Nvidia Computer Hardware DG 04927 001

USER GUIDE

Tegra^™200 Series Developer Board

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Table of Contents

1.0 INTRODUCTION ....................................................................................................................................................................5

2.0 DEVELOPER BOARD OVERVIEW........................................................................................................................................6

2.1 Feature List ........................................................................................................................................................................6

2.2 NVIDIA® Tegra™ 25 0 ........................................................................................................................................................8

2.3 System DRA M ....................................................................................................................................................................8

2.4 Boot Devic e ........................................................................................................................................................................8

2.5 LCD Interface .....................................................................................................................................................................9

2.6 External Display Suppor t ....................................................................................................................................................9

2.7 Audio ..................................................................................................................................................................................9

2.8 US B ....................................................................................................................................................................................9

2.9 Storage.............................................................................................................................................................................10

2.10 Camera (optional)...........................................................................................................................................................10

2.11 Wireless..........................................................................................................................................................................10

2.12 User Interfac e .................................................................................................................................................................11

2.13 Miscellaneous.................................................................................................................................................................11

2.14 Power .............................................................................................................................................................................11

3.0 SATELLITE BOARD HEADERS...........................................................................................................................................12

3.1 Satellite Board Headers....................................................................................................................................................13

3.2 I2C Map............................................................................................................................................................................14

4.0 CONNECTION EXAMPLES .................................................................................................................................................15

4.1 Power ...............................................................................................................................................................................15

4.1.1 Major Components ...................................................................................................................................................................... 16

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

4.1.3 Power Sequencing ...................................................................................................................................................................... 18

4.1.4 Bypass Capacitor Recommendations ......................................................................................................................................... 19

4.1.5 Unused Interface Power Rail s ..................................................................................................................................................... 19

4.1.6 Unused Power Management Signal s .......................................................................................................................................... 19

4.2 Clocks...............................................................................................................................................................................20

4.2.1 32.768KHz Clock......................................................................................................................................................................... 20

4.2.2 Oscillator Clock............................................................................................................................................................................ 20

4.3 DRAM Memory Configuration s .........................................................................................................................................22

4.3.1 Four, 8-bit DDR2 devices ............................................................................................................................................................ 22

4.3.2 Eight, 8-bit DDR2 devices ........................................................................................................................................................... 22

4.3.3 Unused Pins ................................................................................................................................................................................ 23

4.4 NAND ...............................................................................................................................................................................24

4.5 US B ..................................................................................................................................................................................24

4.5.1 Force Recovery ........................................................................................................................................................................... 25

4.5.2 ULPI............................................................................................................................................................................................. 25

4.5.3 PCIe............................................................................................................................................................................................. 26

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4.6 Display..............................................................................................................................................................................27

4.6.1 LCD Displays............................................................................................................................................................................... 27

4.6.2 HDMI ........................................................................................................................................................................................... 29

4.6.3 VGA (CRT) Out ........................................................................................................................................................................... 30

4.7 Camera.............................................................................................................................................................................31

4.7.1 Unused Pins ................................................................................................................................................................................ 31

4.8 SD/SDIO/MM C .................................................................................................................................................................32

4.8.1 SD/MMC Card Connection s ........................................................................................................................................................ 32

4.8.2 eMMC Device Connection s ......................................................................................................................................................... 33

4.8.3 SDIO Device Connections........................................................................................................................................................... 34

4.8.4 Unused Pins ................................................................................................................................................................................ 34

4.9 Miscellaneous...................................................................................................................................................................35

4.9.1 Thermal Diode (Temperature Sensor) ........................................................................................................................................ 35

4.9.2 Debug Interfaces ......................................................................................................................................................................... 35

4.9.3 EFUSE......................................................................................................................................................................................... 36

4.9.4 Strapping Pins ............................................................................................................................................................................. 37

5.0 THERMAL ............................................................................................................................................................................38

5.1 Major Component Thermal Specifications........................................................................................................................38

5.2 Thermal Considerations for Component s .........................................................................................................................38

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1.0 INTRODUCTION

The Smartbook Development System is an example of a development platform built around the Tegra^™200 Series Developer

Board. This example provides a starting point for continued development; it outlines a fairly typical Smartbook configuration

based on the NVIDIA® Tegra™ 250 Computer-on-a-Chip.

This document:

Provides recommendations and integration guidelines for engineers to follow when designing a Smartbook or similar

product that is optimized for high performance and low power consumption.

Details a generic Smartbook Development System: development system consists of the NVIDIA^®Tegra^™200 Series

Developer Kit plus a satellite board containing most of the user input devices and some features for test and

development; can be used for evaluation and/or software development.

Figure 1. Example Smartbook Development System Block Diagram

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2.0 DEVELOPER BOARD OVERVIEW

2.1 Feature List

Applications Processor

SD/SDIO and HSMMC

Standard SD/SDIO/MMC socket

NVIDIA Tegra 250, 23x23mm ,0.8mm pitch

DRAM and Flash Memory

USB and Ethernet

8, 128Mx8, DDR2 @ 333MHz

TPS51116RGET DDR2 Buck Regulator

Hynix 8-bit NAND on board

SMSC LAN 9514 USB Hub and Ethernet

3 USB Type A Host ports

USB for PCIE MiniCard Slot 2

Ethernet RJ-45 Jack

Internal SD/MMC socket supports eMMC module

SMSC USB3315 ULPI PHY

USB for PCIE MiniCard Slot 1

USB Mini Type B connector for Recovery Mode

Baseband

USB based PCIe Mini Card Modules

USIM Card Connector

Buttons, Switches

Display

Power-On, Reset and Force-Recovery Buttons

LVDS Bridge: TI SN75LVDS83B

HDMI (Type A connector)

Slim 15-pin VGA Connector

Miscellaneous Devices

EC: SMSC MEC1308

Temperature Sensor: ADT7461AARMZ_RL7

Audio

Wolfson WM8903L Codec

Stereo Headphones

External and Internal Mics

Left/Right Speaker Amps.

Power

PMIC: TI TPS658621AZGUR

Battery Charge Controller: TI BQ24745RHDR

Main system regulators

3.3V, 5V, 1.8V and 1.05V

Imaging

Other, lower power regulators

3.3V (standby), 1.2V and 1.5V

Dual-lane MIPI CSI connection for camera module

Murata WiFi and Bluetooth module

Wireless

Debug / Test Features

22-pin Debug Connector

JTAG, UART and SPI

Bluetooth: CSR BC6

802.11b/g WiFi: Atheros 6002

Tegra Debug Module (optional)

This is an optional module that may have been shipped with

your Tegra 200 Series Developer Board depending on the

version of the development kit that was ordered.

Power, Reset and Force-Recovery Buttons

Lid Open/Close slider switch

UART4 (4-pin UART) brought to RS232 DB9 serial

connector (intended for software test and debug)

Adds a coin cell battery for uninterrupted Real-Time

Clock operation when the developer board is

powered off

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Figure 2. Tegra 200 Series Developer Board (Top View)

VGA Conn

(J12)

HDMI

Conn

(J18)

LCD (J7)

AC/DC

Jack

(J15)

Camera (J9)

PCIE

Mini-

Mini-B

USB

WiFi Ant

(J24)

Card 0

(J27)

SIM Card

(J19)

SD/MMC

(J5)

Battery

Con

(J14)

PCIE

Mini-

Card 1

(J27)

PMU

(U7)

Tegra T20

(U4)

Ethernet

Jack (J4)

DDR2

(Rank 0)

USB Host

Port (J25)

Dual USB

Host Ports

(J6)

MMC VCORE (J20)

Headphn

Jack (J1)

Debug

Conn

(J10)

Internal

SD/MMC

(J26)

Mic Jack

(J2)

Right

Spkr

(J21)

Satellite

Headers

(J16, J17)

Force Rec

Button

(S2)

Int

Mic

(J8)

Button

(S1)

Reset

Button

(S3)

Left

Spkr

(J11)

Figure 3. Tegra 200 Series Developer Board (Bottom View)

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2.2 NVIDIA® Tegra™ 250

The NVIDIA Tegra 250 computer-on-a-chip is suited for handheld and mobile applications. It’s primary purpose is to control all

system peripherals and provide computing power.

