DATASHEET Low Power Ambient Light and Proximity Sensor with Enhanced Infrared Rejection ISL29147 Features The ISL29147 is a low power Ambient Light Sensor (ALS) and proximity (PROX) sensor. It has a built-in IR-LED for the proximity function. The ALS function measures the amount of light (in the visible spectrum) incident on the ISL29147. * Internal IR-LED and sensor for a complete solution The ALS function has a programmable ambient IR-rejection, which allows fine tuning of light source variations and is ideal for light sensor applications under dark protective glass. The ALS provides a 12-bit measurement. A passive optical filter removes unwanted wavelengths (IR or Ultraviolet) to ensure accurate ALS measurement. The proximity function includes a new offset adjustment to compensate for the IR light reflected off the inside of the protective glass cover and back to the ISL29147 sensor. This offset adjustment allows the sensor to compensate for these internal reflections and preserve the dynamic range of the proximity measurement. The built-in current-driver pulses an external infrared LED at a programmed current for 90s. The infrared light that is reflected and received by the ISL29147 is digitized by an 8-bit ADC. The proximity sensor also has a passive optical filter designed to pass IR and reject visible wavelengths. The ISL29147 provides a hardware pin to indicate an interrupt event. The interrupt pin saves power as the host microcontroller can `wake-up' on an interrupt event and does not need to poll the device for an interrupt event. The interrupt generator is user configurable and provides several options for ALS and PROX trigger configurations. The ISL29147 supports an SMBus compatible I2C interface for configuration and control. * Ideal for applications under dark or tinted glass * Enhanced ambient sunlight rejection to 40k Lux * Programmable proximity sleep time between proximity measurements optimizes power consumption * Hardware interrupt - no polling required * Programmable IR compensation to fine-tune ALS performance for various glass compositions * Programmable IR LED drive current to 250mA * Operates from 2.25V to 3.63V VDD * Power-down IDD, typical 0.2ADC * Tiny 2.40x4x1.2 (mm) optical co-package Applications * Display dimming and adjustment - Mobile devices: smart phones, PDA, GPS - Computing: monitors, laptops, notebooks - Picture frames, tablet-PCs, LCD-TV * Object detection - Touchscreen disabling - Smart power-saving 250 VDD_PULLUP R1 100 C2 1F C1 1F SCL, SDA and INT PULLUPs U1 5 VDD 6 SCL 7 GND 8 LED+ 4 SDA 3 INT 2 IRDR 1 LED- IRDR 250mA SMBus MASTER SCL SDA INT ISL29147 200 PROXIMITY COUNTS VDD_IRLED VDD 150 IRDR 125mA 100 50 R1: 100 5% RESISTOR C1, C2: 1F CERAMIC 10V CAPACITOR 0 0 50 100 150 DISTANCE (mm) FIGURE 1. TYPICAL APPLICATIONS CIRCUIT January 6, 2015 FN8409.3 1 FIGURE 2. PROXIMITY SENSITIVITY CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures. 1-888-INTERSIL or 1-888-468-3774 | Copyright Intersil Americas LLC 2013, 2014, 2015. All Rights Reserved Intersil (and design) is a trademark owned by Intersil Corporation or one of its subsidiaries. All other trademarks mentioned are the property of their respective owners. ISL29147 Block Diagram VDD 5 ALS PHOTODIODE ARRAY COMMAND REGISTER PHOTODIODE AMPLIFIERS (ALS AND IR) DUAL CHANNEL ADCs DATA REGISTER I2C IR PHOTODIODE ARRAY 6 SCL 4 IREF FOSC 8 LED+ 7 GND Pin Configuration SDA INTERRUPT 3 IR DRIVER 2 IRDR INT 1 LED- Pin Description ISL29147 (8 LD 2.40x4 (mm) OPTICAL CO-PACKAGE) TOP VIEW LED- 1 8 LED+ IRDR 2 7 GND INT 3 6 SDA 4 5 VDD SCL PIN# NAME DESCRIPTION 1 LED- Cathode of IR LED. 2 IRDR IR-LED Driver Sink - Connect to IR LED Cathode. 3 INT Active Low, Open-Drain Output. 4 SDA I2C Serial Data Input/Output. 5 VDD Positive supply: 2.25V to 3.63V. 6 SCL I2C Serial Clock Input. 7 GND Ground. 8 LED+ Anode of IR LED. Ordering Information PART NUMBER (Notes 1, 2, 3) PART MARKING ISL29147IROMZ-T7 N/A ISL29147IROMZ-EVALZ Evaluation Board VDD RANGE (V) TEMP RANGE (C) 2.25 to 3.63 -40 to +85 PACKAGE (RoHS Compliant) 8 Ld Optical Co-package PKG. DWG. # L8.2.40x4 NOTES: 1. Please refer to TB347 for details on reel specifications. 2. These Intersil Pb-free plastic packaged products employ special Pb-free material sets; molding compounds/die attach materials and NiPdAu plate - e4 termination finish, which is RoHS compliant and compatible with both SnPb and Pb-free soldering operations. Intersil Pb-free products are MSL classified at Pb-free peak reflow temperatures that meet or exceed the Pb-free requirements of IPC/JEDEC J STD-020. 