset the counters at that reference point. 86 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 RS232 Communication with the Encoder Module RS232 Communication with the Encoder Module The AX3500 contains its own Microcontroller and firmware in Flash. When present, it responds to a large set of dedicated commands and queries via the controller’s serial port. See “RS232 Encoder Command Set” on page 159. Encoder Testing and Setting Using the PC Utility Extensive diagnostic, calibration, setting and testing support is provided in the Roborun PC utility. Basic instructions on how to install and run the PC utility can be found in “Encoder Setting and Testing” on page 188. AX3500 Motor Controller User’s Manual 87 Connecting and Using the Encoder Function 88 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Mode Description Closed Loop Position Mode SECTION 8 This section describes the AX3500 Position mode, how to wire the motor and position sensor assembly and how to tune and operate the controller in this mode. Mode Description In this mode, the axle of a geared-down motor is coupled to a position sensor that is used to compare the angular position of the axle versus a desired position. The controller will move the motor so that it reaches this position. This unique feature makes it possible to build ultra-high torque “jumbo servos” that can be used to drive steering columns, robotic arms, life-size models and other heavy loads. The AX3500 incorporates a full-featured Proportional, Integral, Differential (PID) control algorithm for quick and stable positioning. Selecting the Position Mode The position mode is selected by changing the Motor Control parameter in the controller to either • • • A Open Loop Speed, B Position A Closed Loop Speed, B Position A and B Position Note that in the first two modes, only the second motor will operate in the Position mode. Changing the parameter is best done using the Roborun Utility. See “Loading, Changing Controller Parameters” on page 185. For safety reasons and to prevent this mode from being accidentally selected, Position modes CANNOT be selected by configuring the controller using the built-in switches and display. AX3500 Motor Controller User’s Manual 89 Closed Loop Position Mode Position Sensor Selection The AX3500 may be used with the following kind of sensors: • • • Potentiometers Hall effect angular sensors Optical Encoders The first two are used to generate an analog voltage ranging from 0V to 5V depending on their position. They will report an absolute position information at all times. Optical encoders report incremental changes from a reference which is their initial position when the controller is powered up or reset. Using Optical Encoders in this mode is possible but requires special handling that is described in Figure , “Using the Encoder to Track Position,” on page 85. Sensor Mounting Proper mounting of the sensor is critical for an effective and accurate position mode operation. Figure 59 shows a typical motor, gear box, and sensor assembly. Position Feedback Position Sensor Gear box FIGURE 59. Typical motor/potentiometer assembly in Position Mode The sensor is composed of two parts: • a body which must be physically attached to a non-moving part of the motor assembly or the robot chassis, and • an axle which must be physically connected to the rotating part of the motor you wish to position. A gear box is necessary to greatly increase the torque of the assembly. It is also necessary to slow down the motion so that the controller has the time to perform the position control algorithm. If the gearing ratio is too high, however, the positioning mode will be very sluggish. A good ratio should be such that the output shaft rotates at 1 to 10 rotations per second (60 to 600 RPM) when the motor is at full speed. 90 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Feedback Potentiometer wiring The mechanical coupling between the motor and the sensor must be as tight as possible. If the gear box is loose, the positioning will not be accurate and will be unstable, potentially causing the motor to oscillate. Some sensor, such as potentiometers, have a limited rotation range of typically 270 degrees (3/4 of a turn), which will in turn limit the mechanical motion of the motor/potentiometer assembly. Consider using a multi-turn potentiometer as long as it is mounted in a manner that will allow it to turn throughout much of its range, when the mechanical assembly travels from the minimum to maximum position. Important Notice: Potentiometers are mechanical devices subject to wear. Use better quality potentiometers and make sure that they are protected from the elements. Consider using a solid state hall position sensor in the most critical applications. Optical encoders may also be used when operated as discussed in “Using the Encoder to Measure Speed” on page 84. Feedback Potentiometer wiring When using a potentiometer, it must be wired so that it creates a voltage that is proportional to its angular position: 0V at one extreme, +5V at the other. A 10K potentiometer value is recommended for this use. Analog Feedback is normally connected to the Analog Inputs 1 and 2, except when the controller is configured in Analog Mode. In Analog mode, Analog Inputs 1 and 2 are already used to supply the command. Therefore Analog inputs 3 and 4 are used for feedback Feedback Potentiometer wiring in RC or RS232 Mode In RC or RS232 mode, feedback is connected to Analog Inputs 1 and 2. Connecting the potentiometer to the controller is as simple as shown in the diagram on below. Note that this wiring must not be used if the controller is configured in Analog mode but is switched in RS232 after power up using the method discussed in “Entering RS232 from R/ C or Analog mode” on page 140. Instead, used the wiring for Analog mode discussed in the next section. AX3500 Motor Controller User’s Manual 91 Closed Loop Position Mode 14 2k - 10k +5V 2k - 10k Feedback 1 Feedback 2 5 Ground 11 Ana1 10 Ana2 12 Ana3* 8 Ana4* FIGURE 60. Pot wiring for RS232 or RC Command and Analog Feedback Feedback Potentiometer wiring in Analog Mode When the controller is configured in Analog mode, the analog inputs 1 and 2 are used for commands while the analog inputs 3 and 4 are used for feedback. Analog inputs 3 and 4 have different characteristics than inputs 1 and 2, and so require a lower resistance potentiometer in order to guarantee accuracy Note that the analog inputs 3 and 4 are only available on the AX3500 with PCB revision 3.0 or above. The revision number is marked on the PCB. Roborun will detect the new hardware revision and display Rev B on the screen. 14 2k 2k 2k - 10k +5V 2k - 10k Command 1 Command 2 Feedback 1 Feedback 2 5 Ground 11 Ana1 10 Ana2 12 Ana3* 8 Ana4* FIGURE 61. Pot wiring for Analog Command and Analog Feedback Analog inputs 3 and 4 have different characteristics than inputs 1 and 2, and so require a lower resistance potentiometer in order to guarantee accuracy. Important Notice This wiring is also the one to use when the controller is in Analog mode but switched to RS232 after reset using the method discussed in “Entering RS232 from R/C or Analog mode” on page 140 92 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Analog Feedback on Single Channel Controllers Analog Feedback on Single Channel Controllers On Single Channel controllers (SC Version - not to be confused with Dual Channel controllers of which only one channel is used for position control - See “Single Channel Operation” on page 177.), the controller accepts one command and uses one input for feedback. Feedback Wiring in RC or RS232 Mode on Single Channel Controllers When the controller is configured for RS232 or RC command, the wiring of the feedback must be done as shown in the figure below. 14 2k - 10k Feedback +5V 5 Ground 11 Ana1 10 Ana2 12 Ana3* 8 Ana4* FIGURE 62. Pot wiring on Single Channel controllers (SCversion) and Analog Command Feedback Wiring in Analog Mode on Single Channel Controllers When the controller is configured in Analog mode, the analog input 1 is used for commands while the analog input 4 is used for feedback. Note that the analog inputs 3 and 4 are only available on the AX3500 with PCB revision 3.0 or above. The revision number is marked on the PCB. Roborun will detect the new hardware revision and display Rev B on the screen. 14 2k 2k - 10k Command Feedback +5V 5 Ground 11 Ana1 10 Ana2 12 Ana3* 8 Ana4* FIGURE 63. Pot wiring on Single Channel controllers (SC version) and Analog Command Analog inputs 3 and 4 have different characteristics than inputs 1 and 2, and so require a lower resistance potentiometer in order to guarantee accuracy. AX3500 Motor Controller User’s Manual 93 Closed Loop Position Mode Important Notice This wiring is also the one to use when the controller is in Analog mode but switched to RS232 after reset using the method discussed in “Entering RS232 from R/C or Analog mode” on page 140 Using Optical Encoders in Position Mode Optical Encoders require special handling. See Figure 7, “Connecting and Using the Encoder Function,” on page 77 for a detailed discussion. Sensor and Motor Polarity The sensor polarity (i.e. which rotation end produces 0 or 5V) is related to the motor’s polarity (i.e. which direction the motor turns when power is applied to it). In the Position mode, the controller compares the actual position, as measured by the sensor, to the desired position. If the motor is not at that position, the controller will apply power to the motor so that it turns towards that destination until reached. Important Warning: If there is a polarity mismatch, the motor will turn in the wrong direction and the position will never be reached. The motor will turn continuously with no way of stopping it other than cutting the power or hitting the Emergency Stop button. Determining the right polarity is best done experimentally using the Roborun utility (see “Using the Roborun Configuration Utility” on page 181) and following these steps: 1. Disconnect the controller’s Motor Power (Vmot tabs). 2. Configure the controller in Position Mode using the PC utility. 3. Loosen the sensor’s axle from the motor assembly. 4. Launch the Roborun utility and click on the Run tab. Click the “Start” button to begin communication with the controller. The sensor values will be displayed in the Ana1 and Ana2 boxes. 5. Move the sensor manually to the middle position until a value of “0” is measured using Roborun utility 6. Verify that the motor sliders are in the “0” (Stop) position. Since the desired position is 0 and the measured position is 0, the controller will not attempt to move the motors. The Power graph on the PC must be 0. 7. Apply power to the Motor Power input (Vmot tabs). The motor will be stopped. 8. With a hand ready to disconnect the Motor Power cable or ready to press the “Program” and “Set” buttons at the same time (Emergency Stop), SLOWLY move the sensor off the center position and observe the motor’s direction of rotation. 94 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Encoder Error Detection and Protection 9. If the motor turns in the direction in which the sensor was moved, the polarity is correct. The sensor axle may be tighten to the motor assembly. 10. If the motor turns in the direction away from the sensor, then the polarity is reversed. The wire polarity on the motors should be exchanged. If using a potentiometer as sensor, the GND and +5V wires on the potentiometer may be swapped instead. If using an Optical Encoder, ChA and ChB outputs can be swapped. 11. Move the sensor back to the center point to stop the motor. Cut the power if control is lost. 12. If the polarity was wrong, invert it and repeat steps 8 to 11. 13. Tighten the sensor. Important Safety Warning Never apply a command that is lower than the sensor’s minimum output value or higher than the sensor’s maximum output value as the motor would turn forever trying to reach a position it cannot. For example, if the max position of a potentiometer is 4.5V, which is a position value of 114, a destination command of 115 cannot be reached and the motor will not stop. Encoder Error Detection and Protection The AX3500 contains an Encoder detection and protection mechanism that will cause the controller to halt if no motion is detected on either Encoder while a power level of 25% or higher is applied to the motor. If such an error occurs, the controller will halt permanently until its power is cycled or it is reset. An Encoder error is one of the conditions that is signaled by the LED rapidly flashing an “8” character (see “Permanent Faults” on page 110). Adding Safety Limit Switches The Position mode depends on the position sensor providing accurate position information. If the potentiometer is damaged or one of its wire is cut, the motors may spin continuously in an attempt to reach a fictitious position. In many applications, this may lead to serious mechanical damage. To limit the risk of such breakage, it is recommended to add limit switches that will cause the motors to stop if unsafe positions have been reached independent of the potentiometer reading. If the controller is equipped with and Encoder module, the simplest solution is to implement limit switches as shown in “Wiring Optional Limit Switches” on page 82. This wiring can be used whether or not Encoders are used for feedback. If no Encoder module is present, an alternate method is shown in Figure 64. This circuit uses Normally Closed limit switches in series on each of the motor terminals. As the motor reaches one of the switches, the lever is pressed, cutting the power to the motor. The diode in parallel with the switch allows the current to flow in the reverse position so that the motor may be restarted and moved away from that limit. AX3500 Motor Controller User’s Manual 95 Closed Loop Position Mode The diode polarity depends on the particular wiring and motor orientation used in the application. If the diode is mounted backwards, the motor will not stop once the limit switch lever is pressed. If this is the case, reverse the diode polarity. The diodes may be eliminated, but then it will not be possible for the controller to move the motor once either of the limit switches has been triggered. The main benefit of this technique is its total independence on the controller’s electronics and its ability to work in practically all circumstances. Its main limitation is that the switch and diode must be capable of handling the current that flows through the motor. Note that the current will flow though the diode only for the short time needed for the motor to move away from the limit switches. SW1 SW2 Motor Controller FIGURE 64. Safety limit switches interrupting power to motors Another method uses the AX3500’s Emergency Stop input to shut down the controller if any of the limit switches is tripped. Figure 65 shows the wiring diagram used in this case. Each of the limit switches is a Normally Open switch. Two of these switches are typically required for each motor. Additional switches may be added as needed for the second motor and/or for a manual Emergency Stop. Since very low current flows through the switches, these can be small, low cost switches. The principal restriction of this technique is that it depends on the controller to be fully functioning, and that once a switch is activated, the controller will remain inactive until the switch is released. In most situations, this will require manual intervention. Another limitation is that both channels will be disabled even if only one channel caused the fault. 96 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Using Current Limiting as Protection Manual Emergency Stop Switch SW1 SW2 Motor Ground Controller Emergency Stop Input FIGURE 65. Safety limit using AX3500’s Emergency Stop input Important Warning Limit switches must be used when operating the controller in Position Mode. This will significantly reduce the risk of mechanical damage and/or injury in case of damage to the position sensor or sensor wiring. Using Current Limiting as Protection It is a good idea to set the controller’s current limit to a low value in order to avoid high current draws and consequential damage in case the motor does not stop where expected. Use a value that is no more than 2 times the motor’s draw under normal load conditions. Control Loop Description The AX3500 performs the Position mode using a full featured Proportional, Integral and Differential (PID) algorithm. This technique has a long history of usage in control systems and works on performing adjustments to the Power Output based on the difference measured between the desired position (set by the user) and the actual position (captured by the position sensor). Figure 66 shows a representation of the PID algorithm. Every 16 milliseconds, the controller measures the actual motor position and substracts it from the desired position to compute the position error. The resulting error value is then multiplied by a user selectable Proportional Gain. The resulting value becomes one of the components used to command the motor. The effect of this part of the algorithm is to apply power to the motor that is proportional with the distance between the current and desired positions: when far apart, high power is applied, with the power being gradually reduced and stopped as the motor moves to the final position. The Proportional feedback is the most important component of the PID in Position mode. AX3500 Motor Controller User’s Manual 97 Closed Loop Position Mode A higher Proportional Gain will cause the algorithm to apply a higher level of power for a given measured error, thus making the motor move quicker. Because of inertia, however, a faster moving motor will have more difficulty stopping when it reaches its desired position. It will therefore overshoot and possibly oscillate around that end position. Proportional Gain x E= Error Desired Position Analog Position Sensor dE dt x Σ Output A/D Measured Position Integral Gain or Optical Encoder dE dt x Differential Gain FIGURE 66. PID algorithm used in Position mode The Differential component of the algorithm computes the changes to the error from one 16 ms time period to the next. This change will be a relatively large number every time an abrupt change occurs on the desired position value or the measured position value. The value of that change is then multiplied by a user-selectable Differential Gain and added to the output. The effect of this part of the algorithm is to give a boost of extra power when starting the motor due to changes to the desired position value. The differential component will also help dampen any overshoot and oscillation. The Integral component of the algorithm performs a sum of the error over time. In the position mode, this component helps the controller reach and maintain the exact desired position when the error would otherwise be too small to energize the motor using the Proportional component alone. Only a very small amount of Integral Gain is typically required in this mode. PID tuning in Position Mode As discussed above, three parameters - Proportional Gain, Integral Gain and Differential Gain - can be adjusted to tune the position control algorithm. The ultimate goal in a well tuned PID is a motor that reaches the desired position quickly without overshoot or oscillation. Because many mechanical parameters such as motor power, gear ratio, load and inertia are difficult to model, tuning the PID is essentially a manual process that takes experimentation. 98 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 PID tuning in Position Mode The Roborun PC utility makes this experimentation easy by providing one screen for changing the Proportional, Integral and Differential gains and another screen for running and monitoring the motors. When tuning the motor, first start with the Integral Gain at zero, increasing the Proportional Gain until the motor overshoots and oscillates. Then add Differential gain until there is no more overshoot. If the overshoot persists, reduce the Proportional Gain. Add a minimal amount of Integral Gain. Further fine tune the PID by varying the gains from these positions. To set the Proportional Gain, which is the most important parameter, use the Roborun utility to observe the three following values: • • • Command Value Actual Position Applied Power With the Integral Gain set to 0, the Applied Power should be: Applied Power = (Command Value - Actual Position) * Proportional Gain Experiment first with the motor electrically or mechanically disconnected and verify that the controller is measuring the correct position and is applying the expected amount of power to the motor depending on the command given. Verify that when the Command Value equals the Actual Position, the Applied Power equals to zero. Note that the Applied Power value is shown without the sign in the PC utility. In the case where the load moved by the motor is not fixed, the PID must be tuned with the minimum expected load and tuned again with the maximum expected load. Then try to find values that will work in both conditions. If the disparity between minimal and maximal possible loads is large, it may not be possible to find satisfactory tuning values. Note that the AX3500 uses one set of Proportional, Integral and Differential Gains for both motors, and therefore assumes that similar motors, mechanical assemblies and loads are present at each channel. AX3500 Motor Controller User’s Manual 99 Closed Loop Position Mode 100 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Mode Description Closed Loop Speed Mode SECTION 9 This section discusses the AX3500 Close Loop Speed mode. Mode Description In this mode, an analog or digital speed sensor measures the actual motor speed and compares it to the desired speed. If the speed changes because of changes in load, the controller automatically compensates the power output. This mode is preferred in precision motor control and autonomous robotic applications. The AX3500 incorporates a full-featured Proportional, Integral, Differential (PID) control algorithm for quick and stable speed control. Selecting the Speed Mode The speed mode is selected by changing the Motor Control parameter in the controller to either: • • • A and B Closed Loop Speed, Separate A and B Closed Loop Speed, Mixed A Closed Loop Speed, B Position Note that in the last selection, only the first motor will operate in the Closed Loop Speed mode. Changing the parameter to select this mode is done using the Roborun Utility. See “Loading, Changing Controller Parameters” on page 185. For safety reasons and to prevent this mode from being accidentally selected, Closed Loop Speed modes CANNOT be selected by configuring the controller using the built-in switches and display. AX3500 Motor Controller User’s Manual 101 Closed Loop Speed Mode Using Optical Encoder for Speed FeedbackDigital Optical Encoders may be used to capture accurate motor speed. This capability is only available on controllers fitted with the optional encoder module. Detailed information on how to install and wire optical encoders is provided at “Connecting and Using the Encoder Function” on page 77. If using optical encoders, omit the Analog Tachometer discussion in this section and resume reading from “Control Loop Description” on page 104. Optical Encoders require special handling. See “Connecting and Using the Encoder Function” on page 77 for a detailed discussion. Tachometer or Encoder Mounting Proper mounting of the speed sensor is critical for an effective and accurate speed mode operation. Figure 67 shows a typical motor and tachometer or encoder assembly. Analog Tachometer or Optical Encoder Speed feedback FIGURE 67. Motor and speed sensor assembly needed for Close Loop Speed mode P iti F db k Tachometer wiring The tachometer must be wired so that it creates a voltage at the controller’s analog input that is proportional to rotation speed: 0V at full reverse, +5V at full forward, and 0 when stopped. Connecting the tachometer to the controller is as simple as shown in the diagram below. +5V 14 1kOhm Zero Adjust 100 Ohm pot Max Speed Adjust 10kOhm pot Tach Ana 1: Ana 2: Ana 3: Ana 4: 11 10 12 8 Internal Resistors and Converter 47kOhm A/D 10kOhm 47kOhm 1kOhm Ground 5 FIGURE 68. Tachometer wiring diagram 102 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Speed Sensor and Motor Polarity Speed Sensor and Motor Polarity The tachometer or encoder polarity (i.e. which rotation direction produces a positive of negative speed information) is related to the motor’s rotation speed and the direction the motor turns when power is applied to it. In the Closed Loop Speed mode, the controller compares the actual speed, as measured by the tachometer, to the desired speed. If the motor is not at the desired speed and direction, the controller will apply power to the motor so that it turns faster or slower, until reached. Important Warning: If there is a polarity mismatch, the motor will turn in the wrong direction and the speed will never be reached. The motor will turn continuously at full speed with no way of stopping it other than cutting the power or hitting the Emergency Stop buttons. Determining the right polarity is best done experimentally using the Roborun utility (see “Using the Roborun Configuration Utility” on page 181) and following these steps: 1. Disconnect the controller’s Motor Power. 