MAX15022_11 Datasheet, PDF(23/28 Page) Maxim Integrated Products – Dual, 4A/2A, 4MHz, Step-Down DC-DC Regulator with Dual LDO Controllers

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MAX15022_11 Datasheet, PDF (23/28 Pages) Maxim Integrated Products – Dual, 4A/2A, 4MHz, Step-Down DC-DC Regulator with Dual LDO Controllers

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Dual, 4A/2A, 4MHz, Step-Down DC-DC

Regulator with Dual LDO Controllers

The input capacitance to the base of the pass transistor

(CQIN), any external base-to-emitter capacitance (CBE,

see the Base-Drive Noise Reduction section), the tran-

sistorâs input resistance (RIN), and the base-to-emitter

pullup resistor (RP_) set a second pole:

( ) fPOLE2[kHz]

2Ï

CBE

CQIN

[ÂµF]

Ã RTOTAL[kâ¦]

where RTOTAL = RIN RP1/2.

To maintain the stability, at a minimum the following

condition must be satisfied:

AV Ã fPOLE1 < fPOLE2

i.e., the second pole must occur above the unity-gain

crossover. At heavy output load, we can simplify as fol-

lows:

ROUT3/4 << R1FB3/4 + R2FB3/4

CBE << CQIN â gmâPNP Ã ÏF

RP1/2

RIN

Î²

gmâPNP

And hence, the output capacitance (COUT3/4) must sat-

isfy the following equation:

COUT3/4 > Î± Ã gC_ Ã ÏF Ã Î²2

where:

Î±=

R2FB3/4

R1FB3/4 + R2FB3/4

Ã is the current gain of the PNP transistor, gC_ is the

transconductance of the internal amplifier (1.2mA/mV

typical), and ÏF is the forward transit time of the PNP

transistor. For example, using a PNP transistor with a Ã

of 120, ÏF of 400ps, gC_ = 1.2mA/mV, and Î± = 0.5 for a

1.2V output voltage, COUT must be at least 3.9ÂµF.

If the second pole occurs well after unity-gain crossover,

the linear regulator remains stable. If not, then increase

the output capacitance, COUT3/4, such that:

fPOLE2 > 2 Ã fCOUT_

If the output capacitor is a high-ESR capacitor, then

cancel the ESR zero with a pole at FB3/4. This is

accomplished by adding a capacitor (CFB3/4) from

FB3/4 to ground, such that:

CFB3/4[ÂµF]

2Ï

(R1FB3/4

R2FB3/4)[kâ¦] Ã

fESR[kHz]

For a sufficiently low output capacitance, choose a fast

PNP transistor without an excessively high Ã. Note,

selecting a transistor with a Ã that is too low can

adversely impact load regulation.

Output 3 and Output 4 Capacitors

Connect COUT (as determined above) between the lin-

ear regulatorâs output and ground, as close as possible

to the MAX15022 and the external pass transistors.

Depending on the selected pass transistor, larger

capacitor values may be required for stability (see the

Stability Requirement section).

Once the minimum capacitor value for stability is deter-

mined, verify that the linear regulatorâs output does not

contain excessive noise. Although adequate for stabili-

ty, small capacitor values can provide too much band-

width, making the linear regulator sensitive to noise.

Larger capacitor values reduce the bandwidth, thereby

reducing the regulatorâs noise sensitivity.

Base-Drive Noise Reduction

The high-impedance base driver is susceptible to sys-

tem noise, especially when the linear regulator is lightly

loaded. Capacitively coupled switching noise or induc-

tively coupled EMI on the base drive may cause fluctu-

ations in the base current, which appear as noise on

the linear regulatorâs output. To avoid this, keep the

base-driver traces away from the step-down converter

and as short as possible to minimize noise coupling.

A bypass capacitor (CBE) can be placed across the

base-to-emitter resistor. This bypass capacitor, in addi-

tion to the transistorâs input capacitance, reduces the

frequency of the second pole (fPOLE2) that could desta-

bilize the linear regulator. Therefore, the stability

requirements determine the maximum base-to-emitter

capacitance (CBE) that can be added. A capacitance

in the range of 470pF to 2200pF is recommended.

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