3. For Moisture Sensitivity Level (MSL), please see product information page for ISL29147. For more information on MSL, please see tech brief TB363. Submit Document Feedback 2 FN8409.3 January 6, 2015 ISL29147 Absolute Maximum Ratings Thermal Information VDD Supply Voltage between VDD and GND . . . . . . . . . . . . . . . . . . . . . .4.0V I2C Bus Pin Voltage (SCL, SDA). . . . . . . . . . . . . . . . . . . . . . . . . -0.5V to 4.0V I2C Bus Pin Current (SCL, SDA). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . <10mA INT Pin Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.5V to 4.0V INT Pin Current . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . <10mA ESD Rating Human Body Model (Tested per JESD22-A114E) (Note 4) . . . . . . . . 2kV Thermal Resistance (Typical) JA (C/W) 8 Ld Optical Co-package (Note 5). . . . . . . . 425 Maximum Die Temperature . . . . . . . . . . . . +90C Storage Temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -40C to +85C Operating Temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -40C to +85C Pb-Free Reflow Profile (*) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . see TB487 *Peak temperature during solder reflow +235C max CAUTION: Do not operate at or near the maximum ratings listed for extended periods of time. Exposure to such conditions may adversely impact product reliability and result in failures not covered by warranty. NOTES: 4. ESD on all pins is 2kV except IRDR, which is 1.5kV. 5. JA is measured in free air with the component mounted on a high effective thermal conductivity test board with "direct attach" features. See Tech Brief TB379. Electrical Specifications VDD = 3.0V, TA = +25C. MAX (Note 10) UNITS MIN (Note 10) TYP 2.25 3.0 3.63 V ALS_EN = 0; PROX_EN = 0 0.2 1.0 A Supply Current for ALS+Prox in Sleep Time ALS_EN = 1; PROX_EN = 1 125 140 A PARAMETER DESCRIPTION TEST CONDITION INPUT POWER VDD IDD_OFF IDD_NORM IDD_PRX_SLP IDD_ALS Power Supply Range Supply Current when Powered Down Supply Current for Prox in Sleep Time ALS_EN = 0; PROX_EN = 1 95 A Supply Current for ALS ALS_EN = 1; PROX_EN = 0 95 A ADC (ALS and PROX) tINTGR_ALS 12-bit ALS Conversion Time 80 95 110 ms tINTGR_PROX 8-bit Prox Conversion Time 0.4 0.50 0.6 ms DATAALS_0 ALS Result when Dark EAMBIENT = 0 Lux, 900 Lux range DATAALS_F Full Scale ALS ADC Code EAMBIENT > selected range maximum Lux DATA1 DATA Output Variation Over Light Sources: Fluorescent, Incandescent and Sunlight Ambient light sensing, no cover glass After programmable active IR compensation (Note 6) 10 % DATA2 DATA Output Variation Over Light Sources: Fluorescent, Incandescent and Sunlight Ambient light sensing under cover glass After programmable active IR compensation (Note 6) 10 % Linearity ALS ADC Data Linearity 20% - 80% of full range 5 % 1 Counts DATAPROX_0 Prox Data without Object in Path DATAPROX_F Full Scale Prox ADC Code ProxWASH Washout Bit Activation Level ProxOffsetMax Maximum PROX Offset, Referenced to Proximity ADC Range ProxOffsetInc Proximity Offset Adjust Increment Referenced to Proximity ADC Range Submit Document Feedback 3 1 Counts 4095 255 Norwood Solar Emulator Counts Counts 40k Lux 512 LSB 27 LSB FN8409.3 January 6, 2015 ISL29147 Electrical Specifications PARAMETER VDD = 3.0V, TA = +25C. (Continued) DESCRIPTION TEST CONDITION MIN (Note 10) TYP MAX (Note 10) UNITS LED DRIVER (IRDR PIN) tr Rise Time for IRDR Sink Current RLOAD = 15 at IRDR pin, 20% to 80% 25 ns tf Fall time for IRDR Sink Current RLOAD = 15 at IRDR pin, 80% to 20% 15 ns IIRDR_0 IRDR Sink Current PROX_DR = 0; VIRDR = 0.5V 31.25 mA IIRDR_1 IRDR Sink Current PROX_DR = 1; VIRDR = 0.5V 62.5 mA IIRDR_2 IRDR Sink Current PROX_DR = 2; VIRDR = 0.5V 125 mA IIRDR_3 IRDR Sink Current PROX_DR = 3; VIRDR = 0.5V 250 mA IRDR Leakage Current PROX_EN = 0; VIRDR = 3.63V 0.001 VIRDR IRDR Pin Voltage Compliance Register bit PROX_DR = 0 tPULSE IIRDR On Time Per PROX Reading IIRDR_LEAK IR-LED Specifications SYMBOL 0.50 1 A 4.3 V 90 s TA = +25C. PARAMETER TEST CONDITIONS MIN (Note 10) TYP MAX (Note 10) UNITS VF IR-LED Forward Voltage VR IR-LED Reverse Voltage P IR-LED Peak Output Wavelength IF = 100mA 855 nm IR-LED Spectral Half-Width IF = 100mA 30 nm E IR-LED Radiant Power IF = 100mA 38 mW I2C Electrical Specifications SYMBOL IF = 100mA 1.8 V 5.5 V For SCL and SDA unless otherwise noted, VDD = 3V, TA = +25C (Note 8). PARAMETER VI2C Supply Voltage Range for I2C Interface fSCL TEST CONDITIONS MIN (Note 10) MAX (Note 10) UNITS 3.63 V SCL Clock Frequency 400 kHz VIL SCL and SDA Input Low Voltage 