TSDMTX-5V-EVM Wireless Charging Transmitter WIRELESS CHARGING User Guide TSDMTX-5V-EVM Dual-Mode (Qi and PMA) Transmitter www.semtech.com Introduction The Semtech TSDMTX-5V-EVM is an evaluation platform for test and experimentation of a wireless charging transmitter based on the Semtech TS80000 Wireless Power Transmitter Controller, TS61001 Full-Bridge FET Driver, and TS31023 Linear Regulator. This evaluation module provides a complete system solution for both Qi and PMA standards of power transmission, making this transmitter an ideal platform for powering the majority of wireless receivers in use today. Objectives The objective of this User Guide is to provide a fast, easy and thorough method to experiment with and evaluate the Semtech solutions for wireless charging systems. Sufficient information is provided to support the engineer in all aspects of adding wireless charging support to their products. Semtech offers a range of solutions to meet the needs of a wide range of system developers. Developers are provided with all the information on how this EVM was built as a starting point for their own designs using the TS80000 and other Semtech components. Table of Contents Wireless Charging Concepts .................................................................................................... 2 Product Description ................................................................................................................. 3 Standard Use .......................................................................................................................... 5 Firmware Management ............................................................................................................ 8 FOD Test ................................................................................................................................. 9 Documentation ...................................................................................................................... 10 A. Block Diagram ............................................................................................................ 10 B. Schematic .................................................................................................................. 11 C. Bill Of Materials "BOM" ............................................................................................... 13 D. Board Layout.............................................................................................................. 14 E. Board Layers .............................................................................................................. 15 FAQs ..................................................................................................................................... 17 Next Steps ............................................................................................................................. 18 Wireless Charging User Guide TSDMTX-5V-EVM www.semtech.com 1 of 19 Semtech Wireless Charging Concepts Wireless power transfer is, essentially, a transformer. Power is provided to a primary coil which produces an electromagnetic (EM) field. In this field, a secondary coil is placed. The EM field induces a current into the secondary coil, providing power to whatever it is connected to. However, unlike a conventional power transformer that operates at line frequencies and requires an iron core for efficiency, wireless power systems are designed to operate in the 100 kHz range, and thus can perform efficiently with an air core. As such, the primary and secondary windings, if closely spaced, can be in separate devices, the primary being part of a transmitter and the secondary within a receiver. This implementation can also be described as a radio broadcast process, and as such, these transformer coils can also be seen as antennas with equal validity, and the two terms will be used interchangeably in this text. Receiver Rectifier Controller FET Array Transmitter Power Supply Control Supply Regulation Power End Equipment