NCP1422LEDGEVB ON Semiconductor, NCP1422LEDGEVB Datasheet - Page 11

NCP1422LEDGEVB

Manufacturer Part Number

NCP1422LEDGEVB

Description

EVAL BOARD FOR NCP1422LED

Manufacturer

ON Semiconductor

Datasheets

1.NCP1422MNR2G.pdf (14 pages)

2.NCP1421LEDEVB.pdf (6 pages)

3.NCP1422LEDGEVB.pdf (1 pages)

Specifications of NCP1422LEDGEVB

Design Resources

NCP1422LEDGEVB BOM NCP1422LEDGEVB Schematic NCP1422LEDEVB Gerber Files

Current - Output / Channel

800mA

Outputs And Type

1, Non-Isolated

Voltage - Output

500 ~ 700 mV

Voltage - Input

3.6V

Utilized Ic / Part

NCP1421

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Features

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

Other names

NCP1422LEDEVBOS
NCP1422LEDEVBOS
NCP1422LEDGEVBOS

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complicated process. Selecting the right inductor and

capacitor values can allow the converter to provide

optimum performance. The following is a simple method

based on the basic first−order equations to estimate the

inductor and capacitor values for NCP1422 to operate in

Continuous Conduction Mode (CCM). The set component

values can be used as a starting point to fine tune the

application circuit performance. Detailed bench testing is

still necessary to get the best performance out of the circuit.

Design Parameters:

Calculate the feedback network:

Calculate the Low Battery Detect divider:

Low Battery

Switching mode converter design is considered a

Open Drain

Shutdown

Output

Input

Select R2 = 200 k

Select R4 = 330 k

R3 + R4

R3 + 300 k

R1 + R2

R1 + 200 k

OUT

OUT−RIPPLE

= 1.8 V to 3.0 V, Typical 2.4 V

= 2.0 V

= 500 mA

= 3.3 V

*Optional

R2 200 k

V REF

V OUT

V REF

V LB

1.20 V

= 40 mV

1.20 V

2.0 V

3.3 V

Figure 23. Typical Application Schematic for 2 Alkaline Cells Supply

* 1

* 1 + 220 k

* 1 + 350 k

p−p

10 p*

at I

OUT

220 k

330 k

GENERAL DESIGN PROCEDURES

TYPICAL APPLICATION CIRCUIT

= 500 mA

350 k

http://onsemi.com

200 nF

NCP1422

LBI/EN

LBO

REF

maximum I

and calculate the inductor value:

Assume I

power inductor can be calculated as follows:

A standard value of 6.5 mH is selected for initial trial.

calculate the output capacitor value:

where t

NCP1422

OUT−RIPPLE

Determine the Steady State Duty Ratio, D, for typical

Determine the average inductor current, I

Determine the peak inductor ripple current, I

Determine the output voltage ripple, V

C OUT u

. The operation is optimized around this point:

22 mF

L +

I LAVG +

GND

RIPPLE−P

2 I RIPPLE*P

OUT

D + 1 *

BAT

= 0.75 mS and ESR

V IN

OUT

V OUT*RIPPLE * I OUT

45 mV * 500 mA

= 40 mV

500 mA

t ON

is 20% of I

1 * D

I OUT

V OUT

V IN

V OUT

V IN

P−P

+ 500 mA

I OUT

+ 1 * 2.4 V

at I

2.4 V

1 * 0.273

0.75 mS

2 (137.6 mA)

LAVG

OUT

33 mF

COUT

1 * D

6.5 mH

3.3 V

0.05 W

t ON

= 500 mA

. The inductance of the

0.75 mS

= 0.05 ,

+ 688 mA

+ 0.273

ESR COUT

+ 18.75 mF

OUT−RIPPLE,

+ 6.5 mH

800 mA

OUT

LAVG,

RIPPLE−P,

= 3.3 V

and

NCP1422LEDGEVB ON Semiconductor, NCP1422LEDGEVB Datasheet - Page 11

NCP1422LEDGEVB

Specifications of NCP1422LEDGEVB

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