ISL6523CB Intersil, ISL6523CB Datasheet - Page 7

ISL6523CB

Manufacturer Part Number

ISL6523CB

Description

IC CTRLR VRM8.5 PWM DUAL 28-SOIC

Manufacturer

Intersil

Datasheet

1.ISL6523CBZ.pdf (16 pages)

Specifications of ISL6523CB

Applications

Controller, Intel VRM8.5

Voltage - Input

5 ~ 15 V

Number Of Outputs

Operating Temperature

0°C ~ 70°C

Mounting Type

Surface Mount

Package / Case

28-SOIC (7.5mm Width)

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Voltage - Output

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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 chipset (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 chip’s power-on reset. Thus,

DRIVE4 is driven to raise the OUT4 voltage before the input

supplies reach their POR levels. As seen in Figure 5, 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 28µA current source

charges an external capacitor (C

about 4.5V. As the SS24 voltage increases, the PWM2 error

amplifier allows generation of PHASE pulses of increasing

width that charge the output capacitor(s), providing 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 oscillator’s

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

3.0V

10V

SS24

ATX 12V

ATX 3.3V

ATX 5V

FIGURE 5. SOFT-START INTERVAL

OUT4

(1.8V)

TIME

VTTPG

OUT3

SS24

PGOOD

(1.5V)

) on the SS24 pin to

SS13

OUT1

OUT2

(1.65V)

(1.2V)

ISL6523

above 1.08V, the first PWM pulse on PHASE1 triggers the

VTTPG pin to go high. The oscillator’s 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.

The T2 to T3 time interval is dependent upon the value of

up time of the OUT1 and OUT3 voltages. If selecting a

different capacitor then recommended in the circuit application

literature, consider the effects the different value will have on

the ramp-up time and inrush currents of the OUT1 and OUT3

outputs.

Fault Protection

All four outputs are monitored and protected against extreme

overload. The chip’s response to an output overload is

selective, depending on the faulting output.

An overvoltage on V

1, 2, and 3, and latches the IC off. An under-voltage on

on outputs 1 or 2, or an under-voltage event on output 3,

increments the respective fault counter and triggers a

shutdown of outputs 1, 2, and 3, followed by a soft-start re-

start. After three consecutive fault events on either counter,

the chip is latched off. Removal of bias power resets both the

fault latch and the counters. Both counters are also reset by

a successful start-up of all the outputs.

Figure 6 shows a simplified schematic of the fault logic. The

overcurrent latches are set dependent upon the states of the

overcurrent (OC1 and OC2), output 3 under-voltage (UV3)

and the soft-start signals (SS13, SS24). Window

comparators monitor the SS pins and indicate when the

respective C

signals). An under-voltage on either linear output (VSEN3 or

VSEN4) is ignored until the respective UP signal goes high.

This allows V

start-up. Following an overcurrent event (OC1, OC2, or UV3

event), bringing the SS24 pin below 0.8V resets the

OUT4

SS13

. The same capacitor is also responsible for the ramp-

output latches the IC off. A single overcurrent event

OUT3

pins are fully charged to above 4.0V (UP

and V

OUT1

OUT4

output (VSEN1) disables outputs

to increase without fault at

ISL6523CB Intersil, ISL6523CB Datasheet - Page 7

ISL6523CB

Specifications of ISL6523CB

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