0.55 V VIH SCL and SDA Input High Voltage Vhys Hysteresis of Schmitt Trigger Input VOL Low-level Output Voltage (open-drain) at 4mA Sink Current Ii 1.7 TYP Input Leakage for each SDA, SCL Pin 1.25 V 0.05VDD V -10 0.4 V 10 A tSP Pulse Width of Spikes that must be Suppressed by the Input Filter 50 ns tAA SCL Falling Edge to SDA Output Data Valid 900 ns Capacitance for each SDA and SCL Pin 10 pF Ci tHD:STA Hold Time START Condition After this period, the first clock pulse is generated 600 ns tLOW LOW Period of the SCL Clock Measured at the 30% of VDD crossing 1300 ns tHIGH HIGH Period of the SCL Clock 600 ns tSU:STA Set-up Time for a START Condition 600 ns tHD:DAT Data Hold Time 30 ns Submit Document Feedback 4 FN8409.3 January 6, 2015 ISL29147 I2C Electrical Specifications SYMBOL tSU:DAT For SCL and SDA unless otherwise noted, VDD = 3V, TA = +25C (Note 8). (Continued) PARAMETER TEST CONDITIONS Data Set-up Time MIN (Note 10) TYP MAX (Note 10) UNITS 100 ns tR Rise Time of both SDA and SCL Signals (Note 9) 20 + 0.1 x Cb ns tF Fall Time of both SDA and SCL Signals (Note 9) 20 + 0.1 x Cb ns Set-up Time for STOP Condition 600 ns Bus Free Time Between a STOP and START Condition 1300 ns tSU:STO tBUF Cb Capacitive Load for Each Bus Line 400 Maximum determined by tR and tF 1 pF Rpull-up SDA and SCL System Bus Pull-Up Resistor k tVD;DAT Data Valid Time 0.9 s tVD:ACK Data Valid Acknowledge Time 0.9 s VnL Noise Margin at the LOW Level 0.1VDD V VnH Noise Margin at the HIGH Level 0.2VDD V NOTES: 6. Cover glass assumes fixed infrared/visible light transmissivity ratio of 10. 7. An 850nm infrared LED is used in production test for proximity/IR sensitivity testing. 8. All parameters in the I2C Electrical Specifications table are guaranteed by design and simulation. 9. Cb is the capacitance of the bus in pF. 10. Parameters with MIN and/or MAX limits are 100% tested at +25C, unless otherwise specified. Temperature limits established by characterization and are not production tested. Submit Document Feedback 5 FN8409.3 January 6, 2015 ISL29147 Each I2C transaction ends with the master asserting a stop condition (SDA rising while SCL remains high). For more information about the I2C standard, consult the PhilipsTM I2C specification documents. ISL29147 Configuration and Control I2C Interface Timing specifications are included in "I2C Electrical Specifications" on page 4. The timing parameters are defined in Figure 3. The ISL29147 configuration and control is performed using the I2C or SMBus. The ISL29147's I2C interface slave address is internally hard wired as 8'b1000100x, where x denotes the R/W bit. The I2C interface on the ISL29147 supports single and multiple byte read and write transfers using the random-read/write protocol. The ISL29147 does not support I2C `Repeat Start' protocol. Every I2C transaction begins with the master asserting a start condition (SDA falling while SCL remains high). The first transmitted byte is initiated by the master and includes 7 address bits and a R/W bit. The slave is responsible for pulling SDA low during the ACK time after every transmitted byte. NOTE: In most system implementations, the ISL29147 is connected to a single I2C master with one or more slave devices, consequently, absence of the "Repeat Start" function does not adversely affect I2C bus system performance. Figure 4 shows a sample one-byte read. The I2C bus master always drives the SCL (clock) line, while either the master or the slave can drive the SDA (data) line. FIGURE 3. I2C TIMING DIAGRAM I2C DATA DEVICE ADDRESS START I2C SDA MASTER REGISTER ADDRESS W A A6 A5 A4 A3 A2 A1 A0 W A R7 R6 R5 R4 R3 R2 R1 R0 A I2C SDA SLAVE (ISL29147) SDA DRIVEN BY MASTER I2C CLK 1 2 3 4 5 6 7 A 8 9 A SDA DRIVEN BY MASTER 1 2 3 4 5 6 DEVICE ADDRESS STOP START 7 8 9 A6 A5 A4 A3 A2 A1 A0 W SDA DRIVEN BY MASTER 1 2 3 4 5 6 DATA BYTE0 A SDA DRIVEN BY ISL29147 A A D7 D6 D5 D4 D3 D2 D1 D0 7 8 9 1 2 3 4 5 6 7 8 9 FIGURE 4. I2C DRIVER TIMING DIAGRAM FOR MASTER AND SLAVE CONNECTED TO COMMON BUS Submit Document Feedback 6 FN8409.3 January 6, 2015 ISL29147 Typical Performance Curves 100 250 90 80 IRDR 250mA CIE 1924 PHOTOPIC CURVE 70 150 FSR (%) PROXIMITY COUNTS 200 IRDR 125mA 100 60 50 40 30 50 ALS RESPONSE (BLUE) RANGE: 900 Lux 20 10 0 0 1100 1050 1000 950 900 850 800 750 700 650 600 550 500 450 DISTANCE (mm) 400 150 100 350 50 300 0 WAVELENGTH (nm) FIGURE 5. PROXIMITY SENSITIVITY (Note 11) FIGURE 6. ALS SENSITIVITY (Note 12) 15 100 80 ALS RESPONSE (1% ) VALUE CHANGE (% FSR) 90 10 50% 5 70 60 50 40 30 20 10% 0 0 8k 16k 10 24k 32k AMBIENT LIGHT LEVEL (LUX) FIGURE 7. PROXIMITY AMBIENT LIGHT REJECTION (Note 13) 40k 0 -90 -75 -60 -45 -30 -15 0 15 30 45 60 75 90 ANGLE () FIGURE 8. ALS ANGULAR SENSITIVITY (Note 14) NOTES: 11. Figure 5 shows ISL29147 Proximity distance sweeps with different IRDR LED current settings using an 18% Grey card reflector. 