ISL6261AIRZ-T Intersil, ISL6261AIRZ-T Datasheet - Page 21

ISL6261AIRZ-T

Manufacturer Part Number

ISL6261AIRZ-T

Description

IC CORE CTRLR 1PHASE 40-QFN

Manufacturer

Intersil

Datasheet

1.ISL6261ACRZ.pdf (33 pages)

Specifications of ISL6261AIRZ-T

Applications

Converter, Intel IMVP-6

Voltage - Input

5 ~ 21 V

Number Of Outputs

Voltage - Output

0.3 ~ 1.5 V

Operating Temperature

-40°C ~ 100°C

Mounting Type

Surface Mount

Package / Case

40-VFQFN, 40-VFQFPN

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Current page: 21 of 33
Download datasheet (2Mb)

For example: L = 0.45µH, DCR = 1.1mΩ, R

Since the inductance and the DCR typically have 20% and

7% tolerance respectively, the L/DCR time constant of each

individual inductor may not perfectly match the RC time

constant of the current sensing network. In mass production,

this effect will make the transient response vary a little bit

from board to board. Compared with potential long-term

damage on CPU reliability, an immediate system failure is

worse. So it is desirable to avoid the waveforms shown in

Figure 11. It is recommended to choose the minimum C

value based on the maximum inductance so only the

scenarios of Figures 10 and 12 may happen. It should be

noted that, after calculation, fine-tuning of C

be needed to account for board parasitics. C

be a high-grade cap like X7R with low tolerance. Another

good option is the NPO/COG (class-I) capacitor, featuring

only 5% tolerance and very good thermal characteristics. But

the NPO/COG caps are only available in small capacitance

values. In order to use such capacitors, the resistors and

thermistors surrounding the droop voltage sensing and

droop amplifier need to be scaled up 10X to reduce the

capacitance by 10X. Attention needs to be paid in balancing

the impedance of droop amplifier.

Dynamic Mode of Operation - Compensation

Parameters

The voltage regulator is equivalent to a voltage source equal

to VID in series with the output impedance. The output

impedance needs to be 2.1mΩ in order to achieve the

2.1mV/A load line. It is highly recommended to design the

compensation such that the regulator output impedance is

2.1mΩ. A type-III compensator is recommended to achieve

the best performance. Intersil provides a spreadsheet to

design the compensator parameters. Figure 13 shows an

example of the spreadsheet. After the user inputs the

parameters in the blue font, the spreadsheet will calculate

the recommended compensator parameters (in the pink

font), and show the loop gain curves and the regulator output

impedance curve. The loop gain curves need to be stable for

regulator stability, and the impedance curve needs to be

equal to or smaller than 2.1mΩ in the entire frequency range

to achieve good transient response.

The user can choose the actual resistor and capacitor values

based on the recommendation and input them in the

spreadsheet, then see the actual loop gain curves and the

regulator output impedance curve.

Caution needs to be used in choosing the input resistor to

the FB pin. Excessively high resistance will cause an error to

the output voltage regulation due to the bias current flowing

= 3.4kΩ

parallel

. 0

(

0011

. 7

3 ,

4 .

)

174

= 7.68kΩ, and

value may still

also needs to

(EQ. 27)

ISL6261A

in the FB pin. It is recommended to keep this resistor below

3k.

Droop using Discrete Resistor Sensing -

Static/Dynamic Mode of Operation

Figure 3 shows a detailed schematic using discrete resistor

sensing of the inductor current. Figure 14 shows the

equivalent circuit. Since the current sensing resistor voltage

represents the actual inductor current information, R

simply provide noise filtering. The most significant noise

comes from the ESL of the current sensing resistor. A low

low ESL sensing resistor is strongly recommended. The

recommended R

220pF. Since the current sensing resistance does not

appreciably change with temperature, the NTC network is

not needed for thermal compensation.

Droop is designed the same way as the DCR sensing

approach. The voltage on the current sensing resistor is

given by the following Equation 28:

Equation 21 shows the droop amplifier gain. So the actual

droop is given by Equation 29:

Solving for R

For example: R

easy calculation gives that R

The current sensing traces should be routed directly to the

current sensing resistor pads for accurate measurement.

However, due to layout imperfections, the calculated R

may still need slight adjustment to achieve optimum load line

slope. It is recommended to adjust R

has achieved thermal equilibrium at full load.

rsen

droop

drp

sen

drp

sen

drp2

⋅

droop

⎛

⎜

⎝

⎛

⎜ ⎜

⎝

yields:

is 100Ω and the recommended C

droop

= 2.1mΩ. If R

sen

drp

−

⎞

⎟

⎠

⎞

⎟ ⎟

⎠

drp2

is 1.1k.

sen

drp2

= 1m and R

after the system

December 21, 2007

drp1

(EQ. 28)

(EQ. 29)

(EQ. 30)

and C

= 1k,

FN6354.2

drp2

ISL6261AIRZ-T Intersil, ISL6261AIRZ-T Datasheet - Page 21

ISL6261AIRZ-T

Specifications of ISL6261AIRZ-T

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