Datasheet LM2574HVM-ADJ, LM2574HVM-5.0, LM2574HVM-3.3, LM2574HVM-12, LM2574HVN-3.3 Datasheet (NSC)

LM2574/LM2574HV
SIMPLE SWITCHER

™

0.5A Step-Down Voltage Regulator

General Description

The LM2574 series of regulators are monolithic integrated
circuits that provide all the active functions for a step-down
(buck) switching regulator, capable of driving a 0.5A load
with excellent line and load regulation. These devices are
available in fixed output voltages of 3.3V, 5V, 12V, 15V, and
an adjustable output version.

Requiring aminimumnumber of external components, these
regulators are simple to use and include internal frequency
compensation and a fixed-frequency oscillator.

The LM2574 series offers a high-efficiency replacement for
popular three-terminal linear regulators. Because of its high
efficiency, the copper traces on the printed circuit board are
normally the only heat sinking needed.

A standard series of inductors optimized for use with the
LM2574 are available from several different manufacturers.
This feature greatly simplifies the design of switch-mode
power supplies.

Other features include a guaranteed

±

4%tolerance on out­put voltage within specified input voltages and output load
conditions, and

±

10%on the oscillator frequency. External
shutdown is included, featuring 50 µA (typical) standby cur­rent. The output switch includes cycle-by-cycle current limit­ing, as well as thermal shutdown for full protection under
fault conditions.

Features

n 3.3V, 5V, 12V, 15V, and adjustable output versions
n Adjustable version output voltage range, 1.23V to 37V

(57V for HV version)

±

4%max over line and load

conditions

n Guaranteed 0.5A output current
n Wide input voltage range, 40V, up to 60V for HV version
n Requires only 4 external components
n 52 kHz fixed frequency internal oscillator
n TTL shutdown capability, low power standby mode
n High efficiency
n Uses readily available standard inductors
n Thermal shutdown and current limit protection

Applications

n Simple high-efficiency step-down (buck) regulator
n Efficient pre-regulator for linear regulators
n On-card switching regulators
n Positive to negative converter (Buck-Boost)

Typical Application (Fixed Output Voltage Versions)

Patent Pending
SIMPLE SWITCHER

™

is a trademark of National Semiconductor Corporation

DS011394-1

Note: Pin numbers are for 8-pin DIP package.

June 1999

LM2574/LM2574HV SIMPLE SWITCHER 0.5A Step-Down Voltage Regulator

© 1999 National Semiconductor Corporation DS011394 www.national.com

Connection Diagrams

8-Lead DIP

DS011394-2

* No internal connection, but should be soldered to PC board for best heat
transfer.

Top View

Order Number LM2574-3.3HVN, LM2574HVN-5.0,

LM2574HVN-12, LM2574HVN-15, LM2574HVN-ADJ,

LM2574N-3.3, LM2574N-5.0, LM2574N-12,

LM2574N-15 or LM2574N-ADJ

See NS Package Number N08A

14-Lead Wide

Surface Mount (WM)

DS011394-3

Top View

Order Number LM2574HVM-3.3, LM2574HVM-5.0,

LM2574HVM-12, LM2574HVM-15, LM2574HVM-ADJ,

LM2574M-3.3 LM2574M-5.0, LM2574M-12,

LM2574M-15 or LM2574M-ADJ

See NS Package Number M14B

www.national.com 2

Absolute Maximum Ratings (Note 1)

If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.

Maximum Supply Voltage

LM2574 45V
LM2574HV 63V

ON /OFF Pin Input Voltage

−0.3V ≤ V ≤ +V

IN

Output Voltage to Ground

(Steady State) −1V

Minimum ESD Rating

(C=100 pF, R=1.5 kΩ)2kV

Storage Temperature Range −65˚C to +150˚C

Lead Temperature

(Soldering, 10 seconds) 260˚C
Maximum Junction Temperature 150˚C
Power Dissipation Internally Limited

Operating Ratings

Temperature Range

LM2574/LM2574HV −40˚C ≤ T

J

≤ +125˚C

Supply Voltage

LM2574 40V

LM2574HV 60V

LM2574-3.3, LM2574HV-3.3
Electrical Characteristics

Specifications with standard type face are for T

J

=

25˚C, and those with boldface type apply over full Operating Tempera-

ture Range.

Symbol Parameter Conditions LM2574-3.3 Units

(Limits)

LM2574HV-3.3

Typ Limit

(Note 2)

SYSTEM PARAMETERS (Note 3) Test Circuit

Figure 2

V

OUT

Output Voltage V

IN

=

12V, I

LOAD

=

100 mA 3.3 V

3.234 V(Min)

3.366 V(Max)

V

OUT

Output Voltage 4.75V ≤ VIN≤ 40V, 0.1A ≤ I

LOAD

≤ 0.5A 3.3 V

LM2574 3.168/3.135 V(Min)

3.432/3.465 V(Max)

V

OUT

Output Voltage 4.75V ≤ VIN≤ 60V, 0.1A ≤ I

LOAD

≤ 0.5A 3.3

LM2574HV 3.168/3.135 V(Min)

3.450/3.482 V(Max)

η Efficiency V

IN

=

12V, I

LOAD

=

0.5A 72

%

LM2574-5.0, LM2574HV-5.0
Electrical Characteristics

Specifications with standard type face are for T

J

=

25˚C, and those with boldface type apply over full Operating Tempera-

ture Range.

Symbol Parameter Conditions LM2574-5.0 Units

(Limits)

LM2574HV-5.0

Typ Limit

(Note 2)

SYSTEM PARAMETERS (Note 3) Test Circuit

Figure 2

V

OUT

Output Voltage V

IN

=

12V, I

LOAD

=

100 mA 5 V

4.900 V(Min)

5.100 V(Max)

V

OUT

Output Voltage 7V ≤ VIN≤ 40V, 0.1A ≤ I

LOAD

≤ 0.5A 5 V

LM2574 4.800/4.750 V(Min)

5.200/5.250 V(Max)

V

OUT

Output Voltage 7V ≤ VIN≤ 60V, 0.1A ≤ I

LOAD

≤ 0.5A 5

LM2574HV 4.800/4.750 V(Min)

5.225/5.275 V(Max)

η Efficiency V

IN

=

12V, I

LOAD

=

0.5A 77

%

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LM2574-12, LM2574HV-12
Electrical Characteristics

Specifications with standard type face are for T

J

=

25˚C, and those with boldface type apply over full Operating Tempera-

ture Range.

