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DRV2603EVM-CT

DRV2603EVM-CT

  • 厂商:

    BURR-BROWN(德州仪器)

  • 封装:

    Module

  • 描述:

    EVAL MODULE FOR DRV2603

  • 数据手册
  • 价格&库存
DRV2603EVM-CT 数据手册
User's Guide SLOU340B – May 2012 – Revised September 2013 DRV2603 ERM/LRA Haptic Driver Evaluation Kit The DRV2603 is a haptic driver designed to control Linear Resonant Actuators (LRA) and Eccentric Rotating Mass (ERM) motors. The DRV2603 provides many features which help eliminate the design complexities of haptic motor control including reduced solution size, high efficiency output drive, simplified control signaling, quick device startup, and auto-resonance frequency tracking. The DRV2603EVM-CT Evaluation Module (EVM) is a complete demo and evaluation platform for the DRV2603. The kit includes a microcontroller, linear actuator, eccentric rotating mass motor, samples waveforms and capacitive touch buttons which can be used to completely demonstrate and evaluate the DRV2603. This document contains instructions for setup and operation of the DRV2603EVM-CT, as well as an indepth description and examples of haptic waveforms for LRA and ERM actuators. Evaluation Kit Contents: • DRV2603EVM-CT Demo and Evaluation board • Mini-USB Cable Needed for programming and advanced configuration: • Code Composer Studio™ (CCS) or IAR Embedded Workbench IDE for MSP430 • EZ430-F2013, MSP430 LaunchPad (MSP-EXP430G2), or MSP430-FET430UIF hardware programming tool • DRV2603EVM-CT Firmware Code Composer Studio is a trademark of Texas Instruments. I2C is a trademark of N.B.X Corporation. SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback DRV2603 ERM/LRA Haptic Driver Evaluation Kit Copyright © 2012–2013, Texas Instruments Incorporated 1 www.ti.com 1 2 3 4 5 6 7 8 Contents Getting Started .............................................................................................................. 3 1.1 Evaluation Module Operating Parameters ...................................................................... 4 1.2 Quick Start Board Setup .......................................................................................... 4 DRV2603 Demonstration Program ....................................................................................... 5 2.1 Modes and Effects Table ......................................................................................... 5 2.2 Description of the Modes ......................................................................................... 5 Hardware Configuration .................................................................................................... 7 3.1 Input and Output Overview ....................................................................................... 7 3.2 Power Supply Selection ........................................................................................... 8 3.3 Using an External Actuator ....................................................................................... 8 3.4 PWM Input Source ................................................................................................. 9 3.5 Enable Pin Source ................................................................................................ 10 3.6 LRA/ERM Mode Source ......................................................................................... 11 Measurement and Analysis .............................................................................................. 12 4.1 Output Measurements ........................................................................................... 12 MSP430 Control and Firmware .......................................................................................... 13 5.1 Additional Hardware Modes ..................................................................................... 13 5.2 Modifying or Reprogramming the Firmware .................................................................. 15 5.3 MSP430 Pin-Out .................................................................................................. 16 Schematic .................................................................................................................. 17 Layout ....................................................................................................................... 18 Bill of Materials ............................................................................................................. 21 List of Figures 1 Board Diagram .............................................................................................................. 3 2 LRA Auto-Resonance Off .................................................................................................. 6 3 LRA Auto-Resonance On .................................................................................................. 6 4 LRA Click without Braking ................................................................................................. 6 5 LRA Click with Braking ..................................................................................................... 6 6 LRA Click and Release Effect ............................................................................................. 6 7 LRA Scroll Wheel Effect 8 9 10 11 12 13 14 15 16 17 18 19 20 21 ................................................................................................... Terminal Block and Test Points ........................................................................................... External PWM Input ........................................................................................................ External Enable ............................................................................................................ Hardware Select Actuator Mode......................................................................................... Terminal Block and Test Points ......................................................................................... DRV2603 Unfiltered Waveform .......................................................................................... DRV2603 Filtered Waveform ............................................................................................ Measuring the DRV2603 Output with a Digital Low-pass Filter ..................................................... Measuring the DRV2603 Output Signal with an Analog Low-pass Filter .......................................... X-Ray Top View ........................................................................................................... Top Copper ................................................................................................................. Layer 2 Copper ............................................................................................................ Layer 3 Copper ............................................................................................................ Bottom Copper ............................................................................................................. 6 8 9 10 11 12 12 12 13 13 18 18 19 19 20 List of Tables 2 1 Mode and Effects Table .................................................................................................... 2 Hardware Overview ......................................................................................................... 7 3 Binary Counting Modes ................................................................................................... 14 DRV2603 ERM/LRA Haptic Driver Evaluation Kit 5 SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback Copyright © 2012–2013, Texas Instruments Incorporated Getting Started www.ti.com 4 1 MSP430 Pin-Out ........................................................................................................... 16 Getting Started The DRV2603 can be used as a demonstration or evaluation tool. When the DRV2603EVM-CT Evaluation Module is powered on, a demo application automatically starts. To power the board, connect the DRV2603EVM-CT to an available USB port on your computer using the included mini-USB cable. The demo begins with a board power-up sequence and then will enter the demo effects mode. The four larger buttons (B1-B4) can be used to sample haptic effects using both the ERM and LRA motor in the top right corner. The two smaller mode buttons (“–“, “+”) are used to change between the different sets of effects. See the DRV2603 Demonstration Program section for a more detailed description of the demo application. USB Power DRV2603 Driver Power Select Pins Decrement Mode USB VBAT MSP430 DRV2603 Actuators SBW External Power ERM and LRA Actuators OUT MSP DRV Increment Mode Programmer Connector Effect Buttons Press to play haptic effects. Figure 1. Board Diagram SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback DRV2603 ERM/LRA Haptic Driver Evaluation Kit Copyright © 2012–2013, Texas Instruments Incorporated 3 Getting Started 1.1 www.ti.com Evaluation Module Operating Parameters The following table lists the operating conditions for the DRV2603 on the evaluation module. 1.2 Parameter Specification Supply voltage range 2.5V to 5.2V Power-supply Current Rating 400mA External PWM Voltage, VPWM (optional) 1.8V to VDD Quick Start Board Setup The DRV2603EVM-CT firmware contains haptic effects which showcase the features and benefits of the DRV2603. Follow the instructions below to begin the demo. 1. Out of the box, the jumpers are set to begin demo mode using USB power. The default jumper settings can be found in the table below. Jumper Default Position Description JP1 Shorted Connect MSP430 PWM output to DRV2603 PWM input JP2 Shorted 3.3V reference for I2C JP3, JP4 Shorted Connect on-board actuators to DRV2603 MSP USB to MSP Select USB (5V) or VBAT power for the MSP430 DRV USB to DRV Select USB (5V) or VBAT power for the DRV2603 2. Connect the included mini-USB cable to the USB connector on the DRV2603EVM-CT board. 3. Connect the other end of the USB cable to an available USB port on a computer, USB charger, or USB battery pack. 4. If the board is powered correctly the four colored LEDs will light up, the four mode LEDs will flash, and the LRA and ERM will play an effect, indicating the board has been successfully initialized. 4 DRV2603 ERM/LRA Haptic Driver Evaluation Kit SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback Copyright © 2012–2013, Texas Instruments Incorporated DRV2603 Demonstration Program www.ti.com 2 DRV2603 Demonstration Program The DRV2603EVM-CT demo contains haptic effects which showcase the features and benefits of the DRV2603. The sections below provide a detailed description of the included effects. 2.1 Modes and Effects Table The effects preloaded on the DRV2603EVM-CT are listed in Table 1. The modes are selected using the “+” and “–“ mode buttons in the center of the board. The current mode can be identified by the white LEDs directly above the mode buttons. Buttons B1-B4 trigger the effects listed in the description column and will change based on the selected mode. Table 1. Mode and Effects Table Mode Mode 0 LEDs Off Mode 1 LED M4 On Mode 2 LED M3 On Mode 3 LED M2 On Mode 4 LED M1 On Button Description Actuator Mode B1 Ramp-up and click B2 Click and Ramp-down LRA (Auto-Resonance On) B3 Ramp-up and click B4 Click and Ramp-down B1 LRA Alert (Buzz) LRA (Auto-Resonance On) B2 LRA Alert (Buzz) LRA (Auto-Resonance Off) B3 ERM Alert (Buzz) ERM B4 LED Flash (Visual Alert Only) – B1 Click with braking B2 Click no braking B3 Double-click with braking B4 Double-click no braking B1 Keyboard Click (Click with braking) B2 Spacebar Effect (Click and Release) B3 Backspace Effect (Double-tick) B4 Scroll Wheel Effect B1 Click with braking B2 Click no braking B3 Double-click with braking B4 Double-click no braking ERM LRA (Auto-Resonance On) LRA (Auto-Resonance On) ERM B1 Mode 5 LED M0 On B2 B3 Concentration Game ERM and LRA (Auto-Resonance On) B4 2.2 Description of the Modes The modes above were created to showcase various benefits of the DRV2603. See the description of each mode below for more details. 