DC053A-A - ANALOG DEVICES - Product.Network

DEMO MANUAL DC053A

PARAMETER CONDITIONS MIN TYP MAX UNITS

Output Voltage R2 = R3 = 1% (Note 1) 11.60 12.04 12.50 V

Output Current V

= 5V 250 mA

Input Voltage Range (Note 2) 2.7 11 V

Switching Frequency LT1372 500 kHz

LT1377 1 MHz

Output Ripple Voltage I

LOAD

= 250mA 150 mV

P-P

LOAD

= 250mA (Note 3) 80 mV

P-P

OUT2

, I

LOAD

= 250mA 3 mV

P-P

Supply Current I

LOAD

= 0A 4.5 mA

Shutdown Supply Current I

LOAD

= 0A, V

S/S

= 0V (Note 4) 100 µA

DEMO MANUAL DC053A

LT1372/LT1377 5V to 12V

Step-Up Converters

NO-DESIGN SWITCHER

Note 3: To reduce output ripple voltage, change C7 to a 2.2µF ceramic

chip capacitor (Tokin 1E225ZY5U-C203).

Note 4: Single inductor step-up converters have a direct path from the

input supply to the output, and therefore draw some supply current even

when the LT1372/LT1377 is in shutdown. Shutdown supply current will

also increase with the addition of an output load. Applications are

available which remove this direct path and reduce shutdown supply

current to 30µA maximum, independent of loading.

Note 1: The reference voltage tolerance of the LT1372/LT1377 is ±1.6%

over temperature. Output voltage is a worst-case summation of R2, R3

and reference tolerances, plus feedback input current times R3. For a

tighter output voltage range, use lower tolerance feedback resistors, or a

fixed voltage version of the LT1372/LT1377 (consult Linear Technology

Marketing).

Note 2: Increase L1 to 10µH for V

< 4.75V or to 15µH for V

< 3.3V.

TYPICAL PERFOR A CE CHARACTERISTICS A D BOARD PHOTO

INPUT VOLTAGE (V)

MAXIMUM OUTPUT CURRENT (A)

1.0

0.9

0.8

0.7

0.6

0.5

0.4

0.3

0.2

0.1

0

46711

DC053A G02

35 8

OUT

= 12V

*INCREASE L1 TO 10µH FOR V

< 4.75V

OR TO 15µH FOR V

< 3.3V

DC053A BP

OUTPUT CURRENT (A)

0.01

EFFICIENCY (%)

0.1 1

DC053A G01

100 V

= 5V

Maximum Output Current vs Input Voltage*

12V Output Efficiency

PERFOR A CE SU ARY

UWWW

A = 25°C, VIN = 5V, S/S pin open, unless otherwise specified.

DESCRIPTIO

Demonstration board DC053A is a complete DC/DC step-

up switching regulator using the LT

1372 or the LT1377

constant frequency, high efficiency converter in an 8-pin

SOIC package. High frequency switching allows the use of

, LTC and LT are registered trademarks of Linear Technology Corporation.

very small inductors, making this all surface mount solu-

tion ideal for space conscious systems.

Component Side

DEMO MANUAL DC053A

PARTS LIST

REFERENCE

DESIGNATOR QUANTITY PART NUMBER DESCRIPTION VENDOR TELEPHONE

C1 1 AVX 12065C473MAT2A 0.047µF, 50V, 20%, X7R Capacitor AVX (803) 946-0362

C2 1 AVX 12065C472MAT2A 0.0047µF, 50V, 20%, X7R Capacitor AVX (803) 946-0362

C3, C4 2 AVX TPSD226M025R0200 22µF, 25V, 20%, Tantalum Capacitor AVX (207) 282-5111

C5, C6 0 Capacitor, Optional (See Text)

C7 1 AVX 12065C104MAT2A 0.1µF, 50V, 20%, X7R Capacitor AVX (803) 946-0362

D1 1 MBRS130LT3 30V, 1A, Schottky Diode Motorola (602) 244-5768

E1 to E5 5 1502-2 2-Turret, 0.092 Terminal Keystone (718) 956-8900

E6 0 Terminal, Optional (See Text)

L1 1 CD43-4R7KC 4.7µH, SMT Inductor Sumida (708) 956-0666

L2 0 Inductor, Optional (See Text)

