TPS8802EVM

www.ti.com Table of Contents User’s Guide Using the TPS8802EVM ABSTRACT This quick-start guide describes the operation and use of the TPS8802 evaluation module (EVM) and the accompaning EVM graphical user interface control software. Table of Contents 1 Introduction.............................................................................................................................................................................3 1.1 Applications........................................................................................................................................................................3 1.2 Features............................................................................................................................................................................. 3 1.3 Recommended Equipment.................................................................................................................................................3 2 Setup........................................................................................................................................................................................4 2.1 Sensor Connections...........................................................................................................................................................4 2.2 Jumper and Switch Configurations.................................................................................................................................... 4 2.3 Power Connection..............................................................................................................................................................5 2.4 USB2ANY Connection....................................................................................................................................................... 6 3 Analog Evaluation...................................................................................................................................................................8 3.1 CO AFE Evaluation............................................................................................................................................................ 9 3.2 Photo AFE Evaluation...................................................................................................................................................... 13 3.3 Power Management and Sleep Mode..............................................................................................................................19 3.4 Horn Driver Evaluation..................................................................................................................................................... 21 3.5 Register Map....................................................................................................................................................................28 4 Board Layout.........................................................................................................................................................................29 5 Schematic and Bill of Materials...........................................................................................................................................33 5.1 Schematic........................................................................................................................................................................ 33 5.2 Bill of Materials.................................................................................................................................................................34 6 Revision History................................................................................................................................................................... 36 List of Figures Figure 2-1. Switch, Jumper, and Power Connections..................................................................................................................5 Figure 2-2. TPS880x GUI Connected to USB2ANY Adapter...................................................................................................... 6 Figure 2-3. Test Command Successful........................................................................................................................................7 Figure 3-1. Evaluation Selection Menu........................................................................................................................................8 Figure 3-2. CO Amplifier Settings................................................................................................................................................ 