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USER MANUAL
8500 SERIES DC ELECTRONIC LOADS
Models 8500, 8502, 8510, 8512, 8514, 8518, 8520,
8522, 8524 & 8526
Safety
The following general safety precautions must be observed during all phases of operation of this instrument.
Failure to comply with these precautions or with specific warnings elsewhere in this manual violates safety standards of design, manufacture, and intended use of the instrument. B&K Precision assumes no liability for the customer’s failure to comply with these requirements.
Verify that all safety precautions are taken. Note the instrument's external markings described under "Safety
Symbols".
This product is a Safety Class 1 instrument, which means it is provided with a protective earth terminal. To minimize shock hazard, the instrument chassis and cover must be connected to an electrical ground. The instrument must be connected to the AC line power through a grounded power cable, with the ground wire firmly connected to an electrical ground (safety ground) at the power outlet. Note: Any interruption of the protective (grounding) conductor or disconnection of the protective earth terminal will cause a potential shock hazard that could result in personal injury.
DO NOT OPERATE THE INSTRUMENT IN AN EXPLOSIVE ATMOSPHERE OR IN THE PRESENCE OF
FUMES OR FLAMMABLE GASES.
KEEP AWAY FROM LIVE CIRCUITS.
Operating personnel must not remove instrument covers. Component replacement and internal adjustments must be made only by qualified service personnel. Do not replace components with the power cable connected. Under certain conditions, dangerous voltages may exist even with the power cable removed. To avoid injuries always disconnect power, discharge circuits and capacitors, and remove external voltage sources before touching components.
DO NOT SERVICE OR ADJUST ALONE.
Do not try to perform internal service or adjustment unless another person capable of rendering first aid and resuscitation is present.
Safety Symbols
Note the instrument's external markings as follows:
Direct current
Alternating current
Both direct and alternating current
Protective earth (ground) terminal
WARNING
CAUTION
Caution (refer to accompanying documents)
The WARNING sign denotes a hazard. It calls attention to a procedure, practice, or the like which, if not correctly performed or adhered to, could result in personal injury. Do not proceed beyond a WARNING sign until the indicated conditions are fully understood and met.
The CAUTION sign denotes a hazard. It calls attention to an operating procedure, or the like, which, if not correctly performed or adhered to, could result in damage to or destruction of part or all of the product. Do not proceed beyond a CAUTION sign until the indicated conditions are fully understood and met.
8500 DC Load Series Version: November 4, 2008 Page 2 of 76
Table of Contents
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8500 DC Load Series Version: November 4, 2008 Page 4 of 76
I-set
OFF
CONFIG
OFF
Notation
Represents a key on the front panel. Note that some of these may be accessed in combination with the Shift key.
Annunciator, value, or message shown on the vacuum fluorescent display.
Menu item
Default menu item
8500 DC Load Series Version: November 4, 2008 Page 5 of 76
Quick reference
Model numbers covered by this document
●
●
●
●
●
●
●
●
●
●
The B&K Precision DC Loads covered by this manual are:
8500
8502
8510
8512
8514
8518
8520
8522
8524
8526
Unless otherwise noted, this document will refer to all of these instruments as the DC Load.
Instrument differences, where appropriate, will be noted.
Options and accessories
The items included with the instrument are:
1. Power cord
2. User manual
3. Installation CD with application software PV8500 and USB driver for optional TTL to USB adapter
4. TTL to RS232 serial converter IT-131
5. Test report
Optional accessories are:
6. rack mount kit IT-E151
7. TTL to USB serial adapter IT-132
Overview of instrument
The DC Load is a two terminal device that can be connected to DC sources. Here, a DC source is a
voltage that is always positive on the DC Load's + terminal referenced to the - terminal.
DC Electronic Loads are used for design, manufacturing and evaluation of DC power supplies, batteries, and power components. Other applications include fuel-cell and photovoltaic cell test. The
DC Load can operate under the following modes:
●
Draw a constant voltage from a DC source.
●
●
●
Draw a constant current from a DC source.
Draw a constant power from a DC source.
Present a constant resistance to the DC source (this behavior simulates a perfect resistor
8500 DC Load Series Version: November 4, 2008 Page 6 of 76
whose resistance doesn't change as a function of current or voltage).
triggering options allow the dynamic load behavior to be synchronized with other events.
A battery test mode is provided that will measure the ampere*hour (A*hr) characteristic of a battery.
Shorts can be simulated by either the front panel or custom programming. The DC source or other
components can be protected from excessive voltage, current, or power, which will cause the DC
Load to shut down if excessive levels or reverse polarity are detected.
Dynamic profiles and last instrument states can be stored in non-volatile memory.
to DC converters, and battery chargers.
Typical tasks
To perform the following tasks, consult the indicated sections
Task Section(s)
Manual on/off CC, CV, CW, or CR test
Timed on/off CC, CV, CW, or CR test
Triggered CC, CV, CW, or CR test
Constant current mode
Constant voltage mode
Constant power mode
Constant resistance mode
Constant current mode
Constant voltage mode
Constant power mode
Constant resistance mode
Timed operation
Constant current mode
Constant voltage mode
Constant power mode
Constant resistance mode
Triggering
Transient operation Constant load with one transient
Load with multiple transients Lists (dynamic condition)
Determine A*hr characteristic of battery Battery test
Run a sequence of tests Test files
Front panel
The following picture is the front panel for the 8510 DC Load. All models have the same front panel,
only the terminal section will vary based on the model.
8500 DC Load Series Version: November 4, 2008 Page 7 of 76
1
2
3 4 5 6
Button
1
2
3
4
5
6
Function(s)
16-character display shows voltage and current measurements.
Rotary knob. Turn to adjust a setting value. Press in to toggle between setting the currently-selected mode's value and reading the voltage and current, as shown in the above picture.
Power switch to turn the instrument on or off.
Numeric keypad:
Numeric entry keys.
Secondary key functions.
Keypad:
Enable/disable input.
Set up the current, voltage, power, and resistance modes.
Scroll through menus and options.
Input terminals. Depending on the model, you will have different types and numbers of input terminals.
Models 8500/8502 come with one plus and one minus terminal
Models 8510/8512 come with two positive and two negative terminals however each terminal is able to sink the maximum current supported by the instrument.
Thus, it is not necessary to double up on the wires when sinking a high current unless you wish to.
Models 8514/8518 also come with two positive and two negative terminals however it is required to double up on the wires when sinking a current exceeding 120A.
Models 852x come with a screw terminal block to connect the wires
8500 DC Load Series Version: November 4, 2008 Page 8 of 76
Standard display
The standard display for the instrument is the voltage and current at the instrument's terminals. You may press the △ or ▽ keys to see the instantaneous power and the mode's parameter setting.
Standard display
Front panel keys
POWER
1 2
A B
3 ESC
Tran
4 5 6 0
Store Recall S-Tran Menu
7 8 9
Local Battery Short Trigger
I-set
P-set
V-set
R-set
Shift Input on/off
ENTER
V-set
I-set
P-set
R-set
Shift + A
Shift + B
Shift + Store
Shift + Recall
Choose constant voltage mode.
Choose constant current mode.
Choose constant power mode.
Choose constant resistance mode.
Set the current mode's load value from the A value of the corresponding transient operation. See the Transient
operation section. This key does not work when the
TRAN annunciator is on.
Set the current mode's load value from the B value of the corresponding transient operation. See the Transient
operation section. This key does not work when the
TRAN annunciator is on.
Store the DC Load state in non-volatile memory. You may
store 25 different states.
Recall the DC Load state from non-volatile memory. You
may recall 25 different states.
8500 DC Load Series Version: November 4, 2008 Page 9 of 76
Shift + Menu
Shift + Short
Enter the instrument's menu system.
Turn short circuit on or off.
Shift + Tran Start or stop transient condition.
Shift + Trigger Causes an immediate trigger.
Shift + Battery
Shift + S-Tran
On/Off
Shift
Turn on or off battery testing function (measures battery capacity in ampere*hours).
Set transient condition parameters.
Turns DC Load ON or OFF (OFF is high impedance
state).
The shift key is used to select the alternate operation of a key, indicated by the word under the key.
△
▽
0 to 9
•
Esc
Enter
Scroll up key.
Scroll down key.
Enter the digits 0 to 9.
Decimal point.
The escape key. It can be used to exit keyboard entry or move up a level in the menu.
Enter the selected value or setting.
Rear panel
Your instrument's rear panel may look different from the following figure, but the same functionality will be present.
1
4 3 2
1
2
3
3 pin IEC320 AC input connector.
4 pin trigger and remote sensing connector.
9-Pin serial port interface connector. NOTE: This port's terminals utilize 5 volt
TTL logic signals. Do connect an RS-232 cable with standard RS-232 voltages on the cables connectors. Doing so may damage the instrument and is
8500 DC Load Series Version: November 4, 2008 Page 10 of 76
4
not covered by warranty.
Line voltage selection switch (110 VAC or 220 VAC)
Display annunciators
Annunciator
OFF
UNREG
CC
CV
CW
CR
PROT
TRAN
LIST
SENSE
LIMIT
ERROR
LINK
RMT
SHIFT
LOCK
Meaning
The load is off.
The input is unregulated.
Constant current mode.
Constant voltage mode.
Constant power mode.
Constant resistance mode.
Not used.
Transient operation is enabled.
List mode is initiated or running.
Remote sensing is on.
Not used.
An error has occurred.
The instrument is communicating with an IT-E131 or IT-E132 communications adapter. This annunciator will stay lit for approximately 3 seconds after the last remote communication with
Instrument is in the remote state. The only active key is the Local key. This is set with the 20H remote command (see the Remote
programming section).
The Shift key has been pressed.
The keyboard is locked by a password.
Menus
Use Shift + Menu to enter the menus. “Lvl” indicates the menu level, which is also indicated by the indentation of the menu item text. Scroll through the menu items using the △ and ▽ keys. Return to a previous menu level by pressing the Esc key. Words in the heavy font such as OFF indicate the default menu selection.
Lvl
1 CONFIG
Menu item Function
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3
3
2
3
3
2
3
3
2
3
3
2
3
3
2
3
3
2
3
3
2
3
3
2
3
3
Lvl
3
2
2
2
3
3
Menu item
INITIAL CONFIG
POWER-ON RECALL
ON
OFF
INPUT RECALL
ON
OFF
KEY SOUND SET
ON
OFF
KNOB LOCK SET
ON
OFF
SHORT CUT RECALL
ON
OFF
RANGE SELECT
ON
OFF
REMOTE SENSE
ON
OFF
ADC UPDATE RATE
HIGH
LOW
TRIGGER SOURCE
IMMEDIATE
EXTERNAL
BUS
CONNECT MODE
MAXTIPLEXING
SEPARATE
8500 DC Load Series
Function
Return instrument to factory default settings.
Power on state of instrument.
Remembers state at last power-down.
Does not remember state at last power-down.
Remember whether load was ON
If load was ON prior to turning the power off, the ON state will be resumed after power on. POWER-ON
RECALL must also be on for this to work.
After power on, the instrument will be in the OFF state.
Enable audible beep when key is pressed.
No sound when key is pressed.
Rotary knob is non-functional.
Rotary knob is functional.
Quickly recall a setup register by pressing a number key.
Allows quick recall of a setup by pressing the number key.
Pressing a number key does not recall a setup.
Change the precision of displayed values.
Allows the user to select the instrument's range, giving better voltage and/or current resolution. Press
Shift + △ or Shift + ▽ to toggle resolutions.
Current and voltage measurement resolution are fixed.
See the Remote sense section.
Remote sensing is on.
Remote sensing is off.
Set the rate at which the display is updated.
How the instrument is triggered.
Triggered from the Shift + Trigger key.
Triggered from a TTL high signal (longer than 5 ms) at the trigger connector on rear panel.
Triggered from a serial bus command.
Not supported with this hardware. (Should actually say
"multiplexing".)
Version: November 4, 2008 Page 12 of 76
Lvl
3
3
3
2
3
3
3
2
3
2
Menu item
BAUDRATE SET
4800
9600
19200
38400
COMM. PARITY SET
NONE
EVEN
ODD
ADDRESS SET
2
2 EXIT
1 SYSTEM SET
2 MAX CURRENT SET
2
2
KEY LOCK SET
MAX POWER SET
MAX VOLTAGE SET
2 VOLTAGE ON SET
3
2
3
2
3
4
2 VOLTAGE OFF SET
2
3
2 EXIT
1 LIST SET
MODE SET
FIXED MODE
LIST MODE
CALL LIST FILE
RECALL N
EDIT LIST FILE
CURRENT LIST
ONCE
8500 DC Load Series
Function
Set the serial bus connection speed.
Serial connection parity.
Set the instrument's address. Must be an integer between 0x00 and 0xFE inclusive.
Set the instrument's password to 1 - 4 digits. Press the
Enter key without any data entry to remove the password. If you accidentally locked the keyboard, follow instructions at the end of this manual, chapter “in case of trouble” to unlock the keypads.
Return to prior menu level.
Set the maximum allowed current. Exceeding this value will cause the load to shut off. This value also becomes the maximum current you can set.
Set the maximum allowed power. Exceeding this value will cause the load to shut off. This value also becomes the maximum power you can set.