R1 1 AVX CR32-202J-T 2k, 5%, SMT1206 Resistor AVX (803) 946-0524

R2 1 AVX CR32-6191F-T 6.19k, 1%, SMT 1206 Resistor AVX (803) 946-0524

R3 1 AVX CR32-5362F-T 53.6k, 1%, SMT-1206 Resistor AVX (803) 946-0524

U1* 1 LT1372CS8 SO-8, LT1372, Switching Regulator IC LTC®(408) 432-1900

U1* 1 LT1377CS8 SO-8, LT1377, Switching Regulator IC LTC (408) 432-1900

*The two demo board versions are:

DC53A-A: U1 = LT1372CS8

DC53A-B: U1 = LT1377CS8

PACKAGE A D SCHE ATIC DIAGRA SM

W UW

U1

LT1372/LT1377



*SUMIDA CD43-4R7KC

**MILLER PM20-1R0K

NOTES: UNLESS OTHERWISE SPECIFIED

1. ALL RESISTOR VALUES OHMS, 1/8W, 5%

2. ALL CAPACITOR VALUES µF, 50V, 20%

3. ALL POLARIZED CAPACITOR AVX TPS SERIES OR EQUIVALENT

4. PLACE C7 AT THE LOAD

GND

DC053A F01

GNDS

NFB

S/S

D1

MBRS130

C3

22µF

25V

C1

0.047µF

C2

0.0047µFR1

R3

53.6k, 1%

R2

6.19k

OUT

12V

0.25A

C6

4.7µF

25V

C4

22µF

25V

OUT2



12V

0.25A

L1*

4.7µH

L2**

1µH

OPTIONAL

OUTPUT FILTER

C5

OMIT

C7

0.1µF

(NOTE 4)

E5E3

Figure 1. Switching Regulator 5V to 12V, 0.25A; 500kHz for the LT1372 and 1MHz for the LT1377

1

2

3

8

7

6

5



TOP VIEW



FB

NFB

S/S



GND

GNDS

S8 PACKAGE

8-LEAD PLASTIC SO

LT1372CS8

LT1377CS8

DEMO MANUAL DC053A

OPERATIO

DC053A Operation

This DC053A demonstration board is intended for evalu-

ating the LT1372/LT1377 switching regulator in a typical

step-up application. Solid turret terminals are provided for

easy connection to test equipment. A device pinout and

board schematic are shown in Figure 1. Please refer to the

LT1372/LT1377 data sheet for additional specifications

and applications information. Also useful is Linear

Technology’s SwitcherCAD software when creating your

own designs.

Hook-Up

Connect the input supply and measurement instruments

to the V

and GND terminals on the left side of the board.

The S/S pin (synchronization/shutdown) can be con-

nected to V

or left open. Connect the output load and

measurement instruments to the V

OUT

and GND terminals

on the right side of the board. V

OUT2

is for evaluating an

optional output filter and can be left open.

LT1372/LT1377 Operation

The LT1372/LT1377 are monolithic high frequency cur-

rent mode switchers. Each device can operate from an

input supply range of 2.7V to 25V (DC053A maximum

= 11V), and draws only 4mA quiescent current. The on-

chip current limited power switch is guaranteed to 1.5A

minimum switch current with a 0.5Ω typical “on” resis-

tance and a 35V minimum breakdown voltage. Running at

a fixed frequency of 500kHz (LT1372) or 1MHz (LT1377),

switching can also be easily synchronized to a higher

frequency by driving the S/S pin with a logic level source.

Shutdown is activated by pulling the S/S pin below 0.6V,

which reduces device supply current to 30µA maximum.

Under normal operating conditions, a 1.245V reference

voltage is developed at the Feedback pin. The output

voltage is set by R2 and R3, where V

OUT

= V

REF

(1 + R3/R2).

Although not used in this application, the part also has a

Negative Feedback pin (NFB) which can be used to set the

output voltage of positive-to-negative converters. When in

use, a –2.49V reference voltage is developed at the

NFB pin.

The V

pin is the output of the error amplifier. During

normal regulator operation this pin sits at a voltage be-

tween 1V (low output current) and 1.9V (high output

current). The V

pin is also where loop frequency compen-

sation is performed with an RC network to ground.

COMPONENTS

Inductors

The inductor is a Sumida CD43-4R7KC, which is a 4.7µH

unshielded ferrite unit. It was selected for low cost and

small physical size. Similar units are available from other

manufacturers. There are benefits to higher frequency

switching (1MHz LT1377 versus 500kHz LT1372) and

higher value inductors. Both higher frequency switching

and higher value inductors allow more output current

because they reduce peak current in the switch. Both also

reduce input ripple voltage and output ripple voltage. An

inductor with a closed magnetic path (i.e., E-core or

toroid) may also be chosen to reduce the RFI/EMI of the

circuit.