2.2.1 Mode 0 – Ramp and Fade Waveforms Mode 0 is ramp effects which demonstrate transitional effect capabilities of both LRAs and ERMs. 2.2.2 Mode 1 – Buzz and Alerts Mode 1 demonstrates an LRA with auto-resonance on, an LRA with auto-resonance off, and an ERM. Compare the difference in strength between the LRA with and without auto-resonance. SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback DRV2603 ERM/LRA Haptic Driver Evaluation Kit Copyright © 2012–2013, Texas Instruments Incorporated 5 DRV2603 Demonstration Program www.ti.com Figure 2 and Figure 3 compare the acceleration (in blue) between a driver without auto-resonance detection and a driver with auto-resonance detection. Figure 2. LRA Auto-Resonance Off 2.2.3 Figure 3. LRA Auto-Resonance On Mode 2 – LRA Clicks Mode 2 showcases LRA clicks and double clicks. Notice the difference in length of the click with braking and without braking. Then compare the double clicks and notice the event separation is only possible with braking. Figure 4 and Figure 5 show the difference between a click with braking and a click without braking. Notice the acceleration (in blue) is much longer when braking is not applied. Figure 4. LRA Click without Braking 2.2.4 Figure 5. LRA Click with Braking Mode 3 – User Interface Effects Mode 3 showcases LRA user interface effects. 1. Button 1 – Basic click effect 2. Button 2 – Click and Release effect – when holding the board press this button. The button will click when pressed down and bump when released giving a full button effect. 3. Button 3 – Double tick effect – the double tick effect can be used for a backspace key or some other special function key. 4. Button 4 – Scroll wheel effect – press this button while holding the board and feel the scroll-like effect imitating a flick or scroll gesture. 6 DRV2603 ERM/LRA Haptic Driver Evaluation Kit SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback Copyright © 2012–2013, Texas Instruments Incorporated Hardware Configuration www.ti.com Figure 6. LRA Click and Release Effect 2.2.5 Figure 7. LRA Scroll Wheel Effect Mode 4 – ERM Clicks Mode 4 showcases ERM clicks and double clicks. Similarly to the LRA, compare the click with braking and without braking and notice the sharper feel with braking. 2.2.6 Mode 5 – Concentration Game Mode 5 is a game that incorporates the various LRA and ERM effects. This can be used to demonstrate haptics in a real application. To 1. 2. 3. 4. 5. 3 begin playing Concentration: Press any of the large effect buttons. The game will then count down. Once the countdown completes, a button will light and an effect will play. Repeat the pattern by pressing the same button. After each successfully repeated pattern, the board will repeat the same pattern and add one additional button to the sequence. Hardware Configuration The DRV2603EVM-CT is very flexible and can be used to completely evaluate the DRV2603. The following sections list the various hardware configurations. 3.1 Input and Output Overview The DRV2603EVM-CT allows complete evaluation of the DRV2603 though test points, jacks and connectors. Table 2 gives a brief description of the hardware. Table 2. Hardware Overview Signal Description I/O PWM External DRV2603 PWM input Input / Observe EN External DRV2603 enable control Input / Observe OUT+ / OUT- Filtered output test points for observation, connect to oscilloscope or measurement equipment Output OUT Unfiltered output terminal block, connect to actuator Output USB USB power (5V) Input VBAT External Supply Power (2.5V-5.2V) Input SBW MSP430 programming header Input / Output I2C MSP430 I2C™ bus Input / Output SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback DRV2603 ERM/LRA Haptic Driver Evaluation Kit Copyright © 2012–2013, Texas Instruments Incorporated 7 Hardware Configuration www.ti.com Table 2. Hardware Overview (continued) Signal Description I/O Audio The audio jack is connected to an ADC on the MSP430. This is used for audio-to-haptics conversion using special software on the MSP430. Input Hardware configuration details can be found in the following sections. 3.2 Power Supply Selection The DRV2603EVM-CT can be powered by USB or an external power supply (VBAT). Jumpers “DRV” and “MSP” are used to select USB or VBAT for the DRV2603 and MSP430G2553, respectively. See the following table for possible configurations. Supply Configuration DRV MSP DRV2603 Supply Voltage (1) USB – Both USB USB 5V DRV2603 External Supply, MSP430 VBAT USB USB VBAT External Supply - Both VBAT VBAT VBAT USB with 3.3V LDO (2) - Both USB USB 3.3V (R4 = Short, R5 = Open) (1) (2) 3.3 The DRV2603 supply must be on before operating the MSP430. If a 3.3V DRV2603 supply voltage is preferred while using the USB as the power source, remove R5 and add a zero ohm resistor across R4. Using an External Actuator OUT- OUT+ OUT 470pF 100k 100k 470pF From DRV2603 Figure 8. Terminal Block and Test Points The DRV2603EVM-CT can be used with an external actuator. Follow the instructions below to attach an actuator to the "OUT" terminal block. 1. Remove jumpers JP3 and JP4, which will disconnect the on-board actuators from the DRV2603. 2. Attach the positive and negative leads of the actuator to the green “OUT” terminal block keeping in mind polarity. 3. Screw down the terminal block to secure the actuator leads. It is important to use the green terminal block when connecting an external actuator. The "OUT+" and "OUT-" testpoints have low-pass filters and should only be used for oscilloscope and bench measurements. 8 DRV2603 ERM/LRA Haptic Driver Evaluation Kit SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback Copyright © 2012–2013, Texas Instruments Incorporated Hardware Configuration www.ti.com 3.4 PWM Input Source EN PWM DRV2603 MSP430 R8 P3.1 PWM EN OUT+ PWM GND ERM/LRA VDD JP1 VDD P3.0 OUTR2 R1 R3 Figure 9. External PWM Input The DRV2603 input signal can be driven by the on-board MSP430 PWM or an external PWM source. The input source is selected by shorting or disconnecting JP1. JP1 PWM Source Shorted MSP430 Open External PWM using PWM testpoint To set the DRV2603 enable pin high while using an external PWM source: 1. Enter Additional Hardware Modes by holding the "+" button until the actuator buzzes and the mode LEDs blink. 2. Select Mode 3 (00011'b) using the increment mode button ("+"). 