Set the maximum allowed voltage. Exceeding this value will cause the load to shut off. This value also becomes the maximum voltage you can set.
Used to set an ON voltage threshold. See the Voltage
threshold section.
Used to set an OFF voltage threshold. See the
Voltage threshold section.
Return to prior menu level.
Lists are programmed sequences of load values.
Load characteristics set by front panel.
Load characteristics are dynamic and controlled by a list stored in memory.
Recall an existing list from nonvolatile memory.
N is list number.
Note that each list file has four lists, one for each operation mode (CC, CV, CW, CR).
List is executed once per trigger.
Version: November 4, 2008 Page 13 of 76
Lvl
4
4
3
4
4
2
3
2
4
3
4
4
3
Menu item
REPEAT
VOLTAGE LIST
ONCE
REPEAT
POWER LIST
ONCE
REPEAT
RESISTANCE LIST
ONCE
REPEAT
CALL TEST FILE
RECALL N
EDIT TEST FILE
2 LIST STORE MODE
3
3
3
3
8 X 120 STEPS
4 X 250 STEPS
2 X 500 STEPS
1 X 1000 STEPS
2 EXIT
1 LOAD ON TIMER
2 TIMER STATE
3 ON
3 OFF
2 TIMER SET
2 EXIT
1 EXIT
Function
List is repeatedly executed after the trigger is received.
List is executed once per trigger.
List is repeatedly executed after the trigger is received.
List is executed once per trigger.
List is repeatedly executed after the trigger is received.
List is executed once per trigger.
List is repeatedly executed after the trigger is received.
Recalls a stored test file (see Test files section).
N is file number.
See Test files section for more details.
Set how the nonvolatile memory is partitioned to store lists. You can choose between numerous short lists or fewer longer lists.
Return to prior menu level.
Enable a timed load.
When the load timer is enabled by this menu element, the load is turned on when the On/Off key is pressed.
After the set time period has elapsed, the load is turned off.
When the load is turned on via the On/Off key, the load stays ON indefinitely.
Set the time period from 1 to 60000 s for the load to be on.
Return to prior menu level.
Return to standard display.
8500 DC Load Series Version: November 4, 2008 Page 14 of 76
Models 8500 & 8502 (300 W)
Input rating
Parameter
Voltage
Current
Power
Specifications
8500
0 to 120 V
1 mA to 30 A
Parameter
CV Mode
Regulation
CC Mode
Regulation
Current Measurement
Voltage Measurement
300 W
8500
8500/8502 common characteristics
Range
8502
Accuracy
0.1 – 120 V
0.1-18 V
0.1 – 500 V
±(0.05%+0.02% FS)
±(0.05%+0.025% FS)
±(0.1%+0.1% FS) 0 – 3 A
0 – 30 A
0 – 3 A
0 – 30 A
0-120 V
0-18 V
0 – 3 A
0 – 15 A
0 – 3 A
0 – 15 A
0 – 500 V
±(0.2%+0.15% FS)
±(0.1% + 0.1% FS)
8500: ±(0.2%+0.15% FS)
8502: ±(0.2%+0.3% FS)
±(0.02% + 0.02% FS)
±(0.02% + 0.025% FS)
8502
0 to 500 V
1 mA to 15 A
Resolution
1 mV
10 mV
0.1 mA
1 mA
0.1 mA
1 mA
1 mV
10 mV
Models 8510/8512/8514/8518 (1200 & 2400 W)
Input rating
Parameter
Voltage
Current
Power
Parameter
CV Mode
Regulation
CC Mode
Regulation
Current Measurement
Voltage Measurement
8510
0 – 120 V
0 – 120 A
600 W
8512
0 – 500 V
0 – 30 A
8514 8518
0 – 120 V
0 – 240 A
1200 W
0 – 60 V
0 – 240 A
8510/8512/8514/8518 common characteristics
8510
0-12 A
0-12 A
Range
8512 8514
0.1-18 V
0.1 V to Vmax
0-3 A 0-24 A
0 – max Current
0-3 A 0-24 A
0 – max. Current
8518
Accuracy
±(0.05%+0.02% FS)
±(0.05%+0.025% FS)
±(0.1%+0.1% FS)
±(0.2%+0.15% FS)
±(0.1% + 0.1% FS)
±(0.2%+0.15% FS)
0 – 18 V
0 - Vmax
8510/8514:
(0.02% + 0.025% FS)
8512/8518:
(0.02% + 0.02% FS)
±(0.02% + 0.025% FS)
Resolution
1 mV
10 mV
1 mA
10 mA
1 mA
10 mA
1 mV
10 mV
8500 DC Load Series Version: November 4, 2008 Page 15 of 76
Models 8520/8522/8524/8526 (2400W & 5000W)
Parameter
Input rating
Voltage
Current
Power
8520 8522
0 – 120 V
0 – 240 A
2400 W
0 – 500 V
0 – 120 A
8524 8526
0 – 60 V
0 – 240 A
5000 W
0 – 500 V
0 – 120 A
Parameter
CV Mode
Regulation
CC Mode
Regulation
Current Measurement
Voltage Measurement
8520/8522/8524/8526 common characteristics
8520
0-24 A
0-12 A
8522
Range
8524
0.1-18 V
0.1 V to Vmax
0-12 A 0-24 A
0 – max Current
0-3 A 0-24 A
0 – max. Current
0 – 18 V
0 - Vmax
8526
Accuracy
±(0.05%+0.02% FS)
±(0.05%+0.025% FS)
0-12 A ±(0.1%+0.1% FS)
±(0.2%+0.15% FS)
0-12 A ±(0.1% + 0.1% FS)
±(0.2%+0.15% FS)
8522/8526:
(0.02% + 0.02% FS)
8520/8524:
(0.02% + 0.025% FS)
±(0.02% + 0.025%FS)
Resolution
1 mV
10 mV
1 mA
10 mA
1 mA
10 mA
1 mV
10 mV
All DC load models
Parameter
CR Mode Regulation
Input current ≥FS 10%
Input Voltage≥FS 10%
CW Mode Regulation
Input current ≥FS 10%
Input Voltage≥FS 10%
Power Measurement
Input current ≥ FS 10%
Input Voltage ≥ FS 10%
Battery testing function
Transition Mode common characteristics for all DC load models
Range Accuracy
0.1 -10 Ω ±(1%+0.3% FS)
10-99 Ω ±(1%+0.3% FS)
100-999 Ω
1K-4 KΩ
0-100 W
±(1%+0.3% FS)
±(1%+0.8% FS)
±(1%+0.1% FS)
100 W – max Power
0-100 W
±(1%+0.1% FS)
±(1%+0.1% FS)
Resolution
0.001 Ω
0.01 Ω
0. 1 Ω
1 Ω
1 mW
100 mW
1 mW
100-max Power ±(1%+0.1% FS) 100 mW
Input=0.1 V – 120 V Max measurement capacity= 999 A/H
Resolution =10 mA Timer range=1~60000 sec
Range of Frequency 0.1 Hz-1 kHz Frequency error rate <0.5%
NOTE: Specifications and information are subject to change without notice. Please visit www.bkprecision.com for the most current product information.
Environmental Conditions
This instrument is intended for indoor use in a pollution degree 2 environment. Operating environmental limits are as follows:
8500 DC Load Series Version: November 4, 2008 Page 16 of 76
Parameter
Humidity
Altitude
AC Line voltage
Operating temperature
Storage temperature
Specification
≤ 95% relative humidity, non-condensing
≤ 2000 m
220 AV±10% ,47~63 Hz
110 AV±10% ,47~63 Hz
0 – 40 ºC
-10 – 60 ºC
Internal Resistances
The internal resistances of the DC load models are less than or equal to the following values:
Model
8500
8502
8510
8512
8514
8518
8520
8522
8524
8526
Internal
Resistance(m Ω)
≤ 35
≤ 200
≤ 15
≤ 100
≤ 8
≤ 5
≤ 45
≤ 30
≤ 6.5
≤ 15
Operational power curve
The DC load's output follows a power curve illustrated below:
8500 DC Load Series Version: November 4, 2008 Page 17 of 76
The curved portion is where the dissipated power is at the rated power of the instrument (and is actually a hyperbolic shape). When you use the menu to set lower-than-maximum power or current, the operating region may look like the following:
Note the gap between the operating region and the current axis for lower voltages. More detail is described in the following section.
Low Voltage Characteristics
The following graphs show the voltage/current relationships for low voltages:
8500 DC Load Series Version: November 4, 2008 Page 18 of 76
Slew rate
The slew rate for each DC load varies from model to model. The variations are also dependent on the different regions measured for each individual load. In general, the slew rate for low current transitions, say 0 to 0.5 A, is significantly lower than slew rate for current transitions from 30 to 70 A.
The provided table below indicates measured slew rates based on the maximum range of current transition of the models are capable of. For example, model 8500's slew rate would be measured with current transition from 0 A to 30 A.
Note: The graph below illustrates slew rate measurements. In general, the indicated slew rates in the table below are measured based on the maximum current range each model is able to handle.
Between the 10% and 90% region, the slew rate can be measured by observing the steepest slope portion. The indicated measured time would be used to calculate the slew rate. Hence, the slew rate calculation is simply (rated max. current – 0 A) / T, where T is the measured time from 10% to
90% region and rated max. current is the specified maximum current of each load.
8500 DC Load Series Version: November 4, 2008 Page 19 of 76
As a reference, below is a table of slew rates for their respective models:
Model
8500
8502
8510
8512
8514
8518
8520
8522
8524
8526
8500 DC Load Series
Slew rate
0.5A/ S
0.5A/ S
1A/ S
0.5A/ S
1A/ S
1A/ S
1A/ S
1A/ S
1A/ S
1A/ S
Version: November 4, 2008 Page 20 of 76
Glossary
△
▽
A
B
Battery
CC
Condition
CR
CV
Constant resistance
Constant voltage
CW Constant power
Dynamic condition See Condition.
Enter
Esc
I-set
Knob click
Choose the indicated value or setting.
Stop current entry and go to previous menu level.
Configure the instrument for constant current mode.
Press the knob in until it clicks. This is an alternate method for changing settings.
Link
Up arrow key. Used to scroll through the menu or cause the temporary display of the alternate standard display.
Down arrow key. Used to scroll through the menu or cause the temporary display of the alternate standard display.
Value for first setting of transient mode.
Value for second setting of transient mode.
Select battery testing mode. See Battery test section.
Constant current
Steady state, transient, or dynamic. Steady state condition means the load mode is operated in a steady state. Transient condition means the load mode is switched between two values with user-selectable timing.
Dynamic means multiple levels and timings are available (and are gotten by using lists).
List
Local
Menu
Mode
Mode settings
On/Off
P-set
Power
This annunciator will light up when communications are coming in across the serial interface. It will stay lit for approximately 3 seconds after the last command was received.
A list is a stored sequence of test parameter and test duration values.
These are used for dynamic load profiles.
Returns control to the front panel.
Show the top level item of the instrument's menus.
Mode of operation of the instrument. The four modes are CC, CV, CW, and CR.
Parameter values for CC, CV, CW, and CR modes.
Manually toggle the instrument between its set mode and an infinite impedance state.
Configure the instrument for constant power mode.
Power switch to turn the instrument on and off.
8500 DC Load Series Version: November 4, 2008 Page 21 of 76
R-set
Recall
Remote sensing
S-Tran
Shift
Configure the instrument for constant resistance mode.
Recall instrument state from non-volatile memory.
Allows the instrument to measure the load power properly in case of large currents by sensing the voltage at the source, rather than at the instrument's terminals. This removes the effect of the resistance of long leads.
Set parameters (A, B, and transition times) for transient mode.
Shift key, which allows access to the functions written beneath the number keys.
Short
Store
Test file
Tran
Toggles between normal operation and a low resistance short.
Allows the user to save the instrument state in non-volatile memory.
A sequence of different test modes used for automated testing.
Set to transient condition.
Transient condition See Condition.
Trigger The key that causes an immediate trigger.
V-set
VFD
Configure the instrument for constant voltage mode.
Vacuum fluorescent display, the technology used for the instrument's display.
8500 DC Load Series Version: November 4, 2008 Page 22 of 76
Installation
Inspection
Items you should have received
When you open the box containing the instrument, you should find the following items:
2. Power cord
3. User manual
4. Installation CD with application software PV8500
5. TTL to RS-232 serial converter IT-131
6. Calibration report
Instrument location
This instrument is intended for indoor use in a pollution degree 2 environment. Please refer to the specifications table for the allowable environment operating limits.
Significant power may be dissipated in the DC Load, which includes one or more thermostatically-
operated fans. The fans draw air through the bottom and sides and exhaust it out the back. It is important to allow at least 25 mm (1 inch) of clearance on all sides of the instrument so adequate cooling airflow can be maintained.
CAUTION Do not block the fan exhaust at the rear of the load.
Outline Drawings
All dimensions are in millimeters (mm).