9 Figure 3-3. Clean Air CO Amplifier Output................................................................................................................................ 10 Figure 3-4. CO Amplifier Output with Sensor and Calibration Gas............................................................................................10 Figure 3-5. COTEST_EN Register Bit........................................................................................................................................11 Figure 3-6. CO Connectivity Test without Sensor...................................................................................................................... 12 Figure 3-7. CO Connectivity Test with Sensor........................................................................................................................... 12 Figure 3-8. Photo Amplifier Settings.......................................................................................................................................... 13 Figure 3-9. LED Power Supply Settings.................................................................................................................................... 14 Figure 3-10. LED Driver Settings...............................................................................................................................................15 Figure 3-11. EVM Photo Measurement Probe Configuration.....................................................................................................16 Figure 3-12. LED A Signals....................................................................................................................................................... 17 Figure 3-13. LED B Signals....................................................................................................................................................... 17 Figure 3-14. Photo Signal with Photo Chamber........................................................................................................................ 18 Figure 3-15. Power Management Evaluation............................................................................................................................ 19 Figure 3-16. Power Management Measurement....................................................................................................................... 19 Figure 3-17. Sleep Mode with SLP_BST = 1............................................................................................................................. 20 Figure 3-18. TPS8802EVM and Three-terminal Piezo Setup....................................................................................................21 Figure 3-19. Register Map: CONFIG2 Register.........................................................................................................................22 Figure 3-20. Register Map: ENABLE2 Register........................................................................................................................ 22 SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Using the TPS8802EVM Copyright © 2022 Texas Instruments Incorporated 1 Trademarks www.ti.com Figure 3-21. Register Map: BOOST Register............................................................................................................................ 23 Figure 3-22. EVM Three-terminal Horn Driver Measurement Probe Configuration...................................................................23 Figure 3-23. Untuned HORNSL, HORNBR, and HORNFB Waveforms.................................................................................... 24 Figure 3-24. Feedback Potentiometer....................................................................................................................................... 24 Figure 3-25. Tuned HORNSL, HORNBR, and HORNFB Waveforms........................................................................................25 Figure 3-26. TPS8802EVM and Two-terminal Piezo Setup.......................................................................................................26 Figure 3-27. Two-terminal Piezo Waveforms (HORNFB to ground).......................................................................................... 27 Figure 3-28. Two-terminal Piezo Waveforms (HORNFB to MCU)............................................................................................. 27 Figure 3-29. Register Map Search Function..............................................................................................................................28 Figure 4-1. TPS8802EVM Top Layer PCB Layout.....................................................................................................................29 Figure 4-2. TPS8802EVM Ground Layer PCB Layout.............................................................................................................. 