Rainbow Electronics MAX15020 User Manual

MAX15020

2A, 40V Step-Down DC-DC Converter with
Dynamic Output-Voltage Programming

14

______________________________________________________________________________________

Compensation Design

The MAX15020 uses a voltage-mode control scheme
that regulates the output voltage by comparing the
error-amplifier output (COMP) with an internal ramp to
produce the required duty cycle. The output lowpass
LC filter creates a double pole at the resonant frequen-
cy, which has a gain drop of -40dB/decade. The error
amplifier must compensate for this gain drop and
phase shift to achieve a stable closed-loop system.

The basic regulator loop consists of a power modulator,
an output feedback divider, and a voltage error amplifi-
er. The power modulator has a DC gain set by V

IN

/

V

RAMP

, with a double pole and a single zero set by the

output inductance (L), the output capacitance (C

OUT

)

(C6 in the Figure 2) and its ESR. The power modulator
incorporates a voltage feed-forward feature, which auto-
matically adjusts for variations in the input voltage
resulting in a DC gain of 9. The following equations
define the power modulator:

The switching frequency is internally set at 300kHz or
500kHz, or can vary from 100kHz to 500kHz when driven
with an external SYNC signal. The crossover frequency
(f

C

), which is the frequency when the closed-loop gain is

equal to unity, should be set as f

SW

/ 2π or lower.

The error amplifier must provide a gain and phase
bump to compensate for the rapid gain and phase loss
from the LC double pole. This is accomplished by utiliz-
ing a Type 3 compensator that introduces two zeros
and three poles into the control loop. The error amplifier
has a low-frequency pole (f

P1

) near the origin.

In reference to Figures 3 and 4, the two zeros are at:

And the higher frequency poles are at:

Compensation when f

C

< f

ESR

Figure 3 shows the error-amplifier feedback as well as
its gain response for circuits that use low-ESR output
capacitors (ceramic). In this case f

ZESR

occurs after f

C

.

f

Z1

is set to 0.8 x f

LC(MOD)

and f

Z2

is set to f

LC

to com-

pensate for the gain and phase loss due to the double
pole. Choose the inductor (L) and output capacitor
(C

OUT

) as described in the

Inductor Selection

and

Output Capacitor Selection

sections.

Choose a value for the feedback resistor R6 in Figure 3
(values between 1kΩ and 10kΩ are adequate).
C12 is then calculated as:

f

C

occurs between f

Z2

and f

P2

. The error-amplifier gain

(GEA) at f

C

is due primarily to C11 and R9.

Therefore, GEA(f

C

) = 2π x f

C

x C11 x R9 and the modu-

lator gain at f

C

is:

Since G

EA(fC)

x G

MOD(fC)

= 1, C11 is calculated by:

f

P2

is set at 1/2 the switching frequency (f

SW

). R6 is

then calculated by:

Since R7 >> R6, R7 + R6 can be approximated as R7.
R7 is then calculated as:

f

P3

is set at 5 x f

C

. Therefore, C13 is calculated as:

C

C

C

R

f

P

13

12

2

12

9

1

3

=

Ч

Ч

Ч

−

π

R

f

C

LC

7

1

2

11

=

Ч

Ч

π

R

C

f

SW

6

1

2

11 0 5

=

Ч

Ч

Ч

π

.

C

f

L

C

R

G

C

OUT

MOD DC

11

2

9

=

Ч Ч

Ч

Ч

π

(

)

G

G

L

C

f

MOD fC

MOD DC

OUT

C

(

)

(

)

(

)

=

Ч Ч

Ч

2

2

2

π

C

f

R

LC

12

1

2

0 8

9

=

Ч

Ч

Ч

π

.

f

R

C

and f

R

C

C

C

C

P

P

2

3

1

2

6

11

1

2

9

12

13

12

13

=

Ч

Ч

=

Ч

Ч

Ч
+

⎛
⎝⎜

⎞
⎠⎟

π

π

f

R

C

and f

R

R

C

Z

Z

1

2

1

2

9

12

1

2

6

7

11

=

Ч

Ч

=

Ч

+

Ч

π

π

(

)

G

V

V

f

L

C

f

C

ESR

MOD DC

IN

RAMP

LC

ESR

OUT

(

)

=

=

=

Ч

=

Ч

Ч

9

1

2

1

2

π

π