MAX44000GDT+T

EVALUATION KIT AVAILABLE LE AVAILAB MAX44000 Ambient and Infrared Proximity Sensor General Description Features The MAX44000 combines a wide-dynamic range ambient light sensor with an integrated infrared proximity sensor. The IC is a perfect solution for touch-screen portable devices. S Tiny, 2mm x 2mm x 0.6mm UTDFN-Opto Package S VDD = 1.7V to 3.6V S Low-Power Operation 5µA in Ambient Mode 7µA in Ambient Plus Proximity Mode 70µA in Ambient Plus Proximity Mode, Including 100mA LED Current The IC can consume as low as 11µA (time averaged) in ambient light sensing plus proximity sensing, including external IR LED current. The on-chip ambient sensor has the ability to make wide dynamic range 0.03 lux to 65,535 lux measurements. An on-chip IR proximity detector is matched with an integrated IR LED driver. All readings are available on an I2C communication bus. A programmable interrupt pin minimizes the need to poll the device for data, freeing up microcontroller resources, reducing system software overhead, and ultimately, reducing power consumption. S Excellent Light Source Matching Programmable Green and IR Channel Gains S Integrated Single-Pulse IR LED Driver 10mA to 110mA Programmable Range Internal Ambient Cancellation S -40NC to +105NC Temperature Range The IC is designed to drive an external IR LED and can operate from a VDD of 1.7V to 3.6V. It consumes just 5µA operating current when only the ambient light sensor is enabled and 7µA when the proximity receiver and driver are enabled. Ordering Information PART TEMP RANGE PIN-PACKAGE MAX44000GDT+ -40NC to +105NC 6 OTDFN-EP* +Denotes a lead(Pb)-free/RoHS-compliant package. *EP = Exposed pad. Applications Smartphones Accessories Typical Application Circuit appears at end of data sheet. Industrial Sensors Presence Detection Simplified Block Diagram Functional Diagrams VDD VLED VDD VIS + IR (ALS) ALS PGA MICROCONTROLLER 14-BIT SDA MAX44000 IR LED IR (ALS) SCL ALS PGA I2C INT 14-/8-BIT IR (PRX) AMBIENT CANCELLATION PRX PGA GND DRV Pin Configurations appear at end of data sheet. Functional Diagrams continued at end GNDof data sheet. UCSP is a trademark of Maxim Integrated Products, Inc. For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642, or visit Maxim’s website at www.maximintegrated.com. 19-5859; Rev 0; 10/11 MAX44000 Ambient and Infrared Proximity Sensor ABSOLUTE MAXIMUM RATINGS Continuous Power Dissipation (TA = +70NC) 6-Pin OTDFN (derate 11.9mW/NC above +70NC)............. 953mW Operating Temperature Range......................... -40NC to +105NC Soldering Temperature (reflow).......................................+260NC All Pins to GND.....................................................-0.3V to +4.0V Output Short-Circuit Current Duration........................Continuous Continuous Input Current into Any Terminal.................... Q20mA Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. ELECTRICAL CHARACTERISTICS (VDD = 1.8V, TMIN – TMAX = -40°C to +105°C, TA = +25°C, unless otherwise noted.) (Note 1) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS AMBIENT LIGHT RECEIVER CHARACTERISTICS Maximum Ambient Light Sensitivity Fluorescent light (Note 2) Ambient Light Saturation Level 0.03 Lux/LSB 65,535 Lux Gain Error Green LED 538nm response, TA = +25NC (Note 2) Light Source Matching Fluorescent/incandescent light 10 % Infrared Transmittance 850nm vs. 538nm, TA = +25NC 0.5 % Ultraviolet Transmittance 363nm vs. 538nm, TA = +25NC 2 % Dark Current Level 100ms conversion time, 0 lux, TA = +25NC 0 Count 14-bit resolution, has 50Hz/60Hz rejection 100 ADC Conversion Time ADC Conversion Time Accuracy 15 12-bit resolution 25 10-bit resolution 6.25 8-bit resolution 1.56 ms 6 TA = -40NC to +105NC 0.7 TA = +25NC % % INFRARED PROXIMITY RECEIVER CHARACTERISTICS Maximum Proximity Detection Sensitivity 850nm IR LED, 60µW/cm2 Sunlight Rejection Offset No reflector 0 to 100k lux Sunlight Rejection Gain Error With reflector 0 to 100k lux 2 1.5 mW/cm2/ LSB 0 Counts 0.1 Counts/ klux Maxim Integrated MAX44000 Ambient and Infrared Proximity Sensor ELECTRICAL CHARACTERISTICS (continued) (VDD = 1.8V, TMIN – TMAX = -40°C to +105°C, TA = +25°C, unless otherwise noted.) (Note 1) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS IR LED TRANSMITTER Minimum IR LED Drive Current Sink 10 mA Maximum IR LED Drive Current Sink 110 mA Current Control Step 10 Current Control Accuracy DRV Leakage Current Voltage Compliance of DRV Pin mA IOUT = 110mA, VDRV = 1.5V 12 IOUT = 50mA, VDRV = 1.5V 10 IOUT = 10mA, VDRV = 1.5V 12 IOUT = 0mA, VDRV = 3.6V 0.1 IDRV = 110mA, DIOUT = 10%; VDRV = 3.6V 0.5 IDRV = 100mA, DIOUT = 2%, VDRV = 3.6V 0.6 Internal Transmit Pulse Width 100 % FA V Fs POWER SUPPLY Power-Supply Voltage Quiescent Current (Ambient Mode) Software Shutdown Current 1.7 VDD Is ISHDN TA = +25NC 3.6 V 5 10 FA 0.1 0.3 0.6 TA = -40NC to +105NC Quiescent Current Proximity During IR LED pulsed operation 375 Quiescent Current (ALS + Proximity, Time Average) With proximity and ALS sensing on 6.8 FA 100 ms Power-Up Time tON DIGITAL CHARACTERISTICS (SDA, SCL, INT) ISINK = 6mA VOL Output Low Voltage (SDA, INT) INT Leakage Current SDA, SCL Input Current I2C Input Low Voltage VIL_I2C SDA, SCL I2C VIH_I2C SDA, SCL Input High Voltage Input Capacitance Maxim Integrated   600 FA FA 0.06 0.4 V 0.01 1000 nA 0.01 1000 nA 0.4 V 1.6 V 3 pF 3 MAX44000 Ambient and Infrared Proximity Sensor ELECTRICAL CHARACTERISTICS (continued) (VDD = 1.8V, TMIN – TMAX = -40°C to +105°C, TA = +25°C, unless otherwise noted.) (Note 1) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS 400 kHz I2C TIMING CHARACTERISTICS Serial-Clock Frequency fSCL Bus Free Time Between STOP and START tBUF 1.3 Fs Hold Time (Repeated) START