AW36518FCR

AW36518 Oct. 2018 V1.0 High Efficiency, Independent 1.5A Flash LED Driver Features General Description  1.5A Accurate and Programmable LED Current Source  Flash：2.94mA~1.5A，256 levels 5.88mA/level  Torch： 0.75mA~386mA，256 levels 1.51mA/level  Flash Timeout：40ms~1.6s，16 levels  Flash/Torch/IR Mode The AW36518 is a LED flash driver that provides a high level of adjustability within a small solution size. The AW36518 utilizes a 2MHz or 4MHz fixed-frequency synchronous boost converter to provide power to the 1.5A constant current LED sources. The 256 levels current sources provide the flexibility to adjust the current of LED in Flash/Torch/IR modes. The AW36518 provides IVFM protection to prevent system reset or shutdown under low battery condition.  Up to 85% Flash Efficiency  Optimized Flash LED Current During Low Battery Conditions (IVFM) The AW36518 are controlled via an I2C compatible interface. The main features of the AW36518 include: flash/torch current, flash timeout duration, IVFM and TX interrupt. The AW36518 also provides hardware flash/torch pin (STROBE/TORCH) to control Flash/Torch events.  Hardware Flash/Torch Enable (STROBE/TORCH)  Synchronization Input for RF Power Amplifier Pulse Events (TX)  400kHz I2C：AW36518 (I2C Address=0x63)  0.4mm Pitch，FCQFN-10L Package Compatible with AW3648 The 2MHz or 4MHz switching frequency options, overvoltage protection (OVP), and adjustable current limit allow for the use of tiny, low-profile inductors and 10-µF ceramic capacitors. The device operates over a –40°C to +85°C ambient temperature range. Application Smartphone Camera Flash The AW36518 is available in small 0.4mm pitch FCQFN 1.6mm×1.2mm -10L package. Typical Application Circuit L 1μH 3A VIN CIN 10μF IN SW OUT COUT 10μF AW36518FCR STROBE/TORCH TX SDA SCL MCU LED Flash LED D GND Typical Application Circuit of AW36518 All trademarks are the property of their respective owners. www.awinic.com.cn 1 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Pin Configuration And Top Mark AW36518FCR Pin Configuration (Top View) A GND B SW SCL C OUT STROBE/ TORCH D LED TX LED 1 2 3 IN AW36518FCR Top Mark (Top View) SDA LGW6 XXX LGW6 – AW36518FCR XXX – Production Tracing Code Pin Configuration and Top Mark Pin Definition No. NAME TYPE A1 GND Ground Ground A2 IN Power Input voltage connection. Connect IN to GND with a 10µF or larger ceramic capacitor. A3 SDA I/O Serial data input/output of the I2C interface. B1 SW Power Switch pin of the step-up DC-DC convertor. B3 SCL I/O C1 OUT Power Step-up DC-DC converter output. Connect a 10µF ceramic capacitor between OUT and GND. C3 STROBE/TORCH I/O Active high hardware flash/torch/IR enable. Drive STROBE/TORCH high to turn on Flash/Torch/IR pulse. Internal pull down resistor of 300kΩ between STROBE/TORCH and GND. D1 LED Power High-side current source output for flash LED, connect pin D1 to D3 externally D2 TX I/O Power amplifier synchronization input. Internal pull down resistor of 300kΩ between TX and GND. D3 LED Power High-side current source output for flash LED, connect pin D1 to D3 externally. www.awinic.com.cn DESCRIPTION Serial clock input of the I2C interface. 2 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Ordering Information Part Number Temperature Package Marking Moisture Sensitivity Level Environmental Information Delivery Form AW36518FCR -40°C~85°C FCQFN 1.6mmX1.2mm -10L LGW6 MSL1 ROHS+HF 3000 units/ Tape and Reel AWINIC Flash LED Driver Series Product Channels Type Description Package AW36515 2 Boost High Efficiency, Dual Independent 2A Flash LED Driver FCQFN-10L AW3644 2 Boost High Efficiency, Dual Independent 1.5A Flash LED Driver CSP-12B AW3643 2 Boost High Efficiency, Dual 1.5A Flash LED Driver CSP-12B AW36413 2 Boost High Efficiency, Dual 1.5A Flash LED Driver CSP-12B AW3648 1 Boost High Efficiency, 1.5A Flash LED Driver CSP-12B AW3642 1 Boost High Efficiency, 1.5A Flash LED Driver CSP-9B AW3641E 1 Charge Pump Flash Current & Flash Timer Programmable 1A Flash LED Driver DFN-10L AW36402 1 Current Sink 200mA 1-wire Configurable Front Flash LED Driver with Ultra Small Package DFN-6L AW36404 1 Current Sink 400mA 1-wire Configurable Front Flash LED Driver with Ultra Small Package DFN-8L AW36406 1 Current Sink 600mA PWM Configurable Front Flash LED Driver with Ultra Small Package DFN-8L www.awinic.com.cn 3 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Typical Application Circuits L 1μH 3A VIN CIN 10μF IN SW OUT COUT 10μF AW36518FCR STROBE/TORCH TX SDA SCL MCU LED Flash LED D GND AW36518 Application Circuit Notice for Typical Application Circuits: 1: Please place CIN，COUT as close to the chip as possible. 2: Connect the inductor on the top layer close to the SW pin. 3: For the sake of driving capability, the power lines, output lines, and the connection lines of L and LED should be short and wide as possible. 4: Traces carry high current are marked in red in the above figure. www.awinic.com.cn 4 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Absolute Maximum Ratings(NOTE1) PARAMETERS Range Unit -0.3 to 6 V SCL, SDA, STROBE/TORCH, TX −0.3 to (VIN+0.3) V Continuous power dissipation Internally limited IN, SW, OUT, LED Max Junction Temperature TJMAX 155 °C -65 to 150 °C Maximum lead temperature (soldering) 260 °C Junction to Ambient Thermal Resistance θJA 90.2 °C /W HBM ±2000 V CDM ±1500 V Storage Temperature TSTG ESD, All Pins(NOTE2) +IT：+200 Latch-Up (Test method: JEDEC STANDARD NO.78D) -IT： -200 mA Recommended Operating Conditions PARAMETERS Range Unit VIN 2.7 to 5.5 V Junction temperature (TJ) -40 to 125 °C Ambient temperature (TA) -40 to 85 °C NOTE1: Conditions out of those ranges listed in "absolute maximum ratings" may cause permanent damages to the device. In spite of the limits above, functional operation conditions of the device should within the ranges listed in "recommended operating