Table 1 Features (Available / Used on Tegra 200 Series Developer Board)

Dual-core ARM® Cortex-A9 MPCore™ processor

CPU

32-bit 333MHz DDR2 SDRAM (to 1GB)

2 chip selects

Dynamic voltage and frequency scaling

Multiple clock and power domains

Independent gating of power domains

Integrated Open GLES 2.0 3D core

External Memory Support

Advanced Power Management

2D/3D acceleration

SPI (Qty 1), I2C (Qty 3), UART (Qty 2)

I2S/PCM (Qty 2)

ULPI HS

USB 2.0 HS (Qty 3)

SDIO (Qty 3)

Internal 4-bit SD/8-bit MMC

Connectivity and Expansion

Storage

eMMC compatible module available

External 4-bit MMC/SD

Dual Display (Integrated LCD + external)

18-bit LVDS LCD

HDMI to 1080p and VGA

Camera (CSI)

Multimedia Support

Pre/Post Processing Acceleration with ISP

MPEG-4/H264/JPEG Encoder

For more information on Tegra 250, refer to the Tegra 200 Series Datasheet (Electrical, Mechanical and

Thermal Specifications and the Design Guide.

Note:

2.3 System DRAM

The Tegra 200 Series Developer Board has 8 DDR2 128M x 8 devices for 1GB total system DRAM. The DDR2 will operate up

to 333MHz for a peak bandwidth of 2.7GB/s. The memory is arranged as one or two 32-bit Ranks. Each Rank uses a different

Chip Select and Clock Enable. For low power operation with memory retention, self refresh is supported.

2.4 Boot Device

A 4Gb (512MB) Hynix HY27UF084G2BTPCB 8-bit NAND is available for use as the boot device. In addition, an internal 4-bit

SD, 8-bit MMC socket (J26) is provided to support other flash memories.

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2.5 LCD Interface

The Smartbook Development System routes an 18-bit parallel RGB interface from the Tegra 250 to a Texas Instruments

SN75LVDS83B LVDS Transmitter which goes to an LVDS panel connector (J7). The connector is a Foxconn GS13307-11230-

7F.

The controls available for the panel and backlight include:

Panel power provided by main 3.3V Buck regulator and enabled by the Tegra 250 GPIO on LCD_PWR2

(EN_VDD_PNL)

Backlight enable controlled by the Tegra 250 GPIO on pin SDIO3_DAT2 (SDIO block)

Backlight PWM controlled by PM3_PWM0 on SDIO3_DAT3 (SDIO block)

Backlight power provided from VDD_VBAT (battery or AC/DC adapter) and enabled by the Tegra 250 GPIO on

LCD_CS1_N

LVDS Transmitter shutdown enabled by Tegra 250 GPIO on pin LCD_PWR0

2.6 External Display Support

A standard HDMI Type A connector (J18) is provided and supports up to 1080p60Hz operation. The Tegra 200 Series

Developer Board supports Hot Plug Detect by routing the HP_DET line on the HDMI connector to the Tegra 250 HDMI_INT_N

interrupt pin. The DDC interface is shared between HDMI and the VGA interface, so only one of these displays can be

connected at a time.

A standard 15-pin VGA connector (J12) is also provided and supports resolutions up to 1600x1200. The Tegra 200 Series

Developer Board also supports detection of a VGA device connection. This uses the Tegra 250 pin SPI2_SCK on the Audio

block.

2.7 Audio

The Tegra 200 Series Developer Board integrates the Wolfson Microelectronics WM8903 Ultra Low Power CODEC for Portable

Audio Applications. The Tegra 250 DAP1 interface supporting I2S protocol communicates audio data to/from the CODEC.

GEN1_I2C is used for CODEC configuration. The audio subsystem features:

Left and Right amplified speaker output via two Wolfson WM9001 amplifiers

Headers for connecting Left (J11)/Right (J21) speakers

Stereo headphone jack (J1)

Both internal Microphone (J8) and external microphone jack (J2)

2.8 USB

The Tegra 250 has three available USB controllers. Controllers #1 and #3 come out on the USB PHYs on the USB1 and USB3

pins. Controller #2 can be used for either ULPI or HSIC (only one at a time). All three USB controllers are used on the Tegra

200 Series Developer Board.

Controller #1

USB1 (PHY) is required for Recovery mode and so is brought out to a USB Mini B connector (J3). USB1 is configured as a

device to allow connection to a host PC, typically for flashing images at the factory or possibly in the field.

Controller #2

USB2 provides a ULPI interface on the Tegra 200 Series Developer Board and connects to an external USB3315 ULPI PHY.

The PHY then connects to PCIe Mini-Card 0 (J27) which is intended for a 3G baseband module.

Controller #3

USB3 (PHY) is routed to an SMSC LAN9514 USB Hub and Ethernet controller. This controller provides one Ethernet interface

and four USB Host ports. The Tegra 200 Series Developer Board routes the Ethernet signals to a standard RJ-45 jack. Three

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of the USB ports are brought to standard Type A connectors (J6 – Dual host port connector and J25 – Single host port). The

forth USB is routed to PCIe Mini-Card #1 (J28).

2.9 Storage

There are two SD/MMC sockets on the Tegra 200 Series Developer Board. Both sockets support High Speed operation

(52MHz for MMC, 50MHz for SD/SDIO)

SD/MMC Socket 1 (J26)

The J26 SD/MMC socket is a combination 8-bit MMC and 4-bit SD/MMC socket intended to be for internal storage, most likely

an eMMC module. Although this device is in a socket, it is not meant to be used as removable storage in a real design. 3.3V is

supplied to the socket. There is also a 2-pin header (J5) to supply a core rail at 2.85V. This header is used when the eMMC

module is installed in this socket.

SD/MMC Socket 2 (J5)

The J5 SD/MMC Socket is a removable storage is a standard 4-bit SD/MMC socket. This would normally be located to allow

SD/MMC/SDIO cards to be inserted and removed by the user. 3.3V is supplied to this socket.

2.10 Camera (optional)

A socket for a camera module is provided on the Tegra 200 Series Developer Board (J9).

2.11 Wireless

Bluetooth and Wifi

The Tegra 200 Series Developer Board integrates a MuRata BT/WF Module using the CSR-BC6 and Atheros AR6002

controllers.

The Bluetooth 2.0 transceiver sends and receives on a 2.4GHz line, including Enhanced Data Rates (EDR) up to 3Mbps and

scatter-net support. USB and Dual UART Ports with rates up to 3MBaud are supported. It operates at full speed Bluetooth

operation with full piconet support and co-exists with 802.11. The CSR device will act as a serial peripheral when connected to

the Tegra 250 via a serial port. This interface, as with WiFi below, will be implemented on a substrate (typically LTCC) supplied

by MuRata containing all components required for operation, to minimize tuning and testing. An external antenna for 2.4GHz

(available off the shelf) is also required

The 802.11b/g transceiver sends and receives on a 2.4GHz line at 54Mbps max. It provides full QoS for 802.11e and security

support 802.11i and co-exists with the Bluetooth device. The interface of choice is SDIO. This interface will be implemented on

a LTCC substrate supplied by MuRata and soldered down to our board to minimize tuning and testing.