Condition tHD,STA 0.6 Fs Low Period of the SCL Clock tLOW 1.3 Fs High Period of the SCL Clock tHIGH 0.6 Fs Setup Time for a REPEATED START tSU.STA 0.6 Fs Data Hold Time tHD,DAT 0 Data Setup Time tSU,DAT SDA Transmitting Fall Time 100 ISINK P 6mA, tR and tF between 0.3 x VDD and 0.7 x VDD tF Setup Time for STOP Condition 0.9 0.6 tSP 0 Pulse Width of Suppressed Spike ns 100 tSU,STO Fs ns Fs 50 ns Note 1: All devices are 100% production tested at TA = +25NC. Temperature limits are guaranteed by design. Note 2: Guaranteed by design. Green 538nm LED chosen for production so that the IC responds to 100 lux flourescent light with 100 lux. Typical Operating Characteristics (VDD = 1.8V, TMIN – TMAX = -40°C to +85°C, unless otherwise noted. All devices are 100% production tested at TA = +25°C. Temperature limits are guaranteed by design.) ADC COUNT vs. DISTANCE vs. LED DRIVE CURRENT 60 200 IOUT = 110mA 150 40 100 20 50 IOUT = 50mA 270 370 470 570 670 770 870 970 1070 WAVE LENGTH (nm) 250 200 WHITE CARD 150 100 IOUT = 20mA GREY CARD 50 0 0 0 4 250 ADC COUNT 80 ADC COUNT vs. DISTANCE vs. OBJECT 300 MAX44000 toc02a GREEN CHANNEL RED CHANNEL CIE CURVE ADC COUNT NORMALIZED OUTPUT 100 300 MAX44000 toc01 120 MAX44000 toc02b SPECTRUM RESPONSE 0 20 40 60 80 DISTANCE (mm) 100 120 140 0 10 20 30 40 50 60 70 80 90 100 DISTANCE (mm) Maxim Integrated MAX44000 Ambient and Infrared Proximity Sensor Typical Operating Characteristics (continued) (VDD = 1.8V, TMIN – TMAX = -40°C to +85°C, unless otherwise noted. All devices are 100% production tested at TA = +25°C. Temperature limits are guaranteed by design.) 1000 INCANDESCENT 800 100 600 50 400 200 BLACK GLASS REFLECTOR 0 0 100 200 300 400 500 600 700 800 900 1000 SUPPLY CURRENT vs. SUPPLY VOLTAGE vs. TEMPERATURE 9 TA = +85°C 7 5 4 TA = +25°C TA = -40°C 3 2 1 30 20 ROTATED WITH AXIS BETWEEN PIN 1/2/3 AND 4/5/6 10 9 8 7 6 5 4 3 STANDARD AMBIENT MODE DARKROOM CONDITION 0 1.7 1.9 2.1 2.3 2.5 2.7 2.9 3.1 3.3 3.5 3.7 SUPPLY VOLTAGE (V) Maxim Integrated 40 STANDARD AMBIENT MODE DARKROOM CONDITION VDD = 1.7 V TO 3.6V 10 TA = +105°C 6 50 OUTPUT ERROR vs. TEMPERATURE COUNTS (UNITS) SUPPLY CURRENT (µA) 8 60 11 MAX44000 toc05 10 70 -90 -70 -50 -30 -10 10 30 50 70 90 -80 -60 -40 -20 0 20 40 60 80 LUMINOSITY ANGLE (°) 10k 20k 30k 40k 50k 60k 70k 80k SUNLIGHT (LUX) REFERENCE METER READING (LUX) 80 0 0 0 MAX44000 toc04 MAX44000 toc03b PRXTIM, PRXPGA : 0x02 = 1111 xxxx LED CURRENT: 0x03 = xxxx 1110 for 100mA WITH NO REFLECTOR, PROX COUNT STAYED AT 0 AT ALL lux LEVEL WITH A BLACK GLASS AS REFLECTOR AND lux LEVEL CHANGED FROM 50 TO 75000 lux PROX COUNTS DROPPED BY 7% AT MID-ADC RANGE PROX COUNT DROPPED BY 35% AT QUARTER ADC RANGE 90 MAX44000 toc06 1200 NO REFLECTOR 100 RELATIVE SENSITIVITY (% FROM 0°) ADC COUNT FLUORESCENT ADC COUNT ALSTIM[1:0] = 00 ALSPGA[1:0] = 10 1400 150 MAX44000 toc03 1600 RADIATION PATTERN SUNLIGHT REJECTION LIGHT SENSITIVITY vs. LUX LEVEL 1800 2 1 0 -40 -15 10 35 60 85 110 TEMPERATURE (°C) 5 MAX44000 Ambient and Infrared Proximity Sensor Typical Operating Characteristics (continued) (VDD = 1.8V, TMIN – TMAX = -40°C to +85°C, unless otherwise noted. All devices are 100% production tested at TA = +25°C. Temperature limits are guaranteed by design.) SUPPLY CURRENT vs. LUX SUPPLY CURRENT vs. TIME MAX44000 toc08 MAX44000 toc07 30 STANDARD AMBIENT MODE SUPPLY CURRENT (µA) 25 AMBIENT + PROXIMITY MODE IDRV 50mA/div 20 15 IDD 200µA/div 10 5 0 1 10 100 1000 100k 10k 100µs/div LUX 140 110mA IDRV SETTING 100 120 80 100 80 60 60 50mA IDRV SETTING 40 40 10mA IDRV SETTING 20 20 0 5 10 SINK CURRENT (mA) 6 15 20 70 60 TOTAL CURRENT (uA) 120 MAX44000 toc10 THE DATA WAS TAKEN ON THE INTERRUPT PIN IDRV (mA) OUTPUT LOW VOLTAGE (V) 160 MAX44000 toc09 180 TOTAL CURRENT CONSUMPTION INCLUDING IR LED CURRENT vs. IR LED CURRENT LEVEL IR LED CURRENT vs. OUTPUT DRIVE VOLTAGE, IDRV vs. VDRV MAX44000 toc11 OUTPUT LOW VOLTAGE vs. SINK CURRENT ITOTAL = IDD + IIR_LED AMBIENT + PROXIMITY MODE 100ms INTEGRATION TIME ITOTAL 50 40 30 20 IDD 10 0 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 VDRV (V) 20 40 60 80 100 120 IR LED LEVEL (mA) Maxim Integrated MAX44000 Ambient and Infrared Proximity Sensor Pin Configuration TOP VIEW + VDD 1 GND 2 DRV 3 MAX44000 EP* 6 SDA 5 SCL 4 INT *EP = EXPOSED PAD, CONNECT TO GND. Pin Description PIN NAME 1 VDD Power Supply FUNCTION 2 GND Ground 3 DRV IR LED Current Driver 4 Interrupt. Active-low output. 5 INT SCL 6 SDA I2C Data EP — I2C Clock Exposed Pad. EP is internally connected to GND. EP must be connected to GND. Detailed Description The MAX44000 combines a wide-dynamic range ambient light sensor with an integrated infrared proximity sensor. The die is placed inside an optically transparent (UTDFN-Opto) package. A photodiode array inside the IC converts the light to a current, which is then processed by low-power circuitry into a digital value. The data is then stored in an output register that is read by an I2C interface. The IC contains three types of photodiodes: a green photodiode and two types of infrared photodiodes. Ambient light sensing (ALS) is accomplished by subtracting the infrared ALS photodiode signal from the green ALS photodiode signals after applying respective gains. The Maxim Integrated infrared proximity photodiodes are optimized for better sensitivity for near infrared signals, specifically 850nm, and can be used for proximity sensor measurements. In the ALS mode, the ALS photodiodes are connected to two ADCs. The user can choose to view either just the green ALS signal, or just the infrared ALS signal, or the difference of the green and infrared ALS photodiodes. In the proximity detect mode, the infrared proximity photodiodes are connected to the proximity receiver circuit and then to an 8-bit ADC. Three key features of the IC’s analog design are its lowpower design, single-pulse proximity receive operation, and interrupt pin operation. 