12. Figure 6 shows ISL29147 Ambient Light Sensor Spectral response when compared to a theoretical CIE 1924 Photopic curve. The `Blue' line shows the ISL29147 response and the `Red' line depicts the CIE 1924 Photopic curve. 13. Figure 7 shows the ISL29147 Proximity Ambient Light Rejection using a Norwood Solar Emulator. At 40k Lux ambient light level, the Proximity Washout Count (Reg 0x0D[7:1]) is 127 indicating a saturation in Proximity Signal processing path. The Proximity Washout bit 0x0D[0] is active at approximately 90% of the maximum level. At 10% initial PROX count (due to optical leakage from IR LED to the ISL29147), the PROX data error is under 2%. At 50% initial PROX count (severe optical leakage), the PROX data error is about 7%. 14. Figure 8 shows the Ambient Light Sensor Angular Sensitivity of the ISL29147 using a white LED light source. Submit Document Feedback 7 FN8409.3 January 6, 2015 ISL29147 ISL29147 Register Set TABLE 1. ISL29147 CONFIGURATION AND CONTROL REGISTERS ADDRESS (HEX) 0x00 0x01 REGISTER NAME Device ID Config0 POWER-ON DEFAULT b11000xxx 0x00 REGISTER ACCESS RO RW RW RW RW 0x02 Config1 0x00 0x04 Config2 INTConfig Submit Document Feedback 0x00 0x10 8 FUNCTION NAME/VALUE [7:0] FUNCTION Device Identification [7:3] [11000] ISL29147 Device ID [2:0] [XXX] Reserved [7:0] Proximity Configuration [7:6] Reserved [5] [4:2] [1:0] RW [7:0] RW [7] RW [6:3] RW [2] RW 0x03 BIT FIELDS [1:0] PROX_EN Proximity Enable/Disable [1] Enable [0] Disable PROX_SLP Proximity Sleep Time Select [000] 400ms [001] 100ms [010] 50ms [011] 25ms [100] 12.5ms [101] 6.25ms [110] 3.125ms [111] 0ms IRDR_DRV IR LED Current [00] 31.25mA [01] 62.5mA [10] 125mA [11] 250mA Proximity/ALS Configuration INT_ALG Interrupt Algorithm [0] Hysteresis Window [1] Window Comparator PROX_OFFSET Proximity Offset Compensation ALS_EN Ambient Light Sensing Enable/Disable [1] Enable [0] Disable ALS_RANGE Ambient Light Sensor Range Select [00] 56.25 Lux [01] 112.5 Lux [10] 900 Lux [11] 1800 Lux ALS_IR_COMP Ambient Light Sensor IR Compensation RW [7:0] RW [7:5] RW [4:0] ALSIRComp ALS Infra Red Compensation (Unsigned Binary) RW [7:0] INTConfig Interrupt Configuration, Status and Control Reserved FN8409.3 January 6, 2015 ISL29147 TABLE 1. ISL29147 CONFIGURATION AND CONTROL REGISTERS (Continued) ADDRESS (HEX) REGISTER NAME POWER-ON DEFAULT REGISTER ACCESS RO RW RO RO RW RW BIT FIELDS [7] [6:5] [4] [3] [2:1] [0] FUNCTION NAME/VALUE PROX_INT_FLG FUNCTION Proximity Interrupt Flag [1] Proximity Interrupt Event [0] No Proximity Interrupt Event PROX_PRST Proximity Interrupt Reporting Persistency [00] INT after 1 Proximity Flag Event [01] INT after 2 Consecutive Proximity Flag Event [10] INT after 4 Consecutive Proximity Flag Event [11] INT after 8 Consecutive Proximity Flag Event PWR_FAIL Power Failure (Brown-out) Alarm [1] Brown-Out Detected [0] Normal Operation ALS_INT_FLG Ambient Light Sensor Interrupt Flag [1] ALS Interrupt Flag Event [0] No ALS Interrupt Flag Event ALS_INT_PRST ALS Interrupt Reporting Persistency [00] INT after 1 ALS Flag Event [01] INT after 2 Consecutive ALS Flag Event [10] INT after 4 Consecutive ALS Flag Event [11] INT after 8 Consecutive ALS Flag Event INT_CFG Interrupt Output (Pin) Configuration [1] Interrupt if ALS and PROX Event [0] Interrupt if ALS or PROX Event 0x05 PROX_INT_TL 0x00 RW [7:0] PROX_INT_TL Proximity Interrupt LOW threshold 0x06 PROX_INT_TH 0xFF RW [7:0] PROX_INT_TH Proximity Interrupt HIGH threshold 0x07 ALS_INT_TL 0x00 RW [7:0] ALS_INT_TL1 ALS Interrupt LOW threshold bit[11:4] 0x08 ALS_INT_TLH 0x0F RW [7:0] [7:4] ALS_INT_TL0 ALS Interrupt LOW threshold bit[3:0] [3:0] ALS_INT_TH1 ALS Interrupt HIGH threshold bit[11:8] [7:0] ALS_INT_TH0 ALS Interrupt HIGH threshold bit[7:0] 0x09 ALS_INT_TH 0xFF RW ALS Interrupt LOW/HIGH threshold bits 0x0A PROX_DATA RO [7:0] PROX_DATA Proximity Data (Unsigned Binary) 0x0B ALS_DATA_HB RO [7:0] ALS_DATA_HB ALS Data HIGH Byte [7:4] Set to 0000 [3:0] ALS Data Bit[11:8] 0x0C ALS_DATA_LB RO [7:0] ALS_DATA_LB ALS Data Bit[7:0] 0x0D PROX_AMBIR RO [7:0] PROX_AMBIR Proximity Mode Ambient IR Measurement [7:1] RO 0x0E Config3 Submit Document Feedback 0x00 9 [0] [7:0] Proximity Mode Ambient IR Component PROX_WASH Proximity Washout Status [1] Proximity