ISL6266AIRZ-T Intersil, ISL6266AIRZ-T Datasheet - Page 28

ISL6266AIRZ-T

Manufacturer Part Number

ISL6266AIRZ-T

Description

IC CORE CTRLR 2PHASE 48-QFN

Manufacturer

Intersil

Datasheet

1.ISL6266HRZ.pdf (30 pages)

Specifications of ISL6266AIRZ-T

Applications

Converter, Intel IMVP-6

Voltage - Input

5 ~ 25 V

Number Of Outputs

Voltage - Output

0.3 ~ 1.5 V

Operating Temperature

-40°C ~ 100°C

Mounting Type

Surface Mount

Package / Case

48-VQFN

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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a mathematical calculation file available to the user. The

power stage parameters such as L and Cs are needed as

the input to calculate the compensation component values.

Attention must be paid to the input resistor to the FB pin. Too

high of a resistor will cause an error to the output voltage

regulation because of bias current flowing in the FB pin. It is

better to keep this resistor below 3kΩ when using this file.

Static Mode of Operation - Current Balance Using

DCR or Discrete Resistor Current Sensing

Current Balance is achieved in the ISL6266A by measuring

the voltages present on the ISEN pins and adjusting the duty

cycle of each phase until they match. R

each inductor, or around each discrete current resistor, are

used to create a rather large time constant such that the

ISEN voltages have minimal ripple voltage and represent the

DC current flowing through each channel's inductor. For

optimum performance, R

selected to be 0.22µF. When discrete resistor sensing is

used, a capacitor most likely needs to be placed in parallel

with R

ISL6266A uses an RC filter to sense the average voltage on

phase node and forces the average voltage on the phase

node to be equal for current balance. Even though the

ISL6266A forces the ISEN voltages to be almost equal, the

inductor currents will not be exactly equal. Using DCR

current sensing as an example, two errors have to be added

to find the total current imbalance.

In the previous 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 previous 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%*√(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. The 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.

If the PC board trace resistance from the inductor to the

microprocessor are significantly different between two

phases, the current will not be balanced perfectly. Intersil

has a proprietary method to achieve the perfect current

sharing in cases of severely imbalanced layouts.

1. Mismatch of DCR: If the DCR has a 5% tolerance, the

2. Mismatch of phase voltages/offset voltage of ISEN pins:

resistors could mismatch by 10% worst case. If each

phase is carrying 20A, the phase currents mismatch by

20A*10% = 2A.

The phase voltages are within 2mV of each other by the

current balance circuit. The error current that results is

given by 2mV/DCR. If DCR = 1mΩ then the error is 2A.

to properly compensate the current balance circuit.

is chosen to be 10kΩ and C

and C

around

ISL6266, ISL6266A

When choosing the current sense resistor, both the

tolerance of the resistance and the TCR are important. Also,

the current sense resistor’s combined tolerance at a wide

temperature range should be calculated.

Droop Using Discrete Resistor Sensing -

Static/Dynamic Mode of Operation

Figure 42 shows the equivalent circuit of a discrete current

sense approach. Figure 33 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, because there is no NTC required for thermal

compensation, the R

section is not required. Second, because there is no time

constant matching required, the C

matched to the L/DCR time constant. This component does

indeed provide noise immunity and therefore is populated

with a 39pF capacitor.

The R

sufficient for this approach.

Now the input to the droop amplifier is essentially the

The gain of the droop amplifier, K

for the ratio of the R

using Equation 35.

Solving for the R

Intel IMVP-6+ specification, R

Equation 36 is obtained:

Because these values are extremely sensitive to layout,

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 R

Fault Protection - Overcurrent Fault Setting

As previously described, the overcurrent protection of the

ISL6266A is related to the droop voltage. Previously the

droop voltage was calculated as I

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 programmed as an

equivalent droop voltage droop. Knowing the voltage droop

level allows the user to program the appropriate drop across

the R

Vrsense

rsense

droopamp

drp2

values in the previous section, R

voltage. This voltage is given by Equation 34.

EQV

(

resistor. This voltage drop will be referred to as

droopamp

drp2

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

(

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

drp2

to obtain the desired droop value.

sense

droop

sense

value, R

–

⁄

resistor network in the previous

2 )

•

) R

•

OUT

to droop impedance, R

drp1

sense

droop

droopamp

Load

3.2kΩ

= 0.0021(V/A) as per the

= 0.001Ω and R

component is not

droop

, must be adjusted

= 1.5k_1%, are

, where R

droop

drp1

June 14, 2010

(EQ. 34)

(EQ. 36)

(EQ. 35)

FN6398.3

= 1kΩ,

droop

ISL6266AIRZ-T Intersil, ISL6266AIRZ-T Datasheet - Page 28

ISL6266AIRZ-T

Specifications of ISL6266AIRZ-T

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