7 MAX44000 Ambient and Infrared Proximity Sensor The IC operates from a VDD of 1.7V to 3.6V and consumes just 5FA current in ALS mode and 7FA time-averaged in proximity mode. The on-chip IR proximity detector DC ambient rejection circuitry is synchronized with pulsing of an integrated IR LED transmitter to improve noise immunity from external fluctuating IR sources. This scheme also reduces IR LED power consumption compared to alternate methods and eliminates red-glow problems with the use of 850nm IR LEDs; power consumption is reduced to 11FA (time averaged), including the current consumption of an external IR LED. An on-chip programmable interrupt function eliminates the need to continually poll the device for data, resulting in a significant power saving. Ambient Light Sensing Variation between light sources can extend beyond the visible spectral range. For example, fluorescent and incandescent light sources with similar visible brightness (lux) can have substantially different IR radiation content (since the human eye is blind to it). Since this infrared radiation can be picked up by silicon photodiodes, differences in light spectra can affect brightness measurement of light sensors. For example, light sources with high IR content, such as an incandescent bulb or sunlight, would suggest a much brighter environment than our eyes would perceive them to be. Other light sources such as fluorescent and LED-based systems have very little infrared content. The IC incorporates on-chip compensation techniques to minimize these effects and still output an accurate lux response in a variety of lighting conditions. On-chip user-programmable green channel and IR channel gain trim registers allow the light sensor response to be tailored to the application, such as when the light sensor is placed under dark or colored glass. 120 120 100 100 80 STANDARD ALS (GREEN-RED) 60 40 20 80 GREEN CHANNEL RED CHANNEL CIE CURVE 60 40 20 0 0 270 370 470 570 670 770 870 970 1070 270 370 470 570 670 770 870 970 1070 WAVELENGTH (nm) WAVELENGTH (nm) Figure 1. Spectral Response Compared to Ideal Photopic Curve 8 The photopic curve represents a typical human eye’s sensitivity to wavelength. As can be seen in Figure 1 and Figure 2, its peak sensitivity is at 555nm (green). The human eye is insensitive to infrared (> 700nm) and ultraviolet (< 400nm) radiation. NORMALIZED OUTPUT NORMALIZED RESPONSE The ambient light sensors are designed to detect brightness in the same way as human eyes do. To achieve this, the light sensor needs to have a spectral sensitivity that is identical to the photopic curve of the human eye (see Figure 1). Small deviations from the photopic curve can affect perceived brightness by ambient light sensors to be wildly different. However, there are practical difficulties in trying to reproduce the ideal photopic curve in a small cost-efficient package. The IC instead uses two different types of photodiodes (a green and an infrared) that have different spectral sensitivities—each of which is amplified and subtracted on-chip with suitable gain coefficients so that the most extreme light sources (fluorescent and incandescent) are well matched to a commercial illuminance lux meter. Figure 2. Green Channel and IR Channel Response at Identical Gains on a Typical MAX44000 Maxim Integrated MAX44000 Ambient and Infrared Proximity Sensor Proximity Light Sensing large amounts of DC IR radiation. Due to the use of a single-pulse technique in pulsing the external infrared LED, the chip is also immune to fixed-frequency external infrared radiation such as from remote controls, electronic ballasts, etc., leading to more reliable infrared proximity sensor operation. The proximity sensing uses an external, pulsed infrared LED source to emit controlled amounts of infrared radiation. When an external object reflects back some of this infrared radiation back to the IC, it is detected by the integrated light detector. The amount of reflected light detected is then used to determine the object’s proximity to the sensor. LED Driver The IC features a LED driver that delivers a pulsed current at the output. The pulse amplitude is programmable through the I2C interface from 0 to 110mA in steps of 10mA. A low-voltage compliance of DRV pin allows IR LEDs to be powered from lower voltage rails, possibly even a 1.8V rail. High-current drive accuracy improves performance by eliminating part-to-part variation. It is important to take account for the fact that different objects at the same distance from the sensor can reflect different amounts of infrared radiation depending on their texture and color. The IC includes on-chip ambient cancellation circuitry in the receive path of the infrared proximity sensor. This scheme allows the part to operate in the presence of Register Description REGISTER B7 B6 B5 B4 B3 B2 B1 B0 REGISTER ADDRESS POWER-ON RESET STATE R/W 0x00 0x04 R STATUS Interrupt Status PWRON PRXINTS ALSINTS CONFIGURATION Main Configuration Receive Configuration Transmit Configuration TRIM 1 1 1 MODE[2:0] 1 PRXINTE ALSINTE 0x01 0x24 R/W ALSPGA[1:0] 0x02 0x00 R/W 0x03 0x00 R/W ALSTIM[1:0] DRV[3:0] ADC DATA ADC High Byte (ALS) ADC Low Byte (ALS) ADC Byte (PROX) OFL 0x04 0x00 R ALSDATA[7:0] ALSDATA[13:8] 0x05 0x00 R PRXDATA[7:0] 0x16 0x00 R 0x06 0x00 R/W 0x07 0x00 R/W 0x08 0x00 R/W 0x09 0x00 R/W THRESHOLD SET ALS Upper Threshold (High Byte) ALS Upper Threshold (Low Byte) ALS Lower Threshold (High Byte) ALS Lower Threshold (Low Byte) Maxim Integrated UPTHR[13:8] UPTHR[7:0] LOTHR[13:8] LOTHR[7:0] 9 