Models: 8500& 8502
8500 DC Load Series Version: November 4, 2008 Page 23 of 76
Models 8510, 8512, 8514 & 8518
Models 8520, 8522
8500 DC Load Series Version: November 4, 2008 Page 24 of 76
Models 8524 & 8526
Unit (mm)
8500 DC Load Series Version: November 4, 2008 Page 25 of 76
Model number
8500
8502
8510
8512
8514
8518
8520
8522
8524
8526
Dimensions in mm
215W×88H×355D
215W×88H×355D
429W×88H×355D
429W×88H×355D
429W×88H×355D
429W×88H×355D
444W×180H×539D
444W×180H×539D
444W×357H×539D
490W×357H×539D
Mass in kg
5.2
5.2
14
14
14
14
30
30
67
67
Bench operation
The 8500 DC Load is provided with a carrying handle. The following pictures demonstrate various
ways to use the handle.
The handle may be removed if desired. A rack mounting kit (IT-E151) is also available.
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First turn-on checkout
CAUTION
Ensure that the line voltage selector switch on the back panel is set to match your line voltage. Failure to do so could result in damage to the instrument.
Connect an appropriate IEC power cord to the DC Load and plug the power cord into an AC power
outlet. Ensure that nothing is connected to the INPUT terminals. Turn the instrument on by pushing the Power button in. The instrument should display SYSTEM SELFTEST , then display
0.00V 0.000A
. A small annunciator will display OFF in the upper left corner of the display. If you
do not see this display, please consult the In case of trouble chapter.
The following test will verify the DC Load can operate properly in constant current mode. Press the
I-set button (you may have to press it twice) and use the numeric keypad to set the current to 0.1 A.
To do this, press . (the decimal point), 1, Enter. Alternatively, you can adjust the current level with the knob, then click the knob or press Enter.
approximately 0.1 A of current flowing as shown by the instrument's ammeter and approximately 1 volt. The CC annunciator should be displayed, showing that the instrument is in the constant current mode.
The instrument's voltage display may read a bit less than the power supply's output -- this may be
due to a voltage drop in the wires connecting the power supply to the DC Load. Press the or
▽ keys to see the power that is being consumed by the load.
Press the V-set button (you may have to press it twice). Note the load is turned off. Set the power
well below the supply voltage level, e.g. 1 V. Press the On/Off key. Verify the proper voltage level
(1 V) is shown on the display. Press the △ or ▽ keys to see the power being dissipated.
Press the P-set button (you may have to press it twice). Note the load is turned off. Set the power level to 0.1 watt. Press the On/Off key. Press the △ or ▽ keys to verify that the power is about 0.1
8500 DC Load Series Version: November 4, 2008 Page 27 of 76
watt.
Press the R-set button (you may have to press it twice). Set the resistance to 100 Ω . Press the
On/Off key. Verify that the current is approximately the displayed voltage in V divided by 100.
You can cycle between the four modes by pressing the I-set, V-set, P-set, and R-set buttons. Note that the previously-set values are remembered.
If the instrument worked as explained above, you've demonstrated that the four operating modes of the instrument are working. Please refer to the next section for detailed operation instructions.
Operational introduction
There are four operational modes of the instrument: constant current, constant voltage, constant power, and constant resistance (we will abbreviate these as CC, CV, CW, and CR, respectively).
These are selected by the I-set, V-set, P-set, and R-set buttons, respectively. If you press a mode button different than the currently set mode, the load will be set to OFF and the newly selected mode's setting will be displayed for about 3 seconds. Pressing the same mode button again will prompt for the new constant value for the selected mode.
There are three operational conditions for the instrument in these modes: steady state, transient, and dynamic.
Condition Behavior
Steady state
Transient
Dynamic
The selected mode parameter is maintained at a constant value. For example, if you selected constant current mode and set the current value to 1 A, the instrument would maintain this current indefinitely when the load is ON .
There are two mode parameters and the load switches between these two settings with user-specified timing. An example of a transient load in constant resistance mode would be a load of 10 Ω for 1 second and 20 Ω for 3 seconds.
Similar to the transient condition, but capable of emulating more complex timedependent loads. The dynamic condition uses lists to specify the timedependent behavior.
Examples of the three conditions of operation are illustrated in the following diagram:
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Steady state
Transient
B
A
Dynamic
Repeat
Time
Power-on state
The default power-on instrument state is to not remember the instrument mode settings before the last power-down. If you wish to have the mode settings remembered across a power-down, powerup cycle, use the following keystrokes:
Key Display
Shift + Menu :CONFIG
Enter
▽
▽
Enter
▽
Enter
:INITIAL CONFIG
:INPUT RECALL
:POWER-ON RECALL
:OFF <DEFAULT>
:ON
:POWER-ON RECALL
Esc
Esc
:CONFIG
Standard voltage/current display
Constant current mode
In constant current mode, the DC load will sink a constant current, regardless of the voltage at its
terminals. To set up the DC Load to operate in constant current mode and in the steady state
condition, use the following keystrokes:
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Key
I-set
On/Off
△ or ▽
On/Off
Display
If you press this key after powering up and there is no currentlystored constant current value, you'll be prompted for the desired current level. If there was a current value already stored, it will be momentarily displayed and the instrument will be in CC mode. If you wish to change the current setting, press I-set again. The OFF annunciator will be displayed.
Turns the constant current load on. The CC annunciator will be on.
Momentarily display the power level and the set current value.
Turns the load off.
To operate the DC Load in CC mode in a transient condition, see the Transient operation section.
To operate the DC Load in CC mode in a dynamic condition, see the Lists section.
Constant voltage mode
In constant voltage mode, the DC load will cause a constant voltage to appear at its terminals. To
set up the DC Load to operate in constant voltage mode and in the steady state condition, use the
following keystrokes:
Key Display
V-set
On/Off
△ or ▽
On/Off
If you press this key after powering up and there is no currentlystored constant voltage value, you'll be prompted for the desired voltage level. If there was a voltage value already stored, it will be momentarily displayed and the instrument will be in CV mode. If you wish to change the voltage setting, press V-set again. The
OFF annunciator will be displayed.
Turns the constant voltage load on. The CV annunciator will be on.
Momentarily display the power level and the set voltage value.
Turns the load off.
To operate the DC Load in CV mode in a transient condition, see the Transient operation section.
To operate the DC Load in CV mode in a dynamic condition, see the Lists section.
Constant power mode
In constant power mode, the DC load will cause a constant power to be dissipated in the load. To
set up the DC Load to operate in constant power mode and in the steady state condition, use the
following keystrokes:
Key Display
P-set If you press this key after powering up and there is no currentlystored constant power value, you'll be prompted for the desired
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Key
On/Off
△ or ▽
On/Off
Display power level. If there was a power value already stored, it will be momentarily displayed and the instrument will be in CW mode. If you wish to change the power setting, press P-set again. The OFF annunciator will be displayed.
Turns the constant power load on. The CW annunciator will be on.
Momentarily display the power level and the set power value.
Turns the load off.
To operate the DC Load in CW mode in a transient condition, see the Transient operation section.
To operate the DC Load in CW mode in a dynamic condition, see the Lists section.
Constant resistance mode
In constant resistance mode, the DC load will behave as a fixed resistance value. To set up the DC
Load to operate in constant resistance mode and in the steady state condition, use the following
keystrokes:
Key Display
R-set
On/Off
△ or ▽
On/Off
If you press this key after powering up and there is no currentlystored constant resistance value, you'll be prompted for the desired resistance. If there was a resistance value already stored, it will be momentarily displayed and the instrument will be in CR mode. If you wish to change the resistance setting, press R-set again. The
OFF annunciator will be displayed.
Turns the constant resistance load on. The CR annunciator will be on.
Momentarily display the power level and the set resistance value.
Turns the load off.
To operate the DC Load in CR mode in a transient condition, see the Transient operation section.
To operate the DC Load in CR mode in a dynamic condition, see the Lists section.
Timed operation
The DC Load can be set to allow timed operation. When you turn the load on, it stays on for the
specified time, then turns itself off.
To set up timed operation, use the following keystrokes:
Key
Shift + Menu
△ △
Display
:CONFIG
:LOAD ON TIMER
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Key
Enter
Enter
▽
Enter
Enter
Esc Esc
Display
:TIMER STATE
Use arrow keys to set to :ON .
:TIMER SET
TIMER=XXXXXS Enter desired time interval. Valid values are
1 to 60000 seconds (1000 minutes).
:TIMER SET
Standard display
Now, when you turn a load on, it will stay on for the designated time, then turn off.
To turn off timed operation, enter the menu :CONFIG:LOAD ON TIMER:TIMER STATE and set it to
:OFF .
Changing display resolution
The DC Load has two ranges of current and voltage (see the specifications). You can enable higher
resolution for voltages and currents on the lower range. Enter the menu with Shift + Menu and set the menu element :CONFIG:RANGE SELECT to ON.
Increasing current resolution
sinking a current higher than the top end of the lower range, it will be reset to the top end of the lower range. To change back to the lower current resolution, press Shift + ▽ again.
Increasing voltage resolution
To increase the voltage resolution (and change to the lower range), press Shift + . You may see
OVERVOLTAGE message on the display if the voltage is too high. To change back to the lower voltage resolution, press Shift + △ again.
Short
When a test mode is on, you may press Shift + Short to emulate a short. This will draw maximum current from the DC supply in any of the four operation modes (CC, CV, CW, or CR). In CC, CV, or
CR mode, you may press Shift + Short to stop the short. The DC Load will return to its previous
operation. However, in CW mode, the short current will continue to be drawn; to stop the short, you must press the On/Off key
Note: When emulating a Short while in CV mode, the current software limit may trigger the DC load
Input to turn Off, provided the current limit is reached. This does not affect the programmed settings and the DC load will restore the previously programmed values once the Short condition is removed.
Battery test
The battery test feature measures the time it takes for a battery voltage to drop to a specified value
while drawing a constant current from the battery. When the voltage at the DC Load's terminals
reaches the specified voltage, the test is ended and the integrated current (i.e., charge supplied by
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the battery) in ampere*hours (A*hrs) of the battery is calculated and displayed. To run a battery test, follow these steps:
Key presses Display
I-set, enter current value with numerical keys, then press
Enter.
Shift + Battery
Set the DC Load to constant current mode and set the
current you want to draw from the battery. (You may have to press the I-set key twice to be able to set the current value.)
MIN VOLT= 0.10V
This indicates you're being asked for the voltage level where the battery test will be over.
Enter voltage level and press
Enter.
△ or ▽
When you press Enter, the test will start. The annunciator will be on.
CC
Shows the power level and the ampere*hours (A*hrs) accumulated so far.
When the battery voltage drops below the specified value, the test will turn off and you will see the OFF annunciator.
△ or ▽ Display the total charge delivered by the battery in ampere*hours (A*hrs).
Shift + Battery Turns battery testing mode off.
NOTE: you must make sure that you press Shift + Battery at the end of the test. Otherwise, the instrument will not respond to any key presses except △ or ▽.
Transient operation
The transient condition allows switching between two different load values. There are three different types of transient operation.
Continuous transient operation
In continuous transient operation, the load is continuously switched between two load values. An example is shown in the following figure:
10A
5A
2.0ms
3.0ms
Continuous Transient Operation
Note that this transient behavior works with any of the operation modes CC, CV, CW, or CR. Here are the keystrokes used to setup this continuous transient condition:
Keys
I-set
Display
Standard display of voltage and current (or, you'll be asked to enter a current value).
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Keys Display
Shift + S-Tran LEVEL A= X.XXXA
You are being prompted for the first current value.
Press the 5 key for 5 A.
Enter
Enter
Enter
Enters the 5 A value, then displays WIDTH A = X.XMS
. You're being prompted for the duration of the 5 A load -- press the 3 key for 3 ms.
Enters the 3 ms value, then displays LEVEL B= X.XXXA
. You are being prompted for the second current value. Press the 1 and 0 keys to enter
10 A.
Enters the 10 A value, then displays WIDTH B = X.XMS
. You're being prompted for the duration of the 10 A load -- press the 2 key for 2 ms.
Enter
Enter
Enters the 2 ms duration, then displays :CONTINUOUS , :PULSE , or
:TOGGLED . Use the △ or ▽ arrow keys to display :CONTINUOUS .
Returns to the standard display of voltage and current.
To activate this continuous transient condition, press Shift + Tran, then press On/Off. The load will begin switching between the two Tran values with the timing you entered.
Pulse transient operation
In pulse transient operation, the load operates at the A value that has been entered until a trigger is received. At the trigger, the load switches to the B value and stays at that level for the B timing value. Then the load switches back to the A value and stays there until another trigger is received.
Here's an example:
10A
5A TWD
10ms
TWD
10ms
TRIG TRIG
Pulsed Transient Operation
Here are the keystrokes needed to set up this example:
Keys Display
I-set Standard display of voltage and current (or, you'll be asked to enter a current value).
Shift + S-Tran LEVEL A= X.XXXA
You are being prompted for the first current value.
Press the 5 key for 5 A.
Enter Enters the 5 A value, then displays WIDTH A = X.XMS
prompted for the duration of the 5 A load. In the pulse mode of operation, this width is ignored, so enter any convenient value.
. You're being
Enter Displays LEVEL B= X.XXXA
. You are being prompted for the second
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Enter
Enter
Enter
Keys Display current value. Press the 1 and 0 keys to enter 10 A.