An external antenna supporting both Bluetooth and WiFi for 2.4GHz (available off the shelf) is required and available from a

variety of suppliers.

PCIe Mini-Card (3G Modem support and more)

The Tegra 200 Series Developer Board provides two PCIe Mini-Card slots. Both slots support PCIe operation as well as USB

2.0 High Speed. Slot #0 (J27) also routes to a UIM SIM socket (J19) and is intended to support compatible 3G Modem

modules. PCIe Mini-Card slot #1 (J28) could be used for other peripherals such as Solid-State drives or a different WiFi

solution.

Note:

Contact NVIDIA for list of certified PCI express peripherals

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2.12 User Interface

Attach your USB keyboard and mouse to any of the available USB Type-A Host ports (J6, J25).

2.13 Miscellaneous

Temperature Sensor

On Semiconductor Model ADT7461AARMZ_RL7

0.25°C resolution/1°C accuracy (remote channel used)

Interfaces to PWR_I2C

Programmable over/under temperature limits

Debug Options

The Tegra 200 Series Developer Board provides development/debugging interfaces including JTAG, UART and Ethernet.

The Tegra Debug Module [E1173] interfaces to the Tegra 200 Series Developer Board using the expansion headers. This

board provides:

A UART interface through a RS232 DB9 serial connector (intended for software test and debug)

Remote POWER, RESET and FORCE RECOVERY buttons

Adds a coin cell battery for uninterrupted Real-Time Clock operation when the developer board is powered off

2.14 Power

Power Source

Battery: 3-Cell, Li Ion, 24WHr, 11.1V Nominal

AC/DC Adapter: TopMagnetics HK-HW30-A15, 15/30W

100V – 240V operation

Battery Charge Controller

Texas Instruments BQ24745RHDR

PMU

Texas Instruments TPS658621AZGUR

Dedicated DC/DCs

Main system 3.3V and 5V rails: Texas Instruments TPS51220ARTVT

Main system 1.8V: Texas Instruments TPS51116RGER

PCIe 1.05V for the Tegra 250: Texas Instruments TPS62290DRVR

External LDOs

1.2V: Texas Instruments TPS72012YZUT

1.5V: Texas Instruments TPS74201RGWR

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3.0 SATELLITE BOARD HEADERS

Two dual row 50-pin expansion headers enable the ability to connect a satellite board to the Tegra 200 Series Developer Board

and are used to extend developer board functionality.

Figure 4. Example Satellite Board Block Diagram

Tegra 200 Series Developer

Board (E1162)

Additional Functionality

Wireless

Modules

LEDs (WPAN, WWAN, WLAN)

Coin

Cell

PMU

RESET

Button

LEDs (PWR, CHG, NUM,

CAPS, SCROLL, RF)

ONKEY

Button

RESET

I2C

PWR_I2C

PROG

HDR

EEPROM

Tegra 2

PWR_I2C

UART4

RS-232

TRCV

DB9

CON

Tx, Rx, RTS, CTS

LID_Status

Switch

GPIO

RF On/Off

Switch

ForceRecovery

Button

GMI_RE_N

CAM_I2C

16x8

18x8

KBC

Res

16x8

Mux

KBC

GPIO

HeartBeat

LED

I2C

Touchpad

PS/2

Touchpad

PS/2

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3.1 Satellite Board Headers

All the interface connections between a satellite board and the Tegra 200 Series Developer Board are through two sets of

Samtec FTS series 50-pin Micro Strips connectors.

Table 2. Satellite Connectors Pinout

Dir

Pin #

Signal Name

Pin #

Dir

Pin #

Signal Name

Pin #

KB_COL7

EC_KSO17

Out

LED_WPAN*

VDD_CELL_RMT

KB_COL6

KB_COL5

EC_KSO16

EC_KSO15

EC_KSO14

EC_KSO13

EC_KSO12

EC_KSO11

EC_KSO10

EC_KSO9

EC_KSO8

EC_KSO7

EC_KSO6

EC_KSO5

EC_KSO4

EC_KSO3

EC_KSO2

EC_KSO1

EC_KSO0

EC_KSI7

Out

LED_WLAN*

LED_WWAN*

W_DISABLE *

LED_WIFI_BT *

LED_CHARGE*

LED_POWER*

UART4_TXD

VDDIO_NAND_MB

UART4_RXD

UART4_CTS*

UART4_RTS*

NO CONNECT

FORCE_ACOK

VDDIO_SYS_MB

PWR_I2C_SCL

PWR_I2C_SDA

VDD_3V3_MB

GND

Out

KB_COL4

KB_COL3

Out

KB_COL2

Out

KB_COL1

KB_COL0

15 LED_SCROLL_LOCK*

Out

KB_ROW15

KB_ROW14

KB_ROW13

KB_ROW12

KB_ROW11

KB_ROW10

KB_ROW9

KB_ROW8

KB_ROW7

KB_ROW6

KB_ROW5

KB_ROW4

KB_ROW3

KB_ROW2

KB_ROW1

KB_ROW0

EC_KSI0

LED_CAPS_LOCK*

LED_NUM_LOCK*

GND

SPDIF_IN

Out

SPDIF_OUT

GND

Out

IR_TXD

PS2_TS_CLOCK

PS2_TS_DATA

GND

IR_RXD

LID_OPEN*

VDD_5V0_MB

TP_IRQ*

Out

CAM_I2C_SDA

CAM_I2C_SCL

GND

EC_KSI6

EC_KSI5

TS_IRQ*

PS2_TP_CLOCK

PS2_TP_DATA

EC_KSI4

NO CONNECT

ONKEY*

EC_KSI3

LED_HEARTBEAT* 46

Out

EC_KSI2

47 FORCE_RECOVERY*

49 RESET*

SYS_RESET_B*

EC_KSI1

VDD_3V3_EC_MB

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3.2 I2C Map

The I2C interface can be used to connect a touch screen, touch pad and other devices.

There are two options for the Touch devices. I2C versions of these devices (recommended) interface to the Tegra 250, while

PS/2 versions connect to the EC controller.

Table 3. Tegra 200 Series Developer Board I2C Map

Domain

VDDIO_VI

Contrlr

Pins

Volt.

Device

ID / I2C Addr

Location

Tegra 250 Slave addr:

0x45

I2C3

CAM_I2C_SCL/SDA

3.3V

MEC1308 (I2C Master)

Main Board

VDDIO_VI

I2C3

I2C1

CAM_I2C_SCL/SDA

GEN1_I2C_SCL/SDA

3.3V

1.8V

Touchpad

0x28

TBD

Remote Location

Main Board

VDDIO_VI

Touchscreen

Camera

VDDIO_UART

0x36

0x0C

Autofocus DAC

Main Board

Pack is Master or Slave

Slave addr: 0x0B

VDDIO_UART

I2C1

GEN1_I2C_SCL/SDA

3.3V

Option for SMB to Battery Pack

Main Board

VDDIO_UART

VDDIO_LCD

VDDIO_SYS

VDDIO_UART

VDDIO_SYS

I2C1

I2C2

GEN1_I2C_SCL/SDA

DDC_SCL/SDA

3.3V

5.0V

1.8V

Option for SMB to Charger

Mini VGA or HDMI Display

TI TPS658621 PMU

WM8903 Audio Codec

ID EEPROM

0x09

Main Board

Remote Location

Main Board

0x30, 0x50, 0x52

PWR_I2C PWR_I2C_SCL/SDA

0x34

0x1A

0x50

0x51

0x4C

I2C1

PWR_I2C

ID EEPROM

Temperature Sensor

Figure 5. I2C Diagram

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4.0 CONNECTION EXAMPLES

4.1 Power

Figure 6. Tegra 250 Power Connection Example

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4.1.1 Major Components

4.1.1.1 PMU

The Tegra 200 Series Developer Board includes a multi-channel power management unit for embedded processors (TI

TPS658621).

