Hardware Manual

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Hardware Manual

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Contents

1 Introduction........................................................................................................................................... 5

2

1.1

Board overview ........................................................................................................................................................ 7

What’s in the Box ................................................................................................................................. 8

3 Getting started ...................................................................................................................................... 9

3.1

Prerequisites ............................................................................................................................................................ 9

4

3.2

Starting the board for the first time ......................................................................................................................... 9

Dragonboard Overview .................................................................................................................. 10

4.1

System Block diagram ............................................................................................................................................ 10

4.2

Processor ............................................................................................................................................................... 10

4.3

Memory ................................................................................................................................................................. 10

4.4

MicroSDHC ............................................................................................................................................................. 10

4.5

WiFi/BT/RF ............................................................................................................................................................. 10

4.6

Display Interface .................................................................................................................................................... 11

4.6.1

HDMI .............................................................................................................................................................. 11

4.6.2

MIPI-DSI ......................................................................................................................................................... 11

4.7

Camera Interfaces .................................................................................................................................................. 11

4.8

USB Ports ............................................................................................................................................................... 12

4.8.1

USB-Host ports .............................................................................................................................................. 12

4.8.2

USB-Device port ............................................................................................................................................. 12

4.9

Audio ...................................................................................................................................................................... 13

4.9.1

BT Audio ........................................................................................................................................................ 13

4.9.2

HDMI Audio ................................................................................................................................................... 13

4.10

DC-power and Battery Power ................................................................................................................................ 13

4.11

Measurements ....................................................................................................................................................... 13

4.12

Buttons ................................................................................................................................................................... 13

4.13

External Fan connection......................................................................................................................................... 13

4.14

UART ...................................................................................................................................................................... 13

4.15

JTAG........................................................................................................................................................................ 13

4.16

System and user LEDs ............................................................................................................................................ 14

4.17

Expansion Connector ............................................................................................................................................. 14

4.18

Additional Functionality ......................................................................................................................................... 14

4.18.1

GPS ................................................................................................................................................................ 14

4.18.2

On Board Analog Microphone ....................................................................................................................... 14

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5

4.18.3

Analog Connector .......................................................................................................................................... 14

Low speed Expansion connector ................................................................................................. 15

5.1

UART {0/1} ............................................................................................................................................................. 16

5.2

I2C {0/1} ................................................................................................................................................................. 16

5.3

GPIO {A-L} .............................................................................................................................................................. 16

5.4

SPI 0 ....................................................................................................................................................................... 16

5.5

PCM/I2S ................................................................................................................................................................. 16

5.6

Power and Reset .................................................................................................................................................... 17

6

5.7

Power Supplies ....................................................................................................................................................... 17

High speed expansion connector ................................................................................................ 18

6.1

MIPI DSI 0 ............................................................................................................................................................... 19

6.2

MIPI CSI {0/1} ......................................................................................................................................................... 20

6.3

I2C {2/3} ................................................................................................................................................................. 20

6.4

HSIC ........................................................................................................................................................................ 20

6.5

Reserved ................................................................................................................................................................ 20

6.6

SD/SPI..................................................................................................................................................................... 20

6.7

Clocks ..................................................................................................................................................................... 20

7

6.8

USB ......................................................................................................................................................................... 20

Analog Expansion Connector ........................................................................................................ 21

7.1

Speaker .................................................................................................................................................................. 21

7.2

Mic ......................................................................................................................................................................... 21

7.3

Headset .................................................................................................................................................................. 21

8

7.4

FM Antenna ........................................................................................................................................................... 21

Power management ......................................................................................................................... 22

8.1

DC Power Input ...................................................................................................................................................... 22

8.2

Power Source Selection ......................................................................................................................................... 22

8.3

Power Consumption .............................................................................................................................................. 22

8.4

Power Sequencing.................................................................................................................................................. 23

8.5

Voltage Rails ........................................................................................................................................................... 23

9

8.6

Power Measurements ............................................................................................................................................ 23

8.6.1

Power-In measurement ................................................................................................................................. 23

8.6.2

PMIC Power-In measurement ....................................................................................................................... 23

Buttons and status LED’s ................................................................................................................ 24

9.1

Buttons ................................................................................................................................................................... 24

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9.1.1

Volume up ..................................................................................................................................................... 24

9.1.2

Volume down ................................................................................................................................................. 24

9.1.3

Power Button ................................................................................................................................................. 24

9.1.4

Reset Button .................................................................................................................................................. 24

9.2

LED’s ....................................................................................................................................................................... 24

9.2.1

User LED 1-4 .................................................................................................................................................. 24

9.2.2

Bluetooth status ............................................................................................................................................ 24

9.2.3

WiFi status ..................................................................................................................................................... 24

10 Boot configuration ............................................................................................................................ 25

11 Mechanical specification ................................................................................................................ 26

11.1

Board dimensions .................................................................................................................................................. 26

12 Special care when using USB......................................................................................................... 27

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1 Introduction

The DragonBoard 410c (‘410c’) board is a 96Boards compliant community board based on Qualcomm® Snapdragon 400 series of SoC’s.

