MAX1652 Datasheet, PDF(10/28 Page) Maxim Integrated Products – High-Efficiency, PWM, Step-Down DC-DC Controllers in 16-Pin QSOP

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MAX1652 Datasheet, PDF (10/28 Pages) Maxim Integrated Products – High-Efficiency, PWM, Step-Down DC-DC Controllers in 16-Pin QSOP

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High-Efficiency, PWM, Step-Down

DC-DC Controllers in 16-Pin QSOP

Standard Application Circuits

Itâs easy to adapt the basic MAX1653 single-output 3.3V

buck converter (Figure 1) to meet a wide range of appli-

cations with inputs up to 30V (limited by choice of exter-

nal MOSFET). Simply substitute the appropriate

components from Table 1 (candidate suppliers are pro-

vided in Table 2). These circuits represent a good set of

trade-offs among cost, size, and efficiency while staying

within the worst-case specification limits for stress-relat-

ed parameters such as capacitor ripple current.

Donât change the frequency of these circuits without

first recalculating component values (particularly induc-

tance value at maximum battery voltage).

For a discussion of dual-output circuits using the

MAX1652 and MAX1654, see Figure 9 and the

Secondary Feedback-Regulation Loop section.

Detailed Description

The MAX1652 family are BiCMOS, switch-mode power-

supply controllers designed primarily for buck-topology

regulators in battery-powered applications where high

efficiency and low quiescent supply current are critical.

The parts also work well in other topologies such as

boost, inverting, and Cuk due to the flexibility of their

floating high-speed gate driver. Light-load efficiency is

enhanced by automatic idle-mode operationâa vari-

able-frequency pulse-skipping mode that reduces

losses due to MOSFET gate charge. The step-down

power-switching circuit consists of two N-channel

MOSFETs, a rectifier, and an LC output filter. The out-

put voltage is the average of the AC voltage at the

switching node, which is adjusted and regulated by

changing the duty cycle of the MOSFET switches. The

gate-drive signal to the N-channel high-side MOSFET

must exceed the battery voltage and is provided by a

flying capacitor boost circuit that uses a 100nF capaci-

tor connected to BST.

INPUT

0.1ÂµF

V+

CMPSH-3

4.7ÂµF

ON/OFF

SHDN

DH 16

CONTROL

BST 14

LOW-NOISE

CONTROL

SKIP

MAX1653

LX 15

0.1ÂµF

DL 13

0.01ÂµF

(OPTIONAL)

NOTE: KEEP CURRENT-SENSE

LINES SHORT AND CLOSE

TOGETHER. SEE FIGURE 8.

PGND 12

SYNC

CSH

CSL

GND

REF

150kHz/300kHz

JUMPER

0.33ÂµF

Figure 1. Standard 3.3V Application Circuit (see Table 1 for Component Values)

+5V AT

5mA

+3.3V

OUTPUT

GND

OUT

REF OUTPUT

+2.5V AT 100ÂµA

10 ______________________________________________________________________________________

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