Capacitors (and Input/Output Ripple Voltage)

The capacitors on this board are low ESR (Effective Series

Resistance) tantalum units specifically designed for switch-

mode power supply applications. At these high frequen-

cies, input and output ripple voltages are more a function

of the ESR of the capacitor than the capacitance value. For

example, at 500kHz a 22µF capacitor has a capacitive

reactance of only 0.014Ω, which is much lower than the

limiting 0.2Ω maximum ESR of the capacitors used.

Therefore, if a reduction in input or output ripple voltage is

required, use two or more capacitors in parallel instead of

a larger value capacitor. If very low output ripple voltage is

needed, adding an output LC filter may be a cheaper

solution. The output contains very narrow voltage spikes

because of the parasitic inductance of the output capaci-

tor. Due to their high frequency nature, the amplitude of

the spikes is determined by the ESL (Effective Series

Inductance) of the output capacitor. But this also makes

them easy to filter. Small 0.1µF ceramic chip capacitors

work well in reducing the spikes, and if the traces connect-

ing to the load are a few inches or more, the parasitic

inductance of the traces combined with any local load

bypass capacitor will virtually eliminate the spikes at the

load.

Information furnished by Linear Technology Corporation is believed to be accurate and reliable.

However, no responsibility is assumed for its use. Linear Technology Corporation makes no represen-

tation that the interconnection of its circuits as described herein will not infringe on existing patent rights.

DEMO MANUAL DC053A

Linear Technology Corporation

1630 McCarthy Blvd., Milpitas, CA 95035-7487

(408) 432-1900

●

FAX

: (408) 434-0507

●

TELEX

: 499-3977

LT/GP 0895 500 • PRINTED IN USA

 LINEAR TECHNOLOGY CORPORATION 1995

OPERATIO

Diodes

Use diodes designed for switching applications with ad-

equate current rating and fast turn on times, such as

Schottky or ultra-fast diodes. In selecting a diode, the

basic parameters of interest are forward voltage, maxi-

mum reverse voltage, average operating current and peak

current. Lower forward voltage yields higher circuit effi-

ciency and lower power dissipation in the diode. The

worst-case reverse voltage is equal to the output voltage.

The average diode current will be equal to the output

current, but the peak diode current can be many times

higher than the output current. Except for output short

conditions, peak diode current is limited to the switch

current limit of 2.4A maximum.

Thermal Considerations

Care should be taken to ensure that the worst-case input

voltage and load current conditions do not cause exces-

sive die temperatures. Please consult the LT1372/LT1377

data sheet or Linear Technology’s SwitcherCAD software

for more information.

PCB Layout

In many cases, the circuit area traces of the demonstration

board may be dropped directly into your PCB layout. If not,

there are a few things to be aware of with high frequency

converter layouts. Keep the traces connecting the Switch

(Pin 8), output diode, output capacitor and Ground pin

(Pin 7) as short as possible. This will reduce RFI and limit

the voltage spikes caused by parasitic inductance. Keep

the more sensitive components, mainly the feedback

resistors and V

pin network, away from the high current

switching components.

PCB LAYOUT A D FIL

Component Side

Solder Mask

PC FAB DRAWI G

2.000

0.200

0.400

2.000

NOTES:

1. FINISHED MATERIAL IS FR4, 0.062 THICK, 2-OZ COPPER

2. PCB WILL BE DOUBLE-SIDED WITH PLATED THROUGH-HOLES

3. PTH SIZES AFTER PLATING, 0.001 MIN WALL THICKNESS

4. SOLDER MASK BOTH SIDES USING PC401 OR EQUIVALENT

5. SILKSCREEN COMPONENT SIDE USING WHITE NONCONDUCTIVE INK

6. ALL DIMENSIONS IN INCHES, ±0.005

7. ALL HOLE SIZES AFTER PLATING, – 0 TO 0.003 MAX

 HOLE CHART

SYMBOLDIAMETER QTY PLT 

NONE 0.020 3 YES

 A 0.094 6 YES

 B 0.062 2 NO

TOTAL HOLES 11 

DC053A FAB

Component Mask Solder Side

Component Side Silkscreen