Symbol Parameter Conditions LM2574-12 Units

(Limits)

LM2574HV-12

Typ Limit

(Note 2)

SYSTEM PARAMETERS (Note 3) Test Circuit

Figure 2

V

OUT

Output Voltage V

IN

=

25V, I

LOAD

=

100 mA 12 V

11.76 V(Min)

12.24 V(Max)

V

OUT

Output Voltage 15V ≤ VIN≤ 40V, 0.1A ≤ I

LOAD

≤ 0.5A 12 V

LM2574 11.52/11.40 V(Min)

12.48/12.60 V(Max)

V

OUT

Output Voltage 15V ≤ VIN≤ 60V, 0.1A ≤ I

LOAD

≤ 0.5A 12

LM2574HV 11.52/11.40 V(Min)

12.54/12.66 V(Max)

η Efficiency V

IN

=

15V, I

LOAD

=

0.5A 88

%

LM2574-15, LM2574HV-15
Electrical Characteristics

Specifications with standard type face are for T

J

=

25˚C, and those with boldface type apply over full Operating Tempera-

ture Range.

Symbol Parameter Conditions LM2574-15 Units

(Limits)

LM2574HV-15

Typ Limit

(Note 2)

SYSTEM PARAMETERS (Note 3) Test Circuit

Figure 2

V

OUT

Output Voltage V

IN

=

30V, I

LOAD

=

100 mA 15 V

14.70 V(Min)

15.30 V(Max)

V

OUT

Output Voltage 18V ≤ VIN≤ 40V, 0.1A ≤ I

LOAD

≤ 0.5A 15 V

LM2574 14.40/14.25 V(Min)

15.60/15.75 V(Max)

V

OUT

Output Voltage 18V ≤ VIN≤ 60V, 0.1A ≤ I

LOAD

≤ 0.5A 15

LM2574HV 14.40/14.25 V(Min)

15.68/15.83 V(Max)

η Efficiency V

IN

=

18V, I

LOAD

=

0.5A 88

%

LM2574-ADJ, LM2574HV-ADJ
Electrical Characteristics

Specifications with standard type face are for T

J

=

25˚C, and those with boldface type apply over full Operating Tempera-

ture Range. Unless otherwise specified, V

IN

=

12V, I

LOAD

=

100 mA.

Symbol Parameter Conditions LM2574-ADJ Units

(Limits)

LM2574HV-ADJ

Typ Limit

(Note 2)

SYSTEM PARAMETERS (Note 3) Test Circuit

Figure 2

V

FB

Feedback Voltage V

IN

=

12V, I

LOAD

=

100 mA 1.230 V

1.217 V(Min)

1.243 V(Max)

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LM2574-ADJ, LM2574HV-ADJ
Electrical Characteristics

(Continued)

Specifications with standard type face are for T

J

=

25˚C, and those with boldface type apply over full Operating Tempera-

ture Range. Unless otherwise specified, V

IN

=

12V, I

LOAD

=

100 mA.

Symbol Parameter Conditions LM2574-ADJ Units

(Limits)

LM2574HV-ADJ

Typ Limit

(Note 2)

SYSTEM PARAMETERS (Note 3) Test Circuit

Figure 2

V

FB

Feedback Voltage 7V ≤ VIN≤ 40V, 0.1A ≤ I

LOAD

≤ 0.5A 1.230 V

LM2574 V

OUT

Programmed for 5V. Circuit of

Figure 2

1.193/1.180 V(Min)

1.267/1.280 V(Max)

V

FB

Feedback Voltage 7V ≤ VIN≤ 60V, 0.1A ≤ I

LOAD

≤ 0.5A 1.230

LM2574HV V

OUT

Programmed for 5V. Circuit of

Figure 2

1.193/1.180 V(Min)

1.273/1.286 V(Max)

η Efficiency V

IN

=

12V, V

OUT

=

5V, I

LOAD

=

0.5A 77

%

All Output Voltage Versions
Electrical Characteristics

Specifications with standard type face are for T

J

=

25˚C, and those with boldface type apply over full Operating Tempera-

ture Range. Unless otherwise specified, V

IN

=

12V for the 3.3V, 5V, and Adjustable version, V

IN

=

25V for the 12V version,

and V

IN

=

30V for the 15V version. I

LOAD

=

100 mA.

Symbol Parameter Conditions LM2574-XX Units

(Limits)

LM2574HV-XX

Typ Limit

(Note 2)

DEVICE PARAMETERS

I

b

Feedback Bias
Current

Adjustable Version Only, V

OUT

=

5V 50 100/500 nA

f

O

Oscillator Frequency (see Note 10) 52 kHz

47/42 kHz(Min)
58/63 kHz(Max)

V

SAT

Saturation Voltage I

OUT

=

0.5A (Note 4) 0.9 V

1.2/1.4 V(max)

DC Max Duty Cycle

(ON)

(Note 5) 98

%

93

%

(Min)

I

CL

Current Limit Peak Current, (Notes 4, 10) 1.0 A

0.7/0.65 A(Min)

1.6/1.8 A(Max)

I

L

Output Leakage (Notes 6, 7) Output=0V 2 mA(Max)
Current Output=−1V 7.5 mA

Output=−1V 30 mA(Max)

I

Q

Quiescent Current (Note 6) 5 mA

10 mA(Max)

I

STBY

Standby Quiescent ON /OFF Pin=5V (OFF) 50 µA
Current 200 µA(Max)

θ

JA

Thermal Resistance N Package, Junction to Ambient (Note 8) 92

θ

JA

N Package, Junction to Ambient (Note 9) 72 ˚C/W

θ

JA

M Package, Junction to Ambient (Note 8) 102

θ

JA

M Package, Junction to Ambient (Note 9) 78

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All Output Voltage Versions
Electrical Characteristics

(Continued)

Specifications with standard type face are for T

J

=

25˚C, and those with boldface type apply over full Operating Tempera-

ture Range. Unless otherwise specified, V

IN

=

12V for the 3.3V, 5V, and Adjustable version, V

IN

=

25V for the 12V version,

and V

IN

=

30V for the 15V version. I

LOAD

=

100 mA.

Symbol Parameter Conditions LM2574-XX Units

(Limits)

LM2574HV-XX

Typ Limit

(Note 2)

ON /OFF CONTROL Test Circuit

Figure 2

V

IH

ON /OFF Pin Logic V

OUT

=

0V 1.4 2.2/2.4 V(Min)

V

IL

Input Level V

OUT

=

Nominal Output Voltage 1.2 1.0/0.8 V(Max)

I

H

ON /OFF Pin Input ON /OFF Pin=5V (OFF) 12 µA
Current 30 µA(Max)

I

IL

ON /OFF Pin=0V (ON) 0µA

10 µA(Max)

Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur.Operating Ratings indicate conditions for which the device is in­tended to be functional, but do not guarantee specific performance limits. For guaranteed specifications and test conditions, see the Electrical Characteristics.