30 Figure 4-3. TPS8802EVM Power Layer PCB Layout................................................................................................................ 31 Figure 4-4. TPS8802EVM Bottom Layer PCB Layout............................................................................................................... 32 Figure 5-1. TPS8802EVM Schematic........................................................................................................................................33 List of Tables Table 2-1. VMCU and VBST Power-up Voltage...........................................................................................................................4 Table 5-1. Bill of Materials..........................................................................................................................................................34 Trademarks USB2ANY™ is a trademark of Texas Instruments. All trademarks are the property of their respective owners. 2 Using the TPS8802EVM SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated www.ti.com Introduction 1 Introduction The TPS8802EVM is used to evaluate the TPS8802 smoke and CO alarm analog front end (AFE) and power management IC. The EVM allows for easy connection from the TPS8802 to a user-supplied photoelectric chamber and carbon monoxide sensor. The TPS8802 GUI interfaces with the EVM to quickly evaluate the photo amplifier, LED driver, and CO amplifier performance, system power consumption, and other blocks with the register map. For a more thorough evaluation, an external microcontroller can be connected to the TPS8802EVM to create a smoke detection system. 1.1 Applications • • 10-year battery smoke and CO alarms AC powered smoke and CO alarms 1.2 Features • • • • • • • • • • • • • Dual LED drivers for blue and IR LEDs Wide bandwidth, low offset photodiode amplifier Ultra-low power CO transimpedance amplifier LDOs for internal analog blocks and external microcontroller Single buffered analog output AMUX for CO and photo signals Serial interface for configuring amplifiers, drivers, regulators Default-enabled boost converter for 2-V battery operation Horn driver with self-resonant and PWM modes Interconnect driver for multi-alarm connection Power-saving sleep mode with wake-up interrupt Battery test load Under-voltage, over-temperature fault monitors Wide input voltage range for flexible power supply configuration 1.3 Recommended Equipment • • • • • 2-V to 15.5-V power supply capable of 100 mA USB2ANY™ interface adaptor TPS880x GUI software – Installation files are available in the TPS8802EVM product folder Multimeter for measuring supply current, regulator voltages and CO amplifier output Oscilloscope for measuring photodiode signal pulse shape SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Using the TPS8802EVM Copyright © 2022 Texas Instruments Incorporated 3 Setup www.ti.com 2 Setup Specific connections on the TPS8802EVM board require configuration before starting the evaluation. 2.1 Sensor Connections TI recommends connecting a photoelectric smoke chamber and CO sensor to the TPS8802EVM for the evaluation. The TPS8802EVM has a built-in photodiode (D7), blue LED (D8), and IR LED (D6) for functional testing. These components can be de-soldered in order to connect a photoelectric chamber photodiode, IR LED, and/or blue LED its place. Ensure the photodiode wires are kept short to preserve signal integrity. The CO sensor is connected to J17 screw terminals with the sensor counter terminal tied to AGND. 2.2 Jumper and Switch Configurations The S1 switch position determines the VMCU and VBST voltage at power-up. Ensure that only one S1 subswitch is in the ON position. Table 2-1 displays the VMCU and VBST voltage corresponding with each S1 switch position. For proper operation with the USB2ANY adapter, set VMCU to 3.3 V with sub-switch 4. Table 2-1. VMCU and VBST Power-up Voltage S1 Switch Position VMCU (V) VBST (V) 1 1.5 3 2 1.8 3 3 2.5 4 4 3.3 5 The J2 jumper connects VBST to VCC. With the J2 jumper connected and the power supply connected to VBAT, the boost converter supplies power via VCC. This configuration allows the EVM to operate at a voltage level from 2 V to 11.5 V1. The J6 jumper selects the I2C device address. Connect J6 to the AGND position to set the address to 0x3F. Connect J6 to the VMCU position to set the address to 0x2A. The GUI is compatible with both options and defaults to 0x2A. 1 4 The J14 shunt connecting VBAT to DINB limits the VBAT voltage to 11.5 V. If the shunt is moved to J1 connecting LEDLDO to DINB, up to 15.5 V can be supplied on VBAT. Using the TPS8802EVM SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated www.ti.com Setup Figure 2-1. Switch, Jumper, and Power Connections 2.3 Power Connection Connect the power supply to VBAT and PGND. Set the power supply to 2 V, 100 mA2. Enable the power supply and measure the voltage on VMCU (TP27) to ensure it is operating at the voltage option selected by S1: • • • • 1.5 V 1.8 V 2.5 V 3.3 V Measure the voltage on VBST to ensure it is either 3 V, 4 V, or 5 V. See Table 2-1 for more information on the initial VMCU and VBST voltage. 