Washout Detected [0] Normal Proximity Operation SoftReset Software Reset 0x38 Initiate Soft Reset 0x00 Normal operation FN8409.3 January 6, 2015 ISL29147 Registers 0x01 and 0x02 are used to configure the primary proximity and ALS parameters. Register 0x03 is used for optimizing IR compensation in ALS measurements. A procedure to optimize IR compensation is described in "ALS IR Compensation" on page 11. Register 0x04 is the Interrupt Configuration and Status Register, they are used primarily to indicate interrupt events from proximity and ALS measurements. A PWR_FAIL bit to indicate a `Brown-Out' event is available and is set in case of a power supply interruption. A `Brown-Out' event does not generate a hardware interrupt. The host microcontroller must clear this bit by writing a `0' to Reg 0x04[4]. Register 0x04 is also used to configure ALS and Proximity interrupt persistency and the operation of the INT pin. Registers 0x05 and 0x06 are used to set the proximity `LOW' and `HIGH' threshold for proximity interrupt event generation. Registers 0x07, 0x08 and 0x09 are used to set the ALS `LOW' and `HIGH' threshold. Two 12-bit numbers span three address locations as shown in Table 1. Data registers 0x0A holds result of proximity conversion. The proximity result should be validated by `Washout' bit in Reg 0x0D[0]. Registers 0x0B and 0x0C holds result of an ALS measurement. The ALS data is 12 bits wide. Least Significant Byte of the ALS data is available at address 0x0C and Most Significant Byte (MSB) of ALS data is available at address 0x0B. The MSB is right justified, i.e., the upper nibble is always zero and lower nibble contains four data bits. Register 0x0D[7:1] contains ambient IR measurement in proximity measurement phase. This measurement is for detecting ambient Wash out condition, which is indicated by Reg 0x0D[0] being `HIGH'. Proximity `Washout' is described in "Proximity Ambient Washout Detection" on page 11. A software reset can be initiated by writing 0x38 to Register 0x0E. ISL29147 Operation Photodiodes and ADCs The ISL29147 contains two photodiode arrays, which convert photons (light) into current. The ALS photodiodes are designed to mimic the human eye's wavelength response curve to visible light. The ALS photodiodes' current output is digitized by a 12-bit ADC. The ALS ADC output is accessed by reading from Reg 0x0B and 0x0C when the ADC conversion is completed. The ALS ADC converter uses a charge-balancing architecture. Charge-balancing is best suited for converting small current signals in the presence of periodic AC noise. The ISL29147 targets an integration time of 90ms, which can vary 15% from nominal. The ALS integration time is intended to minimize 60Hz flicker. The ALS runs continuously with new data available every 90ms. The proximity sensor runs continuously with a time between conversions controlled by PROX_SLP (Reg 0x01[6:4]). Ambient Light Sensing The ISL29147 is set for ambient light sensing when Register bit ALS_EN = 1. Four measurement ranges from 56.25 Lux to 1800 Lux are available. The ALS measurement range is configured via Reg 0x02[1:0]. Proximity Sensing When proximity sensing is enabled (PROX_EN = 1), the external IR LED is driven for 90s by the built-in IR LED driver through the IRDR pin. ALS CONVERSION TIME = 90ms (FIXED) SEVERAL s BETWEEN CONVERSIONS ALS ACTIVE 90ms PROX SENSOR ACTIVE 90ms 90ms 90ms 90ms TIME 0.50ms FOR PROX CONVERSION TIME IRDR (CURRENT DRIVER) SERIES OF CURRENT PULSES TOTALING 0.09ms TIME SLEEP TIME (PROX_SLP) FIGURE 9. TIMING DIAGRAM FOR PROX/ALS EVENTS - NOT TO SCALE The IR LED current depends on PROX_DRV (Reg 0x01[1:0]). Drive current settings are as shown in Table 1. The IR LED drive is in high impedance state when not active. When the IR from the LED reaches an object and gets reflected back to the ISL29147, the reflected IR light is converted into a current. This current is converted to digital data using an 8-bit ADC. The proximity measurement takes 0.5ms for one conversion including the 90s LED drive time. The period between proximity measurements is determined by PROX_SLP (sleep time) in Reg 0x01[4:2]. Average LED driving current consumption is given by Equation 1. I lRDR ;PEAK 90s I lRDR ;AVE = ----------------------------------------------------T SLEEP (EQ. 1) A typical IRDR scheme is 250mA pulses every 400ms, averaging about 56A DC. The proximity sensor uses an 8-bit ADC, which operates in a similar fashion. The IRDR pin drives (pulses) an infrared LED, the emitted IR reflects off an object back into the ISL29147, and