Note 2: All limits guaranteed at room temperature (Standard type face) and at temperature extremes (bold type face). All room temperature limits are 100%produc-
tion tested. All limits at temperature extremes are guaranteed via correlation using standard Statistical Quality Control (SQC) methods. All limits are used to calculate
Average Outgoing Quality Level.

Note 3: External components such as the catch diode, inductor, input and output capacitors can affect switching regulator system performance. When the LM2574
is used as shown in the

Figure 2

test circuit, system performance will be as shown in system parameters section of Electrical Characteristics.

Note 4: Output pin sourcing current. No diode, inductor or capacitor connected to output pin.
Note 5: Feedback pin removed from output and connected to 0V.
Note 6: Feedback pin removed from output and connected to +12V for the Adjustable, 3.3V,and 5V versions, and +25V for the 12V and 15V versions, to force the

output transistor OFF.
Note 7: V

IN

=

40V (60V for high voltage version).

Note 8: Junction to ambient thermal resistance with approximately 1 square inch of printed circuit board copper surrounding the leads. Additional copper area will
lower thermal resistance further. See application hints in this data sheet and the thermal model in Switchers Made Simple software.

Note 9: Junction to ambient thermal resistance with approximately 4 square inches of 1 oz. (0.0014 in. thick) printed circuit board copper surrounding the leads. Ad­ditional copper area will lower thermal resistance further. (See Note 8.)

Note 10: The oscillator frequency reduces to approximately 18 kHz in the event of an output short or an overload which causes the regulated output voltage to drop
approximately 40%from the nominal output voltage. This self protection feature lowers the average power dissipation of the IC by lowering the minimum duty cycle
from 5%down to approximately 2%.

Typical Performance Characteristics (Circuit of

Figure 2

)

Normalized Output Voltage

DS011394-27

Line Regulation

DS011394-28

Dropout Voltage

DS011394-29

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Typical Performance Characteristics (Circuit of

Figure 2

) (Continued)

Current Limit

DS011394-30

Supply Current

DS011394-31

Standby
Quiescent Current

DS011394-32

Oscillator Frequency

DS011394-33

Switch Saturation
Voltage

DS011394-34

Efficiency

DS011394-35

Minimum Operating Voltage

DS011394-36

Supply Current
vs Duty Cycle

DS011394-37

Feedback Voltage
vs Duty Cycle

DS011394-38

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Typical Performance Characteristics (Circuit of

Figure 2

) (Continued)

Feedback
Pin Current

DS011394-39

Junction to Ambient
Thermal Resistance

DS011394-40

Continuous Mode Switching Waveforms
V

OUT

=

5V, 500 mA Load Current, L=330 µH

DS011394-6

Notes:

A: Output Pin Voltage, 10V/div
B: Inductor Current, 0.2 A/div
C: Output Ripple Voltage, 20 mV/div,
AC-Coupled
Horizontal Time Base: 5 µs/div

Discontinuous Mode Switching Waveforms
V

OUT

=

5V, 100 mA Load Current, L=100 µH

DS011394-7

Notes:

A: Output Pin Voltage, 10V/div
B: Inductor Current, 0.2 A/div
C: Output Ripple Voltage, 20 mV/div,
AC-Coupled
Horizontal Time Base: 5 µs/div

500 mA Load Transient Response for Continuous
Mode Operation. L=330 µH, C

OUT

=

300 µF

DS011394-8

Notes:

A: Output Voltage, 50 mV/div.
AC Coupled
B: 100 mA to 500 mA Load Pulse
Horizontal Time Base: 200 µs/div

250 mA Load Transient Response for Discontinuous
Mode Operation. L=68 µH, C

OUT

=

470 µF

DS011394-9

Notes:

A: Output Voltage, 50 mV/div.
AC Coupled
B: 50 mA to 250 mA Load Pulse
Horizontal Time Base: 200 µs/div

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Block Diagram

DS011394-10

R1=1k

3.3V, R2=1.7k
5V, R2=3.1k
12V, R2=8.84k
15V, R2=11.3k
For Adj. Version
R1=Open, R2=0Ω

Note: Pin numbers are for the 8-pin DIP package.

FIGURE 1.

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Test Circuit and Layout Guidelines

As in any switching regulator, layout is very important. Rap­idly switching currents associated with wiring inductance
generate voltage transients which can cause problems. For
minimal inductance and ground loops, the length of the leads
indicated by heavy lines should be kept as short as pos-
sible. Single-point grounding (as indicated) or ground plane
construction should be used for best results. When using the
Adjustable version, physically locate the programming resis­tors near the regulator, to keep the sensitive feedback wiring
short.

Fixed Output Voltage Versions

DS011394-11

CIN— 22 µF, 75V

Aluminum Electrolytic

C

OUT

— 220 µF, 25V

Aluminum Electrolytic
D1 — Schottky, 11DQ06
L1 — 330 µH, 52627

(for 5V in, 3.3V out, use

100 µH, RL-1284-100)
R1 — 2k, 0.1

%

R2 — 6.12k, 0.1

%

Adjustable Output Voltage Version

DS011394-12

FIGURE 2.

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Test Circuit and Layout Guidelines

(Continued)

U.S. Source
Note 1: Pulse Engineering, (619) 674-8100

P.O. Box 12236, San Diego, CA 92112

Note 2: Renco Electronics Inc., (516) 586-5566
60 Jeffryn Blvd. East, Deer Park, NY 11729

*

Contact Manufacturer

European Source
Note 3: NPI/APC +44 (0) 634 290588

47 Riverside, Medway City Estate
Strood, Rochester, Kent ME2 4DP. UK

*

Contact Manufacturer

Inductor Pulse Eng. Renco NPI

Value (Note 1) (Note 2) (Note 3)

68 µH

*

RL-1284-68-43 NP5915

100 µH

*

RL-1284-100-43 NP5916
150 µH 52625 RL-1284-150-43 NP5917
220 µH 52626 RL-1284-220-43 NP5918/5919
330 µH 52627 RL-1284-330-43 NP5920/5921
470 µH 52628 RL-1284-470-43 NP5922
680 µH 52629 RL-1283-680-43 NP5923

1000 µH 52631 RL-1283-1000-43

*

1500 µH

*

RL-1283-1500-43

*

2200 µH

*

RL-1283-2200-43

*

FIGURE 3. Inductor Selection by

Manufacturer’s Part Number

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LM2574 Series Buck Regulator Design Procedure

PROCEDURE (Fixed Output Voltage Versions) EXAMPLE (Fixed Output Voltage Versions)

Given:

V

OUT

=

Regulated Output Voltage (3.3V, 5V, 12V, or 15V)

V

IN

(Max)=Maximum Input Voltage

I

LOAD

(Max)=Maximum Load Current

Given:

V

OUT

=

5V

V

IN

(Max)=15V

I

LOAD

(Max)=0.4A

1. Inductor Selection (L1)
A. Select the correct Inductor value selection guide from

Fig-

ures 4, 5, 6

,or

Figure 7

. (Output voltages of 3.3V, 5V, 12V or
15V respectively). For other output voltages, see the design
procedure for the adjustable version.

