LX1671CLQ Microsemi Analog Mixed Signal Group, LX1671CLQ Datasheet - Page 12

LX1671CLQ

Manufacturer Part Number

LX1671CLQ

Description

IC CTRLR PS QUAD OUTPUT 38MLPQ

Manufacturer

Microsemi Analog Mixed Signal Group

Series

LoadSHARE™r

Datasheet

1.LX1671CLQ.pdf (21 pages)

Specifications of LX1671CLQ

Pwm Type

Voltage Mode

Number Of Outputs

Frequency - Max

345kHz

Duty Cycle

85%

Voltage - Supply

4.5 V ~ 5.5 V

Buck

Yes

Boost

Flyback

Inverting

Doubler

Divider

Cuk

Isolated

Operating Temperature

0°C ~ 70°C

Package / Case

38-MLPQ

Frequency-max

345kHz

For Use With

LX1671 EVA KIT - KIT EVAL FOR SWITCHING REGULATOR

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Meier Automation Equipment Co., Limited

Part Number:

LX1671CLQ

Manufacturer:

MSC

Quantity:

20 000

Current page: 12 of 21
Download datasheet (420Kb)

Rev. 1.2b, 2006-02-13

The following circuit description shows how to select the

The higher current inductor will have the lower ESR value. If the

equivalent series resistance, (ESR). As can be seen in the

previous example, if the offset error is zero and the ESR of the

two inductors are identical, then the two inductor currents will be

identical.

inductors, the value of the inductor’s ESR can be changed to

allow more current to flow through one inductor than the other.

The inductor with the lower ESR value will have the larger

current. The inductor currents are directly proportional to the

ratio of the inductor’s ESR value.

inductor ESR for each phase where a different amount of power

is taken from two different input power supplies. A typical setup

will have a +5V power supply connected to the phase 1 half

bridge driver and a +3.3V power supply connected to the phase 2

half bridge driver. The combined power output for this core

voltage is 18W (+1.5V @ 12A). For this example the +5V power

supply will supply 7W and the +3.3V power supply will supply

the other 11W. 7W @ 1.5V is a 4.67A current through the phase

1 inductor. 11W @ 1.5V is a 7.33A current through the phase 2

inductor.

the power level split.

ESR of the phase 1 inductor is selected as 10mΩ, then the ESR

value of the phase 2 inductor is calculated as:

inductors can be chosen from standard vendor tables with an ESR

ratio close to the required values. Inductors can also be designed

for a given application so that there is the least amount of

compromise in the inductor’s performance.

-P

Depending on the required accuracy of this power sharing;

The first method is to change the ratio of the inductors

HASE

+3.3V @ 11W

46.7mV

1.5V +

+5V @ 7W

, L

The ratio of inductor ESR is inversely proportional to

To change the ratio of current between the two

Figure 7 –LoadSHARE Using Inductor ESR

OAD

SHARE (ESR M

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⎜

⎝

. 4

. 7

ESR

11861 Western Avenue, Garden Grove, CA. 92841, 714-898-8121, Fax: 714-893-2570

6.4mΩ

⎞

⎟

⎠

10mΩ

2 I

1 I

mΩ

ETHOD

T H E O R Y O F O P E R A T I O N

4.67A

7.33A

4 .

)

mΩ

1.5V @ 12A

Integrated Products, Power Management

18W

Microsemi

while having a much larger current in one phase versus the other.

A simple resistor divider can be used on the input side of the Low

Pass Filter that is taken off of the switching side of the inductors.

If the Phase 2 current is to be larger than the current in Phase 1; the

resistor divider is placed in the feedback path before the Low Pass

Filter that is connected to the Phase 2 inductor. If the Phase 2

current needs to be less than the current in Phase 1; the resistor

divider is then placed in the feedback path before the Low Pass

Filter that is connected to the Phase 1 inductor.

resistor divider network in the feedback path, appears as a voltage

generator between the ESR of the two inductors.

voltage generator to be positive at Phase 2. With a divider in the

feedback path of Phase 1 the voltage generator becomes positive at

Phase 1. The Phase with the positive side of the voltage generator

will have the larger current. Systems that operate continuously

above a 30% power level can use this method, a down side is that

the current difference between the two inductors still flows during

a no load condition.

light load state, this method should not be used if a wide range of

output power is required.

the value of the resistor divider network required to generate the

offset voltage necessary to produce the different current ratio in the

two output inductors. The power sharing ratio is the same as that

of Figure 7. The Offset Voltage Generator is symbolic for the DC

voltage offset between Phase 1 & 2. This voltage is generated by

small changes in the duty cycle of Phase 2. The output of the LPF

is a DC voltage proportional to the duty cycle on its input. A small

amount of attenuation by a resistor divider before the LPF of Phase

2 will cause the duty cycle of Phase 2 to increase to produce the

added offset at V2. The high DC gain of the error amplifier will

force LPF2 to always be equal to LPF1.

calculations determine the value of the resistor divider necessary to

satisfy this example.

-P

Sometimes it is desirable to use the same inductor in both phases

The following description and Figure 8 show how to determine

A divider in the feedback path from Phase 2 will cause the

Multiple Output LoadSHARE™ PWM

As in Figure 7, the millivolts of DC offset created by the

This produces a low efficiency condition during a no load or

HASE

( C O N T I N U E D )

, L

OAD

SHARE (F

RODUCTION

EEDBACK

ATA

IVIDER

HEET

ETHOD

The following

LX1671

)

Page 12

LX1671CLQ Microsemi Analog Mixed Signal Group, LX1671CLQ Datasheet - Page 12

LX1671CLQ

Specifications of LX1671CLQ

Available stocks

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