MAX1632AEAI Datasheet, PDF(16/29 Page) Maxim Integrated Products – Multi-Output, Low-Noise Power-Supply Controllers for Notebook Computers

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MAX1632AEAI Datasheet, PDF (16/29 Pages) Maxim Integrated Products – Multi-Output, Low-Noise Power-Supply Controllers for Notebook Computers

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Multi-Output, Low-Noise Power-Supply

Controllers for Notebook Computers

Discharging the output capacitor through the main

inductor causes the output to momentarily go below

GND. Clamp this negative pulse with a back-biased 1A

Schottky diode across the output capacitor (Figure 1).

To ensure overvoltage protection on initial power-up,

connect signal diodes from both output voltages to VL

(cathodes to VL) to eliminate the VL power-up delay.

This circuitry protects the load from accidental overvolt-

age caused by a short-circuit across the high-side

power MOSFETs. This scheme relies on the presence

of a fuse, in series with the battery, which is blown by

the resulting crowbar current. Note that the overvoltage

circuitry will interfere with external keep-alive supplies

that hold up the outputs (such as lithium backup or hot-

swap power supplies); in such cases, the MAX1633A,

MAX1634A, or MAX1635A should be used.

Low-Noise Operation (PWM Mode)

PWM mode (SKIP = high) minimizes RF and audio

interference in noise-sensitive applications (such as hi-

fi multimedia-equipped systems), cellular phones, RF

communicating computers, and electromagnetic pen-

entry systems. See the summary of operating modes in

Table 2. SKIP can be driven from an external logic

signal.

Interference due to switching noise is reduced in PWM

mode by ensuring a constant switching frequency, thus

concentrating the emissions at a known frequency out-

side the system audio or IF bands. Choose an oscillator

frequency for which switching frequency harmonics do

not overlap a sensitive frequency band. If necessary,

synchronize the oscillator to a tight-tolerance external

clock generator. To extend the output-voltage-regula-

tion range, constant operating frequency is not main-

tained under overload or dropout conditions (see the

Overload and Dropout Operation section.)

PWM mode (SKIP = high) forces two changes upon the

PWM controllers. First, it disables the minimum-current

comparator, ensuring fixed-frequency operation.

Second, it changes the detection threshold for reverse-

current limit from 0mV to -100mV, allowing the inductor

current to reverse at light loads. This results in fixed-

frequency operation and continuous inductor-current

flow. This eliminates discontinuous-mode inductor ring-

ing and improves cross regulation of transformer-

coupled multiple-output supplies, particularly in circuits

that do not use additional secondary regulation through

SECFB or VDD.

In most applications, tie SKIP to GND to minimize qui-

escent supply current. VL supply current with SKIP high

is typically 20mA, depending on external MOSFET gate

capacitance and switching losses.

Internal Digital Soft-Start Circuit

Soft-start allows a gradual increase of the internal cur-

rent-limit level at startup to reduce input surge currents.

Both SMPSs contain internal digital soft-start circuits,

each controlled by a counter, a digital-to-analog con-

verter (DAC), and a current-limit comparator. In shut-

down or standby mode, the soft-start counter is reset to

zero. When an SMPS is enabled, its counter starts

counting oscillator pulses, and the DAC begins incre-

menting the comparison voltage applied to the current-

limit comparator. The DAC output increases from 0mV to

100mV in five equal steps as the count increases to 512

clocks. As a result, the main output capacitor charges

up relatively slowly. The exact time of the output rise

depends on output capacitance and load current, and

is typically 1ms with a 300kHz oscillator.

Dropout Operation

Dropout (low input-output differential operation) is

enhanced by stretching the clock pulse width to

increase the maximum duty factor. The algorithm fol-

lows: If the output voltage (VOUT) drops out of regula-

tion without the current limit having been reached, the

SMPS skips an off-time period (extending the on-time).

At the end of the cycle, if the output is still out of regula-

tion, the SMPS skips another off-time period. This

action can continue until three off-time periods are

skipped, effectively dividing the clock frequency by as

much as four.

The typical PWM minimum off-time is 300ns, regardless

of the operating frequency. Lowering the operating fre-

quency raises the maximum duty factor above 98%.

Adjustable-Output Feedback

(Dual Mode FB)

Fixed, preset output voltages are selected when FB_ is

connected to ground. Adjusting the main output volt-

age with external resistors is simple for any of the

MAX1630A family ICs, through resistor-dividers con-

nected to FB3 and FB5 (Figure 2). Calculate the output

voltage with the following formula:

VOUT = VREF (1 + R1 / R2)

where VREF = 2.5V nominal.

The nominal output should be set approximately 1% or

2% high to make up for the MAX1630Aâs -2% typical

load-regulation error. For example, if designing for a

3.0V output, use a resistor ratio that results in a nominal

output voltage of 3.05V. This slight offsetting gives the

best possible accuracy. Recommended normal values

nominal output, connect FB_ directly to CSL_.

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