B. From the inductor value selection guide, identify the induc­tance region intersected by V

IN

(Max) and I

LOAD

(Max).

C. Select an appropriate inductor from the table shown in

Fig-

ure 3

. Part numbers are listed for three inductor manufactur­ers. The inductor chosen must be rated for operation at the
LM2574 switching frequency (52 kHz) and for a current rating
of 1.5 x I

LOAD

. For additional inductor information, see the in­ductor section in the Application Hints section of this data
sheet.

1. Inductor Selection (L1)
A. Use the selection guide shown in

Figure 5

.

B. From the selection guide, the inductance area intersected
by the 15V line and 0.4A line is 330.

C. Inductor value required is 330 µH. From the table in

Figure

3

, choose Pulse Engineering PE-52627, Renco RL-1284-330,

or NPI NP5920/5921.

2. Output Capacitor Selection (C

OUT

)

A. The value of the output capacitor together with the inductor

defines the dominate pole-pair of the switching regulator loop.
For stable operation and an acceptable output ripple voltage,
(approximately 1%of the output voltage) a value between
100 µF and 470 µF is recommended.

B. The capacitor’s voltage rating should be at least 1.5 times
greater than the output voltage. For a 5V regulator, a rating of
at least 8V is appropriate, and a 10V or 15V rating is recom­mended.

Higher voltage electrolytic capacitors generally have lower
ESR numbers, and for this reason it may be necessary to se­lect a capacitor rated for a higher voltage than would normally
be needed.

2. Output Capacitor Selection (C

OUT

)

A. C

OUT

=

100 µF to 470 µF standard aluminum electrolytic.

B. Capacitor voltage rating=20V.

3. Catch Diode Selection (D1)
A. The catch-diode current rating must be at least 1.5 times

greater than the maximum load current. Also, if the power
supply design must withstand a continuous output short, the
diode should have a current rating equal to the maximum cur­rent limit of the LM2574. The most stressful condition for this
diode is an overload or shorted output condition.

B. The reverse voltage rating of the diode should be at least

1.25 times the maximum input voltage.

3. Catch Diode Selection (D1)
A. For this example, a 1A current rating is adequate.
B. Use a 20V 1N5817 or SR102 Schottky diode, or any of the

suggested fast-recovery diodes shown in

Figure 9

.

4. Input Capacitor (C

IN

)

An aluminum or tantalum electrolytic bypass capacitor located
close to the regulator is needed for stable operation.

4. Input Capacitor (CIN)

A22 µF aluminum electrolytic capacitor located near the input
and ground pins provides sufficient bypassing.

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LM2574 Series Buck Regulator Design Procedure (Continued)

INDUCTOR VALUE SELECTION GUIDES (For Continuous Mode Operation)

DS011394-26

FIGURE 4. LM2574HV-3.3 Inductor Selection Guide

DS011394-13

FIGURE 5. LM2574HV-5.0 Inductor Selection Guide

DS011394-14

FIGURE 6. LM2574HV-12 Inductor Selection Guide

DS011394-15

FIGURE 7. LM2574HV-15 Inductor Selection Guide

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LM2574 Series Buck Regulator Design Procedure (Continued)

PROCEDURE (Adjustable Output Voltage Versions) EXAMPLE (Adjustable Output Voltage Versions)

Given:

V

OUT

=

Regulated Output Voltage

V

IN

(Max)=Maximum Input Voltage

I

LOAD

(Max)=Maximum Load Current

F=Switching Frequency

(Fixed at 52 kHz)

Given:

V

OUT

=

24V

V

IN

(Max)=40V

I

LOAD

(Max)=0.4A

F=52 kHz

1. Programming Output Voltage

(Selecting R1 and R2, as

shown in Figure 2

)

Use the following formula to select the appropriate resistor
values.

R1can be between 1k and 5k.

(For best temperature coeffi-

cient and stability with time, use 1%metal film resistors)

1. Programming Output Voltage

(Selecting R1 and R2)

R

2

=

1k (19.51−1)=18.51k, closest 1%value is 18.7k

2. Inductor Selection (L1)
A. Calculate the inductor Volt

•

microsecond constant,

E

•

T(V•µs), from the following formula:

B. Use the E•T value from the previous formula and match
it with the E

•

T number on the vertical axis of the Inductor

Value Selection Guide shown in

Figure 8

.

C. On the horizontal axis, select the maximum load current.
D. Identify the inductance region intersected by the E

•

T
value and the maximum load current value, and note the in­ductor value for that region.

E. Select an appropriate inductor from the table shown in

Fig-

ure 3

. Part numbers are listed for three inductor manufactur­ers. The inductor chosen must be rated for operation at the
LM2574 switching frequency (52 kHz) and for a current rating
of 1.5 x I

LOAD

. For additional inductor information, see the in­ductor section in the application hints section of this data
sheet.

2. Inductor Selection (L1)
A. Calculate E

•

T(V•µs)

B. E•T=185 V•µs
C. I

LOAD

(Max)=0.4A

D. Inductance Region=1000
E. Inductor Value=1000 µH

Choose from Pulse Engineer-

ing Part

#

PE-52631, or

Renco

Part#RL-1283-1000.

DS011394-16

FIGURE 8. LM2574HV-ADJ Inductor Selection Guide

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LM2574 Series Buck Regulator Design Procedure (Continued)

PROCEDURE (Adjustable Output Voltage Versions) EXAMPLE (Adjustable Output Voltage Versions)

3. Output Capacitor Selection (C

OUT

)

A. The value of the output capacitor together with the inductor

defines the dominate pole-pair of the switching regulator loop.
For stable operation, the capacitor must satisfy the following
requirement:

The above formula yields capacitor values between 5 µF and
1000 µF that will satisfy the loop requirements for stable op­eration. But to achieve an acceptable output ripple voltage,
(approximately 1%of the output voltage) and transient re­sponse, the output capacitor may need to be several times
larger than the above formula yields.