2. Configure the controller in Open Loop Mode using the PC utility. This will cause the motors to run in Open Loop for now. 3. Launch the Roborun utility and click on the Run tab. Click the “Start” button to begin communication with the controller. The tachometer values will be displayed in the appropriate Analog input value boxe(s) which will be labeled Ana 1 and Ana 2. If encoders are used, look for the reported speed value in the Enc boxes. 4. Verify that the motor sliders are in the “0” (Stop) position. 5. If a tachometer is used, verify that the measured speed value read is 0 when the motors are stopped. If not, trim the “0” offset potentiometer. 6. Apply power to the Motor Power wires. The motor will be stopped. 7. Move the cursor of the desired motor to the right so that the motor starts rotating, and verify that a positive speed is reported. Move the cursor to the left and verify that a negative speed is reported. 8. If the tachometer or encoder polarity is the same as the applied command, the wiring is correct. 9. If the tachometer polarity is opposite of the command polarity, then either reverse the motor’s wiring, or reverse the tachometer wires. If an encoder is used, swap its CHA and ChB outputs 10. If a tachometer is used, proceed to calibrate the Max Closed Loop speed. 11. Set the controller parameter to the desired Closed Loop Speed mode using the Roborun utility. AX3500 Motor Controller User’s Manual 103 Closed Loop Speed Mode Adjust Offset and Max Speed For proper operation, the controller must see a 0 analog speed value (2.5V voltage on the analog input). To adjust the 0 value when the motors are stopped, use the Roborun utility to view the analog input value while the tachometer is not turning. Move the 0 offset potentiometer until a stable 0 is read. This should be right around the potentiometer’s middle position. The tachometer must also be calibrated so that it reports a +127 or -127 analog speed value (5V or 0V on the analog input, respectively) when the motors are running at the maximum desired speed in either direction. Since most tachometers will generate more than +/- 2.5V, a 10kOhm potentiometer must be used to scale its output. To set the potentiometer, use the Roborun utility to run the motors at the desired maximum speed while in Open Loop mode (no speed feedback). While the tachometer is spinning, adjust the potentiometer until the analog speed value read is reaching 126. Note: The maximum desired speed should be lower than the maximum speed that the motors can spin at maximum power and no load. This will ensure that the controller will be able to eventually reach the desired speed under most load conditions. Important Warning: It is critically important that the tachometer and its wiring be extremely robust. If the tachometer reports an erroneous voltage or no voltage at all, the controller will consider that the motor has not reached the desired speed value and will gradually increase the applied power to the motor to 100% with no way of stopping it until power is cut off or the Emergency Stop is activated. Control Loop Description The AX3500 performs the Closed Loop Speed mode using a full featured Proportional, Integral and Differential (PID) algorithm. This technique has a long history of usage in control systems and works on performing adjustments to the Power Output based on the difference measured between the desired speed (set by the user) and the actual position (captured by the tachometer). Figure 69 shows a representation of the PID algorithm. Every 16 milliseconds, the controller measures the actual motor speed and subtracts it from the desired position to compute the speed error. The resulting error value is then multiplied by a user selectable Proportional Gain. The resulting value becomes one of the components used to command the motor. The effect of this part of the algorithm is to apply power to the motor that is proportional with the difference between the current and desired speed: when far apart, high power is applied, with the power being gradually reduced as the motor moves to the desired speed. A higher Proportional Gain will cause the algorithm to apply a higher level of power for a given measured error thus making the motor react more quickly to changes in commands and/or motor load. 104 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 PID tuning in Speed Mode The Differential component of the algorithm computes the changes to the error from one 16 ms time period to the next. This change will be a relatively large number every time an abrupt change occurs on the desired speed value or the measured speed value. The value of that change is then multiplied by a user selectable Differential Gain and added to the output. The effect of this part of the algorithm is to give a boost of extra power when starting the motor due to changes to the desired speed value. The differential component will also greatly help dampen any overshoot and oscillation. The Integral component of the algorithm perform a sum of the error over time. This component helps the controller reach and maintain the exact desired speed when the error is reaching zero (i.e. measured speed is near to, or at the desired value). Proportional Gain x E= Error Desired Speed Tachometer dE dt x Σ Output A/D Measured Speed or Integral Gain Optical Encoder dE dt x Differential Gain FIGURE 69. PID algorithm used in Speed mode PID tuning in Speed Mode As discussed above, three parameters - Proportional Gain, Integral Gain, and Differential Gain - can be adjusted to tune the Closed Loop Speed control algorithm. The ultimate goal in a well tuned PID is a motor that reaches the desired speed quickly without overshoot or oscillation. Because many mechanical parameters such as motor power, gear ratio, load and inertia are difficult to model, tuning the PID is essentially a manual process that takes experimentation. The Roborun PC utility makes this experimentation easy by providing one screen for changing the Proportional, Integral and Differential gains and another screen for running and monitoring the motors. First, run the motor with the preset values. Then experiment with different values until a satisfactory behavior is found. AX3500 Motor Controller User’s Manual 105 Closed Loop Speed Mode In Speed Mode, the Integral component of the PID is the most important and must be set first. The Proportional and Differential component will help improve the response time and loop stability. In the case where the load moved by the motor is not fixed, tune the PID with the minimum expected load and tune it again with the maximum expected load. Then try to find values that will work in both conditions. If the disparity between minimal and maximal possible loads is large, it may not be possible to find satisfactory tuning values. Note that the AX3500 uses one set of Proportional Integral and Differential Gains for both motors and therefore assumes that similar motors, mechanical assemblies and loads are present at each channel. 106 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Use of the LED Display Normal and Fault Condition LED Messages SECTION 10 This section discusses the meaning of the various messages and codes that may be displayed on the LED display during normal operation and fault conditions. Use of the LED Display The AX3500 uses a single 7-segment LED display to report a number of operating or fault conditions. The type of reported information depends on the controller’s operating context: During normal motor operation: • Motor direction During Parameter Settings • Selected parameter and its value In R/C mode with Radio off • No control message During Error condition • Error condition (overheat, emergency stop, short circuit) During Self-Test mode • • Software revision number Motor direction AX3500 Motor Controller User’s Manual 107 Normal and Fault Condition LED Messages Motor Direction Status When the controller is running, two pairs of LED segments are directly related to command informations to the Power Output stage. The position and meaning of the segments are shown in the figure below. Motor 2 Direction Lit: Forward Off: Reverse Motor 1 Direction Lit: Forward Off: Reverse FIGURE 70. Each command bit is wired to 2 LED segments Note that the display does not provide Power information. Therefore it is possible that the motor be stopped while the display indicates that the direction is forward. In such a situation controller is set to apply the power in the forward direction to the output stage but the motor is stopped because the applied power is zero. The LED can display a total of 5 patterns summarized in Table 18. TABLE 18. Motor Commands and resulting display Possible Display Motor 1 Motor 2 Comment Is also displayed when controller is active with a 0 command on each channel (i.e. motors at speed 0) 108 Forward Forward Reversed Forward AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Fault Messages TABLE 18. Motor Commands and resulting display Possible Display Motor 1 Motor 2 Forward Reversed Reversed Reversed MOSFET Transistors are OFF Motors are freewheeling Comment Signals a temporary Off condition in case of Overvoltage, undervoltage or Overtemperature condition (see page 38), of if Dead-man switch is activated (see page 52) Rapidly Flashing MOSFET Transistors are OFF Motors are freewheeling Controller is permanently Off after an Encoder Error, Short Circuit detection or Emergency Stop activation. Controller must be restarted. Fault Messages The AX3500 uses the LED display to report fault conditions. When these messages are displayed, the motors are normally stopped. No Control This message is displayed in the R/C mode to indicate that no valid radio signal has been detected at its inputs or that radio signal has been lost. When the controller is configured in the mixed mode, signals on channel 1 and channel 2 must be present to enable the controller. When the controller is configured in the separate mode, a signal received on either channel will enable the controller. When enabled, the controller will display the normal motor status described previously. The “no control” message is displayed using the following sequence of digits. AX3500 Motor Controller User’s Manual 109 Normal and Fault Condition LED Messages FIGURE 71. No Radio signal scrolling message Temporary Faults Temporary Faults are condition that cause the controller’s Power Output stage to turn Off and remain off for as long as the fault is present. Temporary Faults are indicated with the LED displaying a solid “8”. Conditions that cause temporary faults are: • • • • Overvoltage Undervoltage Overtemperature condition (see page 38) Dead-man activation (see page 52) Permanent Faults Permanent Faults are irrecoverable error condition. When such a condition is detected, the controller’s Power Output stage is turned Off for safety reasons and remains Off until it is reset of powered down and up. Permanent Faults are indicated with a rapidly flashing “8”. Condition causing a permanent fault are: • • • Encoder Error Short Circuit detection Emergency Stop activation Emergency stop condition can be triggered by pressing the Prog and Set button simultaneously, or by activating the Estop/Inv input if enabled. Self-Test Display Self test is a special condition that is entered by holding the Program and Set button immediately after power-on or reset. During self test, the LEDs will display the controller’s software revision number by flashing a sequence of digits as shown in the figure below. Then each motor will, in turn, be ramped to maximum forward and maximum reverse. When the motors are operating, the LED will display one of the patterns described in Table 18. The cycle will repeat indefinitely until the controller is powered Off or reset. 110 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Self-Test Display = Software version 1.9b FIGURE 72. Example of Software revision number display AX3500 Motor Controller User’s Manual 111 Normal and Fault Condition LED Messages 112 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Mode Description SECTION 11 R/C Operation This section describes the controller’s wiring and functions specific to the R/C radio control mode. Mode Description The AX3500 can be directly connected to an R/C receiver. In this mode, the speed or position information is contained in pulses whose width varies proportionally with the joysticks’ positions. The AX3500 mode is compatible with all popular brands of R/C transmitters. The R/C mode provides the simplest method for remotely controlling a robotic vehicle: little else is required other than connecting the controller to the R/C receiver (using the provided cable) and powering it On. For better control and improved safety, the AX3500 can be configured to perform correction on the controls and will continuously monitor the transmission for errors. FIGURE 73. R/C radio control mode AX3500 Motor Controller User’s Manual 113 R/C Operation Selecting the R/C Input Mode The R/C Input Mode is the factory default setting. If the controller has been previously set to a different Input Mode, it will be necessary to reset it to the R/C mode using one of the following methods: • Restoring the factory defaults by pressing and holding the Program and Set buttons while powering on the controller until the LED display flashes • Setting the “I” parameter to the value “0” using one of several methods described in the chapters “Configuring the Controller using the Switches” on page 175, “Using the Roborun Configuration Utility” on page 181, and “Accessing & Changing Configuration Parameter in Flash” on page 147. Connector I/O Pin Assignment (R/C Mode) 9 15 Pin1 8 FIGURE 74. Pin locations on the controller’s 15-pin connector When used in R/C mode, the pins on the controller’s DB15 connector are mapped as described in the table below. TABLE 19. Connector pin-out in R/C mode Pin Number Input or Output Signal Description 1 and 9 Output Output C 2A Accessory Output C 2 Output RS232 data RS232 Data Logging Output 3 Input Ch 1 R/C radio Channel 1 pulses 4 Input Ch 2 R/C radio Channel 2 pulses 5 and 13 Power Out Ground Controller ground (-) 6 GND In Ground Optocoupler GND Input Unused in RevB Hardware 7 +5V In +5V Optocoupler +5V Input Unused in RevB Hardware 114 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 R/C Input Circuit Description TABLE 19. Connector pin-out in R/C mode Pin Number Input or Output Signal Description 8 Digital In R/C: Ch 3 / Ana In 4 R/C radio Channel 3 pulses - (Not available on AX3500) 10 Analog in Ana in 2 Channel 2 speed or position feedback input 11 Analog in Ana in 1 Channel 1 speed or position feedback input 12 Analog in Ana in 3 Unused 14 Power Out +5V +5V Power Output (100mA max.) 15 Input Input EStop/Inv Emergency Stop or Invert Switch input R/C Input Circuit Description The AX3500 R/C inputs are directly connected to the MCU logic. Figure 75 shows an electrical representation of the R/C input circuit. +5V Output R/C Channel 1 R/C Channel 2 R/C Channel 3 14 Controller Power 3 4 MCU 8 5-13 Controller Ground FIGURE 75. AX3500 R/C Input equivalent circuit Supplied Cable Description The AX3500 is delivered with a custom cable with the following wiring diagram: AX3500 Motor Controller User’s Manual 115 R/C Operation 1 2 3 1 8 9 15 FIGURE 76. RC Cable wiring diagram 3 2 1 . FIGURE 77. RC connection cable Powering the Radio from the controller The 5V power and ground signals that are available on the controller’s connector may be used to power the R/C radio. The wire loop is used to bring the controller’s power to the the radio as well as for powering the optocoupler stage. Figure 78 below shows the connector wiring necessary to do this. Figure 79 shows the equivalent electrical diagram. 116 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Powering the Radio from the controller Channel 3 Channel 2 3: 4: 6: 7: 8: Channel 1 Channel 1 Command Pulses Channel 2 Command Pulses Radio battery (-) Ground Radio battery (+) Channel 3 Command Pulses 8 9 Pin 1 Wire loop bringing power from controller to RC radio 15 FIGURE 78. Wiring for powering R/C radio from controller 14 Controller Power R/C Radio Power 7 R/C Radio R/C Channel 1 3 R/C Channel 2 4 R/C Channel 3 8 R/C Radio Ground 6 5-13 MCU Controller Ground FIGURE 79. R/C Radio powered by controller electrical diagram Important Warning Do not connect a battery to the radio when in this mode. The battery voltage will flow directly into the controller and cause permanent damage if its voltage is higher than 5.5V. This mode of operation is the most convenient and is the one wired in the R/C cable delivered with the controller. AX3500 Motor Controller User’s Manual 117 R/C Operation Connecting to a Separately Powered Radio This wiring option must be used when the controller is used with a RC receiver that is powered by its own separate battery. The red wire in the loop must be cut so that the 5V out from the controller does not flow to the radio, and so that the battery that is connected to the controller does not inject power into the controller. The figure below show the cable with the loop cut. Figure 81 shows the equivalent electrical diagram. Channel 3: Channel 2 3: 4: 6: 7: 8: Channel 1 Channel 1 Command Pulses Channel 2 Command Pulses Radio battery (-) Ground Radio battery (+) Channel 3 Command Pulses 8 9 Pin 1 Cut red loop 15 FIGURE 80. Wiring when receiver is powered by its own separate battery R/C Radio Power 14 Controller Power Cut 7 Radio Battery R/C Radio R/C Channel 1 3 R/C Channel 2 4 R/C Channel 3 8 R/C Radio Ground 6 5-13 MCU Controller Ground FIGURE 81. Electrical diagram for connection to independently powered RC radio Operating the Controller in R/C mode In this operating mode, the AX3500 will accept commands from a Radio Control receiver used for R/C models remote controls. The speed or position information is communicated to the AX3500 by the width of a pulse from the R/C receiver: a pulse width of 1.0 millisec- 118 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Reception Watchdog ond indicates the minimum joystick position and 2.0 milliseconds indicates the maximum joystick position. When the joystick is in the center position, the pulse should be 1.5ms. Note that the real pulse-length to joystick-position numbers that are generated by your R/C radio may be different than the ideal 1.0ms to 2.0ms discussed above. To make sure that the controller captures the full joystick movement, the AX3500 defaults to the timing values shown in Figure 82. These vales can be changed and stored as new defaults. For best control accuracy, the AX3500 can be calibrated to capture and use your radio’s specific timing characteristics and store them into its internal Flash memory. This is done using a simple calibration procedure described on page 123. joystick position: min center max 1.05ms 0.45ms R/C pulse timing: 0.9ms FIGURE 82. Joystick position vs. pulse duration default values The AX3500 has a very accurate pulse capture input and is capable of detecting changes in joystick position (and therefore pulse width) as small as 0.4%. This resolution is superior to the one usually found in most low cost R/C transmitters. The AX3500 will therefore be able to take advantage of the better precision and better control available from a higher quality R/C radio, although it will work fine with lesser expensive radios as well. Internally, the measured pulse width is compared to the reference minimum, center and maximum pulse width values. From this is generated a number ranging from -127 (when the joystick is in the min. position), to 0 (when the joystick is in the center position) to +127 (when the joystick is in the max position). This number is then used to set the motors’ desired speed