Enters the 10 A value, then displays WIDTH B = X.XMS
. You're being prompted for the duration of the 10 A load -- press the 1 and 0 key for 10 ms.
Enters the 10 ms duration, then displays :CONTINUOUS , :PULSE , or
:TOGGLED . Use the △ or ▽ arrow keys to display :PULSE .
Returns to the standard display of voltage and current.
To activate this pulse transient condition, press Shift + Tran, then press On/Off. The load will start at the A level of current you entered (5 A). Press Shift + Trigger to cause the load to switch to the
B level of current (10 A). The 10 A current will last for the designated 10 ms, then switch back to the
A level (5 A).
NOTE: This example requires the :CONFIG:TRIGGER menu item be set to :IMMEDIATE. If set to :EXTERNAL, you'd trigger the instrument with a high TTL level signal on the trigger terminals on the rear panel. If set to :BUS, you'd trigger the instrument with a software trigger.
Toggled transient operation
In toggled transient operation, the load starts at the stored parameter for the mode. When a trigger is received, the load switches to the B value. When another trigger is received, the load switches to the A value. It stays at the A value until another trigger is received, at which point it switches to the
B value. Further triggers cause the load to switch between the A and B values. Here's an example:
10A
5A
TRG
TRG
Toggled Transient Operation
Here are the keystrokes needed to setup this example:
Keys Display
I-set Standard display of voltage and current. Enter a value of 5 A (you may need to press the I-set key again). Press Enter.
Enters the CC mode's value. The standard display is shown.
Enter
Shift + S-Tran LEVEL A= X.XXXA
You are being prompted for the first current value.
Press the 5 key for 5 A.
Enter Enters the 5 A value, then displays WIDTH A = X.XMS
. You're being prompted for the duration of the 5 A load. In the toggled mode of operation, this width is ignored, so enter any convenient value.
8500 DC Load Series Version: November 4, 2008 Page 35 of 76
Enter
Keys
Enter
Enter
Enter
Display
Displays LEVEL B= X.XXXA
. You are being prompted for the second current value. Press the 1 and 0 keys to enter 10 A.
Enters the 10 A value, then displays WIDTH B = X.XMS
. You're being prompted for the duration of the 10 A load. . In the toggled mode of operation, this width is ignored, so enter any convenient value
Displays :CONTINUOUS , :PULSE , or :TOGGLED . Use the △ or ▽ arrow keys to display :TOGGLED .
Returns to the standard display of voltage and current.
To activate this toggled transient condition, press Shift + Tran, then press On/Off. The load will start at the value you entered for A (5 A). Then press Shift + Trigger to cause the load to switch to the B level of current (10 A). The next trigger will cause the load to shift back to the A level (5 A).
Subsequent triggers repeat this behavior.
NOTE: This example requires the :CONFIG:TRIGGER menu item be set to :IMMEDIATE. If set to :EXTERNAL, you'd trigger the instrument with a high TTL level signal on the trigger terminals on the rear panel. If set to :BUS, you'd trigger the instrument with a software trigger.
Toggle between two test values
When you have entered A and B values through the Shift + S-Tran menu, those values are available to you at the front panel. Suppose you set the instrument to operate in CC mode at a current of 1 A. If the transient A level was 5 A and the transient B level was 10 A, you can set the instrument to the A level by pressing Shift + A. The load has to be on and cannot be in transient condition (i.e., the TRAN annunciator must not be lit). Otherwise, the A value will be stored as the
CC mode's current. Similarly, Shift + B causes the B value to be stored as the CC mode's current.
The load can be on or off for this to work.
Lists (dynamic condition)
Transient operation is used for simple step changes in load values. More complicated dynamic behavior of the load can be obtained through the use of lists. Lists are a sequence of load value and duration pairs. Lists are the logical extension of transient operation.
To illustrate the use of a list, we'll create a list that runs the following constant current profile on a power supply:
Trigger
0 1 2 3 4 5
List count=1 List count=2
List sequence
This list is characterized by the following current/duration pairs
8500 DC Load Series Version: November 4, 2008 Page 36 of 76
Current, A
3
0
2
0
6
Duration, ms
1000
800
500
300
500
Between times
0 and 1
1 and 2
2 and 3
3 and 4
4 and 5
This list has 5 steps, located at the transitions 1 through 5. The first duration, 1000 ms, occurs after the triggered event. Subsequent durations are from the previous transition to the current transition.
Here are the keystrokes to set up this list:
Keys
Shift + Menu
▽ ▽
Enter
Enter
Enter
▽ ▽
Enter
Enter
Enter
5 Enter
3 Enter
1000 Enter
Enter
Enter
Esc Esc
Display
:CONFIG
:LIST SET
:MODE SET
Select :LIST mode. This will cause the LIST annunciator to turn on.
:MODE SET
:EDIT LIST FILE
:CURRENT LIST
Select :REPEAT .
LIST COUNT= N How many steps this list has. Enter the number 5.
COUNT 1= X.XXA
Set the current for the first step. Enter 3.
COUNT 1= X.XXMS
Set the duration for the first step. Enter 1000.
Repeat the current and duration entry for the following 4 steps.
STORE LIST FILE1 The 1 is underlined, indicating you can enter a number to specify the "file" (i.e., block of EEPROM) to store this list to.
Choose a number via the keypad or the knob. You can choose any number between 1-8.
:EDIT LIST FILE
Standard display
First, press the On/Off key. The load will sink the current that is stored as the CC mode parameter
(set it to 0 A if you don't want an initial current). Then press Shift + Trigger to have the list start executing.
Should you wish to have the list only execute once after the trigger, you can edit the list to use
:ONCE instead of :REPEAT .
To exit List mode press the Shift and Trigger key
Test files
Test files are a generalization of lists -- they let you generate a sequence of tests using different
8500 DC Load Series Version: November 4, 2008 Page 37 of 76
modes, mode parameters, and durations. They are useful for executing a set of tests on a device, then displaying whether the tests passed or failed. We will illustrate how to use test files by a short example.
Suppose we have a small AC to DC power supply (a "wall-wart") and we want to set up an acceptance test for a number of these devices. Our test will consist of two steps:
1. Set the DC load to constant current mode to draw the rated current of 0.35 A from the device. The output voltage of the device at the rated current must be between 4.4 volts and
4.6 volts.
2. When the device operates into a short, the supplied current must be larger than 2.0 A.
Keys
Shift + Menu
▽ ▽
Enter
▽ ▽ ▽ ▽
Enter
2.5 Enter
5 Enter
15 Enter
2 Enter
Enter
.35 Enter
Enter
Enter
4.4 Enter
4.6 Enter
1 Enter
Enter
Display
:CONFIG
:LIST SET
:MODE SET
:EDIT TEST FILE
MAX CURR= 3.000A
Set the maximum current to 2.5 A
MAX VOLT= 18.00V
Set the maximum voltage to 5 V
MAX POWER= 150.00W
Set the maximum power to 15 W
TEST COUNT= 6 Our test will consist of two steps, so we enter 2. You can enter up to 20 steps.
CONST CURRENT Since our first test is in constant current mode, we'll just press Enter to select this mode.
SET 1= 0.210A
This is the prompt for the constant current value. We set it to 0.35 A.
SHORT OFF We can turn a short on or off at this step. Here, we want short off, so we just press Enter.
READBACK V We're being prompted for what parameter to read back and check. We want voltage, so we press Enter.
MIN 1= 5.80V
We want the minimum voltage read back to be at least 4.4
V.
MAX 1= 6.15V
The maximum value we'll allow is 4.6 V.
DELAY 1= 1.0<S> This delay time is how long to wait before making the readback measurement. If you set it to 25.5 seconds, the test will halt at this point, requiring you to press Shift + Trigger to continue the test. We'll use 1 second.
CONST CURRENT We're being prompted for the mode to use for the next step. We'll again use constant current, so we'll press Enter (this step will also be a short, so the mode doesn't really matter).
SET 2= 5.000A We'll set the current to 2.5 A, which is the maximum current we've allowed for this test..
8500 DC Load Series Version: November 4, 2008 Page 38 of 76
Keys
2.5 Enter
▽ Enter
Enter
2 Enter
2.5 Enter
2 Enter
Enter
Esc Esc
EDIT TEST FILE
Display
SHORT OFF We select short on and then press Enter.
READBACK A We want to readback the current, so we press Enter.
MIN 2= 4.950A Our minimum value is 2.0 A.
MAX 2= 5.050A
We choose 2.5 A as the maximum value.
DELAY 2= 3.0<S> We'll wait 2 seconds for the maximum current.
STORE TEST FILE1 The 1 is underlined, meaning you can choose which test file number to store this test to. You can choose any number between 1-8. Here, we will use 1, so just press Enter.
Exit the menu. The normal display is shown (V and A).
The test file has been created and saved in file position 1. Now we will run the test on the device.
Keys
Shift + Menu
▽ ▽
Enter
▽ ▽ ▽
Enter
Enter
Esc Esc
Shift I-set
Shift Trigger
Esc
Display
:CONFIG
:LIST SET
:MODE SET
:CALL TEST FILE
RECALL 1 We're being prompted for which file number to recall. Since we saved to file number 1, we just press Enter.
CALL TEST FILE The test file is now loaded, so we return to the normal display.
Exit the menu. The normal display is show (V and A).
NAME:TEST FILE 1 We've entered automatic testing mode. The display is showing which test file we're using.
This starts the test. You'll see the values sequentially displayed. Then you'll either see PASS or FAULT . You can press Shift Trigger again for another test run or press Esc to return to the normal display.
Return to the normal display.
Triggering
Triggering is used with the transient and dynamic conditions to allow synchronization of the DC
Load's behavior with other events. There are three types of triggers you may use (set in the
CONFIG:TRIGGER SOURCE menu):
Trigger Type
IMMEDIATE
Explanation
An immediate trigger is created by pressing Shift + Trigger on the
8500 DC Load Series Version: November 4, 2008 Page 39 of 76
Trigger Type
EXTERNAL
BUS
Explanation front panel keys.
An external trigger is a TTL high signal applied to the Trigger connection on the back panel. This TTL signal must last for more than
5 ms. A trigger applied to this input can be used to change settings
(voltage, current , resistance), toggle between settings in transienttoggle mode, or generate a pulse in pulse mode.
The instrument will be triggered if a 5AH command is sent via the
RS-232 interface. See the Remote operation section for more details.
Voltage threshold operation
The DC Load can be set to only turn on if the voltage is at or above a set value. Additionally, the
load will turn off if the voltage drops below a second set value. This feature works for any mode.
An example of use would be to ensure an electronic system under test will not have power applied
unless the supply voltage is above a certain value. The DC Load would be put in series with the
power supply. Remote sensing would be turned on and the remote sensing connector on the back would be used to connect to the power supply's output voltage.
Use the menu items SYSTEM SET:VOLTAGE ON SET and SYSTEM SET:VOLTAGE OFF SET to set the on and off voltage thresholds, respectively.
Example 1:
Set the instrument to constant current mode with the I-set key and set the current level to 0.1 A.
Turn the load on by pressing the On/Off key. When power is applied to the DC Load, the voltage
must rise above 1.0 V before the load draws current from the source. If the voltage drops below 1.0
V on the load's terminals, the load will stop drawing current from the source.
Example 2: Same as the previous example, except set the VOLTAGE ON SET to 1.0 V and the
SYSTEM SET:VOLTAGE OFF SET 0.0 V. As before, the load will turn on only when the voltage exceeds 1.0 V, but once it is "triggered" on, it will now stay on, even if the voltage drops to zero.
Passwords
If you enter the menu CONFIG:KEY LOCK SET, you can set a one to four digit password. This password will be required when changing settings from the front panel. The only operations allowed without entering the password are:
Shift + A
Shift + B
Shift + Short
Shift + Tran
Shift + Trigger
On/Off
To remove the password, enter the menu CONFIG:KEY LOCK SET and do not press any number keys, then press Enter.
Protection features
To protect external hardware when using the DC Load, you can set the maximum allowed values for
current, voltage, and power. These settings will override any settings subsequently made from the
8500 DC Load Series Version: November 4, 2008 Page 40 of 76
front panel using the I-set, V-set, P-set, or R-set keys.
To set these protection values, use the following keystrokes:
Keys
Shift + Menu
▽
Enter
Esc Esc
:CONFIG
:SYSTEM SET
Display
Select between:
:MAX CURRENT SET
:MAX POWER SET
:MAX VOLTAGE SET using the △ and ▽ arrow keys, then press Enter. Enter the desired value, then press Enter to accept it.
Exit from the menu.
Example: Suppose you are measuring current vs. voltage characteristics of a 1 watt resistor. You could set the maximum allowed power to 1.1 watts to test the resistor's rating, yet not go over the maximum rating by more than 10% to ensure you don't destroy the resistor. If you tried to use the P-
set key to set the power to more than 1.1 W, the instrument will limit the set value to 1.1 W.
Over Voltage protection
If input voltage exceeds the voltage limit set by the user, the DC load will turn the input OFF and the buzzer will sound. The display will show OVER VOLTAGE. The maximum voltage limit value is equal to the maximum rated voltage for each model. For the over voltage protection state to be activated, the voltage level presented to the load terminal must exceed the limit set value by approximately 5%.