B. The capacitor’s voltage rating should be at last 1.5 times
greater than the output voltage. For a 24V regulator, a rating
of at least 35V is recommended.

Higher voltage electrolytic capacitors generally have lower
ESR numbers, and for this reasion it may be necessary to se­lect a capacitor rate for a higher voltage than would normally
be needed.

3. Output Capacitor Selection (C

OUT

)

However, for acceptable output ripple voltage select
C

OUT

≥ 100 µF

C

OUT

=

100 µF electrolytic capacitor

4. Catch Diode Selection (D1)
A. The catch-diode current rating must be at least 1.5 times

greater than the maximum load current. Also, if the power
supply design must withstand a continuous output short, the
diode should have a current rating equal to the maximum cur­rent limit of the LM2574. The most stressful condition for this
diode is an overload or shorted output condition. Suitable di­odes are shown in the selection guide of

Figure 9

.

B. The reverse voltage rating of the diode should be at least

1.25 times the maximum input voltage.

4. Catch Diode Selection (D1)
A. For this example, a 1A current rating is adequate.
B. Use a 50V MBR150 or 11DQ05 Schottky diode, or any of

the suggested fast-recovery diodes in

Figure 9

.

5. Input Capacitor (C

IN

)

An aluminum or tantalum electrolytic bypass capacitor located
close to the regulator is needed for stable operation.

5. Input Capacitor (CIN)

A22 µF aluminum electrolytic capacitor located near the input
and ground pins provides sufficient bypassing. See (

Figure 9

).

To further simplify the buck regulator design procedure, Na­tional Semiconductor is making available computer design
software to be used with the Simple Switcher line of switching
regulators. Switchers Made Simple (version 3.3) is available
ona(3

1

⁄2") diskette for IBM compatible computers from a Na-

tional Semiconductor sales office in your area.

www.national.com15

LM2574 Series Buck Regulator Design Procedure (Continued)

Application Hints

INPUT CAPACITOR (CIN)

To maintain stability, the regulator input pin must be by­passed with at least a 22 µF electrolytic capacitor. The ca­pacitor’s leads must be kept short, and located near the
regulator.

If the operating temperature range includes temperatures
below −25˚C, the input capacitor value may need to be
larger. With most electrolytic capacitors, the capacitance
value decreases and the ESR increases with lower tempera­tures and age. Paralleling a ceramic or solid tantalum ca­pacitor will increase the regulator stability at cold tempera­tures. For maximum capacitor operating lifetime, the
capacitor’s RMS ripple current rating should be greater than

INDUCTOR SELECTION

All switching regulators have two basic modes of operation:
continuous and discontinuous. The difference between the
two types relates to the inductor current, whether it is flowing
continuously, or if it drops to zero for a period of time in the
normal switching cycle. Each mode has distinctively different
operating characteristics, which can affect the regulator per­formance and requirements.

The LM2574 (or any of the Simple Switcher family) can be
used for both continuous and discontinuous modes of opera­tion.

In many cases the preferred mode of operation is in the con­tinuous mode. It offers better load regulation, lower peak
switch, inductor and diode currents, and can have lower out­put ripple voltage. But it does require relatively large inductor
values to keep the inductor current flowing continuously, es­pecially at low output load currents.

To simplify the inductor selection process, an inductor selec­tion guide (nomograph) was designed (see

Figure 4

through

Figure 8

). This guide assumes continuous mode operation,
and selects an inductor that will allow a peak-to-peak induc­tor ripple current (∆I

IND

) to be a certain percentage of the
maximum design load current. In the LM2574 SIMPLE
SWITCHER, the peak-to-peak inductor ripple current per­centage (of load current) is allowed to change as different
design load currents are selected. By allowing the percent­age of inductor ripple current to increase for lower current
applications, the inductor size and value can be kept rela­tively low.

V

R

1 Amp Diodes

Schottky Fast Recovery

20V 1N5817

SR102

MBR120P

30V 1N5818

SR103

11DQ03 The

MBR130P following

10JQ030 diodes

40V 1N5819 are all

SR104 rated to

11DQ04 100V

11JQ04

MBR140P

50V MBR150 11DF1

SR105 10JF1

11DQ05 MUR110

11JQ05 HER102

60V MBR160

SR106

11DQ06

11JQ06

90V 11DQ09

FIGURE 9. Diode Selection Guide

www.national.com 16

Application Hints (Continued)

INDUCTOR RIPPLE CURRENT

When the switcher is operating in the continuous mode, the
inductor current waveform ranges from a triangular to a saw­tooth type of waveform (depending on the input voltage). For
a given input voltage and output voltage, the peak-to-peak
amplitude of this inductor current waveform remains con­stant. As the load current rises or falls, the entire sawtooth
current waveform also rises or falls. The average DC value
of this waveform is equal to the DC load current (in the buck
regulator configuration).

If the load current drops to a low enough level, the bottom of
the sawtooth current waveform will reach zero, and the
switcher will change to a discontinuous mode of operation.
This is a perfectly acceptable mode of operation. Any buck
switching regulator (no matter how large the inductor value
is) will be forced to run discontinuous if the load current is
light enough.

The curve shown in

Figure 10

illustrates how the peak-to-

peak inductor ripple current (∆I

IND

) is allowed to change as
different maximum load currents are selected, and also how
it changes as the operating point varies from the upper bor­der to the lower border within an inductance region (see In­ductor Selection guides).

Consider the following example:

V

OUT

=

5V

@

0.4A

V

IN

=

10V minimum up to 20V maximum

The selection guide in

Figure 5

shows that for a 0.4A load
current, and an input voltage range between 10V and 20V,
the inductance region selected by the guide is 330 µH. This
value of inductance will allow a peak-to-peak inductor ripple
current (∆I

IND

) to flow that will be a percentage of the maxi-

mum load current. For this inductor value, the ∆I

IND

will also
vary depending on the input voltage. As the input voltage in­creases to 20V, it approaches the upper border of the induc­tance region, and the inductor ripple current increases. Re­ferring to the curve in

Figure 10

, it can be seen that at the

0.4A load current level, and operating near the upper border
of the 330 µH inductance region, the ∆I

IND

will be 53%of

0.4A, or 212 mA p-p.
This ∆I

IND

is important because from this number the peak
inductor current rating can be determined, the minimum load
current required before the circuit goes to discontinuous op­eration, and also, knowing the ESR of the output capacitor,

the output ripple voltage can be calculated, or conversely,
measuring the output ripple voltage and knowing the ∆I

IND

,

the ESR can be calculated.
From the previous example, the Peak-to-peak Inductor

Ripple Current (∆I

IND

)=212 mA p-p. Once the ∆

IND

value is
known, the following three formulas can be used to calculate
additional information about the switching regulator circuit:

1. Peak Inductor or peak switch current

2. Minimum load current before the circuit becomes dis-

continuous

3. Output Ripple Voltage=(∆I

IND

) x (ESR of C

OUT

)

The selection guide chooses inductor values suitable for
continuous mode operation, but if the inductor value chosen
is prohibitively high, the designer should investigate the pos­sibility of discontinuous operation.The computer design soft­ware

Switchers Made Simple

will provide all component
values for discontinuous (as well as continuous) mode of op­eration.

