ISL29028 Datasheet, PDF(10/15 Page) Intersil Corporation – Low Power Ambient Light and Proximity Sensor with Intelligent Interrupt

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ISL29028 Datasheet, PDF (10/15 Pages) Intersil Corporation – Low Power Ambient Light and Proximity Sensor with Intelligent Interrupt

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ISL29028

Interrupt Function

The ISL29028 has an intelligent interrupt scheme

designed to shift some logic processing away from

intensive microcontroller I2C polling routines (which

consume power) and towards a more independent light

sensor which can instruct a system to âwake upâ or âgo

to sleepâ.

An ALS interrupt event (ALS_FLAG) is governed by

Registers 5 through 7. The user writes a high and low

threshold value to these registers and the ISL29028 will

issue an ALS interrupt flag if the actual count stored in

Registers 0x9 and 0xA are outside the userâs programmed

window. The user must write 0 to clear the ALS_FLAG.

A proximity interrupt event (PROX_FLAG) is governed by

the high and low thresholds in registers 3 and 4

(PROX_LT and PROX_HT). PROX_FLAG is set when the

measured proximity data is more than the higher

threshold X-times-in-a-row (X is set by user; see next

paragraph). The proximity interrupt flag is cleared when

the prox data is lower than the low proximity threshold

X-times-in-a-row, or when the user writes â0â to

PROX_FLAG.

Interrupt persistency is another useful option available

for both ALS and proximity measurements. Persistency

requires X-in-a-row interrupt flags before the INT pin is

driven low. Both ALS and Prox have their own

independent interrupt persistency options. See

ALS_PRST and PROX_PRST bits in Register 2.

The final interrupt option is the ability to AND or OR the

two interrupt flags using Register 2 Bit 0 (INT_CTRL). If

the user wants both ALS/Prox interrupts to happen at the

same time before changing the state of the interrupt pin,

set this bit high. If the user wants the interrupt pin to

change state when either the ALS or the Proximity

interrupt flag goes high, leave this bit to its default of 0.

VDD Power-up and Power Supply

Considerations

Upon power-up, please ensure a VDD slew rate of

0.5V/ms or greater. After power-up, or if the userâs power

supply temporarily deviates from our specification (2.25V

to 3.63V), Intersil recommends the user write 0x00 to

three registers: 0x0E, 0x0F, and 0x01 (in that order),

wait ~1ms or more and then rewrite all registers to the

desired values. If the user prefers a hardware reset

method instead of writing to test registers: set VDD = 0V

for 1 second or more, power back up at the required slew

rate, and write registers to the desired values.

Power-Down

To put the ISL29028 into a power-down state, the user

can set both PROX_EN and ALS_EN bits to 0 in Register 1.

Or more simply, set all of Register 1 to 0x00.

Calculating Lux

The ISL29028âs ADC output codes are directly proportional

to lux when in ALS mode (see ALSIR_MODE bit).

Ecalc = Î±RANGE Ã OUTADC

(EQ. 2)

In Equation 2, Ecalc is the calculated lux reading and OUT

represents the ADC code. The constant Î± to plug in is

determined by the range bit ALS_RANGE (register 0x1

bit 1) and is independent of the light source type.

TABLE 15. ALS SENSITIVITY AT DIFFERENT RANGES

ALS_RANGE

Î±RANGE

(Lux/Count)

0.0326

0.522

Table 15 shows two different scale factors: one for the

low range (ALS_RANGE = 0) and the other for the high

range (ALS_RANGE = 1).

Noise Rejection

Charge balancing ADCâs have excellent noise-rejection

characteristics for periodic noise sources whose

frequency is an integer multiple of the conversion rate.

For instance, a 60Hz AC unwanted signalâs sum from 0ms

to k*16.66ms (k = 1,2...ki) is zero. Similarly, setting the

deviceâs integration time to be an integer multiple of the

periodic noise signal greatly improves the light sensor

output signal in the presence of noise. Since wall sockets

may output at 60Hz or 50Hz, our integration time is

100ms: the lowest common integer number of cycles for

both frequencies.

Proximity Detection of Various Objects

Proximity sensing relies on the amount of IR reflected

back from objects. A perfectly black object would

absorb all light and reflect no photons. The ISL29028 is

sensitive enough to detect black ESD foam which

reflects only 1% of IR. For biological objects, blonde

hair reflects more than brown hair and customers may

notice that skin tissue is much more reflective than hair.

IR penetrates into the skin and is reflected or scattered

back from within. As a result, the proximity count peaks

at contact and monotonically decreases as skin moves

away. The reflective characteristics of skin are very

different from that of paper.

Typical Circuit

A typical application for the ISL29028 is shown in

Figure 5. The ISL29028âs I2C address is internally

hardwired as 0b100010<x>, with x representing the

logic state of input I2C address pin ADDR0. The device

can be tied onto a systemâs I2C bus together with other

I2C compliant devices.

Soldering Considerations

Convection heating is recommended for reflow soldering;

direct-infrared heating is not recommended. The plastic

ODFN package does not require a custom reflow

soldering profile, and is qualified to +260Â°C. A standard

reflow soldering profile with a +260Â°C maximum is

recommended.

(http://www.intersil.com/data/tb/TB477.pdf)

FN6780.1

March 2, 2010

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