MAX1584 Datasheet, PDF(15/29 Page) Maxim Integrated Products

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MAX1584 Datasheet, PDF (15/29 Pages) Maxim Integrated Products – 5-Channel Slim DSC Power Supplies

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5-Channel Slim DSC Power Supplies

Step-Down DC-DC Converter

The step-down DC-DC converter is optimized for gen-

erating low output voltages (down to 1.25V) at high effi-

ciency. Output voltages lower than 1V can be set by

adding an additional resistor (see the Applications

Information section). The step-down runs from the volt-

age at PVSD. This pin can be connected directly to the

battery if sufficient headroom exists to avoid dropout;

otherwise, PVSD can be powered from the output of

another converter. The step-down can also operate

with the step-up for boost-buck operation.

Under moderate to heavy loading, the converter oper-

ates in a low-noise PWM mode with constant frequency

and modulated pulse width. Efficiency is enhanced

under light (<75mA typ) loading by assuming an idle

mode during which the step-down switches only as

needed to service the load. In this mode, the maximum

inductor current is 100mA for each pulse. The step-

down DC-DC is inactive until the step-up DC-DC is in

regulation.

The step-down also features an open-drain SDOK out-

put that goes low when the step-down output is in regu-

lation. SDOK can be used to drive an external MOSFET

switch that gates 3.3V power to the processor after the

core voltage is in regulation. This connection is shown

in Figure 13.

Boost-Buck Operation

The step-down input can be powered from the output

of the step-up. By cascading these two channels, the

step-down output can maintain regulation even as the

battery voltage falls below the step-down output volt-

age. This is especially useful when trying to generate

3.3V from 1-cell Li+ inputs, or 2.5V from 2-cell alkaline

or NiMH inputs, or when designing a power supply that

must operate from both Li+ and alkaline/NiMH inputs.

Compound efficiencies of up to 90% can be achieved

when the step-up and step-down are operated in

series.

Note that the step-up output supplies both the step-up

load and the step-down input current when the step-

down is powered from the step-up. The step-down

input current reduces the available step-up output cur-

rent for other loads.

Direct Battery Step-Down Operation

The step-down converter can also be operated directly

from the battery as long as the voltage at PVSD does

not exceed PVSU by more than a Schottky diode for-

ward voltage. When using this connection, connect an

external Schottky diode from the battery input to PVSU.

On the MAX1584/MAX1585, there is an internal 10kâ¦

resistance from PVSU to PVSD. This adds a small addi-

tional current drain (of approximately (VPVSU - VPVSD) /

10kâ¦) from PVSU when PVSD is not connected directly

to PVSU.

Step-down direct battery operation improves efficiency

for the step-down output (up to 95%), but restricts the

upper limit of the output voltage to 200mV less than the

minimum battery voltage. In 1-cell Li+ designs (with a

2.7V min), the output can be set up to 2.5V. In 2-cell

alkaline or NiMH designs, the output can be limited to

1.5V or 1.8V, depending on the minimum-allowed cell

voltage.

The step-down can only be briefly operated in dropout

since the MAX1584/MAX1585 fault protection detects

the out-of-regulation condition and activates after

100,000 OSC cycles (200ms at fOSC = 500kHz). At that

point, all MAX1584/MAX1585 channels shut down.

AUX1, AUX2, and AUX3 DC-DC Controllers

The three auxiliary controllers operate as fixed-frequen-

cy voltage-mode PWM controllers. They do not have

internal MOSFETs, so output power is determined by

external components. The controllers regulate output

voltage by modulating the pulse width of the DL_ drive

signal to an external MOSFET switch. The MAX1584

contains two step-up/flyback controllers (AUX1 and

AUX2) and one step-down controller (AUX3). The

MAX1585 contains one step-up controller (AUX1), one

inverting controller (AUX2), and one step-down con-

troller (AUX3).

Figure 3 shows a functional diagram of the AUX con-

trollers. The inverting and step-down controllers differ

from the step-up controllers only in the gate-drive logic

and FB polarity and threshold. The sawtooth oscillator

signal at OSC governs timing. At the start of each

cycle, DL_ turns on the external MOSFET switch. For

step-up controllers, DL_ goes high, while for inverting

and step-down controllers, DL_ goes low (to turn on

PFETs). The external MOSFET then turns off when the

internally level-shifted sawtooth rises above CC_ or

when the maximum duty cycle is exceeded. The switch

remains off until the start of the next cycle. A transcon-

ductance error amplifier forms an integrator at CC_ so

that high DC loop gain and accuracy can be main-

tained. In step-up and step-down controllers, the FB_

threshold is 1.25V, and higher FB_ voltages reduce the

MOSFET duty cycle. In inverting controllers, the FB_

threshold is 0V, and lower (more negative) FB_ volt-

ages reduce the MOSFET duty cycle.

Auxiliary controllers do not start until the step-up DC-DC

output is in regulation. If the step-up, step-down, or any

of the auxiliary controllers remains faulted for 100,000

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