MAX15023 Datasheet, PDF(12/28 Page) Maxim Integrated Products – Wide 4.5V to 28V Input, Dual-Output Synchronous Buck Controller

English

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

MAX15023 Datasheet, PDF (12/28 Pages) Maxim Integrated Products – Wide 4.5V to 28V Input, Dual-Output Synchronous Buck Controller

◁

Wide 4.5V to 28V Input, Dual-Output

Synchronous Buck Controller

Detailed Description

The MAX15023 dual, synchronous, step-down con-

troller operates from a 5.5V to 28V or 5V Â±10% input

voltage range and generates two independent output

voltages. As long as the controllerâs input bias voltage

is within the specified range, the input power bus can

also be lower than 4.5V and step-down conversion

from a 3.3V rail is also possible. Both output voltages

can be set from 0.6V to 85% of regulatorâs input volt-

age. Each output can support loads of 12A or higher.

The switching sequence of the regulators is interleaved

with 180Â° out-of-phase operation, so that input voltage

ripple and total RMS input ripple current are reduced.

Enable inputs with precise turn-on/off threshold

(Â±4.2%) allow accurate external UVLO settings. Power-

good (PGOOD) open-drain outputs can be used for

supply sequencing.

The MAX15023âs capability to provide low output volt-

ages (down to 0.6V) and high output current (in excess

of 12A) makes it ideal for applications where a 5V or

12V bus is postregulated to deliver low voltages and

high currents, such as in set-top boxes.

The switching frequency is adjustable from 200kHz to

1MHz using an external resistor. The MAX15023âs

adaptive synchronous rectification eliminates the need

for external freewheeling Schottky diodes.

The MAX15023 utilizes voltage-mode control and exter-

nal compensation. The device also utilizes cycle-by-

cycle low-side source peak current limit for overcurrent

protection, where the external low-side MOSFETâs on-

resistance is used as a current-sense element during

the inductor freewheeling time, eliminating the need for

a current-sense resistor. The current-limit threshold

voltage is resistor adjustable independently on each

regulator from 30mV to 300mV and is temperature

compensated, so that the effects of the MOSFETâs

RDS(ON) variation over temperature are reduced.

Hiccup-mode current limit reduces average current

and power dissipation during a prolonged short-circuit

condition.

The MAX15023 also features a proprietary adaptive

internal digital soft-start and allows prebias startup

without discharging the output. Adaptive digital soft-

start, by acting on the loop voltage reference, automati-

cally prolongs the soft-start time, if the current-limit

threshold is reached during the soft-start sequence.

This increases the ability to smoothly bring up a large,

unknown amount of output capacitance. Also, since

soft-start is invoked during hiccup-mode short-circuit

protection, the same voltage reference rollback algo-

rithm achieves good control of the peak inductor cur-

rent during steady short-circuit or overload conditions.

An additional protection feature (cycle-by-cycle low-

side sink peak current limit) prevents the regulators from

sinking excessive amount of current if the prebias volt-

age exceeds the programmed steady-state regulation

level, or if another voltage source is trying to force the

output above that. This way, the synchronous rectifier

MOSFET and the body diode of the high-side MOSFET

do not experience dangerous levels of current stress

while the regulator is sinking current from the output.

Thermal shutdown protects the MAX15023 from exces-

sive power dissipation.

DC-DC PWM Controller

The MAX15023 step-down controller uses a PWM volt-

age-mode control scheme (see the Functional

Diagram) for each channel. Control loop compensation

is external for providing maximum flexibility in choosing

the operating frequency and output LC filter compo-

nents. An internal transconductance error amplifier pro-

duces an integrated error voltage at COMP_ that helps

provide higher DC accuracy. The voltage at COMP_

sets the duty cycle using a PWM comparator and a

ramp generator. On the rising edge of its internal clock,

the high-side n-channel MOSFET of each regulator

turns on and remains on until either the appropriate

duty cycle or the maximum duty cycle is reached.

During the high-side MOSFETâs on-time, the inductor

current ramps up. During the second-half of the switch-

ing cycle, the high-side MOSFET turns off and the low-

side n-channel MOSFET turns on. Now the inductor

releases the stored energy as its current ramps down,

providing current to the output. Under overload condi-

tions, when the inductor current exceeds the selected

cycle-by-cycle low-side source peak current-limit

threshold (see the Current-Limit Circuit (LIM_) section),

the high-side MOSFET does not turn on at the subse-

quent clock rising edge and the low-side MOSFET

remains on to let the inductor current ramp down.

Interleaved Out-of-Phase Operation

The two independent regulators in the MAX15023 oper-

ate 180Â° out-of-phase to reduce input filtering require-

ments, reduce electromagnetic interference (EMI), and

improve efficiency. This effectively lowers component

cost and saves board space, making the MAX15023

ideal for cost-sensitive applications.

12 ______________________________________________________________________________________

▷