MIC2954 Datasheet, PDF(10/12 Page) Micrel Semiconductor

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MIC2954 Datasheet, PDF (10/12 Pages) Micrel Semiconductor – 250mA Low-Dropout Regulator

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MIC2954

or about 0.01ÂµF. When doing this, the output capacitor must

be increased to 3.3ÂµF to maintain stability. These changes

reduce the output noise from 430ÂµV to 100ÂµV rms for a

100kHz bandwidth at 5V output. With the bypass capacitor

added, noise no longer scales with output voltage so that

improvements are more dramatic at higher output voltages.

Automotive Applications

The MIC2954 is ideally suited for automotive applications for

a variety of reasons. It will operate over a wide range of input

voltages with very low dropout voltages (40mV at light loads),

and very low quiescent currents (75ÂµA typical). These

features are necessary for use in battery powered systems,

such as automobiles. It is a âbulletproofâ device with the ability

to survive both reverse battery (negative transients up to 20V

below ground), and load dump (positive transients up to 60V)

conditions. A wide operating temperature range with low

temperature coefficients is yet another reason to use these

versatile regulators in automotive designs.

Thermal Calculations

Layout Considerations

The MIC2954-07BM/-08BM (8-pin surface-mount package)

has the following thermal characteristics when mounted on a

single layer copper-clad printed circuit board.

PC Board Dielectric Material

FR4

Ceramic

Î¸JA

160Â°C/W

120Â°C/W

Micrel

Multilayer boards having a ground plane, wide traces near the

pads, and large supply bus lines provide better thermal

conductivity.

Our calculations will use the âworst caseâ value of 160Â°C/W,

which assumes no ground plane, minimum trace widths, and

a FR4 material board.

Pad Layout (minimum recommended geometry)

245 mil

50 mil

150 mil

30 mil

50 mil

Nominal Power Dissipation and Die Temperature

The MIC2954-07BM/-08BM at a 55Â°C ambient temperature

will operate reliably at up to 440mW power dissipation when

mounted in the âworst caseâ manner described above. This

power level is equivalent to a die temperature of 125Â°C, the

recommended maximum temperature for nonmilitary grade

silicon integrated circuits.

Schematic Diagram

FEEDBACK

Q15A

Q42

20 kâ¦

50 kâ¦

Q40

Q41

R11

kâ¦

R11

20.6

kâ¦

Q20

R8 R10

31.4 kâ¦

150

kâ¦

180

140

27.8 kâ¦

kâ¦

R12

110

Q13

Q12

kâ¦

Q11

R30

kâ¦

50 kâ¦

13 kâ¦

50 kâ¦

10 kâ¦

ERROR

Q37

Q36

Q38

R26

60 kâ¦

Q39

Q34

R25

2.8 kâ¦

Q15B

R18

20kâ¦

Q26

Q25

Q24

OUT

Q16 Q17

R17

Q14

12 kâ¦

SENSE

R27

182 kâ¦

5V TAP

R28

60 kâ¦

R13

100

kâ¦

Q18

Q21

40 pF

R14

350

kâ¦

Q29

Q19

Q22

Q23

R15

100 kâ¦

R16

30 kâ¦

R17

10 â¦

Q28

R22

150 kâ¦

Q30 Q31

R21 8 â¦

R24

50 kâ¦

R23 60 kâ¦

SHDN

GND

DENOTES CONNECTION ON

MIC2954-02Bx/-03Bx ONLY

MIC2954

August 1999

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