2 Peak current drawn from the supply is 600 mA for boost converter operation. If device does not power up with 100 mA current limit, increase the power supply current limit to 600 mA. SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Using the TPS8802EVM Copyright © 2022 Texas Instruments Incorporated 5 Setup www.ti.com 2.4 USB2ANY Connection Use a USB cable to connect the USB2ANY adapter to a computer with the TPS880x GUI installed. Open the TPS880x GUI and verify the USB2ANY adapter is recognized (see Figure 2-2). With the EVM powered, connect the USB2ANY adapter to the EVM using the USB2ANY adapter 10-pin ribbon cable. Click EXPLORE TPS8802EVM then QUICK START and select the device address corresponding to the J6 jumper (see Section 2.2). Send the test command to verify the EVM, USB2ANY adapter, and GUI software are all connected. Figure 2-2. TPS880x GUI Connected to USB2ANY Adapter 6 Using the TPS8802EVM SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated www.ti.com Setup Figure 2-3. Test Command Successful SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Using the TPS8802EVM Copyright © 2022 Texas Instruments Incorporated 7 Analog Evaluation www.ti.com 3 Analog Evaluation Click START EVALUATION and select the feature to evaluate. The Analog Front End section guides the CO AFE and photo AFE evaluation, and the Power Saving Mode section guides the standby power consumption and sleep mode evaluation. Enter the register map to evaluate the other blocks in the TPS8802 device. Figure 3-1. Evaluation Selection Menu 8 Using the TPS8802EVM SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated www.ti.com Analog Evaluation 3.1 CO AFE Evaluation If a CO sensor is available, connect it to the J17 terminal block. Select the feedback resistance and reference voltage in the GUI software. The TPS8802EVM default configuration uses the internal resistors and references. To use an external feedback resistor, solder a resistor to R5. To use an external input resistor, replace the R1 0-Ω resistor with the required input resistance. The output resistor filters the CO amplifier output when a capacitor is installed on C3. Set the AMUX SELECTION to CO AMPLIFIER. Enable the CO amplifier and measure the voltage on AMUX_BUF. Figure 3-2. CO Amplifier Settings SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Using the TPS8802EVM Copyright © 2022 Texas Instruments Incorporated 9 Analog Evaluation www.ti.com Figure 3-3. Clean Air CO Amplifier Output Figure 3-4. CO Amplifier Output with Sensor and Calibration Gas 10 Using the TPS8802EVM SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated www.ti.com Analog Evaluation 3.1.1 CO Connectivity Test A simple test confirms that the CO sensor is connected to the EVM. Remove the shunt connected to J7 and connect a shunt to J15 and J16. Write COTEST_EN = 1 and measure the pulse shape on AMUX_BUF using an oscilloscope. When COTEST_EN = 1, the PREF pin is pulled low and injects charge into the CO sensor and amplifier. The AMUX pulse shape is different if the CO sensor is disconnected. Write COTEST_EN = 0, remove the J15 and J16 shunts, and connect the J7 shunt when finished. Figure 3-5. COTEST_EN Register Bit SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Using the TPS8802EVM Copyright © 2022 Texas Instruments Incorporated 11 Analog Evaluation www.ti.com Figure 3-6. CO Connectivity Test without Sensor Figure 3-7. CO Connectivity Test with Sensor 12 Using the TPS8802EVM SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated www.ti.com Analog Evaluation 3.2 Photo AFE Evaluation Connect the photoelectric chamber to the EVM. If a photoelectric chamber is not available, place a box over the EVM to block ambient light and reflect the EVM LED light into the photodiode when testing the photo AFE. Enable the photo amplifier, photo gain amplifier, and set the AMUX SELECTION to PHOTO GAIN AMPLIFIER. Select the photo reference on the EVM with jumper J7 and enable the photo reference voltage if the reference is set to PREF. Set the gain factor to the