Over Current protection
When operating in CR, CC or CW mode, the load current will be limited by a current limit value set by the user. The maximum current limit value is equal to the maximum rated current for each model.
Once the maximum current limit is reached, the DC Load will enter the over current protection state and the current will be limited to the set value. (The input will not turn off). If the DC load previously operated CR or CW mode, the DC load will automatically revert to CC mode and the VFD display will indicate CC. When the DC load operates in a combined CV / transition mode or CV / List mode, the buzzer will sound if the input current exceeds the current limit and the display will show a flashing current value.
Over Power protection
If the input power exceeds the power limit in the normal operation mode, the DC load will enter the over power protection state. The display will show CW.
If the input power exceeds the limit when in transition mode or list mode, the buzzer will sound and the display will flash the current value and voltage value.
Reverse voltage protection
This feature protects the load module in case the DC input terminals are connected to a power source with
8500 DC Load Series Version: November 4, 2008 Page 41 of 76
reversed polarity. If a reverse voltage condition is detected, the buzzer will sound and REVERSE VOLTAGE will be displayed on screen.
Over Temperature protection
If internal temperature exceeds safety limits (80 ;176 °F), the Over temperature circuitry will be activated. The
DC Load will turn off the input, the buzzer will sound, and the display will show OVERHEAT.
Remote sensing
Remote sensing is used to counteract the effect of lead resistance. For example, if you connect a
the wires. Using remote sensing, you can sense the voltage at the power supply's terminals, effectively removing the effect of the voltage drop in the connection wire.
When using remote sensing, the power displayed by the instrument includes both the power dissipated inside the instrument and the power dissipated in the leads from the power supply to the
To turn remote sensing on:
Keys Display
Shift + Menu
Enter
▽ 8 times
Enter
▽
Enter
Esc Esc
:CONFIG
:INITIAL CONFIG
:REMOTE SENSE
:OFF|DEFAULT|
:ON
:REMOTE SENSE and annunciator shows Sense.
Exit from the menu.
The following diagram shows the remote sensing terminals on the back of the instrument:
The following shows a wiring diagram for remote sensing:
8500 DC Load Series Version: November 4, 2008 Page 42 of 76
Example: A power supply is connected to the DC load with 72.5 cm of 20-gauge solid copper wires.
The constant current i set to 5 A. The power supply's output meter reads 27.0 V and the DC Load's
voltage display reads 26.71 V with a power dissipation of 133.70 W. This is without remote sensing enabled. With remote sensing turned on and the remote sensing terminals connected to the power
supply output terminals, the DC Load reads 26.98 V and indicates 134.95 W of power dissipation.
This demonstrates that (134.95 - 133.70) = 1.25 W is dissipated in the 20-gauge wires. From the resistance per unit length of 20-gauge wires, the expected dissipated power at 5 A can be calculated as 1.21 W.
Saving and Recalling settings
The DC Load provides 25 non-volatile registers to save instrument settings for recall later.
To save the instrument's settings to a register, press Shift + Store. You'll be prompted for a register number. Enter a number between 1 and 25, then press the Enter key. The settings are saved.
Note that this will overwrite any values previously saved in that register.
To recall the instrument's settings from a register, press Shift + Recall. You'll be prompted for a register number. Enter a number between 1 and 25, then press the Enter key. The stored settings are saved. Note that this will overwrite all values currently set in the instrument.
If you try to recall a register with no data in it, you will get a NO EEPROM DATA error message.
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Remote operation
Communication cables
The DC Load has a DB9 connector on the rear panel that allows remote communication.
WARNING
Do not connect the DC Load's DB9 connector to a standard RS-232
instrument. Doing so may damage the instrument, as the instrument requires TTL logic signals, not standard RS-232 voltages.
Two adapters are available to perform the correct level shifting.
RS232 to TTL serial converter cable IT-131 (standard)
Connect the INSTRUMENT side of the adapter to the DC load DB9 connector. Connect the
COMPUTER end to an RS-232 port on your computer.
PC
IT-E131 communication cable
IT IT-E131 ISOLATED
COMMUNICATION CABLE
RS232 ISOLATION TTL(5V)
859666668889942311
RX
TX
Load
The LEDs in the adapter will blink when information is sent through the adapter. This is a good way to tell if your communication link is active.
USB to TTL serial converter cable IT-132 (option)
The IT-E132 adapter allows you to talk to the DC load via your Windows ® computer's USB interface.
To use this interface, you must install the software driver that came with the IT-E132 adapter.
To install the driver, run the PL-2303 Driver Installer.exe file that comes on the CD. This will install the driver . After installation, right click on My Computer and select Manage. Click on Device
Manager in the left-hand pane, then click on Ports in the right hand pane. You should see an entry named Prolific USB-to-Serial Comm Port.
Once the driver software is installed on your system, it will appear as if you have a new COM port.
8500 DC Load Series Version: November 4, 2008 Page 44 of 76
This COM port can then be accessed as if it were a regular RS-232 port.
The LEDs in the adapter will blink when information is being sent through the adapter. This is a good way to tell if your communication link is active.
RS-232 settings
In order for the computer to communicate with the DC Load, both must be set to the same RS-232 settings. These communication settings are:
1. Baud rate must be one of 4800, 9600, 19200, or 38400.
2. 8 data bits.
3. One stop bit.
4. No parity.
Overview of DC Load programming
Packet structure
The DC Load is programmed using packets of bytes. A packet always contains 26 bytes, either going to or coming from the instrument. The basic programming rule is:
You send a 26 byte packet to the instrument. You then read a 26 byte packet back from the DC Load to either
●
●
Get the status of your submitted packet, or
Get the data you requested.
The following are conventions we will follow in this chapter:
1. Hexadecimal integers will be represented by the prefix 0x.
2. Numbers are in base 10 number system unless otherwise indicated.
3. Byte numbering is zero-based, meaning numbering starts with 0.
The structure of each 26 byte packet is:
Byte 0 Byte 1 Byte 2 Byte 3 to 24 Byte 25
0xAA Address Command Command's data Checksum
Thus, the first byte of any command packet or returned packet is always 0xAA.
Address must be a byte that is between 0x00 and 0xFE. Setting of the address is optional. It is not required to communicate with the instrument. The address can be set from the front panel and is stored in non-volatile memory. This feature is useful when communicating via USB, and connecting several instruments, e.g. via a USB hub. In this scenario, Windows assigns a virtual COM port to each device which is unknown prior to establishing communications with the instrument (could be different each time). In this case, the user can correlate each virtual COM port randomly assigned by
Windows with a user defined address.
Command is a byte that identifies which DC Load command is used.
The area for the command's data contains parameter information for the command or the data that is requested via a previous command. Some commands have no data at all. It is a good programming practice to set all unused bytes to 0x00.
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The checksum number is the arithmetic sum of each of the bytes modulo 256.
Status packets
When you send a command that does not cause the DC Load to send requested information back to you, you will receive a status packet back. The structure of a status packet is
Byte 0 Byte 1 Byte 2 Byte 3
0xAA Address 0x12 Status byte
Byte 4 to 24
Reserved
The meaning of the return status byte is defined below:
0x90
0xA0
0xB0
0xC0
0x80
Checksum incorrect
Parameter incorrect
Unrecognized command
Invalid command
Command was successful
Byte 25
Checksum
Example program
As you have seen, the native programming interface to the DC loads is fairly low-level. It involves sending 26 byte commands and receiving 26 byte responses from the instrument. To demonstrate how to write your own source code to remotely control the DC load, we provide a custom program written in python which translates well into other text based languages like C/C++
About Python: Python is a dynamic object-oriented programming language that can be used for various kinds of software development. It offers strong support for integration with other languages and tools, comes with extensive standard libraries, and is easy to learn in a few days time. Python is distributed under an OSI-approved open source license that makes it free to use.
You can download a complete python program along with detailed documentation from our website at www.bkprecision.com
. Also available under the download area is a high level library which will make programming much easier as it does the low level bit manipulation for you. Instead of sending a 26 byte string, you can send a high level command such as SetMaxCurrent(current)
Example script:
# Set DC load to remote mode.
import serial length_packet = 26 # Number of bytes in a packet def DumpCommand(bytes):
assert(len(bytes) == length_packet)
header = " "*3
print header,
for i in xrange(length_packet):
if i % 10 == 0 and i != 0:
print header,
if i % 5 == 0:
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print " ",
s = "%02x" % ord(bytes[i])
if s == "00":
s = chr(250)*2
print s,
print def CalculateChecksum(cmd):
assert((len(cmd) == length_packet - 1) or (len(cmd) == length_packet))
checksum = 0
for i in xrange(length_packet - 1):
checksum += ord(cmd[i])
checksum %= 256
return checksum def main():
port = 3 # COM4 for my computer
baudrate = 38400
sp = serial.Serial(port, baudrate) # Open a serial connection
# Construct a set to remote command
cmd = chr(0xaa) + chr(0x00) + chr(0x20) # First three bytes
cmd += chr(0x01) + chr(0x00)*(length_packet - 1 - 4)
cmd += chr(CalculateChecksum(cmd))
assert(len(cmd) == length_packet)
# Send command to DC load
sp.write(cmd)
print "Set to remote command:"
DumpCommand(cmd)
# Get response from DC load
response = sp.read(length_packet)
assert(len(response) == length_packet)
print "Response:"
DumpCommand(response) main()
The first three lines of the ma i n ( )
function set up a serial port to talk to. The next five lines construct the string that we will send to the DC load. The c h r ( )
function creates a single character that has the ASCII value of the argument. The
+
symbols allow strings to be concatenated. The expression c h r ( 0 ) * a _ n u m b e r
creates a string of ASCII
0 x 0 0
characters whose length is a _ n u m b e r
. . The last character is the checksum of the previous 25 characters, calculated for us by the
Ca l c u l a t e C h e c k s u m ( )
function.
When a command is sent to the instrument, you must always request for return data, which will always be another 26 bytes. This is also dumped to the screen.
You can download a complete python program along with detailed documentation from our website at www.bkprecision.com
8500 DC Load Series Version: November 4, 2008 Page 47 of 76
Here are the printed results when the above script is ran:
Set to remote command:
aa ·· 20 01 ·· ·· ·· ·· ·· ··
·· ·· ·· ·· ·· ·· ·· ·· ·· ··
·· ·· ·· ·· ·· cb
Response:
aa ·· 12 80 ·· ·· ·· ·· ·· ··
·· ·· ·· ·· ·· ·· ·· ·· ·· ··
·· ·· ·· ·· ·· 3c
The
·
characters represent the bytes with a value of
0 x 0 0
. This makes it easier to see the nonzero bytes in the string.
The first byte of a command is always
0 x a a
and the second byte is the address of the DC load. The address should be set to 0. The third byte identifies the command "set to remote" and the fourth byte is a 1, which means enable remote mode. If the fourth byte was 0, this command would set the
DC load to local mode.
The third byte of the response string is
0 x 1 2
, which means this is a packet that gives the status of the last command sent. The fourth byte is
0 x 8 0
, which means the command completed successfully.
On the DC load, you should see the
Rm t
annunciator turned on immediately after running the script.
You will also see the
L i n k
annunciator light up while communications are going on, then blink out after a few seconds.
Press
S h i f t + L o c a l
to set the DC load back to local mode.
We've learned two key things about the DC load:
1. Commands are always sent as 26 byte packets.
2. For any command you send to the DC load, you must also request the return of a 26 byte packet. This returned packet will either be a status packet or an information packet containing data you requested -- for example, the power level currently set.
Get in the habit of looking at the LEDs on the IT-E131 or IT-E132 interfaces. Every command you send to the DC load should result in both the RX and TX LEDs blinking once. If this does not happen, something is wrong with the code, interface, or instrument.
Chapter organization
The remainder of this chapter contains a reference on the syntax of DC Load commands and some
8500 DC Load Series Version: November 4, 2008 Page 48 of 76
example programs. The Summary of commands section is a list of the commands, but without details. The Command details section explains how to use each command.
Summary of commands
The Byte values in the following table are used to identify the commands to be sent in the command packet (byte 2).
