Wireless Power Transmitter for 3W Applications P9235A-R Datasheet Features Description The P9235A-R is a 3W, magnetic induction, wireless power transmitter for low power applications. The system-on-chip operates with an input voltage range of 4.5 - 5.5V while integrating micro-controller, voltage regulation, over-current protection, full bridge power stage drivers and on-chip simultaneous voltage and current demodulation. The transmitter includes industry-leading 32bit ARM(R) Cortex(R)M0 processor offering a high level of programmability, while consuming extremely low standby power. The device features two LED outputs with pre-defined user programmable blinking patterns, buzzer and programmable over-current protection supporting wide range of applications. The I2C serial communication allows the user to read back information such as voltage, current, frequency and fault conditions. Together with the P9027LP-R receiver, the P9235A-R is a complete wireless power system solution. The P9235A-R is available in a Pb-free, space-saving VFQFN 5 mm X 5 mm, 40 pin package. The product is rated over an operating temperature range of -40C to +85C. VIN range: 4.5 - 5.5 V Supports receiver for up to 3W of power transfer 80% peak efficiency (when coupled with P9027LP receiver) Integrated power stage drivers Low standby power Simultaneous voltage and current demodulation Integrated 32 bit ARM(R) Cortex(R)-M0 Processor Supports I2C interface for field programmability Programmable current limit Over-Current and Over-Temperature protection Active low enable pin for electrical on/off Pre-defined programmable LED patterns Dedicated remote temperature sensing -40C to +85C ambient operating temperature range VFQFN 5mm X 5mm, 40 pin package Typical Applications Smart Watches Headsets Health and Fitness monitors Portable Medical applications Figure 1. Application Diagram VIN RSENSE V_BRIDGE 4.5V -5.5V LED_RED LED_GRN ISNS_IN EN ISNS_L ISNS_OUT On VIN Off Discrete R,C Filter 1 ISNS_H LDO33 GH_BRG1 GL_BRG1 VO_5 GH_BRG2 SW_B VIN_LDO P9235A-R GL_BRG2 LDO33 LDO18 Resistor dividers (c) 2016 Integrated Device Technology, Inc LDO18 VSNS SDA SCL ILIM LED_PAT RSVD1 RSVD2 Discrete R,C Filter 2 LDO18 TS 1 May 17, 2016 P9235A-R Datasheet Absolute Maximum Ratings These absolute maximum ratings are stress ratings only. Stresses greater than those listed in Table 3, 4 and 5 may cause permanent damage to the device. Functional operation of the P9235A-R at absolute maximum ratings is not implied. Exposure to absolute maximum rating conditions for extended periods may affect long-term reliability. Table 1. Absolute Maximum Ratings Summary (All voltages are referred to ground.) Pins EN , VIN, SW_B, VBRG_IN, SW_BRG1, SW_BRG2, ISNS_H, ISNS_L, BST_BRG1, BST_BRG2, GH_BRG1, GH_BRG2 VO_5, VO_33, VIN_LDO, LED_GRN, LED_RED, VDDIO, GPIO_A4, GPIO_B2, GPIO_B3, RSVD1, RSVD2, SCL, SDA, ILIM, LED_PAT, TS, BUZ, GL_BRG1, GL_BRG2, VSNS_IN, ISNS_IN, ISNS_OUT, VDRV_IN GND_S, GND_BRG, VSNS_GND, GND_B, EPGND Rating Units -0.3 to 28 V -0.3 to 6 V +0.3 V -0.3 to 2 V LDO18 Thermal Characteristics Table 21,2,3. Package Thermal Characteristics Symbol Description QFN Rating Units JA Thermal Resistance Junction to Ambient 28.5 C/W JC Thermal Resistance Junction to Case 21.87 C/W JB Thermal Resistance Junction to Board 1.27 C/W TJ Operating Junction Temperature -40 to +125 C TA Ambient Operating Temperature -40 to +85 C TSTG Storage Temperature -55 to +150 C TLEAD Lead Temperature (soldering, 10s) +300 C Notes: 1. The maximum power dissipation is PD(MAX) = (TJ(MAX) - TA) / JA where TJ(MAX) is 85C. Exceeding the maximum allowable power dissipation will result in excessive die temperature, and the device will enter thermal shutdown. 2. This thermal rating was calculated on JEDEC 51 standard 4-layer board with dimensions 3" x 4.5" in still air conditions. 3. Actual thermal resistance is affected by PCB size, solder joint quality, layer count, copper thickness, air flow, altitude, and other unlisted variables. Table 3. ESD Information Test Model HBM CDM Pins All pins All pins. (c) 2016 Integrated Device Technology, Inc 2 Ratings Units +/- 2000 +/- 500 V V May 17, 2016 P9235A-R Datasheet Electrical Characteristics Table 4. Device Characteristics VIN = 5 V, VDDIO = 3.3 V, EN = 0V, LP= 6.5 H, CP = 400 nF TA = -40C to +85C. Typical values are at 25C, unless otherwise noted. Symbol Description Conditions/Notes Min Typical Max Units Input Supplies and UVLO VIN Input Operating Range 4.5 5.0 5.5 VIN_UVLO_FW Firmware Controlled UnderVoltage Lockout. VIN Rising 4.3 V ISTD_BY2 ISHD Standby Mode Current Shutdown Current Periodic ping ENB = VIN 12 25 mA A 80 V Enable - EN VOH_ENB Output logic high VOL_ENB Output logic low 2.0 V 0.25 V Buck Converter1,2 - COUT=10F; L=4.7H VOUT IOUT Buck Output Voltage Output Current VIN>5.5V 5 50 V mA CL= 3nF; 10 - 90%, 90 - 10% 50 150 ns CL= 3nF; 10 - 90%, 90 - 10% 150 300 ns N-Channel MOSFET Drivers TLS_ON_OFF THS_ON_OFF Low Side Gate Drive Rise & Fall times High Side Gate Drive rise & Fall times Input Current Sense VSEN_OFST Amplifier offset voltage Measured at ISNS_OUT pin; ISNS_H=ISNS_L 0.6 ISENACC_TYP Measured Current sense accuracy VR_ISEN=25mV, I=1.25A 3.5 V % Analog to Digital Converter N Channel VIN,FS LDO181,2 Resolution Number of channels Full scale Input voltage 12 10 2.4 Bit V - COUT=1F; VOUT18 VOUT/VOUT IOUT18_MAX Output voltage Output voltage accuracy Maximum load current 1.71 1.8 5 10 1.89 V % mA 3.15 3.3 3.45 5 V % 20 mA 140 120 C C LDO331,2 - COUT=1F; VOUT33 Output voltage VOUT/VOUT Output voltage accuracy IOUT33_MAX Maximum Output Current Thermal Shutdown TSD Thermal shutdown (c) 2016 Integrated Device Technology, Inc Threshold Rising Threshold Falling 3 May 17, 2016 P9235A-R Datasheet Table 5. Device Characteristic (Continued) VIN = 5 V, VDDIO = 3.3 V, EN = 0V, LP = 6.5 H, CP = 400 nF TA = -40C to +85C. Typical values are at 25C, unless otherwise noted. Description Conditions/Notes Min Typical Max Units Symbol Clock Oscillators FLSOSC Low speed clock 50 kHz FCLOCK OSC clock frequency 6 MHz FCENTER2 PLL VCO frequency 120 MHz General Purpose Inputs/Outputs (GPIO) VIH Input high voltage 0.7*VDDIO VIL Input low voltage ILKG Leakage Current VOH Output logic high I=8mA VOL Output logic low I=8mA V -1.0 0.3*VDDIO V 1 .0 A 2.4 V 0.5 V SCL, SDA (I2C Interface) fSCL_MSTR Clock Frequency As I2C master 400 kHz fSCL_SLV Clock Frequency As I2C slave 400 kHz CB Capacitive load For each bus line CBIN SCL, SDA Input Capacitance ILKG Leakage Current 100 5.0 1.0 pF pF 1.0 A NOTES: 1. Do not externally load. For internal biasing only. 2. Guaranteed by design and not subject to 100% production testing (c) 2016 Integrated Device Technology, Inc 4 May 17, 2016 P9235A-R Datasheet Typical Performance Characteristics Figure 2. Typical Performance Characteristics - 3W Efficiency vs Current - 3W Load Regulation vs Current - 3W Vin=5V, Vout=5V, Tx=P9235A-R, Tx coil=760308101103, Gap=1.5mm, Rx coil=760308102213, Rx=P9027LP-R, No air flow, Room temperature Vin=5V, Vout=5V, Tx=P9235A-R, Tx coil=760308101104, Gap=1.5mm, Rx coil=760308101220, Rx=P9027LP-R, No air flow, Room temperature 85 0.5 80 0.4 0.3 Load Regulation (%) Efficiency (%) 75 70 65 60 55 50 0.2 0.1 0 -0.1 0 40 80 120 160 200 240 280 320 360 400 -0.2 -0.3 45 -0.4 60 120 180 240 300 360 420 480 540 600 -0.5 Iout (mA) Iout (mA) Figure 3. Typical Performance Characteristics - 2W Efficiency vs Current - 2W Load Regulation vs Current - 2W Vin=5V, Vout=5V, Tx=P9235A-R, Tx coil=760308101104, Gap=1.5mm, Rx coil=760308101220, Rx=P9027LP-R, No air flow, Room temperature Vin=5V, Vout=5V, Tx=P9235A-R, Tx coil=760308101104, Gap=1.5mm, Rx coil=760308101220, Rx=P9027LP-R, No air flow, Room temperature 70 0.5 65 0.4 60 0.3 Load Regulation (%) Efficiency (%) 75 55 50 45 40 35 30 25 40 80 120 160 200 240 280 320 360 0.2 0.1 0 -0.1 0 40 80 120 160 200 240 280 320 360 400 -0.2 -0.3 -0.4 400 -0.5 Iout (mA) Iout (mA) Figure 4. Typical Performance Characteristics - 1W Efficiency vs Current - 1W Load Regulation vs Current -1W Vin=5V, Vout=5V, Tx=P9235A-R, Tx coil=WT151512-21F2, Gap=1.5mm, Rx coil=WR121220-27M8, Rx=P9027LP-R, No air flow, Room temperature Vin=5V, Vout=5V, Tx=P9235A-R, Tx coil=WT151512-21F2, Gap=1.5mm, Rx coil=WR121220-27M8, Rx=P9027LP-R, No air flow, Room temperature 60 0.5 0.4 0.3 LoadRegulation (%) Efficiency (%) 50 40 30 20 10 0.2 0.1 0 -0.1 0 20 40 60 80 100 120 140 160 180 200 -0.2 -0.3 0 20 40 60 80 100 120 140 160 180 -0.4 200 -0.5 Iout (mA) (c) 2016 Integrated Device Technology, Inc Iout (mA) 5 May 17, 2016 P9235A-R Datasheet Pin Configuration 40 39 38 37 36 35 34 33 32 31 ISNS_H ISNS_L ISNS_OUT ISNS_IN VSNS_IN VSNS_GND VBRG_IN VIN_DRV GH_BRG1 BST_BRG1 Figure 5. QFN-40 5 mm x 5 mm - Top View 1 EN SW_BRG1 30 2 GND_S GL_BRG1 29 3 VO_5 GND_BRG 28 4 VIN GL_BRG2 27 5 SW_B SW_BRG2 26 6 GND_B BST_BRG2 25 EP (Center Exposed Pad) GPIO_B2 22 10 RSVD1 LED_GRN 21 LED_RED VO_18 BUZ 9 TS 23 GPIO_A4 GPIO_B3 LED_PAT VIN_LDO ILIM 8 SDA 24 SCL GH_BRG2 VDDIO VO_33 RSVD2 7 11 12 13 14 15 16 17 18 19 20 (c) 2016 Integrated Device Technology, Inc 6 May 17, 2016 P9235A-R Datasheet Pin Description Table 6. Pin Descriptions Pin(s) Name Type Description Active low enable pin. When connected to logic high, the device shuts down and consumes less than 25 A of current. When connected to logic low, the device is in normal operation. 1 EN I 2 GND_S - Ground connection. 3 VO_5 O Regulated output voltage used for the internal device biasing. Connect a 1 F capacitor from this pin to ground. This pin should not be externally loaded. 4 VIN I Input power supply. Connect a 10 F capacitor from this pin to ground. 5 SW_B O Step-down regulator switch node. Connect one of the terminals of a 4.7 H inductor to this pin. 6 GND_B - Ground connection. 7 VO_33 O Regulated 3.3 V output voltage used for internal device biasing. Connect a 1 F capacitor from this pin to ground. This pin should not be externally loaded. 8 VIN_LDO I Low Dropout input power supply. Connect this pin to a 5 V source, either to the output of the 5 V output step-down regulator or to the input power supply pin, VIN. 9 VO_18 O Regulated 1.8 V output voltage used for internal device biasing. Connect a 1 F capacitor from this pin to ground. This pin should not be externally loaded. 10 RSVD1 I This pin is reserved for internal use only. Pull down to ground with an external 47 k resistor. 11 RSVD2 I This pin is reserved for internal use only. Pull down to ground with an external 47 k resistor. 12 VDDIO I Input power supply for all GPIOs. Can be connected to a power supply ranging from 1.8 - 5.0 V. 13 SCL I Clock for I2C communication. Connect a 5.1 K resistor from this pin to VO_5 14 SDA I/O Data for I2C communication. Connect a 5.1 K resistor from this pin to VO_5 15 ILIM I Programmable over-current limit pin. Connect a resistor from this pin to GND to set the current-limit threshold. To disable the current-limit, connect the pin directly to GND. For more information, see current limit application section. 16 LED_PAT I Programmable LED pattern selection. Connect the center tap of the resistor divider to this pin. For more information on various LED blinking pattern, see LED pattern application section. 17 GPIO_A4 I/O General purpose input/output. The GPIO's power is supplied from the VDDIO pin. This pin is configured as an output. If it is not used then it may be left floating. 