The following table lists its key features:

Processor Qualcomm Snapdragon 410

Quad-core ARM® Cortex® A53 at up to 1.2 GHz per core

64-Bit capable

Qualcomm Adreno 306 400MHz GPU for PC-class graphics with support for advanced APIs, including OpenGL ES 3.0, OpenCL, DirectX, and content security

Memory/

Storage

Video

Camera Support

Audio

Connectivity

I/O Interfaces

External

Storage

1GB LPDDR3 533MHz

8GB eMMC 4.51

SD 3.0 (UHS-I)

1080p@30fps HD video playback and capture with H.264 (AVC), and 720p playback with H.265 (HEVC)

Integrated ISP with support for image sensors up to 13MP

PCM/AAC+/MP3/WMA, ECNS, Audio+ post-processing (optional)

WLAN 802.11b/g/n 2.4GHz

Bluetooth 4.1

One USB 2.0 micro B (device mode only)

Two USB 2.0 (host mode only)

GPS

On-board GPS antenna

On-board BT and WLAN antenna

One 40-pin Low Speed (LS) expansion connector

• UART, SPI, I2S, I2C x2, GPIO x12, DC power

One 60-pin High Speed (HS) expansion connector

• 4L-MIPI DSI, USB, I2C x2, 2L+4L-MIPI CSI

Footprint for one optional 16-pin analog expansion connector for stereo headset/ line-out, speaker and analog line-in

The board can be made compatible with Arduino using an add-on mezzanine board

Micro SD card slot

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User Interface

OS-support

Power,

Mechanical and

Environmental

Power/Reset

Volume Up/down

6 LED indicators

• 4 - user controllable

• 2 - for radios (BT and WLAN activity)

Android 5.1

Linux based on Ubuntu

Windows 10

IoT

Power: +6.5V to +18V

Dimensions: 54mm by 85mm meeting 96Boards™ Consumer Edition standard dimensions specifications.

Operating Temp: 0°C to +70°C

RoHS and Reach compliant

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1.1 Board overview

4.

5.

6.

1.

2.

3.

(J8) Low Speed Expansion Connector

APQ8016 Snapdragon Processor

(U9) Power Management PMIC

(J7) Analog Expansion Connector

WLAN/Bluetooth/GPS

(J1) Power Jack

7.

8.

(J5) uSD Card Socket

(J6) HDMI Type A Port

9. (J9) High Speed Connector

10. (J4) Micro USB Type B Connector

11. Bluetooth/WLAN LED’s

12. (J3) USB Host2 Connector

13. User LED’s 1-4

14. (J2) USB Host1 Connector

15. (S3-4) Vol+/Vol- Buttons

16. (S2) Power Button

17. Bluetooth/WLAN Antenna

18. GPS Antenna

19. (S6) Boot Switches

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2 What’s in the Box

The box contains one 410c board and a quick start guide.

Let’s Play.

8/27

3 Getting started

3.1 Prerequisites

Before you power up your 410c board for the first time you will need the following:

410c board.

A 96Boards compliant power supply (sold separately by Arrow).

A HDMI or DVI LCD Monitor that supports a resolution of 1080P/30Hz.

HDMI-HDMI cable or HDMI-DVI cable to connect the board to the Monitor.

A computer keyboard with USB interface

A computer mouse with USB interface.

3.2 Starting the board for the first time

To start the board, follow these simple steps: step 1. Connect the HDMI cable to the 410c HDMI connector (marked J6) and to the LCD Monitor. step 2. Connect the keyboard to the boards USB connector marked J3 and the mouse to the USB connector marked J2. (It doesn’t matter which order you connect them in. You can also connect via an external USB Hub.)

step 3.

step 4.

Ensure that the boot switches S6 are set to ‘0000’, all in Off position.

Connect the power supply to power connector J1.

Once you plug the power supply into a power outlet the board will start the booting process, and you should see Android boot up.

Please note that the first boot takes several minutes due to Androids initialization. Subsequent boot times should be faster.

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4 Dragonboard Overview

4.1 System Block diagram

4.2 Processor

The Snapdragon 410 APQ8016 is a quad 64-bit ARM Cortex-A53 MPcore Harvard Superscalar core, supports both LP-DDR2

/ LP-DDR3 SDRAM interface, Hexagon QDSP6, 13.5 MP camera input support, Adreno 306 GPU, 1080p video encode/decode, gpsOneGen 8C with GLONASS, Bluetooth 4.1, OpenGL ES 3.0, DirectX, OpenCL, Renderscript Compute,

FlexRender support.

4.3 Memory

The 410c uses a single embedded Multi Chip Package (eMCP) dual function LPDDR3/eMMC memory solution. The installed chip provides 8Gbyte of solid state storage and 1Gbyte of LPDDR3.

The LPDDR3 is a 32bit width bus implementation interfacing directly to the APQ8016 build-in LPDDR controller.

The maximum DDR clock is 533Mhz

The eMMC is an 8bit implementation interfacing with APQ8016 SDC1 interface supporting eMMC 4.5 specifications.

4.4 MicroSDHC

The 96Boards specification calls for a microSDHC socket to be present on the board.

The 410c board

SD slot (J5) signals are routed directly to the APQ8016 SDC2 interface. The slot is a push-push type with a dedicated support for card detect signal (many

SD slots do not have a dedicated CD pins, they use DATA3 state as the card detected signal). The 410c board uses APQ GPIO_38 as the SD_CARD_DET_N.

4.5 WiFi/BT/RF

The 96Boards specifications calls for a WiFi (minimally 802.11g/n) and Bluetooth 4.1 (Bluetooth Low Energy)

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The 410c board deployed Qualcomm’s RF chip WCN3620 (U5) solution that integrates three different wireless connectivity technologies into a single device, the interfaces are:

WLAN compliant with IEEE 802.11 b/g/n specifications, meeting 96Boards minimal requirements for WiFi.

Bluetooth compliant with the BT specifications version 4.1 (BR/EDT + BLE), meeting the 96Boards requirements for BT

Worldwide FM radio, this interface is not part of the 96Boards mandatory specification. It is an optional addition that has not been tested is not officially supported.