Electromagnetic Flux Wireless power systems differ in another major aspect from conventional transformers, in that they are intelligently managed. A transmitter will only provide power when a receiver is present, and only produce the amount of power requested by the receiver. In addition, the system is capable of recognizing when the electromagnetic field has been interrupted by an unintended element, a 'foreign object', and will shut down the transfer to prevent any significant amount of power being absorbed by anything but a proper receiver. The intelligent management of the wireless power transmission process is achieved though the programming of the TS80000, which first searches for a receiver. Once found, the receiver informs the transmitter of its power requirements, and transmission begins. The system then verifies the right amount of power is being sent, and that none is being lost to foreign objects. The receiver will continually provide ongoing requests for power to maintain the transaction. If the requests cease, the transaction terminates. Via this protocol, even complex charging patterns can be supported, as the transmitter can provide varying amounts of power at different times, as requested by the receiver. Should the receiver require no further power, such as when a battery charge is completed, it can request no further power be sent, and the transmitter will reduce its output accordingly. Wireless power systems have been broken into three basic power categories. "Wearable" devices, such as headsets, wrist-band devices, medical sensors, and so forth - all operate in the low power range, up to 5 watts. Medium power devices, in the 5- to 15-watt range, include most handheld devices, such as cell phones, tablets, and medical electronics. High power wireless systems are intended to support devices such as power tools, radio controlled ("RC") devices such as drones, and other equipment requiring 15 to 100 watts of power. Wireless Charging User Guide TSDMTX-5V-EVM www.semtech.com 2 of 19 Semtech Product Description The TSDMTX-5V-EVM Evaluation Module is a ready-to-use demonstration platform allowing testing of up to 5 watts of wireless power transmission compliant with the dominant industry standards - Qi and PMA. The transmitter may be coupled with any Qi or PMA receiver module to form a complete wireless power transmission system. For the system designer, a likely choice might be the complementary Semtech TSDMRX-5W-EVM, which can allow a variety of experiments to easily be performed in order to learn more about the behavior of the system. There are a number of other Semtech Receiver EVMs that support different power levels and output voltages, any of which can be used as all support the Qi and/or PMA standard and therefore are compatible with the TSDMTX-5V-EVM transmitter. In addition, the evaluator can also use any existing Qi or PMA compliant product, though the limited access these devices offer may make the range of experiments that can be performed more limited. Those who wish to develop their own board, or integrate this functionality into an existing system can use the EVM as a starting point for their design, as it demonstrates a working model from which to proceed. Toward this end, all documentation for the EVM is provided to make the process as efficient as possible. The key technology in the EVM is the Semtech TS80000 integrated circuit, which controls the system and implements the Qi and PMA protocols. Developers can vary the supporting componentry to meet their goals as desired. In this user guide, an introduction will be provided to the evaluator for how to use the EVM for wireless power transmission as well as how the TSDMRX-5W-EVM can be used in conjunction with it. Once the system is set up and working, a selection of tests and activities will be described that the evaluator can choose to perform. USB For Power And Flash Update LED Behavior Wireless Charging User Guide TSDMTX-5V-EVM www.semtech.com 3 of 19 Semtech The red and green LEDs on the EVM let the user know what the