Feature List

Host Interface

I2C Control I/F

Core/CPU power request signals

32.768KHz Clock

Reset input

Reset output

RTC LDO

1.0V-1.2V nominal voltage range with 25mV steps

Separate LDO for RTC domain allowing Deep Sleep mode support – the Tegra 250 lowest power mode

Switch RTC domain automatically back to 1.2V when wake-up event detected (w/CORE_PWR_REQ)

CORE switcher

1.0V-1.2V nominal voltage range with 25mV steps

CORE and RTC domains must track each other within 170mV

Tracking can be ensured in software

Optimized DVS handled by NVIDIA BSP (DVFS architecture)

Turned off if CORE_PWR_REQ is de-asserted – on at 1.2V when CORE_PWR_REQ asserted

CPU switcher

0.85-1.0V nominal voltage range with 25mV steps

Optimized DVS handled by NVIDIA BSP (DVFS architecture)

Turned off if CPU_PWR_REQ is de-asserted – on at 1.0V when CPU_PWR_REQ asserted

PLL LDO

Use 1.1V LDO

Very good line regulation ensured using DC/DC switcher as LDO source

STDBY input

Standby mode: Only the minimum rails are kept powered (RTC and SYSTEM domains, DDR2 in self-refresh)

The Tegra 250 indicates Standby mode by de-asserting CORE_PWR_REQ (polarity programmable)

4.1.1.2 Battery Charge Controller

The Tegra 200 Series Developer Board includes a battery charger with input current detect comparator and charge enable pin

(TI bq24745). For a detailed description and list of device features, see http://focus.ti.com/lit/ds/symlink/bq24745.pdf.

4.1.1.3 Battery Pack (Not Included)

The Tegra 200 Series Developer Board can be used with a 3 cell (3S1P) Lithium ion battery pack that has a nominal voltage of

10.8 volts and a total capacity of 2200mAh. The 3S1P is ideal for applications that can operate on lower voltages.

4.1.1.4 External Switchers, LDOs, Power Switches

The Tegra 200 Series Developer Board includes the following components:

Notebook System Power Controller (TI TPS51220): a dual synchronous buck regulator controller with 2 LDOs. For a

detailed description and list of device features, see http://focus.ti.com/lit/ds/symlink/tps51220.pdf.

DDR2 Memory Power Supply (TI TPS51116): provides a power supply for the DDR2memory system. For a detailed

description and list of device features, see http://focus.ti.com/lit/ds/symlink/tps51116.pdf.

350mA Low-Dropout Linear Regulator (TI TPS72012): for a detailed description and list of device features, see

http://focus.ti.com/lit/ds/symlink/tps72012.pdf.

Step Down Converter (TI TPS62290): synchronous step down dc-dc converter optimized for battery powered portable

devices. For a detailed description and list of device features, see http://focus.ti.com/lit/ds/symlink/tps62290.pdf.

135-mΩ Dual Power-Distribution Switch (TI TPS2052): for a detailed description and list of device features, see

http://focus.ti.com/lit/ds/symlink/tps2052.pdf.

135-mΩ Power Distribution Switch (TI TPS2051): for a detailed description and list of device features, see

http://focus.ti.com/lit/ds/symlink/tps2051.pdf.

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4.1.2 Power Supplies

The Tegra 250 has 29 power rails (3 cores, 14 analog and 12 digital I/O). Depending on system design, many of the rails can

share a power supply, and some are not needed for all designs. The example shown in Table 4 is based on the Smartbook

Development System design and should be representative of these types of designs. This table mainly lists the supplies

required by the Tegra 250. Others are required to support some of the peripherals typically seen in a Smartbook.

Table 4 Tegra 250 Power Supply Allocation Example

Voltage (V)

Supported

Power Rails

Power Supply

Enable

(Tegra 200

Series DB)

Voltages (V)

VDD_RTC

1.0 – 1.2

0.9 – 1.0

1.1

Up to 1.2

Up to 1.0

1.1

PMU LDO2

PMU SM0

PMU LDO1

PMU LD04

PMU SM2 (3.7V) + Internal Trigger

CORE_PWR_REQ + Internal Trigger

CPU_PWR_REQ + Internal Trigger

PMU SM2 (3.7V) + Internal Trigger

VDD_CORE

VDD_CPU

AVDD_PLLx

VDDIO_SYS, AVDD_OSC

1.8

VDDIO_LCD,VDDIO_BB,VDDIO_AUDIO,VDDIO_UART

VDDIO_DDR

1.8,2.8,3.3

1.8

EN_VDD_1V8

1.8

TPS51116, DC/DC

(PG_VDDIO_SYS – PMU LDO4PG)

AVDD_USB, AVDD_USB_PLL

VDD_DDR_RX

3.3

PMU LDO3

PMU SM2 (3.7V) + Internal Trigger

EN_VDD_3V3 (Output of SR)

PMU SM2 (3.7V)

2.8

PMU LDO9

VDDIO_NAND (if 3.3V), VDDIO_SDIO, VDDIO_VI

AVDD_VDAC

1.8,2.8,3.3

2.7 – 3.3

3.3

TPS51220, DC/DC

PMU LDO6

2.85

3.3

AVDD_HDMI

PMU LDO7

PMU SM2 (3.7V)

AVDD_HDMI_PLL

1.8, 2.5

3.3

1.8

PMU LDO8

PMU SM2 (3.7V)

VDDIO_PEX_CLK

3.3

PMU LDO0

PMU SM2 (3.7V)

AVDD_DSI_CSI

1.2

TPS72012, LDO2

TPS62290, DC/DC

PMU LD05

EN_VDD_1V2 (PMU GPIO)

EN_VDD_1V05 (PMU GPIO)

AVDD_PCIE, AVDD_PEX, AVDD_PEX_PLL, VDD_PEX

VCORE_MMC

1.05

2.85

2.7 – 3.6

Note:

1: This includes pins AVDD_PLLA_C_P (powers PLLA, PLLC and PLLP), AVDD_PLLM, AVDD_PLLU (powers

PLLU and PLLD) and AVDD_PLLX. If PCIE not supported in a design, AVDD_PCIE should be left

unpowered as the leakage is significant.

2: Supplies must meet maximum rate requirement in AP20 EMT of 165mV/us

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4.1.3 Power Sequencing

The Power solution, including the PMU and any external supplies/logic, must be able to meet the Tegra 250 power sequence

requirements. These requirements are detailed in the Tegra 200 Series datasheet (Electrical, Mechanical and Thermal

Specifications). Figure 7 shows the sequence used for the Smartbook Development System.