4.6 Display Interface

4.6.1 HDMI

The 96Boards specification calls for an HDMI port to be present on the board. The APQ8016 doesn’t include a built-in

HDMI interface. The 410c deploys the built-in MIPI-DSI 4 lanes interface as the source for the HDMI output. A peripheral

DSI to HDMI Bridge (U3, Analog Devices ADV7533) performs this task and it supports a resolution from 480i to 1080p at

30Hz.

While the ADV7533 supports automatic input video format timing detection (CEA-861E), an I2C channel from the APQ8016 allows the user to configure the operation of this bridge. It is I2C3 interface from the SoC that connects to the bridge.

This bridge supports audio as well (meeting the 96Boards requirements to provide audio via HDMI). The 410c uses a single bit I2S2 interface from the APQ8016 for this task.

Please note that the 96Boards specification calls for a MIPI-DSI interface to be routed to the High Speed Expansion connector. Since the APQ8016 has only one MIPI-DSI interface. A muxing device (U11, FSA644UCX) is being use on the board. Only one interface, HDMI, or the Expansion MIPI-DSI can be active at a given time. The controlling signal is named

‘DSI_SW_SEL_APQ’. When this signal is logic low, ‘0’, the MIPI-DSI is routed to the DSI-HDMI Bridge. When

‘DSI_SW_SEL_APQ’ is logic level high, ‘1’, the MIPI-DSI is routed to the High Speed Expansion connector. This design assigned the ‘DSI_SW_SEL_APQ’ function to GPIO_32.

User can overwrite the software control by sliding switch 4 of DipSwitch S6 to the ‘ON’ position. That action forces the DSI mux to route the MIPI-DSI to the DSI-HDMI Bridge. The overwrite option exist for the HDMI only, you cannot hardware overwrite the mux to the High Speed Expansion connector.

4.6.2 MIPI-DSI

The 96Boards specification calls for a MIPI-DSI implementation via the High Speed Expansion Connector.

The 410c implemented a four-lane MIPI_DSI interface meeting this requirement. More information about this

implementation can be found in chapter 6 High speed expansion connector.

4.7 Camera Interfaces

The 96Boards specification calls for two camera interfaces.

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The 410c implements two camera interfaces, one with a four-lane MIPI_CSI interface and one with two-lane MIPI_CSI

interface, meeting this requirement. More information about this implementation can be found in chapter 6 High speed expansion connector.

4.8 USB Ports

4.8.1 USB-Host ports

The 96Boards specification calls for three USB host ports. The APQ8016 includes a single USBOTG channel. A USB Mux, S1, routes this single USB channel either to a USB HUB or to the MicroUSB connector (J4). The control of S1 is done via a software controlled GPIO (USB_SW_SEL_PM, GPIO_4 from the board PMIC). When this signal is logic low, ‘0’, the USB data lines are routed to the MicroUSB connector and the APQ8016 built-in USBOTG port is set to device mode. When

‘USB_SW_SEL_PM’ is logic level high, ‘1’, the USB data lines are routed to U10 (a 3-port USB HUB) and the APQ8016 builtin USBOTG port is set to host mode. The user can overwrite the software control by sliding switch 3 of DipSwitch S6 to the

‘ON’ position. That action forces the USB–mux S1 to route the built-in USBOTG data lines to the USB HUB. The overwrite option exists for the host mode only, you cannot hardware overwrite the mux to force device mode.

Port 1 of the USB HUB is routed to J3, a Type ‘A’ USB Host connector. A current limited controller (U4) sets the Power

Current limit to 1.18A. This port is named HOST2 in the board schematic.

Port 2 of the USB HUB is routed to J2, a Type ‘A’ USB Host connector. A current limited controller (U6) sets the Power

Current limit to 1.18A. This port is named HOST1 in the board schematic.

Port 3 of the USB HUB is routed to the High Speed Expansion connector. No current limited controller is implemented on the board for this channel.

Please note: the board can work in one mode at a time, Host mode or Device mode, not both.

Please note: Since the APQ8016 has only a single USBOTG channel, care needs to be taken when the USB HOST function is to be used. Please verify that no cable is connected to the MicroUSB type B connector (and to a host on the other side of the cable) as the hardware of the 410c board will inform software about the presence of a request to configure the

USBOTG to device mode. Depending on the software release that is used on the board, the driver may configure the USB

Mux to Device mode and none of the USB HOST ports will be connected to the SoC.

4.8.2 USB-Device port

The 96Boards specification calls for a USB port to be implemented as an OTG port or a device port.

The 410c board implements a device port. The port is located at J4, a MicroUSB type B. If an application requires the use of the device port, USB_SW_SEL_PM signal must be set to low ‘0’ and the user must verify that switch 3 of Dip Switch S6 is set to the ‘OFF’ position.

Please note: the board can work in one mode at a time, Host mode or Device mode, not both.

12/27

4.9 Audio

The 96Boards specifications calls for a minimum of single channel audio through two interfaces, BT and

HDMI/MHL/DisplayPort

The 410c meets this requirement and has additional audio channels. More information about these additional channels

can be found in chapter 4.18 Additional Functionality.

4.9.1 BT Audio

The BT implementation on the 410c is via a MAC in the APQ8016 and an external modem, WCN3620 (U5). A two wire interface between the SoC and the modem carries all communication including audio.

4.9.2 HDMI Audio

A 3-wire (audio out only) I2S channel is routed directly from the APQ8016 SoC I2S interface pins to the DSI-HDMI bridge

(U3).

4.10 DC-power and Battery Power

The 96Boards specification calls for power to be provided to the board in one of the following ways:

An 8V to 18V power from a dedicated DC jack

An 8V to 18V power from the SYS_DCIN pins on the Low Speed Expansion Connector

A USB Type C port at 5V

Please see section 9.1 for detailed information on 410c implementation of DC Power

4.11 Measurements

The 96Boards specification calls for support for measuring power consumptions of the board.