18 TS I Remote temperature sensing. Connect a 10 k NTC via a voltage divider to this pin. 19 BUZ O Buzzer pin output. (c) 2016 Integrated Device Technology, Inc 7 May 17, 2016 P9235A-R Datasheet Table 7. Pin Descriptions (continued) Pin(s) Name Type Description Open drain output. Connect a red LED to this pin. This pin can sink a maximum current of 25 mA (typical) 20 LED_RED O 21 LED_GRN O Open drain output. Connect a green LED to this pin. This pin can sink a maximum current of 25 mA (typical) 22 GPIO_B2 I/O General purpose input/output. The GPIO's power is supplied from the VDDIO pin. This pin is configured as an output. If it is not used then it may be left floating. 23 GPIO_B3 I/O General purpose input/output. The GPIO's power is supplied from the VDDIO pin. This pin is configured as an output. If it is not used then it may be left floating. 24 GH_BRG2 O Gate driver output for the high-side half bridge 2. 25 BST_BRG2 I Bootstrap pin for the half bridge 2. Tie an external capacitor from this pin to the SW_BRG2 to generate a drive voltage, which is higher than the input voltage. 26 SW_BRG2 O Switch node for half bridge 2. 27 GL_BRG2 O Gate driver output for the low-side half bridge 2. 28 GND_BRG - Ground return connection for half bridge 1 and half bridge 2 external FETs and associated components. 29 GL_BRG1 O Gate driver output for the low-side half bridge 1. 30 SW_BRG1 O Switch node for half bridge 1. 31 BST_BRG1 I Bootstrap pin for half bridge 1. Tie an external capacitor from this pin to the SW_BRG1 to generate a drive voltage higher than the input voltage. 32 GH_BRG1 O Gate driver output for the high-side half bridge 1. 33 VIN_DRV I Input power supply for the internal gate drivers. Connect a 10 F capacitor from this pin to ground. 34 VBRG_IN I Bridge voltage input voltage sense. 35 VSNS_GND - Ground connection for voltage sense signals. 36 VSNS_IN I Voltage modulation signal input. 37 ISNS_IN I 38 ISNS_OUT O Differential (ISNS_H - ISNS_L) current sense buffered output. 39 ISNS_L I Input current sense negative input 40 ISNS_H I Input current sense positive input EPGND - Expose pad. Thermal pad for heat sinking purposes. Connect EPGND to GND plane. Current modulation signal input. ISNS_OUT is fed into this pin after external conditioning (c) 2016 Integrated Device Technology, Inc 8 May 17, 2016 P9235A-R Datasheet GND_S Demodulation (Isense) Demodulation (Vsense) Buck Controller VIN Half/Full Bridge PWM Controller SW_B 32-Bit ARM M0 Processor LDO33 LDO 1.8V LDO18 GPIO_A4 RSVD1 RSVD2 SDA Low Side Driver 1 GL_BRG1 SW_BRG1 BST_BRG2 GH_BRG2 SW_BRG2 GL_BRG2 GND_BRG LDO 3.3V SCL GH_BRG1 Low Side Driver 2 VIN_LDO VIN_DRV BST_BRG1 High Side Driver 1 High Side Driver 2 GND_B VSNS_GND ISNS_OUT ISNS_H ISNS_L Current Sense Amplifier VSNS_IN VO_5 PreReg Bridge Voltage Sense ISNS_IN Reference VBRG_IN EN Figure 6. P9235A-R Block Diagram 32KB 4KB OTP SRAM 12-Bit ADC 120MHz PLL MUX 6MHz OSC VDDIO I/O Module LED Driver BUZ Driver LED_GRN LED_RED BUZ GPIO_B2 GPIO_B3 LED_PAT I2C (c) 2016 Integrated Device Technology, Inc TS ILIM 9 May 17, 2016 P9235A-R Datasheet Theory of Operation General System Architecture A wireless power transfer system has two sub-systems: the wireless power transmitter (Tx) and the wireless power receiver (Rx). The transmitter makes power available through a full bridge/half bridge driven LC resonant tank. It transmits power through the generation of an AC magnetic field. Once the receiver coil is placed near the magnetic field, the field will induce an AC current through the receiving coil where it is converted into a DC current. High Level Control Scheme Wireless power systems adopt a set of pre-defined in-band communication commands as the close loop control strategy. The amount of power transferred is controlled by the receiver. The receiver sends out Control Error Packets (CEP) to the transmitter to increase power, decrease power, or maintain the power level. The transmitter responds by adjusting the switching frequency and/or duty ratio. The receiver requests more power by sending out a CEP, which includes a positive numerical value. The communication is digital. The communication 1's and 0's ride on top of the power link that exists between the two coils. Wireless Power Communication When the transmitter is not transferring power to the receiver, it is in the low power Standby Mode. While in this mode, in order to detect a receiver, the transmitter sends out periodic analog and digital pings. Analog pings are very short AC detection pulses. These short pulses do not transmit enough energy to wake up the receiver, only to detect its presence. Digital pings, on the other hand, do transmit enough power to enable the receiver to wake up and begin communication. The transmitter uses digital pings to listen for a response from a receiver. After the transmitter detects a receiver, it may extend the digital ping. This causes the system to proceed to the Identification and Configuration phase. Once the receiver is detected and powered up, it will send out communications packets to handshake with the transmitter. The first communication packet the receiver sends out is the Signal Strength packet, followed by Identification packets and Configuration packets. Once the handshake process is done, the receiver will send out periodic Control Error packets and Received Power packets to adjust the power. If the receiver needs to stop the power transfer, it will send out an End of Power Transfer (EPT) communication packet. The transmitter stops transmitting power immediately, and starts pre-defined routines according to the information decoded from the EPT packet. System Fault Protection The wireless power transfer system implements system level protection. These include over voltage, under voltage, over current, and over temperature protection. On the transmitter side, whenever a fault condition is detected, it shuts down the whole system