Figure 7. Power-up Sequence Example

VBAT (10.2-12.6V, 15V)

VDD_5V0 (5V, DC/DC TPS51220A)

VDD_3V3_SBY (3.3V, DC/DC TPS51220A)

BATTERY or AC/DC

VDDIO_ONKEY (2.2V, PMU LDO)

ONKEY (VDD_2V2)

VDD_SM2 (3.7V, PMU SM2)

PMU SUPPLY

EXTERNAL SUPPLY

Signals

VDD_RTC (1.2V, PMU LDO2)

VDD_CORE (1.2V, PMU SM0)

AVDD_PLL (1.1V, PMU LDO1)

VDDIO_SYS/AVDD_OSC (1.8V, PMU LDO4)

CLK_32K_IN (PMU)

32KHz Ramp Time

System Clock (External Source or XTAL)

VDD_1V8 (1.8V, DC/DC TPS51116)

V2REF_DDR2 (0.9V, DC/DC TPS51116)

AVDD_USB / USB_PLL (3.3V, PMU LDO3)

VCORE_MMC (2.85V, PMU LDO5)

VDD_DDR_RX (2.85V, PMU LDO9)

VDD_3V3 (3.3V, DC/DC TPS51220A)

VDD_CPU (1.0V, PMU SM1)

Oscillator Ramp Time

SYS_RESET_N (PMU)

AVDD_VDAC (2.85V, PMU LDO6)

AVDD_HDMI (3.3V, PMU LDO7)

AVDD_HDM_PLL (1.8V, PMU LDO8)

VDDIO_PEX_CLK (3.3V, PMU LDO0)

Misc. 1.5V, 3.3V, 5.0V, Backlight

AVDD_DSI_CSI (1.2V, LDO TPS72012)

VDD_1V05 (1.05V, DC/DC TPS62290)

Off by

Default

GPIO

Enabled

VDD_3V3: VDDIO_NAND_3V3, VDDIO_SDIO,VDDIO_VI

VDD_1V8: VDDIO_NAND_1V8, VDDIO_LCD, VDDIO_BB, VDDIO_AUDIO, VDDIO_UART, VDDIO_DDR

VDD_1V05: AVDD_PLLE, AVDD_PEX, AVDD_PEX_PLL, VDD_PEX

Note:

1: VDD_RTC, VDD_CORE, Critical PLLs, AVDD_OSC, VDDIO_SYS, VDDIO_DDR, VDDIO_NAND, 32.768KHz

and System clocks required before SYS_RESET_N goes high

2: Recommended Power-down sequence is reverse of Power-up.

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4.1.4 Bypass Capacitor Recommendations

Table 5 lists the basic recommendations for bypass capacitors near the Tegra 250. In general, one 0.1uf per power pin (or

group for cores) is desirable. These should be placed as close as possible to the respective power pins. In addition, for the

higher power/higher frequency I/O rails one or more 4.7uf bulk capacitor is recommended and should be placed in the general

area of the power and interface pins.

Table 5 Power Supply Capacitor Recommendations for Tegra 250 Supplies

Power Rail

0.1uF Bypass

Capacitors

4.7uF Bulk

Capacitors

Power Rail

0.1uF Bypass

Capacitors

4.7uF Bulk

Capacitors

Cores

VDD_CORE

VDD_RTC

VDD_CPU

Analog

AVDD_PLLn¹

AVDD_DSI_CSI

AVDD_OSC

AVDD_VDAC

AVDD_HDMI_PLL

AVDD_PEX_PLL

Digital

1 each

AVDD_HDMI

AVDD_USB_PLL

AVDD_USB

AVDD_IC_USB

AVDD_PEX

AVDD_PLLE

VDDIO_DDR

VDDIO_NAND

VDDIO_HSIC

VDDIO_BB

VDDIO_DDR_RX

VDDIO_VI

VDDIO_SDIO

VDDIO_SYS

VDDIO_LCD

VDDIO_AUDIO

VDD_PEX

VDDIO_UART

VDDIO_PEX_CLK

Note:

1: AVDD_PLLA_P_C, AVDD_PLLM, AVDD_PLLU, AVDD_PLLX

4.1.5 Unused Interface Power Rails

The example also assumes that all the interfaces are to be used. If a design does not use any functions on one or more of the

interface blocks, the associated power rail does not need to be powered. For the correct handling of each of the rails in this

case, check the Unused Pin section under for the interface in this document. Generally, unused digital power rails can be left

unconnected or tied to ground while unused analog rails should be left unconnected.

4.1.6 Unused Power Management Signals

A few of the signals related to power management may not be required in some designs. This includes SYS_CLK_REQ and

CLK_32K_OUT. If not required, these pins can be configured as GPIOs instead. CORE_PWR_REQ may also not be needed in

all designs, but this pin does not have a GPIO option. If any of these pins are not used, either as their primary function or as a

GPIO (if available), they can be left unconnected.

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4.2 Clocks

The Tegra 250 has a large number of internal functional blocks supporting a broad range of interfaces. Each of these has its

own clocking requirements. The RTC (Real Time Clock) and PMC (Power Management Controller) require a 32.768KHz clock,

to be provided externally. In addition, a higher frequency reference clock (OSC) is required. This can come from a crystal or an

external source, and feeds several integrated PLLs that provide a variety of clocking options for the core and I/O blocks. The

Tegra 250 clocking scheme is shown in Figure 8.

Figure 8. Tegra 250 Clocking Block Diagram

4.2.1 32.768KHz Clock

The 32.768KHz clock is provided externally by the PMU. This clock is input on the CLK_32K_IN pin which is referenced to the

VDDIO_SYS rail. See the Tegra 200 Series Datasheet (Electrical, Mechanical and Thermal Specifications) for details on the

requirements for this clock.

4.2.2 Oscillator Clock

The Tegra 200 Series Developer Board utilizes a 12MHz crystal connected to the Tegra 250 XTAL_IN, XTAL_OUT pins to

generate the reference clock internally. A reference circuit is shown in Figure 9.

Table 6 contains the requirements for the crystal used, the value of the parallel bias resistor and information to calculate the

values of the two external load capacitors (C_L1and C_L2) shown in the circuit.

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Figure 9. Crystal Connection Example

Table 6 Crystal and Circuit Requirements

Symbol

F_P

Parameter

Min

Typ

Max

Unit

MHz

ppm

Parallel resonance crystal Frequency

Frequency Tolerance

F_TOL

C_L

±50

Load Capacitance for crystal parallel resonance

Crystal Drive Level

300

MΩ

Ω

R_BIAS

ESR

External Bias Resistor

Equivalent Series Resistance

Note:

FP, FTOL, CL and DL are found in the Xtal Datasheet

ESR = RM * (1 + C0/CL)/2 where RM = Motional Resistance, C0 =Shunt Capacitance from Xtal datasheet.

Datasheets may specify ESR directly – consult manufacturer if unclear whether ESR or RM are specified.

Load capacitor values (C_Lx) can be found with formula C_L= [(C_L1xC_L2)/(C_L1+C_L2)]+C_PCB

Or since C_L1and C_L2are typically of equal value, C_L= (C_Lx/2)+C_PCB. or C_Lx= (C_L– C_PCB) x 2

CL = Load capacitance (Xtal datasheet). CPCB is PCB capacitance (trace, via, pad, etc.)

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4.3 DRAM Memory Configurations

Tegra 250 supports standard DDR2 SDRAM. Up to 1GB total memory, two chip selects and two Clock Enables are supported.

A full 8-device configurations using x8 DDR2 devices is shown. A 4 device configuration is possible and is a subset of the 8

device configuration. Only Rank 0 would be used in this case.