conditions". Exposure to absolute-maximum-rated conditions for prolonged periods may affect device reliability. NOTE2: The human body model is a 100pF capacitor discharged through a 1.5kΩ resistor into each pin. Test method: ANSI/ESDA/JEDEC JS-001. CDM test method: JEDEC22-C101E. www.awinic.com.cn 5 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Electrical Characteristics Typical values tested at TA=25°C. Minimum and maximum limits apply over the full operating ambient temperature range(-40°C≤TA≤85°C). Unless otherwise specified, VIN=3.6V. Symbol Description Test Condition Min Typ Max Unit 5.5 V 0.4 0.8 mA 3 10 A Vin Supply VIN Input operating range 2.7 IQ Quiescent supply current Device not switching, pass mode ISB Standby supply current Device disabled, 2.7V≤VIN≤5.5V,SCL=SDA=0V UVLO Under voltage lockout threshold Falling VIN 2.5 V Rising VIN 2.6 V Current Source Specifications ILED1/2 VOVP VOUT=4V, flash code=0xFF=1.5A -7% 1.5 7% A VOUT=4V, torch code=0x7F=192.7mA -10% 192.7 10% mA ON threshold 4.85 5 5.15 OFF threshold 4.75 4.9 5.05 Current source accuracy VOUT over-voltage protect threshold V Boost Converter Specifications RPMOS PMOS switch on-resistance 90 mΩ RNMOS NMOS switch on-resistance 70 mΩ ICL Switch current limit FSW VIVFM Reg 0x07, bit[0]=0 -12% 1.9 12% Reg 0x07, bit[0]=1 -12% 2.8 12% Reg 0x07, bit[1]=0 -6% 2 6% Reg 0x07, bit[1]=1 -6% 4 6% Reg 0x02, bits[5:3]=”000” -3% 2.9 3% A Switching frequency Input voltage flash monitor trip threshold MHz Thermal shutdown threshold 155 Thermal shutdown hysteresis 20 TSD V °C www.awinic.com.cn 6 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Electrical Characteristics(continued) Typical values tested at TA=25°C. Minimum and maximum limits apply over the full operating ambient temperature range(-40°C≤TA≤85°C). Unless otherwise specified, VIN=3.6V. Symbol Description Test Condition Min Typ Max Unit I2C-Compatible Interface Specifications(SCL,SDA) VIL Input logic low 0 0.4 V VIH Input logic high 1.2 VIN V VOL Output logic low 0.4 V ILOAD=3mA STROBE/TORCH, TX Voltage Specifications VIL Input logic low 0 0.4 V VIH Input logic high 1.2 VIN V RPD Internal pull down resistors www.awinic.com.cn 300 7 kΩ Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 I2C Interface Timing Symbol Min Description FSCL Interface Clock frequency TDEGLITCH Deglitch time Typ Max Units 400 kHz SCL 200 ns SDA 250 ns THD:STA (Repeat-start) Start condition hold time 0.6 s TLOW Low level width of SCL 1.3 s THIGH High level width of SCL 0.6 s TSU:STA (Repeat-start) Start condition setup time 0.6 s THD:DAT Data hold time 0 s TSU:DAT Data setup time 0.1 s TR Rising time of SDA and SCL 0.3 s TF Falling time of SDA and SCL 0.3 s TSU:STO Stop condition setup time 0.6 s TBUF Time between start and stop condition 1.3 s VIH SDA VIL tBUF tLOW tHIGH tR tSP tF VIH SCL VIL Stop Start tHD:STA tHD:DAT tSU:DAT tSU:STA Start tSU:STO Stop I2C INTERFACE TIMING www.awinic.com.cn 8 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Typical Characteristics Ambient temperature is 25°C, input voltage is 3.6 V, CIN = COUT = 2×10 µF and L=1 µH, unless otherwise noted . 1.6 0.4 1.4 0.36 0.32 1.2 0.28 ILED1 (A) ILED (A) 1 0.8 0.6 0.2 0.16 0.12 0.4 0.08 0.2 0.04 0 0 0 32 64 96 128 160 192 224 256 0 96 128 160 192 224 LED Flash Current vs Brightness Code LED Torch Current vs Brightness Code 1.60 1.58 1.58 1.56 1.56 1.54 1.54 1.52 1.52 1.50 1.48 1.48 1.46 1.44 1.44 1.42 1.42 3 3.5 4 4.5 VIN (V) fSW=2MHz ILED=1.5A 5 256 1.50 1.46 1.40 1.40 5.5 2.5 Flash 3 3.5 4 4.5 VIN (V) fSW=4MHz ILED=1.5A LED Flash Current vs Input Voltage 5 5.5 Flash LED Flash Current vs Input Voltage 1.10 1.10 1.08 1.08 1.06 1.06 1.04 1.04 1.02 1.02 ILED (A) ILED (A) 64 LED Torch Code (dec#) 1.60 2.5 32 LED Flash Code (dec#) ILED (A) ILED (A) 0.24 1.00 0.98 1.00 0.98 0.96 0.96 0.94 0.94 0.92 0.92 0.90 0.90 2.5 3 ILED=1.0A 3.5 4 VIN (V) fSW=2MHz 4.5 5 Flash LED Flash Current vs Input Voltage www.awinic.com.cn 9 5.5 2.5 3 ILED=1.0A 3.5 4 VIN (V) fSW=4MHz 4.5 5 5.5 Flash LED Flash Current vs Input Voltage Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Typical Characteristics (continued) Ambient temperature is 25°C, input voltage is 3.6 V, CIN = COUT = 2×10 µF and L=1 µH, unless otherwise noted . 0.87 0.60 0.85 0.58 0.83 0.56 0.54 0.79 ILED (A) ILED (A) 0.81 0.77 0.75 0.52 0.50 0.48 0.73 0.71 0.46 0.69 0.44 0.67 0.42 2.5 3 3.5 4 4.5 VIN (V) fSW=2MHz ILED=0.749A 5 5.5 2.5 Flash 0.43 0.42 0.42 0.41 0.41 0.4 ILED (A) ILED (A) 0.44 0.43 0.39 0.38 0.36 0.35 0.35 0.34 ILED=0.386A VIN(V) fsw=2MHz 5 2.5 Torch 0.22 0.21 0.21 0.2 ILED (A) ILED (A) 0.22 0.19 0.18 0.16 0.15 ILED=0.192A VIN(V) fsw=2MHz Torch www.awinic.com.cn 5.5 10 5.5 Torch 0.15 2.5 3 3.5 ILED=0.192A LED1/2 Torch Current vs Input Voltage 5 0.18 0.16 5 4.5 0.2 0.17 4.5 4 VIN(V) fsw=4MHz 0.19 0.17 4 3.5 LED1/2 Torch Current vs Input Voltage 0.23 3.5 3 ILED=0.386A 0.23 3 Flash 0.34 5.5 LED1/2 Torch Current vs Input Voltage 2.5 5.5 0.38 0.37 4.5 5 0.4 0.36 4 4.5 0.39 0.37 3.5 4 VIN (V) fSW=2MHz LED Flash Current vs Input Voltage 0.44 3 3.5 ILED=0.502A LED Flash Current vs Input Voltage 2.5 3 4 4.5 VIN(V) fsw=4MHz 5 5.5 Torch LED1/2 Torch Current vs Input Voltage Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Typical Characteristics (continued) Ambient temperature is 25°C, input voltage is 3.6 V, CIN = COUT = 2×10 µF and L=1 µH, unless otherwise noted . 