or position that the controller will then attempt to reach. For best results, reliability and safety, the controller will also perform a series of corrections, adjustments and checks to the R/C commands, as described in the following sections. Reception Watchdog Immediately after it is powered on, if in the R/C mode, the controller is ready to receive pulses from the R/C radio and move the motors accordingly. AX3500 Motor Controller User’s Manual 119 R/C Operation If no pulses are present, the motors are disabled, and the controller’s display will scroll alternatively the letters “no ctrl” as shown in Figure 83 below. FIGURE 83. “No control” message will scroll when no valid radio signal is present After powering on the R/C radio receiver and transmitter, and if the wiring is correct, the controller will start receiving pulses. For a preset amount of time, the controller will monitor the pulse train to make sure that they are regular and therefore genuine R/C radio command pulses. After that, the motors are enabled and the LEDs will display a pattern related to the actual motor direction (see Figure , “Motor Direction Status,” on page 108). This power-on Watchdog feature prevents the controller from becoming active from parasite pulses and from moving the motors erratically as a result. Similarly, if the pulse train is lost while the motors were enabled, the controller will wait a short preset amount of time before it disables the motors. If the pulses reappear during that time, the controller continues without any breaks. If the communication is confirmed to be lost, the “no ctrl” message is displayed again. Note: the Accessory Outputs C will be turned Off when radio is lost. Important Notice about PCM Radios PCM radios have their own watchdog circuitry and will output a signal (normally a “safe condition” value) when radio communication is lost. This signal will be interpreted by the AX3500 as a valid command and the controller will remain active. To benefit from the AX3500’s radio detection function, you will need to disable the PCM radio watchdog. R/C Transmitter/Receiver Quality Considerations As discussed earlier in this chapter, the AX3500 will capture the R/C’s command pulses with great accuracy. It will therefore be able to take advantage of the more precise joysticks and timings that can be found in higher quality R/C radio, if such added precision is desired in the application. Another important consideration is the R/C receiver’s ability to operate in an electrically noisy environment: the AX3500 switches high current at very high frequencies. Such transients along long battery and motor wires will generate radio frequency noise that may interfere with the R/C radio signal. The effects may include reduced remote control range and/or induced errors in the command pulse resulting in jerky motor operation. A higher quality PCM R/C transmitter/radio is recommended for all professional applications, as these are more immune to noise and interference. While a more noise-immune radio system is always desirable, it is also recommended to layout the wiring, the controller, radio and antenna so that as little as possible electrical 120 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Joystick Deadband Programming noise is generated. Section “Electrical Noise Reduction Techniques” on page 37 provides a few suggestions for reducing the amount of electrical noise generated in your robot. Joystick Deadband Programming In order to avoid undesired motor activity while the joysticks are centered, the AX3500 supports a programmable deadband feature. A small deadband is set in the controller by default at the factory. This deadband can be stretched, reduced or eliminated using the Roborun utility or by changing the “d” parameter using one of the three methods described in the chapter “Configuring the Controller using the Switches” on page 175. The AX3500 has 8 preset deadband values coded 0 to 7. The value 0 disables the deadband. Other values select a deadband according to the table below. The deadband value applies equally to both joysticks. The deadband is measured as a percentage of total normal joystick travel. For example, a 16% deadband means that the first 16% of joystick motion in either direction will have no effect on the motors. If the joystick is recalibrated to operate using a shorter travel (see “Joystick Calibration” on page 122), the percent value in the table will not be as accurate. TABLE 20. Selectable deadband values Deadband Parameter Value Deadband as Percent of full Joystick Travel d=0 No deadband d=1 8% d=2 16% - default value d=3 24% d=4 32% d=5 40% d=6 46% d =7 54% Note that the deadband only affects the start position at which the joystick begins to take effect. The motor will still reach 100% when the joystick is at its full position. An exaggerated illustration of the effect of the deadband on the joystick action is shown in the Figure 84 below. AX3500 Motor Controller User’s Manual 121 R/C Operation Min Reverse Deadband (no action) Max Reverse Min Forward Max Forward Centered Position FIGURE 84. Effect of deadband on joystick position vs. motor speed Command Control Curves The AX3500 can also be set to translate the joystick motor commands so that the motors respond differently depending on whether the joystick is near the center or near the extremes. Five different exponential or logarithmic translation curves may be applied. Since this feature applies to the R/C, Analog and RS232 modes, it is described in detail in “Command Control Curves” on page 48, in the General Operation section of this manual. Left/Right Tuning Adjustment When operating in mixed mode with one motor on each side of the robot, it may happen that one motor is spinning faster than the other one at identically applied power, causing the vehicle to pull to the left or to the right. To compensate for this, the AX3500 can be made to give one side up to 10% more power than the other at the same settings. This capability is described in detail in “Left / Right Tuning Adjustment” on page 49, in the General Operation section of this manual. Joystick Calibration This feature allows you to program the precise minimum, maximum and center joystick positions of your R/C transmitter into the controller’s memory. This feature will allow you to use the full travel of your joystick (i.e. minimum = 100% reverse, maximum = 100% forward). It also ensures that the joystick’s center position does indeed correspond to a “0” motor command value. Joystick calibration is also useful for modifying the active joystick travel area. For example, the figure below shows a transmitter whose joystick’s center position has been moved back so that the operator has a finer control of the speed in the forward direction than in the reverse position. 122 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Automatic Joystick Calibration There are two methods for calibrating the joysticks: • The automatic method is the simplest and is based on the controller “learning” the joystick’s parameters using the simple training sequence described below. • The manual method lets you enter actual timing numbers directly in the controllers flash memory using your PC running the Roborun configuration utility. This method is described in “Loading, Changing Controller Parameters” on page 185. New Desired Center Position Min Reverse Min Forward Max Reverse Max Forward FIGURE 85. Calibration example where more travel is dedicated to forward motion Automatic Joystick Calibration To calibrate the joystick(s) follow these steps: • • Press and hold the Program button while resetting or powering up the controller • • Turn the R/C transmitter and receiver On • When the display flashes the letter “J” followed by the “-” sign, press the Set button • When the display flashes the letter “J” followed by “o”, the controller has entered the joystick calibration mode • • • Move each joystick to the desired minimum and maximum position several times • After 10 seconds, the controller will enter the Program mode and flash the first parameter (I) and its value (0 if set R/C mode) Press the Program button several times until the letter “J” is displayed. If you miss it, keep pressing the Program button for another cycle. Move the joystick(s) back to the desired center position With the joystick(s) in the center position, press the Program button to record the change permanently in the controller’s Flash memory. Restart the controller by pressing the Reset button or cycling the power. To reset the controller to factory default or to program the joystick’s positions using numerical values, see “Configuring the Controller using the Switches” on page 175 and “Using the Roborun Configuration Utility” on page 181. AX3500 Motor Controller User’s Manual 123 R/C Operation Notes: If you attempt to calibrate the joysticks while the radio is off or not connected to the controller, the calibration data will not change and the previously stored information will continue to be used. If calibration is performed with only one R/C channel connected to the controller, then only the joystick that is active will be calibrated. The other channel will keep its original settings. A minimum amount of travel is required between the min, max and center joystick positions. If, while calibrating, the joystick has not been moved far enough from either side of the center position, the controller will automatically include a minimum of travel to ensure proper and safe operation. In most cases, this creates no undesired effect to the driving characteristics of the robot. R/C calibration only applies to the channel 1 and channel 2 inputs. The accessory activation channel (channel 3) is preset at the factory and cannot be changed. Important Notice To ensure that only stable pulses are present, the R/C transmitter and radio must be On before entering joystick calibration. Note: Channel 3 is not available on the controllers equipped with encoder inputs. Data Logging in R/C Mode While in R/C Mode, the AX3500 will continuously send a string of characters on the RS232 output line. This string will contain 12 two-digit hexadecimal numbers representing the following operating parameters. • • • • • • • • Captured R/C Command 1 and 2 Power Applied to Controller’s output stage Values applied to Analog inputs 1 and 2 Amps on channel 1 and 2 Internal Heat Sink temperatures 1 and 2 Main Battery voltage Internal 12V voltage Encoder Speed or Position feedback. The entire string is repeated every 200 milliseconds with the latest internal parameter values. This information can be logged using the Roborun Utility (see “Viewing and Logging Data in Analog and R/C Modes” on page 197). It may also be stored in a PDA that can be placed in the mobile robot. The string and data format is described in “Analog and R/C Modes Data Logging String Format” on page 170. The serial port’s output can be safely ignored if it is not required in the application. To read the output string while operating the controller with the R/C radio, you must modify the R/C cable to add an RS232 output wire and connector that will be connected to the 124 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Data Logging in R/C Mode PC’s communication port. Figure 86 and below shows the wiring diagram of the modified R/C cable for connection to a PC. DB9 Female To PC DB15 Male To Controller 1 1 RX Data 6 9 7 10 8 11 9 12 2 2 RS232 Data Out 3 R/C Ch 1 3 4 R/C Ch 2 4 GND 5 5 13 14 15 GND 6 7 R/C GND R/C +5V 8 FIGURE 86. Modified R/C cable with RS232 output for data logging to a PC AX3500 Motor Controller User’s Manual 125 R/C Operation 126 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Mode Description Analog Control and Operation SECTION 12 This section describes how the motors may be operated using analog voltage commands. Mode Description The AX3500 can be configured to use a 0 to 5V analog voltage, typically produced using a potentiometer, to control each of its two motor channels. The voltage is converted into a digital value of -127 at 0V, 0 at 2.5V and +127 at 5V. This value, in turn, becomes the command input used by the controller. This command input is subject to deadband threshold and exponentiation adjustment. Analog commands can be used to control motors separately (one analog input command for each motor) or in mixed mode. Important Notice The analog mode can only be used in the Closed Loop speed or position modes when Optical Encoders are used for feedback. Position potentiometers or tachometers cannot be used since there is only one analog input per channel and since this this input will be connected to the command potentiometer. AX3500 Motor Controller User’s Manual 127 Analog Control and Operation Connector I/O Pin Assignment (Analog Mode) 9 15 Pin1 8 When used in the Analog mode, the pins on the controller’s DB15 connector are mapped as described in the table below TABLE 21. DB15 Connector pin assignment in Analog mode 128 Pin Number Signal Input or Output Description 1 Output C Output 2Amp Accessory Output C (same as pin 9) 2 Data Out Output RS232 data output to the PC for data logging 3 Data In Input unused 4 Input F Input See “Special Use of Accessory Digital Inputs” on page 52 5 Ground Out Power Output Controller ground (-) 6 Ground In Power Input unused 7 +5V In Power Input unused 8 Input E Input Not available on AX3500 9 Output C Output 2Amp Accessory Output C (same as pin 1) 10 Channel 2 In Analog in Channel 2 analog input 11 Channel 1 In Analog in Channel 1 analog input 12 Output D Output Not available on AX3500 13 Ground Out Power Controller ground (-) 14 +5V Out Power Output +5V Power Output (100mA max.) 15 Switch Input Input Emergency Stop or Invert Switch input AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Connecting to a Voltage Source Connecting to a Voltage Source The analog inputs expect a DC voltage of 0 to 5V which can be sourced by any custom circuitry (potentiometer, Digital to Analog converter). The controller considers 2.5V to be the zero position (Motor Off). 0V is the maximum reverse command and +5V is the maximum forward command. The inputs’ equivalent circuit is show in Figure 87 below. +5V 14 Internal Resistors and Converter Analog In1: pin 11 In2: pin 10 47kOhm A/D 0V = Min 2.5V = Off 5V = Max 10kOhm 47kOhm 13 Ground FIGURE 87. Analog input circuit Notice the two 47K resistors, which are designed to automatically bring the input to a midpoint (Off) position in case the input is not connected. The applied voltage must have sufficient current (low impedance) so that it is not affected by these resistors. Connecting a Potentiometer Figure 88 shows how to wire a potentiometer to the AX3500. By connecting one end to ground and the other to 5V, the potentiometer acts as an adjustable voltage divider. The voltage will thus vary from 0V when the tap is at the minimum position and to 5V when the tap is at the maximum position. The controller considers 2.5V to be the zero position (Motor Off). 2.5V is the potentiometer’s mid point position. AX3500 Motor Controller User’s Manual 129 Analog Control and Operation +5V 14 Internal Resistors and Converter Analog Input 1 2 3 or 4 10kOhm 10 11 12 8 47kOhm A/D 10kOhm 47kOhm 13 Ground FIGURE 88. Potentiometer connection wiring diagram The controller includes two 47K ohm resistors pulling the input to a mid-voltage point of 2.5V. When configured in the Analog Input mode, this will cause the motors to be at the Off state if the controller is powered with nothing connected to its analog inputs. Important Notice The controller will not activate and will display the “no ctrl” message after power up or reset until the analog inputs are at 2.5V FIGURE 89. The “no control” message indicates that joystick is not centered at power up Selecting the Potentiometer Value The potentiometer can be of almost any value. Undesirable effects occur, however, if the value is too low or too high. If the value is low, an unnecessarily high and potentially damaging current will flow through the potentiometer. The amount of current is computed as the voltage divided by the potentiometer’s resistance at its two extremes. For a 1K potentiometer, the current is: I = U/R = 5V / 1000 Ohms = 0.005A = 5mA For all practical purposes, a 1K potentiometer is a good minimal value. If the value of the potentiometer is high, then the two 47K resistors built into the controller will distort the reading. The effect is minimal on a 10K potentiometer but is significant on a 130 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Analog Deadband Adjustment 100K or higher potentiometer. Figure 90 shows how the output voltage varies at the various potentiometer positions for three typical potentiometer values. Note that the effect is an exponentiation that will cause the motors to start moving slowly and accelerate faster as the potentiometer reaches either end. This curve is actually preferable for most applications. It can be corrected or amplified by changing the controller’s exponentiation parameters (see “Command Control Curves” on page 48. Voltage at Input 5V 1K Pot 4V 3V 10K Pot 100K Pot 2V 1V 0V Min Center Max Potentiometer Position FIGURE 90. Effect of the controller’s internal resistors on various potentiometers Analog Deadband Adjustment The controller may be configured so that some amount of potentiometer or joystick travel off its center position is required before the motors activate. The deadband parameter can be one of 8 values, ranging from 0 to 7, which translate into a deadband of 0% to 16%. Even though the deadband will cause some of the potentiometer movement around the center position to be ignored, the controller will scale the remaining potentiometer movement to command the motors from 0 to 100%. Note that the scaling will also cause the motors to reach 100% at slightly less than 100% of the potentiometer’s position. This is to ensure that 100% motor speed is achieved in all circumstances. Table 22 below shows the effect of the different deadband parameter values. Changing the deadband parameter can be done using the controller’s switches (see “Configuring the Controller using the Switches” on page 175) or the Roborun utility on a PC (see “Loading, Changing Controller Parameters” on page 185). AX3500 Motor Controller User’s Manual 131 Analog Control and Operation TABLE 22. Analog deadband parameters and their effects Parameter Value Pot. Position resulting in Motor Power at 0% Pot. Position resulting in Motor Power at -/+100% 0 0% 2.5V 94% 0.15V and 4.85V 1 0% to 2.4% 2.44V to 2.56V 96% 0.10V and 4.90V 2 0% to 4.7% 2.38V to 2.62V 93% 0.18V and 4.83V 3 (default) 0% to 7.1% 2.32V to 2.68V 95% 0.13V to 4.88V 4 0% to 9.4% 2.27V to 2.74 93% 0.18V and 4.83V 5 0% to 11.8% 2.21V to 2.80V 95% 0.13V to 4.88V 6 0% to 14.2% 2.15V to 2.86V 94% 0.15V and 4.85V 7 0% to 16.5% 2.09V to 2.91V 96% 0.10V and 4.90V Important Notice Some analog joysticks do not cause the potentiometer to reach either extreme. This may cause the analog voltage range to be above 0V and below 5V when the stick is moved to the extreme, and therefore the controller will not be able to deliver full forward or reverse power. Power-On Safety When powering on the controller, power will not be applied to the motors until both the Channel 1 and Channel 2 potentiometers have been centered to their middle position (2.5V on each input). This is to prevent the robot or vehicle from moving, in case the joystick was in an active position at the moment the controller was turned on. The “no ctrl” message will scroll on the LED display while the controller is disabled. Under Voltage Safety If the controller is powered through the Power Control input and the motor battery voltage drops below 5V, the controller will be disabled until the analog commands are centered to the midpoint (2.5V on each input). Data Logging in Analog Mode While in Analog Mode, the AX3500 will continuously send a string of characters on the RS232 output line. This string will contain 13 two-digits hexadecimal number representing the following operating parameters. • • • • 132 Captured Analog Command 1 and 2 Power Applied to Controller’s output stage Raw analog command values Amps on channel 1 and 2 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Data Logging in Analog Mode • • • • Internal Heat Sink temperatures 1 and 2 Main Battery voltage Internal 12V voltage Encoder Speed or Position The entire string is repeated every 213 milliseconds with the latest internal parameter values. This information can be logged using the Roborun Utility (see “Viewing and Logging Data in Analog and R/C Modes” on page 197). It may also be stored in a PDA that can be placed in the mobile robot. The string and data format is described in “Analog and R/C Modes Data Logging String Format” on page 170. The serial port’s output can be safely ignored if it is not required in the application. To read the output string while operating the controller with an analog command, the cable must be modified to add an RS232 output wire and connector that will be connected to the PC’s communication port. Figure 91 below shows the wiring diagram of the modified cable for connection to a PC or to a PDA, respectively. DB9 Female To PC DB15 Male To Controller 1 1 RX Data 6 9 7 10 8 11 9 12 2 2 RS232 Data Out Ana Ch2 3 3 Ana Ch1 4 4 GND 5 GND 5 13 14 15 6 +5V 7 8 FIGURE 91. Modified Analog cable with RS232 output data logging for PC DB9 Male To PDA DB15 Male To AX2500 1 1 RX Data 6 9 2 2 7 10 8 11 9 12 RS232 Data Out 3 Ana Ch2 3 4 Ana Ch1 4 GND 5 5 13 14 15 GND 6 7 +5V 8 FIGURE 92. Modified Analog cable with RS232 output data logging for PDA AX3500 Motor Controller User’s Manual 133 Analog Control and Operation 134 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Use and benefits of RS232 Serial (RS-232) Controls and Operation SECTION 13 This section describes the communication settings and the commands accepted by the AX3500 in the RS232 mode of operations. This information is useful if you plan to write your own controlling software on a PC or microcomputer. These commands will also allow you to send commands manually using a terminal emulation program. If you wish to use your PC simply to set parameters and/or to exercise the controller, you should use the Roborun utility described on page 135. Use and benefits of RS232 The serial port allows the AX3500 to be connected to microcomputers or wireless modems. This connection can be used to both send commands and read various status information in real-time from the controller. The serial mode enables the design of autonomous robots or more sophisticated