3. In Mode 3, press one of the following buttons to enable the DRV2603. • B1 - disable the DRV2603 • B2 - enable with LRA auto-resonance on • B3 - enable with LRA auto-resonance off • B4 - enable in ERM mode 4. If the DRV2603 is enabled, the "EN" LED will glow. SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback DRV2603 ERM/LRA Haptic Driver Evaluation Kit Copyright © 2012–2013, Texas Instruments Incorporated 9 Hardware Configuration 3.5 www.ti.com Enable Pin Source EN PWM DRV2603 MSP430 R8 P3.1 PWM EN OUT+ PWM GND ERM/LRA VDD JP1 VDD P3.0 OUTR2 R1 R3 Figure 10. External Enable The enable pin on the DRV2603 is controlled by the MSP430. To use an external control source or GPIO there are two options. Using the Additional Hardware Modes in the MSP430 firmware, select "Mode 5" which will Hi-Z the MSP430 I/O enable control pin so it does not interfere with the external enable control source. 1. Enter Additional Hardware Modes by holding the "+" button until the actuator buzzes and the mode LEDs blink. 2. Select Mode 5 (00101'b) using the increment mode button ("+"). 3. Connect the external control source to the EN test point at the top of the board. 4. In Mode 5, press one of the following buttons to Hi-Z the DRV2603 enable (EN) pin. • B1 - disable Hi-Z mode • B2 - Hi-Z MSP430 EN pin, select LRA auto-resonance on • B3 - Hi-Z MSP430 EN pin, select LRA auto-resonance off • B4 - Hi-Z MSP430 EN pin, select ERM mode To physically disconnect the MSP430 from the DRV2603 enable pin: 1. Remove resistor R8 which disconnects the MSP430 from the DRV2603. 2. Connect the external control source to the EN test point at the top of the board. 10 DRV2603 ERM/LRA Haptic Driver Evaluation Kit SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback Copyright © 2012–2013, Texas Instruments Incorporated Hardware Configuration www.ti.com 3.6 LRA/ERM Mode Source EN PWM DRV2603 MSP430 R8 P3.1 PWM EN OUT+ PWM GND ERM/LRA VDD JP1 VDD P3.0 OUTR2 R1 R3 Figure 11. Hardware Select Actuator Mode The DRV2603EVM-CT includes both an LRA and ERM actuator. By default, the MSP430 firmware will apply the appropriate logic voltage to the DRV2603 actuator select pin (LRA/ERM) and select the appropriate actuator using an on-board load switch (U5). To manually select the on-board actuator using the MSP430 firmware: 1. Enter Additional Hardware Modes by holding the "+" button until the actuator buzzes and the mode LEDs blink. 2. Select Mode 3 (00011'b) using the increment mode button ("+"). 3. In Mode 3, press one of the following buttons to enable the DRV2603 and select the appropriate actuator. • B1 - disable the DRV2603 • B2 - select the on-board LRA and enable the DRV2603 • B3 - select the on-board LRA and enable the DRV2603 • B4 - select the on-board ERM and enable the DRV2603 4. If the DRV2603 is enabled, the "EN" LED will glow. To manually set the actuator select pin using hardware, use resistors R1, R2, and R3 to configure the DRV2603 . 1. Remove resistor R1, which will disconnect the MSP430. 2. To select LRA mode, add a 0Ω resistor across R2 which will short the pin to VBAT. 3. To select ERM mode, add a 0Ω resistor across R3 which will short the pin to ground. To 1. 2. 3. manually select either the on-board ERM or LRA actuator using hardware: Remove resistor R34 which will disconnect the MSP430. To select the LRA, place a 0Ω resistor across R35. To select the ERM, no additional resistors are needed. SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback DRV2603 ERM/LRA Haptic Driver Evaluation Kit Copyright © 2012–2013, Texas Instruments Incorporated 11 Measurement and Analysis www.ti.com Actuator Selection Resistor Configurations Actuator Type R1 R2 R3 R34 R35 ERM Open Open 0Ω Open Open LRA Open 0Ω Open Open 0Ω External ERM Open Open 0Ω X (1) X (1) External LRA Open 0Ω Open X (1) X (1) (1) Does not matter 4 Measurement and Analysis 4.1 Output Measurements The DRV2603 uses PWM modulation to create the output signal for both ERM and LRA actuators. To measure and observe the DRV2603 output waveform, connect an oscilloscope or other measurement equipment to the filtered output test points, “OUT+” and “OUT-“. OUT- OUT+ OUT 470pF 100k 100k 470pF From DRV2603 Figure 12. Terminal Block and Test Points The DRV2603 drives LRA and ERM actuators using a 20kHz PWM modulated waveform, but only the frequencies around the LRA resonant frequency or the ERM DC drive voltage are relevant to the haptic actuator vibration. The higher frequency switching content does not contribute to the vibration strength of the actuator and can make it difficult to interpret the modulated output waveform on an oscilloscope. The oscilloscope image on the left shows the DRV2603 unfiltered waveform and the image on the right shows a filtered version used for observation and measurement. Figure 13. DRV2603 Unfiltered Waveform Figure 14. DRV2603 Filtered Waveform To observe the modulated output waveform and ensure that the 20kHz switching waveform and associated harmonics are not captured, use either a digital or analog, low pass filter when viewing the output waveform. TI recommends using a 1st-order, low-pass filter with a cutoff between 1kHz and 3.5kHz. Below are recommended output filters for use while measuring and characterizing the DRV2603. Certain oscilloscopes have a built-in digital, low-pass filter, so no external components are required. 12 DRV2603 ERM/LRA Haptic Driver Evaluation Kit SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback Copyright © 2012–2013, Texas Instruments Incorporated MSP430 Control and Firmware www.ti.com OUT+ Ch1 ERM or LRA Ch2 Ch1-Ch2 (Differential) with Digital Low-Pass Filter Oscilloscope OUT- Figure 15. Measuring the DRV2603 Output with a Digital Low-pass Filter An analog 1st order, low-pass, RC filter can also be used; however, care must be taken not to use a filter impedance that is too low. Low filter impedance can affect the back-EMF of the actuator and interfere with the auto-resonance detection algorithm. See the recommend values in Figure 16. 100k OUT+ 470 pF ERM Or LRA Ch1 Ch1-Ch2 (Differential ) Ch2 100k OUT- Oscilloscope 470 pF Figure 16. Measuring the DRV2603 Output Signal with an Analog Low-pass Filter 5 MSP430 Control and Firmware The DRV2603EVM-CT is controlled by a programmable MSP430. This section contains information for programming and controlling the board using the MSP430. 5.1 Additional Hardware Modes Additional modes are available on the DRV2603EVM-CT that provide increased board control and functionality. The additional modes are not available in “demo” mode, but can be access by switching to “binary counting mode”. In “binary counting mode” the mode LEDs count in binary (32 modes) rather than in “demo” mode format (only 6 modes including off). 