MAX1587AETL-T Maxim Integrated Products, MAX1587AETL-T Datasheet - Page 24

MAX1587AETL-T

Manufacturer Part Number

MAX1587AETL-T

Description

Other Power Management PMICs w/Dynamic Core for PDAs

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX1587CETLT.pdf (30 pages)

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The LSB of the address word is the read/write (R/W) bit.

R/W indicates whether the master is writing or reading

(RD/W 0 = write, RD/W 1 = read). The MAX1586/

MAX1587 only support the SEND BYTE format; there-

fore, RD/W is required to be 0.

After receiving the proper address, the MAX1586/

MAX1587 issue an ACK by pulling SDA low for one

clock cycle. The MAX1586/MAX1587 have two user-

programmed addresses (Table 3). Address bits A7

through A2 are fixed, while A1 is controlled by SRAD.

Connecting SRAD to GND sets A1 = 0. Connecting

SRAD to IN sets A1 = 1.

When V3 is dynamically changed with the serial inter-

face, the output voltage changes at a rate controlled by

a capacitor (C

The voltage change is a conventional RC exponential

described by:

A useful approximation is that it takes approximately 2.2

RC time constants for V3 to move from 10% to 90% of

the voltage difference. For C

is 330µs. For 1V to 1.3V change, this equates to

1mV/µs. See the Typical Operating Characteristics for

examples of different ramp-rate settings.

The maximum capacitor value that can be used at

RAMP is 2200pF. If larger values are used, the V3 ramp

rate is still controlled according to the above equation,

but when V3 is first activated, POK indicates an “in reg-

ulation” condition before V3 reaches its final voltage.

The RAMP pin is effectively the reference for REG3.

FB3 regulates to 1.28 times the voltage on RAMP.

The outputs V1 and V2 have preset output voltages, but

can also be adjusted using a resistor voltage-divider. To

set V1 to 3.3V, connect FB1 to GND. V2 can be preset to

1.8V or 2.5V on the MAX1586A and MAX1587A. To set

V2 to 1.8V on the MAX1586A and MAX1587A, connect

FB2 to IN. To set to 2.5V, connect FB2 to GND. V2 can

preset to 3.3V or 2.5V on the MAX1587B. To set V2 to

3.3V on the MAX1587B, connect FB2 to IN. To set to

2.5V, connect FB2 to GND.

To set V1 or V2 to other than the preset output voltages,

connect a resistor voltage-divider from the output volt-

age to the corresponding FB input. The FB_ input bias

current is less than 100nA, so choose the low-side

(FB_-to-GND) resistor (R

culate the high-side (output-to-FB_) resistor (R

High-Efficiency, Low-I

Dynamic Core for PDAs and Smart Phones

Vo(t) = Vo(0) + dV(1 – exp(-t/(100kΩ C

______________________________________________________________________________________

RAMP

Setting the Output Voltages

) connected from RAMP to ground.

V3 Output Ramp-Rate Control

) to be 100kΩ or less. Then cal-

Design Procedure

RAMP

= 1500pF, this time

RAMP

) using:

)))

PMICs with

The V3 (VCC_CORE) output voltage is set from 0.7V to

1.475V in 25mV steps by the I

the Serial Interface section for details.

Linear regulator V4 provides a fixed 1.3V output volt-

age. Linear regulator V5 provides a fixed 1.1V output

voltage. V4 and V5 voltages are not adjustable.

The output voltage of linear regulator V6 (VCC_USIM) is

set to 0V, 1.8V, 2.5V, or 3.0V by the I

See the Serial Interface section for details.

Linear regulator V7 (VCC_BATT) tracks the voltage at

V1 as long as ON1 is high and V1 is in regulation. When

ON1 is low or V1 is not in regulation, V7 switches to the

backup battery (V

The external components required for the step-down

are an inductor, input and output filter capacitors, and a

compensation RC network.

The MAX1586/MAX1587 step-down converters provide

best efficiency with continuous inductor current. A rea-

sonable inductor value (L

This sets the peak-to-peak inductor current at 1/2 the

DC inductor current. D is the duty cycle:

Given L

is 0.5 x I

inductor exceeds the peak inductor current and the

rated maximum DC inductor current exceeds the maxi-

mum output current (I

larger than L

to obtain the maximum possible output current. Larger

inductance values accomplish this by supplying a

given load current with a lower inductor peak current.

Typically, output current and efficiency are improved

for inductor values up to about two times L

inductance is raised too much, however, the inductor

size may become too large, or the increased inductor

resistance may reduce efficiency more than the gain

derived from lower peak current.

Smaller inductance values allow smaller inductor sizes,

but also result in larger peak inductor current for a

given load. Larger output capacitance may then be

needed to suppress the increase in output ripple

caused by larger peak current.

The input capacitor in a DC-DC converter reduces cur-

rent peaks drawn from the battery or other input power

OUT(MAX)

IDEAL

OUT

. Make sure the saturation current of the

= [2(V

IDEAL

, the peak-to-peak inductor ripple current

. The peak inductor current is 1.25 x

BKBT

= R

can be used to optimize efficiency or

) x D(1 - D)]/(I

D = V

OUT(MAX)

[(V

IDEAL

OUT

Capacitor Selection

/ V

/1.25) – 1]

) is derived from:

Inductor Selection

C serial interface. See

). Inductance values

OUT(MAX)

C serial interface.

IDEAL

x f

OSC

. If the

)

MAX1587AETL-T Maxim Integrated Products, MAX1587AETL-T Datasheet - Page 24

MAX1587AETL-T

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