remote controlled robots than is possible using the R/C mode. RS232 commands are very precise and securely acknowledged by the controller. They are also the method by which the controller’s features can be accessed and operated to their fullest extent. When connecting the controller to a PC, the serial mode makes it easy to perform simple diagnostics and tests, including: • • • • • • Sending precise commands to the motors Reading the current consumption values and other parameters Obtaining the controller’s software revision and date Reading inputs and activating outputs Setting the programmable parameters with a user-friendly graphical interface Updating the controller’s software AX3500 Motor Controller User’s Manual 135 Serial (RS-232) Controls and Operation Connector I/O Pin Assignment (RS232 Mode) 9 15 Pin1 8 FIGURE 1. Pin locations on the controller’s 15-pin connector When used in the RS232 mode, the pins on the controller’s DB15 connector are mapped as described in the table below TABLE 23. DB15 Connector pin assignment in RS232 mode Pin Number Input or Output Signal Description 1 and 9 Output Output C 2A Accessory Output C 2 Output Data Out RS232 Data from Controller to PC 3 Input Data In RS232 Data In from PC 4 Input Input F Digital Input F readable RS232 mode Dead man switch activation 5 and 13 Power Out Ground Controller ground (-) 6 GND In Ground Unused in RevB Hardware 7 +5V In Power Unused in RevB Hardware Optocoupler +5V Input. Connect to pin 14 Unused in RevB Hardware 8 Digital In and Analog In Input E / Ana in 4 Analog Input 4 in RevB Hardware 10 Analog in Ana in 2 Channel 2 speed or position feedback input 11 Analog in Ana in 1 Channel 1 speed or position feedback input Ana in 3 Analog input 3 12 136 Optocoupler GND Input, Connect to pin 5 Unused in RevB Hardware 14 Power Out +5V +5V Power Output (100mA max.) 15 Input Input EStop/Inv Emergency Stop or Invert Switch input AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Cable configuration Cable configuration The RS232 connection requires the special cabling as described in the figure below. The 9pin female connector plugs into the PC (or other microcontroller). The 15-pin male connector plugs into the AX3500. It is critical that you do not confuse the connector’s pin numbering. The pin numbers on the drawing are based on viewing the connectors from the front (facing the sockets or pins). Most connectors have pin numbers molded on the plastic. DB9 Female To PC DB15 Male To Controller 1 1 RX Data TX Data 6 9 7 10 8 11 9 12 2 3 Data Out 3 Data In 4 4 GND 2 5 5 GND 13 6 14 7 15 8 FIGURE 93. PC to AX3500 RS232 cable/connector wiring diagram Extending the RS232 Cable The AX3500 is delivered with a 4-foot cable adapter which may be too short, particularly if you wish to run and monitor the controller inside a moving robot. RS232 extension cables are available at most computer stores. However, you can easily build one using a 9-pin DB9 male connector, a 9-pin DB9 female connector and any 3-wire cable. These components are available at any electronics distributor. A CAT5 network cable is recommended, and cable length may be up to 100’ (30m). Figure 94 shows the wiring diagram of the extension cable. AX3500 Motor Controller User’s Manual 137 Serial (RS-232) Controls and Operation DB9 Female DB9 Male 1 1 RX Data TX Data 6 6 7 7 8 8 9 9 2 3 Data Out 3 Data In 4 4 GND 2 5 5 GND FIGURE 94. RS232 extension cable/connector wiring diagram Communication Settings The AX3500 serial communication port is set as follows: 9600 bits/s, 7-bit data, 1 Start bit, 1 Stop bit, Even Parity Communication is done without flow control, meaning that the controller is always ready to receive data and can send data at any time. These settings cannot be changed. You must therefore adapt the communication setting in your PC or microcomputer to match those of the controller. Establishing Manual Communication with a PC The controller can easily be connected to a PC in order to manually exercise its capabilities. Simply connect the supplied cable to the AX3500 on one end (DB-15 connector) and to a free COM port on the other end (DB-9 connector). Once connected, you will need a Terminal Emulation program to display the data received from the controller on the PC’s screen and to send characters typed on the keyboard to the controller. All Windows PC’s come with the Hyperterm terminal emulation software. Locate the Hyperterm launch icon in the Start button: Programs > Accessories > Communication folder. You will need to configure Hyperterm to use the COM port to which you have connected the controller (typically COM1) and to configure the communication settings as described in the section above. To save time and avoid errors, a hyperterm configuration file is automatically installed in your PC’s Start button menu when the Roboteq’s Roborun utility is installed (See “Downloading and Installing the Utility” on page 181). The configuration file is set to use the 138 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Establishing Manual Communication with a PC COM1port. You can easily change this setting to a different port from the program’s menus. Note that starting with version 1.9, the Roborun PC utility also includes a Terminal Emulation Console for communicating with the controller using raw data. See “Using the Console” on page 196. In all cases, immediately after reset or power up, the controller will output a short identity message followed by a software revision number and software revision date as follows: Roboteq v1.9b 06/01/07 s The letter below the prompt message is a code that provides information on the hardware and can be ignored. If in R/C or Analog mode, type the Enter key 10 times to switch to RS232 mode and display the OK prompt FIGURE 95. Power-on message appearing on Hyperterm RS232 Communication with the Encoder Module The AX3500 contains its own Microcontroller and firmware in Flash. The Encoder’s MCU communicates with the one on the main board of the controller. During normal operations, the two MCUs exchange information as needed, transparently to the user. During a short time at power up, however, the Encoder’s MCU will send data to the main serial port. The sent data is a separate prompt message which: • • • Announces the presence of the encoder MCU Outputs its software revision and date Outputs a code identifying the module’s hardware ID The serial port settings are described in “Serial (RS-232) Controls and Operation” on page 135. AX3500 Motor Controller User’s Manual 139 Serial (RS-232) Controls and Operation Power up prompt from main MCU Hardware Code of main board Power up prompt from encoder MCU Hardware Code of Encoder Module FIGURE 96. Hyperterm session showing power up messages from both MCUs After this information is sent, the Encoder’s MCU will “listen” for approximately 100ms and will enter the In System Programming mode (ISP) if the letter “Z” is sent to it. While in the ISP mode, new software can be loaded into the Encoder’s MCU via the controller’s main serial port. Details on software updating are given in section “Updating the Controller’s Software” on page 199. Entering RS232 from R/C or Analog mode If the controller is configured in R/C or Analog mode, it will not be able to accept and recognize RS232 commands immediately. However, the controller will be “listening” to the serial port and will enter the serial mode after it has received 10 continuous “Enter” (Carriage Return) characters. At that point, the controller will output an “OK” message, indicating that it has entered the RS232 mode and that it is now ready to accept commands. Note that for improved safety, the RS232 watchdog is automatically enabled when entering the RS232 in this way. See “RS-232 Watchdog” on page 142. When reset again, the controller will revert to the R/C mode or Analog mode, unless the Input Mode parameter has been changed in the meantime. Data Logging String in R/C or Analog mode If the controller is in the R/C or analog mode, immediately after reset it will send a continuous string of characters (one character every 8ms, one entire string every 200ms) containing operating parameters for data logging purposes. This information can be safely ignored and the controller will still be able to switch to RS232 mode upon receiving 10 continuous Carriage Returns as described above. The format of the data logging string and it content is described in Figure , “Analog and R/C Modes Data Logging String Format,” on page 170 140 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Commands Acknowledge and Error Messages RS232 Mode if default If the controller is configured in RS232 mode, it will automatically be in the RS232 mode upon reset or power up. In this case, the “OK” message is sent automatically, indicating that the controller is ready to accept commands through its serial port. Commands Acknowledge and Error Messages The AX3500 will output characters in various situations to report acknowledgements or error conditions as listed below. Character Echo At the most fundamental level, the AX3500 will echo back to the PC or Microcontroller every valid character it has received. If no echo is received, one of the following is occurring: • • • the controller is not in the RS232 mode the controller is Off the controller may be defective Command Acknowledgement The AX3500 will acknowledge commands in one of two ways: For commands that cause a reply, such as a speed or amps queries, the reply to the query must be considered as the command acknowledgement. For commands where no reply is expected, such as speed setting, the controller will issue a “plus” character (+) after every command as an acknowledgment. Command Error If a command or query has been received with errors or is wrong, the control will issue a “minus” character (-) to indicate the error. If the controller issues the “-” character, it should be assumed that the command was lost and that it should be repeated. Watchdog time-out If the RS232 watchdog is enabled, the controller will stop the motors and issue a “W” character if it has not received a valid character from the PC or microcontroller within the past 1 seconds. AX3500 Motor Controller User’s Manual 141 Serial (RS-232) Controls and Operation RS-232 Watchdog For applications demanding the highest operating safety, the controller may be configured to automatically stop the motors (but otherwise remain fully active) if it fails to receive a character on its RS232 port for more than 1 seconds. The controller will also send a “W” character every second to indicate to the microcomputer that such a time-out condition has occurred. The character does not need to be a specific command, but any ASCII code, including invisible ones. The RS232 watchdog is enabled or disabled depending on the value of the “Input Command Mode” parameter. The RS232 watchdog is automatically enabled when entering the RS232 mode from the RC or from the Analog modes (see “Entering RS232 from R/C or Analog mode” on page 140) Controller Commands and Queries AX3500 commands and queries are composed of a series of 2 or 4 characters followed by the “enter” (carriage return) code. The controller will send back (echo) every character it is receiving. By checking that the returned character is the same as the one sent, it is possible to verify that there has been no error in communication. After a command has been received and properly executed, the controller will send the “+” character. If a command has been received with errors or bad parameters, the controller will send the “-” character. The table below lists the AX3500 RS232 commands and queries TABLE 24. 142 Command Type %rrrrrr Command Description Reset Controller !Ann Command Channel 1, forward command to value nn !ann Command Channel 1, reverse command to value nn !Bnn Command Channel 2, forward command to value nn !bnn Command Channel 2, reverse command to value nn !C Command Turn Accessory Output C n !c Command Turn Accessory Output C Off ?a or ?A Query Read Battery Amps ?v or ?V Query Read Power Level applied to motors AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Controller Commands and Queries TABLE 24. Command Type Description ?p or ?P Query Read Analog Inputs 1 and 2 ?r or ?R Query Read Analog Inputs 3 and 4 ?m or ?M Query Read Heatsink Temperature ?e or ?E Query Read Battery and Internal Voltage ?i or ?I Query Read Digital Inputs ?k or ?K Query Quick read of Encoder Speed or Position Set Motor Command Value Description: Send a speed of position value from 0 to 127 in the forward or reverse direction for a given channel. In mixed mode, channel 1 value sets the common forward and reverse value for both motors, while channel 2 sets the difference between motor 1 and motor 2 as required for steering. In all other modes, channel 1 commands motor 1 and channel 2 commands motor 2. Syntax: !Mnn Where M= A: channel 1, forward direction a: channel 1, reverse direction B: channel 2, forward direction b: channel 2, reverse direction Where nn= Speed or position value in 2 Hexadecimal digits from 00 to 7F Examples: !A00 !B7F !a3F channel 1 to 0 channel 2, 100% forward channel 1, 50% reverse Notes: The hexadecimal number must always contain two digits. For example, !a5 will not be recognized and the controller will respond with a “-” to indicate an error. The proper command in this case should be !a05. Set Accessory Output Description: Turn on or off the digital output line on the 15-pin connector. See “AX3500’s Inputs and Outputs” on page 56 for details on how to identify and wire these signals. Syntax: !M Where: M= c: output C off C: output C onExamples: turn C output off turn C output on !C !c AX3500 Motor Controller User’s Manual 143 Serial (RS-232) Controls and Operation Query Power Applied to Motors Description: This query will cause the controller to return the actual amount of power that is being applied to the motors at that time. The number is a hexadecimal number ranging from 0 to +127 (0 to 7F in Hexadecimal). In most cases, this value is directly related to the command value, except in the conditions described in the notes below. Syntax: ?v or ?V Reply: nn mm Where: nn = motor 1 applied power value mm = motor 2 applied power value Notes: The applied power value that is read back from the controller can be different than the command values for any of the following reasons: current limitation is active, motors operate at reduced speed after overheat detection, or mixed mode is currently active. No forward or reverse direction information is returned by this query. This query is most useful for providing feedback to a microcontroller commanding the controller. Query Amps from Battery to each Motor Channel Description: This query will cause the controller to return the actual number of Amps flowing from the battery to power each motor. The number is an unsigned Hexadecimal number ranging from 0 to 256 (0 to FF in Hexadecimal). Syntax: ?a or ?A Reply: nn mm Where: nn = motor 1 Amps mm = motor 2 Amps Notes: The Amps measurement has an approximately 10% precision. Its main purpose is to provide feedback to the controller’s current limitation circuitry. Important Notice The current flowing in the motor can be higher than the battery flowing out of the battery. See “Battery Current vs. Motor Current” on page 45. Important Notice On the AX3500, the number returned by the ?a command must be divided by two to obtain the actual Amps value 144 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Controller Commands and Queries Query Analog Inputs Description: This query will cause the controller to return the values of the signals present at its two analog inputs. If the controller is used in close-loop speed mode with analog feedback, the values represent the actual speed measured by the tachometer. When used in position mode, the values represent the actual motor position measured by a potentiometer. In all other modes, the values represent the measured voltage (0 to 5V) applied to the analog inputs. The values are signed Hexadecimal numbers ranging from -127 to +127. The -127 value represents 0V at the input, the 0 value represents 2.5V, and the +127 value represents +5V. Analog 1 and 2 Syntax: ?p or ?P Analog 3 and 4 Syntax: ?r or ?R Reply: nn mm Where: nn = analog input 1 value, speed or position mm = analog input 2 value, speed or position Notes: The command returns a signed hexadecimal number where 0 to +127 is represented by 00 to 7F, and -1 to -127 is represented by FF to 80 respectively. On controllers prior to RevB, querying Analog inputs 3 and 4 will return a meaningless number. Query Heatsink Temperatures Description: This query will cause the controller to return values based on the temperature measured by internal thermistors located at each heatsink side of the controller. Because NTC thermistors are non-linear devices, the conversion or the read value into a temperature value requires interpolation and a look up table. Figure 38 on page 68 shows this correlation. Sample conversion software code is available from Roboteq upon request. The values are unsigned Hexadecimal numbers ranging from 0 to 255. The lowest read value represents the highest temperature. Syntax: ?m or ?M Reply: nn mm Where: nn = thermistor 1 read value mm = thermistor 2 read value Notes: The hexadecimal format is intended to be deciphered by a microcontroller. When exercising the controller manually, you may use the Decimal to Hexadecimal conversion table on page 170. AX3500 Motor Controller User’s Manual 145 Serial (RS-232) Controls and Operation Query Battery Voltages Description: This query will cause the controller to return values based on two internally measured voltages: the first is the Main Battery voltage present at the thick red and black wires. The second is the internal 12V supply needed for the controller’s microcomputer and MOSFET drivers. The values are unsigned Hexadecimal numbers ranging from 0 to 255. To convert these numbers into a voltage figure, use the formulas described in “Internal Voltage Monitoring Sensors” on page 67. Syntax: ?e or ?E Reply: nn mm Where: nn = main battery voltage value mm = internal 12V voltage value Notes: The hexadecimal format is intended to be deciphered by a microcontroller. When exercising the controller manually, refer to the Decimal to Hexadecimal conversion table on page 171. Query Digital Inputs Description: This query will cause the controller to return the state of the controller’s two accessory inputs (inputs E and F) and the state of the Emergency Stop/Inverted input. See “Connecting Sensors and Actuators to Input/Outputs” on page 55 for information on how to wire and use these signals. The returned values are three sets of two digits with the values 00 (to indicate a 0 or Off state), or 01 (to indicate a 1 or On state). Syntax: ?i or ?I Reply: nn mm oo Where: nn = Input E status mm = Input F status oo = Estop/Invert Switch Input status Examples: ?I 01 00 01 Read Input status query Controller replies, Input E is On Input F is Off Emergency stop switch is high (not triggered) Note: the Input E value is not meaningful and should be discarded. Reset Controller Description: This command allows the controller to be reset in the same manner as if the reset button were pressed. This command should be used in exceptional conditions only or after changing the controller’s parameters in Flash memory so that they can take effect. 146 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Accessing & Changing Configuration Parameter in Flash Syntax: %rrrrrr Reply: None. Controller will reset and display prompt message Accessing & Changing Configuration Parameter in Flash It is possible to use RS232 commands to examine and change the controller’s parameters stored in Flash. These commands will appear cryptic and difficult to use for manual parameter setting. It is recommended to use the Graphical configuration utility described in “Using the Roborun Configuration Utility” on page 181. Note that many parameters will not take effect until the controller is reset or a special command is sent. The complete list of parameters accessible using these commands is listed in “Automatic Switching from RS232 to RC Mode” on page 169. Reading and writing parameters is done using the following commands: Read parameter Syntax: ^mm Reply: DD Where mm= parameter number DD= current parameter value Example: ^00 01 Read value parameter 0 Controller replies, value is 01 Modify parameter Syntax: ^mm nn Reply: + if command was executed successfully - if error Where mm= parameter number nn= new parameter value Examples: ^02 03 Store 03 into parameter 2 Notes: All parameters and values are expressed with 2 hexadecimal digits No changes will be made and an error will be reported (“-” character) when attempting to read or write a parameter that does not exist or when attempting to store a parameter with an invalid value. Apply Parameter Changes Description: Many parameters will take effect only after the controller is reset. This command can be AX3500 Motor Controller User’s Manual 147 Serial (RS-232) Controls and Operation used (instead of resetting the controller) to cause these parameters to take effect after only a ~100ms delay. Syntax: ^FF Reply: + Success, changed parameters are now active - if error Table 25 below lists the complete set of configuration parameters that may be accessed and changed using RS232 commands. Flash Configuration Parameters List TABLE 25. Configuration parameters in Flash Param Address 148 Description Active after 00 Input control mode Reset 01 Motor Control mode and Closed Loop Feedback type Reset or ^FF 02 Amps limit Reset or ^FF 03 Acceleration Reset or ^FF 04 Input Switch function Reset or ^FF 05 reserved 06 Joystick Deadband or Analog Deadband Reset or ^FF 07 Exponentiation on channel 1 Instant 08 Exponentiation on channel 2 Instant 09 Reserved 0A Left / Right Adjust Reset or ^FF 0B Encoder 1 Time Base Reset or ^FF Reset or ^FF 0C Encoder 2 Time Base 0D Reserved 0E Encoder Distance Divider Reset or ^FF 0F Gain Integral for PID Reset or ^FF 10 Gain Diff for PID Reset or ^FF 11 Gain Prop for PID Reset or ^FF 12 Joystick Center 1 MS Instant 13 Joystick Center 1 LS Instant 14 Joystick Center 2 MS Instant 15 Joystick Center 2 LS Instant 16 Joystick Min 1 MS Instant 17 Joystick Min 1 LS Instant 18 Joystick Min 2 MS Instant AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Accessing & Changing Configuration Parameter in Flash TABLE 25. Configuration parameters in Flash Param Address Description Active after 19 Joystick Min 2 LS Instant 1A Joystick Max 1 MS Instant 1B Joystick Max 1 LS Instant 1C Joystick Max 2 MS Instant 1D Joystick Max 2 LS Instant F0 Amps Calibration Parameter 1 Reset F1 Amps Calibration Parameter 2 Reset These parameters are stored in the controller’s Flash memory and are not intended to be changed at runtime. Important Notice The above parameters are stored in the MCU’s configuration flash. Their storage is permanent even after the controller is powered off. However, because of the finite number of times flash memories can be reprogrammed (approx. 