LM2595ADPBCKGEVB ON Semiconductor, LM2595ADPBCKGEVB Datasheet - Page 10

LM2595ADPBCKGEVB

Manufacturer Part Number

LM2595ADPBCKGEVB

Description

EVAL BOARD FOR LM2595ADPBCKG

Manufacturer

ON Semiconductor

Datasheets

1.LM2595DSADJR4G.pdf (25 pages)

2.LM2595ADPBCKGEVB.pdf (1 pages)

Specifications of LM2595ADPBCKGEVB

Design Resources

LM2595ADPBCKGEVB BOM LM2595ADPBCKGEVB Gerber Files LM2595ADPBCKGEVB Schematic

Main Purpose

DC/DC, Step Down

Outputs And Type

1, Non-Isolated

Voltage - Output

Current - Output

Voltage - Input

4.5 ~ 40 V

Regulator Topology

Buck

Frequency - Switching

150kHz

Board Type

Fully Populated

Utilized Ic / Part

LM2595

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Power - Output

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

For Use With/related Products

LM2595ADPBCKG

Other names

LM2595ADPBCKGEVBOS

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PROCEDURE (ADJUSTABLE OUTPUT VERSION: LM2595) (CONTINUED)

5. Output Capacitor Selection (C

6. Feedforward Capacitor (C

It provides additional loop stability mainly for higher input voltages.

For Cff selection use Table 1. The compensation capacitor between

0.6 nF and 15 nF is wired in parallel with the output voltage setting

resistor R2, The capacitor type can be ceramic, plastic, etc..

4. Inductor Selection (L1)

A. Since the LM2595 is a forward−mode switching regulator

B. The capacitors voltage rating should be at least 1.5 times

A. Use the following formula to calculate the inductor Volt x

B. Match the calculated E x T value with the corresponding

C. Next step is to identify the inductance region intersected by

D. Select an appropriate inductor from Table 3.

T + V

with voltage mode control, its open loop has 2−pole−1−zero

frequency characteristic. The loop stability is determined by

the output capacitor (capacitance, ESR) and inductance

values.

For stable operation use recommended values of the output

capacitors in Table 1.

Low ESR electrolytic capacitors between 180 mF and

1000 mF provide best results.

greater than the output voltage, and often much higher

voltage rating is needed to satisfy low ESR requirement

microsecond [V x ms] constant:

number on the vertical axis of the Inductor Value Selection

Guide shown in Figure 19. This E x T constant is a

measure of the energy handling capability of an inductor and

is dependent upon the type of core, the core area, the

number of turns, and the duty cycle.

the E x T value and the maximum load current value on the

horizontal axis shown in Figure 19.

The inductor chosen must be rated for a switching

frequency of 150 kHz and for a current rating of 1.15 x I

The inductor current rating can also be determined by

calculating the inductor peak current:

where t

* V

p(max)

is the “on” time of the power switch and

OUT

* V

t on +

Load(max)

SAT

Procedure

V out

)

out

)

* V

OUT

x 1.0

)

f osc

SAT

) V

* V out t on

) V

150 kHz

1000

http://onsemi.com

Load

4. Inductor Selection (L1)

5. Output Capacitor Selection (C

6. Feedforward Capacitor (C

In this example, it is recommended to use a feedforward

capacitor 4.7 nF.

A. Calculate E x T [V x ms] constant:

B. E x T = 19.2 [V x ms]

C. I

D. Proper inductor value = 68 mH

A. In this example, it is recommended to use a Nichicon PM

Inductance Region = L30

Choose the inductor from Table 3.

capacitor: 220 mF/25 V

Load(max)

T + 12 * 5 * 1.0

T + 6

= 1.0 A

11.5

5.5

6.7 V

Example

12 * 1 ) 0.5

5 ) 0.5

)

out

)

150 kHz

1000

LM2595ADPBCKGEVB ON Semiconductor, LM2595ADPBCKGEVB Datasheet - Page 10

LM2595ADPBCKGEVB

Specifications of LM2595ADPBCKGEVB

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