Inductors are available in different styles such as pot core,
toroid, E-frame, bobbin core, etc., as well as different core
materials, such as ferrites and powdered iron. The least ex­pensive, the bobbin core type, consists of wire wrapped on a
ferrite rod core. This type of construction makes for an inex­pensive inductor, but since the magnetic flux is not com­pletely contained within the core, it generates more electro­magnetic interference (EMI). This EMl can cause problems
in sensitive circuits, or can give incorrect scope readings be­cause of induced voltages in the scope probe.

The inductors listed in the selection chart include powdered
iron toroid for Pulse Engineering, and ferrite bobbin core for
Renco.

An inductor should not be operated beyond its maximum
rated current because it may saturate. When an inductor be­gins to saturate, the inductance decreases rapidly and the
inductor begins to look mainly resistive (the DC resistance of
the winding). This can cause the inductor current to rise very
rapidly and will affect the energy storage capabilities of the
inductor and could cause inductor overheating. Different in­ductor types have different saturation characteristics, and
this should be kept in mind when selecting an inductor. The
inductor manufacturers’ data sheets include current and en­ergy limits to avoid inductor saturation.

OUTPUT CAPACITOR

An output capacitor is required tofilter the output voltage and
is needed for loop stability. The capacitor should be located
near the LM2574 using short pc board traces. Standard alu­minum electrolytics are usually adequate, but low ESR types
are recommended for low output ripple voltage and good
stability. The ESR of a capacitor depends on many factors,
some which are: the value, the voltage rating, physical size
and the type of construction. In general, low value or low
voltage (less than 12V) electrolytic capacitors usually have
higher ESR numbers.

The amount of output ripple voltage is primarily a function of
the ESR (Equivalent Series Resistance) of the output ca-

DS011394-18

FIGURE 10. Inductor Ripple Current (∆I

IND

) Range

Based on Selection Guides from

Figure 4

through

Figure 8

.

www.national.com17

Application Hints (Continued)

pacitor and the amplitude of the inductor ripple current
(∆I

IND

). See the section on inductor ripple current in Applica-

tion Hints.
The lower capacitor values (100 µF- 330 µF) will allow typi-

cally 50 mV to 150 mV of output ripple voltage, while larger­value capacitors will reduce the ripple to approximately
20 mV to 50 mV.

Output Ripple Voltage=(∆I

IND

) (ESR of C

OUT

)

To further reduce the output ripple voltage, several standard
electrolytic capacitors may be paralleled, or a higher-grade
capacitor may be used. Such capacitors are often called
“high-frequency,” “low-inductance,” or “low-ESR.” These will
reduce the output ripple to 10 mV or 20 mV.However, when
operating in the continuous mode, reducing the ESR below

0.03Ω can cause instability in the regulator.
Tantalum capacitors can have a very low ESR, and should

be carefully evaluated if it is the only output capacitor. Be­cause of their good low temperature characteristics, a tanta­lum can be used in parallel with aluminum electrolytics, with
the tantalum making up 10%or 20%of the total capacitance.

The capacitor’s ripple current rating at 52 kHz should be at
least 50%higher than the peak-to-peak inductor ripple cur­rent.

CATCH DIODE

Buck regulators require a diode to provide a return path for
the inductor current when the switch is off. This diode should
be located close to the LM2574 using short leads and short
printed circuit traces.

Because of their fast switching speed and low forward volt­age drop, Schottky diodes provide the best efficiency, espe­cially in low output voltage switching regulators (less than
5V). Fast-Recovery, High-Efficiency, or Ultra-Fast Recovery
diodes are also suitable, but some types with an abrupt turn­off characteristic may cause instability and EMI problems. A
fast-recovery diode with soft recovery characteristics is a
better choice. Standard 60 Hz diodes (e.g., 1N4001 or
1N5400, etc.) are also not suitable. See

Figure 9

for Schot-

tky and “soft” fast-recovery diode selection guide.

OUTPUT VOLTAGE RIPPLE AND TRANSIENTS

The output voltage of a switching power supply will contain a
sawtooth ripple voltage at the switcher frequency, typically
about 1%of the output voltage, and may also contain short
voltage spikes at the peaks of the sawtooth waveform.

The output ripple voltage is due mainly to the inductor saw­tooth ripple current multiplied by the ESR of the output ca­pacitor. (See the inductor selection in the application hints.)

The voltage spikes are present because of the the fast
switching action of the output switch, and the parasitic induc­tance of the output filter capacitor. To minimize these voltage
spikes, special low inductance capacitors can be used, and
their lead lengths must be kept short. Wiring inductance,
stray capacitance, as well as the scope probe used to evalu­ate these transients, all contribute to the amplitude of these
spikes.

An additional small LC filter (20 µH & 100 µF) can be added
to the output (as shown in

Figure 16

) to further reduce the
amount of output ripple and transients. A 10 x reduction in
output ripple voltage and transients is possible with this filter.

FEEDBACK CONNECTION

The LM2574 (fixed voltage versions) feedback pin must be
wired to the output voltage point of the switching power sup­ply. When using the adjustable version, physically locate
both output voltage programming resistors near the LM2574
to avoid picking up unwanted noise. Avoid using resistors
greater than 100 kΩ because of the increased chance of
noise pickup.

ON /OFF INPUT

For normal operation, the ON /OFF pin should be grounded
or driven with a low-level TTL voltage (typically below 1.6V).
To put the regulator into standby mode, drive this pin with a
high-level TTL or CMOS signal. The ON /OFF pin can be
safely pulled up to +VINwithout a resistor in series with it.
The ON /OFF pin should not be left open.