immediately and protects itself. If the receiver detects a fault condition, it will send the End of Power Transfer packets to shut down the system. The transmitter will continue to transmit power from the time of the receiver fault detection to the reception of the End of Power Transfer packet. Over voltage protection: If the transmitter VIN is greater than 5.5 V, and the system is not in the Power Transfer mode, then the transmitter will shut down until the VIN is in the range of 4.5 V to 5.5 V. If the system is already in the Power Transfer mode, then the transmitter takes no action. Under voltage protection: If the transmitter VIN is less than 4.5 V, the transmitter will shut down for five minutes, or until the VIN is cycled. off/on. Over current protection: The transmitter uses a 20 m sense resistor (RSENSE, R6) to monitor the current. If the transmitter detects a current greater than the programmed current limit, it will shut down for five minutes, or until VIN is cycled off/on. Over temperature protection: If the TS pin (pin 18) voltage falls below 600 mV (typical) then the transmitter will shut down. It will restart once the TS voltage rises above 800 mV (200 mV hysteresis). (c) 2016 Integrated Device Technology, Inc 10 May 17, 2016 P9235A-R Datasheet Applications Information LDOs There are three internal LDOs, which supply the P9235A-R internal voltage rails. Do not externally load any of the LDOs. VO_5 is the output of a high voltage LDO, which serves as the pre-regulator. VO_5 initially supplies the input voltage to the other two LDOs until the buck regulator output voltage powers up. The other two LDOs, VO_33 and VO_18, have output voltages of 3.3 V and 1.8 V, respectively. The analog circuitry is power by the 3.3 V LDO. The digital circuitry is powered by the 1.8 V LDO. LDO Input and Output Capacitors For proper load voltage regulation and operational stability, low ESR ceramic capacitors are required on the input and output of each LDO. A 10 F low ESR ceramic cap is recommended for both the input (C19) and output (C14, C27, C29) capacitors. The capacitor's connection to the ground pin should be as short as possible for optimal device performance. Buck Regulator The buck regulator is the power supply for the 3.3 V and 1.8 V LDOs, and thus for all the internal analog and digital circuitry, excluding the pre-regulator only. Do not externally load any of the LDOs. The current sourcing capability of this internal buck regulator is 50 mA maximum. The two half bridge gate driver circuits are directly power by the buck regulator. The P9235A-R buck regulator operates in hysteretic pulse mode to set the output voltage and will regulate the output voltage at 5 V (typical) when VIN is greater than 5.5 VDC. For operation with VIN less than 5.5 V, the buck output will decrease below 5 V. When the VIN is less than 5 V, the regulator will switch to a linear mode that is similar to a LDO. The input (C18, C19) and output (C20, C21) capacitors must be connected directly between each power rail pins and power GND pin (and placed as close as possible to the respective IC pins). The output capacitors should be selected based on the typical reference schematic to guarantee control loop stability. A 10 F low ESR ceramic cap is recommended for both the bulk input (C19) and bulk output (C21) capacitor. The buck regulator output voltage is connected to the VIN_LDO pin; therefore, the connection from the buck output to the VIN_LDO pin should be made as wide and short as possible to minimize output voltage errors. Buck Inductor Selection A 4.7 H inductor (L1) is used for the P9235A-R buck regulator. Select the inductor saturation current rating to exceed the value of peak inductor current (during normal operation and start up). The inductor included in the Bill of Materials is recommended. Keep the inductor DCR to a minimum to improve the efficiency of the regulator. Decoupling Capacitors As with any high-performance mixed-signal IC, P9235A-R must be isolated from the system power supply noise. A decoupling capacitor of 0.1 F should be connected between each power supply pin (includes VIN, the buck regulator, LDOs, VBRG_IN, V_BRIDGE: C18, C20, C28, C9, C12, C31) and the PCB ground plane. It must be placed as close as possible to these pins. The decoupling capacitor must be mounted on the component side of the PCB. Note: The VO_33 does not need this decoupling capacitor if the user follows the IDT recommended, optimized layout. Full Bridge Input Capacitor At least one 10 F capacitor (C19) must be placed at the VIN pin. At least three 10 F capacitors (C10, C11, C30) must be placed across the full bridge voltage source (the V_BRIDGE node in the schematic) to minimize voltage ripple and voltage drop due to the large current requirements. The full-bridge is used to convert DC voltage to AC voltage for power transfer. These 10 F capacitors must be placed as close as possible to the respective pins. Note: If the half bridge FETs are not physically close together then two 10 F capacitors per half bridge are needed. Follow the IDT optimized layout in order to minimize these capacitors (c) 2016 Integrated Device Technology, Inc 11 May 17, 2016 P9235A-R Datasheet Enable Function (EN Pin) When voltage on the EN pin is greater than 2.5 V, the P9235A-R shuts down the buck regulator. It goes onto Shutdown Mode, which disables all the analog and digital modules. Current consumption in Shutdown Mode is less than 25 A. When EN is less than 1.0 V, the P9235A-R is fully functional, and all the blocks are enabled. Figure 7 shows EN thresholds. V_EN (V) Figure 7. EN pin threshold 2.5V VEN_H VEN_L 1.0V Normal Operating mode Shutdown Mode Normal Operating mode Time When EN is less than 1.0 V and a receiver is not yet