LM25576EVAL National Semiconductor, LM25576EVAL Datasheet - Page 12

LM25576EVAL

Manufacturer Part Number

LM25576EVAL

Description

BOARD EVALUATION FOR LM25576

Manufacturer

National Semiconductor

Series

PowerWise®, SIMPLE SWITCHER®r

Datasheets

1.LM25576MHNOPB.pdf (24 pages)

2.LM25576BLDTNOPB.pdf (4 pages)

3.LM25576EVAL.pdf (6 pages)

Specifications of LM25576EVAL

Main Purpose

DC/DC, Step Down

Outputs And Type

1, Non-Isolated

Voltage - Output

Current - Output

Voltage - Input

7 ~ 42V

Regulator Topology

Buck

Frequency - Switching

300kHz

Board Type

Fully Populated

Utilized Ic / Part

LM25576

Lead Free Status / RoHS Status

Not applicable / Not applicable

Power - Output

Other names

*LM25576EVAL

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The sample & hold DC level illustrated in Figure 6 is derived

from a measurement of the re-circulating Schottky diode an-

ode current. The re-circulating diode anode should be con-

nected to the IS pin. The diode current flows through an

internal current sense resistor between the IS and PGND

pins. The voltage level across the sense resistor is sampled

and held just prior to the onset of the next conduction interval

of the buck switch. The diode current sensing and sample &

hold provide the DC level of the reconstructed current signal.

The positive slope inductor current ramp is emulated by an

external capacitor connected from the RAMP pin to AGND

and an internal voltage controlled current source. The ramp

current source that emulates the inductor current is a function

of the Vin and Vout voltages per the following equation:

Proper selection of the RAMP capacitor depends upon the

selected value of the output inductor. The value of C

be selected from: C

the output inductor in Henrys. With this value, the scale factor

of the emulated current ramp will be approximately equal to

the scale factor of the DC level sample and hold ( 0.5 V / A).

The C

vice and connected directly to the pins of the IC (RAMP and

AGND).

For duty cycles greater than 50%, peak current mode control

circuits are subject to sub-harmonic oscillation. Sub-harmonic

RAMP

capacitor should be located very close to the de-

RAMP

= (5µ x (Vin – Vout)) + 25µA

RAMP

= L x 10

-5

, where L is the value of

FIGURE 6. Composition of Current Sense Signal

RAMP

can

oscillation is normally characterized by observing alternating

wide and narrow pulses at the switch node. Adding a fixed

slope voltage ramp (slope compensation) to the current sense

signal prevents this oscillation. The 25µA of offset current

provided from the emulated current source adds some fixed

slope to the ramp signal. In some high output voltage, high

duty cycle applications, additional slope may be required. In

these applications, a pull-up resistor may be added between

the V

sation.

For V

Calculate optimal slope current, I

For example, at V

Install a resistor from the RAMP pin to V

RAMP

OUT

= V

and RAMP pins to increase the ramp slope compen-

FIGURE 7. R

> 7.5V:

/ (I

OUT

- 25µA)

= 10V, I

RAMP

to V

= 50µA.

20208745

for V

= V

OUT

x 5µA/V.

> 7.5V

20208708

LM25576EVAL National Semiconductor, LM25576EVAL Datasheet - Page 12

LM25576EVAL

Specifications of LM25576EVAL

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