required value. If no extra gain is required, set the AMUX SELECTION to PHOTO AMPLIFIER. It is recommended to install a 470 kΩ resistor connecting PREF to VINT if the photo gain is set to 11x, 20x, or 35x. The 470 kΩ resistor changes the PREF voltage to 70mV and prevents the gain stage output from dropping below 50 mV in worst-case conditions. Figure 3-8. Photo Amplifier Settings Configure the power to the LEDs. By default, LED A is connected to LEDLDO and LED B is connected to VBAT. Use the J1, J5, J8, and J14 jumpers to select which supply powers each LED. Enable the LEDLDO if it powers either LED. SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Using the TPS8802EVM Copyright © 2022 Texas Instruments Incorporated 13 Analog Evaluation www.ti.com Figure 3-9. LED Power Supply Settings Configure the PWM pulse settings for the LED driver. The default setting 201 ms pulse rate and 1 ms pulse width sufficiently tests the LED driver. This setting controls the PWM signal from the USB2ANY adapter to the EVM. Configure the LED current for each driver. The default EVM CSA resistance is 10 Ω and the default EVM CSB resistance is 1.3 Ω. These resistors can be switched on the EVM to change the LED current and temperature compensation. Set the DAC voltage to fine tune the LED current. Set the temperature coefficient to the required setting. Click SETUP TEST after configuring the photo amplifier, LED power supply, and LED driver. 14 Using the TPS8802EVM SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated www.ti.com Analog Evaluation Figure 3-10. LED Driver Settings Select the LED to be tested. Enable the LED PWM to send the PWM signal to the LEDEN pin. Enable LEDPIN_EN to control the LED driver using the LEDEN pin. Place a box over the EVM if the EVM LEDs and photodiode are used to block ambient light and reflect the LED light into the photodiode. Use an oscilloscope to measure the LED current, photo input amplifier, and photo gain amplifier signals. Probe LEDEN to measure the LED control signal. Probe CSA or CSB to measure the LED driver current. Probe PDO to measure the photo input stage amplifier. Probe AMUX_BUF to measure the photo gain stage amplifier. SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Using the TPS8802EVM Copyright © 2022 Texas Instruments Incorporated 15 Analog Evaluation www.ti.com Figure 3-11. EVM Photo Measurement Probe Configuration 16 Using the TPS8802EVM SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated www.ti.com Analog Evaluation Figure 3-12. LED A Signals Figure 3-13. LED B Signals SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Using the TPS8802EVM Copyright © 2022 Texas Instruments Incorporated 17 Analog Evaluation www.ti.com Figure 3-14. Photo Signal with Photo Chamber 18 Using the TPS8802EVM SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated www.ti.com Analog Evaluation 3.3 Power Management and Sleep Mode 3.3.1 Power Management The power management evaluation page allows the user to conveniently control many blocks that are critical for system power consumption. Use the interface to enable and disable each block. Connect a multimeter in series with the power supply to measure current. Remove the J4 USB2ANY adapter cable when performing critical measurements. Raise the VBAT voltage above VINT and VMCU if the boost converter is disabled. In Figure 3-16, the VBAT voltage is raised to 3.6 V to maintain regulation of the MCULDO. Figure 3-15. Power Management Evaluation Figure 3-16. Power Management Measurement SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Using the TPS8802EVM Copyright © 2022 Texas Instruments Incorporated 19 Analog Evaluation www.ti.com 3.3.2 Sleep Mode Sleep mode disables blocks for a programmable amount of time and flags the MCU when sleep mode is exited. Enter the required amount of sleep time via the GUI and click ENTER to start the sleep timer. Click EXIT to exit sleep mode if the device is in sleep mode. Probe the GPIO pin to measure the interrupt signal that occurs when the sleep timer finishes. CLEAR INTERRUPT resets the interrupt signal. The interrupt signal is reset whenever the STATUS1 register is read. By default, the GUI reads all registers every 5 seconds. Disable the automatic register reading by navigating to the Register Map page and changing the Auto Read setting to Off. Figure 3-17. Sleep Mode with SLP_BST = 1 20 Using the TPS8802EVM SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated www.ti.com Analog Evaluation 3.4 Horn Driver Evaluation The TPS8802EVM supports direct connection with a piezo horn. The HBEN pin and HORN_EN register bit enables the integrated horn driver and operates independent of any smoke or CO condition. Connect the piezo horn terminal to the respective EVM terminal as shown in Figure 3-18. The silver (HORNSL, M) and brass (HORNBR, G) connect to the J13 terminal block. For a three-terminal piezo horn, connect the piezo feedback terminal to PIEZOF in the J10 terminal block. Additionally, populate jumpers at J11 and J12 for a three-terminal piezo configuration. 