MAX44000 Ambient and Infrared Proximity Sensor Register Description (continued) REGISTER B7 B6 B5 B4 Threshold Persist Timer B3 B2 B1 PRXPST[1:0] PROX Threshold Indicator B0 ALSPST[1:0] ABOVE PROX Threshold PRXTHR[7:0] Digital Gain Trim of Green Channel TRIM_ GREEN_ IR[0] TRIM_GAIN_GREEN[6:0] Digital Gain Trim of Infrared Channel TRIM_GAIN_IR[8:1] REGISTER ADDRESS POWER-ON RESET STATE R/W 0x0A 0x00 R/W 0x0B 0x00 R/W 0x0C 0x00 R/W 0x0F 0x80 R/W 0x10 0x80 R/W The individual register bits are explained below. Default power-up bit states are highlighted in bold. Interrupt Status Register (0x00) REGISTER B7 B6 B5 B4 Interrupt Status B3 B2 B1 B0 PWRON PRXINTS ALSINTS REGISTER ADDRESS POWER-ON RESET STATE R/W 0x00 0x04 R The PWRON bit in the Interrupt Status register 0x00, if set, indicates that a power-on-reset (POR) condition has occurred, and any user-programmed thresholds cannot be valid anymore. The ALSINTS bit in the Interrupt Status register 0x00 indicates that an ambient light interrupt condition has occurred. The PRXINTS bit in the Interrupt Status register 0x00 indicates that a proximity receive interrupt condition has occurred. If any of these bits is set to 1, the INT pin is pulled low and asserted. Note: On Rev-1 of the device, the PWRON bit does not pull the INT pin low, even if set to 1. Reading the Interrupt Status register clears the PWRON, ALSINTS, and PRXINTS bits, if set, and deasserts the INT pin. INT is pulled high by the off-chip pullup resistor. The ALSINTS and PRXINTS bits are disabled and set to 0 if the respective interrupt enable bits in Main Configuration register 0x01 are set to 0. Ambient Interrupt Status (ALSINTS) BIT 0 10 OPERATION 0 No interrupt trigger event has occurred. 1 The ambient light intensity has traversed outside the designated window limits defined by Threshold registers for greater than persist timer count ALSPST[1:0], or an overflow condition in the ambient light readings has occurred. This bit also causes the INT pin to be pulled low. Once set, the only way to clear this bit is to read this register or to set the ALSINTE bit in register 0x01 to 0. Maxim Integrated MAX44000 Ambient and Infrared Proximity Sensor Proximity Interrupt Status (PRXINTS) BIT 1 OPERATION 0 No interrupt trigger event has occurred. 1 The IR proximity receive intensity has exceeded the threshold limit for greater than persist timer count PRXPST[1:0]. This bit also causes the INT pin to be pulled low. Once set, the only way to clear this bit is to read this register or to set PRXINTE bit to 0. Power-On Reset Status (PWRON) BIT 2 OPERATION 0 No interrupt trigger event has occurred. 1 The part went through a power-up event, either because the part was turned on or because there was a powersupply voltage glitch. All interrupt threshold settings in the registers have been reset to a default state and should be examined. A 1 on this bit also causes the INT pin to be pulled low. Note: INT is not pulled low on Rev-1 of the IC. Once this bit is set, the only way to clear this bit is to read this register. Main Configuration Register (0x01) REGISTER B7 Main Configuration B6 B5 TRIM B4 B3 B2 MODE[2:0] B1 B0 PRXINTE ALSINTE REGISTER ADDRESS POWER-ON RESET STATE R/W 0x01 0x24 R/W This register is used to set the operating mode of the IC (ALS and/or proximity) and enable interrupt operation of the device. TRIM BIT 5 OPERATION 0 Use bytes written to TRIM_GAIN_GREEN[7:0] and TRIM_GAIN_IR[7:0] registers to set the fine-trim gain of the green and IR gain channels. 1 Use factory-programmed gains for green and IR channels. Ignore bytes written to TRIM_GAIN_GREEN[7:0] and TRIM_GAIN_IR[7:0] registers. MODE[2:0] The 3-bit MODE[2:0] defines eight operating modes for the IC, as shown below. MODE[2:0] OPERATING MODE 000 Shutdown Analog circuits are shut down, but the digital register retains values. 001 ALS G-IR Standard ALS mode stores the difference between green and infrared channel readings. Proximity channel operation and updates are disabled. OPERATION 010 ALS G ALS green channel only. Proximity channel operation and updates are disabled. 011 ALS IR Infrared channel only. Proximity channel operation and updates are disabled. 100 ALS/PROX ALS and PROX are interleaved continuously. 101 PROX Only PROX only continuously. ALS channel operation and updates are disabled. 110 Reserved Do not use. 111 Reserved Do not use. Maxim Integrated 11 MAX44000 Ambient and Infrared Proximity Sensor Proximity Interrupt Enable (PRXINTE) BIT 1 OPERATION 0 The PRXINTS bit remains unasserted, and proximity channel readings are not compared with interrupt thresholds. 1 Detection of a proximity interrupt event triggers a hardware interrupt (INT pin is pulled low) and sets the PRXINTS bit (register 0x00, B1). Proximity channel readings are compared with proximity interrupt threshold settings and proximity persist timer. Ambient Interrupt Enable (ALSINTE) BIT 0 OPERATION 0 The ALSINTS bit remains unasserted, and ALS channel readings are not compared with interrupt thresholds. 1 Detection of an ambient light interrupt event triggers a hardware interrupt (INT pin is pulled low) and sets the ALSINTS bit (register 0x00, B0). ALS channel readings are compared with ALS interrupt threshold settings and ALS persist timer. Receive Configuration Register (0x02) REGISTER Receive Configuration B7 B6 B5 B4 1 1 1 1 B3 B2 ALSTIM[1:0] B1 B0 ALSPGA[1:0] REGISTER ADDRESS POWER-ON RESET STATE R/W 0x02 0x00 R/W This register sets the ADC integration time and front-end photodiode circuitry sensitivity (gain) for the ALS channel. The ADC integration time also controls the bit resolution of measurements. ADC conversions are made of MSB first (the IC needs longer conversion times for higher resolution measurements). Use of lower PGA gains helps expand the full-scale range of the ADC at the expense of per-LSB sensitivity. 