GROUNDING

The 8-pin molded DIP and the 14-pin surface mount pack­age have separate power and signal ground pins. Both
ground pins should be soldered directly to wide printed cir­cuit board copper traces to assure low inductance connec­tions and good thermal properties.

THERMAL CONSIDERATIONS

The 8-pin DIP (N) package and the 14-pin Surface Mount
(M) package are molded plastic packages with solid copper
lead frames. The copper lead frame conducts the majority of
the heat from the die, through the leads, to the printed circuit
board copper, which acts as the heat sink. For best thermal
performance, wide copper traces should be used, and all
ground and unused pins should be soldered to generous
amounts of printed circuit board copper, such as a ground
plane. Large areas of copper provide the best transfer of
heat (lower thermal resistance) to the surrounding air, and
even double-sided or multilayer boards provide better heat
paths to the surrounding air. Unless the power levels are
small, using a socket for the 8-pin package is not recom­mended because of the additional thermal resistance it intro­duces, and the resultant higher junction temperature.

Because of the 0.5A current rating of the LM2574, the total
package power dissipation for this switcher is quite low,
ranging from approximately 0.1W up to 0.75W under varying
conditions. In a carefully engineered printed circuit board,
both the N and the M package can easily dissipate up to

0.75W, even at ambient temperatures of 60˚C, and still keep
the maximum junction temperature below 125˚C.

A curve displaying thermal resistance vs. pc board area for
the two packages is shown in the Typical Performance Char­acteristics curves section of this data sheet.

These thermal resistance numbers are approximate, and
there can be many factors that will affect the final thermal re­sistance. Some of these factors include board size, shape,
thickness, position, location, and board temperature. Other
factors are, the area of printed circuit copper, copper thick­ness, trace width, multi-layer, single- or double-sided, and
the amount of solder on the board. The effectiveness of the
pc board to dissipate heat also depends on the size, number
and spacing of other components on the board. Further­more, some of these components, such as the catch diode
and inductor will generate some additional heat. Also, the
thermal resistance decreases as the power level increases
because of the increased air current activity at the higher
power levels, and the lower surface to air resistance coeffi­cient at higher temperatures.

www.national.com 18

Application Hints (Continued)

The data sheet thermal resistance curves and the thermal
model in

Switchers Made Simple

software (version 3.3)
can estimate the maximum junction temperature based on
operating conditions. ln addition, the junction temperature
can be estimated in actual circuit operation by using the fol­lowing equation.

T

j

=

T

cu

+(θ

j-cuxPD

)

With the switcher operating under worst case conditions and
all other components on the board in the intended enclosure,
measure the copper temperature (T

cu

) near the IC. This can
be done by temporarily soldering a small thermocouple to
the pc board copper near the IC, or by holding a small ther­mocouple on the pc board copper using thermal grease for
good thermal conduction.

The thermal resistance (θ

j-cu

) for the two packages is:

θ

j-cu

=

42˚C/W for the N-8 package

θ

j-cu

=

52˚C/W for the M-14 package

The power dissipation (P

D

) for the IC could be measured, or

it can be estimated by using the formula:

Where ISis obtained from the typical supply current curve
(adjustable version use the supply current vs. duty cycle
curve).

Additional Applications

INVERTING REGULATOR

Figure 11

shows a LM2574-12 in a buck-boost configuration
to generate a negative 12V output from a positive input volt­age. This circuit bootstraps the regulator’s ground pin to the
negative output voltage, then by grounding the feedback pin,
the regulator senses the inverted output voltage and regu­lates it to −12V.

For an input voltage of 8V or more, the maximum available
output current in this configuration is approximately 100 mA.
At lighter loads, the minimum input voltage required drops to
approximately 4.7V.

The switch currents in this buck-boost configuration are
higher than in the standard buck-mode design, thus lowering
the available output current. Also, the start-up input current
of the buck-boost converter is higher than the standard buck­mode regulator, and this may overload an input power
source with a current limit less than 0.6A. Using a delayed
turn-on or an undervoltage lockout circuit (described in the
next section) would allow the input voltage to rise to a high
enough level before the switcher would be allowed to turn
on.

Because of the structural differences between the buck and
the buck-boost regulator topologies, the buck regulator de­sign procedure section can not be used to to select the in­ductor or the output capacitor. The recommended range of
inductor values for the buck-boost design is between 68 µH
and 220 µH, and the output capacitor values must be larger
than what is normally required for buck designs. Low input
voltages or high output currents require a large value output
capacitor (in the thousands of micro Farads).

The peak inductor current, which is the same as the peak
switch current, can be calculated from the following formula:

Where f

osc

=

52 kHz. Under normal continuous inductor cur-

rent operating conditions, the minimum V

IN

represents the
worst case. Select an inductor that is rated for the peak cur­rent anticipated.

Also, the maximum voltage appearing across the regulator is
the absolute sum of the input and output voltage. For a −12V
output, the maximum input voltage for the LM2574 is +28V,
or +48V for the LM2574HV.

The

Switchers Made Simple

version 3.3) design software
can be used to determine the feasibility of regulator designs
using different topologies, different input-output parameters,
different components, etc.

NEGATIVE BOOST REGULATOR

Another variation on the buck-boost topology is the negative
boost configuration. The circuit in

Figure 12

accepts an input

voltage ranging from −5V to −12V and provides a regulated

−12V output. Input voltages greater than −12V will cause the
output to rise above −12V, but will not damage the regulator.

DS011394-19

Note: Pin numbers are for the 8-pin DIP package.

FIGURE 11. Inverting Buck-Boost Develops −12V

www.national.com19

Additional Applications (Continued)

Because of the boosting function of this type of regulator, the
switch current is relatively high, especially at low input volt­ages. Output load current limitations are a result of the maxi­mum current rating of the switch. Also, boost regulators can
not provide current limiting load protection in the event of a
shorted load, so some other means (such as a fuse) may be
necessary.

UNDERVOLTAGE LOCKOUT

In some applications it is desirable to keep the regulator off
until the input voltage reaches a certain threshold. An under­voltage lockout circuit which accomplishes this task is shown
in

Figure 13

while

Figure 14

shows the same circuit applied
to a buck-boost configuration. These circuits keep the regu­lator off until the input voltage reaches a predetermined
level.

V

TH

≈ VZ1+2VBE(Q1)

DELAYED STARTUP

The ON /OFF pin can be used to provide a delayed startup
feature as shown in

Figure 15

. With an input voltage of 20V
and for the part values shown, the circuit provides approxi­mately 10 ms of delay time before the circuit begins switch­ing. Increasing the RC time constant can provide longer de­lay times. But excessively large RC time constants can
cause problems with input voltages that are high in 60 Hz or
120 Hz ripple, by coupling the ripple into the ON /OFF pin.