the photo diodes convert the reflected IR to a current signal in 0.5ms. The ADC subtracts the IR reading before and after the LED is driven to remove ambient IR contribution. Submit Document Feedback 10 FN8409.3 January 6, 2015 ISL29147 Total Current Consumption Total current consumption is the sum of IDD and IIRDR. The IRDR pin sinks current and the average IRDR current is calculated by using Equation 1. The IDD depends on voltage and the mode of operation. For simplicity, Equation 1 ignores proximity ADC conversion time since it is much smaller than the sleep time. ALS IR Compensation The ISL29147 is designed for operation under dark glass cover. Glass or plastic covers can significantly attenuate visible light and pass the Infrared light without much attenuation. Consequently, the ISL29147 under a glass cover experiences an IR rich environment. The on-chip ALS passive optical filter on the ISL29147 is designed to block most of the IR incident on the ALS photo diodes. In addition, the ISL29147 provides a programmable active IR compensation that subtracts residual IR still reaching the sensor. The ALS_IR_COMP register (Reg 0x03[4:0]) allows fine tuning of the residual infrared component from the ALS output. The recommended procedure for determining ALS IR compensation is as follows: * Illuminate the ISL29147 based product with a light source without IR, such as a white LED. Record the ALS measurement and the Lux level. * Illuminate the device with an IR LED and the White LED. Take an ALS measurement and Lux level measurement. * Adjust the ALS_IR_COMP register (Reg 0x03, bits 4:0) to compensate for the IR contribution. * Repeat steps above until the IR light source contribution to the ALS measurement is under 10 percent assuming no change in Lux level due to IR light source. Proximity Offset Systems built with a protective glass cover over the ISL29147 can provide light `leakage' or `crosstalk' from the IR LED by reflection from the glass saturating the proximity sensor measurement system (Figure 10). Saturation can occur when the reflection from the glass with no object in the proximity detection space exceeds the full scale of the measurement system. The ISL29147 proximity system provides a user programmable proximity offset correction to compensate for this reflection. GLASS COVER SENSOR The PROX_IR_COMP register (Reg 0x02[6:3]) applies a corrective offset to the received signal prior to ADC conversion, which allows the signal to be brought within the usable range of the proximity measurement system. Proximity Ambient Washout Detection Optical proximity sensor can saturate when illuminated with excessive ambient light. The ISL29147 provides a warning flag when the proximity measurement may be erroneous due to excessive ambient light. The PROX_WASH register (Reg 0x0D[0]) reports this condition. Interrupts Events The ISL29147 interrupts are designed to minimize host micro-controller overhead of continuous polling. The ISL29147 can generate interrupts on the results of an ALS measurement or proximity measurement. The ALS interrupt event ALS_FLAG (Reg 0x04[3]) is governed by Reg 0x07 through Reg 0x09. Two 12-bit high and low threshold values are written to these registers. The ISL29147 will set the ALS interrupt flag, if the ADC conversion count in Registers 0x0B and 0x0C are outside the programmed thresholds. The ALS_FLAG is cleared by writing a `0' to Reg 0x04[3]. A proximity interrupt event (PROX_FLAG) is governed by the high and low thresholds in Reg 0x05 and Reg 0x06 (PROX_LT and PROX_HT) are indicated by Reg 0x04[7]. PROX_FLAG is set when the measured proximity data is more than the higher threshold. The proximity interrupt flag is cleared when the proximity data is lower than the low proximity threshold or by writing a `0' to Reg 0x04[7]. The Proximity interrupt generation can be selected between `out-of-window' threshold and hysteresis schemes. When the PROX_INT_ALG register (Reg 0x02, Bit 7) is set to 0, proximity uses a hysteresis scheme; when set to 1, proximity uses a window comparator scheme. In hysteresis mode, the interrupt event is generated if the proximity ADC count is higher than the PROX_HT threshold and the interrupt event is cleared when the proximity ADC count is less than the PROX_LT threshold. The interrupt event flag can also be cleared by writing a `0' to Reg 0x04[7]. INTERRUPT PERSISTENCE To minimize interrupt events due to `transient' conditions, an interrupt persistency option is available for both ALS and proximity measurements. Persistency