12 Maxim Integrated MAX44000 Ambient and Infrared Proximity Sensor Ambient ADC Conversion Time (ALSTIM) The 2-bit ALSTIM[1:0] sets the integration time for ALS ADC conversion, as shown in Table 1. Table 1. Ambient ADC Conversion Time ALSTIM[1:0] INTEGRATION TIME (ms) FULL-SCALE ADC COUNTS 00 100 16,384 14 1x 01 25 4096 12 4x 10 6.25 1024 10 16x 11 1.5625 256 8 64x BIT RESOLUTION RELATIVE LSB SIZE Ambient Light Measurement Gain (ALSPGA) The 2-bit ALSPGA[1:0] sets the gain of the ambient light sensing measurement according to Table 2. Table 2. Ambient Light Measurement Gain ALSPGA[1:0] LUX/LSB RELATIVE LSB SIZE 00 0.03125 1x 01 0.125 4x 10 0.5 16x 11 4 128x Transmit Configuration Register (0x03) This register controls the driver current setting and is used when the Proximity channel is enabled. REGISTER B7 B6 B5 B4 Transmit Configuration B3 B2 B1 DRV[3:0] B0 REGISTER ADDRESS POWER-ON RESET STATE R/W 0x03 0x00 R/W LED Drive Current Setting (DRV) The 4 bits of DRV set the LED drive current according to Table 3. Table 3. LED Drive Current Settings DRV[3:0] LED CURRENT (mA) DRV[3:0] LED CURRENT (mA) 0000 LED driver disabled 1000 40 0001 10 1001 50 0010 20 1010 60 0011 30 1011 70 0100 40 1100 80 0101 50 1101 90 0110 60 1110 100 0111 70 1111 110 Maxim Integrated 13 MAX44000 Ambient and Infrared Proximity Sensor ALS Data Register (0x04, 0x05) REGISTER B7 B6 ADC High Byte (ALS) B5 B4 OFL B3 B2 B1 B0 ALSDATA[13:8] ADC Low Byte (ALS) ALSDATA[7:0] REGISTER ADDRESS POWER-ON RESET STATE R/W 0x04 0x00 R 0x05 0x00 R The 2 bytes here (ALSDATA[13:0]) hold the results of the ALS signal conversion. The resolution and bit length of the result is controlled by the value of ALSTIM[1:0] and ALSPGA[1:0] bits. The result is always right justified in the two registers, and the unused high bits are zero. OFL indicates an overflow condition on the ALS channel. If this occurs, set the ALS range (ALSPGA[1:0]) to a higher range. If the OFL bit is set to 1 (there is an overflow condition), and the ALSINTE bit is set to 1 (enabled), then the ALSINTS bit is set to 1 and the INT pin is pulled low. The data in this register could be the green channel, infrared channel, or ALS readings (green channel, infrared channel readings), depending on the mode selected by the user. Internal update of these two registers is disabled during I2C read operations to ensure proper data handoff between the ADC and the I2C registers. Update of the I2C registers is resumed once the master sends a STOP (P) command. Therefore, when reading the 2 bytes of this register, the master should not send a STOP command between the 2-byte reads. Instead, a Repeated START (Sr) command should be used. The exact read sequence using the Repeated START command is shown in the I2C Serial Interface section. PROX Data Registers (0x15, 0x16) REGISTER ADC Byte (PROX) B7 B6 B5 B4 B3 PRXDATA[7:0] B2 B1 B0 REGISTER ADDRESS POWER-ON RESET STATE R/W 0x16 0x00 R The byte here (PRXDATA[7:0]) hold the results of the proximity receive signal conversion. Internal update of the register is disabled during I2C read operations to ensure proper data handoff between the ADC and the I2C registers. Update of the I2C registers is resumed once the master sends a STOP command. 14 Maxim Integrated MAX44000 Ambient and Infrared Proximity Sensor ALS Interrupt Threshold Registers (0x06–0x09) REGISTER B7 B6 B5 B4 ALS Upper Threshold (High Byte) B3 B2 B1 B0 REGISTER ADDRESS POWER-ON RESET STATE R/W 0x06 0x00 R/W 0x07 0x00 R/W 0x08 0x00 R/W 0x09 0x00 R/W UPTHR[13:8] ALS Upper Threshold (Low Byte) UPTHR[7:0] ALS Lower Threshold (High Byte) LOTHR[13:8] ALS Lower Threshold (Low Byte) LOTHR[7:0] The ALS upper threshold and ALS lower threshold (UPTHR[13:0] and LOTHR[13:0]) set the window limits that are used to trigger an ALS interrupt. It is important to set these values according to the selected bit resolution/integration time chosen for the ALS measurement based on the ALSTIM[1:0] and ALSPGA[1:0] settings. The upper 2 bits are always ignored. If the INTE bit is set, and the lux level is greater or lower than the respective thresholds for a period greater than that defined by the ALSPST persist time, the INTS bit in the Status register is set and the INT pin is pulled low. ALS/PROX Threshold Persist Timer Register (0x0A) REGISTER B7 B6 B5 Threshold Persist Timer B4 B3 B2 PRXPST[1:0] B1 B0 REGISTER ADDRESS POWER-ON RESET STATE R/W 0x0A 0x00 R/W ALSPST[1:0] The MAX44000 incorporates a persist function that allows the users to set the number of consecutive triggers before interrupt. PRXPST[1:0] and ALSPST[1:0] set one of four persist values that control how readily the interrupt logic reacts to a detected event. This feature is added to reduce false or nuisance interrupts. PRXPST[1:0] OR ALSPST[1:0] NO. OF CONSECUTIVE TRIGGERS BEFORE INTERRUPT 00 1 01 2 10 4 11 16 When ALSPST[1:0] is set to 00, and the ALSINTE bit is set to 1, the first time an ALS interrupt event is detected, the ALSINTE interrupt bit is set and the INT pin goes low. If ALSPST[1:0] is set to 01, then four consecutive interrupt events must be detected on four consecutive measurement cycles. Similarly, if ALSPST[1:0] is set to 10, or 11, then 8 or 16 consecutive interrupts must be detected. If there is an intervening measurement cycle where no interrupt is detected, then the count is reset to zero. The proximity interrupt function is managed in the same way with PRXPST[1:0]. Maxim Integrated 15 MAX44000 Ambient and Infrared Proximity Sensor Proximity Threshold Registers (0x0B, 0x0C) REGISTER B7 B6 PROX Threshold Indicator B5 B4 B3 B2 B1 