transmitter is doing as it operates. As seen in the diagram below, when power is applied, the transmitter initializes as indicated by the green LED lighting for about a half second. Next, as the transmitter searches for a nearby receiver, no LED is lit, keeping power to a minimum in this standby state. When a receiver is located the transmitter receives instructions on the upcoming transaction to perform. Power is then transmitted and the green LED flashes each second indicating an ongoing charging event. During charging, if a foreign object is detected, charging is aborted and the red LED will flash each second indicating the fault detected, and will continue to do so until the receiver is removed from the target zone. Similarly, any other detected error will also abort the charging process, indicated by a steady red LED that remains lit until the receiver is taken away. Error conditions include communication errors between receiver and transmitter, and detection of excess voltage, current, power, or temperature on the receiver or transmitter. Absent an error, charging continues until the receiver indicates no further power is required, usually when an attached battery is fully recharged. At this point, the transmitter enters the charge complete state, as indicated by the green LED being lit steadily, which it continues to do until the receiver is removed from the transmitter. Whenever the receiver is removed from the target area, the transmitter returns to the standby state, searching for another transaction to begin. Apply Power 1/2 sec Startup Sequence - off - Standby (ping...) Blinking Charging if FOD Blinking Solid Charge Complete if Error Solid Green LED Wireless Charging User Guide TSDMTX-5V-EVM Receiver Removed www.semtech.com Red LED 4 of 19 Semtech Standard Use The TSDMTX-5V-EVM is easy to set up and use. Connect a USB cable from any USB port capable of driving up to 1 amp (most PCs will suffice) to the USB port on the EVM. On application of power, the green LED should light for about a second and then turn off. Note: you can also apply power via the J5 port from an external 5 volt power supply (not included with the EVM kit), but not when the USB cable is in use. At this point, the EVM is ready to transmit power. A few times each second, the transmitter emits a `ping' of energy in search of a compliant receiver in range. When in range, the receiver is powered by the ping sufficiently to be able to announce its presence to the transmitter, and a transaction begins. The transmitter provides a small amount of power to the newly discovered receiver, so it can tell the transmitter what its power requirements are. At the completion of the handshake, the transmitter begins providing the requested power, indicated by a blinking green LED. During power transfer, the receiver continuously communicates with the transmitter, actively directing the process. In this way, it is assured that power is only sent when and how it is required by an available and desirous receiver - and in the way that is compatible to the requirements of the receiver. If required, a receiver can actively increase or decrease its power request, and the transmitter will act accordingly. As such, equipment with complex charging requirements can be precisely supported and only the desired amount of power is provided. Once charging is completed, the LED stops blinking and displays a steady green `completed' state. If at any time an error is detected, the red LED is lit and transmission is halted. To restart, the receiver must be removed from the range of the transmitter and returned to the target zone to start a new transaction. Productized Receiver Test If you have a product that is Qi or PMA compliant, simply place it on the circular target of the black plastic antenna cover. The transmitter should demonstrate the above actions, and the device receiving power should indicate it is taking a charge in whatever manner its users guide states. You can also perform foreign object detection (FOD) by following the steps in the "FOD