Command Group Byte Action
Return data
Remote
ON/OFF
Maximum parameter values
Operation mode
Mode parameters
Transient parameters
0x12
Indicates a packet that returns the status of the last command you sent to the DC Load
0x20 Set the DC Load to remote operation
0x21 Turn the load ON or OFF
0x22 Set the maximum voltage allowed
0x23 Read the maximum voltage allowed
0x24 Set the maximum current allowed
0x25 Read the maximum current allowed
0x26 Set the maximum power allowed
0x27 Read the maximum power allowed
0x28 Set CC, CV, CW, or CR mode
0x29 Read the mode being used (CC, CV, CW, or CR)
0x2A Set CC mode current
0x2B Read CC mode current
0x2C Set CV mode voltage
0x2D Read CV mode voltage
0x2E Set CW mode power
0x2F Read CW mode power
0x30 Set CR mode resistance
0x31 Read CR mode resistance
0x32 Set CC mode transient current and timing
0x33 Read CC mode transient parameters
0x34 Set CV mode transient voltage and timing
0x35 Read CV mode transient parameters
0x36 Set CW mode transient power and timing
0x37 Read CW mode transient parameters
0x38 Set CR mode transient resistance and timing
0x39 Read CR mode transient parameters
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Command Group Byte
List operations
Battery testing
LOAD ON
Address
LOCAL
Remote sensing
Triggering
Store/Recall
Action
0x3A Select the list operation (CC/CV/CW/CR)
0x3B Read the list operation (CC/CV/CW/CR)
0x3C Set how lists repeat (ONCE or REPEAT)
0x3D Read how lists repeat
0x3E Set the number of list steps
0x3F Read the number of list steps
0x40 Set one of the step's current and time values
0x41 Read one of the step's current and time values
0x42 Set one of the step's voltage and time values
0x43 Read one of the step's voltage and time values
0x44 Set one of the step's power and time values
0x45 Read one of the step's power and time values
0x46 Set one of the step's resistance and time values
0x47 Read one of the step's resistance and time values
0x48 Set the list file name
0x49 Read the list file name
0x4A Set the memory partitioning for storing lists
0x4B Read the memory partitioning for storing list steps
0x4C Store the list file
0x4D Recall the list file
0x4E Set minimum voltage in battery testing
0x4F Read minimum voltage in battery testing
0x50 Set timer value of for LOAD ON
0x51 Read timer value for LOAD ON
0x52 Disable/enable timer for LOAD ON
0x53 Read timer state for LOAD ON
0x54 Set communication address
0x55 Enable/disable LOCAL control
0x56 Enable/disable remote sensing
0x57 Read the state of remote sensing
0x58 Select trigger source
0x59 Read trigger source
0x5A Trigger the electronic load
0x5B Store DC Load's settings
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Command Group Byte Action
0x5C Recall DC Load's settings
Function
0x5D Select FIXED/SHORT/TRAN/LIST/BATTERY function
0x5E Get function type (FIXED/SHORT/TRAN/LIST/BATTERY)
Read display values 0x5F Read input voltage, current, power and relative state
Calibration
0x60 Enter instrument calibration state
0x61 Get the instrument calibration state
0x62 Set voltage calibration point index
0x63 Send the actual voltage to the calibration program
0x64 Set current calibration point index
0x65 Send the actual current to the calibration program
0x66 Store the calibration data to EEPROM
Product information
0x67 Set calibration information
0x68 Read calibration information
0x69 Restore the factory default calibration data
0x6A Get product's model, serial number, and firmware version
0x6B Read the bar code information
0x6C Set the bar code information
Command details
In the following, please remember that the word mode only refers to one of the four operational modes of the DC Load: constant current (CC), constant voltage (CV), constant power (CW), or constant resistance (CR).
Notation for tables
In the following sections, we abbreviate the details of the commands. Since the first three bytes of a command are i) the constant 0xAA, ii) the instrument address, and iii) the command, we will not show those for each command. In addition, the 26th byte, the checksum, will also not be shown.
The table includes a column for Byte offset. This is the zero-based index of the byte in the packet.
Note the offset numbers are in decimal.
A table entry of “Reserved” means the data are currently unused or reserved for future use. Good programming practice is to set these bytes to 0x00.
Some commands require two byte and four byte integers to represent parameter settings. These integers are stored in the command packet in little-endian format. Little-endian is a byte ordering format in which bytes with lower addresses have lower significance. We will refer to the individual bytes as follows:
For a two byte integer, the least significant byte will be called the low byte and the most significant byte will be called the high byte.
For a four byte integer, we will use the following notation:
Least significant two bytes, least significant byte Lower low byte
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Least significant two bytes, most significant byte
Most significant two bytes, least significant byte
Most significant two bytes, most significant byte
As an example, for the integer 0x23A749F5, we'd have
1st byte
2nd byte
3rd byte
4th byte
0xF5 Lower low byte
0x49 Lower high byte
0xA7 Higher low byte
0x23 Higher high byte
Lower high byte
Higher low byte
Higher high byte
0x12 Indicates a return packet for a command sent to the DC Load
Byte offset
Meaning
3 Status byte (i.e., status of last command sent to DC Load).
4-24 Reserved
Below is a table of all possible status byte values and their corresponding indication.
0x90
0xA0
0xB0
0xC0
0x80
Checksum incorrect
Parameter incorrect
Unrecognized command
Invalid command
Command was successful
0x20 Set the DC Load to remote operation
Byte offset
Meaning
3 0 means front panel operation.
1 means remote operation.
4-24 Reserved
0x21 Turn the load ON or OFF
Byte offset
Meaning
3 0 is OFF.
1 is ON.
4-24 Reserved
0x22 Set the maximum voltage allowed
Byte offset
Meaning
3 Lower low byte of maximum voltage. 1 represents 1 mV.
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Byte offset
Meaning
4
5
6
Lower high byte of maximum voltage.
Upper low byte of maximum voltage.
Upper high byte of maximum voltage.
7-24 Reserved
Example: Suppose you want to set the maximum voltage to 16.000V. Since 1 represents 1mV,
16.000V translates to 16,000 in decimal. With 4 bytes in Hex, that would be 0x00003E80. Since the bytes are ordered in little-endian format, 0x80 would be the 3 rd byte, 0x3E the 4 th byte, 0x00 as 5 th byte, and 0x00 as the 6 th byte.
0x23 Read the maximum voltage allowed
Byte offset
Meaning
3
4
5
6
Lower low byte of maximum voltage. 1 represents 1 mV.
Lower high byte of maximum voltage.
Upper low byte of maximum voltage.
Upper high byte of maximum voltage.
7-24 Reserved
0x24 Set the maximum current allowed
Byte offset
Meaning
3 Lower low byte of maximum current. 1 represents 0.1 mA.
4
5
Lower high byte of maximum current.
Upper low byte of maximum current.
6 Upper high byte of maximum current.
7-24 Reserved
Example: Suppose you want to set the maximum current to 3.0000A. Since 1 represents 0.1mA,
3.0000A translates to 30,000 in decimal. With 4 bytes in Hex, that would be 0x00007530. Since the bytes are ordered in little-endian format, 0x30 would be the 3 rd byte, 0x75 the 4 th byte, 0x00 as 5 th byte, and 0x00 as the 6 th byte.
0x25 Read the maximum current allowed
Byte offset
Meaning
3
4
Lower low byte of maximum current. 1 represents 0.1 mA.
Lower high byte of maximum current.
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Byte offset
Meaning
5
6
Upper low byte of maximum current.
Upper high byte of maximum current.
7-24 Reserved
0x26 Set the maximum power allowed
Byte offset
Meaning
3
4
Lower low byte of maximum power. 1 represents 1 mW.
Lower high byte of maximum power.
5
6
Upper low byte of maximum power.
Upper high byte of maximum power.
7-24 Reserved
Example: Suppose you want to set the maximum power to 200.000W. Since 1 represents 1mW,
200.000W translates to 200,000 in decimal. With 4 bytes in Hex, that would be 0x00030D40. Since the bytes are ordered in little-endian format, 0x40 would be the 3 rd byte, 0x0D the4 th byte, 0x03 as 5 th byte, and 0x00 as the 6 th byte.
0x27 Read the maximum power allowed
Byte offset
Meaning
3
4
Lower low byte of maximum power. 1 represents 1 mW.
Lower high byte of maximum power.
5
6
Upper low byte of maximum power.
Upper high byte of maximum power.
7-24 Reserved
0x28 Set CC, CV, CW, or CR mode
Byte offset
Meaning
3 Mode:
0 is CC
1 is CV
2 is CW
3 is CR
4-24 Reserved
0x29 Read the mode being used (CC, CV, CW, or CR)
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Byte offset
Meaning
3 Mode:
0 is CC
1 is CV
2 is CW
3 is CR
4-24 Reserved
0x2A Set CC mode current
Byte offset
Meaning
3
4
5
Lower low byte of current. 1 represents 0.1 mA.
Lower high byte of current.
Upper low byte of current.
6 Upper high byte of current.
7-24 Reserved
0x2B Read CC mode current
Byte offset
Meaning
3
4
5
6
Lower low byte of current. 1 represents 0.1 mA.
Lower high byte of current.
Upper low byte of current.
Upper high byte of current.
7-24 Reserved
0x2C Set CV mode voltage
Byte offset
Meaning
3
4
5
6
Lower low byte of voltage. 1 represents 1 mV.
Lower high byte of voltage.
Upper low byte of voltage.
Upper high byte of voltage.
7-24 Reserved
0x2D Read CV mode voltage
Byte offset
Meaning
3 Lower low byte of voltage. 1 represents 1 mV.
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Byte offset
3
4
Meaning
4
5
6
Lower high byte of voltage.
Upper low byte of voltage.
Upper high byte of voltage.
7-24 Reserved
0x2E Set CW mode power
Byte offset
Meaning
3
4
5
6
Lower low byte of power. 1 represents 1 mW.
Lower high byte of power.
Upper low byte of power.
Upper high byte of power.
7-24 Reserved
0x2F Read CW mode power
Byte offset
Meaning
3
4
Lower low byte of power. 1 represents 1 mW.
Lower high byte of power.
5
6
Upper low byte of power.
Upper high byte of power.
7-24 Reserved
0x30 Set CR mode resistance
Byte offset
Meaning
3
4
5
6
Lower low byte of resistance. 1 represents 1 Ω .
Lower high byte of resistance.
Upper low byte of resistance.
Upper high byte of resistance.
7-24 Reserved
0x31 Read CR mode resistance
Byte offset
Meaning
Lower low byte of resistance. 1 represents 1 Ω .
Lower high byte of resistance.
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Byte offset
Meaning
5
6
Upper low byte of resistance.
Upper high byte of resistance.
7-24 Reserved
0x32 Set CC mode transient current and timing
Byte offset
Meaning
3 to 6 Value A of current in units of 0.1 mA. Little-endian 4 byte number.
7 to 8 Time for A current in units of 0.1 ms. Little-endian 2 byte number.
9 to 12 Value B of current in units of 0.1 mA. Little-endian 4 byte number.
13 to 14 Time for B current in units of 0.1 ms. Little-endian 2 byte number.
15 Transient operation:
0 is CONTINUOUS
1 is PULSE
2 is TOGGLED
16-24 Reserved
0x33 Read CC mode transient parameters
Byte offset
Meaning
3 to 6 Value A of current in units of 0.1 mA. Little-endian 4 byte number.
7 to 8 Time for A current in units of 0.1 ms. Little-endian 2 byte number.
9 to 12 Value B of current in units of 0.1 mA. Little-endian 4 byte number.
13 to 14 Time for B current in units of 0.1 ms. Little-endian 2 byte number.
15 Transient operation:
0 is CONTINUOUS
1 is PULSE
2 is TOGGLED
16-24 Reserved
0x34 Set CV mode transient voltage and timing
Byte offset
Meaning
3 to 6 Value A of voltage in units of 1 mV. Little-endian 4 byte number.
7 to 8 Time for A voltage in units of 0.1 ms. Little-endian 2 byte number.
9 to 12 Value B of voltage in units of 1 mV. Little-endian 4 byte number.
13 to 14 Time for B voltage in units of 0.1 ms. Little-endian 2 byte number.
15 Transient operation:
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Byte offset
Meaning
0 is CONTINUOUS
1 is PULSE
2 is TOGGLED
16-24 Reserved
0x35 Read CV mode transient parameters
Byte offset
Meaning
3 to 6 Value A of voltage in units of 1 mV. Little-endian 4 byte number.
7 to 8 Time for A voltage in units of 0.1 ms. Little-endian 2 byte number.
9 to 12 Value B of voltage in units of 1 mV. Little-endian 4 byte number.
13 to 14 Time for B voltage in units of 0.1 ms. Little-endian 2 byte number.
15 Transient operation:
0 is CONTINUOUS
1 is PULSE
2 is TOGGLED
16-24 Reserved
0x36 Set CW mode transient power and timing
Byte offset
Meaning
3 to 6 Value A of power in units of 1 mW. Little-endian 4 byte number.
7 to 8 Time for A power in units of 0.1 ms. Little-endian 2 byte number.
9 to 12 Value B of power in units of 1 mW. Little-endian 4 byte number.
13 to 14 Time for B power in units of 0.1 ms. Little-endian 2 byte number.
15 Transient operation:
0 is CONTINUOUS
1 is PULSE
2 is TOGGLED
16-24 Reserved
0x37 Read CW mode transient parameters
Byte offset
Meaning
3 to 6 Value A of power in units of 1 mW. Little-endian 4 byte number.
7 to 8 Time for A power in units of 0.1 ms. Little-endian 2 byte number.
9 to 12 Value B of power in units of 1 mW. Little-endian 4 byte number.
13 to 14 Time for B power in units of 0.1 ms. Little-endian 2 byte number.
8500 DC Load Series Version: November 4, 2008 Page 58 of 76
Byte offset
Meaning
15 Transient operation:
0 is CONTINUOUS
1 is PULSE
2 is TOGGLED
16-24 Reserved
0x38 Set CR mode transient resistance and timing
Byte offset
Meaning
3 to 6 Value A of resistance in units of 1 Ω . Little-endian 4 byte number.
