FSEZ1016A データシートの表示(PDF) - Fairchild Semiconductor
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FSEZ1016A Datasheet PDF : 16 Pages
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Functional Description
Figure 24 shows the basic circuit diagram of a primary-
side regulated flyback converter, with typical waveforms
shown in Figure 25. Generally, discontinuous
conduction mode (DCM) operation is preferred for
primary-side regulation because it allows better output
regulation. The operation principles of DCM flyback
converter are as follows:
During the MOSFET ON time (tON), input voltage (VDL) is
applied across the primary-side inductor (Lm). Then
MOSFET current (Ids) increases linearly from zero to the
peak value (Ipk). During this time, the energy is drawn
from the input and stored in the inductor.
When the MOSFET is turned off, the energy stored in
the inductor forces the rectifier diode (D) to turn on.
While the diode is conducting, the output voltage (VO),
together with diode forward-voltage drop (VF), are
applied across the secondary-side inductor (Lm×Ns2/
Np2) and the diode current (ID) decreases linearly from
the peak value (Ipk× Np/Ns) to zero. At the end of
inductor current discharge time (tDIS), all the energy
stored in the inductor has been delivered to the output.
When the diode current reaches zero, the transformer
auxiliary winding voltage (VW) begins to oscillate by the
resonance between the primary-side inductor (Lm) and
the effective capacitor loaded across MOSFET.
During the inductor current discharge time, the sum of
output voltage and diode forward-voltage drop is
reflected to the auxiliary winding side as (VO+VF)×
NA/NS. Since the diode forward-voltage drop decreases
as current decreases, the auxiliary winding voltage
reflects the output voltage best at the end of diode
conduction time where the diode current diminishes to
zero. By sampling the winding voltage at the end of the
diode conduction time, the output voltage information
can be obtained. The internal error amplifier for output
voltage regulation (EA_V) compares the sampled
voltage with internal precise reference to generate error
voltage (VCOMV), which determines the duty cycle of the
MOSFET in CV mode.
Meanwhile, the output current can be estimated using
the peak drain current and inductor current discharge
time since output current is the same as the average of
the diode current in steady state.
The output current estimator detects the peak value of
the drain current by a peak detection circuit and
calculates the output current by the inductor discharge
time (tDIS) and switching period (tS). This output
information is compared with the internal precise
reference to generate error voltage (VCOMI), which
determines the duty cycle of the MOSFET in CC mode.
With
Fairchild’s
innovative
technique
TRUECURRENT™, constant current (CC) output can
be precisely controlled.
Of the two error voltages, VCOMV and VCOMI, the smaller
determines the duty cycle. During constant voltage
regulation mode, VCOMV determines the duty cycle while
VCOMI is saturated to HIGH. During constant current
regulation mode, VCOMI determines the duty cycle while
VCOMV is saturated to HIGH.
VAC
Np:Ns
ID
IO
D
+
V DL
-
+
Lm
+ VF -
L
VO
O
A
D
-
EA_I
IO
Estimator
VCOMI Ref
PWM
Control
t DIS
Detector
V COMV
EA_V
VO
Estimator
Ref
Primary-Side Regulation
Controller
CS
RCS
VS
VDD
RS1
RS2
Ids
NA
+
Vw
-
Figure 24. Simplified PSR Flyback Converter Circuit
Ids (MOSFET Drain-to-Source Current)
I pk
I (Diode Current)
D
I
pk
•
NP
NS
V (Auxiliary Winding Voltage)
W
VF•
NA
NS
VO •
NA
NS
I D.avg = I o
t ON
t DIS
t
S
Figure 25. Key Waveforms of DCM Flyback
Converter
© 2009 Fairchild Semiconductor Corporation
FSEZ1016A • Rev. 1.0.2
10
www.fairchildsemi.com
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