detected, the P9235A-R is in the low power Standby Mode. The P9235A-R periodically comes out of Standby Mode to generate digital and analog pings to detect the presence of a receiver. Between these pings, the P9235A-R continues in the Standby Mode to maintain low power consumption. Input Current Sense The P9235A-R monitors its input current by using an external sense resistor (R6), in series with the input voltage rail of the full bridge LC tank driver circuit (Q2, Q3). The voltage across the sense resistor is fed into the ISNS_H and ISNS_L pin via an RC filter (R4,R5,C2). The differential signal of ISNS_H and ISNS_L is processed by the internal ADC and associated firmware. The current sense resistor is sensitive to noise, as well as to circuit board conditions. On the layout of PCB, it is necessary to use Kelvin sensing when routing the ISNS_H and ISNS_L connections. Incorrect current reporting may also occur when a re-worked board has residue (e.g. flux) around the sense resistor. More details are available in the P9235A-R layout guide, AN936. For 2W/3W applications, use a 20m sense resistor (R6). For 1W applications use a 50 m sense resistor. Adjust the resistor divider (R27, R31) value on the LED_PAT pin according to the sense resistor used. Communication and Modulation The wireless power system uses an in-band communication, such that the current and voltage on the transmitter's power coil assume two states, namely a HI state and a LO state. For a valid state, the amplitude is constant, within a certain variation , for at least ts ms. If the wireless power receiver is properly aligned to the transmitter's power coil, and for all appropriate loads, at least one of the following two conditions shall apply, as shown in Figure 8. Difference of the amplitude of the transmitter current in the HI and LO state: 15 mA. Difference of the amplitude of the transmitter voltage in the HI and LO state: 200 mV. The minimum hold time for a valid HI or LO state: 0.15 ms Figure 8. Modulation ts ts ts HI State HI State ts Modulation Depth LO State LO State The receiver uses a 2 kHz, differential, bi-phase encoding scheme to modulate data bits onto the power signal. A logic ONE bit is encoded (c) 2016 Integrated Device Technology, Inc 12 May 17, 2016 P9235A-R Datasheet using two narrow transitions. A logic ZERO bit is encoded using two wider transitions as shown in Figure 9. Figure 9. Bit encoding scheme. t CLK ONE ZERO ONE ONE ZERO ONE ZERO ZERO Each byte in the communication packet comprises 11 bits in an asynchronous serial format. The start bit is always LO. This is followed by 8 bits of data. The final two bits are parity and stop, as shown in Figure 10. Figure 10. Byte encoding scheme. Start b0 b1 b2 b3 b4 b5 b6 b7 Parity Stop The wireless power receiver communicates with the wireless power transmitter via communication packets. Each communication packet has the following structure: Figure 11. Communication packet structure Preamble Header Message Checksum LED Pattern Selection A green LED and a red LED indicate status. The LED Patterns depend on the selected LED mode. The voltage applied through resistor divider to the LED_PAT pin selects the desired LED mode. Table 8 shows the available selections. Note that the LED pin selection is combined with the input current sense resistor. Pulling the LED_PAT pin to GND via a 47 k resistor will set the LED pattern to the default Mode 1. (c) 2016 Integrated Device Technology, Inc 13 May 17, 2016 P9235A-R Datasheet Table 8. LEDs indication table pattern Current Sense Resistor Option Number Voltage on LED_PA T pin[V] Resistor Divider Values (Input voltage: LDO18) RTOP RBOTTOM [R27] [R31] 20 m 1 Pull down <0.037 V NP 47 k,1% 20 m 2 0.11 V 715 k,1% 47 k,1% 20 m 3 0.18 V 422 k,1% 47 k,1% 20 m 4 0.26 V 280 k,1% 47 k,1% 20 m 5 0.33 V 210 k,1% 47 k,1% 20 m 6 0.41 V 160 k,1% 47 k,1% 50 m 7 0.63 V 86.6 k,1% 47 k,1% 50 m 8 0.71 V 71.5 k,1% 47 k,1% 50 m 9 0.78 V 61. k,1% 47 k,1% 50 m 10 0.86 V 51.1 k,1% 47 k,1% 50 m 11 0.93 V 44.2 k,1% 47 k,1% 50 m 12 1.01 V 36.5 k,1% 47 k,1% Operational Status LED #/Color Standby Transfer Complete Fault LED1-Green Off On Off LED2-Red Off Off Off LED1-Green On Off Off LED2-Red On Off Off LED1-Green LED2-Red Off - Blink 1 Hz - On - LED1-Green Off On Off LED2-Red LED1-Green On Blink 1Hz On LED2-Red On Off Off LED1-Green Off Off On LED2-Red Off On Off LED1-Green Off On Off LED2-Red Off Off Off LED1-Green On Off Off LED2-Red On Off Off LED1-Green Off Blink 1 Hz On LED2-Red - - - LED1-Green Off On Off LED2-Red LED1-Green On Blink 1Hz On LED2-Red On Off Off LED1-Green Off Off On LED2-Red Off On Off Off Blink 4 Hz Off Blink 4 Hz Blink 4Hz Blink 4 Hz Off Blink 4 Hz Off Blink 4 Hz Off Blink 4 Hz Off Blink 4 Hz Blink 4 Hz Blink 4 Hz Off Blink 4 Hz Off Blink 4 Hz Input Over Current Protection Input over current protection protects the transmitter half-bridge and receiver from exposure to conditions that may cause damage or unexpected behavior from the system. While the P9235A-R is in the power transfer stage, it monitors the input current, through the voltage across the input current sense resistor. If the input current goes above the programmed threshold, the P9235A-R will shut down for 5 minutes, and then re-try through digital pings. If the receiver condition remains the same for 5 more minutes, the P9235A-R will continue the periodic analog pings only (no digital pings). If the receiver is removed, or the input power is cycled, the P9235A-R will restart digital pings immediately. The ILIM pin voltage selects the input current limit through a voltage divider connected to LDO18. Table 9 shows options for 1, 2, and 3W systems, given minimum expected efficiencies. The default value input current limit is 1.25A. The default value occurs when ILIM