Testing" section below. EVM Receiver Tests Additional testing can be performed with the use of an EVM receiver module. There are a number of Semtech Receiver EVMs that support different power levels and output voltages, any of which can be used, as all support the Qi and/or PMA standard and therefore are compatible with the TSDMTX-5V-EVM transmitter. In this User Guide, the TSDMRX-5V-EVM has been selected as the receiver to experiment with. Other Semtech receiver EVMs may be used instead in a similar manner; refer to the user guide for the selected receiver for details specific to the selected device. In order to use the TSDMRX-5V-EVM as a target receiver, simply place the receiver over the target circle on the transmitter EVM module. You should see the LEDs on each EVM turn green, indicating a transaction has been established. The EVM's purpose is to receive power; next you can decide what to deliver that power to. The user has a number of possible options to choose from. The optimal load to select would be a Programmable DC Electronic Load. A `load box' can easily be set to draw a selected current or power at the turn of a knob, making them very flexible and easy to use in observing power supply operation in general. If a load box is not available, a power resistor decade box is nearly as convenient, as it can easily be set to any desired resistance to simulate a range of load conditions. In either case, be sure the test load is rated for at least the amount of power being tested. If need be, a selection of power resistors Wireless Charging User Guide TSDMTX-5V-EVM www.semtech.com 5 of 19 Semtech could be used as test loads, though without the ease of modification of the prior options. Finally, any device that uses a 5 volt input up to 5 watts of power can be used as a test load should that be desired. Whatever load is selected, wires must be run from the VOUT+ and VOUT- pins of the receiver EVM to the selected test load, as per the illustration below. Once the load is added, the receiver EVM can be used to perform a variety of tests. Alternately, power can be drawn from the VBUS and GND lines of the USB port if desired. Status LED Connect a DC voltmeter across the VOUT+ and VOUT- pins to monitor the voltage being output to the load, and a DC ammeter in series with the VOUT+ line. Set levels to allow for up to 10 volts and 2 amps to be observed. With no load selected, place the receiver on the center of the transmitter target circle. Once transmission begins, you should observe approximately 5 volts and 0 amperes on the meters. Apply a variety of loads to observe performance at 1, 2, and 5 watt levels. Voltage should remain nearly constant, and current should follow the P=V*I relationship. Experiment with the maximum power that can be drawn before the receiver detects an overload and cuts off power. You should be able to observe on a minor overload, the receiver will attempt to restore power by retesting the load intermittently. In the case of a major overload, the transmitter may register an error, as indicated by a red LED on the transmitter, which will halt further activity until the receiver is removed from the target area for several seconds before being returned to start a new transaction. Wireless Charging User Guide TSDMTX-5V-EVM www.semtech.com 6 of 19 Semtech Observe Coil Signals The following information is not required in order to use the EVM, as what can be observed below is entirely managed by the Semtech TS80000 Wireless Controller. However, it allows the observer an opportunity to see how the receiver and transmitter actively manage the wireless power process. If you wish to observe the intrinsic wireless process, place an oscilloscope probe on one antenna lead, with the probe ground run to the board ground (one of the fastener screws will suffice). Be sure the scope can handle signals up to 100 volts. While the EVM power supply is only 5 volts, the antenna is part of a resonant circuit where considerably higher voltages are developed. To observe the search ping, apply power to