Please see section 8.6 for detailed information on 410c power measurement implementation.

4.12 Buttons

The 96Boards specification calls for the present of two buttons, a Power on/sleep button and a Reset button.

The 410c meets these requirements. Please see section 10 for detailed information on the buttons of the 410c board.

4.13 External Fan connection

The 96Boards specification calls for support for an external fan. That can be achieved by using the 5V or the SYS_DCIN, both present on the Low Speed Expansion connector.

4.14 UART

The 96Boards specification calls for support for one SoC UART and an optional second UART both to be routed to the Low

Speed Expansion Connector.

The 410c meets these requirements and additionally routes UART0 Tx/Rx lines to an on-board connector (J15). If the user wants to use this on-board UART, J15 needs to be soldered to the board as well as R173 and R174 (0 ohm 0201).

4.15 JTAG

The 96Boards specification does not call for a dedicated JTAG connector. However the Dragonboard has JTAG and UART signals routed to J15. The J15 connector does not have a standard JTAG connector pitch and is not populated on the board.

13/27

4.16 System and user LEDs

The 96Boards specifications calls for six LEDs to be implemented on the board. The specification defines the LEDs color and mechanical location on the board.

Two activity LEDs:

• WiFi activity LED – 410c board drives this Yellow LED via MPP_2, an IO from the PMIC.

• BT activity LED – 410c board drives this Blue LED via MPP_3, an IO from the PMIC.

Four User-LED’s:

The four user LEDs are surface mount Green in 0603 size located next to the two USB type A connector and labeled ‘USER

LEDS 4 3 2 1’. The 410c board drives two LEDs from the SoC GPIO, APQ GPIO_21 and APQ GPIO_120. The other two User

LEDs are driven by the PMIC via PM GPIO_1 and PM GPIO_2.

4.17 Expansion Connector

The 96Boards specification calls for two Expansion Connectors, a Low Speed and a High Speed.

The 410c meets this requirement, please review section 6.0 for detailed information regarding the Low Speed Expansion

Connector and section 7.0 for detailed information regarding the High Speed Expansion Connector.

4.18 Additional Functionality

The 96Boards specifications allows for additional functionality provided that all mandatory functionality is available and there is no impact on the physical footprint specifications including height and do not prevent the use of the 96Boards CE low speed and high speed expansion facilities

The 410c board implements a few additional functions, which are listed in the following sub-chapters.

4.18.1 GPS

The GPS implementation is based on Qualcomm WGR7640 GNSS RF receiver (U7) supporting GPS, GLONASS and

COMPASS. The APQ8016 communicates directly with the WGR7640.

4.18.2 On Board Analog Microphone

Information on the on board microphone can be found in section 8.2.

4.18.3 Analog Connector

Detailed information on the analog connector is provided in section 8.0.

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5 Low speed Expansion connector

The following tables show the Low Speed Expansion Connector pin out:

9

11

13

15

17

19

21

23

3

5

7

1

PIN

25

27

29

31

33

35

37

96Boards Signals

GND

UART0_CTS

UART0_TxD

UART0_RxD

UART0_RTS

UART1_TxD

UART1_RxD

I2C0_SCL

I2C0_SDA

I2C1_SCL

I2C1_SDA

GPIO-A

GPIO-C

GPIO-E

GPIO-G

GPIO-I

GPIO-K

+1V8

+5V

39 GND

PIN 96Boards Signals

2

4

6

GND

PWR_BTN_N

RST_BTN_N

8 SPI0_SCLK

10 SPI0_DIN

12 SPI0_CS

14 SPI0_DOUT

16 PCM_FS

18 PCM_CLK

20 PCM_DO

22 PCM_DI

24 GPIO-B

26 GPIO-D

28 GPIO-F

30 GPIO-H

32 GPIO-J

34 GPIO-L

36 SYS_DCIN

38 SYC_DCIN

40 GND

GND

410c Signals

UART0_CTS_N (APQ GPIO_2)

UART0_TX (APQ GPIO_0)

UART0_RX (APQ GPIO_1)

UART0_RTS_N (APQ GPIO_3)

UART1_TX (APQ GPIO_4)

UART1_RX (APQ GPIO_5)

I2C0_SCL (APQ GPIO_7)

I2C0_SDA (APQ GPIO_6)

I2C1_SCL (APQ GPIO_23)

I2C1_SDA (APQ GPIO_22)

LS_EXP_GPIO_A (APQ GPIO_36) (APQ INT)

LS_EXP_GPIO_C (APQ GPIO_13) (TS_INT_N)

LS_EXP_GPIO_E (APQ GPIO_115) (GYRO_ACCL_INT_N)

LS_EXP_GPIO_G (APQ GPIO_24) (DSI_VSYNC)

LS_EXP_GPIO_I (APQ GPIO_35) (CSI0_RST)

LS_EXP_GPIO_K (APQ GPIO_28) (CSI1_RST)

LS_EXP_1P8

SYS_5P0

GND

410c Signals

GND

PHONE_ON_N

PM_RESIN_N

SPI0_CLK (APQ GPIO_19)

SPI0_MISO (APQ GPIO_17)

SPI0_CS_N (APQ GPIO_18)

SPI0_MOSI (APQ GPIO_16)

LS_EXP_MI2S_WS (APQ GPIO_110)

LS_EXP_MI2S_SCK (APQ GPIO_113) (ALPS_INT)

LS_EXP_MI2S_DATA0 (APQ GPIO_114)

N.C.