5.1.1 Enter Binary Counting Mode To 1. 2. 3. enter “binary counting mode” and access the additional modes: Press and hold the increment mode button (“+”) for approximately 3 seconds. Release the button when the actuator buzzes and the mode LEDs flash. Select from the “binary counting modes” using the “+” and “-“ buttons. All modes, including “demo” modes, are available in binary counting mode, see Table 3 for a description. 5.1.2 Exit Binary Counting Mode To 1. 2. 3. exit “binary counting mode” and return to “demo” mode: Press and hold the decrement mode button (“-“) for approximately 3 seconds. Release the button when the actuator buzzes and mode LEDs flash. Select from the “demo” modes using the “+” and “-“ buttons. SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback DRV2603 ERM/LRA Haptic Driver Evaluation Kit Copyright © 2012–2013, Texas Instruments Incorporated 13 MSP430 Control and Firmware 5.1.3 www.ti.com Binary Counting Modes Table 3 lists the modes available in “binary counting mode”. The same modes in “demo” mode are present in “binary counting mode”. Table 3. Binary Counting Modes Mode Button Mode 0 Ramp and Clicks. See Table 1 Mode 0. Mode 1 Concentration Game. See Table 1 Mode 5. Mode 2 ERM Clicks. See Table 1 Mode 4. Mode 3 External PWM LEDs: 00011 Mode 4 Mode 7 Life Test Buzz (LRA) LEDs: 00111 Mode 8 Mode 9 Auto-resonance off frequence adjust LEDs: 01001 Mode 10 Life Test Buzz (ERM) LEDs: 01010" Mode 16 14 Actuator Mode B1 Disable Amplifier B2 Enable DRV2603 LRA (Auto-Resonance On) B3 Enable DRV2603 LRA (Auto-Resonance Off) B4 Enable DRV2603 ERM Notes External PWM - Apply an external PWM source to the PWM testpoint, use MSP430 for hardware configuration. Remove jumper JP1. LRA Keyboard and Mouse Effects. See Table 1 Mode 3. B1 Mode 5 B2 External PWM and External B3 Enable LEDs: 00101 B4 Mode 6 Life Test (LRA) LEDs: 00110 Description Disable Amplifier Enable DRV2603 LRA (Auto-Resonance On) Enable DRV2603 LRA (Auto-Resonance Off) Enable DRV2603 ERM B1 Begin Life Test B2 Test Buzz B3 Decrease output voltage (+1 increment) B4 Increase output voltage (+1 increment) B1 Begin Life Test B2 Test Buzz B3 Decrease output voltage (+1 increment) B4 Increase output voltage (+1 increment) External PWM / External Enable - Apply an external PWM source and enable signal. Enable pin on MSP430 is Hi-Z. Remove jumper JP1. LRA (Auto-resonance On) Life Test (2 seconds on, 1 second off) - life test repeats infinite times and board must be powered down to stop. Increment / Decrement amplitude using B3 and B4. Test new amplitude using B2. LRA (Auto-resonance On) Life Test (Infinite Buzz) board must be powered down to stop buzz. Increment / Decrement amplitude using B3 and B4. Test new amplitude using B2 before beginning life test. LRA Clicks. See Table 1 Mode 2 B1 Alert (Auto-resonance On) B2 Alert (Auto-resonance Off) B3 Decrease output frequency B4 Increase output frequence B1 Begin Life Test B2 Test Buzz B3 Decrease output voltage (+1 increment) B4 Increase output voltage (+1 increment) LRA (Auto-resonance On) LRA (Auto-resonance Off) Vary the auto-resonance off output frequency and see the change in vibration force over frequency. Compare B2 (autoresonance off) with B1 (auto-resonance on). Life Test (Infinite Buzz) board must be powered down to stop buzz. Increment / Decrement amplitude using B3 and B4. Test new amplitude using B2 before beginning life test. ERM Alerts. See Table 1 Mode 1. DRV2603 ERM/LRA Haptic Driver Evaluation Kit SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback Copyright © 2012–2013, Texas Instruments Incorporated MSP430 Control and Firmware www.ti.com 5.2 Modifying or Reprogramming the Firmware The MSP430 firmware on the DRV2603EVM-CT can be modified or reprogrammed to create new haptic effects or behaviors. Find the latest firmware source code and binaries on TI.com. Follow the instructions below to modify or reprogram the DRV2603EVM-CT. 1. Purchase one of the following MSP430G2553 compatible programmers: • EZ430-F2013 (recommended) • MSP-EXP430G2 (recommended) - requires the additional purchase of a header for J4 – Digi-Key: ED8650-ND – Mouser: 575-500201 • MSP430-FET430UIF - requires a JTAG to Spy-Bi-Wire adapter (MSP-JTAGSBW if available) 2. Download and install Code Compose Studio (CCS) or IAR Embedded Workbench IDE. 3. Download the DRV2603EVM-CT source code and binaries from TI.com. 4. Connect the programmer to an available USB port. 5. Connect the programmer to the “SBW” header on the DRV2603EVM-CT. 6. In CCS, (a) Open the project file by selecting Project > Import Existing CCS Project. (b) Select Browse and navigate to the DRV2603EVM-CT project folder, then press OK. (c) Select the checkbox next to the DRV2603EVM-CT project in the “Discovered projects” window and then press “Finish”. (d) Before compiling, navigate to Project > Properties > Build > MSP430 Compiler > Advanced Options > Language Options and make sure the checkbox for “Enable support for GCC extensions (--gcc)” is checked. 7. In IAR, (a) Create a new MSP430 project in IAR, (b) Select the MSP430G2553 device, (c) Copy the files in the project folder downloaded from TI.com to the new project directory. SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback DRV2603 ERM/LRA Haptic Driver Evaluation Kit Copyright © 2012–2013, Texas Instruments Incorporated 15 MSP430 Control and Firmware 5.3 www.ti.com MSP430 Pin-Out The DRV2603EVM-CT contains a MSP430G2553 low-cost microcontroller which controls the board and contains sample haptic effects. The pin-out for the microcontroller can be found in Table 4. Table 4. MSP430 Pin-Out 16 # Label Description 1 P1.1 Green LED 2 P1.2 Yellow LED 3 P1.3 Blue LED 4 P1.4 VREF+ 5 P1.5 Audio-to-Haptics 6 P3.1 Enable 7 P3.0 Actuator Mode Selection 8 NC 9 P2.0 Button 1 10 P2.1 Button 2 11 P2.2 Button 3 12 P3.2 PWM 13 P3.3 WLED 0 14 P3.4 WLED 1 15 P2.3 Button 4 16 P2.4 "+" Button 17 P2.5 "–" Button 18 P3.5 WLED 2 19 P3.6 WLED 3 20 P3.7 WLED 4 21 P1.6/SCL I2C Clock 22 P1.7/SDA I2C Data 23 SBWTDIO Spy-Bi-Wire Data 24 SBWTCK Spy-Bi-Wire Clock 25 P2.7 26 P2.6 LRA/ERM Load Switch 27 AVSS Analog Ground 28 DVSS Digital Ground 29 AVCC Analog Supply 30 DVCC Digital Supply 31 P1.0 32 NC Red LED DRV2603 ERM/LRA Haptic Driver Evaluation Kit SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback Copyright © 2012–2013, Texas Instruments Incorporated Data- 5v NC NC I2C SBW GND SCL-IN SDA-IN +3.3V GND SBWTDIO SBWTCK JP2 FB2 FB1 C8 SDA 0.1ufd/6.3V 0402 GND PowerPad U2 MSP GND U2 R22 DNP 0402 R21 DNP 0402 DNP 0603 R4 DNP 0402 R23 GND DNP 0402 R24 1.0ufd/6.3V 0402 C7 +3.3V B1 B3 B4 RIGHT LEFT GND Audio-to-Haptics 511 0402 R12 DNP 0402 R41 0.0 0402 R40 GND GND 511 0402 R11 0805 Red 0805 Green +3.3V DNP 0402 49.9K 0402 DNP 0402 0.0 0402 C11 R47 GND C13 GND 0.0 0402 R1 ENIN Orange Black GND GND DNP 0402 R3 DNP 0402 GND GND 10ufd/16V 0805 C6 Orange EXTIN GND GND GND GND 249 0402 249 0402 C1 U1 GND GND DNP 0402 R35 Vbat 0.1ufd/16V 0402 0.0 0402 R34 Vbat C12 JP4 JP3 0.0 0402 GND 0.1ufd/16V 0402 GND 249 0402 R18 White 0603 M1 White 0603 GND 249 0402 R19 M0 U5 NO GND NC 0.0 0402 R32 GND 100K/5% 0402 R51 GND 100K/5% 0402 R50 0.0 0402 R33 DNP 0402 R31 TS5A12301EYFPR WCSP6-YFP IN COM V+ DNP 0402 R30 470pfd/50V 0402 X7R C15 470pfd/50V 0402 X7R C14 GND ERM/LRA ACTUATOR SWITCH R36 Vbat 249 0402 R17 White 0603 M2 GND MODE SELECT LEDS DRV2603RUN QFN10-RUN LoadSwitch WLED4 GND R16 White 0603 M3 R15 White 0603 M4 - AVM1 + Orange OUT- Orange OUT+ Green 6A/125V OUT LRA_OUT- LRA_OUT+ LRA GND ERM DRV2603RUN CAPTOUCH EVM DRV2603 EXT INPUT R2 Vbat Black TP1 GND GND 100ufd/6.3V TCT-TANT1206 C5 Vbat + 0.1ufd/6.3V 0402 820 0402 R45 49.9K 0402 R43 GND R46 GND 511 0402 R14 0805 Blue R42 10ufd/6.3V 0603 X5R R44 GND GND 511 0402 R13 0805 Yellow 511 0402 R9 Green 0603 P1.1 EN 0.0 0402 R8 DRV P1.3 B2 VREF+ Audio2Haptics JP1 DNP 0402 R25 0.0 0603 WLED3 R5 WLED2 +5V-USB BTN0 P1.2 P1.4 P1.5 P3.1 P3.0 NC SJ-3523-SMT 3.5mm Audio 0.1ufd/6.3V 0402 C10 +3.3V GND DNP 0402 R20 TPS73633DBV 3.3V/400mA U3 BTN3 CAPTOUCH RESISTORS GND MSP430G2553RHB QFN32-RHB GND QFN32-RHB SSOP8-DCT +3.3V C9 SBWTCK SBWTDIO P1.7/SDA P1.6/SCL P3.7 P3.6 P3.5 P2.5 1.5K 0402 R26 Green 0603 5V GND TXS0102DCT U4 SCL GND GND WLED4 WLED3 WLED2 BTN5 600 Ohms/2A 0805 GND 600 Ohms/2A 0805 0.1ufd/6.3V 0402 9.76K 0402 R7 +3.3V Data+ USB MINIB ID_NC Case Case SBYBIWIRE GND GND Case Case USB USB POWER +5V-USB BTN4 GND A2 BTN1 Green 6A/125V VCAA OE A1 BTN3 P2.4 P2.7 WLED1 P3.4 AVSS BTN5 P2.2 BTN2 P2.1 P1.0 DVCC WLED0 P3.3 DVSS BTN2 3.6V - 5.5V POWER SUPPLY B2 B1 P2.3 P2.6 LoadSwitch P3.2 AVCC BTN1 MSP / DRV 1-2: VBAT POWER 2-3: USB POWER GND VCCB Copyright © 2012–2013, Texas Instruments Incorporated Shield BTN4 BTN0 P2.0 SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback NC WLED1 6 WLED0 VBAT www.ti.com Schematic Schematic DRV2603 ERM/LRA Haptic Driver Evaluation Kit 17 Layout 7 www.ti.com Layout Figure 17. X-Ray Top View Figure 18. Top Copper 18 DRV2603 ERM/LRA Haptic Driver Evaluation Kit SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback Copyright © 2012–2013, Texas Instruments Incorporated Layout www.ti.com Figure 19. Layer 2 Copper Figure 20. Layer 3 Copper SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback DRV2603 ERM/LRA Haptic Driver Evaluation Kit Copyright © 2012–2013, Texas Instruments Incorporated 19 Layout www.ti.com Figure 21. Bottom Copper 20 DRV2603 ERM/LRA Haptic Driver Evaluation Kit SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback Copyright © 2012–2013, Texas Instruments Incorporated Bill of Materials www.ti.com 8 ITEM Bill of Materials MANU PARTNUM QTY REF DESIGNATORS VENDOR PARTNUM DESCRIPTION VENDOR MANUFACTURER SEMICONDUCTORS 1 DRV2603RUN 1 U1 DRV2603RUN NO DATA YET QFN10-RUN ROHS TEXAS INSTRUMENTS TEXAS INSTRUMENTS 2 TXS0102DCTR 1 U4 296-21978-1 2-BIT BIDIR LEVEL TRANSLATOR SSOP8-DCT ROHS DIGI-KEY TEXAS INSTRUMENTS 3 MSP430G2553IRHB32 1 T U2 595P430G2553IRHB32T MIXED SIGNAL MICRO 16KB FLASH 512B RAM QFN32-RHB ROHS MOUSER TEXAS INSTRUMENTS 4 TPS73633MDBVREP 1 U3 296-21283-1 VOLT REG 3.3V 400MA LDO CAP FREE NMOS SOT23-DBV5 ROHS DIGI-KEY TEXAS INSTRUMENTS 5 TS5A12301EYFPR 1 U5 296-23757-1-ND IEC LEVEL 4 ESD-PROTECTED 0.75-OHM ANALOG SWITCH WCSP6-YFP ROHS DIGI-KEY TEXAS INSTRUMENTS 6 LTST-C190KGKT 2 5V,EN 160-1435-1-ND LED,GREEN,2.0V,SMD0603,ROHS DIGI-KEY LITE-ON INC. 7 LNJ037X8ARA 5 M0,M1,M2,M3,M4 LNJ037X8ARACT-ND LED, WHITE 2.9V SMD0805 ROHS DIGI-KEY PANASONIC 8 SML-LXT0805SRW-TR 1 B1 67-1555-1 LED, RED 2.0V SMD0805 ROHS DIGI-KEY LUMEX OPTO 9 SML-LXT0805GW-TR 1 B2 67-1553-1 LED, GREEN 2.0V SMD0805 ROHS DIGI-KEY LUMEX OPTO 10 SML-LXT0805YW-TR 1 B3 67-1554-1 LED, YELLOW 2.0V SMD0805 ROHS DIGI-KEY LUMEX OPTO 11 LTST-C171TBKT 1 B4 160-1645-1-ND LED, BLUE 3.3V SMD0805 ROHS DIGI-KEY LITE-ON INC. CAPACITORS 12 GRM155R71C104KA8 8D 2 C1,C12 490-3261-1-ND CAP SMD0402 CERM 0.1UFD 16V X7R 10% ROHS DIGI-KEY MURATA 13 C1005X5R0J104K 4 C8,C9,C10,C13 445-1266-1 CAP SMD0402 CERM 0.1UFD 6.3V 10% X5R ROHS DIGI-KEY TDK CORP 14 0805YD106KAT2A 1 C6 478-5165-1 CAP SMD0805 CERM 10UFD 16V X5R 10% ROHS DIGI-KEY AVX 15 GRM155R60J105KE19 1 D C7 490-1320-1 CAP SMD0402 CERM 1.0UFD 6.3V X5R 10% ROHS DIGI-KEY MURATA 16 GRM188R60J106ME4 7D 1 C11 490-3896-1-ND CAP SMD0603 CERM 10UFD 6.3V 20% X5R ROHS DIGI-KEY MURATA 17 C0402C471K5RACTU 2 C14,C15 399-1025-1 CAP SMD0402 CERM 470PFD 50V 10% X7R ROHS DIGI-KEY KEMET 18 TCTAL0J107M8R 1 C5 511-1498-1-ND CAP TANT1206 100UFD 6.3V 20% TCT SERIES ROHS DIGI-KEY ROHM SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback DRV2603 ERM/LRA Haptic Driver Evaluation Kit Copyright © 2012–2013, Texas Instruments Incorporated 21 Bill of Materials www.ti.com ITEM MANU PARTNUM QTY REF DESIGNATORS VENDOR PARTNUM 19 ERJ-2GEJ821 1 R45 20 ERJ-2RKF9761X 1 R7 P9.76KLCT-ND 21 RMCF0402ZT0R00 6 R1,R8,R32,R33,R34,R 36 22 RC0402FR-07511RL 5 R9,R11,R12,R13,R14 23 ERJ-2GEJ152 1 R26 24 RMCF0603ZT0R00 1 R5 25 ERJ-2RKF2490X 5 R15,R16,R17,R18,R19 P249LTR-ND 26 ERJ-2RKF4992X 2 R43,R44 27 CRCW04020000Z0ED 2 28 ERJ-2GEJ104 2 DESCRIPTION VENDOR MANUFACTURER RESISTOR SMD0402 THICK FILM 9.76K OHMS 1/10W 1% ROHS DIGI-KEY PANASONIC RMCF0402ZT0R00CT ZERO OHM JUMPER SMT 0402 0 OHM 1/16W,5% ROHS DIGI-KEY STACKPOLE ELECTRONICS 311-511LRCT-ND RESISTOR SMD0402 THICK FILM 511 OHMS 1% 1/16W ROHS DIGI-KEY YAGEO RESISTORS RESISTOR,SMT,0402,THICK FILM,5%,1/16W,820 RESISTOR,SMT,0402,THICK FILM,5%,1/16W,1.5K RMCF0603ZT0R00CT- RESISTOR SMD0603 ZERO OHMS ND 1/10W ROHS Panasonic DIGI-KEY STACKPOLE ELECTRONICS RESISTOR,SMT,0402,249 OHM,1%,1/16W DIGI-KEY Panasonic P49.9KLCT RESISTOR SMD0402 THICK FILM 49.9K OHMS 1/16W 