1000 times), these parameters are not meant to be changed regularly, or on-the-fly. All parameters in Flash (except for the Amps calibration) are reset to their default values every time new firmware is loaded into the controller. Input Control Mode Address: Access: Effective: ^00 Read/Write After Reset This parameter selects the method the controller uses for accepting commands Value Mode See pages 0 R/C Radio mode (default) page 113 1 RS232, no watchdog page 113 2 RS232, with watchdog 3 Analog mode page 127 Motor Control Mode Address: Access: Effective: ^01 Read/Write After Reset or ^FF AX3500 Motor Controller User’s Manual 149 Serial (RS-232) Controls and Operation This parameters selects the various open loop and closed loop operating modes as well as the feedback method. Bit 2:0 Definition Motor Control Mode See pages 0 = A & B separate speed open loop (default) page 42 1 = A & B mixed speed open loop page 89 page 101 2 = A speed open loop, B position 3 = A & B position 4 = A & B separate speed closed loop 5 = A & B mixed speed closed loop 6 = A speed close loop, B position 6:3 6 7 Reserved Ch1 Feedback type Ch2 Feedback type 0 = Analog page 101 1 = Encoder page 89 0 = Analog 1 = Encoder Amps Limit Address: Access: Effective: ^02 Read/Write After Reset or ^FF This parameter configures the controller’s Amps limit. Note that this limits the amps flowing out of the power supply. Current flowing through the motors may be higher. Bit 3:0 Definition Coarse Amps See pages 0 = 15A page 44 1 = 22.5A 2 = 30A 3 = 37.5A 4 = 45A 5 = 52.5A (default) 6 = 60A 7:4 Fine Amps Mutliply this number by 0.5 and substract result from the Coarse Amps value Acceleration Address: Access: Effective: 150 ^03 Read/Write After Reset or ^FF AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Accessing & Changing Configuration Parameter in Flash This parameter configures the rate at which the controller internally changes the command value from the one it was to the one just received. Bit 7:0 Definition See pages 0 = very slow See “Programmable Acceleration” on page 47 for complete list of acceptable values 1 = slow (2) = medium-slow (default) 3 = medium 4 = fast 5 = fastest Input Switches Function Address: Access: Effective: ^04 Read/Write After Reset or ^FF This parameter enables and configures the effect of the controller’s Digital Inputs and other settings. Bit 1:0 Definition See pages Enable and Configure Invert/Estop (00) = Input Disabled (default) page 51 01 = Input as Emergency Stop page 52 10 = Disabled 11 = Input as Invert Command 2 3 Output C when Motor On (0) = No Action (default) Encoder Safety (0) = No Action (default) page 51 1 = Output C On when either motor is On page 81 1 = Disables Controller if Encoder detect no movement while power is applied to the motors 5:4 Input E Unavailable 7:6 Input F (00) = No action (default) page 52 01 = Cut FET power when Input E is Low page 53 10 = Activate output C 11 = Cut FET when Input E is High AX3500 Motor Controller User’s Manual 151 Serial (RS-232) Controls and Operation RC Joystick or Analog Deadband Address: Access: Effective: ^06 Read/Write After Reset or ^FF This parameter configures the amount of joystick or potentiometer motion can take place around the center position without power being applied to the motors. Bit 7:0 Definition See pages Values are for Joystick deadband page 121 0 = no deadband or 1 = 8% page 131 (2) = 16% (default) 3 = 24% 4 = 32% 5 = 40% 6 = 46% 7 = 54% Exponentiation on Channel 1 and Channel 2 Address: Access: Effective: ^08 - Channel 1 ^09 - Channel 2 Read/Write Instantly This parameter configures the transfer curve that is applied the input command. Bit 7:0 Definition See pages (0) = Linear (no exponentiation - default) page 122 1 = strong exponential 2 = normal exponential 3 = normal logarithmic 4 = strong logarithmic Left/Right Adjust Address: Access: Effective: 152 ^0B Read/Write After Reset or ^FF AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Accessing & Changing Configuration Parameter in Flash This parameter configures the compensation curve when motors are spinning in one direction vs. the other. Bit 7:0 Definition See pages 0, 1, ..., 6 = -5.25%, -4.5%, ...,-0.75% page 49 (7) = no adjustment (default) 8, ..., D, E** = +0.75, ..., +4.5%, +5.25% Default Encoder Time Base 1 and 2 Address: ^0B - Encoder 1 ^0C - Encoder 2 Read/Write After Reset or ^FF Access: Effective: These parameters are the Encoder Time base values that are loaded after the controller is reset or powered on. Time Bases are used to determine rotation speed depending on the Encoder’s resolution. Time Bases can be changed at Runtime using separate commands (see page 156). Time Base values are integer number from 0 to 63. Bit 7:0 Definition See pages 0 to 63 (16) default page 84 Default Encoder Distance Divider Address: Access: Effective: ^0E Read/Write After Reset or ^FF This parameters is the Encoder’s Distance Divider that is loaded after the controller is reset or powered on. The Encoder Distance Divider can be changed at Runtime using separate commands (see page 156). Parameter values are integer number from 0 to 7. Bit 7:0 Definition See pages 0 to 63 (16) default page 84 AX3500 Motor Controller User’s Manual 153 Serial (RS-232) Controls and Operation Default PID Gains Address: Access: Effective: ^0F - Proportional Gain ^10 - Integral Gain ^11 - Derivative Gain Read/Write After Reset or ^FF These parameters are the Gains values that are loaded after the controller is reset or powered on. These Gains apply to both channels. Gains can be changed at Runtime, and values can be different for each channel using separate commands (see page 156). Gains values are integer number from 0 to 63. This number is divided by 8 internal so that each increment equals 0.125. Bit 7:0 Definition See pages 0 to 63 (16) default page 97 and page 104 Joystick Min, Max and Center Values Address: Effective: ^12 - Joystick Center 1 MS ^13 - Joystick Center 1 LS ^14 - Joystick Center 2 MS ^15 - Joystick Center 2 LS ^16 - Joystick Min 1 MS ^17 - Joystick Min 1 LS ^18 - Joystick Min 2 MS ^19 - Joystick Min 2 LS ^1A - Joystick Max 1 MS ^1B - Joystick Max 1 LS ^1C - Joystick Max 2 MS ^1D - Joystick Max 2 LS Instantly These parameters are the Gains values that are loaded after the controller is reset or powered on. These Gains apply to both channels. Gains can be changed at Runtime, and values can be different for each channel using separate commands (see page 156). 154 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Reading & Changing Operating Parameters at Runtime Gains values are integer number from 0 to 63. This number is divided by 8 internal so that each increment equals 0.125. Bit 7:0 Definition See pages 8 bit value. Two registers used to form one 16 bit number for each Joystick parameter. page 122 Default values (in decimal): Min = 4400 Center = 1600 Max = 3200 Reading & Changing Operating Parameters at Runtime It is possible to change several of the controller’s operating modes, on-the-fly during normal operation. Unlike the Configuration Parameters that are stored in Flash (see above), the Operating Parameters are stored in RAM and can be changed indefinitely. After reset, the Operating Parameters are loaded with the values stored in the Configuration Parameter flash. They are then changed using RS232 commands. Use the command following commands to Read/Change the Operating Modes Syntax: ^mm Read Parameters at location mm ^mm DD Write Parameters DD in location DD mm and DD are Hexadecimal values. The table below lists the available parameters TABLE 26. Runtime R/W Parameters list Location Function R/W 80 Channel 1 Operating Modes R/W 81 Channel 2 Operating Modes R/W 82 PID Proportional gain 1 R/W 83 PID Proportional gain 2 R/W 84 PID Integral gain 1 R/W 85 PID Integral gain 2 R/W 86 PID Differential gain 1 R/W 87 PID Differential gain 2 R/W 88 PWM frequency R/W 89 Controller Status R Only 8A Controller Model R Only AX3500 Motor Controller User’s Manual 155 Serial (RS-232) Controls and Operation TABLE 26. Runtime R/W Parameters list Location Function R/W 8B Current Amps limit 1 R Only 8C Current Amps limit 2 R Only Important Notice: Do not write in the locations marked as Read Only. Doing so my cause Controller malfunction. Operating Modes Registers Address: Access: Effective: ^80 - Channel 1 ^81 - Channel 2 Read/Write Instantly Modifying the bits in the Operating Mode registers will change the controller’s operating modes on-the fly. Changes take effect at the controller’s next 16ms iteration loop. After reset, these bits get initialized according to the configuration contained in Flash. Values are in Hexadecimal.Example: 00000101 = Hex 05 TABLE 27. Operating Modes Register Definition Bit Function 7 to 3 Not Used 2 0: Open Loop 1: Closed Loop (when in Speed Mode) 1 0: Speed Mode 1: Position Mode 0 0: Analog Feedback 1: Encoder Feedback Read/Change PID Values Address: Access: Effective: ^82 - P1 ^83 - I1 ^84 - D1 ^85 - P2 ^86 - I2 ^87 - D2 Read/Write Instantly The Proportional, Integral and Derivative gain for each channel can be read and changed onthe-fly. This function also provides a mean for setting different PID values for each channel. 156 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Reading & Changing Operating Parameters at Runtime Actual Gain value is the value contained in the register divided by 8. Changes take effect at the controller’s next 16ms iteration loop. After reset, these bits get initialized according to the configuration contained in Flash. PWM Frequency Register Address: Access: Effective: ^88 Read/Write Instantly The controller’s default 16kHz PWM Frequency can be changed to a higher value in fine increments. This feature may be used to reduce the interference in case the controller’s PWM frequency harmonics are too close to the radio receiver’s frequency. The value can be changed at any time and takes effect immediately. The frequency is: 15,625 Hz * 255 / Register Value The controller’s default frequency provides the best efficiency and should be changed only if absolutely required and only if operating the controller in RS232 or Analog modes. Changes to the PWM frequency will affect the RS232 watchdog timer and PID may need re-tuning. The controller automatically reverts to the default 16kHz PWM frequency after reset. Controller Status Register Address: Access: Effective: ^89 Read Only Instantly The Controller Status Register can be polled at any time to see if there is a pending fault condition. Any one bit set will cause the controller to turn off the Power Output stage. Conditions marked as Temporary mean that the controller will resume operation as soon as the fault condition disappears. Permanent conditions will cause the controller to remain off until it is reset either by cycling power, pressing the reset button, or sending the %rrrrrr command. TABLE 28. Controller Status Register Definition Bit Fault Condition Effect 0 Overvoltage Temporary 1 Overtemperature Temporary 2 Undervoltage Temporary 3 Manually Forced MOSFETs Off Temporary 4 Unused 5 Confirmed Short Circuit Permanent 6 Confirmed Encoder Error Permanent 7 Emergency Stop Pressed Permanent AX3500 Motor Controller User’s Manual 157 Serial (RS-232) Controls and Operation Controller Identification Register Address: Access: Effective: ^8A Read Only Instantly This register may be used to query the Controller’s model and some of its optional hardware configurations. TABLE 29. Controller Identification Register Definition Bit Model or Function 0 AX500 1 AX1500 2 AX2500 3 AX3500 4 Unused 5 Encoder Present 6 Short Circuit Detection Present 7 Unused Current Amps Limit Registers Address: Access: Effective: ^8B - Channel 1 ^8C - Channel 2 Read Only Instantly These registers can be polled to view what the Amps limit is at the current time. This limit normally is the one that is preset by the user except when the controller is operating at high temperature, in which case the allowable current drops as temperature rises. See “Temperature-Based Current Limitation” on page 44. To convert the register value in Amps, divide the reading by 2. 158 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 RS232 Encoder Command Set RS232 Encoder Command Set The Encoder module responds to a dedicated set of commands and queries. The serial port setting and basic command format is identical to this for all other functions of the controller as described in “Serial (RS-232) Controls and Operation” on page 135. Read Encoder Counter Description: Read the value of the Encoder counter(s). The number is a signed 32 bit number that may range from -2,147,836,648 to +2,147,836,647. The value is output in Hexadecimal format of value 80000000 to 7FFFFFFF respectively. To speed up communication, only the significant digits are sent in response to a counter query. For example, if the counter contains the value +5 (which is the same number in decimal and hex), the response to the query will be 5 and not 00000005. The formatting algorithm takes into account the number’s sign. Details on the data format are given in section Counters’ values can be read as Absolute or Relative. An Absolute counter read will return the full counter value after every read query. In a Relative counter read, the counter value is immediately cleared immediately after being read so that the next read query returns the new number of counts since the last time the counter was read. Additionally, in a few of the query modes, the Encoder module returns the sum for both counters. This is useful for measuring the average travelled distance by the right and left wheels of a robotic vehicle. Syntax: ?q or Qn Where n= 0: Encoder 1, Absolute 1: Encoder 2, Absolute 2: Sum of Encoders 1 and 2, Absolute 4: Encoder 1, Relative 5: Encoder 2, Relative 6: Sum of Encoders 1 and 2, Relative Reply: nnnnnnnn Where: nnnnnnnn = counter value using 1 to 8 Hex digits. See “Counter Read Data Format” on page 167 for format description Examples: ?Q0 ?Q5 Read Encoder 1, Absolute Read Encoder 2, Relative Set/Reset Encoder Counters and Destination Registers Description: Set one or both counters to zero or a user-defined value. The value is a signed 32 bit number that may range from -2,147,836,648 to +2,147,836,647 (Hexadecimal format of value 80000000 to 7FFFFFFF respectively. AX3500 Motor Controller User’s Manual 159 While resetting is a single step command, setting the counters to a non-zero value requires two steps: 1- load a 4 byte buffer (32-bit) with the desired value. 2- Transfer the buffer’s content to the counter(s). Loading the buffer can be done using the commands described in “Read / Modify Encoder Module Registers and Parameters” on page 162. The buffer will also be altered after a Counter Read command, in which case it will contain the last read counter value. Syntax: !q or !Qn Where n= 0: Reset Encoder 1 counter 1: Reset Encoder 2 counter 2: Reset both Encoder counters 4: Set Encoder 1 counter with value in buffer 5: Set Encoder 2 counter with value in buffer 6: Set both Encoder both counters with value in buffer 7: Set Encoder 1 destination register with value in buffer 8: Set Encoder 2 destination register with value in buffer Reply: Examples: !Q2 !Q5 + if command was properly received and executed - if an error occurred Reset both counters Load value contained in buffer into counter 2 ?Q0, followed by !Q1 Read counter 1 and copy its value into counter 2 Read Speed Description: This query will cause the controller to return the speed computed by the Encoder module. The values are signed Hexadecimal numbers ranging from -127 to +127. The -127 value represents the maximum RPM in the reverse direction. +127 represents the maximum RPM in the forward direction. The relation of this relative number and the actual, absolute RPM value depends on the encoder’s resolution and a user programmable Time Base. See “Using the Encoder to Measure Speed” on page 84 for a detailed discussion. Syntax: ?z or ?Z Reply: nn mm Where: nn = speed 1 value mm = speed 2 value Notes: The command returns a signed hexadecimal number where 0 to +127 is represented by 00 to 7F, and -1 to -127 is represented by FF to 80 respectively. The hexadecimal format is intended to be deciphered by a microcontroller. When exercising the controller manually, you may use the Decimal to Hexadecimal conversion table on page 171. 160 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 RS232 Encoder Command Set Read Distance Description: This query will cause the controller to return the distance between the current position and the value in the destination register. The values are signed Hexadecimal numbers ranging from -127 to +127. The -127 value represents the relative distance according to the formulas described in “Using the Encoder to Track Position” on page 85. Syntax: ?d or ?D Reply: nn mm Where: nn = distance 1 value mm = distance 2 value Notes: The command returns a signed hexadecimal number where 0 to +127 is represented by 00 to 7F, and -1 to -127 is represented by FF to 80 respectively. The hexadecimal format is intended to be deciphered by a microcontroller. When exercising the controller manually, you may use the Decimal to Hexadecimal conversion table on page 171. Read Speed/Distance Description: This query is will cause the controller to return either the speed or the distance computed by the Encoder module, depending on the operating mode that is selected. This command is similar to either of the two previous ones, except that it is read from a different location inside the controller and is a filtered value that smoothened abrupt changes. Syntax: ?k or K Reply: nn mm Where: nn = speed 1 or distance 1 value mm = speed 2 or distance 2 value Read Encoder Limit Switch Status Description: This query will cause the controller to return the status of the four optional Encoder limit switches. The returned value is a two-digit (8-bit) Hexadecimal number of which the each of the 4 least significant bit represents one of the hardware switches. Note that for this function to work, limit switches must be connected to the encoder module using the special wiring diagram show in “Wiring Optional Limit Switches” on page 82. If no limit switches are present, this query will return the logic levels of each of the encoder’s quadrature outputs, which in most cases is not relevant information. Syntax: ?w or ?W AX3500 Motor Controller User’s Manual 161 Reply: 0n Where: n = switch status The relationship between the value of n and the switch status is shown in the table below. Extracting the status of a given switch from this number is easily accomplished in software using masking. TABLE 30. Reported value and switch status relationship Switch Switch n Value n Value 4 3 2 1 4 3 2 1 0 0 0 0 0 1 0 0 0 1 8 1 0 0 0 9 1 0 0 1 2 0 0 1 0 A 1 0 1 0 3 0 0 1 1 B 1 0 1 1 4 0 5 0 1 0 0 C 1 1 0 0 1 0 1 D 1 1 0 1 6 0 1 1 0 E 1 1 1 0 7 0 1 1 1 F 1 1 1 1 Note that the 0 and 1 levels represent a Closed Switch and Open Switch status, respectively. Read / Modify Encoder Module Registers and Parameters Description These commands make it possible to examine and change parameters that are stored in the Encoder’s module MCU RAM. While this command provides unrestricted access to up to 256 memory locations, a small number of these locations should never be read or altered. Parameter address and returned values are two digit Hexadecimal numbers (8-bit). Important Note Command character has been changed from “$” to “*” starting in version 1.7 of the controller firmware. Read parameter 162 Syntax: *mm Reply: DD Where mm= address location of parameter DD= parameter value AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 RS232 Encoder Command Set Example: *84 01 Read value of parameter at address hex 84 Controller replies, value is 01 Modify parameter Syntax: *mm nn Reply: + if command was executed successfully - if error Where mm= parameter address nn= new parameter value Examples: *84 03 Store 03 into parameter at address hex 84 Notes: All parameters and values are expressed with 2 hexadecimal digits. The table below lists maps the few relevant parameters that can be accessed using this command. TABLE 31. Address Parameter Description Size Access 84 Encoder Hardware ID Code 1 byte Full 85 Switches Status 1 byte Full 86 Speed or Distance 1 (depending on operating mode) 1 byte Full 87 Speed or Distance 2 (depending on operating mode) 1 byte Full 88 Counter Read/Write Mailbox MSB (bits 31 to 24) 89 Counter Read/Write Mailbox (bits 23 to 16) 4 bytes Full 8A Counter Read/Write Mailbox (bits 15 to 8) 8B Counter Read/Write Mailbox LSB (bits 7 to 0) 8C Counter 1 MSB (bits 31 to 24) 8D Counter 1 (bits 23 to 16) 4 bytes Limited 8E Counter 1 (bits 15 to 8) 8F Counter 1 LSB (bits 7 to 0) 90 Counter 2 MSB (bits 31 to 24) 91 Counter 2 (bits 23 to 16) 4 bytes Limited 92 Counter 2 (bits 15 to 8) 93 Counter 2 LSB (bits 7 to 0) 94 Destination Register 1 MSB (bits 31 to 24) 95 Destination Register 1 (bits 23 to 16) 4 bytes Full 96 Destination Register 1 (bits 15 to 8) 97 Destination Register 1 LSB (bits 7 to 0) AX3500 Motor Controller User’s Manual 163 TABLE 31. Address Parameter Description 98 Destination Register 1 MSB (bits 31 to 24) 99 Destination Register 1 (bits 23 to 16) Size Access 4 bytes Full 9A Destination Register 1 (bits 15 to 8) 9B Destination Register 1 LSB (bits 7 to 0) 9C Distance 1 (when Position Mode enabled) 1 byte Full 8D Distance 2 (when Position Mode enabled) 1 byte Full 86 Speed 1 1 byte Full 87 Speed 2 1 byte Full A2 Time Base for speed computation of Encoder 1. Multiply this number by 256us to obtain the actual Time Base period. 1 byte Full A3 Time Base for speed computation of Encoder 2. Multiply this number by 256us to obtain the actual Time Base period. 