ISL6313B Intersil Corporation, ISL6313B Datasheet - Page 19

ISL6313B

Manufacturer Part Number

ISL6313B

Description

Two-Phase Buck PWM Controller

Manufacturer

Intersil Corporation

Datasheet

1.ISL6313B.pdf (33 pages)

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Dynamic VID

Modern microprocessors need to make changes to their core

voltage as part of normal operation. They direct the ISL6313B

to do this by making changes to the VID inputs. The ISL6313B

is required to monitor the DAC inputs and respond to on-the-

fly VID changes in a controlled manner, supervising a safe

output voltage transition without discontinuity or disruption.

The DAC mode the ISL6313B is operating in determines

how the controller responds to a dynamic VID change.

INTEL DYNAMIC VID TRANSITIONS

When in Intel VR11 mode the ISL6313B checks the VID

inputs on the positive edge of an internal 5.5MHz clock. If a

new code is established and it remains stable for 3

consecutive readings (0.36µs to 0.54µs), the ISL6313B

recognizes the new code and changes the internal DAC

reference directly to the new level. The Intel processor

controls the VID transitions and is responsible for

incrementing or decrementing one VID step at a time. In VR11

mode, the ISL6313B will immediately change the internal

DAC reference to the new requested value as soon as the

request is validated, which means the fastest recommended

rate at which a bit change can occur is once every 1µs. If the

VID code is changed by more then one step at a time, the

DAC will try to track it at a 5.5MHz step rate. This will likely

cause an overcurrent or overvoltage fault.

AMD DYNAMIC VID TRANSITIONS

When running in AMD 5-bit or 6-bit modes of operation, the

ISL6313B responds differently to a dynamic VID change then

when in Intel VR11 mode. In the AMD modes the ISL6313B

still checks the VID inputs on the positive edge of an internal

5.5MHz clock. In these modes the VID code can be changed

by more than a 1-bit step at a time. If a new code is

established and it remains stable for 3 consecutive readings

(0.36µs to 0.54µs), the ISL6313B recognizes the change

and begins slewing the DAC in 6.25mV steps at a stepping

frequency of 345kHz until the VID and DAC are equal. Thus,

the total time required for a VID change, t

only on the size of the VID change (ΔV

The time required for a ISL6313B-based converter in AMD 5-bit

DAC configuration to make a 1.1V to 1.5V reference voltage

change is about 186µs, as calculated using Equation 14.

VID “OFF” DAC CODES

Both the Intel VR11 and the AMD 5-bit VID tables include “Off”

DAC codes, which indicate to the controller to disable all

regulation. Recognition of these codes is slightly different in that

they must be stable for 4 consecutive readings of a 5.5MHz

clock (0.54µs to 0.72µs) to be recognized. Once an “Off” code

is recognized the ISL6313B latches off, and must be reset by

dropping the EN pin.

DVID

www.DataSheet4U.com

------------------------- -

345

⋅

⎛

⎝

-------------------- -

0.00625

VID

⎞

⎠

VID

DVID

, is dependent

(EQ. 14)

ISL6313B

Compensating Dynamic VID Transitions

During a VID transition, the resulting change in voltage on

the FB pin and the COMP pin causes an AC current to flow

through the error amplifier compensation components from

the FB to the COMP pin. This current then flows through the

feedback resistor, R

overshoot or undershoot at the end of the VID transition. In

order to ensure the smooth transition of the output voltage

during a VID change, a VID-on-the-fly compensation

network is required. This network is composed of a resistor

and capacitor in series, R

and the FB pin.

This VID-on-the-fly compensation network works by

sourcing AC current into the FB node to offset the effects of

the AC current flowing from the FB to the COMP pin during a

VID transition. To create this compensation current the

ISL6313B sets the voltage on the DVC pin to be 2x the

voltage on the REF pin. Since the error amplifier forces the

voltage on the FB pin and the REF pin to be equal, the

resulting voltage across the series RC between DVC and FB

is equal to the REF pin voltage. The RC compensation

components, R

create the desired amount of compensation current.

The amount of compensation current required is dependant

on the modulator gain of the system, K1, and the error

amplifier R-C components, R

between the FB and COMP pins. Use Equations 15, 16 and

17 to calculate the RC component values, R

for the VID-on-the-fly compensation network. For these

equations: V

the oscillator ramp amplitude (1.5V); and R

error amplifier R-C components between the FB and COMP

pins.

DVC

FIGURE 10. DYNAMIC VID COMPENSATION NETWORK

REF

---------- -

VSEN

A R

------- -

DVC

DAC

is the input voltage for the power train; V

DVC

+ R

DVC

and C

GND

---------------- -

K1 1

, and can cause the output voltage to

DVC

–

DVC

and C

, can then be selected to

DVC

and C

ISL6313B INTERNAL CIRCUIT

= I

DVC

, that are in series

, between the DVC

DVC

AMPLIFIER

and C

ERROR

November 6, 2008

and C

are the

(EQ. 15)

(EQ. 16)

(EQ. 17)

COMP

FN6809.0

DVC

ISL6313B Intersil Corporation, ISL6313B Datasheet - Page 19

ISL6313B

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