100 95 VLED=3.5V 90 VLED=3.8V 95 VLED=3.1V 90 VLED=4.1V 85 85 VLED=4.4V 80 ηLED (%) ηLED (%) 100 VLED=3.3V 75 70 80 75 70 65 65 60 60 55 55 50 2.5 3.0 3.5 ILED=1.5A 4.0 4.5 5.0 VIN (V) fSW=2Mhz Flash 50 5.5 2.5 ILED=1.5A 100 100 95 95 90 90 85 85 80 80 75 70 65 60 55 55 50 ILED=1.0A 4.0 4.5 VIN (V) VLED=3.2V fSW=2MHz 5.0 2.5 Flash 95 90 90 85 85 80 80 ηLED (%) ηLED (%) 100 75 70 65 60 55 55 50 ILED=0.386A 5.0 VIN (V) VLED=2.9V fSW=2MHz 5.5 Torch LED Efficiency vs Input Voltage www.awinic.com.cn 3.5 4.0 4.5 VIN (V) VLED=3.2V fSW=4MHz 5.0 5.5 Flash 70 60 4.5 Flash 75 65 4.0 5.5 LED Efficiency vs Input Voltage 95 3.5 3.0 ILED=1.0A 100 3.0 5.0 50 5.5 LED Efficiency vs Input Voltage 2.5 4.5 70 60 3.5 4.0 VIN (V) VLED=3.5V fSW=2Mhz 75 65 3.0 3.5 LED Efficiency vs Input Voltage ηLED (%) ηLED (%) LED Efficiency vs Input Voltage 2.5 3.0 11 50 2.5 3.0 ILED=0.192A 3.5 4.0 4.5 5.0 VIN (V) VLED=2.75V fSW=2MHz 5.5 Torch LED Efficiency vs Input Voltage Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Typical Characteristics (continued) 2.150 4.300 2.125 4.250 2.100 4.200 2.075 4.150 2.050 4.100 fSW (Mhz) fSW (Mhz) Ambient temperature is 25°C, input voltage is 3.6 V, CIN = COUT = 2×10 µF and L=1 µH, unless otherwise noted . 2.025 2.000 4.000 1.975 3.950 1.950 3.900 1.925 3.850 1.900 3.800 2.5 2.75 3 3.25 3.5 3.75 4 4.25 4.5 4.75 5 2.5 2.75 3 3.25 3.5 3.75 4 4.25 4.5 4.75 VIN (V) VIN (V) 2-MHz Frequency vs Input Voltage 4-MHz Frequency vs Input Voltage 3.0 7 2.5 6 5 5 ISTB (μA) 2.0 ISTB (μA) 4.050 1.5 1.0 4 3 2 0.5 1 0.0 2.5 3 3.5 4 4.5 5 0 5.5 2.5 3 3.5 4 4.5 5 VIN (V) I2C=0V VIN (V) I2C=1.8V Standby Current vs Input Voltage Standby Current vs Input Voltage 5 5.5 3.0 2.5 4 ISTB (μA) ISTB (μA) 2.0 3 2 1.5 1.0 1 0.5 0 0.0 2.5 3 3.5 4 4.5 5 5.5 2.5 3 3.5 4 4.5 5 VIN (V) I2C=3.3V VIN (V) I2C=VIN Standby Current vs Input Voltage Standby Current vs Input Voltage www.awinic.com.cn 12 5.5 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Typical Characteristics (continued) 2.20 2.16 2.12 2.08 2.04 2.00 1.96 1.92 1.88 1.84 1.80 1.76 1.72 1.68 1.64 1.60 ICL (A) ICL (A) Ambient temperature is 25°C, input voltage is 3.6 V, CIN = COUT = 2×10 µF and L=1 µH, unless otherwise noted . 2.5 2.7 2.9 3.1 3.3 3.5 VIN (V) fSW=2MHz ICL=1.9A ILED=1.5A 3.7 3.9 4.1 2.20 2.16 2.12 2.08 2.04 2.00 1.96 1.92 1.88 1.84 1.80 1.76 1.72 1.68 1.64 1.60 4.3 2.5 VLED=4.5V 2.9 3.1 3.3 3.5 VIN (V) fSW=4MHz ICL=1.9A ILED=1.5A Inductor Current Limit vs Input Voltage 3.7 3.9 4.1 4.3 VLED=4.5V Inductor Current Limit vs Input Voltage 3.0 3.0 2.8 2.8 2.6 2.6 2.4 2.4 ICL (A) ICL (A) 2.7 2.2 2.2 2.0 2.0 1.8 1.8 1.6 1.6 1.4 1.4 2.5 2.8 3.1 ILED=1.5A 3.4 3.7 VIN (V) fSW=2MHz ICL=2.8A 4 4.3 4.6 4.9 2.5 ILED(500mA/DIV) fSW=2MHz 4 4.3 4.6 4.9 VLED=4.5V IIN(1A/DIV) ILED(500mA/DIV) TIME (500 μs/DIV) VLED=3.4V Ramp Up www.awinic.com.cn 3.7 VIN (V) fSW=4MHz ICL=2.8A VOUT(2V/DIV) TIME (500 μs/DIV) ILED=1.5A 3.4 Inductor Current Limit vs Input Voltage Inductor Current Limit vs Input Voltage IIN(1A/DIV) 3.1 ILED=1.5A VLED=4.5V VOUT(2V/DIV) 2.8 ILED=1.5A fSW=2MHz VLED=3.4V Ramp Down 13 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Typical Characteristics (continued) Ambient temperature is 25°C, input voltage is 3.6 V, CIN = COUT = 2×10 µF and L=1 µH, unless otherwise noted . VIN (100mV/DIV) TX signal VOUT(2V/DIV) IIN (500mA/DIV) IIN(800mA/DIV) ILED (200mA/DIV) ILED(500mA/DIV) TIME (500 μs/DIV) TIME (2 ms/DIV) ILED=1.5A fSW=2MHz VLED=3.18V fSW=2MHz VLED=3.18V VIVFM=2.9V IVFM - Stop and Hold TX Interrupt www.awinic.com.cn ILED=1.5A 14 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Detailed Functional Description The AW36518 is a high-power LED flash driver capable of delivering up to 1.5A in either of the LED. The device incorporates a 2MHz or 4MHz constant frequency-synchronous current-mode PWM boost converter and dual high-side current sources to regulate the LED current over the 2.7V to 5.5V input voltage range. The AW36518 PWM DC-DC boost converter switches and boosts the output to maintain at least VHR across the current source. This minimum headroom voltage ensures that current source remains in regulation. If the input voltage is above the LED voltage + current source headroom voltage, the device would not switch, but turn the PMOS on continuously (Pass mode). In Pass mode the difference between (V IN − ILED × RPMOS) and the voltage across the LED is dropped across the current source. The AW36518 has two logic inputs including a reusable hardware Flash/Torch Enable (STROBE/TORCH) and a Flash Interrupt input (TX) designed to interrupt the flash pulse during high battery-current conditions. These logic inputs have internal 300kΩ (typical) pull-down resistors to GND. Control is done via an I2C-compatible interface. This includes adjustment of the Flash and Torch current levels, changing the Flash Timeout Duration, and changing the switch current limit. Additionally, there are flag and status bits that indicate flash current timeout, LED over-temperature condition, LED failure (open/short), device thermal shutdown, TX interrupt, and VIN under-voltage conditions. www.awinic.com.cn 15 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Functional Block Diagram SW AW36518 OVP IN Thermal Shutdown Protection UVLO POR VOVP IVFM OSC 2/4MHz OUT Boost Controller Current Limit LED STROBE/TORCH TX SDA SCL Control Logic /Regsiter 2 IC Interface LED & OUT Short Detect GND Features Description Power On Reset When the supply voltage VIN drops below a predefined voltage VPOR (2.0V typical), the device generates a reset signal to perform a power-on reset operation, which will reset all control circuits and configuration registers. Once VIN goes above around VPOR (2.0V typical), it should stay high for at least 2ms time before any I2C command can be accepted. Software Reset By setting bit[7](Software Reset Bit) to a ‘1’ in the Boost Configuration Register(0x07) via I 2C interface will reset the AW36518 internal circuit and all configuration registers, after the soft reset command is input through I2C, it needs to wait at least 2ms before any other I2C command can be accepted. Flash Mode In Flash Mode, the LED current source provides 256 target current levels from 2.94mA to 1.5A. The Flash currents are adjusted via the LED Flash Brightness Registers. Flash mode is activated by the Enable Register(setting M1, M0 to '11'), or by pulling the STROBE/TORCH pin