3.4.1 Three-Terminal Piezo Evaluation Figure 3-18. TPS8802EVM and Three-terminal Piezo Setup SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Using the TPS8802EVM Copyright © 2022 Texas Instruments Incorporated 21 Analog Evaluation www.ti.com In the TPS880x GUI navigate to the register map. The horn driver evaluation modifies the following registers: configuration register, enable register, and the boost converter register. The configuration register determines how the horn driver is configured. Figure 3-19. Register Map: CONFIG2 Register • • • For two-terminal mode: HORNSEL = 0. For three-terminal mode: HORNSEL = 1. HORN_THR (relevant to three-terminal mode), see Section 3.4.2. The enable register controls the horn driver circuit. Figure 3-20. Register Map: ENABLE2 Register • 22 Set HORN_EN = 1. Using the TPS8802EVM SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated www.ti.com Analog Evaluation Since the boost converter supplies the horn driver supply voltage, adjusting the booster converter registers affects the horn loudness. Figure 3-21. Register Map: BOOST Register • • Set BST_CLIM = 30 mA to 500 mA. Set VBST = 2.7 V to 15 V. Use an oscilloscope to probe the EVM test points: HORNSL (TP16), HORNBR (TP16), and HORNFB (TP35). Figure 3-22. EVM Three-terminal Horn Driver Measurement Probe Configuration SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Using the TPS8802EVM Copyright © 2022 Texas Instruments Incorporated 23 Analog Evaluation www.ti.com 3.4.2 Three-Terminal Piezo Tuning Set the HBEN pin (TP31) high by connecting it to the VMCU voltage. An untuned piezo feedback network exhibits the following waveform. Figure 3-23. Untuned HORNSL, HORNBR, and HORNFB Waveforms From the figure above, HORNSL, HORNBR, and HORNFB operate below the expected piezo rated frequency of 3.5 kHz. To tune the piezo, enable the horn driver circuit and adjust the potentiometer, see Figure 3-24. A current ammeter in series with the VBAT power supply will also assist with piezo tuning, tune the potentiometer to achieve the peak current draw for the system and the resonant oscillation observed in Figure 3-25. Figure 3-24. Feedback Potentiometer 24 Using the TPS8802EVM SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated www.ti.com Analog Evaluation Achieving resonance on the horn pins, the duty cycle can be further fine-tuned in the register map under the configuration registers: CONFIG2 register with the HORN_THR registers. To achieve maximum loudness, adjust the “HORN_THR” value that operates the horn driver circuit at approximately 50% duty cycle. A tuned piezo will generate the following waveforms. Figure 3-25. Tuned HORNSL, HORNBR, and HORNFB Waveforms HORNSL and HORNBR are square waves out of phase by 180° with each other. Both waveforms operate near a 50% duty cycle. Additionally, HORNSL, HORNBR, and HORNFB oscillate at the piezo resonance frequency of 3.5 kHz. SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Using the TPS8802EVM Copyright © 2022 Texas Instruments Incorporated 25 Analog Evaluation www.ti.com 3.4.3 Two-Terminal Piezo Evaluation Connect a function generator or a microcontroller digital output pin to the HBEN test point: TP31 and connect HORNFB to ground. For an alternative configuration, feed the HORNFB pin with an inverse polarity waveform of HBEN square wave. To improve rise time and fall time of the output and reduces power dissipation, place a 1-mH inductor between the external piezo M wire and EVM HORNSL terminal. Additionally, remove jumper J11 and jumper J12 with PIEZOF terminal floating. Figure 3-26. TPS8802EVM and Two-terminal Piezo Setup In Figure 3-27, set a square wave with the piezo oscillation frequency on the HBEN test point and ground the HORNFB test point. Probe both the HORNBR test point and HORNSL test point to measure the piezo voltage waveforms. 