pin is connected to GND via a 47 k resistor. (c) 2016 Integrated Device Technology, Inc 14 May 17, 2016 P9235A-R Datasheet Table 9. ILIM programmable thresholds Resistor Divider Values (Input voltage: LDO18) RTOP RBOTTOM [R26] [R30] 130 k,1% 47 k,1% Max Power Vout /Max Iout 1W 5 V/200 mA 0.75 A 0.48 V 2W 5 V/400 mA 1.25 A 0.78 V NP 47 k,1% 3W 5 V/600 mA 2.0 A 1.23 V 22 k,1% 47 k,1% Input current Limit threshold Voltage on ILIM pin Remote Temperature Sensing and Over Temperature Protection The P9235A-R uses a NTC thermistor connected to the TS pin to monitor the remote temperature during the power transfer phase. Connect the NTC thermistor to a voltage divider as shown in Figure 15. If the voltage on the TS pin decreases below 0.6 V, the transmitter shuts off the power, and will resume the wireless power transfer once the TS pin voltage rises above 0.8 V. Figure 12. NTC connection LDO33 RBIAS TS RTHM VTS = LDO33 x R THM,TRIP = 600mV (R THM,TRIP + R BIAS ) Where: VTS (V) = Trip voltage at the desired trip temperature RTHM,TRIP (k) = Resistance of the thermistor at the desired trip temperature Given LDO33 = 3.3V and RBIAS=10k, then RTHM,TRIP = 2.22 k at the trip temperature The basic characteristic of an NTC thermistor is: 1 1 R R 0exp B T T0 Where: T (Kelvin) = The trip temperature. R0 (k) = The known resistance at calibration temperature T0 (Kelvin). B (beta, Kelvin) = The material constant . With RBIAS=10k, RTHM =2.2k, and VTS=600mV at a trip temperature T, the desired R0 and B can be calculated, and the appropriate thermistor chosen. (c) 2016 Integrated Device Technology, Inc 15 May 17, 2016 P9235A-R Datasheet Buzzer Function The BUZ pin is able to drive a piezoelectric type transducer without amplification. As shown on the reference schematic, a series current limiting resistor (R20) must be included if a buzzer is used. The buzzer signal is a 2 kHz square wave. It is recommended to use a buzzer with a 2 kHz resonant frequency for best results. End of Power Transfer Response The P9235A-R will shut down and stop the power transfer once it receives an End of Power Transfer (EPT) packet. The P9235A-R will behave differently based on the reason for the EPT request. Table 10 shows the different EPT behaviors. Table 10. End of Power Transfer Response EPT Reason P9235A-R Behavior End of Power Transfer: Over-Current The P9235A-R will shut down the system, keeping the analog ping and digital ping. If the over-current condition is not removed, the system will enter into a hiccup mode. In hiccup mode the following sequence is repeated while the over current condition exists: the system starts up and applies the receiver voltage to the load, the receiver detects an over current condition and reports it to the transmitter, the transmitter shuts down. End of Power Transfer: Over-Temperature The P9235A-R will shut down the system, keeping the analog ping but muting the digital ping for 5 minutes. If the P9027LP-R is removed within 5 minutes, the P9235A-R will restart the digital ping. After 5 minutes, the P9235A-R will send out one digital ping to check if the fault condition has been removed. End of Power Transfer: Charge Complete. The P9235A-R will shut down the system, keeping the analog ping but muting the digital ping for 5 minutes. If the P9027LP-R is removed within 5 minutes, the P9235A-R will restart the digital ping. After 5 minutes, the P9235A-R will send out one digital ping to check if the battery needs to start charging again. End of Power Transfer: Internal Fault The P9235A-R will shut down the system, keeping the analog ping and digital ping. (c) 2016 Integrated Device Technology, Inc 16 May 17, 2016 P9235A-R Datasheet Transmitter Resonant Tank Capacitors For optimum performance, and to keep the characteristics of the resonant tank constant, the resonant frequency and quality factor must not change due to variations in the associated capacitors or inductors. The capacitors of the resonant tank (C15, C17, C23, C25) must be COG/NPO type only. COG/NPO capacitors have no temperature variation, less voltage related de-rating, and better accuracy than other types of capacitors such at the X7R. Do not mix capacitor types when populating the resonant capacitors, use COG/NPO types only. All the resonant capacitors must be rated for 50V. See the Bill of Materials for the recommended values. Transmitter Resonant Tank Coils Each half-bridge output connects to a series-resonance LC tank. The inductor serves as the primary coil of a loosely-coupled transformer; the secondary is the receiver coil connected to the P9027LP-R. The transmitter coils are mounted on a ferrite base acting as a shield to concentrate the field on the top side of the coil and to reduce EMI. The coil assembly can be mounted next to the P9235A-R PCB or on the back of PCB. Either a ground plane or grounded metal shielding (preferably copper) can be added beneath the ferrite shield for added reduction in radiated electrical field emissions. The coil ground plane/shield must be connected to the ground plane by a single trace leading back independently to the board input power connector. For optimum performance, the following coils are recommended for use with the P9235A-R transmitter for 1, 2 and 3 W applications. The recommended coil vendors have been tested and verified to guarantee their performance. Table 11. Coils Recommended with receiver for 1, 2 and 3 W Applications Output Power 1W 2W 3W Vendor Part number Inductance DCR Dimension TDK WT151512-22F2-ID 6.49 uH 0.17 O15 mm SunLord SWA15T15H20C01B 6.30 uH 0.12 O15 mm TDK WT202012-15F2-ID 6.20 uH 0.10 O20 mm Wurth Electronics 760308101104 6.30 uH 0.11 O20 mm SunLord SWA20N20H20C01B 6.30 uH 0.15 O20 mm TDK WT303012-13F2-ID 6.30 uH 0.12 O30 mm Wurth Electronics 760308101103 6.50 uH 0.15 O30 mm SunLord SWA30N30H20C01B 6.25 uH 0.14 O30 mm PCB Layout Considerations Layout and PCB design have a significant influence on the system performance. The power dissipation capabilities of the P9235A-R surface mount packaged power management IC rely heavily on thermally conductive traces and pads to transfer heat away from the package. The regulator or full bridge inverter could show instability, as well as cause EMI problems, if the PCB layout is not designed properly. The following general guidelines will be helpful in designing a board layout for low noise and EMI, as well as, the lowest thermal resistance: 1. 