LS_EXP_GPIO_B (APQ GPIO_12) (TS_RST_N)

LS_EXP_GPIO_D (APQ GPIO_69) (MAG_INT)

LS_EXP_GPIO_F (PM_MPP_4) (DSI_BLCTRL))

LS_EXP_GPIO_H (APQ GPIO_25) (DSI_RST)

LS_EXP_GPIO_J (APQ GPIO_34) (CSI0_PWDN)

LS_EXP_GPIO_L (APQ GPIO_33) (CSI1_PWDN)

SYS_DCIN

SYS_DCIN

GND

Note

Note

I2S only supports audio out

Borrowed GPIO from PMIC

15/27

5.1 UART {0/1}

The 96Boards specifications calls for a 4-wire UART implementation, UART0 and an optimal second 2-wire UART, UART1 on the Low Speed Expansion Connector.

The 410c board implements UART0 as a 4-wire UART that connects directly to the APQ8016 SoC. These signals are driven at 1.8V.

The 410c board implements UART1 as a 2-wire UART that connects directly to the APQ8016 SoC. These signals are driven at 1.8V.

5.2 I2C {0/1}

The 96Boards specification calls for two I2C interfaces to be implemented on the Low Speed Expansion Connector.

The 410c board implements both interfaces, I2C0 and I2C1 that connects directly to the APQ8016SoC. A 2K resistor is provided as pull-up for each of the I2C lines per the I2C specifications, these pull-ups are connected to the 1.8V voltage rail.

5.3 GPIO {A-L}

The 96Boards specifications calls for 12 GPIO lines to be implemented on the Low Speed Expansion Connector. Some of these GPIOs may support alternate functions for DSI/CSI control

The 410c board implements this requirement. 11 GPIOs are routed to the APQ8016 SoC and one GPIO is connected to the on-board PMIC.

GPIO A - Connects to GPIO_36 of APQ8016 SoC, can serves as AQP_INT supporting the 96Boards requirements to create a wake-up event for the SoC. It is a 1.8V signal

GPIO B - Connects to GPIO_12 of APQ8016 SoC. It is a 1.8V signal

GPIO C - Connects to GPIO_13 of APQ8016 SoC. It is a 1.8V signal. Can be configured to be an IRQ line

GPIO D - Connects to GPIO_69 of APQ8016 SoC. It is a 1.8V signal. Can be configured to be an IRQ line

GPIO E - Connects to GPIO_115 of APQ8016 SoC. It is a 1.8V signal. Can be configured to be an IRQ line

GPIO F - Connects to MPP_4 of PM8916 PMIC. It is a 1.8V signal. Can be configured to be the DSI backlight control

GPIO G - Connects to GPIO_24 of APQ8016 SoC. It is a 1.8V signal. Can be configured to be DSI VSYNC signal.

GPIO H - Connects to GPIO_25 of APQ8016 SoC. It is a 1.8V signal. Can be configured to be a DSI_RST signal.

GPIO I - Connects to GPIO_35 of APQ8016 SoC. It is a 1.8V signal. Can be configured to be a CSI0_RST signal.

GPIO J - Connects to GPIO_34 of APQ8016 SoC. It is a 1.8V signal. Can be configured to be a CSI0_PWDN signal.

GPIO K - Connects to GPIO_28 of APQ8016 SoC. It is a 1.8V signal. Can be configured to be a CSI1_RST signal.

GPIO L - Connects to GPIO_33 of APQ8016 SoC. It is a 1.8V signal. Can be configured to be a CSI1_PWDN signal.

5.4 SPI 0

The 96Boards specification calls for one SPI bus master to be provided on the Low Speed Expansion Connector.

The 410c board implements a full SPI master with 4 wires, CLK, CS, MOSI and MISO all connect directly to the APQ8016

SoC. These signals are driven at 1.8V.

5.5 PCM/I2S

The 96Boards specification calls for one PCM/I2S bus to be provided on the Low Speed Expansion Connector. The CLK, FS and DO signals are required while the DI is optional.

The 410c board implements a PCM/I2S with 3 wires, CLK, FS and DO, the optional DI signal is not implemented on the 410c board. The I2S signals are connected directly to the APQ8016 SoC. These signals are driven at 1.8V.

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5.6 Power and Reset

The 96Boards specification calls for a signal on the Low Speed Expansion Connector that can power on/off the board and a signal that serves as a board reset signal.

The 410c board routes the PWR_BTN_N (named PHONE_ON_N on 410c schematic) signal to the KYPDPWR_N pin of the

PM8916 PMIC. This signal is driven by S2 as well, the on-board power on push-button switch. Please note that the push button only provides an On/Sleep function and not OFF functionality.

A mezzanine implementation of this signals should not drive it with any voltage, the only allowed operation is to force it to

GND to start the board from a sleep mode. A board shutdown will occur when this signal is held to ground for more than

15 seconds (based on the current Android release).

The 410c board routes the RST_BTN_N (named PM_RESIN_N on 410c schematic) signal to the RESIN_N pin of the PM8916

PMIC. This signal is driven by S4, the on-board reset switch. This signals is a dual purpose, any press lasting less than 10 seconds serves as Volume Down or Zoom out, a press longer than 10 seconds will reset the board.

5.7 Power Supplies

The 96Boards specification calls for three power rails to be present on the Low Speed Expansion Connector:

+1.8V : Max of 100mA

+5V : Able to provide a minimum of 5W of power (1A).

SYS_DCIN : 9-18V input with enough current to support all the board functions or the output DCIN from onboard DC Connector able to provide a minimum of 7W of power.

The 410c board supports these requirements as follows:

+1.8V : Driven by two PMIC LDOs, LDO15 and LDO16, each can provide 55mA. The PM8916 allows connecting the two

LDOs in parallel to provide 110mA on a 1.8V rail which meets the 96Boards requirement.

+5V : Driven by the 4A 5.0V buck switcher (U13). This buck switcher powers both USB limit current devices (each at

1.18A max). The remaining capacity provides a max current of 1.64A to the Low Speed Expansion Connector, for a total of

8.2W which meets the 96Boards requirements.