26 Using the TPS8802EVM SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated www.ti.com Analog Evaluation Figure 3-27. Two-terminal Piezo Waveforms (HORNFB to ground) For Figure 3-28, set square waveforms is on both the HBEN test point and the HORNFB test point (equal but opposite polarity). Likewise, probe the piezo test points to observe the piezo voltage waveforms. Figure 3-28. Two-terminal Piezo Waveforms (HORNFB to MCU) SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Using the TPS8802EVM Copyright © 2022 Texas Instruments Incorporated 27 Analog Evaluation www.ti.com 3.5 Register Map Use the register map to evaluate other blocks in the TPS8802. Use the search to find register bits that correspond to a certain block or function. Load and save register map configurations in the File menu. Click the question mark icon (?) to display more information about the selected register or bits. Figure 3-29. Register Map Search Function 28 Using the TPS8802EVM SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated www.ti.com Board Layout 4 Board Layout Figure 4-1. TPS8802EVM Top Layer PCB Layout SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Using the TPS8802EVM Copyright © 2022 Texas Instruments Incorporated 29 Board Layout www.ti.com Figure 4-2. TPS8802EVM Ground Layer PCB Layout 30 Using the TPS8802EVM SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated www.ti.com Board Layout Figure 4-3. TPS8802EVM Power Layer PCB Layout SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Using the TPS8802EVM Copyright © 2022 Texas Instruments Incorporated 31 Board Layout www.ti.com Figure 4-4. TPS8802EVM Bottom Layer PCB Layout 32 Using the TPS8802EVM SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated www.ti.com Schematic and Bill of Materials 5 Schematic and Bill of Materials 5.1 Schematic A. It is recommended to install a 470 kΩ resistor connecting PREF to VINT if the photo gain is set to 11x, 20x, or 35x. The 470 kΩ resistor changes the PREF voltage to 70 mV and prevents the gain stage output from dropping below 50 mV in worst-case conditions. Figure 5-1. TPS8802EVM Schematic SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Using the TPS8802EVM Copyright © 2022 Texas Instruments Incorporated 33 Schematic and Bill of Materials www.ti.com 5.2 Bill of Materials Table 5-1. Bill of Materials REF DES QTY VALUE DESCRIPTION SIZE Printed Circuit Board PART NUMBER PCB1 1 TPS880x C2, C7, C12 3 0.1 µF Capacitor, ceramic, 0.1 µF, 25 V, ±5%, X7R, 0603 0603 06033C104JAT2A C4, C13, C16, C18 4 1 µF Capacitor, ceramic, 1 µF, 16 V, ±10%, X5R, 0603 0603 C0603C105K4PACT U C5 1 1 µF Capacitor, ceramic, 1 µF, 16 V, ±10%, X7R, 0603 0603 EMK107B7105KA-T C6, C11 2 4.7 µF Capacitor, ceramic, 4.7 µF, 25 V, ±10%, X7R, 0805 0805 C2012X7R1E475K12 5AB C8, C9, C14, C15 4 47 µF Capacitor, ceramic, 47 µF, 16 V, ±20%, X6S, 1210 1210 GRM32EC81C476ME 15L C17, C21, C22 3 1000 pF Capacitor, ceramic, 1000 pF, 50 V, ±10%, X7R, 0603 0603 C0603X102K5RACT U C20 1 330 pF Capacitor, ceramic, 330 pF, 50 V, ±10%, X7R, 0603 0603 C0603C331K5RACT U C23 1 100 pF Capacitor, ceramic, 100 pF, 50 V, ±5%, C0G/NP0, 0603 0603 885012006057 C24, C25 2 10 pF Capacitor, ceramic, 10 pF, 50 V, ±5%, C0G/NP0, 0603 0603 06035A100JAT2A D1, D2, D3 3 100 V Diode, Switching, 100 V, 0.15 A, SOD-123 SOD-123 1N4148W-TP D5 1 20 V Diode, Schottky, 20 V, 0.5 A, SOD-123 SOD-123 MBR0520LT1G D6 1 Infrared LED, Infrared, TH D5.5 mm SFH 4556 D7 1 D5.7×H9 mm SFH 213 D8 1 H1, H2, H3, H4 4 Machine Screw, Round, #4-40 × 1/4, Nylon, Philips panhead H5, H6, H7, H8 4 Standoff, Hex, 0.5"L #4-40 Nylon J1, J5, J6, J7, J8, J14 6 Header, 2.54 mm, 3×1, Tin, TH Header, 2.54 mm, 3×1, TH 22284033 J2, J9, J11, J12, J15, J16 6 Header, 2.54 mm, 2×1, Tin, TH Header, 2.54 mm, 2×1, TH 22284023 J3, J10, J13, J17 4 Terminal Block, 5.08 mm, 2×1, TH Terminal Block, 039544-3002 5.08 mm, 2×1, TH J4 1 Header (shrouded), 100mil, 5×2, Gold, TH 5×2 Shrouded header L1 1 LBL1 1 R1 1 0 R2 1 R3 1 R4 R6 Silicon PIN Photodiode, TH Blue 33 µH LED, Blue, TH D3.1 mm Screw Standoff Inductor, Drum Core, Ferrite, 33 uH, 0.7 A, 0.38 ohm, SMD 5×3×4.8 mm Thermal Transfer Printable Labels, 0.650" W × 0.200" H 10,000 per roll PCB Label 0.650 × 0.200 inch LTL1CHTBK4 NY PMS 440 0025 PH 1902C 5103308-1 SDR0503-330KL THT-14-423-10 Resistor, 0, 5%, 0.063 W, 0402 0402 RC0402JR-070RL 10.0 kΩ Resistor, 10.0 k, .1%, .0625 W, 0402 0402 RT0402BRD0710KL 100 kΩ Resistor, 100 k, 0.1%, 0.1 W, 0603 0603 RG1608P-104-B-T5 1 10.0 Ω Resistor, 10.0, 0.5%, 0.1 W, 0603 0603 RT0603DRE0710RL 1 1.30 Ω Resistor, 1.30, 0.5%, 0.1 W, 0603 0603 RT0603DRE071R3L R7, R8 2 33 kΩ Resistor, 33 k, 5%, 0.1 W, AEC-Q200 Grade 0, 0603 0603 CRCW060333K0JNE A R9, R10 2 1.0 kΩ Resistor, 1.0 k, 5%, 0.063 W, AEC-Q200 Grade 0, 0402 0402 CRCW04021K00JNE D R11 1 2.4 MΩ Resistor, 2.4 M, 5%, 0.1 W, AEC-Q200 Grade 0, 0603 0603 CRCW06032M40JNE A R13 1 10.0 kΩ Resistor, 10.0 k, 1%, 0.1 W, AEC-Q200 Grade 0, 0603 0603 CRCW06034K70JNE A 34 Using the TPS8802EVM SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated www.ti.com Schematic and Bill of Materials Table 5-1. Bill of Materials (continued) REF DES QTY VALUE R14, R17 2 1.5 MΩ R16 1 R18 SIZE PART NUMBER Resistor, 1.5 M, 5%, 0.1 W, AEC-Q200 Grade 0, 