LM20136MHE/NOPB National Semiconductor, LM20136MHE/NOPB Datasheet - Page 14

LM20136MHE/NOPB

Manufacturer Part Number

LM20136MHE/NOPB

Description

IC REG SYNC BUCK 6A 16-TSSOP

Manufacturer

National Semiconductor

Series

PowerWise®r

Type

Step-Down (Buck)r

Datasheet

1.LM20136MHNOPB.pdf (22 pages)

Specifications of LM20136MHE/NOPB

Design Resources

LM20136 Design Spreadsheet

Internal Switch(s)

Yes

Synchronous Rectifier

Yes

Number Of Outputs

Voltage - Output

0.8 ~ 5 V

Current - Output

Frequency - Switching

410kHz

Voltage - Input

2.95 ~ 5.5 V

Operating Temperature

-40°C ~ 125°C

Mounting Type

Surface Mount

Package / Case

16-TSSOP Exposed Pad, 16-eTSSOP, 16-HTSSOP

Power - Output

2.6W

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

LM20136MHE

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Where, C

L (H) is the value of the inductor, V

voltage drop ignoring loop bandwidth considerations, ΔI

STEP

capacitor ESR, V

the set regulator output voltage. Both the tolerance and volt-

age coefficient of the capacitor needs to be examined when

designing for a specific output ripple or transient drop target.

INPUT CAPACITOR SELECTION (C

Good quality input capacitors are necessary to limit the ripple

voltage at the V

rent during the on-time. In general it is recommended to use

a ceramic capacitor for the input as they provide both a low

impedance and small footprint. One important note is to use

a good dielectric for the ceramic capacitor such as X5R or

X7R. These provide better over temperature performance

and also minimize the DC voltage derating that occurs on Y5V

capacitors. For most applications, a 22 µF, X5R, 6.3V input

capacitor is sufficient; however, additional capacitance may

be required if the connection to the input supply is far from the

PVIN pins. The input capacitor should be placed as close as

possible PVIN and PGND pins of the device.

Non-ceramic input capacitors should be selected for RMS

current rating and minimum ripple voltage. A good approxi-

mation for the required ripple current rating is given by the

relationship:

As indicated by the RMS ripple current equation, highest re-

quirement for RMS current rating occurs at 50% duty cycle.

For this case, the RMS ripple current rating of the input ca-

pacitor should be greater than half the output current. For best

performance, low ESR ceramic capacitors should be placed

in parallel with higher capacitance capacitors to provide the

best input filtering for the device.

SETTING THE OUTPUT VOLTAGE (R

The resistors R

voltage for the device. Table 1, shown below, provides sug-

gestions for R

If different output voltages are required, R

lected to be between 4.99 kΩ to 49.9 kΩ and R

calculated using the equation below.

LOOP COMPENSATION (R

The purpose of loop compensation is to meet static and dy-

namic performance requirements while maintaining adequate

stability. Optimal loop compensation depends on the output

(A) is the load step change, R

TABLE 1. Suggested Values for R

OUT

(F) is the minimum required output capacitance,

FB1

short

4.99

8.87

12.7

21.5

31.6

and R

pin while supplying most of the switch cur-

(kΩ)

and R

(V) is the input voltage, and V

FB2

for common output voltages.

FB2

open

10.2

are selected to set the output

(kΩ)

, C

)

DROOP

ESR

)

FB1

0.8

1.2

1.5

1.8

2.5

3.3

OUT

FB1

, R

(Ω) is the output

FB2

(V) is the output

and R

FB2

should be se-

)

FB1

OUT

FB2

can be

(V) is

OUT-

capacitor, inductor, load, and the device itself. Table 2 below

gives values for the compensation network that will result in

a stable system when using a 100 µF, 6.3V ceramic X5R out-

put capacitor and 1 µH inductor.

If the desired solution differs from the table above the loop

transfer function should be analyzed to optimize the loop

compensation. The overall loop transfer function is the prod-

uct of the power stage and the feedback network transfer

functions. For stability purposes, the objective is to have a

loop gain slope that is -20db/decade from a very low frequen-

cy to beyond the crossover frequency. Figure 5, shown below,

shows the transfer functions for power stage, feedback/com-

pensation network, and the resulting closed loop system for

the LM20136.

The power stage transfer function is dictated by the modula-

tor, output LC filter, and load; while the feedback transfer

TABLE 2. Recommended Compensation for

FIGURE 5. LM20136 Loop Compensation

OUT

5.00

3.30

= 100 µF, L = 1.5 µH & f

3.30

2.50

1.80

1.50

1.20

0.80

2.50

1.80

1.50

1.20

0.80

OUT

2.2

2.7

(nF) R

= 500 kHz

15.4

13.3

10.7

9.31

7.87

4.42

8.45

6.81

4.32

7.5

5.9

(kΩ)

30053913

LM20136MHE/NOPB National Semiconductor, LM20136MHE/NOPB Datasheet - Page 14

LM20136MHE/NOPB

Specifications of LM20136MHE/NOPB

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