2. 3. PC board traces with large cross-sectional areas remove more heat. For optimal results, use large-area PCB patterns with wide copper traces, placed on the component side of the PCB. In cases where maximum heat dissipation is required, use double-sided copper planes connected with multiple vias. Thermal vias provide a thermal path from the bridge FETs to inner and/or bottom layers of the PCB to remove the heat generated by device power dissipation. For more details, please refer to the application note AN936, "P9235A-R Layout Guidelines" for the layout details. (c) 2016 Integrated Device Technology, Inc 17 May 17, 2016 P9235A-R Datasheet Power Dissipation and Thermal Requirements The P9235A-R is offered in a QFN-40 package which has a maximum power dissipation capability of approximately 1.2W. The number of thermal vias between the package and the printed circuit board determines the maximum power dissipation. The maximum power dissipation of the package is limited by the die's specified maximum operating junction temperature, TJ(MAX), of 125C, the maximum ambient operating temperature, TA, of 85C,and the package thermal resistance, JA. The junction temperature rises when the heat generated by the device's power dissipation flows through the package thermal resistance. The QFN package offers a typical thermal resistance, junction to ambient (JA), of 28.5C/W when the PCB layout guideline and surrounding devices are optimized. The techniques as noted in the PCB layout section must be followed when designing the printed circuit board layout. Attention to the placement of the P9235A-R IC and bridge FET packages, in proximity to other heat-generating devices in a given application design, should also be considered. The ambient temperature around the power IC will also have an effect on the thermal limits of an application. The main factors influencing JA (in the order of decreasing influence) are PCB characteristics, die/package attach thermal pad size (QFN) and thermal vias, and final system hardware construction. Board designers should keep in mind that the package thermal metric JA is impacted by the characteristics of the PCB itself upon which the IC is mounted. Changing the design or configuration of the PCB changes the overall thermal resistivity and the board's heat-sinking efficiency. The use of integrated circuits in low-profile and fine-pitch surface-mount packages requires special attention to power dissipation. Many system-dependent issues such as thermal coupling, airflow, added heat sinks, convection surfaces, and the presence of other heatgenerating components affect the power-dissipation limits of a given component. In summary, the three basic approaches for enhancing thermal performance are: 1. 2. 3. Improve the power dissipation capability of the PCB design Improve the thermal coupling of the component to the PCB Introduce airflow into the system First, the maximum power dissipation for a given situation should be calculated: PD(MAX) = (TJ(MAX) - TA)/JA In which PD(MAX) = Maximum Power Dissipation JA = Package Thermal Resistance (C/W) TJ(MAX) = Maximum Device Junction Temperature (C) TA = Ambient Temperature (C) The maximum recommended operating junction temperature (TJ(MAX)) for the P9235A-R device is 120C. The thermal resistance of the 40-pin QFN package is optimally JA=28.5C/W. Operation is specified to a maximum steady-state ambient temperature (TA) of 85C. Therefore, the maximum recommended power dissipation is: PD(Max) = (120C - 85C) / 28.5C/W 1.2 Watt. Thermal Protection To allow the maximum load current, and to prevent thermal overload, he heat generated by the P9235A-R solution must be dissipated into the PCB. All the available pins must be soldered to the PCB. GND pins (exposed paddle, EP) and bridge FET GND pins should be soldered to the PCB ground plane to improve thermal performance, with multiple vias connected to all layers of the PCB. Special Notes NDG QFN-40 Package Assembly Note 1: Unopened Dry Packaged Parts have a one-year shelf life. Note 2: The HIC indicator card for newly-opened Dry Packaged Parts should be checked. If there is any moisture content, the parts must be baked for a minimum of 8 hours at 125C within 24 hours prior to the assembly reflow process. (c) 2016 Integrated Device Technology, Inc 18 May 17, 2016 LDO33 BUZ LDO33 OPTIONAL FEATURS VCC J1 10k R20 RSVD2 D3 GREEN LED R23 R22 RED ILIM 680 1K THERMISTOR 2 t 0.1uF RT1 LDO33 LED_GRN LED_PAT LDO18 Solder_Jumper 0.1uF C20 C29 1uF C28 LDO18 Q1 VIN_USB 1uF 0.1uF C27 LDO33 GND_TS LED_RED 10uF C34 C19 0.1uF VIN_5V INRUSH CURRENT LIMIT C18 C13 0.1uF BUZ_TP D2 LED 100 R21 5 4 3 2 1 TS1 usb_micro_ab ZX62D-AB-5P8 SLD D+ D- R8 ISNS_IN ENB TS GND GND1 LDO18 A4 BUZ_TP B2 B3 LDO18 A4 BUZ B2 B3 GND3 GND2 VSNS_IN LDO33 LDO33 SDA RSVD1 RSVD2 VDDIO VO_33 VO_18 VIN_LDO GND_B VIN SW_B GND_S VO_5 ENB SCL VIN_USB 10 11 12 7 9 8 6 4 5 2 3 ENB 1 RSVD1 RSVD2 LDO33 4.7uH 1uF C14 U1 VIN_5V C21 10uF L1 1k ISNS_H ISNS_L C4 220pF VIN_5V VIN_USB TESTING POINTS VIN_LDO 1uF/10V C7 R7 100K ID FDC654P/SOT23-6 SS1 40 39 ISNS_H ISNS_L 6.8nF C6 1k C3 220pF P9235A-R R2 VSNS_IN 36 35 GND