1 byte Full A4 Encoder threshold level (see “Voltage Levels, Thresholds and Limit Switches” on page 81 1 byte Full A5 Distance divider 1 byte Full A6 Mode Selection 1 byte Limited A8 to AF Pulse width on RC1 to RC8 outputs 1 byte Full Important Warning Do not alter any other area locations, as this may cause program execution failure inside the encoder module. Register Description Encoder Hardware ID code Address: *84 Returns a 4-bit number identifying the encoder module hardware version and the status of two on-board jumpers. For Roboteq use only. Switch Status Address: *85 Returns a 4 bit number (4 least significant bits of the byte), each representing the state of one of the limit switches when installed. The ?W command described at “Read Encoder Limit Switch Status” on page 161 is a preferred method for reading this information. 164 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Register Description Speed or Distance 1 or 2 Address: *86 - Channel 1 *87 - Channel 2 These two registers contain either the measured speed or the measured distance. Whether speed or distance information is returned depends on the settings contained in the Mode register described at. This information is returned using the ?p query (see “Query Analog Inputs” on page 145). Counter Read/Write Mailbox Address: *88 - Most Significant Byte *89 *8A *8B - Least Significant Byte Since the counters are 32-bits wide and accesses are 8-bit wide, it would normally take four separate accesses to fully read or write any of the counters. If the motors are running and the counter is changing in-between these accesses, inaccurate data will be either read or written. Therefore a two-step process is implemented for accessing the encoder’s counters: for loading a new value in the counter, the value must first be loaded in the mailbox. It is then transferred in a single step using a command. When reading a counter, a read command is sent to the encoder module which then copies the counter value into the mailbox. The mailbox system can be used in the same way for reading and writing the destination register. In practice, reading a counter is done by a single command described in “Read Encoder Counter” on page 159. This command will perform the steps above and output the selected counter value. Writing a user-defined value into a counter or destination register requires that the value be loaded in the mailbox using the steps defined in “Read / Modify Encoder Module Registers and Parameters” on page 162, and then that of one of the commands described in “Set/ Reset Encoder Counters and Destination Registers” on page 159 be issued. Counter 1 and 2 Address: *8C - Most Significant Byte Counter 1 *8D *8E *8F - Least Significant Byte *90 - Most Significant Byte Counter 2 *91 *92 *93 - Least Significant Byte These two 32-bit (4-bytes) registers are the actual counters. As discussed above, they should not be accessed directly, as their value may fluctuate between the four accesses needed to read or write a complete 32-bit counter. Destination Register 1 and 2 Address: *94 - Most Significant Byte Destination 1 *95 AX3500 Motor Controller User’s Manual 165 *96 *97 - Least Significant Byte Address: *98 - Most Significant Byte Destination 2 *99 *9A *9B - Least Significant Byte These two 32-bit (4-bytes) registers are used to store the desired destination when the controller is used in position mode. These registers should always be set using the mailbox mechanism described above. See “Using the Encoder to Track Position” on page 85 for a complete description of the position mode. Distance 1 and 2 Address: *9C - Channel 1 *9D - Channel 2 These registers contain a signed 8-bit value (-127 to +127) that represents the distance between the current counter position and the desired destination. This number is computed using a formula described in section “Using the Encoder to Track Position” on page 85. Speed 1 and 2 Address: *9E - Channel 1 *8F - Channel 2 These registers contain a signed 8-bit value (-127 to +127) that represents the motor speed relative to a maximum speed, which in turn depends on the number of encoder counts and time base settings as described in “Using the Encoder to Measure Speed” on page 84. Time Base 1 and 2 Address: *A2 - Channel 1 *A3 - Channel 2 These registers contain the timing information for measuring the speed. See “Using the Encoder Module to Measure Distance” on page 84 for a detailed description. Encoder Threshold Address: *A4 This register is not used in the AX3500 as threshold is fixed at 2.5V in this model. See “Voltage Levels, Thresholds and Limit Switches” on page 81 for a detailed description. Distance Divider Address: *A5 This registers contain the divider ratio that is applied to the difference between the current position and destination. See “Using the Encoder Module to Measure Distance” on page 84 for a detailed description. 166 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Counter Read Data Format RC Pulse Outputs Activation Address: *A5 to *AF The AX3500 has 8 pulse output for commanding standard RC servos or additional controllers. The pulse width for every channel can only be changed using simple RS232 commands. Reading and changing the pulse width is done by accessing 8 parameters that are stored in the Encoder’s module MCU RAM. Parameter address and returned values are two digit Hexadecimal numbers (8-bit). The table below lists maps the RC registers that can be accessed using this command. Address RC Channel Default Value Size Access A8 RC Channel 1 Hex 7F (dec 127) 1 byte Read/Write A9 RC Channel 2 Hex 7F (dec 127) 1 byte Read/Write AA RC Channel 3 Hex 7F (dec 127) 1 byte Read/Write AB RC Channel 4 Hex 7F (dec 127) 1 byte Read/Write AC RC Channel 5 Hex 7F (dec 127) 1 byte Read/Write AD RC Channel 6 Hex 7F (dec 127) 1 byte Read/Write AE RC Channel 7 Hex 7F (dec 127) 1 byte Read/Write AF RC Channel 8 Hex 7F (dec 127) 1 byte Read/Write Counter Read Data Format When receiving a counter read query, the encoder module will output the value of its 32-bit counter. If all 32-bit are sent, this would require 8 ASCII digits to represent the value. A 32-bit counter can store over 2 billion counts in each direction. In practice, it will be rare that counts will be so large than only a partial number of the counter’s bits will be significant at any given time. In order to create a more efficient data stream on the controller’s serial port, a simple compression technique is implemented. The scheme eliminates all of the counter’s most significant bits if they are at 0 (for a positive count number) or F (for a negative count number). For example, if the counter value is Hex 00000015, the value 15 will be returned after a counter query. For negative numbers, a count value of -5 (which is FFFFFFFB in hex), the response to the query will be B. To distinguish between positive and negative numbers, the Encoder module will insert a 0 ahead of any number string starting with a digit value higher than 7 (i.e. 8 to F) to signify that the number is positive. For negative numbers, the Encoder module will insert an F AX3500 Motor Controller User’s Manual 167 ahead of any number string starting with a digit value lower than 8 (i.e. 0 to 7). The table below shows examples of this scheme as applied to various counter values. TABLE 32. Example counter values and RS232 output using a reduction scheme Decimal 32-bit Hex Controller Output +5 00000005 5 +250 000000FA 0FA -6 FFFFFFFA A -235 FFFFFF15 F15 +91,011,186 056CB872 56CB872 -7,986,091 FF862455 862455 When reading the counter value into a microcomputer, the reverse operation must take place: any output that is less than 8 digit long must be completed with a string of 0’s if the first digit is of value 0 to 7, or with a string of F’s if the first digit is of value 8 to F. The resulting Hex representation of a signed 32-bit number must then be converted to binary or decimal as required by the application. The burden of this extra processing is more than offset by the bandwidth relief on the controller’s serial port. Encoder Testing and Setting Using the PC Utility Extensive diagnostic, calibration, setting and testing support is provided in the Roborun PC utility. Basic instructions on how to install and run the PC utility can be found in “Using the Roborun Configuration Utility” on page 181 168 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Automatic Switching from RS232 to RC Mode Automatic Switching from RS232 to RC Mode In many computer controlled applications, it may be useful to allow the controller to switch back to the RC mode. This would typically allow a user to take over the control of a robotic vehicle upon computer problem. While the AX3500 can operate in either RC Radio or RS232 mode, the RS232 Data Input and RC Pulse Input 1 share the same pin on the connector. External hardware is, therefore, needed to switch this pin from the RS232 source or the RC Radio. The diagram in Figure 97 shows the external hardware required to perform such a switch. A third RC channel is used to activate a dual-throw relay. When the radio is Off, or if it is On with the channel 3 off, the relay contact brings the RS232 signal to the shared input. The second relay contact maintains the Power Control wire floating so that the controller remains on. When the RC channel 3 is activated, the relay turns On and brings the RC radio signal 1 to the shared input. The second relay contact brings a discharged capacitor onto the Power Control wire causing the controller to reset. Resetting the controller is necessary in order to revert the controller in the RC mode (the controller must be configured to default to RC mode). RC Activated Switch 4.7k RC3 RC Radio Power Control RC1 RC2 220uF RC1/RxData TxData RC2/InputF Computer RxData Controller TxData FIGURE 97. External circuit required for RS232 to RC switching The switching sequence goes as follows: Upon controller power on with Radio off: (or Radio on with RC ch3 off) • • Controller runs in RC mode (must be configured in RC mode) Computer must send 10 consecutive Carriage Returns. Controller enters RS232 mode Controller is on, Radio urns On with RC ch3 On • • Controller is reset, returning to RC mode Controller will output the continuous parameter strings on the RS232 output. Computer thus knows that RC mode is currently active. Computer sends Carriage Return strings to try to switch controller back in RS232 mode. Since the RS232 line is not connected to the controller, mode will not change. AX3500 Motor Controller User’s Manual 169 Controller is on, Radio is turned Off (or Radio On with RC ch3 Off) • • • Relay deactivates. RS232 is now connected to shared input. String of Carriage Returns now received by controller. Computer looks for OK prompt to detect that the RS232 mode is now active. Note: Wait 5 seconds for the capacitor to discharge before attempting to switch to RC mode if doing this repeatedly. Controller will not reset otherwise. Analog and R/C Modes Data Logging String Format When the controller is configured in R/C or Analog mode, it will automatically and continuously send a string of ASCII characters on the RS232 output. This feature makes it possible to log the controller’s internal parameters while it is used in the actual application. The data may be captured using a PC connected via an RS232 cable wireless or into a 15-pin PDA installed in the actual robot. Details on how to wire the FIGURE 1. Pin or locations onmodem the controller’s connector DB15 connector is described on page 125 for the R/C mode and on page 133 for the Analog mode. m Co St ar tD el im ite m r Co a n m d m 1 an O d ut pu 2 t O ut Po pu we tP r1 A na ow er lo g 2 A I n na 1 lo g I A m n2 ps A m 1 ps Te 2 m pe Te rat m ur pe e 1 ra tu M re ai n 2 Ba tt In Vo te rn lts al Vo En lts co de rS En pd d D /P el im os ite r This string is composed of a start character delimiter, followed by 13 two-digit Hexadecimal numbers representing 13 internal parameter values, and ending with a Carriage Return character. The figure below shows the structure of this string. : 00 11 22 33 44 55 66 77 88 99 AA BB CC FIGURE 98. ASCII string sent by the controller while in R/C or Analog mode The hexadecimal values and format for each parameter is the same as the response to RS232 queries described in page 142. Characters are sent by the controller at the rate of one every 8ms. A complete string is sent in 224ms. Data Logging Cables The wring diagrams shown in the figures below describe an easy-to-assemble cable assembly for use to create insertion points where to connect the PC for debug and data 170 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Decimal to Hexadecimal Conversion Table logging purposes. This cable has a 15-pin male connector and 3 15-pin connectors. The Front View Rear View Female to PC with RxData Only 4 1 3 2 Cut Wire Female to PC with Rx and Tx Data 1 Female to Application 1 Male to controller 1 1 FIGURE 99. ASCII string sent by the controller while in R/C or Analog mode male connector plugs into the controller. The application cable that would normally plug into the controller may now be plugged into one of the adapter’s female connector 2. The PC can be plugged into connector 3 or 4. Connector 3 has the Rx and Tx data lines needed for full duplex serial communication, thus allowing the PC to send commands to the controller. Connector 4 has the Rx line cut so that only a data flows only from the controller to the PC. This configuration is for capturing the data logging strings sent in the RC or Analog modes. Decimal to Hexadecimal Conversion Table The AX3500 uses hexadecimal notation for accepting and responding to numerical commands. Hexadecimal is related to the binary system that is used at the very heart of microcomputers. Functions for converting from decimal to hexadecimal are readily available in high level languages such as C. If the user intends to enter commands manually using the terminal emulation program, the conversion table in Table 33 can be used to do the translation. Note that the table only shows numbers for 0 to 127 decimal (00 to 7F hexadecimal). The AX3500’s speed commands are within this range. Table 34 shows the conversion values for numbers between 128 and 255 (unsigned) and between -1 and -128 (signed) TABLE 33. 0 to +127 signed or unsigned decimal to hexadecimal conversion table Dec Hex Dec Hex Dec Hex Dec Hex 0 00 32 20 64 40 96 60 1 01 33 21 65 41 97 61 2 02 34 22 66 42 98 62 3 03 35 23 67 43 99 63 4 04 36 24 68 44 100 64 AX3500 Motor Controller User’s Manual 171 TABLE 33. 0 to +127 signed or unsigned decimal to hexadecimal conversion table Dec Hex Dec Hex Dec Hex Dec Hex 5 05 37 25 69 45 101 65 6 06 38 26 70 46 102 66 7 07 39 27 71 47 103 67 8 08 40 28 72 48 104 68 9 09 41 29 73 49 105 69 10 0A 42 2A 74 4A 106 6A 11 0B 43 2B 75 4B 107 6B 12 0C 44 2C 76 4C 108 6C 13 0D 45 2D 77 4D 109 6D 14 0E 46 2E 78 4E 110 6E 15 0F 47 2F 79 4F 111 6F 16 10 48 30 80 50 112 70 17 11 49 31 81 51 113 71 18 12 50 32 82 52 114 72 19 13 51 33 83 53 115 73 20 14 52 34 84 54 116 74 21 15 53 35 85 55 117 75 22 16 54 36 86 56 118 76 23 17 55 37 87 57 119 77 24 18 56 38 88 58 120 78 25 19 57 39 89 59 121 79 26 1A 58 3A 90 5A 122 7A 27 1B 59 3B 91 5B 123 7B 28 1C 60 3C 92 5C 124 7C 29 1D 61 3D 93 5D 125 7D 30 1E 62 3E 94 5E 126 7E 31 1F 63 3F 95 5F 127 7F TABLE 34. +128 to 255 unsigned and -1 to -128 signed decimal to hexadecimal conversion table 172 UDec Dec Hex UDec Dec Hex UDec Dec Hex UDec Dec Hex -128 128 80 -96 160 A0 -64 192 C0 -32 224 E0 -127 129 81 -95 161 A1 -63 193 C1 -31 225 E1 -126 130 82 -94 162 A2 -62 194 C2 -30 226 E2 -125 131 83 -93 163 A3 -61 195 C3 -29 227 E3 -124 132 84 -92 164 A4 -60 196 C4 -28 228 E4 -123 133 85 -91 165 A5 -59 197 C5 -27 229 E5 -122 134 86 -90 166 A6 -58 198 C6 -26 230 E6 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Decimal to Hexadecimal Conversion Table TABLE 34. +128 to 255 unsigned and -1 to -128 signed decimal to hexadecimal conversion table UDec Dec Hex UDec Dec Hex UDec Dec Hex UDec Dec Hex -121 135 87 -89 167 A7 -57 199 C7 -25 231 E7 -120 136 88 -88 168 A8 -56 200 C8 -24 232 E8 -119 137 89 -87 169 A9 -55 201 C9 -23 233 E9 -118 138 8A -86 170 AA -54 202 CA -22 234 EA -117 139 8B -85 171 AB -53 203 CB -21 235 EB -116 140 8C -84 172 AC -52 204 CC -20 236 EC -115 141 8D -83 173 AD -51 205 CD -19 237 ED -114 142 8E -82 174 AE -50 206 CE -18 238 EE -113 143 8F -81 175 AF -49 207 CF -17 239 EF -112 144 90 -80 176 B0 -48 208 D0 -16 240 F0 -111 145 91 -79 177 B1 -47 209 D1 -15 241 F1 -110 146 92 -78 178 B2 -46 210 D2 -14 242 F2 -109 147 93 -77 179 B3 -45 211 D3 -13 243 F3 -108 148 94 -76 180 B4 -44 212 D4 -12 244 F4 -107 149 95 -75 181 B5 -43 213 D5 -11 245 F5 -106 150 96 -74 182 B6 -42 214 D6 -10 246 F6 -105 151 97 -73 183 B7 -41 215 D7 -9 247 F7 -104 152 98 -72 184 B8 -40 216 D8 -8 248 F8 -103 153 99 -71 185 B9 -39 217 D9 -7 249 F9 -102 154 9A -70 186 BA -38 218 DA -6 250 FA -101 155 9B -69 187 BB -37 219 DB -5 251 FB -100 156 9C -68 188 BC -36 220 DC -4 252 FC -99 157 9D -67 189 BD -35 221 DD -3 253 FD -98 158 9E -66 190 BE -34 222 DE -2 254 FE -97 159 9F -65 191 BF -33 223 DF -1 255 FF AX3500 Motor Controller User’s Manual 173 174 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 SECTION 16 Configuring the Controller using the Switches The AX3500 Speed Controller can be programmed to operate in many modes using a simple set-up procedure. Two buttons and a 7-segment LED display allow the user to examine and change these settings. Alternatively, the controller may be programmed using a PC connected to the AX3500 controller through the RS232 serial communication port. The new settings are then permanently stored in the controller’s Flash memory so that jumpers are not required, resulting in improved system reliability. Programming Methods There are three methods for programming the AX3500’s settings: • Using the controller’s built-in switches and display. This method is described in details in this chapter. • Using the PC-based Configuration Utility. See “Using the Roborun Configuration Utility” on page 181. • Sending RS232 commands manually. See “Automatic Switching from RS232 to RC Mode” on page 169. Programming using built-in Switches and Display Two switches and an LED display are provided to let you easily configure the controller in any of its many operating modes. Unlike the RS232 programming mode, the switches will let you configure the controller without the need for external hardware or special connectors. In this mode, the controller may be configured while installed on the robot without the need for special tools or a PC. Figure 100 shows the placement of the switches and display. AX3500 Motor Controller User’s Manual 175 Configuring the Controller using the Switches Program 2- When in Programing mode, display flashes parameter and its current value Set Reset 1- Press and hold for 10 seconds while resetting or powering up to enter Program mode 4- Press once to record value change (if any) and move to next parameter 3- Press to advance to next value for parameter. Press and hold Program and Set buttons together for 10 second while resetting or powering on to restore factory defaults FIGURE 100. Operating the controller’s buttons and display Entering Programming Mode Programming mode is entered by pressing and holding the Program button for 10 seconds after resetting the controller. The controller can be reset by powering it down and up or by pressing the Reset switch inserting a paper clip in the hole. While the button is pressed and until the controller enters the programming mode, the display will show the following steady pattern. After 10 seconds, the controller will enter the programming mode and flash a letter representing the first parameter in the list, followed by its numerical value. 176 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Programming using built-in Switches and Display Important Warning Be careful not to confuse the Set and Program button when entering the Programming Mode. Pressing and holding the Set button alone for 10 seconds after reset will cause the controller to enter in self-test mode. This will cause the motors to be turned On and Off according the test sequence described in the Self Test section of this manual. See“Self-Test Mode” on page 53. Changing parameters Pressing the Set button while in Programming Mode will cause the value of the parameter being inspected to be incremented by one. When the maximum valid value is reached, pressing Set again will cause the value to restart at 0. When the desired value is displayed, press the Program button to store it in the controller’s non-volatile memory. This will also cause the controller to display the next parameter and its current value. Note that a new parameter value will ONLY be saved if the Program button is pressed after the value has been changed with the Set button. Additionally, once you have pressed the Set button and begin changing a parameter’s value, it is not possible to cancel the change. If you wish to leave a parameter value unchanged after you have started changing it, you must press the Set button again several times until it goes back to its original value. Alternatively, you can reset or power Off the controller to prevent the new value to be recorded. The Special Case of Joystick Calibration When the Joystick parameter is selected (“J” and “-” flashing), pressing the Set key again will cause the controller to enter the Radio Control Joystick calibration sequence. Once the joystick calibration mode is entered, the display will flash “J” and “o”. With the R/ C receiver and transmitter On, move both joysticks to their full forward, full back, full left and full right positions a few times. This will cause the controller to capture the min. and max. joystick position values. Then move the joysticks to their central (rest) positions. Press the Program button to save these values in the controller’s Flash memory. The min. and max. values saved are these captured when the joystick was moved around. The center values saved are the position of the joystick as it was when Program was pressed. Note that once the Joystick calibration mode is entered, you must go through the complete calibration sequence described above. If the joysticks are not moved, incoherent data may be saved in the Flash causing the controller to malfunction in the R/C mode. If bad calibration data is saved in the Flash, try calibrating again by repeating the entire Joystick Programming sequence, otherwise you may restore the factory defaults (this will cause all parameters you have changed to be restored to their default values as well) The Joystick calibration operation is fully described in the R/C mode chapter. See “Left / Right Tuning Adjustment” on page 49. AX3500 Motor Controller User’s Manual 177 Configuring the Controller using the Switches Restoring factory defaults Should you, for any reason, require to reset the AX3500 controller to its factory default value, press and hold the Program and Set button together for 10 seconds while resetting the controller. All parameters, including Joystick limits, will be reset to their default values shown in the “Programmable Parameters List” on page 178 Exiting the Parameter Setting Mode Exiting the Programming Mode can be done only by pressing the Reset button or powering down the controller. The new parameters will be the ones in use after the controller is reset or first powered up. Programmable Parameters List The following table shows the AX3500’s controller parameters in the order they appear during programming, as well as their valid values. Important Notice The parameter table below is guaranteed to be accurate only if the controller software version number matches the one of this manual. See “Obtaining the Controller’s Software Revision Number” on page 23 for instructions on how to find this number. This manual is for software version 1.9b If the controller has a more current software revision, please download an updated version of this manual from the Roboteq web site at www.Roboteq.com. 178 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Programmable Parameters List This table shows only the parameters that can be programmed using the switches and display. Other less commonly used parameters exist and are only accessible and programmable using the Configuration Utility (page 181) or the RS232 commands (page 147). TABLE 35. Parameters accessible using the controller’s switches and display Order Letter 1 I Description Possible Values (default) See pages Input Command mode: (0) = R/C Radio mode (default) page 113 1 = RS232 full duplex, no watchdog page 135 2 = RS232 half duplex, with watchdog 2 C Motor Control mode 3 = Analog mode page 127 (0) = Separate A, B, speed control, open loop (default) page 42 1 = Mixed A & B, speed control, open loop For safety reasons, the modes below cannot be selected using the switches. 