ISL6524 Datasheet, PDF(7/16 Page) Intersil Corporation – VRM8.5 PWM and Triple Linear Power System Controller

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ISL6524 Datasheet, PDF (7/16 Pages) Intersil Corporation – VRM8.5 PWM and Triple Linear Power System Controller

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VOUT4 can only be set from 1.7V up) by way of an external

resistor divider connected at the corresponding VSEN pin. The

new output voltage set by the external resistor divider can be

determined using the following formula:

VOUT

1.265 V

ï£«

ï£¬1

ï£

R-R----GO-----NU----DT--ï£¸ï£·ï£¶

where ROUT is the resistor connected from VSEN to the

output of the regulator, and RGND is the resistor connected

from VSEN to ground. Left open, the FIX pin is pulled high,

enabling fixed output voltage operation.

DRIVE3 (Pin 18)

Connect this pin to the gate/base of a N-type external pass

transistor (MOSFET or bipolar). This pin provides the drive

for the 1.5V regulatorâs pass transistor.

VSEN3 (Pin 19)

Connect this pin to the output of the 1.5V linear regulator.

This pin is monitored for undervoltage events.

DRIVE4 (Pin 15)

Connect this pin to the base of an external bipolar transistor.

This pin provides the drive for the 1.8V regulatorâs pass

transistor.

VSEN4 (Pin 14)

Connect this pin to the output of the linear 1.8V regulator.

This pin is monitored for undervoltage events.

FAULT/RT (Pin 10)

This pin provides oscillator switching frequency adjustment.

By placing a resistor (RT) from this pin to GND, the nominal

200kHz switching frequency is increased according to the

following equation:

200

-5-----Ã-----1---0----6--

RT(kâ¦)

(RT to GND)

Conversely, connecting a resistor from this pin to VCC

reduces the switching frequency according to the following

equation:

200

-4-----Ã-----1---0----7--

RT(kâ¦)

(RT to 12V)

Nominally, the voltage at this pin is 1.26V. In the event of an

overvoltage or overcurrent condition, this pin is internally

pulled to VCC.

Description

Operation

The ISL6524 monitors and precisely controls 4 output voltage

levels (Refer to Figures 1, 2, 3). It is designed for

microprocessor computer applications with 3.3V, 5V, and 12V

bias input from an ATX power supply. The IC has one PWM

and three linear controllers. The PWM controller is designed to

regulate the microprocessor core voltage (VOUT1). The PWM

controller drives 2 MOSFETs (Q1 and Q2) in a synchronous-

rectified buck converter configuration and regulates the core

voltage to a level programmed by the 5-bit digital-to-analog

converter (DAC). The first linear controller (EA2) is designed to

provide the AGTL+ bus voltage (VOUT2) by driving a MOSFET

(Q3) pass element to regulate the output voltage to a level of

1.2V. The remaining two linear controllers (EA3 and EA4)

supply the 1.5V advanced graphics port (AGP) bus power

(VOUT3) and the 1.8V chip set core power (VOUT4).

Initialization

The ISL6524 automatically initializes in ATX-based systems

upon receipt of input power. The Power-On Reset (POR)

function continually monitors the input supply voltages. The

POR monitors the bias voltage (+12VIN) at the VCC pin, the

5V input voltage (+5VIN) at the OCSET pin, and the 3.3V

input voltage (+3.3VIN) at the VAUX pin. The normal level on

OCSET is equal to +5VIN less a fixed voltage drop (see

overcurrent protection). The POR function initiates soft-start

operation after all supply voltages exceed their POR

thresholds.

Soft-Start

The 1.8V supply designed to power the chip set (OUT4),

cannot lag the ATX 3.3V by more than 2V, at any time. To

meet this special requirement, the linear block controlling

this output operates independently of the chipâs power-on

reset. Thus, DRIVE4 is driven to raise the OUT4 voltage

before the input supplies reach their POR levels. As seen in

Figure 6, at time T0 the power is turned on and the input

supplies ramp up. Immediately following, OUT4 is also

ramped up, lagging the ATX 3.3V by about 1.8V. At time T1,

the POR function initiates the SS24 soft-start sequence.

Initially, the voltage on the SS24 pin rapidly increases to

approximately 1V (this minimizes the soft-start interval).

Then, an internal 28mA current source charges an external

capacitor (CSS24) on the SS24 pin to about 4.5V. As the

SS24 voltage increases, the EA2 error amplifier drives Q3 to

provide a smooth transition to the final set voltage. The

OUT4 reference (clamped to SS24) increasing past the

intermediary level, established based on the ATX 3.3V

presence at the VAUX pin, brings the output in regulation

soon after T2.

As OUT2 increases past the 90% power-good level, the second

soft-start (SS13) is released. Between T2 and T3, the SS13 pin

voltage ramps from 0V to the valley of the oscillatorâs triangle

wave (at 1.25V). Contingent upon OUT2 remaining above

1.08V, the first PWM pulse on PHASE1 triggers the VTTPG pin

to go high. The oscillatorâs triangular wave form is compared to

the clamped error amplifier output voltage. As the SS13 pin

voltage increases, the pulse-width on the PHASE1 pin

increases, bringing the OUT1 output within regulation limits.

Similarly, the SS13 voltage clamps the reference voltage for

OUT3, enabling a controlled output voltage ramp-up. At time

T4, all output voltages are within power-good limits, situation

reported by the PGOOD pin going high.

FN9015.3

April 18, 2005

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