the transmitter and remove the receiver from the target zone. The scope should display a `chirp' of 0.5 to 1mSec in duration with an initial peak of 10 to 20 volts. The frequency within the envelope of the chirp is in the 100-150 kHz range, which is the normal range of Qi and PMA systems. Next, place the receiver on the transmitter target. With the scope set to 0.5 to 1 uSec and 10 to 20 volts per division, you should observe a signal that is a composite of the sinusoidal power signal with a digital `notch' in the sinewave which is produced by the communication between the receiver and transmitter. Note as you vary the load and the location of the receiver on the target that the amplitude and frequency of the coil signal changes. The greater the load, the more signal is sent to transfer the power required by the load. Similarly, the less well coupled the receiver antenna is to the transmitter coil, the more power must be sent to compensate for the inefficient misalignment. You may note voltages near 140 volts peakto-peak in the most demanding conditions. Measure Efficiency By measuring the power from the receiver's VOUT+ and VOUT- pins in comparison to the power entering the transmitter EVM, you can determine the efficiency of the power transfer through the system. The diagram below, for EVMs similar to those used here, demonstrates efficiency is a function of output current, and runs about 75% beyond the mid-power point, assuring good efficiency and minimal heat dissipation concerns. Load vs Efficiency 90% 80% 70% Efficiency 60% 50% 40% 30% 20% 10% 0% 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 Output Current (A) Wireless Charging User Guide TSDMTX-5V-EVM www.semtech.com 7 of 19 Semtech Firmware Management The EVM is shipped with the most current release of the firmware at the time it was manufactured. As the standard evolves, or enhancements are made to the board performance, updates to the firmware will be available via your Semtech FAE. A small utility "FW_FLASH" allows you install the latest firmware to your board, and also to interrogate the board as to which version of the firmware is currently installed. FW_FLASH is also available via your Semtech FAE. Once obtained, install FW_FLASH to any desired location on your computer. If you wish to obtain the latest firmware, obtain and install it as well. Let Windows install an EVM Driver on your PC - Connect a USB cable between the EVM and your PC. Apply power to the EVM. Wait for windows to indicate that it has finished loading a driver for the EVM, then unplug the EVM. Note: you do not need to locate a special driver for this process. Windows will select one of its own. This operation only needs to be performed once on a given PC. Determine the EVM Flash Revision - To set up the EVM hardware correctly for the flash utility, start with an unpowered EVM. Double click on the FW_FLASH icon on your computer. FW_FLASH will open a window on your PC. Connect a USB cable between the EVM and your PC, which applies power and initiates the USB connection. The revision number of the flash firmware found on the EVM will be displayed in the FW_FLASH window. Close the window when you are done reviewing this information. Updating the EVM Flash Revision - Begin with an unpowered EVM. Drag the firmware file to send to the EVM onto the FW_FLASH icon. FW_FLASH will open a window on your PC. Connect the USB cable between the PC and the EVM. In the FW_FLASH window, the utility will indicate the progress of the flash update. In just a few seconds should indicate the update has been completed. Close the window when you are done reviewing this information. Wireless Charging User Guide TSDMTX-5V-EVM www.semtech.com 8 of 19 Semtech FOD Test In a production device, FOD testing is an important feature, in that the transmission process is constantly inspected for the introduction of extraneous materials in the target area that could absorb the transmitted energy and become hot. When Foreign Objects are Detected ("FOD"), the TS80000 shuts down power transmission as