HIGH when bit[5] (Strobe Enable Bit) is ‘1’ in the Enable Register(0x01). Once the Flash sequence is activated the current source ramps up to the programmed Flash current by stepping through all current steps until the programmed current is reached. When the device is enabled in Flash Mode through the Enable Register, all mode bits in the Enable Register are cleared after a flash timeout event. www.awinic.com.cn 16 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Torch Mode In Torch mode, the LED current source provides 256 target current levels from 0.75mA to 386mA on AW36518. The Torch currents are adjusted via the LED Torch Brightness Register. Torch mode is activated by the Enable Register (setting M1, M0 to '10'), or by pulling the STROBE/TORCH pin HIGH when bit[5] (Torch Enable Bit) is ‘1’ in the Enable Register(0x01). Once the TORCH sequence is activated the active current source ramps up to the programmed Torch current by stepping through all current steps until the programmed current is reached. The rate at which the current ramps is determined by the value chosen in the Timing Register. AW36518 will execute flash operation when both bit[4] and bit[5] are ‘1’ in the Enable Register with pulling the STROBE/TORCH pin HIGH. Torch Mode is not affected by Flash Timeout or by a TX Interrupt event. IR Mode In IR Mode, Enable register bit[3:2] should be to ‘01’ (setting M1, M0 to '01') and the STROBE/TORCH pin should be enabled(Strobe Enable Bit). The target LED current is equal to the value stored in the LED Flash Brightness Registers. When IR mode is enabled, the boost converter turns on and set the output equal to the input (pass-mode) . The STROBE/TORCH pin can only be set to be Level sensitive, meaning all timing of the IR pulse is externally controlled, but it is still protected by flash time-out if STROBE width is too long. In IR Mode, the current sources do not ramp the LED output to the target. LED is enabled to the full current setting without delay or slow ramp during STROBE rising edge, and they are fully turned off immediately without delay or slow ramp during STROBE falling edge BOOST VOUT PASS OFF STROBE ILED M1,M0=‘01’ STROBE EN=‘1’ M1,M0=‘00’ STROBE EN=‘1’ IR Mode with Boost VOUT STROBE ILED M1,M0=‘00’ STROBE EN=‘1’ M1,M0=‘01’ STROBE EN=‘1’ IR Mode Pass Only www.awinic.com.cn 17 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 VOUT STROBE Flash Timeout Value ILED M1,M0=‘01’ Timeout Start Timeout STROBE EN=‘1’ Reset Timeout Start Timeout Reset Timeout Start Timeout Reached VOUT goes low， LED turn off IR Mode Timeout Soft Start-up Turn on the AW36518 Torch and Flash modes can be done through the Enable Register. On start-up, when VOUT is less than VIN the internal synchronous PMOS turns on as a current source and delivers 200mA (typical) to the output capacitor. During this time the current source (LED) is off. When the voltage across the output capacitor reaches 2.2 V (typical) the current source turns on. At turn-on the current source steps through each FLASH or TORCH level until the target LED current is reached. This gives the device a controlled turn-on and limits inrush current from the VIN supply. Pass Mode The AW36518 starts up in Pass Mode and stays there until Boost Mode is needed to maintain regulation. In Pass Mode the boost converter does not switch, and the synchronous PMOS turns fully on bringing VOUT up to VIN − ILED × RPMOS. In Pass Mode the inductor current is not limited by the peak current limit. If the voltage difference between VOUT and VLED falls below VHR, the device switches to Boost Mode. By setting bit[2](BOOST MODE) to a ‘1’ in the Boost Configuration Register(0x07), the AW36518 will stay in the Pass Mode regardless of the effects of VHR. Power Amplifier Synchronization (TX) The TX pin is a Power Amplifier Synchronization input. This is designed to reduce the flash LED current and thus limit the battery current during high battery current conditions such as PA transmit events. When the AW36518 is engaged in a Flash event, and the TX pin is pulled high, the LED current is forced into Torch Mode at the programmed Torch current setting. If the TX pin is then pulled low before the Flash pulse terminates, the LED current returns to the previous Flash current level. At the end of the Flash time-out, whether the TX pin is high or low, the LED current turns off. The TX input can be disable by setting bit[7] (TX Enable) to a ‘0’ in the Enable Register(0x01). Input Voltage Flash Monitor (IVFM) The AW36518 has the ability to adjust the flash current based upon the voltage level present at the IN pin utilizing the Input Voltage Flash Monitor (IVFM). The adjustable threshold ranges from 2.9 V to 3.6 V in 100mV steps as well as adjustable hysteresis, with Stop-and-Hold mode. The IVFM threshold and hysteresis are controlled by bits[5:3] and bit[2] respectively, in the IVFM Register(0x02). The Flags2 Register has the IVFM flag bit set when the input voltage crosses the IVFM threshold value. Additionally, the IVFM threshold sets the input voltage boundary that forces the AW36518 to either stop ramping the flash current during startup in Stop and Hold Mode.  