B0 ABOVE PROX Threshold PRXTHR[7:0] REGISTER ADDRESS POWER-ON RESET STATE R/W 0x0B 0x00 R/W 0x0C 0x00 R/W The value set by PRXTHR[7:0] in combination with the ABOVE bit controls the operation of the proximity interrupt function. If the ABOVE bit is set to 1, the proximity interrupt has been enabled (PRXINTE = 1), and the result of a proximity measurement is greater than the value stored in PRXTHR[7:0], then a proximity interrupt event is recorded. The interrupt bit is set subject to count conditions set by PRXPST[1:0]. Similarly, if the ABOVE bit is set to 0, then an interrupt event is recorded if the result of a proximity measurement is less than value stored in PRXTHR[7:0]. Digital Gain Trim Registers (0x0F, 0x10) REGISTER Digital Gain Trim of Green Channel Digital Gain Trim of Infrared Channel B7 B6 B5 B4 B3 B2 B1 TRIM_GAIN_GREEN[6:0] TRIM_GAIN_IR[8:1] B0 REGISTER ADDRESS POWER-ON RESET STATE R/W TRIM_ GAIN_ IR[0] 0x0F 0x80 R/TW 0x10 0x80 R/TW Note: Values read from TRIM_GAIN_ registers are the complements of the written value. This is true for reading both the factoryprogrammed values and the customer-programmed values. TRIM_GAIN_GREEN[6:0] is used to modify the gain of the green channel. TRIM_GAIN_IR[8:0] is used to modify the gain of the IR channel. To tell the part to use the values written to this register, set the TRIM bit to 0 in the Main Configuration register after writing new values to these registers. 16 Maxim Integrated MAX44000 Ambient and Infrared Proximity Sensor Applications Information 2mm Ambient Sensing Applications Typical applications involve placing the IC behind a glass with a small semitransparent window placed above it. Use the photodiode sensitive area as shown in Figure 3 to properly position the window above the part. The part comes equipped with internal gain trim registers for the green and IR ALS photodiodes. By suitably choosing the gains for these channels, accurate ambient light readings can be generated in all lighting conditions irrespective of the type of glass the part is used under. This is especially useful for black-glass applications, where for cosmetic reasons, the part is placed behind a black film to hide its presence, and this film has the peculiar property of attenuating most ambient light, but passing through infrared radiation. In standard ALS mode, the green channel and infrared channel readings are internally subtracted. Since one is observing only the difference in two separate ADC measurements, wrong readings can be obtained if one of the channels becomes saturated, while the other channel continues to rise. Since both the green photodiode also picks up a lot of the infrared signal, this saturation can occur much before the maximum expected full-scale range in certain lighting conditions. For example, under incandescent light, there is a lot more infrared optical power than in the visible spectral range. In these situations, the green channel can saturate much earlier than 511 lux in the most sensitive range. To assist the user in detecting these conditions, an OFL bit is provided that alerts the user of an overrange condition. This bit also triggers an ALS interrupt if it has been enabled. Proximity Sensing Applications The IC integrates a novel proximity sensor interface circuit with a robust built-in ambient IR cancellation scheme. The internal DC IR rejection circuit eliminates problems of ADC saturation in the presence of strong ambient infrared radiation, such as bright sunlight. Further, the proximity sensor uses a single-pulse scheme for the IR transmitter that eliminates red-glow problems seen in competing solutions to drive 850nm IR LEDs, while also reducing average IR LED power consumption to less than 0.1% of the IR LED peak current. Maxim Integrated VCC 1 MAX44000 6 SDA TOP VIEW 1.226mm 0.753mm GND 2 0.39mm DRV 3 5 SCL 2mm PHOTODIODE 4 INT 0.492mm Figure 3. Photodiode Location Interrupt Operation Ambient interrupt is enabled by setting bit 0 of register 0x01 to 1 and proximity interrupt is enabled by setting bit 1 of register 0x01 to 1 (see Table 1 and Table 2). The interrupt pin, INT, is an open-drain output and pulls low when an interrupt condition occurs (e.g., when ambient lux readings exceed threshold limits for a period greater than that set by the Time register). The interrupt status bit is cleared automatically if register 0x00 is read or if the interrupts are disabled. A PWRON interrupt bit is set to alert the master of a chip reset operation in case of a power-supply glitch that can happen on smartphones that place the light sensor on a flex with a small connector. It is best to utilize the interrupt pin on the IC to alert the master to come and read measurements from the IC. This eliminates the need for the microcontroller (I2C master) to continually poll the device for information. Due to the use of pullup resistors on the I2C bus, minimizing I2C bus activity can reduce power consumption substantially. In addition, this frees up the microcontroller resources to service other background processes to improve device performance. The wide variety of smarts available on the chip, such as the ability to set the threshold levels and to count persist timer limits, allow the part to operate in an autonomous mode most of the time. 17 MAX44000 Ambient and Infrared Proximity Sensor Interrupt Pin Voltage Compliance The interrupt pin can withstand external voltages up to 4V when in high-impedance mode per the absolute maximum ratings of the IC. However, when the voltage on the INT pin is higher than the VDD of the part (such as when external pullup voltage is greater than VDD of part), there is a small leakage current of 25µA sink into INT. This additional current drawn through the INT pin should also be accounted for in power-sensitive applications. Typical Operating Sequence The typical operating sequence for the master to communicate to the IC is shown below: 1) Read the Interrupt Status register (0x00) to confirm only the PWRON bit is set. This also clears a hardware interrupt. Note: For Rev-1 devices, a PWRON interrupt does not trigger a hardware interrupt. 