ISL6329 Datasheet, PDF(22/38 Page) Intersil Corporation – Dual PWM Controller Powering AMD SVI Split-Plane Processors

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ISL6329 Datasheet, PDF (22/38 Pages) Intersil Corporation – Dual PWM Controller Powering AMD SVI Split-Plane Processors

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ISL6329

the lower MOSFET to control the output voltage until the

overvoltage event ceases or the input power supply cuts off. For

complete protection, the low side MOSFET should have a gate

threshold well below the maximum voltage rating of the

load/microprocessor.

In the event that during normal operation if the PVCC, VCC or

GVOT voltage falls back below the POR threshold, the pre-POR

overvoltage protection circuitry reactivates to protect from any

more pre-POR overvoltage events.

Undervoltage Detection

The undervoltage threshold is set at VDAC - 300mV typical. When

the output voltage (VSEN-RGND) is below the undervoltage

threshold, PGOOD gets pulled low. No other action is taken by the

controller. PGOOD will return high if the output voltage rises

above VDAC - 250mV typical.

Overcurrent Protection

The ISL6329 takes advantage of the proportionality between the

load current and the average current, IAVG, to detect an

overcurrent condition. See âContinuous Current Samplingâ on

page 14 and âChannel-Current Balanceâ on page 15 for more

detail on how the average current is measured. Once the average

current exceeds 100ÂµA, a comparator triggers the converter to

begin overcurrent protection procedures.

The overcurrent trip threshold is dictated by the DCR of the

inductors, the number of active channels, the DC gain of the

inductor RC filter and the RISEN resistor. The overcurrent trip

threshold is shown in Equation 21.

IOCP

100

Î¼

N---

-R----I--S----E----N--

DCR

ââ

V-----I--N-----â----N------Ã------V----O----U-----T-

2 Ã L Ã fS

-V---V-O---I-U-N---T--â ââ

(EQ. 21)

Where:

K = -------R-----2--------

R1 + R2

See âContinuous Current Samplingâ on

page 14.

fS = Switching Frequency

Equation 21 is valid for both the Core regulator and the

Northbridge regulator. This equation includes the DC load current

as well as the total ripple current contributed by all the phases.

For the Northbridge regulator, N is 1.

During soft-start, the overcurrent trip point is boosted by a factor

of 1.4. Instead of comparing the average measured current to

100ÂµA, the average current is compared to 140ÂµA. Immediately

after soft-start is over, the comparison level changes to 100ÂµA.

This is done to allow for start-up into an active load while still

supplying output capacitor in-rush current.

OVERCURRENT PROTECTION SHUTDOWN

At the beginning of overcurrent shutdown, the controller sets all

of the UGATE and LGATE signals low, puts PWM3, PWM4, PWM5,

and PWM6 (if active) in a high-impedance state, and forces

VDDPWRGD low. This turns off all of the upper and lower

MOSFETs. The system remains in this state for fixed period of

12ms. If the controller is still enabled at the end of this wait

period, it will attempt a soft-start, as shown in Figure 14. If the

fault remains, the trip-retry cycles will continue until either the

fault is cleared or for a total of seven attempts. If the fault is not

cleared on the final attempt, the controller disables UGATE and

LGATE signals for both Core and Northbridge and latches off

requiring a POR of VCC to reset the ISL6329.

OUTPUT CURRENT, 50A/DIV

OUTPUT VOLTAGE,

500mV/DIV

3ms/DIV

FIGURE 14. OVERCURRENT BEHAVIOR IN HICCUP MODE

It is important to note that during soft-start, the overcurrent trip

point is increased by a factor of 1.4. If the fault draws enough

current to trip overcurrent during normal run mode, it may not

draw enough current during the soft-start ramp period to trip

overcurrent while the output is ramping up. If a fault of this type

is affecting the output, then the regulator will complete soft-start

and the trip-retry counter will be reset to zero. Once the regulator

has completed soft-start, the overcurrent trip point will return to

itâs nominal setting and an overcurrent shutdown will be initiated.

This will result in a continuous hiccup mode.

Note that the energy delivered during trip-retry cycling is much

less than during full-load operation, so there is no thermal

hazard.

CORE REGULATOR OVERCURRENT

The ISL6329 features a Dual Overcurrent Protection (OCP)

feature on the Core that allows AMD processors to âthrottleâ the

load current beyond the normal OCP threshold for brief periods of

time. These current spikes occur when idle processor cores are

enabled. Dual OCP is not enabled until soft-start is complete.

When the Core average sensed current, IAVG, exceeds 100Î¼A, the

Core regulator does not immediately initiate overcurrent

protection shutdown. The ISL6329 will, instead, source an

amount of current out of the OCP pin that is equivalent to the

amount of sensed current that exceeds 100Î¼A. A capacitor tied

between the OCP pin and ground will immediately begin

charging. If the voltage across the capacitor, and thus the voltage

on the OCP pin, exceeds 2V then the ISL6329 will immediately

initiate overcurrent protection shutdown. If IAVG decreases to a

level below 100Î¼A prior to the voltage on the OCP pin exceeding

2V, then the OCP pin is internally pulled to ground and the

voltage on the OCP capacitor is discharged. If, at any time, the

average sensed current exceeds 145Î¼A, the ISL6329 will

immediately initiate overcurrent protection shutdown.

It is recommended that the maximum current spike correspond

to an average sensed current level of 120Î¼A. It is also

FN7800.0

April 19, 2011

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