4.3.1 Four, 8-bit DDR2 devices

Four Devices are routed in parallel to form single 32-bit memory Rank (1 Chip Select, 1 Clock Enable)

CLK+/-, Address, BA, RAS/CAS/WR, CKE0, CS0 and ODT0 are routed to all devices (4 loads)

DQ[31:0], DQS[3:0]+/-, DQM[3:0] are routed to one device each (1 load)

4.3.2 Eight, 8-bit DDR2 devices

Two Ranks of four devices each form two 32-bit memory Ranks (2 Chip Selects, 2 Clock Enables)

CLK+/-, Address, BA, RAS/CAS/WR and ODT0 are routed to all devices (8 loads)

CKE[1:0] and CS0[1:0]_N are routed to 4 devices each (4 loads)

DQ[31:0], DQS[3:0]+/-, DQM[3:0] are routed to 2 devices each (2 loads)

Figure 10. Eight, 8-bit DDR2 Configuration

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Table 7. DDR Pinout

Signal

A20

C24

D20

B20

F26

C26

C27

F28

A26

A23

D23

C20

C18

E28

C28

E26

E27

H26

A21

C21

E25

C23

B26

A24

B24

G15

G17

A18

B18

B23

F27

E20

D19

F15

F14

F24

E24

D10

E11

Signal

F19

E15

G23

DDR_A0

DDR_DM0

DDR_DM1

DDR_DM2

DDR_DM3

DDR_DQ0

DDR_DQ1

DDR_DQ2

DDR_DQ3

DDR_DQ4

DDR_DQ5

DDR_DQ6

DDR_DQ7

DDR_DQ8

DDR_DQ9

DDR_DQ10

DDR_DQ11

DDR_DQ12

DDR_DQ13

DDR_DQ14

DDR_DQ15

DDR_DQ16

DDR_DQ17

DDR_DQ18

DDR_DQ19

DDR_DQ20

DDR_DQ21

DDR_DQ22

DDR_DQ23

DDR_DQ24

DDR_DQ25

DDR_DQ26

DDR_DQ27

DDR_DQ28

DDR_DQ29

DDR_DQ30

DDR_DQ31

DDR_A1

DDR_A2

DDR_A3

DDR_A4

F20

E18

D18

F18

F17

E21

D21

F21

E17

D15

F16

E14

F13

D16

D12

D13

F23

F25

H22

G25

F22

D24

H24

E23

DDR_A5

DDR_A6

DDR_A7

DDR_A8

DDR_A9

DDR_A10

DDR_A11

DDR_A12

DDR_A13

DDR_A14

DDR_CLK

DDR_CLK_N

DDR_CAS_N

DDR_CKE0

DDR_CKE1

DDR_CS0_N

DDR_CS1_N

DDR_BA0

DDR_BA1

DDR_BA2

DDR_QUSE0

DDR_QUSE1

DDR_QUSE2

DDR_QUSE3

DDR_RAS_N

DDR_WE_N

DDR_DQS0P

DDR_DQS0N

DDR_DQS1p

DDR_DQS1N

DDR_DQS2p

DDR_DQS2N

DDR_DQS3p

DDR_DQS3N

F12

E12

F10

F11

4.3.3 Unused Pins

Any unused signal pins can be left unconnected.

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4.4 NAND

The Tegra 250 GMI interface supports a broad range of devices including a variety of NAND devices and configurations.

Works with SLC and MLC devices

Supports up to 8 devices with up to 8 chip selects

Figure 11. Single 8-bit NAND Connection Example

4.5 USB

The Tegra 250 has three available USB controllers. Controllers #1 and #3 come out on the USB PHYs on the USB1 and USB3

pins. Controller #2 can be used for either ULPI or HSIC (only one at a time).

Controller #1

This USB controller is routed to an integrated PHY (USB1) and supports low-, full- and high-speed mode. Both Host and Device

modes are supported. VBUS and Device ID are available to support Type A, B or A/B connector types. USB1 is required for

Recovery mode and must be configurable as a USB Device when the Force Recovery strap (on pin GMI_OE_N is held low. In

this case, USB1 is connected to a host, typically for flashing images at the factory or possibly in the field.

Controller #2

Controller #2 can be used for either ULPI or HSIC. Only one can be used in a design.

ULPI is a 12-pin I/F used to connect to compatible external USB PHYs, baseband or other compatible devices. An example of

the ULPI interface being used to connect to an SMSC USB3315 ULPI to USB PHY is shown in the ULPI section.

HSIC is a 2-pin I/F for high-speed chip-to-chip communications to compatible external PHYs, hubs, basebands, etc.

Controller #3

Controller #3 can be routed to a second integrated USB PHY (USB3) or to the IC_USB interface. Only one of these functions

can be used in a design.

USB3 also supports low, full and high speed modes and can be configured as Host or Device. VBUS and Device ID are

provided on this interface. Typically, in a Smartbook design, USB3 would be used as a Host to interface to a Type A host port,

or more likely, a USB Hub. An example of USB3 interfacing to an SMSC LAN9514 USB Hub and Ethernet controller is provided

in section 3.7 .

The IC_USB interface is used to connect to compatible SIM Cards.

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4.5.1 Force Recovery

The Tegra 250 requires USB1 to be available as a Device for Force Recovery mode which is used to download new firmware.

This is shown in Figure 12 where a USB Mini B connector is available to connect to a Host system. Force Recovery mode is

entered by keeping the FORCE_RECOVERY pin low when the system is first powered up (until SYS_RESET_N goes high.

This is accomplished by pressing the momentary push button shown during power-on.

Figure 12 Force Recovery Connections

4.5.2 ULPI

The Tegra 250 optionally supports ULPI (UMTI+ Low Pin Interface) as an option to connect to external USB PHYs, or other

compatible devices.

12 bit interface including ULPI_CLK, ULPI_DIR, ULPI_NXT, ULPI_STP and ULPI_DAT[7:0]

Operates from 60 MHz clock

8-bit SDR data interface - 4-bit DDR data I/F not supported

Figure 13 shows the Tegra 250 interfacing with an external ULPI-USB PHY. The USB PHY can be used to interface to a

compatible Baseband, a USB Hub, etc.

Figure 13. Example ULPI connection to External SMSC USB3317 USB PHY

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Table 8. ULPI Pinout

Signal

ULPI_CLK

ULPI_DIR

ULPI_NXT

ULPI_STP

ULPI_DATA0

ULPI_DATA1

ULPI_DATA2

ULPI_DATA3

ULPI_DATA4

ULPI_DATA5

ULPI_DATA6

ULPI_DATA7

4.5.3 PCIe

The remaining two downstream USB interfaces on the Tegra 200 Series Developer Board are each routed to one of the Mini-

PCIe connectors shown. One use for Mini-PCIe is to support compatible Baseband modules (currently using the USB interface

portion of Mini-PCIe). A SIM socket is provided off one of the PCIe Mini Card connectors for this purpose. Other peripherals

such as Solid-State drives or Wi-Fi may also take advantage of the high performance PCIe interfaces on the PCIe Mini Card

connectors.

Contact NVIDIA for a list of certified PCI express peripherals.

Figure 14. Example LAN9514 USB/Ethernet Hub and Dual Mini-PCIe Connectors

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Table 9. PCIe Pinout

Signal

AC4

AD4

Signal

AC2

AC1

PEX_CLK_OUT1_N

PEX_CLK_OUT1_P

PEX_CLK_OUT2_N

PEX_CLK_OUT2_P

PEX_L0_RXN

PEX_L1_TXN

PEX_L1_TXP

PEX_L2_RXN

PEX_L2_RXP

PEX_L2_TXN

PEX_L2_TXP

PEX_L3_RXN

PEX_L3_RXP

PEX_L3_TXN

PEX_L3_TXP

AA5

AA4

AD1

AD2

AA7

AA6

AA1

AA2

PEX_L0_RXP

PEX_L0_TXN

PEX_L0_TXP

PEX_L1_RXN

PEX_L1_RXP

4.6 Display

LCD Displays

HDMI

VGA (CRT)

SDTV / HDTV Out

4.6.1 LCD Displays

The Tegra 250 supports a broad range of interfaces for connecting to LCD displays. Two separate display controllers can drive

up to two displays. One of the displays can be an LCD while the other an HDMI display, standard NTSC/PAL TV or CRT.