2 = Speed control on A, open loop. Position control on B 3 = A & B Position control 4 = Separate A, B, speed control, closed loop 5 = Mixed A & B, speed control, closed loop 6 = Speed control on A, closed loop. Position control on B 3 A Amp limit 0 = 15A page 44 1 = 22.5A 2 = 30A 3 = 37.5A 4 = 45A (5) = 52.5A default 6 = 60A Amps may be set with a finer resolution using the PC utility 4 S Acceleration 0 = very slow page 47 1 = slow (2) = medium (default) 3 = medium 4 = fast 5 = fastest Acceleration may be set with a finer resolution using the PC utility AX3500 Motor Controller User’s Manual 179 Configuring the Controller using the Switches TABLE 35. Parameters accessible using the controller’s switches and display Order Letter 5 U Description Possible Values (default) See pages Input switch function 0 = causes emergency stop page 51 1 = invert commands switch page 52 (2) = no action (default) 6 b Brake/Coast Not implemented 7 d R/C Joystick Deadband 0 = no deadband *** page 121 1 = 8% page 131 Analog Input Deadband (2) = 16% (default) 3 = 24% 4 = 32% 5 = 40% 6 = 46% 7 = 54% 8 E Exponentiation on channel 1 (0) = Linear (no exponentiation - default) page 122 1 = strong exponential 2 = normal exponential 3 = normal logarithmic 4 = strong logarithmic 9 F Exponentiation on channel 2 Same as E, above 10 L Left / Right Adjust (7) = no adjustment (default) page 49 0, 1, ..., 6 = -5.25%, -4.5%, ...,-0.75% 8, ..., D, E** = +0.75, ..., +4.5%, +5.25% 11 J Joystick calibration - = not calibrating page 122 o = in calibration mode *The coast function is not implemented in this revision of the software. The controller will only operate in brake mode. ** Values are in hexadecimal numbers where the decimal values 10, 11, 12... 15 are represented with the letters A, B, C... F. *** Deadband percent values shown are for R/C mode. For analog deadband values, see page 131. 180 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 SECTION 17 Using the Roborun Configuration Utility A PC-based Configuration Utility is available, free of charge, from Roboteq. This program makes configuring and operating the AX3500 much more intuitive by using pull-down menus, buttons and sliders. The utility can also be used to update the controller’s software in the field as described in “Updating the Controller’s Software” on page 199. System Requirements To run the utility, the following is need: • • PC compatible computer running Windows 98, Me, 2000, XP or Vista • An Internet connection for downloading the latest version of the Roborun Utility or the Controller’s Software • 5 Megabytes of free disk space An unused serial communication port on the computer with a 9-pin, female connector. If there is no free serial port available, the Configuration Utility can still run, but it will not be able to communicate with the controller. If the PC is not equipped with an RS232 serial port, one may be added using an USB to RS232 converter. Downloading and Installing the Utility The Configuration Utility is included on the CD that is delivered with the controller or may be obtained from the download page on Roboteq’s web site at www.roboteq.com. It is recommended that you use the downloaded version to be sure that you have the latest update. • • download and run the file robosetup.exe follow the instructions displayed on the screen AX3500 Motor Controller User’s Manual 181 Using the Roborun Configuration Utility • after the installation is complete, run the program from your Start Menu > Programs > Roboteq The controller does not need to be connected to the PC to start the Utility. Connecting the Controller to the PC The controller must be connected to the PC to use the Utility to perform any of the following functions: • to read the current parameters stored in the controller and display them on the computer • • • • to store new parameters in the controller to exercise the motors using your PC to update the controller’s software calibrate the Amps sensor If the controller is not connected, the Configuration Utility can run and be used to automatically generate the setting codes for manual entry. See “Encoder Setting and Testing” on page 188. Most computers have at least one, but often times two, serial ports. Look for one or two connectors resembling the illustration in Figure 102. FIGURE 102. Look for a 9-pin male connector on your PC If a serial port connector is already connected to something else, it may be possible to unplug the current device and temporarily connect the controller as long as the software operating the current device is not running. If no serial port is available on your PC, use an USB to RS232 adapter. Connect the provided serial cable to the controller on one end and to the PC on the other. Power the controller, preferably using the Power Control tab, with a 12 to 40V battery or power supply with 200mA of minimum output. Connect the thin black wire to the negative (-) terminal, and the Power Control input to the positive (+) of the power supply. The controller will turn On. If it doesn’t, verify that the polarity is not reversed. Upon powering On, the controller will display “no ctrl” if configured in the R/C mode or a steady pattern if configured in the RS232 mode. 182 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Roborun Frame, Tab and Menu Descriptions Roborun Frame, Tab and Menu Descriptions 2 1 5 4 3 FIGURE 103. Roborun screen layout The Roborun screen contains the four main set of commands and information frames described below: 1- Program Revision Number This is the revision and date of the Roborun utility. It is recommended that you always verify that you have the latest revision of the utility from Roboteq’s web site at www.roboteq.com 2- Controller and Communication Link Information This frame will automatically be updated with an indication that a free communication port was found and opened by the utility. If no free communication port is available on your computer, it will be indicated in this window. Try to select another port using the “Change COM Port” button or try to free the port if it is used by a different device and program. With the port open, Roborun will try to establish communication with the controller. If successful, this window will display the software revision, the revision date and a set of digits AX3500 Motor Controller User’s Manual 183 Using the Roborun Configuration Utility identifying hardware revision of the board inside the controller. New version of the AX3500 featuring the additional Analog Inputs 3 and 4 are automatically identified as Rev. B in this area of the screen. 3- Parameter Selection and Setting and Special Functions This is the program’s main frame and includes several types of tabs, each of which has several buttons, menus and other User Interface objects. These tabs and the functions they contain are described in detail in the following sections. Navigate from one set of commands to another by clicking on the desired tab. 4- File and Program Management Commands This frame contains a variety of buttons needed to load and save the parameters from and to the controller or disk. This frame also contains the button needed to initiate a software update to the controller. 5- View Controller Connector Pinout Clicking on this link will conveniently pop a window containing the Controller’s connector pinout. FIGURE 104. Roborun screen layout Getting On-Screen Help The Roborun buttons and fields are very intuitive and self-explanatory. Additional explanations and help is provided by means of ToolTips for several of command. Simply move the cursor to a button, tab or other gadget on the screen and a message box will appear after a few seconds. 184 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Loading, Changing Controller Parameters Loading, Changing Controller Parameters The first set of tabs allows you to view and change the controller’s parameters. These tabs are grouped according to the general type of parameters (Controls, Power Setting, and R/C Settings). When starting Roborun, this screen is filled with the default values. If the controller is connected to your PC, Roborun will automatically detect it and ask you if you wish to read its settings. The controller’s setting in the PC at can be read any other time by pressing the “Load from Controller” button. After changing a parameter, you must save it to the controller manually by pressing the “Save to Controller” button. Control Settings 1 2 3 4 5 6 FIGURE 105. Control modes setting screen The screen shown in Figure 105 is used to view and change the controller’s main control modes. Below is the list of the parameters accessible from this screen: 1- Controller Input: This pull down menu allows the user to select the RS232, R/C or Analog mode of operation. If the RS232 mode is selected, a check box will appear, allowing you to enable or disable the RS232 Watchdog. For more information on these modes, see • • • • “R/C Operation” on page 113 “Serial (RS-232) Controls and Operation” on page 135 “RS-232 Watchdog” on page 142 “Analog Control and Operation” on page 127 2- Motor Control Mode AX3500 Motor Controller User’s Manual 185 Using the Roborun Configuration Utility This pull down menu is used to choose whether the controller will operate in Separate or Mixed mode. For more information on these modes, see “Selecting the Motor Control Modes” on page 42. 3- Input Command Adjustment These pull down menus will let you select one of five conversion curves on each of the input command values. See “Command Control Curves” on page 48. 4- Emergency Stop or Invert Switch Select This pull down menu allows the selection of the controller’s response to changes on the optional switch input: Emergency Stop, Invert Commands, or no action. See “Emergency Stop using External Switch” on page 51 and “Inverted Operation” on page 52. 5- Effect of Digital Inputs This pull down menu allows the selection of the controller’s response to changes on either of the two digital inputs. See “Special Use of Accessory Digital Inputs” on page 52. 6- Output C Activation This check box will cause the controller to activate when power is applied to one or both motors. See “Activating Brake Release or Separate Motor Excitation” on page 51. Power Settings 1 2 3 FIGURE 106. Power settings screen The screen shown in Figure 106 is used to view and change the power parameters of the controller. 1- Amps limit This slider will let you select the max amps that the controller will deliver to the motor before the current limitation circuit is activated. See “User Selected Current Limit Settings” on page 44. Note that this limits the current flowing from the battery. The current flowing through the motor may be higher. See “Battery Current vs. Motor Current” on page 45. 186 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Loading, Changing Controller Parameters 2- Left/Right Adjust This slider will let you configure the controller so that it applies more power to the motors in one direction than in the other. See “Left / Right Tuning Adjustment” on page 49. 3- Acceleration Setting This slider will let you select one of seven preset acceleration values. The label on the right shows a numerical value which represents the amount of time the controller will take to accelerate a motor from idle to maximum speed. See “Programmable Acceleration” on page 47. Analog or R/C Specific Settings 1 2 FIGURE 107. Power settings screen The screen shown in Figure 107 slightly changes in function of whether or not the Analog Input mode is selected. If the Analog Input mode is selected on the main screen, then this page is used to set the Analog Deadband value. In the R/C mode, this page is used to view and change parameters used in the R/C mode of operation. None of these parameters has any effect when running the controller in RS232 mode. If the controller is configured in RS232 mode, some of these menus will turn gray but will remain active. 1- Deadband This slider will let you set the amount of joystick motion off its center position before the motors start moving. The slider will work identically in the R/C or analog mode, however, the % value will be different. See “Joystick Deadband Programming” on page 121 and “Analog Deadband Adjustment” on page 131. 2- Joystick Timing AX3500 Motor Controller User’s Manual 187 Using the Roborun Configuration Utility These fields are enabled only if the R/C mode is selected. These number areas will let you read and modify the R/C pulse timing information used by the controller. New values can be entered manually to create different capture characteristics. They are also useful for viewing the stored values after an automatic joystick calibration sequence. See “Joystick Calibration” on page 122 and “Automatic Joystick Calibration” on page 123. Closed Loop Parameters FIGURE 108. Closed Loop parameter setting screen The screen shown in Figure 108 is used to set the Proportional, Integral and Differential gains needed for the PID algorithm. These PID gains are loaded after reset and apply to both channels. Gains can be changed individually for each channels and on-the-fly using RS232 commands. These parameters are used in the Position mode (see page 89) and the Closed Loop speed mode (see page page 101). Encoder Setting and Testing Extensive diagnostic, calibration, setting and testing support is provided in the Roborun PC utility. Basic instructions on how to install and run the PC utility can be found in “Using the Roborun Configuration Utility” on page 181. Once the utility is up and running and the controller found and identified, click on the “Encoder” tab to bring up the Encoder configuration and setup screen show in Figure 109 below. 188 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Encoder Setting and Testing 1 4 6 2 5 3 7 7 FIGURE 109. Encoder setup and test screen on Roborun With this utility, the following actions can be accomplished: • • • • • Set and program the Encoder module’s parameters in EEPROM Activate the motors in each direction at variable speed View the measured encoder counts View the measured encoder speed View the status of the Limit Switches The screen is composed of the following buttons and displays: 1- Setting of the Encoder’s threshold level - Disabled on AX3500 2- Setting of the Time Base for speed computation 3- Setting Divider for computing relative distance 4- Measure and display speed and relative distance 5- Measure and display counter values 6- Detect and display optional limit switch status 7- Start/Stop communication with controller 8- Set motor speed and direction for testing Encoder Module Parameters Setting The Encoder module has four programmable parameters: Two Time Bases (one for each encoder), a Divider for computing relative distance, and the voltage threshold for discerning a 0 or 1 level at the encoder’s output. In the case of the AX3500, the threshold is fixed at 2.5V and cannot be changed. AX3500 Motor Controller User’s Manual 189 Using the Roborun Configuration Utility The Time Base parameter is used to compute the speed measured by the module. The measured speed is a relative number ranging from 0 to +/-127. The relationship between this relative speed number and the actual RPM is based on the Time Base value and the Encoder’s Pulses Per Revolution (PPR) value (see “Using the Encoder to Measure Speed” on page 84 for details) On this screen, changing the Time Base and PPR values automatically display the “Max RPM” values that can be measured with these settings. For example, with a default setting of 16 and 200 for the Time Base and PPR respectively, the maximum RPM values is 2188. This means that when the motors rotate at 2188 RPM, the measured relative speed is +127. If the motor spins faster, the speed is still reported to be +127. Note that the PPR value is not stored in the controller. It is used only in Roborun to convert relative speed into actual RPM. The Divider parameter is described in “Using the Encoder to Track Position” on page 85. The threshold level parameter and its operation is described in “Voltage Levels, Thresholds and Limit Switches” on page 81. Exercising the Motors A set of buttons and sliders is provided to start/stop communication with the controller and encoder. When communication is active, the screen will be updated with Encoder data. Moving the motor sliders will set the motors to the desired speed and direction. Viewing Encoder Data During operation, this screen will display the following information: • • • The instantaneous relative 0 to +/-127 speed value • • The Encoder counter values The instantaneous relative distance to destination (0 after reset) The actual speed computed from the measured relative speed value, encoder Time Base, and Encoder PPR. The PPR value must be entered manually on this screen every the utility is run, as it is not stored in the controller or on the PC. The status of the optional limit switches RC Output Testing A simple test and diagnostic function is provided in the Roborun PC utility. Basic instructions on how to install and run the PC utility can be found in “Using the Roborun Configuration Utility” on page 181. Once the utility is up and running and the controller found and identified, click on the “RC Out” tab to bring up the test screen show in Figure 109 below. 190 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Running the Motors FIGURE 110. RC Output exercising screen From this screen, moving the cursor on any of the 8 sliders will cause the PC to send RC positioning command to the controller via the RS232 port to its respective output. Running the Motors The Roborun utility will let you exercise and monitor the motors, sensors and actuators using a computer. This feature is particularly useful during development as you will be able to visualize, in real-time, the robot’s Amps consumption and other vital statistics during actual operating conditions. Figure 111 shows the Run Screen and its numerous buttons and dials. AX3500 Motor Controller User’s Manual 191 Using the Roborun Configuration Utility 1 7 4 3 2 6 8 5 FIGURE 111. Motor exercising and monitoring screen 1- Run/Stop Button This button will cause the PC to send the run commands to the controller and will update the screen with measurements received from the controller. When the program is running, the button’s caption changes to “Stop”. Pressing it again will stop the motors and halt the exchange of data between the PC and the controller. If another tab is selected while the program is running, the program will stop as if the Stop button was pressed. 2- Motor Power setting This sub-frame contains a slider and several buttons. Moving the slider in any direction away from the middle (stop) position will cause a power command to be issued to the controller. The value of the command is shown in the text field below the slider. The stop button will cause the slider to return to the middle (stop) position and a 0-value command to be sent to the controller. The + and ++ buttons will cause the slider to move by 1 or 10 power positions respectively. 3- Measurement These series of fields display the various operating parameters reported in real-time by the controller: The Amps field reports the current measured at each channel. The Peak Amps field will store the highest measured Amp value from the moment the program began or from the time at which the peak was reset using the Clr Peak button. Motor Amps is a calculated estimated value based on the batter amps and the current power level. See “Battery Current vs. Motor Current” on page 45. The Power field displays the power level that is actually being applied to the motor. This value is directly related to the motor command except during current limitation, in which 192 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Running the Motors case the power level will be the one needed to keep the Amps within the limit. Note that the display value is not signed and thus does not provide rotation direction information. The Ana fields contain the analog input values that are measured and reported by the controller. When the controller is in the position mode with Analog Feedback, the Ana1 and Ana2 fields will display the position sensed on the feedback potentiometer. When in speed mode, these fields display the measured speed by the tachometers. When the controller is in Analog command mode, the Ana 1 and Ana 2 show the vale of the command potentiometer, while the feedback is on Ana 3 and Ana 4. In all other modes, this field will display the value at the analog input pin. A small button next to this field will toggle the display caption, and change the conversion algorithm from raw analog, to volts or temperature. Note that in order to measure and display the external temperature or voltage, the proper external components must be added to the controller. See “Connecting External Thermistor to Analog Inputs” on page 65 and “Using the Analog Inputs to Monitor External Voltages” on page 66. The Enc field contains the speed or position (depending on the selected operating mode) measured by the Optical Encoder if enabled. The Temp field displays the temperature at the Output Power Transistors for each channel The Bat Volt field displays the main battery’s voltage (voltage applied at the Vmot tabs). The Ctrler Volt field displays the controller’s internal regulated 12V voltage. 