7 to 8 Time for A resistance in units of 0.1 ms. Little-endian 2 byte number.
9 to 12 Value B of resistance in units of 1 Ω . Little-endian 4 byte number.
13 to 14 Time for B resistance in units of 0.1 ms. Little-endian 2 byte number.
15 Transient operation:
0 is CONTINUOUS
1 is PULSE
2 is TOGGLED
16-24 Reserved
0x39 Read CR mode transient parameters
Byte offset
Meaning
3 to 6 Value A of resistance in units of 1 Ω . Little-endian 4 byte number.
7 to 8 Time for A resistance in units of 0.1 ms. Little-endian 2 byte number.
9 to 12 Value B of resistance in units of 1 Ω . Little-endian 4 byte number.
13 to 14 Time for B resistance in units of 0.1 ms. Little-endian 2 byte number.
15 Transient operation:
0 is CONTINUOUS
1 is PULSE
2 is TOGGLED
16-24 Reserved
0x3A Select the list operation (CC/CV/CW/CR)
Byte offset
Meaning
3 List operation mode:
0 is constant current (CC)
1 is constant voltage (CV)
2 is constant power (CW)
8500 DC Load Series Version: November 4, 2008 Page 59 of 76
Byte offset
Meaning
3 is constant resistance (CR)
4-24 Reserved
0x3B Read the list operation (CC/CV/CW/CR)
Byte offset
Meaning
3 List operation mode:
0 is constant current (CC)
1 is constant voltage (CV)
2 is constant power (CW)
3 is constant resistance (CR)
4-24 Reserved
0x3C Set how lists repeat (ONCE or REPEAT)
Byte offset
Meaning
3 How lists repeat:
0 is ONCE
1 is REPEAT
4-24 Reserved
0x3D Read how lists repeat (ONCE or REPEAT)
Byte offset
Meaning
3 How lists repeat:
0 is ONCE
1 is REPEAT
4-24 Reserved
0x3E Set the number of list steps
Byte offset
Meaning
3 to 4 2 byte little-endian integer for number of steps
5-24 Reserved
0x3F Read the number of list steps
Byte offset
Meaning
3 to 4 2 byte little-endian integer for number of steps
5-24 Reserved
8500 DC Load Series Version: November 4, 2008 Page 60 of 76
0x40 Set one of the step's current and time values
Byte offset
Meaning
3 to 4 2 byte little-endian integer specifying which step number in the list
5 to 8 4 byte little-endian integer specifying the current in units of 0.1 mA
9 to 10 2 byte little-endian integer specifying the step timing in units of 0.1 ms
11-24 Reserved
0x41 Read one of the step's current and time values
Byte offset
Meaning
3 to 4 2 byte little-endian integer specifying which step number in the list
5 to 8 4 byte little-endian integer specifying the current in units of 0.1 mA
9 to 10 2 byte little-endian integer specifying the step timing in units of 0.1 ms
11-24 Reserved
0x42 Set one of the step's voltage and time values
Byte offset
Meaning
3 to 4 2 byte little-endian integer specifying which step number in the list
5 to 8 4 byte little-endian integer specifying the voltage in units of 1 mV
9 to 10 2 byte little-endian integer specifying the step timing in units of 0.1 ms
11-24 Reserved
0x43 Read one of the step's voltage and time values
Byte offset
Meaning
3 to 4 2 byte little-endian integer specifying which step number in the list
5 to 8 4 byte little-endian integer specifying the voltage in units of 1 mV
9 to 10 2 byte little-endian integer specifying the step timing in units of 0.1 ms
11-24 Reserved
0x44 Set one of the step's power and time values
Byte offset
Meaning
3 to 4 2 byte little-endian integer specifying which step number in the list
5 to 8 4 byte little-endian integer specifying the power in units of 1 mW
9 to 10 2 byte little-endian integer specifying the step timing in units of 0.1 ms
11-24 Reserved
8500 DC Load Series Version: November 4, 2008 Page 61 of 76
0x45 Set one of the step's power and time values
Byte offset
Meaning
3 to 4 2 byte little-endian integer specifying which step number in the list
5 to 8 4 byte little-endian integer specifying the power in units of 1 mW
9 to 10 2 byte little-endian integer specifying the step timing in units of 0.1 ms
11-24 Reserved
0x46 Read one of the step's resistance and time values
Byte offset
Meaning
3 to 4 2 byte little-endian integer specifying which step number in the list
5 to 8 4 byte little-endian integer specifying the resistance in units of 1 Ω
9 to 10 2 byte little-endian integer specifying the step timing in units of 0.1 ms
11-24 Reserved
0x47 Read one of the step's resistance and time values
Byte offset
Meaning
3 to 4 2 byte little-endian integer specifying which step number in the list
5 to 8 4 byte little-endian integer specifying the resistance in units of 1 Ω
9 to 10 2 byte little-endian integer specifying the step timing in units of 0.1 ms
11-24 Reserved
0x48 Set the list file name
Byte offset
Meaning
3 to 12 List file name (ASCII characters)
13-24 Reserved
0x49 Read the list file name
Byte offset
Meaning
3 to 12 List file name (ASCII characters)
13-24 Reserved
0x4A Set the memory partitioning for storing lists
8500 DC Load Series Version: November 4, 2008 Page 62 of 76
Byte offset
Meaning
3 Partition scheme:
1 means 1 file of 1000 list steps
2 means 2 files of 500 list steps
4 means 4 files of 250 list steps
8 means 8 files of 120 list steps
4-24 Reserved
0x4B Read the memory partitioning for storing list steps
Byte offset
Meaning
3 Partition scheme:
1 means 1 file of 1000 list steps
2 means 2 files of 500 list steps
4 means 4 files of 250 list steps
8 means 8 files of 120 list steps
4-24 Reserved
0x4C Save the list file
Byte offset
Meaning
3 Storage location, a one byte integer from 1 to 8. This number must be consistent with the number of list files allowed as set by the 0x4A command.
4-24 Reserved
0x4D Recall the list file
Byte offset
Meaning
3 Storage location, a one byte integer from 1 to 8.
4-24 Reserved
0x4E Set minimum voltage in battery testing
Byte offset
Meaning
3 to 6 4 byte little-endian integer specifying the minimum voltage in units of 1 mV
7-24 Reserved
0x4F Read minimum voltage in battery testing
Byte offset
Meaning
3 to 6 4 byte little-endian integer specifying the minimum voltage in units of 1 mV
8500 DC Load Series Version: November 4, 2008 Page 63 of 76
Byte offset
Meaning
7-24 Reserved
0x50 Set timer value of for LOAD ON
Byte offset
Meaning
3 to 4 2 byte little-endian integer specifying the time in units of 1 second
5-24 Reserved
0x51 Read timer value for LOAD ON
Byte offset
Meaning
3 to 4 2 byte little-endian integer specifying the time in units of 1 second
5-24 Reserved
0x52 Disable/enable timer for LOAD ON
Byte offset
Meaning
3 0 is disable timer
1 is enable timer
4-24 Reserved
0x53 Read timer state for LOAD ON
Byte offset
Meaning
3 0 is disable timer
1 is enable timer
4-24 Reserved
0x54 Set communication address
Byte offset
Meaning
3 2 byte little-endian integer specifying the address. Must be between 0 and
0xFE, inclusive.
4-24 Reserved
0x55 Enable/disable LOCAL control
Byte offset
Meaning
3 0 means to disable the Local key on the front panel
8500 DC Load Series Version: November 4, 2008 Page 64 of 76
Byte offset
Meaning
1 means to enable the Local key on the front panel
4-24 Reserved
0x56 Enable/disable remote sensing
Byte offset
Meaning
3 0 means to disable remote sensing
1 means to enable remote sensing
4-24 Reserved
0x57 Read the state of remote sensing
Byte offset
Meaning
3 0 means remote sensing is disabled
1 means remote sensing is enabled
4-24 Reserved
0x58 Select trigger source
Byte offset
Meaning
3 Trigger:
0 means immediate trigger (i.e., triggered from the front panel)
1 means external trigger from the rear panel connector
2 means a bus (software) trigger (the 0x5A command)
4-24 Reserved
0x59 Read trigger source
Byte offset
Meaning
3 Trigger:
0 means immediate trigger (i.e., triggered from the front panel)
1 means external trigger from the rear panel connector
2 means a bus (software) trigger (the 0x5A command)
4-24 Reserved
0x5A Trigger the electronic load
Byte offset
Meaning
3-24 Reserved
0x5B Save DC Load's settings
8500 DC Load Series Version: November 4, 2008 Page 65 of 76
Byte offset
Meaning
3 Storage register, a number between 1 and 25 inclusive
4-24 Reserved
0x5C Recall DC Load's settings
Byte offset
Meaning
3 Storage register, a number between 1 and 25 inclusive
4-24 Reserved
0x5D Select FIXED/SHORT/TRAN/LIST/BATTERY function
Byte offset
Meaning
3 Function:
0 means FIXED
1 means SHORT
2 means TRANSIENT
3 means LIST
4 means BATTERY
4-24 Reserved
0x5E Get function type (FIXED/SHORT/TRAN/LIST/BATTERY)
Byte offset
Meaning
3 Function:
0 means FIXED
1 means SHORT
2 means TRANSIENT
3 means LIST
4 means BATTERY
4-24 Reserved
0x5F Read input voltage, current, power and relative state
Byte offset
Meaning
3 to 6 4 byte little-endian integer for terminal voltage in units of 1 mV
7 to 10 4 byte little-endian integer for terminal current in units of 0.1 mA
11 to 14 4 byte little-endian integer for terminal power in units of 1 mW
15 Operation state register (see bit list below)
16 to 17 2 byte little-endian integer for demand state register (see bit list below)
18-24 Reserved
8500 DC Load Series Version: November 4, 2008 Page 66 of 76
The operation state register's bit meanings are:
Bit Meaning
0 Calculate the new demarcation coefficient
1 Waiting for a trigger signal
2 Remote control state (1 means enabled)
3 Output state (1 means ON)
4 Local key state (0 means not enabled, 1 means enabled)
5 Remote sensing mode (1 means enabled)
6 LOAD ON timer is enabled
7 Reserved
The demand state register's bit meanings are:
Bit Meaning
0 Reversed voltage is at instrument's terminals (1 means yes)
1 Over voltage (1 means yes)
2 Over current (1 means yes)
3 Over power (1 means yes)
4 Over temperature (1 means yes)
5 Not connect remote terminal
6 Constant current
7 Constant voltage
8 Constant power
9 Constant resistance
0x60 Enter instrument calibration state
Byte offset
Meaning
3 Calibration state:
0 means disable
1 means enable
0x85 (low byte of calibration password) 4
5 0x11 or 0x12 (high byte of calibration password)
6-24 Reserved
0x61 Get the instrument calibration state
8500 DC Load Series Version: November 4, 2008 Page 67 of 76
Byte offset
Meaning
3 Calibration protection state:
Bit 0: value of 0 means the calibration state is not protected
Bit 0: value of 1 means the calibration state is protected
4-24 Reserved
0x62 Set voltage calibration point index
Byte offset
Meaning
3 Voltage calibration point. Valid values are 0x01 to 0x04.
4-24 Reserved
The DC Load has four calibration points for voltage. These would typically span the full range of the instrument's voltage range.
0x63 Send the actual voltage to the calibration program
Byte offset
Meaning
3 to 6 4 byte little-endian integer representing the voltage in units of mV
7-24 Reserved
0x64 Set current calibration point index
Byte offset
Meaning
3 Current calibration point. Valid values are 0x01 to 0x04.
4-24 Reserved
The DC Load has four calibration points for current. These would typically span the full range of the instrument's current range.
0x65 Send the actual current to the calibration program
Byte offset
Meaning
3 to 6 4 byte little-endian integer representing the current in units of 0.1 mA
7-24 Reserved
0x66 Store the calibration data to EEPROM
Byte offset
Meaning
3-24 Reserved
8500 DC Load Series Version: November 4, 2008 Page 68 of 76
The stored calibration data will be used the next time the DC Load is power cycled.
0x67 Set calibration information
Byte offset
Meaning
3 to 22 ASCII information representing the calibration. Example: you might wish to store the date and time of the calibration and the initials of the person who performed the calibration.
23-24 Reserved
0x68 Read calibration information
Byte offset
Meaning
3 to 22 ASCII information representing the calibration.
23-24 Reserved
0x69 Restore the factory default calibration data
Byte offset
Meaning
3-24 Reserved
0x6A Get product's model, serial number, and firmware version
Byte offset
Meaning
3 to 7 ASCII model information
8 Low byte of firmware version number
9 High byte of firmware version number
10 to 19 Instrument's serial number in ASCII
20-24 Reserved
0x6B Read the bar code information
Note: the bar code information is to be interpreted as ASCII data.
Byte offset
Meaning
3 to 5 Identity
6 to 7 Sub
7 to 9 Version
10 to 11 Year
8500 DC Load Series Version: November 4, 2008 Page 69 of 76
Byte offset
12-24 Reserved
Meaning
8500 DC Load Series Version: November 4, 2008 Page 70 of 76
Serial number and firmware version
To find out the serial number and firmware version of the DC load, turn the instrument on. While the
SYSTEM SELFTEST message is displayed, quickly press and hold down the Shift key. By pressing the △ and ▽ keys, you will see the following information:
120V 30A 320W
SN: XXX-XXX-XXX
VER: X.XX
Instrument's capabilities
Serial number
Firmware version
Press the Esc key to return to normal operation of the instrument.
