Rainbow Electronics MAX15041 User Manual

MAX15041

Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM

Step-Down DC-DC Regulator with Internal Switches

______________________________________________________________________________________

13

If C

OUT

is large, or exhibits a lossy equivalent series

resistance (large ESR), the circuit’s second zero may
come into play around the crossover frequency (f

CO

=

ω

CO

/2

π). In this case, a third pole may be induced by a

second (optional) small compensation capacitor (C

CC

),

connected from COMP to SGND.

The loop response’s fourth asymptote (in bold, Figure
2) is the one of interest in establishing the desired
crossover frequency (and determining the compensa-
tion component values). A lower crossover frequency
provides for stable closed-loop operation at the
expense of a slower load and line transient response.
Increasing the crossover frequency improves the tran-
sient response at the (potential) cost of system instabili-
ty. A standard rule of thumb sets the crossover
frequency ≤ 1/10 of the switching frequency (for the
MAX15041, this is approximately 35kHz for the 350kHz
fixed switching frequency).

First, select the passive and active power components
that meet the application’s requirements. Then, choose
the small-signal compensation components to achieve

the desired closed-loop frequency response and phase
margin as outlined in the

Closing the Loop: Designing

the Compensation Circuitry

section.

Closing the Loop: Designing the

Compensation Circuitry

1) Select the desired crossover frequency. Choose f

CO

equal to 1/10

th

of f

SW

, or f

CO

≈ 35kHz.

2) Select R

C

using the transfer-loop’s fourth asymptote

gain (assuming f

CO

> f

P1

, f

P2

, and f

Z1

and setting

the overall loop gain to unity) as follows:

therefore:

R

V

V

f

C

ESR R

g

G

C

OUT

FB

CO

OUT

LOAD

MV

MOD

=

Ч

Ч

Ч

Ч

+

(

)

Ч

Ч

2

π

R

R

LOAD

1

1

2

=

Ч

Ч

Ч

Ч

Ч

Ч

Ч

Ч

V

V

g

R

G

R

f

C

ES

FB

OUT

MV

C

MOD

LOAD

CO

OUT

π

R

R R

LOAD

+

(

)

1ST ASYMPTOTE
V

FB

x

V

OUT

-1

x

10

AVEA[dB]/20

x

G

MOD

x

R

LOAD

2ND ASYMPTOTE
V

FB

x

V

OUT

-1

x

g

MV

x

(C

C

)

-1

x

G

MOD

x

R

LOAD

3RD ASYMPTOTE
V

FB

x

V

OUT

-1

x

g

MV

x

(C

C

)

-1

x

G

MOD

x

R

LOAD

x

(C

OUT

(ESR + R

LOAD

))

-1

4TH ASYMPTOTE
V

FB

x V

OUT

-1

x g

MV

x R

C

x G

MOD

x R

LOAD

x (C

OUT

(ESR + R

LOAD

))

-1

5TH ASYMPTOTE

V

FB

x

V

OUT

-1

x

g

MV

x

R

C

x

G

MOD

x

(ESR || R

LOAD

)

6TH ASYMPTOTE

V

FB

x

V

OUT

-1

x

g

MV

x

(C

CC

)

-1

x

G

MOD

x

(ESR || R

LOAD

)

UNITY

GAIN

RAD/S

3RD POLE

(C

CC

R

C

)

-1

2ND ZERO

(C

OUT

ESR)

-1

1ST ZERO
(C

C

R

C

)

-1

2ND POLE

(C

OUT

(ESR + R

LOAD

))

-1

1ST POLE

gmV x (10

AVEA[dB]/20

C

C

)

-1

CO

Figure 2. Asymptotic Loop Response of Peak Current-Mode Regulator