SYS_DCIN: Can serves as the board’s main power source or can receive power from the board.

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6 High speed expansion connector

The following table shows the High Speed Expansion Connector pin out:

18

20

22

24

26

28

30

8

10

12

14

16

2

4

6

29

31

33

35

37

39

41

17

19

21

23

25

27

PIN

1

3

11

13

15

5

7

9

43

45

47

49

51

53

55

57

59

PIN

96Boards Signals 410c Signals

SD_DAT0/SPI1_DOUT SPI1_MOSI (APQ GPIO_8)

SD_DAT1 N.C.

SD_DAT2

SD_DAT3/SPI1_CS

SD_SCLK/SPI1_SCLK

SD_CMD/SPI1_DIN

GND

CLK0/CSI0_MCLK

N.C.

SPI1_CS_N (APQ GPIO_10)

SPI1_CLK (APQ GPIO_11)

SPI1_MISO (APQ GPIO_9)

GND

CSI0_MCLK (APQ GPIO_26)

CLK1/CSI1_MCLK

GND

DSI_CLK+

DSI_CLK-

GND

DSI_D0+

DSI_D0-

GND

DSI_D1+

DSI_D1-

GND

DSI_D2+

DSI_D2-

CSI1_MCLK (APQ GPIO_27)

GND

MIPI_DSI0_CLK_P_EXP_CONN

MIPI_DSI0_CLK_M_EXP_CONN

GND

MIPI_DSI0_DATA0_P_EXP_CONN

MIPI_DSI0_DATA0_M_EXP_CONN

GND

MIPI_DSI0_DATA1_P_EXP_CONN

MIPI_DSI0_DATA1_M_EXP_CONN

GND

MIPI_DSI0_DATA2_P_EXP_CONN

MIPI_DSI0_DATA2_M_EXP_CONN

GND

DSI_D3+

DSI_D3-

GND

USB_D+

USB_D-

GND

HSIC_STR

HSIC_DATA

GND

MIPI_DSI0_DATA3_P_EXP_CONN

MIPI_DSI0_DATA3_M_EXP_CONN

GND

USB_HS_D_P_EXP

USB_HS_D_M_EXP

GND

N.C.

N.C.

96Boards Signals

CSI0_C+

CSI0_C-

GND

CSI0_D0+

CSI0_D0-

GND

CSI0_D1+

CCSI0_D1-

GND

CSI0_D2+

CSI0_D2-

GND

CSI0_D3+

CSI0_D3-

GND

MIPI_CSI0_CLK_M

GND

MIPI_CSI0_DATA0_P

MIPI_CSI0_DATA0_M

GND

MIPI_CSI0_DATA1_P

MIPI_CSI0_DATA1_M

GND

MIPI_CSI0_DATA2_P

MIPI_CSI0_DATA2_M

GND

MIPI_CSI0_DATA3_P

MIPI_CSI0_DATA3_M

GND

410c Signals

MIPI_CSI0_CLK_P

Note

This is a SPI implementation. not an SD interface

No HSIC implementation

Note

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42

44

46

48

50

32

34

36

38

40

52

54

56

58

60

6.1 MIPI DSI 0

I2C2_SCL

I2C2_SCL

I2C3_SDA

I2C3_SDA

GND

CSI1_D0+

CSI1_D0-

GND

CSI1_D1+

CSI1_D1-

GND

CSI1_C+

CSI1_C-

GND

RESERVED

I2C2_SCL (APQ GPIO_30)

I2C2_SDA (APQ GPIO_29)

I2C3_SCL (APQ GPIO_15)

I2C3_SDA (APQ GPIO_14)

GND

MIPI_CSI1_DATA0_P

MIPI_CSI1_DATA0_M

GND

MIPI_CSI1_DATA1_P

MIPI_CSI1_DATA1_M

GND

MIPI_CSI1_CLK_P

MIPI_CSI1_CLK_M

GND

N.C.

R61 & R62 need to be

Installed to enable I2C3

The 96Boards specification calls for a MIPI-DSI to be present on the High Speed Expansion Connector. A minimum of one lane is required and up to four lanes can be accommodated on the connector.

The 410c board implementation supports a full four lane MIPI-DSI interface that is routed to the High Speed Expansion

Connector. Since the APQ8016 has only single MIPI-DSI interface and it may be used to drive the DSI-HDMI Bridge, DSI muxing is required.

A muxing device, U11 (FSA644UCK) is used on the board. Only one interface, HDMI, or the Expansion MIPI-DSI can be active at a given time. The controlling signal is named ‘DSI_SW_SEL_APQ’. When this signal is logic low, ‘0’, the MIPI-DSI is routed to the DSI-HDMI Bridge.

When ‘DSI_SW_SEL_APQ’ is logic level high, ‘1’, the MIPI-DSI is routed to the High Speed Expansion connector. This design assigned the ‘DSI_SW_SEL_APQ’ function to GPIO_32.

The user can override the software control by sliding switch 4 of DipSwitch S6 to the ‘ON’ position. That action forces the

DSI mux to route the MIPI-DSI to the DSI-HDMI Bridge. The override option exists for HDMI only. You cannot force the mux to the High Speed Expansion connector. While hardware forces the ESI Mux to the HDMI, software must configure the

HDMI bridge for proper functionality.

Please note: If configuring the board to use the MIPI-DSI is done via software, the user must verify the switch 4 of

DipSwitch S6 is set to the ‘off’ position

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6.2 MIPI CSI {0/1}

The 96Boards specification calls for two MIPI-CSI interfaces to be present on the High Speed Expansion Connector. Both interfaces are optional. CSI0 interface can be up to four lanes while CSI1 is up to two lanes.