Stop and Hold Mode: Stops Current Ramp and holds the level for the remaining flash, If VIN falls below the IVFM threshold value. www.awinic.com.cn 18 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Flash Event VIN T-Filter=4μs IVFM-Threshold Stop & Hold Mode Target Flash Current Flash Current with IVFM Disable Flash Current IVFM Mode Flash Timeout The Flash Timeout period sets the maximum time of one flash event, whether a flash stop command is received or not. The AW36518 has 16 timeout levels ranging from 40ms to 1.6s (see TIMING CONFIGURATION REGISTER (0X08) for more detail). Flash Timeout applies to both Flash and IR modes, and it continues to count when the Flash mode is forced into Torch mode during a TX high event. The mode bits are cleared and bit[0] is set in the Flags1 register(0x0A) upon a Flash Timeout. This fault flag can be reset to '0' by reading back the Flags1 Register (0x0A), 'or by setting the SW RESET bit to a '1', or by removing power to the AW36518. Current Limit When the inductor current limit is reached, the AW36518 terminates the charging phase of the switching cycle until the next switching period. If the over-current condition persists, the device operates continuously in current limit. The AW36518 features two selectable inductor current limits(1.9A and 2.8A) that are programmable by bit[0] in Boost configuration Register(0x07). Since the current limit is sensed in the NMOS switch, there is no mechanism to limit the current when the device operates in Pass Mode (current does not flow through the NMOS in pass mode). The mode bits are not cleared upon a Current Limit event, but a flag bit[3] is set in the Flags1 register(0x0A). This fault flag can be reset to '0' by reading back the Flags1 Register (0x0A), or by setting the SW RESET bit to a '1', or by removing power to the AW36518. Undervoltage Lockout (UVLO) The AW36518 has an internal comparator that monitors the voltage at IN and forces the AW36518 into standby if the input voltage drops to 2.5 V. If the UVLO monitor threshold is tripped, the UVLO flag bit is set in the Flags1 Register (0x0A). If the input voltage rises above 2.5 V, the AW36518 is not available for operation until there is an I2C read of the Flags1 Register (0x0A). Upon a read, the Flags1 register is cleared, and normal operation can resume if the input voltage is greater than 2.5 V. VOUT Short Fault The Output Short Fault flag reads back a '1' if the device is active in Flash or Torch mode and the boost output experiences a short condition. VOUT short condition occurs if the voltage at OUT goes below 2.3V (typ.) while the device is in Torch or Flash mode. There is a deglitch time of 2.048ms before the VOUT Short flag is valid. The mode bits are cleared upon an the VOUT short fault. The AW36518 is not available for operation until VOUT Fault flags is cleared. The VOUT Short Fault can be reset to '0' by reading back the Flags1 Register (0x0A), or by setting the SW RESET bit to a '1', or by removing power to the AW36518. www.awinic.com.cn 19 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 LED Short Fault The LED Short Fault flags read back a '1' if the device is active in Flash or Torch mode and either active LED output experiences a short condition. An LED short condition is determined if the voltage at LED goes below 500mV (typ.) while the device is in Torch or Flash mode. There is a deglitch time of 256μs before the LED Short Fault flag is valid. The mode bits are cleared upon an LED Short Fault. The AW36518 is not available for operation until the LED Short Fault flags is cleared. The LED Short Faults can be reset to '0' by reading back the Flags1 Register (0x0A), or by setting the SW RESET bit to a '1', or by removing power to the AW36518. Overvoltage Protection (OVP) The output voltage is limited to typically 5 V. In situations such as an open LED, the AW36518 raises the output voltage in order to try and keep the LED current at its target value. When VOUT reaches 5 V (typ.) the overvoltage comparator trips and turns off the internal NMOS. When VOUT falls below the “VOVP Off Threshold”, the AW36518 begins switching again. The mode bits are cleared, and the OVP Fault flag is set, when an OVP condition is present for three rising OVP edges. This prevents momentary OVP events from forcing the device to shut down. The AW36518 is not available for operation until the OVP Fault flag is cleared. The OVP Fault can be reset to '0' by reading back the Flags2 Register (0x0A), or by setting the SW RESET bit to a '1', or by removing power to the AW36518. Thermal Shutdown (TSD) When the AW36518 die temperature reaches 155°C, the thermal shutdown detection circuit trips, forcing the AW36518 enter standby mode and writing a '1' to the Thermal Shutdown Fault flag of the Flags1 Register (0x0A) . The AW36518 is only allowed to restart after the Thermal Shutdown Fault flag is cleared. The Thermal Shutdown Faults can be reset to '0' by reading back the Flags1 Register (0x0A), or by setting the SW RESET bit to a '1', or by removing power to the AW36518. Upon restart, if the die temperature is still above 155°C, the AW36518 resets the Fault flag and re-enters standby mode. www.awinic.com.cn 20 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Programming Control Truth Table MODE1 MODE0 STROBE EN TORCH EN STROBE/TORCH PIN ACTION 0 0 0 0 X Standby 0 0 0 1 Pos edge Ext Torch 0 0 1 0 Pos edge Ext Flash 0 0 1 1 Pos edge Ext Flash 1 0 X X X Int Torch 1 1 X X X Int Flash 0 1 0 X X IRLED Standby 0 1 1 X 0 IRLED Standby 0 1 1 X Pos edge IRLED Enabled I2C Interface Data Validation When SCL is high level, SDA level must be constant. SDA can be changed only when SCL is low level. SDA SCL Data Line Stable Data Valid Change of Data Allowed Data Validation Diagram I2C Start/Stop I2C start: SDA changes from high level to low level when SCL is high level. I2C stop: SDA changes from low level to high level when SCL is high level. SDA SCL S/Sr P S: START condition Sr: START Repeated condition P: STOP condition Start and Stop Conditions www.awinic.com.cn 21 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 ACK (Acknowledgement) ACK means the successful transfer of I2C bus data. After master sends an 8-bit data, SDA must be released; SDA is pulled to GND by slave device when slave acknowledges. When master reads, slave device sends 8-bit data, releases the SDA and waits for ACK from master. If ACK is sent and I2C stop is not sent by master, slave device sends the next data. If ACK is not send by master, slave device stops to send data and waits