a safety precaution, and indicates the detected problem by blinking the red status LED. This process is bypassed in the receiver EVM, however, in order to allow engineers to test different antennas and make other hardware modifications without triggering the FOD protocols and complicating the testing process. When such hardware changes are made, the parameters of the feedback measurements change, which the FOD protocol would perceive as a foreign object in the field, and cause the system to shut down. In order to test the FOD protocols, the experimenter can use as a receiver any Qi certified cell phone. Examples of these are the Samsung Galaxy S6, Samsung Galaxy Edge, Samsung Galaxy Note+, various LG and Google Nexus phones, and, some models of the Nokia Lumia. A more extensive list can be found at: http://www.wirelesspowerconsortium.com/products/?brand_name=&product_name=&type_number=&pro duct_type=2&compliant_automotive=&sort=&direction=asc Experiments can be run on foreign objects on receivers with and without FOD management enabled to observe the differences. With FOD disabled, the metal object in the field will absorb some of the transmitted energy and become warm. Using a FOD-enabled production device, power transmission will be aborted when any significant interference in power transfer has been detected. Once a FOD abort takes place, the transaction is terminated, as indicated by a blinking red LED. To restart power transmission, the receiver must be removed from the target area and a new transaction must be initiated. If the FOD is still present, the transaction will fail again, and continue to do so until the FOD is removed from the target area. Based on prior information and experiments, what should be expected if FOD is introduced in the target area of an EVM that is not currently in a power transmission transaction? Why? Wireless Charging User Guide TSDMTX-5V-EVM www.semtech.com 9 of 19 Semtech Documentation The following sections document the hardware design of the TSDMTX-5V-EVM. This information can be used to better understand the functionality of the design, as well as assist in creating your own hardware solution based on this design A. Block Diagram The TSDMTX-5V-EVM may be divided into a number of sub-blocks as show in the diagram below: Antenna: Receive 5 Volt Supply 5 Volt Filters Bridge FETs FET Driver Boost FET Driver 3 Volt LDO Controller Matching Network Antenna: Transmit Filters 5 Volt Filters - smooths the 5 volt input supply FET Driver Boost - raises the 5 volt input above 6 volts for the FET drivers Controller - based on the TS80000 Wireless Power Controller. Includes I/O: USB, I2C, Temp Sensor, LED display FET Driver - based on the TS61001 Full-bridge FET Driver, powers the FETs based on inputs from controller Bridge FETs - gates drive power from the 5v supply to drive the resonant tank circuit (antenna) Matching Network - array of capacitors to create the resonant tank along with the antenna Antenna: Transmit - acts as the primary of an air-core transformer in conjunction with the receiver antenna Filters - adapt the antenna and drive values for use as feedback input to the controller Wireless Charging User Guide TSDMTX-5V-EVM www.semtech.com 10 of 19 Semtech B. Schematic Below are the schematics for the TSDMTX-5V-EVM. Annotation has been added to indicate which part of the block diagram each component is a member of: Controller 9v Filter VCCIN J4 DC IN + - 1 2 F1 L5 VCC_JACK DC_IN 1.5A D8 22V J5 L6 VCC_FLT C49 10uF 25V C50 10uF 25V C51 100nF 50V PGND_JACK C52 10nF 50V 6.8uH 1.5A R48 0 NP C53 10uF 25V PGND R51 0 J6 Micro-B USB Receptacle VBUS DD+ ID GND SHLD 1 2 3 4 5 The Wireless Power TX PCB can be populated in one of the following two configurations: -- 5V DC input -- 12V and/or 19V DC input NP USBD_N USBD_P U5 1 3 4 6 ZX62D-B-5P8 IO1 IO2 IO3 IO4 V+ GND VCC3V3 5 5V DC configuration: -- populate block A (optional) -- populate block B (optional) -- populate block C (always needed for 5V) 12V/19V DC configuration: -- populate block B (optional) -- populate block