2) Set the Threshold and Threshold Persist Timer registers for ambient and proximity sensor measurements (Registers 0x06–0x0C). Note: For Rev-1 devices, leave the Threshold Persist Timer register (Register 0x0A) set to 0. 3) Write F0 to the Receive Configuration register (Register 0x02) to set the ALS sensor in the highest gain setting and ALS ADCs in 14-bit modes of operation. 4) Set the IR LED current to a suitable level by writing to the Transmit Configuration register (0x03). 5) Write 0x13 to Main Configuration register (register 0x01) to set the part in ALS + proximity mode, and to enable ALS and proximity interrupts. 6) Set the new green channel gains and infrared channel gains, if necessary, to customize ALS operation for application conditions. Ensure the TRIM bit is set to 0 when not using default factorytrim settings. 7) Wait for interrupt. 8) Read the Interrupt Status register (0x00) to confirm the IC to be the source of interrupt, and to check for the type of interrupt. If set, this should clear the hardware interrupt on the part. 9) If an ALS interrupt has occurred, read the ADC High Byte (ALS) and ADC Low Byte (ALS) registers (registers 0x04, 0x05) to confirm if data is valid (i.e., OFL = 0), and take appropriate action (e.g., sets new backlight strength). Set new ALS thresholds, if necessary. 10) If a PROX interrupt has occurred, read the PROX ADC registers (register 0x15) and take appropriate action (typically, turn off or turn on touch screen and backlight). Set new proximity thresholds, if necessary. 11) Return to step 7. I2C Serial Interface The IC features an I2C/SMBus-compatible, 2-wire serial interface consisting of a serial-data line (SDA) and a serial-clock line (SCL). SDA and SCL facilitate communication between the IC and the master at clock rates up to 400kHz. Figure 4 shows the 2-wire interface timing diagram. The master generates SCL and initiates data transfer on the bus. A master device writes data to the IC by transmitting the proper slave address followed by the register address and then the data word. Each transmit sequence is framed by a START (S) or Repeated START condition and a STOP condition. Each word transmitted to the IC is 8 bits long and is followed by an acknowledge clock pulse. A master reading data from the IC transmits the proper slave address followed by a series of nine SCL pulses. The IC transmits data on SDA in sync with the master-generated SCL pulses. The master acknowledges receipt of each byte of data. Each read sequence is framed by a START or Repeated START condition, a not acknowledge, and a STOP condition. SDA operates as both an input and an open-drain output. A pullup resistor, typically greater than 500I, is required on the SDA bus. SCL operates as only an input. A pullup resistor, typically greater than 500I, is required on SCL if there are multiple masters on the bus, or if the master in a single-master system has an open-drain SCL output. Series resistors in line with SDA and SCL are optional. Series resistors protect the digital inputs of the IC from high-voltage spikes on the bus lines, and minimize crosstalk and undershoot of the bus signal. Table 4. Slave Address 18 SLAVE ADDRESS FOR WRITING SLAVE ADDRESS FOR READING 1001 0100 1001 0101 Maxim Integrated MAX44000 Ambient and Infrared Proximity Sensor SDA tBUF tSU,STA tSU,DAT tHD,STA tHD,DAT tLOW tSP tSU,STO SCL tHIGH tHD,STA tR tF REPEATED START CONDITION START CONDITION STOP CONDITION START CONDITION Figure 4. 2-Wire Interface Timing Diagram Bit Transfer One data bit is transferred during each SCL cycle. The data on SDA must remain stable during the high period of the SCL pulse. Changes in SDA while SCL is high are control signals. See the START and STOP Conditions section. SDA and SCL idle high when the I2C bus is not busy. START and STOP Conditions SDA and SCL idle high when the bus is not in use. A master initiates communication by issuing a START condition. A START condition is a high-to-low transition on SDA with SCL high. A STOP condition is a low-to-high transition on SDA while SCL is high (Figure 5). A START condition from the master signals the beginning of a transmission to the IC. The master terminates transmission, and frees the bus by issuing a STOP condition. The bus remains active if a Repeated START condition is generated instead of a STOP condition. Early STOP Conditions The IC recognizes a STOP condition at any point during data transmission except if the STOP condition occurs in S Sr the same high pulse as a START condition. For proper operation, do not send a STOP condition during the same SCL high pulse as the START condition. Acknowledge The acknowledge bit (ACK) is a clocked 9th bit that the IC uses to handshake receipt of each byte of data when in write mode (Figure 6). The IC pulls down SDA during the entire master-generated ninth clock pulse if the previous byte is successfully received. Monitoring ACK allows for detection of unsuccessful data transfers. An unsuccessful data transfer occurs if a receiving device is busy or if a system fault has occurred. In the event of an unsuccessful data transfer, the bus master can retry communication. The master pulls down SDA during the ninth clock cycle to acknowledge receipt of data when the IC is in read mode. An acknowledge is sent by the