4- Real-Time Strip Chart Recorder This chart will plot the actual Amps consumption and other parameters as measured from the controller. When active, the chart will show measurement during the last five seconds. Traces for most parameters can be displayed or hidden by clicking on the checkboxes found next to their numeric fields. 5- Transmit and Receive Data These two fields show the data being exchanged between the PC and the controller. While these fields are updated too fast to be read by a person, they can be used to verify that a dialog is indeed taking place between the two units. After the Start button is pressed, the Tx field will show a continuous string of commands and queries sent to the controller. The Rx field will display the responses sent by the controller. If this field remains blank or is not changing even though the Tx field shows that data is being sent, then the controller is Off or possibly defective. Try resetting the controller and pressing the Run/Stop button. These two fields are provided for quick diagnostic. Use the Console Tab for full visibility on the data exchange between the controller and the PC. 6- Input Status and Output Setting This section includes two check boxes and three color squares. The check marks are used to activate either of the controller’s two outputs. The color blocks reflect the status of the AX3500 Motor Controller User’s Manual 193 Using the Roborun Configuration Utility three digital inputs present on the controller. Black represents a “0”level. Green represents a “1” level. 7- Data Logging and Timer A timer is provided to keep track of time while running the motors. An additional set of buttons and displays are provided to operate a data logger. The data logger is fully described in the section that follows. 8- Joystick Enable Enable and configure a joystick. Logging Data to Disk While running the motors, it is possible to have Roborun capture all the parameters that were displayed on the various fields and charts and save them to disk. The log function is capable of recording 32,000 complete sets of parameters, which adds up to approximately 30 minutes of recording time. The figure below details the buttons and check boxes needed to operate this function. 1- Log Check Box When checked, Roborun will capture all the parameters and save them in local RAM. The data is not saved to disk until the “Save to Disk” button is pressed. Data is being captured for as long as the program is in the Run mode, whether or not a motor command is applied. 2- Clear Log This button can be pressed at any time to clear the local RAM from its content. Clearing the log also has the effect of resetting the timer. 3- Log Fill Status This gray text box indicates whether the local RAM log is empty, full or in-between. 4- Reset Timer button The timer automatically runs when the Run button is pressed and data is being exchanged with the controller, regardless of whether or not logging is activated. This button resets the timer. 5- Save Log to Disk button Pressing this button will prompt the user to select a filename and location where to copy the logged data. The file format is a regular text file with each parameter saved one after the other, separated by a coma. The file extension automatically defaults to .csv (coma separated values) so that the data can be imported directly into Microsoft Excel. The first 194 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Running the Motors line of the save file contains the Header names. Each following line contains a complete set of parameters. The Header name, order and parameter definition is shown in Table 36: TABLE 36. Logged parameters order, type and definition Parameter Header Data type/range Measured Parameter Seconds Integer Timer value expressed in seconds Command1 -127 to +127 Command applied to channel 1 Command2 -127 to +127 Command applied to channel 2 Power1 0 to 127 Amount of power applied to the output stage of channel 1 Power2 0 to 127 Same for channel 2 Ana 1, Speed 1, Pos 1 -127 to + 127 or Temp 1 -40 to +150 or Volt 1 0 to 55 Value of sensor connected on analog input 1. Data is automatically converted to the right value and format by Roborun according to the sensor that is being used. Ana 2, Speed 2, Pos 2 -127 to + 127 Temp 2 or -40 to +150 Volt 2 0 to 55 Amps1 0 to 255 Measured Amps on channel 1 Amps2 0 to 255 Measured Amps on channel 2 FET Temp1 -40 to +150 Measured Temperature on channel 1’s heatsink. FET Temp2 -40 to +150 Measured Temperature on channel 2’s heatsink. Batt Volt 0 to 55 Main Battery Voltage. Ctrl Volt 0 to 28.5 Internal 12V Voltage. Enc1 -127 to + 127 Measured Optical Encoder’s Speed or Position depending on selected operating mode Enc2 -127 to + 127 Same for channel 2 Same for channel 2 Connecting a Joystick Exercising the motors can easily be done using a Joystick in addition to the on-screen sliders. Simply connect a joystick to the PC and enable it by clicking in the Joystick check box in the PC utility. If the box is grayed out, the joystick is not properly installed in the PC. Click on the “Config Joystick” button to open a configuration screen and the joystick control panel. Joystick movement should automatically translate into Channel 1 and Channel 2 command values and make the sliders move. These commands are also sent to the controller. In the Config Joystick panel, the Joystick may be configured so that the X-Y channels are swapped and the direction for each axis reversed. It is strongly recommended that an USB rather than Analog joystick be used. AX3500 Motor Controller User’s Manual 195 Using the Roborun Configuration Utility A joystick test program name “Joytest” is automatically installed in the Start menu when installing the Roborun utility. This program may be used to further verify that the joystick is properly installed in the PC and is fully operational. Using the Console The console screen allows you to communicate with the controller using raw ASCII data. This function is very useful for troubleshooting when normal communication with Roborun cannot be established (e.g. “Controller not found”, no response to command changes, communication errors, ...etc.). The Roborun utility will let you exercise and monitor the motors, sensors and actuators using a computer. This feature is particularly useful during development as you will be able to visualize, in real-time, the robot’s Amps consumption and other vital statistics during actual operating conditions. Figure 111 shows the Console Screen and its various components. 3 1 2 4 5 FIGURE 112. Raw ASCII data exchange in Console 1- Terminal Screen This area displays the raw ASCII data as it comes out of the controller. After the controller is reset, it will output a prompt with the firmware’s revision and date. Then, if in the RC or Analog mode, the controller will output a continuous string of characters for data logging. If in RS232 mode, the controller will output an “OK” prompt and is ready to accept commands. 2- Command Entry This window is used to prepare up to 3 command string and send them by clicking on their associated buttons. The string is sent to the controller when clicking on the send button. Commands can only be sent when the controller has entered in RS232 mode. See “Controller Commands and Queries” on page 142 for the complete list of commands and que- 196 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Viewing and Logging Data in Analog and R/C Modes ries. See “RS232 Encoder Command Set” on page 159 for the list of Encoder related commands and queries. 3- Keep Watchdog Alive If the controller is in the RS232 mode with the watchdog enabled, then after 1 second of inactivity motors will be stopped if they were one and a “W” character will be sent to the terminal. When this checkbox is checked, Roborun will send a Null character to the controller on a regular basis so that the watchdog time-out is never reached. 4- Send Reset String Clicking this button while the controller is in RS232 mode, will cause the reset string to be sent to the controller. 5- Send 10 Carriage Returns Clicking this button will cause Roborun to send ten consecutive “Carriage Return” character. If the controller is configured in Analog or RC mode, the Carriage Returns will cause it to switch to RS232 mode until the controller is reset again. Viewing and Logging Data in Analog and R/C Modes When the controller is configured in R/C or Analog mode, it will automatically and continuously send a string of ASCII characters on the RS232 output. “Analog and R/C Modes Data Logging String Format” on page 170 shows the nature and format of this data. This feature makes it possible to view and log the controller’s internal parameters while it is used in the actual application. The data may be captured using a PC connected to the controller via an RS232 cable or wireless modem. When wired for R/C or Analog controls, the AX3500 will not be able to receive commands from the PC and the Roborun software will not recognize the controller as being present. However, when in the Run tab and the Run button activated, Roborun will be receiving the strings sent by the controller and display the various parameters in the right display box and chart. Loading and Saving Profiles to Disk It is possible to save the configuration parameters that are read from the controller or that have been set/changed using the various menus to the disk. This function allows easy recall of various operating profiles at a later time without having to remember or manually reset all the parameters that are used from one configuration to another. To save a profile to disk, simply click on the “Save Profile to Disk” button. You will then be prompted to choose a file name and save. Reading a profile from disk is as simple as clicking on the “Load Profile from Disk” button and selecting the desired profile file. The parameters will be loaded in each of their respective buttons, sliders and text fields on the various Roborun screens. The parameter will not be transferred to the controller until you press the “Save to Controller” button. AX3500 Motor Controller User’s Manual 197 Using the Roborun Configuration Utility Operating the AX3500 over a Wired or Wireless LAN The Roborun utility supports connection and operation of the AX3500 controller over a Wired or Wireless TCP/IP network. This feature makes it easy to tele-operate and monitor the controller across a lab or across the globe via Internet. To operate over the network, two computers are required, as show in Figure 113 below. The top computer is connected to the controller via its COM port. Both computers are connected to a TCP/IP network. Computer running Roboserver Controller Wired or Wireless 802.11 LAN Computer running Roborun Utility FIGURE 113. Operating the controller over a LAN The computer connected to the controller must run a communication server program named Roboserver. This program is automatically installed in the Start menu when installing the Roborun utility. This program’s function it to wait for and accept TCP/IP connection requests from the other computer and then continuously move data between the network and the COM port. When launched, the screen shown below appears. The second computer runs the Roborun utility. To establish contact with the server program, click on the “Change COM/LAN Port” button and enter the IP address of the second computer. Communication should be established immediately. When the two computers are connected, it will be possible to operate the motors and read the controller’s operating parameters in the Roborun Run window. 198 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Updating the Controller’s Software FIGURE 114. Roboserver screenshot when idle Note that it is not possible to use this configuration to change the controller’s parameters or update the controller’s software. Updating the Controller’s Software The AX3500’s operating software can be easily upgraded after it has left the factory. This feature makes it possible to add new features and enhance existing ones from time to time. Important Warning Updating the controller will cause all its parameters to reset to their default conditions. You should re-enter these parameters to the desired value prior to re-installing and using the controller. The upgrade procedure is quick, easy and error proof: 1- Connect the controller to the PC via the provided RS232 cable. 2- Apply a 12V to 40V power supply to the controller’s Ground and Power Control input . Leave VMot disconnected. 3- Launch the Roborun utility if it is not already running. Then click on the “Update Controller Software” button. 4- If the controller is On, Roborun will find it and prompt the selection of the new software file. It may happen that the controller is not responding properly and you may be asked to reset it while connected. 5- Press the “Program” button to start programming. Do not interrupt or cut the power to the controller while the new program is loading into Flash memory. 6- After a verification, you will be notified that the operation was successful and you will see the new software revision and date as reported by the controller. AX3500 Motor Controller User’s Manual 199 Using the Roborun Configuration Utility Notes: The Updating utility will automatically detect whether the new software is intended for the main or encoder’s MCU and program one or the other accordingly. It is a good idea to load the controller’s parameters into the PC and save them to disk prior to updating the software. After the new software in transferred to the controller, you can use the “Load Parameters from Disk” function and transfer them to the controller using the “Save to Controller” button. Updating the Encoder Software The Encoder Module has its own dedicated MCU and software in Flash memory. It may be updated using the Roborun Utility in the same manner as for updating the controller’s software (see “Updating the Controller’s Software” on page 199). Then select the new software file to download. The file’s content automatically identifies it as software for the Encoder MCU rather that the Controller’s MCU. Important Warning Do not reinstall the same firmware version as the one already installed in the encoder module. Creating Customized Object Files It is possible to create versions of the controller’s firmware with default settings that are different than those chosen by Roboteq. This capability can be used to improve system reliability in the unlikely, but not impossible, occurrence of a parameter loss in the controller’s non-volatile memory. Should such an event occur, the controller would revert to the defaults required by the application. 200 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Creating Customized Object Files FIGURE 115. Objectmaker creates controller firmware with custom defaults Creating a custom object file can easily be done using the Objectmaker utility. This short program is automatically installed in the Start menu when installing the Roborun utility. 1- Use the Roborun utility to create and save to disk a profile with all the desired parameter value. 2- Launch Objectmaker from the Start menu. 3- Select the latest official controller firmware issued by Roboteq. 4- Select the profile file that was created and saved earlier. 5- Select a revision letter. This letter will be added at the end of Roboteq’s own version identity number. 6- Click on the Create button and save the new customized object file. 7- Click on the Done button to exit the program. 8- Install the new object file in the controller using the Roborun utility. AX3500 Motor Controller User’s Manual 201 Using the Roborun Configuration Utility 202 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Mechanical Dimensions Mechanical Specifications SECTION 18 This section details the mechanical characteristics of the AX3500 controller. Mechanical Dimensions The AX3500 is delivered as an assembled and tested Printed Circuit Board. The board includes connectors for direct connection to the Optical Encoders and to the Radio, Joystick or microcomputer on one side. On the other side can be found Fast-on tabs for highcurrent connection to the batteries and motors. A heat sink is mounted beneath the board to help with the heat dissipation of the Power Transistors . 0.25" (6.3 mm) 0.35" (8.9mm) 0.57" (14.5mm) 0.1" (1.27mm) 0.3" (7.6 mm) 0.7" (17.8mm) 0.47" (12.0mm) 0.45" (11.4 mm) 0.25" (6.35mm) 1.15" (29.2mm) 1.34" (34.0 mm) 7.45" (174.0mm) FIGURE 116. AX3500 side view and dimensions AX3500 Motor Controller User’s Manual 203 Mechanical Specifications 6.75" (174.0mm) 0.40" (10.15mm) 0.45" (11.4mm) 0.160" (4.0mm) 0.15" (3.8mm) 0.15" (3.8mm) 0.120" (3.0mm) 0.15" (3.8mm) 0.15" (3.8mm) 1.25" (31.75mm) 0.35" (8.9mm) 0.3" (5.1mm) 2.10" (53.35mm) 0.3" (5.1mm) 0.3" (5.1mm) 1.09" (3.8mm) 1.63" (33.0mm) 0.15" (3.8mm) 0.2" (5.1mm) 0.2" (5.1mm) 1.01" (25.7mm) 2.0" (5.08mm) 4.20" (106.7mm) 0.6" (10.11mm) 0.3" (5.08mm) 0.35" (8.9mm) 0.15" (3.8mm) 0.15" (3.8mm) 0.15" (3.8mm) 4.83" (174.0mm) 0.45" (11.4 mm) FIGURE 117. AX3500 top view and dimensions Mounting Considerations The AX3500’s heatsink is located at the bottom of the board. This requires therefore that the board be mounted with spacers that are at minimum 0.6” (15mm). 0.6" (15mm) or longer spacer FIGURE 118. Use spacers to provide clearance for heatsink Thermal Considerations The AX3500 is equipped with an aluminum heatsink beneath the power transistors, ensuring sufficient heat dissipation for operation without a fan in most applications. When mounting the board, and if current is expected to be above 30A on average, ensure that there can be a natural or forced convection flow to remove the heat. Mounting the 204 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Attaching the Controller Directly to a Chassis board against a vertical surface as shown in the figure below will ensure a better natural convection flow and is, therefore, recommended. FIGURE 119. Mount the controller against a vertical surface to maximize convection flow For high current applications, it is possible that the controller may heat up faster and to a higher temperature than can be dissipated by the using natural convection alone. In these applications, you should ensure that air flow exists to remove the heat from the heat sink. In the most extreme use, you should consider using an external fan to circulate air around the controller. Attaching the Controller Directly to a Chassis The AX3500 can be attached to a metal chassis to improve heat dissipation. For this purpose the board has holes at the corners of the PCB, which can be used to fasten it to the chassis. Of course first it is necessary to remove the blue heat sink, which is mounted as standard. A total of 7 screws for the AX3500 are required, four on the corners and three in the heat sink area. In order to avoid that components leads sticking out the back of the PCB make contact with the chassis it is needed to interpose a metal bar (interposer) of thickness sufficient to distance the PCB from the surface of the chassis. AX3500 Motor Controller User’s Manual 205 Mechanical Specifications Note that the back of the PCB has large copper areas exposed just under the power MOS Board Thermal Pad Metal Interposer Metal Chassis Spacer FIGURE 120. Mount the controller without heatsink against a chassis area. It is critical that the interposer either is insulated (example: anodized aluminum) or a layer of thermal conducting - but electrically insulating - pad is used. Failure to do so will cause a short among the drains of the power MOS and the board will fail. Ordinary thermal grease will not act as an insulator. The interposer has to be planar so to ensure good thermal contact wit all power MOS; in alternative use thermal conducting pad that will fill all the voids between the board and the interposer. Precautions to observe Use plastic washers for the screws securing the board to the interposer similar to the ones originally installed. They will prevent the head of the screw from touching the heat sinks of the power MOS an from damaging the PCB and making contact with the copper layers underneath. Should the board be expected to experience heavy vibrations, then use plastic shoulder washer, which will keep the stem of the screws centered. Make sure the screws holding the corners do not bend the board, which remains flat. The screws that should hold securely the PCB are the ones in the power MOS area where the best contact is needed for efficient heat transfer. The four screws at the corners do not need to be tightened excessively and they also require a plastic washer to avoid damage to the PCB. It is a good practice to use nylon screws (8-32 minimum size) for electrical isolation and to allow some elasticity in case of vibrations. At the end of the assembly process check that there is no electrical continuity between any of the power contacts and the interposer/chassis with an ohm meter prior to applying power. 206 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007 Wire Dimensions Wire Dimensions The AX3500 uses Fast-on tabs for the power connections to the batteries and motors. These connectors are rated to support the controller’s maximum specified current. Mating connectors are widely available and use crimping techniques to secure the electrical wires. It is recommended that you use AWG10 wire for all power connections to ground, batteries and motors. Use connectors with a yellow plastic ring or shell as these have the correct opening for AWG 10-12 wire. The Power Control wire and its return Ground may be much thinner as they will never carry current in excess of a couple of milliamperes. Weight Controller weight is 7.5oz (220g) AX3500 Motor Controller User’s Manual 207 Mechanical Specifications 208 AX3500 Motor Controller User’s Manual Version 1.9b. June 1, 2007
advertisement
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project