for I2C stop. Data Output by Transmiter Not Acknowledge（NACK） Data Output by Receiver Acknowledge（ACK） 2 1 SCL From Master 8 9 Clock Pulse for Acknowledgement START condition I2C ACK Timing Write Cycle One data bit is transferred during each clock pulse. Data is sampled during the high state of the serial clock (SCL). Consequently, throughout the clock’s high period, the data should remain stable. Any changes on the SDA line during the high state of the SCL and in the middle of a transaction, aborts the current transaction. New data should be sent during the low SCL state. This protocol allows a single data line to transfer both command/control information and data using the synchronous serial clock. Each data transaction is composed of a Start Condition, a number of byte transfers (set by the software) and a Stop Condition to terminate the transaction. Every byte written to the SDA bus must be 8 bits long and is transferred with the most significant bit first. After each byte, an Acknowledge signal must follow. In a write process, the following steps should be followed: a) Master device generates START condition. The “START” signal is generated by lowering the SDA signal while the SCL signal is high. b) Master device sends slave address (7-bit) and the data direction bit (R/W = 0). c) Slave device sends acknowledge signal if the slave address is correct. d) Master sends control register address (8-bit) e) Slave sends acknowledge signal f) Master sends data byte to be written to the addressed register g) Slave sends acknowledge signal h) If master will send further data bytes the control register address will be incremented by one after acknowledge signal (repeat step f and g) i) Master generates STOP condition to indicate write cycle end SCL 0 1 2 3 4 5 6 7 8 0 1 2 3 4 5 6 7 8 0 1 2 3 4 5 6 7 8 A6 A5 A4 A3 A2 A1 A0 R/WAck A7 A6 A5 A4 A3 A2 A1 A0 Ack D7 D6 D5 D4 D3 D2 D1 D0 Ack SDA Start Device Address Register Address Write Data Stop I2C Write Timing www.awinic.com.cn 22 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Read Cycle In a read cycle, the following steps should be followed: a) Master device generates START condition. b) Master device sends slave address (7-bit) and the data direction bit (R/W = 0). c) Slave device sends acknowledge signal if the slave address is correct. d) Master sends control register address (8-bit). e) Slave sends acknowledge signal. f) Master generates STOP condition followed with START condition or REPEAT START condition. g) Master device sends slave address (7-bit) and the data direction bit (R/W = 1). h) Slave device sends acknowledge signal if the slave address is correct. i) Slave sends data byte from addressed register. j) If the master device sends acknowledge signal, the slave device will increase the control register address by one, then send the next data from the new addressed register. k) If the master device generates STOP condition, the read cycle is ended. SCL 0 1 2 3 4 5 SDA A6 A5 A4 A3 A2 A1 start 0 1 2 3 4 5 6 7 8 A0 R/W Ack A7 A6 A5 A4 A3 A2 A1 A0 Ack 6 7 8 Device Address …… Using Repeat start…… 0 1 2 3 4 5 A6 A5 A4 A3 A2 A1 RS 6 7 8 0 A0 R/W Ack D7 …… S 1 ... 6 D6 …… D1 7 8 D0 Ack stop Read Data Device Address Separated Read/write transaction …… P Register Address 0 1 2 3 4 5 A6 A5 A4 A3 A2 A1 6 7 8 0 A0 R/W Ack D7 Device Address 1 ... 6 7 D6 …… D1 D0 Read Data 8 Ack stop I2C Read Timing www.awinic.com.cn 23 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Register Configuration Register List Register name Address(HEX) Read/Write Default Value Chip ID Register 0x00 Read 0x30 Enable Register 0x01 Read/Write 0x80 IVFM Register 0x02 Read/Write 0x01 LED Flash Brightness Register 0x03 Read/Write 0x7F LED Torch Brightness Register 0x05 Read/Write 0x7F Boost Configuration Register 0x07 Read/Write 0x09 Timing Configuration Register 0x08 Read/Write 0x1A Flags1 Register 0x0A Read 0x00 Flags2 Register 0x0B Read 0x00 Device ID Register 0x0C Read 0x0A Last Flash Register 0x0D Read 0x00 Register Detailed Description  Chip ID Register (0x00) Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Chip ID: “00110000”  Enable Register (0x01) Bit 7 TX Pin Enable 0=Disabled 1=Enabled (Default) Bit 6 Strobe Type 0=Level Triggered (Default) 1=Edge Triggered Strobe Enable 0=Disabled (Default) 1=Enabled Torch Enable 0=Disabled (Default) 1=Enabled Mode Bits: M1, M0 00=Standby (Default) 01=IR Drive 10=Torch 11=Flash LED2 Enable 00=OFF(Default) 11=ON 01 and 10 are not valid settings Note: In Edge or Level Strobe Mode, it is recommended that the trigger pulse width be set greater than 1ms to ensure proper turn-on of the device.  IVFM Register (0x02) Bit 7 RFU Bit 6 UVLO Circuitry 0=Disabled (Default) 1=Enabled www.awinic.com.cn Bit 5 Bit 4 IVFM Levels 000=2.9 V (Default) 001=3.0 V 010=3.1 V 011=3.2 V 100=3.3 V 101=3.4 V 110=3.5 V 111=3.6 V 24 Bit 3 Bit 2 RFU Bit 1 RFU Bit 0 IVFM Enable 0=Disabled (Default) 1=Enabled Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0  LED Flash Brightness Register (0x03) Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 LED Flash Brightness Levels IFLASH(mA)≈(Brightness Code*5.88mA)+2.94mA 00000000=2.94 mA …………… 01111111=748.52 mA …………… 11111111=1.5 A  (Default) LED Torch Brightness Register (0x05) Bit 7 Bit 6 Bit 5 LED Torch Brightness Levels ITORCH(mA)≈(Brightness Code*1.51mA)+0.75mA 00000000=0.75 mA …………… 01111111=192 mA (Default) …………… 11111111=386 mA  Boost Configuration Register (0x07) Bit 7 Software Reset Bit 0=Not Reset (Default) 1=Reset  RFU Bit 5 RFU RFU LED Pin Short Fault Detect 0=Disabled 1=Enabled (Default) Boost Mode 0=Normal (Default) 1=Pass Mode Only Boost Frequency Select 0=2 MHz (Default) 1=4 MHz Boost Current Limit 0=1.9A 1=2.8A (Default) Timing Configuration Register (0x08) Bit 7 RFU  Bit 6 Bit 6 Bit 5 Bit 4 Torch Current Ramp time 000=No Ramp 001=1 ms (Default) 010=32 ms 011=64 ms 