MAX1692 Datasheet, PDF(8/12 Page) Maxim Integrated Products – Low-Noise, 5.5V-Input, PWM Step-Down Regulator

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MAX1692 Datasheet, PDF (8/12 Pages) Maxim Integrated Products – Low-Noise, 5.5V-Input, PWM Step-Down Regulator

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Low-Noise, 5.5V-Input,

PWM Step-Down Regulator

amounts of reverse current to flow from the output dur-

ing light loads. This allows regulation with a constant-

switching frequency and eliminates minimum load

requirements. The NEGLIM comparator threshold is

50mA if VFB < 1.25V, and decreases as VFB exceeds

1.25V to prevent the output from rising. The NEGLIM

threshold in PFM mode is fixed at 50mA. (See Forced

PWM and PWM/PFM Operation section.)

Forced PWM and PWM/PFM Operation

Connect SYNC/PWM to IN for normal forced PWM

operation. Forced PWM operation is desirable in sensi-

tive RF and data-acquisition applications, to ensure that

switching-noise harmonics do not interfere with sensi-

tive IF and data-sampling frequencies. A minimum load

is not required during forced PWM operation, since the

synchronous rectifier passes reverse-inductor current

as needed to allow constant-frequency operation with

no load. Forced PWM operation uses higher supply

current with no load (2mA typ).

Connecting SYNC/PWM to GND enables PWM/PFM

operation. This proprietary control scheme overrides

PWM mode and places the MAX1692 in PFM mode at

light loads to improve efficiency and reduce quiescent

current to 85ÂµA. With PWM/PFM enabled, the MAX1692

initiates pulse-skipping PFM operation when the peak

inductor current drops below 120mA. During PFM oper-

ation, the MAX1692 switches only as needed to service

the load, reducing the switching frequency and associ-

ated losses in the internal switch, the synchronous rec-

tifier, and the external inductor.

During PFM mode, a switching cycle initiates when the

PFM comparator senses that the output voltage has

dropped too low. The P-channel MOSFET switch turns

on and conducts current to the output-filter capacitor

and load until the inductor current reaches the PFM

peak current limit (120mA). Then the switch turns off

and the magnetic field in the inductor collapses, forcing

current through the synchronous rectifier to the output

filter capacitor and load. Then the MAX1692 waits until

the PFM comparator senses a low output voltage again.

The PFM current comparator controls both entry into

PWM mode and the peak switching current during PFM

mode. Consequently, some jitter is normal during tran-

sition from PFM to PWM modes with loads around

100mA, and it has no adverse impact on regulation.

Output ripple is higher during PFM operation. A larger

output-filter capacitor can be used to minimize ripple.

SYNC Input and Frequency Control

The MAX1692âs internal oscillator is set for a fixed-

switching frequency of 750kHz or can be synchronized

to an external clock. Connect SYNC to IN for forced-

PWM operation. Do not leave SYNC/PWM unconnect-

ed. Connecting SYNC/PWM to GND enables PWM/PFM

operation to reduce supply current at light loads.

SYNC/PWM is a negative-edge triggered input that

allows synchronization to an external frequency ranging

between 500kHz and 1000kHz. When SYNC/PWM is

clocked by an external signal, the converter operates in

forced PWM mode. If SYNC is low or high for more than

100Âµs, the oscillator defaults to 750kHz.

Shutdown Mode

Connecting SHDN to GND places the MAX1692 in

shutdown mode. In shutdown, the reference, control

circuitry, internal switching MOSFET, and the synchro-

nous rectifier turn off and the output falls to 0V. Connect

SHDN to IN for normal operation.

Current-Sense Comparators

The MAX1692 uses several internal current-sense com-

parators. In PWM operation, the PWM comparator sets

the cycle-by-cycle current limit (Figure 1) and provides

improved load and line response, allowing tighter spec-

ification of the inductor-saturation current limit to

reduce inductor cost. A second 120mA current-sense

comparator used across the P-channel switch controls

entry into PFM mode. A third current-sense comparator

monitors current through the internal N-channel MOSFET

to set the NEGLIM threshold and determine when to turn

off the synchronous rectifier. A fourth comparator (LIM)

used at the P-channel MOSFET switch detects overcur-

rent. This protects the system, external components, and

internal MOSFETs under overload conditions.

Applications Information

Output Voltage Selection

Select an output voltage between 1.25V and VIN by

connecting FB to a resistor-divider between the output

and GND (Figure 2). Select feedback resistor R2 in the

5kâ¦ to 500kâ¦ range. R1 is then given by:

R1 = R2 [(VOUT / VFB) - 1]

where VFB = 1.232V (See Note 2 of the Electrical

Characteristics). Add a small ceramic capacitor (C5)

around 47pF to 100pF in parallel with R1 to compensate

for stray capacitance at the FB pin and output capacitor

equivalent series resistance (ESR).

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