Alternately, a number of dual LCD combinations are supported. An 18-bit interface to an external LVDS Transmitter to connect

to common Smartbook panels is described. Other interface options are possible. The example assumes an SPWG 18BPP

single channel LVDS panel interface.

Figure 15. Single Channel LVDS Signal Mapping

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Figure 16. Example LVDS Connections

Table 10. LVDS Pinout

Signal

LCD_D0

LCD_D1

LCD_D2

LCD_D3

LCD_D4

LCD_D5

LCD_D6

LCD_D7

LCD_D8

LCD_D13

AA26

AC26

AC27

AC28

AD25

AD28

Y26

LCD_D9

Y25

LCD_D19

LCD_D20

LCD_D21

LCD_D22

LCD_D23

LCD_DE

AA23

AB23

AA22

V25

LCD_D10

LCD_D11

LCD_D12

LCD_D14

LCD_D15

LCD_D16

LCD_D17

LCD_D18

LCD_VSYNC

AA28

AA27

U25

U27

U26

V27

AC22

U23

LCD_HSYNC

LCD_PCLK

AD27

V28

Y27

V26

Y28

AB25

AD26

U28

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4.6.2 HDMI

HDMI_RSET on the Tegra 250 is tied to ground through a 1KΩ, 1% resistor

DDC_SCL/SDA pins are 5V tolerant (no level shifter required). I2C pull-ups connect to 5V supply.

HP_DET drives HDMI_INT (interrupt pin) on the Tegra 250 (Also 5V tolerant - no level shifter required).

Figure 17: HDMI Connection Example

Table 11. HDMI Pinout

Signal

HDMI_TXCN

HDMI_TXCP

HDMI_TXD0N

HDMI_TXD0P

AF17

AG17

AE16

AE17

HDMI_TXD1N

HDMI_TXD1P

HDMI_TXD2N

HDMI_TXD2P

AC18

AD18

AH18

AG18

4.6.2.1 Unused Pins

Any unused signal lines can be left unconnected. If HDMI is not implemented, AVDD_HDMI/HDMI_PLL rails and all signal pins

can be left unconnected.

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4.6.3 VGA (CRT) Out

Figure 18. VGA Output Connection Example

4.6.3.1 Unused Pins

Any unused VDAC pins (VDAC_R, VDAC_G, VDAC_B) can be left unconnected. If the TV/CRT Output function will not be

supported, AVDD_VDAC, VDAC_R/G/B, VDAC_RSET and VDAC_VREF should be left unconnected.

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4.7 Camera

The Tegra 200 Series Developer Board supports a dual lane MIPI CSI connection. The Smartbook Development System uses

an OmniVision Camera module.

Figure 19: Tegra 200 Series Developer Board CSI Camera Connections

Table 12. CSI Pinout

Signal

CSI_CLKAN

CSI_CLKAP

CSI_D1AN

CSI_D1AP

CSI_D2AN

AH26

AG26

AD20

AE20

AH23

CSI_D2AP

CSI_CLKBN

CSI_CLKBP

CSI_D1BN

CSI_D1BP

AG23

AB20

AC20

AH24

AG24

4.7.1 Unused Pins

Any unused signal lines can be left unconnected. If neither DSI nor CSI are implemented, the AVDD_DSI_CSI power rail, all

data/clock lines and the DSI_CSI_RUP, DSI_CSI_RND pins should be left unconnected.

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4.8 SD/SDIO/MMC

The Tegra 250 has four SD/MMC controllers, capable of supporting a variety of devices and protocols including SD Memory,

SDIO, eSD, MMC and eMMC. SD/eSD/SDIO can support up to 4-bits and at Standard or High Speed. MMC/eMMC supports 4

or 8-bit devices Standard or High Speed.

4.8.1 SD/MMC Card Connections

The SD/MMC socket uses the controller mapped to the SDIO2 controller pins on the VI interface domain.

Figure 20. Tegra 200 Series Developer Board Reference design 4-bit SD/MMC Card Socket Connection Example

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4.8.2 eMMC Device Connections

The SD/MMC interface can support a variety of flash memory devices. The Tegra 200 Series Developer Board uses a

combination 4-bit SD/MMC and 8-bit MMC socket to support either standard SD/MMC cards, or proprietary modules with eMMC

(embedded MMC) or other compatible devices for storage and possibly boot options. One available module that can be used

with this socket supports eMMC. The example in Figure 21 shows a connection example that will work with the eMMC module

as both the boot and mass storage device.

Figure 21. Tegra 200 Series Developer Board Reference design 4/8-bit “Captive” SD/MMC Card Socket Connection Example

VDDIO_NAND

0.1uf

Tegra

GND_EMI2

HSMMC_DAT4

HSMMC_DAT5

HSMMC_DAT2

HSMMC_DAT3

HSMMC_CMD

GMI_AD24

GMI_AD25

GMI_AD22

GMI_AD23

GMI_DPD

CMD

GND

VDD

CLK

GND

HSMMC_CLK

GMI_CS5_N

HSMMC_DAT0

HSMMC_DAT1

HSMMC_DAT6

HSMMC_DAT7

GMI_AD20

GMI_AD21

GMI_AD26

GMI_AD27

The Tegra 200 Series Developer Board uses this

socket to as an internal means to support assorted

boot/storage devices including eMMC. This

header is included to provide a core supply to an

eMMC module. Not needed if eMMC or other

device directly on-board

CMD

GND

VDD

CLK

GND

0.1uf

eMMC Core (2.85V)

GPIO_PH2 (HSMMC_CD_N)

GPIO_PH3 (HSMMC_WP)

C_DETECT_N

WP_N

GMI_AD10

GMI_AD11

GND_EMI2

VDDIO_NAND

3.3V

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4.8.3 SDIO Device Connections

An SDIO controller is often used to interface to medium bandwidth peripherals such as a Wi-Fi controller. The connection

example in Figure 22 is from the Smartbook Development System. This shows a Wi-Fi/BT module interfacing to the Tegra 250

SDIO1, UART3 and DAP4 interfaces as well as several GPIO pins for control. Only the signals between the Tegra 250 and the

module are shown.

Figure 22. Tegra 250 SDIO WiFi Connection Example

4.8.4 Unused Pins

Any unused data pins can be left unconnected. If the HSMMC or SD/SDIO interfaces will not be supported at all, then any

unused signal pin can be left unconnected or configured for another function or GPIO. If none of the signals are used on one of

the digital power domains (except VDDIO_DDR and VDDIO_SYS which must be powered for normal operation), then the

associated power rail can be left unconnected or tied to GND.