1% ROHS DIGI-KEY PANASONIC R40,R46 541-0.0JCT ZERO OHM JUMPER SMT 0402 0 OHM 1/16W,5% ROHS DIGI-KEY VISHAY R50,R51 P100KJCT RESISTOR SMD0402 THICK FILM 100K OHMS 1/16W 5% ROHS DIGI-KEY PANASONIC DIGI-KEY TDK FERRITE BEADS 29 MPZ2012S601A 2 FB1,FB2 445-2206-1 FERRITE BEAD SMD0805 600 Ohms 2A ROHS 30 LPPB061NGCN-RC 1 SBW S9010E-06 HEADER THRU FEMALE 1X6-RA 50LS GOLD ROHS DIGI-KEY SULLINS 31 PBC03SAAN 3 DRV,I2C,MSP S1011E-03-ND HEADER THRU MALE 3 PIN 100LS GOLD ROHS DIGI-KEY SULLINS 32 PBC02SAAN 1 JP2 S1011E-02 HEADER THRU MALE 2 PIN 100LS GOLD ROHS DIGI-KEY SULLINS 33 PBC02SAAN 3 JP1,JP3,JP4 HEADER THRU MALE 2 PIN 100LS GOLD ROHS DIGI-KEY SULLINS 34 UX60-MB-5ST 1 USB H2959CT JACK USB MINIB SMT-RA 5PIN ROHS DIGI-KEY HIROSE 35 SJ-3523-SMT 1 Audio CP-3523SJCT-ND JACK AUDIO-STEREO MINI(3.5MM ,3-COND SMT-RA ROHS DIGI-KEY CUI STACK 36 SPC02SYAN 6 MSP (2-3), DRV (2-3), JP1, JP2, JP3, JP4 S9001-ND SHUNT BLACK AU FLASH 0.100LS CLOSED TOP ROHS DIGI-KEY SULLINS 37 1725656 2 OUT,VBAT 277-1273 TERMINAL BLOCK MPT COMBICON 2PIN 6A/125V GREEN 100LS ROHS DIGI-KEY PHOENIX CONTACT HEADERS, JACKS, AND SHUNTS 22 DRV2603 ERM/LRA Haptic Driver Evaluation Kit SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback Copyright © 2012–2013, Texas Instruments Incorporated Bill of Materials www.ti.com ITEM MANU PARTNUM QTY REF DESIGNATORS VENDOR PARTNUM 38 5003 4 ENIN,OUT+,OUT,EXTIN (Solder so that color ring is secured) 5003K 39 5011 2 GND,TP1 (Solder so that color ring is secured) 40 NRS-2574 1 41 ELV1036A 42 DESCRIPTION VENDOR MANUFACTURER PC TESTPOINT, ORANGE, ROHS DIGI-KEY KEYSTONE ELECTRONICS 5011K PC TESTPOINT BLACK 063 HOLE ROHS DIGI-KEY KEYSTONE ELECTRONICS AVM1 NRS-2574 ACUTATOR VIBRATION MOTOR 1,3V 9000 RPM ROHS SANYO SANYO 1 - - ACTUATOR - LINEAR VIBRATOR, 2VRMS AAC AAC - 1 - - Metal Block (Custom Block, Heavy Metal, See metal block spec) Heavy Metal Heavy Metal 43 3-5-468MP 1 - 3M9724-ND TAPE TRANSFER ADHESIVE 3" X 5YD DIGI-KEY 3M 44 2-5-4466W 1 - 3M9962-ND TAPE POLY FOAM 2" x 5YD DIGI-KEY 3M TESTPOINTS AND SWITCHES COMPONENTS NOT ASSEMBLED 45 R0402_DNP 11 R2,R3,R20,R21,R22,R 23,R24,R25,R30,R31, R35 R0402_DNP 46 TestPoint_SMDSquare_2.0mm 2 LRA_OUT+,LRA_OUT- TESTPOINT SMD SQUARE 2.0mm 47 R0603_DNP 1 R4 RMCF0603ZT0R00CT- R0603_DNP ND DIGI-KEY STACKPOLE ELECTRONICS 48 R0402_DNP 2 R41,R47 P4.99KLCT-ND R0402_DNP DIGI-KEY PANASONIC 49 R0402_DNP 1 R42 541-0.0JCT R0402_DNP DIGI-KEY VISHAY SLOU340B – May 2012 – Revised September 2013 Submit Documentation Feedback DRV2603 ERM/LRA Haptic Driver Evaluation Kit Copyright © 2012–2013, Texas Instruments Incorporated 23 EVALUATION BOARD/KIT/MODULE (EVM) ADDITIONAL TERMS Texas Instruments (TI) provides the enclosed Evaluation Board/Kit/Module (EVM) under the following conditions: The user assumes all responsibility and liability for proper and safe handling of the goods. Further, the user indemnifies TI from all claims arising from the handling or use of the goods. Should this evaluation board/kit not meet the specifications indicated in the User’s Guide, the board/kit may be returned within 30 days from the date of delivery for a full refund. THE FOREGOING LIMITED WARRANTY IS THE EXCLUSIVE WARRANTY MADE BY SELLER TO BUYER AND IS IN LIEU OF ALL OTHER WARRANTIES, EXPRESSED, IMPLIED, OR STATUTORY, INCLUDING ANY WARRANTY OF MERCHANTABILITY OR FITNESS FOR ANY PARTICULAR PURPOSE. EXCEPT TO THE EXTENT OF THE INDEMNITY SET FORTH ABOVE, NEITHER PARTY SHALL BE LIABLE TO THE OTHER FOR ANY INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES. Please read the User's Guide and, specifically, the Warnings and Restrictions notice in the User's Guide prior to handling the product. This notice contains important safety information about temperatures and voltages. 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For EVMs not subject to the above rules, this evaluation board/kit/module is intended for use for ENGINEERING DEVELOPMENT, DEMONSTRATION OR EVALUATION PURPOSES ONLY and is not considered by TI to be a finished end product fit for general consumer use. It generates, uses, and can radiate radio frequency energy and has not been tested for compliance with the limits of computing devices pursuant to part 15 of FCC or ICES-003 rules, which are designed to provide reasonable protection against radio frequency interference. Operation of the equipment may cause interference with radio communications, in which case the user at his own expense will be required to take whatever measures may be required to correct this interference. General Statement for EVMs including a radio User Power/Frequency Use Obligations: This radio is intended for development/professional use only in legally allocated frequency and power limits. Any use of radio frequencies and/or power availability of this EVM and its development application(s) must comply with local laws governing radio spectrum allocation and power limits for this evaluation module. It is the user’s sole responsibility to only operate this radio in legally acceptable frequency space and within legally mandated power limitations. Any exceptions to this are strictly prohibited and unauthorized by Texas Instruments unless user has obtained appropriate experimental/development licenses from local regulatory authorities, which is responsibility of user including its acceptable authorization. For EVMs annotated as FCC – FEDERAL COMMUNICATIONS COMMISSION Part 15 Compliant Caution This device complies with part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) This device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation. 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It is intended solely for use for preliminary feasibility evaluation in laboratory/development environments by technically qualified electronics experts who are familiar with the dangers and application risks associated with handling electrical mechanical components, systems and subsystems. It should not be used as all or part of a finished end product. Your Sole Responsibility and Risk. You acknowledge, represent and agree that: 1. 2. 3. 4. You have unique knowledge concerning Federal, State and local regulatory requirements (including but not limited to Food and Drug Administration regulations, if applicable) which relate to your products and which relate to your use (and/or that of your employees, affiliates, contractors or designees) of the EVM for evaluation, testing and other purposes. 