ISL29147_15 Datasheet, PDF(10/15 Page) Intersil Corporation – Low Power Ambient Light and Proximity Sensor with Enhanced Infrared Rejection

English

English German Russian Spanish Italian Polish Chinese Japanese Korean French Portuguese	Language :

ISL29147_15 Datasheet, PDF (10/15 Pages) Intersil Corporation – Low Power Ambient Light and Proximity Sensor with Enhanced Infrared Rejection

◁

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 âALS IR Compensationâ on page 11.

they are used primarily to indicate interrupt events from proximity

and ALS measurements. A PWR_FAIL bit to indicate a âBrown-Outâ

event is available and is set in case of a power supply interruption. A

âBrown-Outâ event does not generate a hardware interrupt. The host

microcontroller must clear this bit by writing a â0â to Reg 0x04[4].

interrupt persistency and the operation of the INT pin.

Registers 0x05 and 0x06 are used to set the proximity âLOWâ and

âHIGHâ threshold for proximity interrupt event generation.

Registers 0x07, 0x08 and 0x09 are used to set the ALS âLOWâ

and âHIGHâ 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 âWashoutâ 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.

measurement phase. This measurement is for detecting ambient

Wash out condition, which is indicated by Reg 0x0D[0] being âHIGHâ.

Proximity âWashoutâ is described in âProximity Ambient Washout

Detectionâ 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 eyeâs wavelength response curve to visible light.

The ALS photodiodesâ 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 Â±15% from nominal. The

ALS integration time is intended to minimize 60Hz flicker.

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.

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 90Âµs by the built-in IR LED driver through the

IRDR pin.

ALS CONVERSION TIME =

90ms (FIXED)

SEVERAL Âµs BETWEEN

CONVERSIONS

ALS

ACTIVE

90ms

PROX

SENSOR

ACTIVE

90ms

0.50ms FOR PROX

CONVERSION

90ms

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 90Î¼s 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.

IlRDR;AVE = I--l--R----D----R----T-;-P--S--E--L--A-E---K-E----Pï´-----9---0----ï----s-

(EQ. 1)

A typical IRDR scheme is 250mA pulses every 400ms, averaging

about 56Î¼A DC.

Submit Document Feedback 10

FN8409.3

January 6, 2015

▷