FAN1577A Fairchild Semiconductor, FAN1577A Datasheet - Page 12
FAN1577A
Manufacturer Part Number
FAN1577A
Description
The FAN1577A is a high-efficiency, voltage-mode, dual-channel, synchronous DC/DC PWM controller for two independent outputs
Manufacturer
Fairchild Semiconductor
Datasheet
1.FAN1577A.pdf
(15 pages)
© 2010 Fairchild Semiconductor Corporation
FAN1577A • Rev. 1.0.0
Type II Compensation Design (for Output Capacitors with High ESR)
FAN1577A is a voltage-mode controller. The control
loop is a single-voltage feedback path, including an
error amplifier and PWM comparator, as shown in
Figure 30. To achieve fast transient response and
accurate output regulation, an adequate compensator
design is necessary. A stable control loop has a 0dB
gain crossing with -20dB/decade slope and a phase
margin greater than 45°.
1. Modulator Frequency Equations
The modulator transfer function is the small-signal
transfer function of V
dominated by a DC gain and the output filter (L
C
f
(V
ΔV
conjugate poles contributed by the LC output filter. The
output LC filter introduces a double pole, -40dB /
decade gain slope above its corner resonant frequency
and a total phase lag of 180 degrees. The resonant
frequency of the LC filter expressed as:
The next step of compensation design is to calculate
the ESR zero contributed by the ESR associated with
the output capacitance. Note that this requires that the
output capacitor have enough ESR to satisfy stability
requirements. The ESR zero of the output capacitor is
expressed as:
ESR
f
f
P(LC)
( Z
O
IN
) with a double-pole frequency at f
RAMP
ESR
. The DC gain of the modulator is the input voltage
) divided by the peak-to-peak oscillator voltage
)
=
(=1.6V). The first step is to calculate the complex
=
2
π
2
π
×
×
C
L
1
O
O
Figure 30.
1
×
×
ESR
C
O
OUT
/V
E/A
Closed Loop
. This transfer function is
LC
and a zero at
O
and
(5)
(6)
12
2. Compensation Frequency Equations
The compensation network consists of the error
amplifier and the impedance networks Z
Figure 31 shows.
Compensation gain uses external impedance networks
Z
High crossover frequency is desirable for fast transient
response, but often jeopardizes system stability. To
cancel one of the LC filter poles, place the zero before
the LC filter resonant frequency. Place the zero at 75%
of the LC filter resonant frequency. Crossover frequency
should be higher than the ESR zero, but less than 1/5
of the switching frequency. The second pole should be
placed at half the switching frequency.
C
f
f
f
P
Z
P
1
1
2
and Z
=
=
=
0
2
2
π
π
×
×
f
R
R
to provide a stable high-bandwidth loop.
1
Figure 31.
2
2
×
×
1
C
(
C
2
1
//
C
2
)
Compensation Loop
www.fairchildsemi.com
C
and Z
f
(7)
as
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