100=128 ms 101=256 ms 110=512 ms 111=1024 ms Bit 3 Bit 2 Bit 1 Bit 0 Bit 1 Bit 0 Flash Time-out Duration 0000=40 ms 0001=80 ms 0010=120 ms 0011=160 ms 0100=200 ms 0101=240 ms 0110=280 ms 0111=320 ms 1000=360 ms 1001=400 ms 1010=600 ms (Default) 1011=800 ms 1100=1000 ms 1101=1200 ms 1110=1400 ms 1111=1600 ms Flags1 Register (0x0A) Bit 7 TX Flag Bit 6 VOUT Short Fault www.awinic.com.cn Bit 5 LED Short Fault Bit 4 LED Short Fault 25 Bit 3 Current Limit Flag Bit 2 Thermal Shutdown (TSD) Fault UVLO Fault Flash Time-Out Flag Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0  Flags2 Register (0x0B) Bit 7 RFU  Bit 6 RFU RFU Bit 6 RFU RFU Bit 3 RFU Bit 2 IVFM Trip Flag Bit 1 OVP Fault Bit 0 RFU Bit 5 RFU Bit 4 Bit 3 Device ID “01” Bit 2 Bit 1 Bit 0 Silicon Revision Bits “010” Last Flash Register (0x0D) Bit 7 RFU RFU Bit 4 Device ID Register (0x0C) Bit 7  Bit 5 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 The value stored is always the last current value the IVFM detection block set ILED=IFLASH-TARGET*((code+1)/256) www.awinic.com.cn 26 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Application Information The AW36518 can drive a flash LED at current up to 1.5A. The 2MHz/4MHz DC-DC boost regulator allows for the use of small value discrete external components. Below are some peripheral selection guidelines. Output Capacitor Selection The AW36518 is designed to operate with a 10µF ceramic output capacitor. When the boost converter is running, the output capacitor supplies the load current during the boost converter on-time. When the NMOS switch turns off, the inductor energy is discharged through the internal PMOS switch, supplying power to the load and restoring charge to the output capacitor. This causes a sag in the output voltage during the on-time and a rise in the output voltage during the off-time. The output capacitor is therefore chosen to limit the output ripple to an acceptable level depending on load current and input/output voltage differentials and also to ensure the converter remains stable. Larger capacitors such as a 22µF or capacitors in parallel can be used if lower output voltage ripple is desired. To estimate the output voltage ripple considering the ripple due to capacitor discharge (ΔVQ) and the ripple due to the capacitors ESR (ΔVESR) use the following equations: For continuous conduction mode, the output voltage ripple due to the capacitor discharge is: VQ  (VOUT  VIN )  I LED VOUT  f  COUT The output voltage ripple due to the output capacitors ESR is found by: V  I I  VESR  RESR   OUT LED  L  VIN 2   I L  Where VIN  (VOUT  VIN ) VOUT  f  L In ceramic capacitors the ESR is very low so the assumption is that 80% of the output voltage ripple is due to capacitor discharge and 20% from ESR. Table 1 lists different manufacturers for various output capacitors and their case sizes suitable for use with the AW36518. Input Capacitor Selection Choosing the correct size and type of input capacitor helps minimize the voltage ripple caused by the switching of the AW36518 boost converter and reduce noise on the boost converter's input pin that can feed through and disrupt internal analog signals. In the typical application circuit a 10-µF ceramic input capacitor works well. It is important to place the input capacitor as close as possible to the AW36518 input (IN) pin. This reduces the series resistance and inductance that can inject noise into the device due to the input switching currents. Table 1 lists various input capacitors recommended for use with the AW36518. Table 1 Recommended Input/ Output Capacitors (X5R/X7R Dielectric) MANUFACTURER PART NUMBER VALUE CASE VOLTAGE RATING TDK C1608JB0J106M 10μF 0603 6.3V TDK C2012JB1A106M 10μF 0805 10V Murata GRM188R60J106M 10μF 0603 6.3V Murata GRM21BR61A106KE19 10μF 0805 10V www.awinic.com.cn 27 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Inductor Selection The AW36518 is designed to use a 0.47µH or 1µH inductor. When the device is boosting (VOUT > VIN) the inductor is typically the largest area of efficiency loss in the circuit. Therefore, choosing an inductor with the lowest possible series resistance is important. Additionally, the saturation rating of the inductor should be greater than the maximum operating peak current of the AW36518. This prevents excess efficiency loss that can occur with inductors that operate in saturation. For proper inductor operation and circuit performance, ensure that the inductor saturation and the peak current limit setting of the AW36518 are greater than IPEAK in the following calculation: I PEAK  I LED  VOUT  I L   VIN I L  where VIN  VOUT  VIN  2  f SW  L  VOUT And f SW =2 or 4MHz. Table 2 lists various inductors and their manufacturers that work well with the AW36518. Table 2 Recommended Inductors MANUFACTURER L PART NO. SIZE ISAT RDC TOKO 1μH DFE201610P-1R0M 2.0 mm x 1.6 mm x 1.0 mm 3.7A 58mΩ TOKO 0.47μH DFE201610P-R470M 2.0 mm x 1.6 mm x 1.0 mm 4.1A 32mΩ Sunlord 1μH WPN252012H1R0MT 2.5mm × 2.0mm ×1.2mm 3.4A 48mΩ www.awinic.com.cn 28 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 PCB Layout Consideration Layout Guidelines The high switching frequency and large switching currents of the AW36518 make the choice of layout important. The following steps should be used as a reference to ensure the device is stable and maintains proper LED current regulation across its intended operating voltage and current range. 1. Place CIN on the top layer (same layer as the AW36518) and as close to the device as possible. The input capacitor conducts the driver currents during the low-side MOSFET turn-on and turn-off and can detect current spikes over 1 A in amplitude. Connecting the input capacitor through short, wide traces to both the IN and GND pins reduces the inductive voltage spikes that occur during switching which can corrupt the VIN line. 2. Place COUT on the top layer (same layer as the AW36518) and as close as possible to the OUT and GND pin. The returns for both CIN and COUT should come together at one point, as close to the GND pin as possible. Connecting COUT through short, wide traces reduce the series inductance on the OUT and GND pins that can corrupt the VOUT and GND lines and cause excessive noise in the device and surrounding circuitry. 