master after each read byte to allow data transfer to continue. A not acknowledge is sent when the master reads the final byte of data from the IC, followed by a STOP condition. CLOCK PULSE FOR ACKNOWLEDGMENT P SCL START CONDITION SCL 1 2 8 9 NOT ACKNOWLEDGE SDA SDA ACKNOWLEDGE Figure 5. START, STOP, and Repeated START Conditions Maxim Integrated Figure 6. Acknowledge 19 MAX44000 Ambient and Infrared Proximity Sensor Write Data Format A write to the IC includes transmission of a START condition, the slave address with the R/W bit set to 0, 1 byte of data to configure the internal register address pointer, one or more bytes of data, and a STOP condition. Figure 7 illustrates the proper frame format for writing 1 byte of data to the IC. The slave address with the R/W bit set to 0 indicates that the master intends to write data to the IC. The IC acknowledges receipt of the address byte during the master-generated ninth SCL pulse. The second byte transmitted from the master configures the IC’s internal register address pointer. The pointer tells the IC where to write the next byte of data. An acknowledge pulse is sent by the IC upon receipt of the address pointer data. The third byte sent to the IC contains the data that is written to the chosen register. An acknowledge pulse from the IC signals receipt of the data byte. Figure 8 illustrates how to write to multiple registers with one frame. The master signals the end of transmission by issuing a STOP condition. Read Data Format Send the slave address with the R/W bit set to 1 to initiate a read operation. The IC acknowledges receipt of its slave address by pulling SDA low during the ninth SCL clock pulse. A START command followed by a read command resets the address pointer to register 0x00. The first byte transmitted from the IC is the contents of register 0x00. Transmitted data is valid on the rising edge of the master-generated serial clock (SCL). The address pointer autoincrements after each read data byte. This autoincrement feature allows all registers to be read sequentially within one continuous frame. A STOP condition can be issued after any number of read data bytes. If a STOP condition is issued followed by another read operation, the first data byte to be read is from register 0x00 and subsequent reads autoincrement the address pointer until the next STOP condition. The address pointer can be preset to a specific register before a read command is issued. The master presets the address pointer by first sending the IC’s slave address with the R/W bit set to 0 followed by the register address. A Repeated START condition is then sent, followed by the slave address with the R/W bit set to 1. The IC transmits the contents of the specified register. The address pointer autoincrements after transmitting the first byte. Attempting to read from register addresses higher than 0xFF results in repeated reads of 0xFF. Note that 0xF6 to 0xFF are reserved registers. The master acknowledges receipt of each read byte during the acknowledge clock pulse. The master must acknowledge all correctly received bytes except the last byte. The final byte must be followed by a not acknowledge from the master and then a STOP condition. Figure 8 illustrates the frame format for reading 1 byte from the IC. Figure 9 illustrates the frame format for reading two registers consecutively without a STOP condition in between reads. ACKNOWLEDGE FROM MAX44000 B7 ACKNOWLEDGE FROM MAX44000 S SLAVE ADDRESS 0 R/W B6 B5 B4 B3 B2 B1 B0 ACKNOWLEDGE FROM MAX44000 A REGISTER ADDRESS A DATA BYTE A P 1 BYTE Figure 7. Writing 1 Byte of Data to the IC 20 Maxim Integrated MAX44000 Ambient and Infrared Proximity Sensor NOT ACKNOWLEDGE FROM MASTER ACKNOWLEDGE FROM MAX44000 ACKNOWLEDGE FROM MAX44000 S SLAVE ADDRESS 0 A REGISTER ADDRESS ACKNOWLEDGE FROM MAX44000 A Sr SLAVE ADDRESS REPEATED START R/W 1 DATA BYTE A R/W A P 1 BYTE Figure 8. Reading 1 Indexed Byte of Data from the IC NOT ACKNOWLEDGE FROM MASTER ACKNOWLEDGE FROM MAX44000 ACKNOWLEDGE FROM MAX44000 S SLAVE ADDRESS 0 A REGISTER ADDRESS 1 R/W ACKNOWLEDGE FROM MAX44000 A Sr SLAVE ADDRESS REPEATED START 1 DATA BYTE 1 A R/W A Sr 1 BYTE NOT ACKNOWLEDGE FROM MASTER S SLAVE ADDRESS 0 R/W ACKNOWLEDGE FROM MAX44000 ACKNOWLEDGE FROM MAX44000 ACKNOWLEDGE FROM MAX44000 A REGISTER ADDRESS 2 A REPEATED START Sr SLAVE ADDRESS 1 R/W A DATA BYTE 2 A P 1 BYTE Figure 9. Reading Two Registers Consecutively Without a STOP Condition Between Reads Maxim Integrated 21 MAX44000 Ambient and Infrared Proximity Sensor Typical Applications Circuit VLED = 1.7V TO 3.6V 1.7V TO 3.6V 1.7V TO 3.6V 1µF 10kI IR LED 10kI 10kI VDD SDA SDA GND SCL SCL MAX44000 DRV INT INT SDA SCL I2C SLAVE_1 22 SDA µC (I2C MASTER) SCL I2C SLAVE_1 Maxim Integrated MAX44000 Ambient and Infrared Proximity Sensor Package Information For the latest package outline information and land patterns (footprints), go to www.maxim-ic.com/packages. Note that a “+”, “#”, or “-” in the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the package regardless of RoHS status. PACKAGE TYPE PACKAGE CODE OUTLINE NO. LAND PATTERN NO. 6 OTDFN-EP D622N+2 21-0490 90-0344 Maxim Integrated 23 MAX44000 Ambient and Infrared Proximity Sensor Revision History REVISION NUMBER REVISION DATE 0 10/11 DESCRIPTION Initial release PAGES CHANGED — Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time. The parametric values (min and max limits) shown in the Electrical Characteristics table are guaranteed. Other parametric values quoted in this data sheet are provided for guidance. 24 ©  Maxim Integrated Maxim Integrated 160 Rio Robles, San Jose, CA 95134 USA 1-408-601-1000 The Maxim logo and Maxim Integrated are trademarks of Maxim Integrated Products, Inc.