D (always needed for 12/19V) 2 IP4221CZ6-S,115 B PGND PGND_JACK Wireless Charging User Guide TSDMTX-5V-EVM USBdata (Optional) www.semtech.com 11 of 19 Semtech VCC5V VCCIN VCC5V R52 C57 10uF 10V 0 NP L7 33 uH 0.37A VCC5V VCC3V3 3.0V VCCDRV U4 D9 7 PGND R54 75K B0540W-7-F C61 10uF 16V Q5 2N7002 DRV_L R55 100K C 5V support PGND PGND PGND C55 100nF 50V DRV_VOLTAGE R61 10K PGND C62 33pF INPUT R46 10K 8 2 OUTPUT R47 15K ENABLE 6 FB R49 75K GND PAD R50 10K 1 9 TS31023 GND GND GND Place close to the MCU 4.7uF decoupling capacitor. PGND VCCIN VCC3V3A TIE1 Net Tie C14 22uF 25V R19 0.020 0.1W U2 R17 4 1.0 TIE2 Net Tie C13 100nF 5 R20 1.0 IN+ OUT V+ IN- REF GND R18 6 3 DC_CURRENT 1K C15 10nF 1 2 DC_CURRENT C16 100nF INA199A2 VBRIDGE R22 PGND 10K U3 PGND DRV_EN DRV_EN 26 27 15 16 11 10 18 12 PWM1_H PWM1_L PWM2_H PWM2_L R30 10K R31 10K C17 100nF 50V R32 10K VB1 SLEEP PGOOD SDATA SCLK HS1ON LS1ON HS2ON LS2ON HO1 21 20 19 PGND DRV_VOLTAGE DRV_CMP 24 22 23 R34 1M VS1 R36 10K 1 R26 3 Q2 BSC120N03MS G C27 2.7nF 50V 25 4 17 14 C45 10uF 16V C43 100nF C41 4.7uF 6.3V C44 100nF 13 Q3 BSC120N03MS G 9 7 C32 100nF 50V PGND PGND PGND PGND C20 NP C21 NP VBRIDGE AGND C25 PGND C35 47nF 250V C38 47nF 250V VS2 8 R39 1.0 VCCG V3P3 LO2 AGND ACA COILB 4.7nF 200V NP Antenna R28 200K NP R12 14K NP R15 14K AGND NP C40 NP C29 NP L3 TX Inductor 24uH D4 BAT54SW-7-F NP C26 33pF NP AGND VCC3V3A COILB VBRIDGE 4.7nF 200V PGND SW2 Q4 BSC120N03MS G R40 2.0 AGND L4 2.2uH 4.2A NP C30 NP C28 NP C31 NP D5 BAT54SW-7-F R38 200K R57 14K AGND ACB_VOLTAGE VCC3V3 R56 14K COILB C34 C36 47nF ACA_VOLTAGE VCC3V3 C37 33pF AGND AGND 6 V5INT PAD PGND C39 C33 22uF 25V R37 29 5 R41 0 C42 2.7nF 50V TS61001 PGND NP COILA VBRIDGE STRTUP AGND NP C24 DC_VOLTAGE C19 4.7nF ACB HO2 PGND C23 PGND PGND AMPP AMPN AMPOUT 0 VCCDRV 2.2uH 4.2A NP R27 2.0 COMPP COMPN COMPOUT PGND L2 SW1 R29 0 0 R23 10K VCC3V3A C22 47nF 1.0 VB2 R35 25K PGND Q1 BSC120N03MS G DC_VOLTAGE 75K R24 R25 0 LO1 R33 10K 28 2 AGND R21 C18 22uF 25V PGND R42 PGND AC_MAX 0 VCC3V3A Matching Network D7 PGND PGND COILA 1K NP COILB C46 R43 BAS21LT3G C47 1nF 200V R59 4.7nF 100K 200V R58 7.5K D6 BAT54SW-7-F R44 1K R60 7.5K AC_MAX VCC3V3 C48 4.7nF R45 1K AGND AGND AGND AGND AGND Place the analog filters close to the Wireless Controller Feedback Filtering Wireless Charging User Guide TSDMTX-5V-EVM www.semtech.com 12 of 19 Semtech C. Bill Of Materials "BOM" Below is a listing of the parts used in the TSDMTX-5V-EVM. An excel spreadsheet file with this information is available on the Semtech website as an added convenience. Designator Value Detail Manufacturer Qty 1 C1, C6, C41 4.7uF/6.3V JMK107BJ475KA-T Tayio Yuden 3 2 C14, C18, C33 22uF/25V TMK316BBJ226ML-T Taiyo Yuden 3 3 C15 10nF/50V GRM155R71H103KA88D Murata 1 4 C17, C32, C51, C55 100nF/50V GRM155R61H104KA01D Murata 4 5 C2-5, C7, C9, C10, 13,C16, C43-44 100nF/10V GRM155R61A104KA01D Murata 11 6 C22, C36 47nF/25V GRM188R71E473KA01D Murata 2 7 C27, C42 2.7nF/50V CC0603KRX7R9BB272 Yageo 2 8 C34 4.7nF/200V C1608X7S2A473K TDK 1 9 C35, C38-40 100nF/50V C3225C0G2E104J250AA TDK 4 10 C37, C62 33pF/16V C0402C0G1C330J020BC TDK 2 11 C45 10uF/16V C2012X5R1E106K085AC TDK 1 12 C46 4.7nF/200V C1608X7S2A473K TDK 1 13 C47 1nF/200V GRM188R72E102KW07D Murata 1 14 C49, C50, C53,C54 10uF/25V C2012X5R1C106K085AC TDK 4 15 C52 10nF/50V C1608X7R1H103K080AA TDK 1 16 C57,C61 10uF/16V C1608X5R1C106M080AB TDK 2 17 C8, C19, C48 4.7nF/10V C0402X5R1A103K020BC TDK 3 18 D3 APHB1608ZGSURKC Kingbright 1 19 D5, D6 BAT54SW-7-F Zetex 2 20 D7 BAS21LT3G ON Semiconductor 1 21 D8 22 D9 23 F1 24 J5 25 J6 ZX62D-B-5P8 Hirose 1 26 L1 600 BLM18AG601SN1D Murata 1 27 L3 6.3uH WT-505090-10K2-A11-G TDK 1 1 22V 1.5A SMAJ22A Bourns 1 B0540W-7-F Zetex 1 CQ12PF CONQUER 1 PJ-014DH-SMT CUI 1 28 L5 IND_CHOKE_TAI_TECH Common Mode Choke 29 L6 6.8uH/1.5A IFSC1515AHER6R8M01 Vishay 1 30 L7 33 Uh/0.37A NR3015T330M Tayio Yuden 1 31 Q1, Q2, Q3, Q4 BSC120N03MS G Infineon 4 32 Q5 2N7002LT3G On Semiconductor 1 33 R1, R46, R22-23, R30-33, R36, R50, R61 10K RC0402FR-0710KL 11 34 R10 220 10K/1% 0402 1 35 R15,R56,R57 14K 14K/1% 0402 3 36 