ISL6262CRZ Intersil, ISL6262CRZ Datasheet - Page 25

ISL6262CRZ

Manufacturer Part Number

ISL6262CRZ

Description

IC CORE REG 2PHASE 48-QFN

Manufacturer

Intersil

Datasheet

1.ISL6262CRZ.pdf (27 pages)

Specifications of ISL6262CRZ

Applications

Converter, Intel IMVP-6

Voltage - Input

5 ~ 25 V

Number Of Outputs

Voltage - Output

0.3 ~ 1.5 V

Operating Temperature

-10°C ~ 100°C

Mounting Type

Surface Mount

Package / Case

48-VQFN

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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In the above example, the two errors add to 4A. For the two

phase DC/DC, the currents would be 22A in one phase and

18A in the other phase. In the above analysis, the current

balance can be calculated with 2A/20A = 10%. This is the

worst case calculation, for example, the actual tolerance of

two 10% DCRs is 10%*sqrt(2) = 7%.

There are provisions to correct the current imbalance due to

layout or to purposely divert current to certain phase for

better thermal management. Customer can put a resistor in

parallel with the current sensing capacitor on the phase of

interest in order to purposely increase the current in that

phase.

In the case the pc board trace resistance from the inductor to

the microprocessor are not the same on two phases, the

current will not be balanced. On the phase that have too

much trace resistance a resistor can be added in parallel

with the ISEN capacitor that will correct for the poor layout.

An estimate of the value of the resistor is:

Rtweak = Risen * Rdcr/(Rtrace-Rmin)

where Risen is the resistance from the phase node to the

ISEN pin; usually 10kΩ. Rdcr is the DCR resistance of the

inductor. Rtrace is the trace resistance from the inductor to

the microprocessor on the phase that needs to be tweaked.

It should be measured with a good microOhm meter. Rmin is

the trace resistance from the inductor to the microprocessor

on the phase with the least resistance.

For example, if the pc board trace on one phase is 0.5mΩ

and on another trace is 0.3mΩ; and if the DCR is 1.2mΩ;

then the tweaking resistor is

Rtweak = 10kΩ * 1.2/(0.5 - 0.3) = 60kΩ.

When choosing current sense resistor, not only the tolerance

of the resistance is important, but also the TCR. And its

combined tolerance at a wide temperature range should be

calculated.

Droop Using Discrete Resistor Sensing - Static/

Dynamic Mode of Operation

Figure 36 shows the equivalent circuit of a discrete current

sense approach. Figure 27 shows a more detailed

schematic of this approach. Droop is solved the same way

as the DCR sensing approach with a few slight

modifications.

First, there is no NTC required for thermal compensation,

therefore, the Rn resistor network in the previous section is

not required. Secondly, there is no time constant matching

required, therefore, the Cn component is not matched to the

L/DCR time constant. This component does indeed provide

noise immunity and therefore is populated with a 39pF

capacitor.

The RS values in the previous section, RS = 1.5k_1% are

sufficient for this approach.

ISL6262

Now, the input to the droop amplifier is essentially the

Vrsense voltage. This voltage is given by the following

equation:

The gain of the droop amplifier, K

for the ratio of the Rsense to droop impedance, Rdroop. We

use the following equation:

Solving for the Rdrp2 value, Rdroop = 0.0021(V/A) as per

the Intel IMVP-6 specification, Rsense = 0.001Ω and

Rdrp1 = 1kΩ, we obtain the following:

These values are extremely sensitive to layout. Once the

board has been laid out, some tweaking may be required to

adjust the full load droop. This is fairly easy and can be

accomplished by allowing the system to achieve thermal

equilibrium at full load, and then adjusting Rdrp2 to obtain

the desired droop value.

Fault Protection - Overcurrent Fault Setting

As previously described, the overcurrent protection of the

ISL6262 is related to the droop voltage. Previously we have

calculated that the droop voltage = ILoad * Rdroop, where

Rdroop is the load line slope specified as 0.0021 (V/A) in the

Intel IMVP-6 specification. Knowing this relationship, the

overcurrent protection threshold can be set up as a voltage

droop level. Knowing this voltage droop level, one can

program in the appropriate drop across the Roc resistor.

This voltage drop will be referred to as Voc. Once the droop

voltage is greater than Voc, the PWM drives will turn off and

PGOOD will go low.

The selection of Roc is given in equation. Assuming we

desire an overcurrent trip level, Ioc, of 55A, and knowing

from the Intel Specification that the load line slope, Rdroop is

0.0021 (V/A), we can then calculate for Roc as shown in

equation.

Note, if the droop load line slope is not -0.0021 (V/A) in the

application, the overcurrent setpoint will differ from

predicted.

Vrsense

Rdrp2

droopamp

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

EQV

(

10μA

•

droopamp

------------------- - I

droop

sense

droop

------------------- - I

sense

•

–

55 0.0021

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

•

OUT

) R

10 10

•

OUT

•

drp1

–

droopamp

3.2kΩ

11.5kΩ

, must be adjusted

May 15, 2006

(EQ. 26)

(EQ. 28)

(EQ. 29)

(EQ. 27)

FN9199.2

ISL6262CRZ Intersil, ISL6262CRZ Datasheet - Page 25

ISL6262CRZ

Specifications of ISL6262CRZ

Available stocks

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