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Any loads applied outside of the specified output range may result in unintended and/or inaccurate operation and/or possible permanent damage to the EVM and/or interface electronics. Please consult the EVM User's Guide prior to connecting any load to the EVM output. If there is uncertainty as to the load specification, please contact a TI field representative. During normal operation, some circuit components may have case temperatures greater than 60°C as long as the input and output are maintained at a normal ambient operating temperature. These components include but are not limited to linear regulators, switching transistors, pass transistors, and current sense resistors which can be identified using the EVM schematic located in the EVM User's Guide. When placing measurement probes near these devices during normal operation, please be aware that these devices may be very warm to the touch. As with all electronic evaluation tools, only qualified personnel knowledgeable in electronic measurement and diagnostics normally found in development environments should use these EVMs. Agreement to Defend, Indemnify and Hold Harmless. You agree to defend, indemnify and hold TI, its licensors and their representatives harmless from and against any and all claims, damages, losses, expenses, costs and liabilities (collectively, "Claims") arising out of or in connection with any use of the EVM that is not in accordance with the terms of the agreement. This obligation shall apply whether Claims arise under law of tort or contract or any other legal theory, and even if the EVM fails to perform as described or expected. Safety-Critical or Life-Critical Applications. If you intend to evaluate the components for possible use in safety critical applications (such as life support) where a failure of the TI product would reasonably be expected to cause severe personal injury or death, such as devices which are classified as FDA Class III or similar classification, then you must specifically notify TI of such intent and enter into a separate Assurance and Indemnity Agreement. Mailing Address: Texas Instruments, Post Office Box 655303, Dallas, Texas 75265 Copyright © 2013, Texas Instruments Incorporated IMPORTANT NOTICE Texas Instruments Incorporated and its subsidiaries (TI) reserve the right to make corrections, enhancements, improvements and other changes to its semiconductor products and services per JESD46, latest issue, and to discontinue any product or service per JESD48, latest issue. Buyers should obtain the latest relevant information before placing orders and should verify that such information is current and complete. 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TI does not warrant or represent that any license, either express or implied, is granted under any patent right, copyright, mask work right, or other intellectual property right relating to any combination, machine, or process in which TI components or services are used. Information published by TI regarding third-party products or services does not constitute a license to use such products or services or a warranty or endorsement thereof. Use of such information may require a license from a third party under the patents or other intellectual property of the third party, or a license from TI under the patents or other intellectual property of TI. Reproduction of significant portions of TI information in TI data books or data sheets is permissible only if reproduction is without alteration and is accompanied by all associated warranties, conditions, limitations, and notices. TI is not responsible or liable for such altered documentation. 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Buyer will fully indemnify TI and its representatives against any damages arising out of the use of any TI components in safety-critical applications. In some cases, TI components may be promoted specifically to facilitate safety-related applications. With such components, TI’s goal is to help enable customers to design and create their own end-product solutions that meet applicable functional safety standards and requirements. Nonetheless, such components are subject to these terms. No TI components are authorized for use in FDA Class III (or similar life-critical medical equipment) unless authorized officers of the parties have executed a special agreement specifically governing such use. Only those TI components which TI has specifically designated as military grade or “enhanced plastic” are designed and intended for use in military/aerospace applications or environments. Buyer acknowledges and agrees that any military or aerospace use of TI components which have not been so designated is solely at the Buyer's risk, and that Buyer is solely responsible for compliance with all legal and regulatory requirements in connection with such use. TI has specifically designated certain components as meeting ISO/TS16949 requirements, mainly for automotive use. In any case of use of non-designated products, TI will not be responsible for any failure to meet ISO/TS16949. Products Applications Audio www.ti.com/audio Automotive and Transportation www.ti.com/automotive Amplifiers amplifier.ti.com Communications and Telecom www.ti.com/communications Data Converters dataconverter.ti.com Computers and Peripherals www.ti.com/computers DLP® Products www.dlp.com Consumer Electronics www.ti.com/consumer-apps DSP dsp.ti.com Energy and Lighting www.ti.com/energy Clocks and Timers www.ti.com/clocks Industrial www.ti.com/industrial Interface interface.ti.com Medical www.ti.com/medical Logic logic.ti.com Security www.ti.com/security Power Mgmt power.ti.com Space, Avionics and Defense www.ti.com/space-avionics-defense Microcontrollers microcontroller.ti.com Video and Imaging www.ti.com/video RFID www.ti-rfid.com OMAP Applications Processors www.ti.com/omap TI E2E Community e2e.ti.com Wireless Connectivity www.ti.com/wirelessconnectivity Mailing Address: Texas Instruments, Post Office Box 655303, Dallas, Texas 75265 Copyright © 2013, Texas Instruments Incorporated
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