R2,R17, R20, R26, R39 1 RC0402FR-071RL 5 37 R18, R44, R45 1K 1K/1% 0402 38 R19 0.020/0.1W 0.02/1% 0603 39 R21, R49, R54 75K 75K/1% 0402 40 R3,R24, R25, R29, R37, R41, R51,R52,R42 0 0K/1% 0402 9 41 R27, R40 2 2.0/1% 0402 2 42 R34 1M 1M/1% 0402 1 Wireless Charging User Guide TSDMTX-5V-EVM www.semtech.com 3 Vishay 1 3 13 of 19 Semtech Designator Value Detail 43 R35 25K 25K/1% 0402 Manufacturer 1 Qty 44 R38 200K 200K/1% 0402 1 45 R47 15K 15K/1% 0402 1 46 R55, R59 100K 200K/1% 0402 2 47 R58, R60 7.5K 7.5K/1% 0402 2 48 R6 1.5K 1.5K/1% 0402 1 49 R8, R9 150 RC0402FR07150RL 50 U1 IC TS80000 Semtech 1 51 U2 IC INA199A1DCKR TI 1 52 U3 IC TS61001 Semtech 1 53 U4 IC TS31023 Semtech 1 54 U5 IC IP4221CZ6-S,115 NXP 1 55 Y1 8MHz CSTCE8M00G55R0 Murata 1 2 D. Board Layout The diagram below shows the locations of the components used in the TSDMTX-5V-EVM PCB. Wireless Charging User Guide TSDMTX-5V-EVM www.semtech.com 14 of 19 Semtech E. Board Layers The TSDMTX-5V-EVM PCB is based on a four layer design as shown below. The ground plane in layer two is recommended to reduce noise and signal crosstalk. The EVM placed all components on the top of the board for easier evaluation of the system. End product versions of this design can be made significantly smaller by distributing components on both sides of the board. The Gerber files for this artwork can be downloaded from the Semtech web page. Top Layer Ground Plane Wireless Charging User Guide TSDMTX-5V-EVM www.semtech.com 15 of 19 Semtech Signal Layer Bottom Layer Wireless Charging User Guide TSDMTX-5V-EVM www.semtech.com 16 of 19 Semtech FAQs Q: What output voltage is provided by the TSDMTX-5V-EVM system? A: It depends on which receiver is being used. For the TSDMRX-5V-EVM, the output would be 5 volts. Q: Where can I find more information on the Qi and PMA standards? A: There are a number of websites that address this subject. A good starting point for Qi would be: http://www.wirelesspowerconsortium.com/technology/how-it-works.html. PMA, which is now joined with A4WP, is now called AirFuel. Information on them can be found at: http://www.airfuel.org/technologies/inductive. Q: Does the EVM part number represent something in particular? A: Yes. The part number is broken into a prefix, main body, and suffix, separated by dashes. The prefix is comprised of three two letter groupings that each help define the product represented. As such, the part number can be read as follows: Prefix characters: 1+2 = Company : TS = Triune/Semtech 3+4 = Environment : DM = Dual Mode WI = Wearable Infrastructure 5+6 = Type : TX = Transmit RX = Receive Mid-section = Device Voltage or Wattage Suffix = Equipment type: EVM = Evaluation Module MOD = Production Module Therefore, the TSDMTX-5V-EVM is a Dual Mode, 5 volt Transmitter Evaluation Module provided by Semtech. Q: What if my questions weren't answered here? A: Go to the Semtech website as described on the next page. An updated FAQ for the TSDMTX-19V1EVM is maintained there and may contain the answers you're looking for. Your local Semtech FAE can also assist in answering your questions. Wireless Charging User Guide TSDMTX-5V-EVM www.semtech.com 17 of 19 Semtech Next Steps For more information on Wireless Power, go to the Semtech webpage at: https://www.semtech.com/power-management/wireless-charging-ics/ You may also scan the bar code to the right to go to the above web page: There you can find the downloadable copies of the schematic, BOM, and board artwork, as well as additional information on how to obtain Semtech wireless power products, from the chip level all the way to complete board modules, as your needs require. Wireless Charging User Guide TSDMTX-5V-EVM www.semtech.com 18 of 19 Semtech IMPORTANT NOTICE Information relating to this product and the application or design described herein is believed to be reliable, however such information is provided as a guide only and Semtech assumes no liability for any errors in this document, or for the application or design described herein. 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