TS ENB ISNS_IN VSNS_IN SCL SDA EPGND GND_BRG GL_BRG2 BST_BRG2 SW_BRG2 GH_BRG2 GL_BRG1 BST_BRG1 SW_BRG1 GH_BRG1 R1 41 28 R16 27 12 C26 R14 R9 12 R12 12 100nF 12 220k R3 VSNS V_BRIDGE C5 5.6nF C16 100nF 0.1uF 25 26 24 29 31 30 10k VIN_LDO C9 10uF/10V C8 32 22nF C1 NP R15 NP R10 NP C36 NP C35 R6 10 R4 C2 C12 3 6 0.1uF 10uF/10V C11 C30 V_BRIDGE 10uF 10uF/10V C10 V_BRIDGE VIN_5V ISNS_H R13 100k ISNS_IN 38 37 ISNS_OUT ISNS_IN 13 14 15 16 17 18 19 SCL SDA ILIM LED_PAT GPIOA4 TS BUZ 33 VIN_DRV 34 VBRG_IN SCL SDA ILIM LED_PAT A4 TS BUZ 0.1uF 3 6 C31 0.02 1uF 1 2 SLD R19 100k VSNS_IN VSNS_GND LED_RED LED_GRN GPIOB2 GPIOB3 20 21 22 23 LED_RED LED_GRN B2 B3 C22 NP 11 10 8 RSVD1 NP 47k NP 47k C32 9 7 6 R25 R29 NP 47k R24 R28 R27 TS R26 R30 NP 47k 19 R31 5 4 C33 22nF/25V AON7810 Q3 5 4 ISNS_L AON7810 Q2 10 R5 1 2 (c) 2016 Integrated Device Technology, Inc NP P9235 A-R Low Power Mass Market Schematics V1P9 0 R18 C24 22nF/25V R11 0 L2_1 VSNS Monday , March 14, 2016 Docum ent Num ber IDTP9235A-R LP MM EV V1P9 R17 5.1k D1 CMOD3003 Sheet 1 Table 12. P9235A-R Schematic Dat e: C L2_2 100nF/50V 100nF/50V 100nF/50V 100nF/50V of 1 Rev Detailed System Diagram Size Tit e l C25 C23 C17 C15 1_0 P9235A-R Datasheet May 17, 2016 P9235A-R Datasheet Components Selection Table 13. Component List Item Reference Description PCB Footprint MFG Part Number 1 Qty 3 C1,C24,C33 22 nF/50 V 0402 C0402C223K5RACTU 2 1 C2 1 uF/10 V 0402 C0402C105M8PACTU 3 2 C3,C4 220 pF/50 V 0402 CL05B221KB5NNNC 4 1 C5 5.6 nF/50 V 0402 CL05B562KB5NNNC 5 1 C6 6.8 nF/50 V 0402 CL05B682JB5NNNC 6 5 C9,C12,C13,C18,C31 0.1 uF/25 V 0402 TMK105BJ104KV-F 7 1 C8 10 uF/10 V 0402 CL05A106MP5NUNC 8 5 C10,C11,C19,C21,C30 10 uF/25 V 0603 CL10A106MA8NRNC 9 4 C7,C14,C27,C29 1 uF/10 V 0402 CL05A105KP5NNNC 10 11 12 13 14 4 2 3 4 1 C15,C17,C23,C25 C16,C26 C20,C34,C28 C22,C32,C35,C36 D1 100 nF/50 V 100 nF 0.1 uF/10 V NP DIODE 1206 0402 0402 0402 SOD523PD C3216C0G1H104J160AA C1005X6S1V104K050BB C0402C104K8RACTU 15 1 D2 Red LED 0603 150 060 RS7 500 0 16 1 D3 Green LED 060 150 060 GS7 500 0 17 1 J1 5P usb_micro_ab 10104111-0001LF 18 1 L1 4.7 uH 0603 CIG10W4R7MNC 19 1 L2 Transmitter coil 20 1 Q1 80 mOhm/4.5 V 21 2 Q2,Q3 N-Channel MOSFETs 22 1 R1 23 3 24 CMOD3003 7650308101104 FDC654P 10 K/%1 SOT23-6 DFN 3 mm X 3 mm 402 R2,R8,R22 1k 0402 RC0402FR-071KL 1 R3 220 k 0402 RC0402FR-07220KL 25 2 R4,R5 10 0402 RT0402DRE0710RL 26 1 R6 0.02 0603 WSL0805R0200FEA 27 3 R7,R13,R19 100 k 0402 ERJ-2GEJ104X 28 4 12 0402 ERJ-2GEJ120X 29 6 NP 0402 30 2 R9,R12,R14,R16 R10,R15,R24.R25,R26,R2 7 R11,R18 0 OHMS RESISTOR 0402 RC0402JR-070RL 31 1 R17 5.1 k 0402 MCR01MRTJ512 32 1 R20 10 k 0402 CRCW040210K0JNED 33 1 R21 100 0402 RC0402JR-07100RL 34 1 R23 680 0402 RC0402JR-07680RL 35 4 R28,R29,R30,R31 47 k 0402 ERJ-2GEJ473X 36 1 RT1 THERMISTOR 0603 ERT-J1VG103FA 37 1 U1 IDTP9235 QFN_5 x 5 mm P9235A-R (c) 2016 Integrated Device Technology, Inc 20 AON7810 RCG040210K0FKED May 17, 2016 P9235A-R Datasheet Package Drawing Figure 13. QFN-40 NDG40 Package Outline Drawing (c) 2016 Integrated Device Technology, Inc 21 May 17, 2016 P9235A-R Datasheet Landing Pattern Drawing Figure 14. QFN-40 NDG40 Landing Pattern Drawing (c) 2016 Integrated Device Technology, Inc 22 May 17, 2016 P9235A-R Datasheet Ordering Information Orderable Part Number Package MSL Rating Shipping Packaging Temperature P9235A-RNDGI NDG40 - QFN-40 5x5x0.40 3 Tray -40 to +85C P9235A-RNDGI8 NDG40 - QFN-40 5x5x0.40 3 Tape and Reel -40 to +85C Marking Diagram 1. 2. 3. "IDT" Company code, "P9235A-R" Part number. "NDG" Package type: QFN, "I" Industrial "#" Device stepping, "YY" Last 2 digits of the year, "WW" Work week that the part was assembled, "$" Assembly location code Revision History [Insert the revision history entries in reverse chronological order.] Revision Date Description of Change May 16, 2016 Final May 2, 2016 This is the first preliminary release of this datasheet.. Corporate Headquarters Sales Tech Support 6024 Silver Creek Valley Road San Jose, CA 95138 www.IDT.com 1-800-345-7015 or 408-284-8200 Fax: 408-284-2775 www.IDT.com/go/sales www.IDT.com/go/support DISCLAIMER Integrated Device Technology, Inc. (IDT) reserves the right to modify the products and/or specifications described herein at any time, without notice, at IDT's sole discretion. Performance specificat ions and operating parameters of the described products are determined in an independent state and are not guaranteed to perform th e same way when installed in customer products. The information contained herein is provided without representation or warranty of any kind, whether express or implied, including, but not limited to, the suitability of IDT's products for any particular purpose, an implied warranty of merchantability, or non-infringement of the intellectual property rights of others. This document is presented only as a guide and does not convey any license under intellectual property rights of IDT or any third parties. IDT's products are not intended for use in applications involving extreme environmental conditions or in life support systems or similar devices where the failure or malfunction of an IDT product can be reasonably expected to significantly affect the health or safety of users. Anyone using an IDT product in such a manner does so at their own risk, absent an express, written agreeme nt by IDT. Integrated Device Technology, IDT and the IDT logo are trademarks or registered trademarks of IDT and its subsidiaries in the United States and other countries. Other trademarks used herein are the property of IDT or their respective third party owners. For datasheet type definitions and a glossary of common terms, visit www.idt.com/go/glossary. (c) Copyright 2016 Integrated Device Technology, Inc. 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