ADJUSTABLE OUTPUT, LOW-RIPPLE POWER SUPPLY

A 500 mA power supply that features an adjustable output
voltage is shown in

Figure 16

.An additional L-C filter that re­duces the output ripple by a factor of 10 or more is included
in this circuit.

DS011394-20

Note: Pin numbers are for 8-pin DIP package.

FIGURE 12. Negative Boost

DS011394-21

Note: Complete circuit not shown.
Note: Pin numbers are for 8-pin DIP package.

FIGURE 13. Undervoltage Lockout for Buck Circuit

DS011394-22

Note: Complete circuit not shown (see

Figure 11

).

Note: Pin numbers are for 8-pin DIP package.

FIGURE 14. Undervoltage Lockout

for Buck-Boost Circuit

DS011394-23

Note: Complete circuit not shown.
Note: Pin numbers are for 8-pin DIP package.

FIGURE 15. Delayed Startup

www.national.com 20

Additional Applications (Continued)

Definition of Terms

BUCK REGULATOR

A switching regulator topology in which a higher voltage is
converted to a lower voltage. Also known as a step-down
switching regulator.

BUCK-BOOST REGULATOR

A switching regulator topology in which a positive voltage is
converted to a negative voltage without a transformer.

DUTY CYCLE (D)

Ratio of the output switch’s on-time to the oscillator period.

CATCH DIODE OR CURRENT STEERING DIODE

The diode which provides a return path for the load current
when the LM2574 switch is OFF.

EFFICIENCY (η)

The proportion of input power actually delivered to the load.

CAPACITOR EQUIVALENT SERIES RESISTANCE (ESR)

The purely resistive component of a real capacitor’s imped­ance (see

Figure 17

). It causes power loss resulting in ca­pacitor heating, which directly affects the capacitor’s operat­ing lifetime. When used as a switching regulator output filter,
higher ESR values result in higher output ripple voltages.

Most standard aluminum electrolytic capacitors in the
100 µF–1000 µF range have 0.5Ω to 0.1Ω ESR. Higher-

grade capacitors (“low-ESR”, “high-frequency”, or “low­inductance”) in the 100 µF–1000 µF range generally have
ESR of less than 0.15Ω.

EQUIVALENT SERIES INDUCTANCE (ESL)

The pure inductance component of a capacitor (see

Figure

17

). The amount of inductance is determined to a large ex­tent on the capacitor’s construction. In a buck regulator, this
unwanted inductance causes voltage spikes to appear on
the output.

OUTPUT RIPPLE VOLTAGE

The AC component of the switching regulator’s output volt­age. It is usually dominated by the output capacitor’s ESR
multiplied by the inductor’s ripple current (∆I

IND

). The peak­to-peak value of this sawtooth ripple current can be deter­mined by reading the Inductor Ripple Current section of the
Application hints.

CAPACITOR RIPPLE CURRENT

RMS value of the maximum allowable alternating current at
which a capacitor can be operated continuously at a speci­fied temperature.

STANDBY QUIESCENT CURRENT (I

STBY

)

Supply current required by the LM2574 when in the standby
mode (ON/OFF pin is driven to TTL-high voltage, thus turn­ing the output switch OFF).

INDUCTOR RIPPLE CURRENT (∆I

IND

)

The peak-to-peak value of the inductor current waveform,
typically a sawtooth waveform when the regulator is operat­ing in the continuous mode (vs. discontinuous mode).

CONTINUOUS/DISCONTINUOUS MODE OPERATION

Relates to the inductor current. In the continuous mode, the
inductor current is always flowing and never drops to zero,
vs. the discontinuous mode, where the inductor current
drops to zero for a period of time in the normal switching
cycle.

DS011394-24

Note: Pin numbers are for 8-pin DIP package.

FIGURE 16. 1.2V to 55V Adjustable 500 mA Power Supply with Low Output Ripple

DS011394-25

FIGURE 17. Simple Model of a Real Capacitor

www.national.com21

Definition of Terms (Continued)

INDUCTOR SATURATION

The condition which exists when an inductor cannot hold any
more magnetic flux. When an inductor saturates, the induc­tor appears less inductiveand the resistive component domi­nates. Inductor current is then limited only by the DC resis­tance of the wire and the available source current.

OPERATING VOLT MICROSECOND CONSTANT (E

•

Top)

The product (in VoIt

•

µs) of the voltage applied to the inductor

and the time the voltage is applied. This E

•

Topconstant 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.

www.national.com 22

Physical Dimensions inches (millimeters) unless otherwise noted

14-Lead Wide Surface Mount (WM)

Order Number LM2574M-3.3, LM2574HVM-3.3, LM2574M-5.0,

LM2574HVM-5.0, LM2574M-12, LM2574HVM-12, LM2574M-15,

LM2574HVM-15, LM2574M-ADJ or LM2574HVM-ADJ

NS Package Number M14B

www.national.com23

Physical Dimensions inches (millimeters) unless otherwise noted (Continued)

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NATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT
DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT AND GENERAL
COUNSEL OF NATIONAL SEMICONDUCTOR CORPORATION. As used herein:

1. Life support devices or systems are devices or
systems which, (a) are intended for surgical implant
into the body, or (b) support or sustain life, and
whose failure to perform when properly used in
accordance with instructions for use provided in the
labeling, can be reasonably expected to result in a
significant injury to the user.

2. A critical component is any component of a life
support device or system whose failure to perform
can be reasonably expected to cause the failure of
the life support device or system, or to affect its
safety or effectiveness.

National Semiconductor
Corporation

Americas
Tel: 1-800-272-9959
Fax: 1-800-737-7018
Email: support@nsc.com

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Fax: +49 (0) 1 80-530 85 86

Email: europe.support@nsc.com
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Tel: 65-2544466
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Email: sea.support@nsc.com

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Japan Ltd.

Tel: 81-3-5639-7560
Fax: 81-3-5639-7507

www.national.com

8-Lead DIP (N)

Order Number LM2574M-3.3, LM2574HVM-3.3, LM2574HVN-5.0, LM2574HVN-12,

LM2574HVN-15, LM2574HVN-ADJ, LM2574N-5.0,

LM2574N-12, LM2574N-15 or LM2574N-ADJ

NS Package Number N08A

LM2574/LM2574HV SIMPLE SWITCHER 0.5A Step-Down Voltage Regulator

National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves the right at any time without notice to change said circuitry and specifications.