requires `X-consecutive' interrupt flags before the INT pin is driven low. Both ALS and PROX have their own independent interrupt persistency options. ALS_PRST and PROX_PRST configuration are controlled from Reg 0x04. LED PCB FIGURE 10. PROXIMITY SET-UP HIGHLIGHTING CROSSTALK REFLECTED FROM COVER GLASS Submit Document Feedback 11 FN8409.3 January 6, 2015 ISL29147 Power-Up and `Brown-Out' Reset Proximity Detection of Various Objects The ISL29147 has an enhanced power-on-reset system. A `Brown-Out' detector flag in Reg 0x04[4] informs the system that the device has powered-up properly. This flag should be reset as part of the initialization sequence. The Proximity sensing relies on the amount of IR reflected back from objects. A perfect black object would absorb all incident light and reflect no photons. The ISL29147 is sensitive enough to detect black ESD foam, which reflects only 1% of IR. Blonde hair typically reflects more than brown hair and skin tissue is more reflective than human hair. A `Brown-Out' condition is defined as an operating condition when the power supply voltage is not within the specified limits. To prevent this condition we recommend the power supply slew rate to be greater than 0.5 V/ms. IR penetrates into the skin and is reflected from within. As a result, the proximity count generally peaks at contact and monotonically decreases as skin moves away. The reflective characteristics of skin are very different from that of an inanimate object such as paper. During the brown-out period at power-up, the I2C interface and the IR LED driver are inactive. Following brown-out, the I2C interface is reinitialized and the configuration registers are set to power-up default values. After power-up and during device initialization, host should examine that the PWR_FAIL flag (Reg 0x04[4]) is set and then clear the flag by writing `0' to Reg 0x04[4]. Typical Application Circuit A typical application circuit for the ISL29147 is shown in Figure 11. The ISL29147's I2C address is internally hard wired as `1000100x', with x representing the R/W bit. The device can be connected to a system's I2C bus together with other I2C compliant devices. It is important to ensure that there is no address conflict with other I2C devices on the bus. Following power-up, a `Brown-Out' condition, if detected, is reported by PWR_FAIL flag by Reg 0x04[4]. Device configuration registers are not set to their power-up default after `Brown-Out'. PWR_FAIL flag should be periodically monitored to detect post power-up power supply interruption. The SCL, SDA and INT pins on the ISL29147 are open drain and require pull-up resistors for proper system operation. Values of the pull-up resistors is system dependent and can range from 2.2k to 10k depending upon the number of I2C devices on the bus. Power-Down Setting ALS_EN (Reg 0x02[2]) and PROX_EN (Reg 0x01[5]) to `0' puts the ISL29147 into a power-down state with power supply current dropping to less than 1A. All configuration registers are maintained in power-down mode. The proximity sensing system can be powered using a dual power supply or using a single power supply. In dual supply configuration, the IR LED and the ISL29147 are powered from separate power supplies. The VDD IRLED can range from 2.25V to 5.0V and the VDD can range from 2.25V to 3.63V. In dual supply configuration, resistor R1 should not be installed. Soft Reset A software reset to ISL29147 can be initiated by writing 0x38 to Reg 0x0E. Following reset, all configuration registers are set to their default power-up state. After soft reset, the ISL29147 defaults to the power-down configuration. In single supply configuration, the IR LED and the ISL29147 are powered from the same power source. The VDD_IRLED can range from 2.25V to 3.63V and the VDD is derived from VDD_IRLED using resistor R1. ALS Data Count Read Out A two byte I2C read from ALS_DATA_HB outputs MSB 1st data on SDA. This data is LSB justified with a zero fill for unused bits. In either power supply configuration, a 1F decoupling capacitor should be installed close to the VDD pin, and another 1F decoupling capacitor should be placed close to the IR LED anode. NOTE: The MSB byte address precedes the LSB byte address. The ALS count is 256*(ALS_DATA_HB) + ALS_DATA_LB. VDD_PULLUP VDD VDD_IRLED SMBus MASTER SCL R1 100 C1 1F C2 1F 5 V 6 DD SCL 7 GND 8 LED+ 4 SDA 3 INT 2 IRDR 1 LED- SDA INT U1 R1: 100 5% RESISTOR C1, C2: 1F CERAMIC 10V CAPACITOR FIGURE 11. TYPICAL APPLICATIONS CIRCUIT Submit Document Feedback 12 FN8409.3 January 6, 2015 ISL29147 