The current 410c board implementation supports a full four lane MIPI-CSI interface on CSI0 and two lanes of MIPI-CSI on

CSI1. All MIPI-CSI signals are routed directly to/from the APQ8016.

6.3 I2C {2/3}

The 96Boards specification calls for two I2C interfaces to be present on the High Speed Expansion Connector. Both interfaces are optional unless a MIPI-CSI interface has been implemented. Then an I2C interface shall be implemented.

The current 410c board implementation supports two MIPI-CSI interfaces and therefore must support two I2C interfaces.

For MIPI-CSI0 the companion I2C2 is routed directly from the APQ8016. For MIPI-CSI1, the companion I2C is I2C3.

Note: You will need to add R61 and R62, 0 ohm 0201 resistors, to the board to support the routing of I2C3 interface to the

High Speed Expansion Connector. Both interfaces, I2C2 and I2C3 have an on-board 2K pull-up resistors pulled-up to the

1.8V voltage rail.

6.4 HSIC

The 96Boards specification calls for an optional MIPI-HSIC interface to be present on the High Speed Expansion Connector.

The 410c board implementation doesn’t support this optional requirement.

6.5 Reserved

The 96Boards specification calls for a 10K pull-up to 1.8V to be connected to pin 60 of the High Speed Expansion

Connector.

The current 410c board implementation does not support this requirement. This issue will be addressed on a future revision of the 410c board.

6.6 SD/SPI

The 96Boards specification calls for an SD interface or a SPI port to be part of the High Speed Expansion Connector.

The 410c board implements a full SPI master with 4 wires (96Boards SPI Configuration), CLK, CS, MOSI and MISO all connect directly to the APQ8016 SoC. These signals are driven at 1.8V.

6.7 Clocks

The 96Boards specification calls for one or two programmable clock interfaces to be provided on the High Speed Expansion

Connector. These clocks may have a secondary function of being CSI0_MCLK and CSI1_MCLK. If these clocks can’t be supported by the SoC than an alternative GPIO or No-Connect is allowed by the specifications.

The 410c board implements two CSI clocks, CSI0_MCLK via APQ GPIO_26 and CSI1_MCLK via APQ GPIO_27. These signals are driven at 1.8V.

6.8 USB

The 96Boards specification calls for a USB Data line interface to be present on the High Speed Expansion Connector.

The 410c board implements this requirements by routing USB channel 3 from the USB HUB to the High Speed Expansion

Connector.

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7 Analog Expansion Connector

7

8

9

4

5

6

PIN

1

2

3

1

0

11

12

13

14

15

16

Function

SPKR_OUT_P

SPKR_OUT_M

VPH_PWR

GND

GND_CFILT

CDC_MIC2_P

CDC_MIC3_P

CDC_HPH_R

CDC_HPH_REF

CDC_HPH_L

CDC_HS_DET

CDC_MIC_BIAS1

N.C.

N.C.

N.C.

FM_RX_ANT

N.C.

Connect to

PM8916 Audio signal CDC_SPKDRV_P

PM8916 Audio signal CDC_SPKDRV_M

A 3.7V from U12 buck switcher

PM8916 Audio signal CDC_GND_CFILT

PM8916 Audio signal CDC_IN2_P

PM8916 Audio signal CDC_IN3_P

PM8916 Audio signal CDC_HPH_R

PM8916 Audio signal CDC_HPH_REF

PM8916 Audio signal CDC_HPH_L

PM8916 Audio signal CDC_HS_DET

PM8916 Audio signal CDC_MIC_BIAS1

WCN3620 RF signal FM_HS_RX

Note

Datasheet pin SPKR_DRV_P

Datasheet pin SPKR_DRV_M

Datasheet pin MIC2_IN

Datasheet pin MIC3_IN

7.1 Speaker

The speaker signals are routed from the PM8916 PMIC built-in Audio CODEC, the two signals are:

SKPR_DRV_P - Class-D speaker amplifier output+

SKPR_DRV_M - Class-D speaker amplifier output-

7.2 Mic

The microphone signals are rounded to the PM8916 PMIC Built-In CODEC, the three signals are:

MIC2_IN - Headset mic

MIC3_IN - Second mic, please note that the first microphone input, MIC1_IN is routed from an on-board analog microphone (not installed on current 410c builds)

MIC_BIAS1 - Ground reference for PMIC bias

7.3 Headset

The headset signals are rounded from the PM8916 PMIC Built-In CODEC, one signal is routed from the connector to the

CODEC, the singles are:

HPH_R - Headphone PA right channel output

HPH_L - Headphone PA left channel output

HPH_REF - Headphone PA ground sensing

HS_DET - Headset detection

7.4 FM Antenna

The FM_RX_ANT signal is the path for the FM antenna to reach the WCN3620 (u5), an integrated three different connectivity technologies device:

WLAN IEE802.11 b/g/n

BT 4.0 (BR/EDR/BLE)

Worldwide FM radio

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8 Power management

The 96Boards specification defines how power arrives to the board and few supplies that the board needs to provide. The on board power requirement for each 96Boards implementation depends on the SoC and the set of peripherals that are specific to that implementation.

The 410c board uses two buck regulators, U13 and U12. U13 takes the power in to the board and generates 5V at 4A. This voltage feeds the USB HOST power limit switches and provides power to the Low Speed Expansion port. U12 takes the power in to the board and generates 3.7V at 4A. This voltage serves as the power in voltage to the on-board PMIC,

PM8916 (U9). The PM8916 can generate 25 different voltage rails.

8.1 DC Power Input

The 96Boards specification calls for a power to be provided to the board in one of the following ways:

An 8V to 18V power from a dedicated DC jack.

