AAT2842 Datasheet, PDF(12/21 Page) Advanced Analogic Technologies – High-Current Charge Pump with S2Cwire™ Control and Dual LDO for Backlight and Flash

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AAT2842 Datasheet, PDF (12/21 Pages) Advanced Analogic Technologies – High-Current Charge Pump with S2Cwire™ Control and Dual LDO for Backlight and Flash

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AAT2842

High-Current Charge Pump with S2Cwireâ¢

Control and Dual LDO for Backlight and Flash

Data

FL% of FSET

100

52.5

46.2

41.4

36.6

31.7

28.5

25.0

21.7

18.4

16.7

15.0

Table 2: Flash Current Register: FL1-FL4

(RFSET = 280kÎ©).

Shutdown

Since the sink switches are the only power returns

for all loads, there is no leakage current when all of

the sink switches are disabled. To activate the shut-

down mode, hold both the BENS and FENS inputs

low for longer than TBENS(OFF) or TFENS(OFF) (500Âµs).

In this state, the AAT2842 typically draws less than

1ÂµA from the input. Data and address registers are

reset to 0 in shutdown.

Low Dropout Regulators

The AAT2842 includes two LDO linear regulators.

The regulators run from the same 2.7V to 5.5V input

voltage as the charge pump. The regulators use a

single on/off control input, ENL. The LDO output

voltages are set through a resistive voltage divider

from the output (OUTA or OUTB) to the feedback

input (FBA or FBB). The ratio of resistor values

determines the LDO output voltage. The low 200mV

dropout voltage at 200mA load current allows the

regulator to maintain output voltage regulation.

Each LDO regulator can supply a continuous load

current up to 200mA. Both LDOs include current

limiting and thermal overload protection to prevent

damage to the load or to the LDOs.

Applications Information

LDO Output Voltage Programming

The output voltages for LDOA and LDOB are pro-

grammed by an external resistor divider network.

As shown in Figure 2, the selection of R1 and R2 is

a straightforward matter.

R1 is chosen by considering the tradeoff between

the feedback network bias current and resistor

value. Higher resistor values allow stray capaci-

tance to become a larger factor in circuit perform-

ance whereas lower resistor values increase bias

current and decrease efficiency.

OUTx

FBx

VREF = 1.2V

VOUT

Figure 2: Selection of External Resistors.

To select appropriate resistor values, first choose

R1 such that the feedback network bias current is

reasonable. Then, according to the desired VOUT,

calculate R2 according to the equation below. An

example calculation follows.

R1 is chosen to be 120K, resulting in a small feed-

back network bias current of 1.2V/120K = 10ÂµA.

The desired output voltage is 1.8V. From this infor-

mation, R2 is calculated from the equation below.

R2 =

R1(VOUT - 1.2)

1.2

The result is R2 = 60K. Since 60K is not a standard

1% value, 60.4K is selected. From this example

calculation, for VOUT = 1.8V, use R1 = 120K and R2

= 60.4K. Example output voltages and correspon-

ding resistor values are provided in Table 3.

2842.2006.10.1.0

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