IR3500VMTRPBF International Rectifier, IR3500VMTRPBF Datasheet - Page 27

IR3500VMTRPBF

Manufacturer Part Number

IR3500VMTRPBF

Description

IC XPHASE3 CTLR VR11.1 32-MLPQ

Manufacturer

International Rectifier

Series

XPhase3™r

Datasheet

1.IR3500VMTRPBF.pdf (34 pages)

Specifications of IR3500VMTRPBF

Package / Case

32-MLPQ

Mounting Type

Surface Mount

Current - Supply

6.5mA

Voltage - Supply

4.75 V ~ 7.5 V

Operating Temperature

0°C ~ 100°C

Applications

Processor

Ic Function

Control IC

Supply Voltage Range

4.75V To 7.5V

Operating Temperature Range

0Â°C To +150Â°C

Digital Ic Case Style

MLPQ

No. Of Pins

Controller Type

XPhase

Filter Terminals

SMD

Rohs Compliant

Yes

Package

32-Lead MLPQ

Circuit

X-Phase Control IC

Switch Freq (khz)

250kHz to 1.5MHz

Pbf

PbF Option Available

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Current page: 27 of 34
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In the above equation, V

above condition is not satisfied there is a need to use a device with higher β

be used instead of a single NPN transistor.

Thermistor R

The threshold voltage of VRHOT comparator is fixed at 1.6V, and a negative temperature coefficient (NTC)

thermistor R

thermistor resistance at allowed maximum temperature T

Select the series resistor R

operational temperature range. Then calculate R

TMAX from (20).

VOLTAGE LOOP COMPENSATION

The adaptive voltage positioning (AVP) is usually adopted in the computer applications to improve the transient

response and reduce the power loss at heavy load. Like current mode control, the adaptive voltage positioning

loop introduces an extra zero to the voltage loop and splits the double poles of the power stage, which makes the

voltage loop compensation much easier.

Adaptive voltage positioning lowers the converter voltage by R

the converter. Pre-select feedback resistor R

The selection of compensation types depends on the output capacitors used in the converter. For applications

using Electrolytic, Polymer or AL-Polymer capacitors and running at lower frequency, type II compensation shown

in Figure 21(a) is usually enough. While for the applications using only ceramic capacitors and running at higher

frequency, type III compensation shown in Figure 21(b) is preferred.

VO+

VDRP

Page 27 of 34

THERM

RFB

RDRP

(a) Type II compensation

is required to sense the temperature of the power stage. If we pre-select R

and Over Temperature Setting Resistors R

DRP

( min) and V

TMAX

HOTSET

VDAC

HOTSET2

RCP

(max)

Figure 21 - Voltage loop compensation network

∗

THERM

CCP1

(

to linearize the NTC thermistor, which has non-linear characteristics in the

∗

−

EAOUT

( max) is the minimum and maximum anticipated input voltage. If the

TMAX

MAX

VCCLDRV

7 .

CCP

EXP

−

VCCL

FB,

[

and calculate the droop resistor RDRP,

THERM

HOTSET

(min)

EAOUT

HOTSET1

6 .

( *

)

MAX

( *

VCCL

corresponding to the allowed maximum temperature

VO+

VDRP

MAX

is calculated from (19).

RFB1

−

(b) Type III compensation

HOTSET1

−

where R

RFB

RDRP

. 1

CFB

ROOM

CDRP

) 6

)]

and R

(18)

min

VDAC

is the required output impedance of

or Darlington configuration can

RCP

HOTSET2

CCP1

(21)

EAOUT

(19)

CCP

July 28, 2008

IR3500V

THERM

(20)

EAOUT

, the NTC

IR3500VMTRPBF International Rectifier, IR3500VMTRPBF Datasheet - Page 27

IR3500VMTRPBF

Specifications of IR3500VMTRPBF

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