3. Connect the inductor on the top layer close to the SW pin. There should be a low-impedance connection from the inductor to SW due to the large DC inductor current, and at the same time the area occupied by the SW node should be small so as to reduce the capacitive coupling of the high dV/dT present at SW that can couple into nearby traces. 4. Avoid routing logic traces near the SW node so as to avoid any capacitive coupling from SW onto any high-impedance logic lines such as TX, STROBE/TORCH, SDA, and SCL. A good approach is to insert an inner layer GND plane underneath the SW node and between any nearby routed traces. This creates a shield from the electric field generated at SW. 5. Terminate the Flash LED cathodes directly to the GND pin of the AW36518. If possible, route the LED returns with a dedicated path so as to keep the high amplitude LED currents out of the GND plane. For Flash LEDs that are routed relatively far away from the AW36518, a good approach is to sandwich the forward and return current paths over the top of each other on two layers. This helps reduce the inductance of the LED current paths. www.awinic.com.cn 29 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Package Description Pin1 Corner TOP VIEW SIDE VIEW 0.40 TYP D C SYMM ℄ B A 1 2 SYMM ℄ 3 BOTTOM VIEW Unit: mm www.awinic.com.cn 30 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Land Pattern Data 0.40 TYP A 0.40 TYP B SYMM ℄ C D 2 1 3 SYMM ℄ 0.05 MAX All AROUND 0.05 MIN All AROUND SOLDER MASK OPENING SOLDER MASK OPENING METAL UNDER SOLDER MASK METAL NO N SOLDER MASK DEFINED SOLDER MASK DEFINED Unit: mm www.awinic.com.cn 31 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Tape and Reel Information TAPE DIMENSIONS REEL DIMENSIONS P1 P0 P2 K0 W B0 D1 A0 Cavity A0：Dimension designed to accommodate the component width B0：Dimension designed to accommodate the component length K0：Dimension designed to accommodate the component thickness W：Overall width of the carrier tape P0：Pitch between successive cavity centers and sprocket hole P1：Pitch between successive cavity centers P2：Pitch between sprocket hole D1：Reel Diameter D0：Reel Width D0 QUADRANT ASSIGNMENTS FOR PIN 1 ORIENTATION IN TAPE Pin 1 Sprocket Holes Q1 Q2 Q1 Q2 Q1 Q2 Q1 Q2 Q3 Q4 Q3 Q4 Q3 Q4 Q3 Q4 User Direction of Feed Pocket Quadrants DIMENSIONS AND PIN1 ORIENTATION D1 (mm) D0 (mm) A0 (mm) B0 (mm) K0 (mm) P0 (mm) P1 (mm) P2 (mm) W (mm) Pin1 Quadrant 180 9.5 1.4 1.85 0.75 2 4 4 8 Q1 All dimensions are nominal www.awinic.com.cn 32 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 Revision History Version Date Change Record V1.0 Oct. 2018 Product Datasheet V1.0 Released www.awinic.com.cn 33 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD AW36518 Oct. 2018 V1.0 DISCLAIMER Information in this document is believed to be accurate and reliable. However, Shanghai AWINIC Technology Co., Ltd (AWINIC Technology) does not give any representations or warranties, expressed or implied, as to the accuracy or completeness of such information and shall have no liability for the consequences of use of such information. AWINIC Technology reserves the right to make changes to information published in this document, including without limitation specifications and product descriptions, at any time and without notice. Customers shall obtain the latest relevant information before placing orders and shall verify that such information is current and complete. This document supersedes and replaces all information supplied prior to the publication hereof. AWINIC Technology products are not designed, authorized or warranted to be suitable for use in medical, military, aircraft, space or life support equipment, nor in applications where failure or malfunction of an AWINIC Technology product can reasonably be expected to result in personal injury, death or severe property or environmental damage. AWINIC Technology accepts no liability for inclusion and/or use of AWINIC Technology products in such equipment or applications and therefore such inclusion and/or use is at the customer’s own risk. Applications that are described herein for any of these products are for illustrative purposes only. AWINIC Technology makes no representation or warranty that such applications will be suitable for the specified use without further testing or modification. All products are sold subject to the general terms and conditions of commercial sale supplied at the time of order acknowledgement. Nothing in this document may be interpreted or construed as an offer to sell products that is open for acceptance or the grant, conveyance or implication of any license under any copyrights, patents or other industrial or intellectual property rights. Reproduction of AWINIC information in AWINIC data books or data sheets is permissible only if reproduction is without alteration and is accompanied by all associated warranties, conditions, limitations, and notices. AWINIC is not responsible or liable for such altered documentation. Information of third parties may be subject to additional restrictions. Resale of AWINIC components or services with statements different from or beyond the parameters stated by AWINIC for that component or service voids all express and any implied warranties for the associated AWINIC component or service and is an unfair and deceptive business practice. AWINIC is not responsible or liable for any such statements. www.awinic.com.cn 34 Copyright © 2018 SHANGHAI AWINIC TECHNOLOGY CO., LTD