IR3502MTRPBF International Rectifier, IR3502MTRPBF Datasheet - Page 13

IR3502MTRPBF

Manufacturer Part Number

IR3502MTRPBF

Description

IC XPHASE3 CONTROLLER 32-MLPQ

Manufacturer

International Rectifier

Series

XPhase3™r

Datasheet

1.IR3502MTRPBF.pdf (39 pages)

Specifications of IR3502MTRPBF

Applications

Processor

Current - Supply

8mA

Voltage - Supply

8 V ~ 16 V

Operating Temperature

0°C ~ 100°C

Mounting Type

Surface Mount

Package / Case

32-MLPQ

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

Other names

IR3502MTRPBFTR

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Meier Automation Equipment Co., Limited

Part Number:

IR3502MTRPBF

Manufacturer:

QFN

Quantity:

20 000

Current page: 13 of 39
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IR3502 THEORY OF OPERATION

Block Diagram

The block diagram of the IR3502 is shown in Figure 7, and specific features are discussed in the following sections.

VID Control

The control IC allows the processor voltage to be set by a parallel eight bit digital VID bus. The VID codes set the

VDAC as shown in Table 1. The VID pins require an external bias voltage and should not be floated. The VID input

comparators monitor the VID pins and control the Digital-to-Analog Converter (DAC), whose output is sent to the

VDAC buffer amplifier. The output of the buffer amplifier is the VDAC pin. The VDAC voltage, input offsets of error

amplifier and remote sense differential amplifier are post-package trimmed to achieve 0.5% system set-point

accuracy for VID range between 1V to 1.6V. A set-point accuracy of ±5mV and ±8mV is achieved for VID ranges of

0.8V-1V and 0.5V-0.8V respectively. The actual VDAC voltage does not determine the system accuracy, which has

a wider tolerance.

The IR3502 can accept changes in the VID code while operating and vary the VDAC voltage accordingly. The slew

rate of the voltage at the VDAC pin can be adjusted by an external capacitor between VDAC pin and LGND pin. A

resistor connected in series with this capacitor is required to compensate the VDAC buffer amplifier. Digital VID

transitions result in a smooth analog transition of the VDAC voltage and converter output voltage minimizing inrush

currents in the input and output capacitors and overshoot of the output voltage.

Adaptive Voltage Positioning

Adaptive voltage positioning is needed to optimize the output voltage deviations during load transients and the

power dissipation of the load at heavy load. The circuitry related to voltage positioning is shown in Figure 8. The

output voltage is set by the reference voltage VSETPT at the positive input to the error amplifier. This reference

voltage can be programmed to have a constant DC offset below the VDAC by connecting RSETPT between VDAC

and VSETPT. The IVSETPT is controlled by the ROSC.

The average load current information for all the phases is fed back to the control IC through the IIN pin. As shown in

Figure 8, this information is thermally compensated with some gain by a set of buffer and thermal compensation

amplifiers to generate the voltage at the VDRP pin. The VDRP pin is connected to the FB pin through the resistor

additional current will flow into the FB pin equal to (VDRP-VDAC) / R

VDRP voltage increases accordingly. More current flows through the feedback resistor R

to have more droop. The positioning voltage can be programmed by the resistor R

produces the desired converter output impedance. The offset and slope of the converter output impedance are

referenced to and therefore independent of the VDAC voltage.

Inductor DCR Temperature Compensation

Remote Voltage Sensing

A negative temperature coefficient (NTC) thermistor should be used for inductor DCR temperature compensation.

The thermistor and tuning resistor network connected between the VN and VDRP pins provides a single NTC thermal

compensation. The thermistor should be placed close to the power stage to accurately reflect the thermal

performance of the inductor DCR. The resistor in series with the thermistor is used to reduce the nonlinearity of the

thermistor.

VOSEN+ and VOSEN- are used for remote sensing and connected directly to the load. The remote sense differential

amplifier with high speed, low input offset and low input bias current ensures accurate voltage sensing and fast

transient response. There is finite input current at both pins VOSEN+ and VOSEN- due to the internal resistor of the

differential amplifier. This limits the size of the resistors that can be used in series with these pins for acceptable

regulation of the output voltage.

DRP

. Since the error amplifier will force the loop to maintain FB to be equal to the VDAC reference voltage, an

Page 13 of 39

DRP

. When the load current increases, the

DRP

so that the droop impedance

July 28, 2009

and causes the output

IR3502

IR3502MTRPBF International Rectifier, IR3502MTRPBF Datasheet - Page 13

IR3502MTRPBF

Specifications of IR3502MTRPBF

Available stocks

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