The 410c board supports this requirement through the use of J1, ‘SYS_DCIN’ power connector.

Please note: the SYS_DCIN can be as low as 6.5V on the 410c board.

An 8V to 18V power from the SYS_DCIN pins on the Low Speed Expansion Connector.

Please note: the SYS_DCIN can be as low as 6.5V on the 410c board.

The 410c board supports incoming power through this connector.

A USB Type C port at 5V.

Please note: The 410c board does not implement a USB Type C port and therefore cannot be powered over USB.

8.2 Power Source Selection

Following the information in section 9.1, the 410c board has only two sources for board incoming power. The 96Boards specification calls for only one power source to be applied to the board at any given time. Following this requirement,

the user of the 410c board should never apply power to the board from J1 and the Low Speed Expansion connector at the same time

. There is no active or passive mechanism on the 410c board to prioritize one source over the other.

8.3 Power Consumption

TBD

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8.4 Power Sequencing

Upon applying power to the 410c board (either one of the two sources), both buck regulators will be enabled and will start regulating their target voltages. When the output of U12 is on, it will power the on-board PMIC, the PM8916. This PMIC has four buck regulators, one boost regulator and 20 LDOs. The sequencing of all power rails is set within the PM8916 configuration scheme during the production of this part. The user has no access to alter, modify or change the PMIC power up sequencing.

8.5 Voltage Rails

Please see section 10 for detailed list of the power rails on the 410c board.

8.6 Power Measurements

The 96Boards specification calls for a minimum of one current sense resistor to be placed on the board permitting a basic power measurement functions.

The 410c implements two different power measurements.

8.6.1 Power-In measurement

A 0.1ohm resistor is placed inline to the SYS_DCIN power line coming from J1 (please note that this power in measurement only works for SYS_DCIN from J1, it will not measure SYS_DCIN applied from the Low Speed Expansion Connector). Placing a probe over this resistor will provide a voltage measurement of the voltage drop across the resistor. Dividing this measurement by 0.1 will give you the amount of the current flowing into the board. The board provides a means to use

ARM Energy probe for this measurement, please verify that JP3 and JP4 are each shorted and J10 is soldered to the board to take advantage of this probe.

8.6.2 PMIC Power-In measurement

A 0.1ohm resistor should replace the existing inline 0 ohm resistor on VPH_PWR line, the output of U12 buck regulator that feeds the PMIC. Placing a probe over this resistor will provide a voltage measurement of the voltage drop across the resistor. Dividing this value by 0.1 will give you the amount of the current flowing into the PMIC. The board provides a means to use an ARM Energy probe for this measurement, the following steps are requires to get this probe measuring this rail:

1. Remove R122 and R123 from the board to prevent a short between SYS_DCIN and VPH_PWR

2. J10 needs to be soldered to the board.

3. R124 and R125, 0 ohm 0201 resistors, need to be soldered to the board.

23/27

9 Buttons and status LED’s

9.1 Buttons

9.1.1 Volume up

The Volume UP button is used to control the output speaker volume of the 410c Board.

9.1.2 Volume down

The Volume Down button is used to control the output speaker volume of the 410c Board.

9.1.3 Power Button

The push-button S2 serves as the power-on/sleep button. Upon applying power to the board, the boot process will start.

Once the board is running you can turn power-off by pressing the power button for more than x seconds. If the board is in a sleep mode, pressing the power bottom for more than 3 seconds will wake up the board.

9.1.4 Reset Button

The on-board S4 push-button has two functions, it serves as a reset button and as a Volume/Zoom- button.

A button press with duration of less than 10 second will be interpreted by software as a volume down or zoom out request. Duration of more than 10 seconds will cause a system reset.

9.2 LED’s

There are two status LEDs and four User LEDs on the 410c board. The Status LEDs report the status of the Bluetooth and

Wi-Fi devices onboard. The user LEDs are driven by the SoC directly.

9.2.1 User LED 1-4

The four user LEDs are surface mount Green LED, 0603 size, located next to the two USB type A connector and labeled

‘USER LEDS 4 3 2 1’.

9.2.2 Bluetooth status

The BT LED on the 410c board is located next to the USBOTG connector; this LED reflects the status of the Bluetooth device.

9.2.3 WiFi status

The WIFI LED on the 410c is located beside the BT LED, this LED reflects the status of the Wi-Fi device.

24/27

10 Boot configuration

There is a 4 switch DipSwitch marked S6 located at the bottom side of the 410c board. For normal operation all four switched need to be set to the ‘off’ position.

Switch 1, ‘USB BOOT’, when set to ‘on’ position, will force boot over USB connection with a PC. This is only required for eMMC boot image upgrade. Please review the proper OS User Guide for more information on this process.

Switch 2, ‘SD BOOT’, when set to ‘on’ position, will force the

SD, J5, to serve as the boot source for the 410c board when set. You can use uSD as the main boot source or it can serve as a method for eMMC boot image upgrade. Please review the proper OS User Guide for more information on this process.

Switch 3, ‘USB HOST’, is described in section 5.8. This switch in not part of the boot configuration.

Switch 4, ‘HDMI SEL’, is described in section 5.6.1. This switch is not part of the boot configuration.

25/27

11 Mechanical specification

11.1 Board dimensions

26/27

12 Special care when using USB

Since the APQ8016 has a single USBOTG channel, care needs to be taken when the USB HOST function is to be used.

Please verify that no cable is connected to the MicroUSB type B connector (and to a host on the other side of the cable) as the hardware of the 410c board will inform software about the presence of a request to configure the USBOTG to device mode. Depending on the software release that is used on the board, the driver may configure the USB Mux to Device mode and none of the USB HOST ports will be connected to the SoC.

27/27

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