0603 0603 CRCW06031M50JNE A 620 Ω Resistor, 620, 1%, 0.1 W, 0603 0603 RC0603FR-07620RL 1 5.6 MΩ Resistor, 5.6 M, 5%, 0.1 W, AEC-Q200 Grade 0, 0603 0603 CRCW06035M60JNE A R19 1 500 kΩ Trimmer, 500 kΩ, 0.5W, TH R20 1 R22, R23 2 S1 1 SH-J1, SH-J2, SH-J3, SH-J4, SH-J5, SH-J6, SH-J7, SH-J8 TP1, TP3, TP4, TP7, TP8, TP11, TP12, TP13, TP14, TP16, TP17, TP20, TP21, TP22, TP23, TP24, TP25, TP26, TP27, TP30, TP31, TP33, TP34, TP35, TP36 DESCRIPTION 1.00 MΩ Resistor, 1.00 M, 1%, 0.1 W, AEC-Q200 Grade 0, 0603 10 MΩ Resistor, 10 M, 5%, 0.1 W, AEC-Q200 Grade 0, 0603 375×190×375mi 3386P-1-504LF l 0603 CRCW06031M00FKE A 0603 CRCW060310M0JNE A Switch, Slide, SPST 4 poles, SMT SW, SMT Half Pitch 4SPST, 5.8×2.7×6.25 mm Shunt, 100 mil, Flash Gold, Black Closed Top 100mil Shunt 218-4LPST SPC02SYAN 8 1×2 5010 25 Test Point, Multipurpose, Red, TH Red Multipurpose Testpoint Black Multipurpose Testpoint TP9, TP18, TP19, TP28, TP32, TP37, TP38 5 Test Point, Multipurpose, Black, TH U1 1 TPS8802DCP, DCP0038A (HTSSOP-38) SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback DCP0038A 5011 TPS8802DCP Using the TPS8802EVM Copyright © 2022 Texas Instruments Incorporated 35 Revision History www.ti.com 6 Revision History NOTE: Page numbers for previous revisions may differ from page numbers in the current version. Changes from Revision A (May 2020) to Revision B (July 2022) Page • Added Section Abstract ..................................................................................................................................... 1 • Added Section Trademarks ............................................................................................................................... 2 • Updated the numbering format for tables, figures, and cross-references throughout the document..................3 • Added Section 3.4 ........................................................................................................................................... 21 • Added Section 3.4.1 ........................................................................................................................................ 21 • Added Section 3.4.2 ........................................................................................................................................ 24 • Added Section 3.4.3 ........................................................................................................................................ 26 Changes from Revision * (October 2019) to Revision A (May 2020) Page • Added Figure 3-4 ............................................................................................................................................... 9 • Added recommendation to install a 470 kΩ resistor connecting PREF to VINT in Section 3.2 ....................... 13 • Updated silkscreen labels in Figure 4-1 ...........................................................................................................29 • Added Figure 4-2 ............................................................................................................................................. 29 • Added Figure 4-3 ............................................................................................................................................. 29 • Updated PCB revision to CSTM002A in Figure 4-4 .........................................................................................29 • Added recommendation to install a 470 kΩ resistor connecting PREF to VINT in Figure 5-1 .........................33 • Changed R13 to 10.0 kΩ, changed C17 to 1nF, de-populated R15, C19, TP5, TP6 in Figure 5-1 ................. 33 • Changed C17 value to 1000 pF in Table 5-1 ................................................................................................... 34 • Changed R13 value to 10.0 kΩ in Table 5-1 .................................................................................................... 34 • Deleted R15, C19, TP5, TP6 in Table 5-1 ....................................................................................................... 34 36 Using the TPS8802EVM SLVUBR8B – OCTOBER 2019 – REVISED JULY 2022 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated IMPORTANT NOTICE AND DISCLAIMER TI PROVIDES TECHNICAL AND RELIABILITY DATA (INCLUDING DATA SHEETS), DESIGN RESOURCES (INCLUDING REFERENCE DESIGNS), APPLICATION OR OTHER DESIGN ADVICE, WEB TOOLS, SAFETY INFORMATION, AND OTHER RESOURCES “AS IS” AND WITH ALL FAULTS, AND DISCLAIMS ALL WARRANTIES, EXPRESS AND IMPLIED, INCLUDING WITHOUT LIMITATION ANY IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT OF THIRD PARTY INTELLECTUAL PROPERTY RIGHTS. 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