8500 DC Load Series Version: November 4, 2008 Page 71 of 76
In case of trouble
Instrument won't turn on
If the instrument won't turn on when the POWER switch is pressed in, please ensure the power cord is plugged into the back of the instrument and the other end of the cord is plugged into a live AC power outlet.
If the instrument still won't turn on, remove the power cord from the instrument. Open the fuse container on the rear panel and check the fuse for continuity.
If the fuse is an open circuit, replace it with the proper fuse indicated in the following table:
Model Fuse specification for 110
VAC operation
Fuse specification for 220
VAC operation
8500
8502
8510
8512
8514
8518
8520
8522
8524
8526
T0.5A, 250 VAC
T0.5A, 250 VAC
T0.5A, 250 VAC
T2.5A, 250 VAC
T2.5A, 250 VAC
T2.5A, 250 VAC
T2.5A, 250 VAC
T2.5A, 250 VAC
T5A, 250 VAC
T5A, 250 VAC
T0.3A, 250 VAC
T0.3A, 250 VAC
T0.3A, 250 VAC
T0.1.25A, 250 VAC
T0.1.25A, 250 VAC
T0.1.25A, 250 VAC
T0.1.25A, 250 VAC
T0.1.25A, 250 VAC
T2.5A, 250 VAC
T2.5A, 250 VAC
WARNING Ensure that the fuse is rated for 250 VAC operation. Lower voltage rated fuses are not suitable for this instrument.
Error messages during power-up
EEPROM ERROR means the calibration data have been lost or the EEPROM is not functional.
ERROR CAL.DATA means that the calibration data have been lost.
If you experience these error messages, the instrument should be returned to B&K Precision for service.
Keypad unlock procedure (Keypad was accidentally locked)
If you accidentally locked the keyboard, follow this procedure to unlock: The procedure below shows how to unlock a model 8500 using “8512” as the unlock key.
1) Press Shift + Menu. You will see PASSWORD: displayed on the screen. Enter 8512, then press the Enter key. Now you will see Connect on the display
2) Press Enter, locate menu Key Lock set, press Enter. Enter 8512, confirm with Enter, press
8500 DC Load Series Version: November 4, 2008 Page 72 of 76
Enter again. Now the password is cleared. Press Esc to exit the menu
To unlock the other DC load models, use the following unlock keys:
Model number
8500
8502
8510
8512
8514
8518
8520
8522
8524
8526
Unlock key code
8512
8512
8513
8513
8514
8518
8516
8516
8518
8518
8500 DC Load Series Version: November 4, 2008 Page 73 of 76
Appendix: Service and warranty information
SERVICE INFORMATION
Warranty Service: Please go to the service and support section on our website www.bkprecision.com
to obtain an RMA
#. Return the product in the original packaging with proof of purchase to the address below. . Clearly state on the RMA form the performance problem and return any leads, probes, connectors and accessories that you are using with the device.
Non-Warranty Service: Please go to the service and support section on our website www.bkprecision.com
to obtain an
RMA #. Return the product in the original packaging to the address below. Clearly state on the RMA form the performance problem and return any leads, probes, connectors and accessories that you are using with the device. Customers not on open account must include payment in the form of a money order or credit card. For the most current repair charges please refer to the service and support section on our website.
Return all merchandise to B&K Precision Corp. with prepaid shipping. The flat-rate repair charge for Non-Warranty Service does not include return shipping. Return shipping to locations in North American is included for Warranty Service. For overnight shipments and non-North American shipping fees please contact B&K Precision Corp.
B&K Precision Corp.
22820 Savi Ranch Parkway
Yorba Linda, CA 92887 www.bkprecision.com
714-921-9095
Include with the returned instrument your complete return shipping address, contact name, phone number and description of problem.
LIMITED ONE-YEAR WARRANTY
B&K Precision Corp. warrants to the original purchaser that its products and the component parts thereof, will be free from defects in workmanship and materials for a period of one year from date of purchase.
B&K Precision Corp. will, without charge, repair or replace, at its option, defective product or component parts. Returned product must be accompanied by proof of the purchase date in the form of a sales receipt.
To obtain warranty coverage in the U.S.A., this product must be registered by completing a warranty registration form on our website www.bkprecision.com
within fifteen (15) days of purchase.
Exclusions: This warranty does not apply in the event of misuse or abuse of the product or as a result of unauthorized alterations or repairs. The warranty is void if the serial number is altered, defaced or removed.
B&K Precision Corp. shall not be liable for any consequential damages, including without limitation damages resulting from loss of use. Some states do not allow limitations of incidental or consequential damages. So the above limitation or exclusion may not apply to you.
This warranty gives you specific rights and you may have other rights, which vary from state-to-state.
B&K Precision Corp.
22820 Savi Ranch Parkway
Yorba Linda, CA 92887 www.bkprecision.com
714-921-9095
8500 DC Load Series Version: November 4, 2008
23
Page 74 of 76
Index
Alphabetical Index
Battery...............................................................21
Battery test...............................................7, 21, 32
CC.....................................................................21
Condition............................................................21
Constant current.................................9, 11, 21, 29
Constant power..................................9, 11, 21, 30
Constant resistance........................9, 11, 21p., 31
Constant voltage.............................9, 11, 21p., 30
CR.....................................................................21
CV......................................................................21
CW.....................................................................21
Draw a constant current.......................................6
Draw a constant power........................................6
Draw a constant voltage......................................6
Dynamic condition..............................................21
Enter............................................................10, 13
Esc...............................................................10, 12
I-set....................................................................21
List................................................11, 13p., 21, 36
Local............................................................11, 21
Menu........................................................8, 12, 21
Menu system.....................................................10
Mode..................................................................21
Mode settings....................................................29
P-set..................................................................21
Present a constant resistance..............................6
R-set..................................................................22
Recall...............................................10, 12, 22, 43
Remote sensing..................................11p., 22, 42
Resistance.........................................................31
Resistance ........................................................31
S-Tran................................................................22
Shift..............................................................11, 22
Shift + △.............................................................32
Shift + ▽.............................................................32
Short................................................10, 12, 22, 32
Standard display...........................................34pp.
Store............................................................10, 22
Tran...................................................................22
Transient condition.............................................22
Transient mode..................................................21
Trigger...............................................11pp., 22, 39
V-set..................................................................22
△........................................................................32
▽........................................................................21
8500 DC Load Series Version: November 4, 2008 Page 75 of 76
22820 Savi Ranch Parkway Yorba Linda CA, 92831
Printed in China
8500 DC Load Series Version: November 4, 2008 Page 76 of 76
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Table of contents
- 2 Safety
- 2 Safety Symbols
- 5 Notation
- 6 Quick reference
- 6 Model numbers covered by this document
- 6 Options and accessories
- 6 Overview of instrument
- 7 Typical tasks
- 7 Front panel
- 9 Standard display
- 9 Front panel keys
- 10 Rear panel
- 11 Display annunciators
- 11 Menus
- 15 Specifications
- 16 Environmental Conditions
- 17 Internal Resistances
- 17 Operational power curve
- 18 Low Voltage Characteristics
- 19 Slew rate
- 20 As a reference, below is a table of slew rates for their respective models:
- 21 Glossary
- 23 Installation
- 23 Inspection
- 23 Items you should have received
- 23 Instrument location
- 23 Outline Drawings
- 23 Models: 8500& 8502
- 24 Models 8510, 8512, 8514 & 8518
- 24 Models 8520, 8522
- 25 Models 8524 & 8526
- 26 Bench operation
- 27 First turn-on checkout
- 28 Operational introduction
- 29 Power-on state
- 29 Constant current mode
- 30 Constant voltage mode
- 30 Constant power mode
- 31 Constant resistance mode
- 31 Timed operation
- 32 Changing display resolution
- 32 Increasing current resolution
- 32 Increasing voltage resolution
- 32 Short
- 32 Battery test
- 33 Transient operation
- 33 Continuous transient operation
- 34 Pulse transient operation
- 35 Toggled transient operation
- 36 Toggle between two test values
- 36 Lists (dynamic condition)
- 37 Test files
- 39 Triggering
- 40 Voltage threshold operation
- 40 Passwords
- 40 Protection features
- 41 Over Voltage protection
- 41 Over Current protection
- 41 Over Power protection
- 41 Reverse voltage protection
- 42 Over Temperature protection
- 42 Remote sensing
- 43 Saving and Recalling settings
- 44 Remote operation
- 44 Communication cables
- 44 RS232 to TTL serial converter cable IT-131 (standard)
- 44 USB to TTL serial converter cable IT-132 (option)
- 45 RS-232 settings
- 45 Overview of DC Load programming
- 45 Packet structure
- 46 Status packets
- 48 Chapter organization
- 49 Summary of commands
- 51 Command details
- 52 0x12 Indicates a return packet for a command sent to the DC Load
- 52 0x20 Set the DC Load to remote operation
- 52 0x21 Turn the load ON or OFF
- 52 0x22 Set the maximum voltage allowed
- 53 0x23 Read the maximum voltage allowed
- 53 0x24 Set the maximum current allowed
- 53 0x25 Read the maximum current allowed
- 54 0x26 Set the maximum power allowed
- 54 0x27 Read the maximum power allowed
- 54 0x28 Set CC, CV, CW, or CR mode
- 54 0x29 Read the mode being used (CC, CV, CW, or CR)
- 55 0x2A Set CC mode current
- 55 0x2B Read CC mode current
- 55 0x2C Set CV mode voltage
- 55 0x2D Read CV mode voltage
- 56 0x2E Set CW mode power
- 56 0x2F Read CW mode power
- 56 0x30 Set CR mode resistance
- 56 0x31 Read CR mode resistance
- 57 0x32 Set CC mode transient current and timing
- 57 0x33 Read CC mode transient parameters
- 57 0x34 Set CV mode transient voltage and timing
- 58 0x35 Read CV mode transient parameters
- 58 0x36 Set CW mode transient power and timing
- 58 0x37 Read CW mode transient parameters
- 59 0x38 Set CR mode transient resistance and timing
- 59 0x39 Read CR mode transient parameters
- 59 0x3A Select the list operation (CC/CV/CW/CR)
- 60 0x3B Read the list operation (CC/CV/CW/CR)
- 60 0x3C Set how lists repeat (ONCE or REPEAT)
- 60 0x3D Read how lists repeat (ONCE or REPEAT)
- 60 0x3E Set the number of list steps
- 60 0x3F Read the number of list steps
- 61 0x40 Set one of the step's current and time values
- 61 0x41 Read one of the step's current and time values
- 61 0x42 Set one of the step's voltage and time values
- 61 0x43 Read one of the step's voltage and time values
- 61 0x44 Set one of the step's power and time values
- 62 0x45 Set one of the step's power and time values
- 62 0x46 Read one of the step's resistance and time values
- 62 0x47 Read one of the step's resistance and time values
- 62 0x48 Set the list file name
- 62 0x49 Read the list file name
- 62 0x4A Set the memory partitioning for storing lists
- 63 0x4B Read the memory partitioning for storing list steps
- 63 0x4C Save the list file
- 63 0x4D Recall the list file
- 63 0x4E Set minimum voltage in battery testing
- 63 0x4F Read minimum voltage in battery testing
- 64 0x50 Set timer value of for LOAD ON
- 64 0x51 Read timer value for LOAD ON
- 64 0x52 Disable/enable timer for LOAD ON
- 64 0x53 Read timer state for LOAD ON
- 64 0x54 Set communication address
- 64 0x55 Enable/disable LOCAL control
- 65 0x56 Enable/disable remote sensing
- 65 0x57 Read the state of remote sensing
- 65 0x58 Select trigger source
- 65 0x59 Read trigger source
- 65 0x5A Trigger the electronic load
- 65 0x5B Save DC Load's settings
- 66 0x5C Recall DC Load's settings
- 66 0x5D Select FIXED/SHORT/TRAN/LIST/BATTERY function
- 66 0x5E Get function type (FIXED/SHORT/TRAN/LIST/BATTERY)
- 66 0x5F Read input voltage, current, power and relative state
- 67 0x60 Enter instrument calibration state
- 67 0x61 Get the instrument calibration state
- 68 0x62 Set voltage calibration point index
- 68 0x63 Send the actual voltage to the calibration program
- 68 0x64 Set current calibration point index
- 68 0x65 Send the actual current to the calibration program
- 68 0x66 Store the calibration data to EEPROM
- 69 0x67 Set calibration information
- 69 0x68 Read calibration information
- 69 0x69 Restore the factory default calibration data
- 69 0x6A Get product's model, serial number, and firmware version
- 69 0x6B Read the bar code information
- 71 Serial number and firmware version
- 72 In case of trouble
- 72 Instrument won't turn on
- 72 Error messages during power-up
- 72 Keypad unlock procedure (Keypad was accidentally locked)
- 74 Appendix: Service and warranty information
- 75 Index