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4.9 Miscellaneous

4.9.1 Thermal Diode (Temperature Sensor)

Figure 23: Thermal Diode Connection Example

Table 13. Thermal Diode Pinout

Signal

THERMD_N

THERMD_P

4.9.2 Debug Interfaces

An optional debug connector providing access to several debugging interfaces can be added to a design, possibly in the early

stages and removed for production. One option is the Debug connector shown in Figure 24. This connector is used with the

E1137 Combo Debug Board. This board interfaces to the Tegra 200 Series Developer Board Debug connector (J10) using a

flex cable. The Combo board provides:

RS-232 interface on a DB-9 connector which uses UART1 on the Tegra 250

Standard 20-pin, 0.1” JTAG header

Can be used with standard ARM software development/debugging hardware

Provides low level access to the CPUs and AVP

Ethernet RJ-45 jack by means of a SPI-Ethernet controller (using the Tegra 250 SPI1 interface)

Note that in the circuit in Figure 24, there is an optional resistor on JTAG_TRST_N. For normal JTAG operation, this resistor

should not be present. The JTAG_TRST_N pin on the Tegra 250 selects whether the JTAG interface is to be used for

communicating with the Tegra 250 CPU complex, or for Test/Scan purposes. When JTAG_TRST_N is pulled low, the JTAG

interface is enabled for access to the CPU complex. When high, it is in Test/Scan mode.

When used in the normal operating mode to access the internal CPUs, in order to reset the Tegra 250 JTAG block, a reset

command is used rather than toggling the JTAG_TRST_N pin.

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Figure 24. Debug Interface Connection

VDDIO_SYS

ONKEY_N

10KΩ

Tegra

DEBUG

CONNECTOR

10KΩ

SPI1_SCK

SPI1_CS0_N

SPI1_MOSI

SPI1_MISO

AUDIO

1.8V

VDDIO_AUDIO

DBG_RESET_N

UART1_TXD

UART1_RXD

UART

VDDIO_UART

JTAG_RTCK

JTAG_TCK

SYSTEM

JTAG_TDI

JTAG_TDO

JTAG_TMS

JTAG_TRST_N

1.8V

VDDIO_SYS

No Stuff

100KΩ

LCD_PWR1

LCD

VDDIO_LCD

DBG_IRQ_N

Unused Pins

If JTAG is not implemented, then JTAG_RTCK and JTAG_TDO can be left unconnected. The JTAG_TDI and JTAG_TMS pins

still need to be pulled up, and JTAG_TRST_N and JTAG_TCK must be pulled down. The rail the JTAG pins reside on

(VDDIO_SYS) must be powered for any mode including Deep Sleep.

4.9.3 EFUSE

The Tegra 250 design must provide a way to supply a 3.3V power source to the FUSE_SRC pin. This can be accomplished

using one of the following mechanisms:

Test point to connect external 3.3V supply

3.3V Output of on-board LDO controlled by the Tegra 250 GPIO

3.3V Output of PMU, controlled by PWR_I2C from the Tegra 250

Permanently connected to always-on 3.3V supply

The power source must provide a nominal voltage of 3.3V and be able to supply a minimum of 100mA. When not powered, a

10K Ω pull-down resistor each on FUSE_SRC is required. A 0.1uf bypass capacitor is also recommended on FUSE_SRC. The

KFUSE_SRC pin must be pulled down with a 10KΩ resistor only..

Figure 25. EFUSE Connections

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4.9.4 Strapping Pins

Straps must be stable from the rising edge of SYS_RESET_N until 12.5us afterward.

Figure 26. Power-on Strapping Connections

Table 14. Power-on Strapping Breakdown

Strap Options

Strap Pins

Description

USB_RECOVERY

GMI_OE_N

0: USB Recovery Mode

1: Boot from secondary device

JTAG_ARM[1:0]

GMI_CLK, GMI_ADV_N

GMI_AD[7:4]

00: Serial JTAG chain, MPCORE and AVP

RAM_CODE[3:0]

SW uses to determine which BCT table to use for DRAM, NAND timing

Selects Boot device - depends on how Boot fuses are burned

BOOT_SELECT_CODE[3:0]

GMI_AD[15:12]

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5.0 THERMAL

5.1 Major Component Thermal Specifications

Most of the major components used in Tegra 200 series Developer Board are listed in Table 39 along with the temperature

range they are able to operate across.

Note:

The specifications noted in Table 16 may change and other versions with wider or

narrower temperature ranges may be available from the manufacturers

Any design using these components must ensure each of these devices do not exceed the maximum temperature. This may

require careful board and mechanical design practices to accommodate various contributors to heat generation.

Table 15. Major Component Thermal Specifications

Device

Definition

Min

Max

Units

°C

Notes

Overall System

Operating temperature (ambient)

Operating Case Temperature

Operating Case temperature

Operating Case Temperature

Tegra 250

-25

-30

°C

Hynix HY5PS1G831CLFP DDR2

Hynix HY27UF084G2B-TPCB NAND

Wolfson WM8903 Audio Codec

TI TPS658621AZGUR PMU

SMSC MEC1308 Embedded Controller

SMSC LAN9514 USB Hub and Ethernet

SMSC USB3315 ULPI Phy

TI SN75LVDS83B LVDS Transmitter

°C

-40

°C

-40

-10

°C

Note:

1. Design specific. Rating shown is typical for many mobile computing designs

5.2 Thermal Considerations for Components

Figure 27 and Figure 28 show the top and bottom of the Tegra 200 Series Developer Board. The components that either

generate heat, or may be very sensitive to temperature are highlighted with different colors:

Green: Adversely sensitive to heat

Yellow: Mild contributor to heat generation

Lt Orange: Medium contributor to heat generation

Dark Orange: Significant contributor to heat generation

The Green coded devices may be significantly affected by temperature. Typically these have more analog circuitry and may not

perform as well hot such as the Camera Module. The other highlighted parts contribute additional heat to the system which can

be problematic to deal with in an enclosed mobile device.

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Figure 27. Top View – Heat Generating and Thermal Sensitive Components

Figure 28. Bottom View – Heat Generating and Thermal Sensitive Components

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The Tegra 200 Series Developer Board does not represent an actual layout for use in a Smartbook design. It does show the

various components typically found in a Smartbook and aids in describing some useful thermal guidelines:

Keep hotter or more sensitive components from being in close proximity to each other

This may include keeping them from being directly opposite each other on each side of the PCB. The exception is

the DDR2 devices which need to be located opposite each other in an 8 device design for signal integrity reasons.

Provide airflow to help remove trapped heat for either side of the PCB where hot components are located

Possibly providing extra room (x, y and z) around hot components to help with airflow

Use some type of metal heat spreader to help dissipate some of the heat from especially hot components.

This could be an additional piece of metal, or having the case (bottom of PCB) or keyboard plate (top of PCB)

contact the hotter components.

Figure 29. Considerations for resolving for thermal “hot spots”

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EXPRESSLY DISCLAIMS ALL IMPLIED WARRANTIES OF NONINFRINGEMENT, MERCHANTABILITY, AND FITNESS FOR A

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Information furnished is believed to be accurate and reliable. However, NVIDIA Corporation assumes no responsibility for the

consequences of use of such information or for any infringement of patents or other rights of third parties that may result from its use.

No license is granted by implication or otherwise under any patent or patent rights of NVIDIA Corporation. Specifications mentioned

in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied.

NVIDIA Corporation products are not authorized for use as critical components in life support devices or systems without express

written approval of NVIDIA Corporation.

Macrovision Compliance Statement

NVIDIA Products that are Macrovision enabled can only be sold or distributed to buyers with a valid and existing authorization from

Macrovision to purchase and incorporate the device into buyer’s products.

Macrovision copy protection technology is protected by U.S. patent numbers 5,583,936; 6,516,132; 6,836,549; and 7,050,698 and

other intellectual property rights. The use of Macrovision’s copy protection technology in the device must be authorized by

Macrovision and is intended for home and other limited pay-per-view uses only, unless otherwise authorized in writing by

Macrovision. Reverse engineering or disassembly is prohibited

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