Soldering Considerations Convection heating is recommended for reflow soldering; direct-infrared heating is not recommended. The plastic optical co-package does not require a custom reflow soldering profile. A standard reflow soldering profile with a +260C maximum is recommended. Additional information regarding soldering the ISL29147 is included in Intersil Technical Brief TB493. PCB Layout Considerations The ISL29147 is relatively insensitive to PCB layout. Adherence to the following guidelines will ensure first pass success and best performance. The ISL29147 drives the IR LED with 0.09ms current pulses. To supply this pulsed current, a 1 to 10F bulk decoupling capacitor (C1) must be connected from the IR LED anode to the GND pin to minimize instantaneous resistive voltage drop. The connection from IR LED cathode to the IRDR pin should be short and with minimal inductance. Similarly, connection from IR LED anode to VDD_IRLED must be made with a low impedance trace. For most applications, a single power supply may be used to power the IR LED and the ISL29147. Use of resistor R1 and capacitor C2 (Figure 11) to help filter out the power supply noise generated from IR LED switching, is recommended for best ISL29147 performance when using a single power supply. For dual supply operation, resistor R1 should not be installed. Route the I2C/SMBus SCL, SDA and the INT traces away from sources of switching noise. The ISL29147 pin GND should connect to a low impedance ground with low resistance and low inductance traces. Ferrite beads and inductors should be avoided in the ground path. If necessary, due to RF consideration, the effects of DCR (DC resistance) should be evaluated on ALS and Proximity system performance. A 1F ceramic decoupling capacitor should be placed as close to VDD pin as possible. Submit Document Feedback 13 FN8409.3 January 6, 2015 ISL29147 Revision History The revision history provided is for informational purposes only and is believed to be accurate, but not warranted. Please go to web to make sure you have the latest revision. DATE REVISION CHANGE January 06, 2015 FN8409.3 Ordering information table on page 2: Corrected typo from ISL29147IR0MZ-T7 to ISL29147IROMZ-T7 (changed from zero to letter "O") January 14, 2014 FN8409.2 Updated POD L8.2.40x4 - from rev 4 to rev 5 - changes from rev 4: top view re-drawn - changed from round to oval detector and added dimensions. December 9, 2013 FN8409.1 Updated POD L8.2.40x4 - Bottom View changed Pin 1 Index Mark from Pin 1 index mark to Pin 4 index area. Updated Note 4 to show correct Pin number. September 16, 2013 FN8409.0 Initial Release. About Intersil Intersil Corporation is a leading provider of innovative power management and precision analog solutions. The company's products address some of the largest markets within the industrial and infrastructure, mobile computing and high-end consumer markets. For the most updated datasheet, application notes, related documentation and related parts, please see the respective product information page found at www.intersil.com. You may report errors or suggestions for improving this datasheet by visiting www.intersil.com/ask. Reliability reports are also available from our website at www.intersil.com/support For additional products, see www.intersil.com/en/products.html Intersil products are manufactured, assembled and tested utilizing ISO9001 quality systems as noted in the quality certifications found at www.intersil.com/en/support/qualandreliability.html Intersil products are sold by description only. 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For information regarding Intersil Corporation and its products, see www.intersil.com Submit Document Feedback 14 FN8409.3 January 6, 2015 ISL29147 Package Outline Drawing L8.2.40x4 8 LEAD OPTICAL CO-PACKAGE Rev 5, 12/13 2.40 0.90 0.30 1.080.05 4.000.10 2.20 1.200.10 0.625 R0.710.05 0.97 0.50 1.650.05 1.430.05 0.65 0.20 0.20 2.400.10 PIN 4 INDEX AREA BOTTOM VIEW 0.80 PACKAGE OUTLINE 8-LEDA 2-IRDR 7-GND 3-INT 6-SCL 4-SDA 5-VDD 0.55 0.97 1-LEDC 0.80 TOP VIEW 2.40 TYPICAL RECOMMENDED LAND PATTERN NOTES: Submit Document Feedback 15 1. Dimensions are in millimeters. Dimensions in ( ) for Reference Only. 2. Dimensioning and tolerancing conform to ASME Y14.5m-1994. 3. Unless otherwise specified, tolerance: Decimal 0.05 4. Pin #4 identifier is a laser-etched dot on bottom surface. FN8409.3 January 6, 2015 Mouser Electronics Authorized Distributor Click to View Pricing, Inventory, Delivery & Lifecycle Information: Intersil: ISL29147IROMZ-T7