FAN100MY Fairchild Semiconductor, FAN100MY Datasheet - Page 10
FAN100MY
Manufacturer Part Number
FAN100MY
Description
IC CTRLR PWM GREEN CV/CC 8SOP
Manufacturer
Fairchild Semiconductor
Datasheet
1.FAN100MY.pdf
(16 pages)
Specifications of FAN100MY
Output Isolation
Isolated
Frequency Range
39 ~ 45kHz
Voltage - Input
5.5 ~ 15 V
Voltage - Output
30V
Power (watts)
660mW
Operating Temperature
-40°C ~ 125°C
Package / Case
8-SOIC (0.154", 3.90mm Width)
Operating Supply Voltage
25 V
Maximum Operating Temperature
+ 105 C
Minimum Operating Temperature
- 40 C
Mounting Style
SMD/SMT
Output Current
90 uA
Output Voltage
4.5 V
Supply Current
3.5 mA
Number Of Outputs
1
Duty Cycle (max)
75 %
Switching Frequency
45 KHz
Fall Time
80 ns
Rise Time
200 ns
Synchronous Pin
No
Topology
Flyback
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Other names
FAN100MYTR
Available stocks
Company
Part Number
Manufacturer
Quantity
Price
Company:
Part Number:
FAN100MY
Manufacturer:
INFINEON
Quantity:
670
Company:
Part Number:
FAN100MY
Manufacturer:
FAIRC
Quantity:
5 000
© 2009 Fairchild Semiconductor Corporation
FAN100 Rev. 1.0.2
Functional Description
0 shows the basic circuit diagram of a primary-side
regulated flyback converter and its typical waveforms
are shown in 0. Generally, discontinuous conduction
mode (DCM) operation is preferred for primary-side
regulation since it allows better output regulation. The
operation principles of DCM flyback converter are as
follows:
During the MOSFET on time (t
applied across the primary side inductor (L
MOSFET current (I
peak value (I
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 be turned
on. While the diode is conducting, the output voltage
(V
applied across the secondary-side inductor (L
N
the peak value (I
inductor current discharge time (t
stored in the inductor has been delivered to the output.
When the diode current reaches zero, the transformer
auxiliary winding voltage (V
resonance between the primary-side inductor (L
the effective capacitor loaded across the 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 (V
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. Thus,
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
(V
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 average of the
diode current in steady state.
The output current estimator detects the peak value of
the drain current with a peak detection circuit and
calculates the output current using the inductor
discharge time (t
output information is compared with the internal precise
reference to generate error voltage (V
determines the duty cycle of the MOSFET in CC mode.
With
TRUECURRENT™, constant current (CC) output can
be precisely controlled.
p
o
COMV
2
), together with diode forward-voltage drop (V
) and the diode current (I
), which determines the duty cycle of the
Fairchild’s
pk
). During this time, the energy is drawn
DIS
ds
pk
) increases linearly from zero to the
× N
) and switching period (t
p
/N
w
s
innovative
) to zero. At the end of
) begins to oscillate by the
D
) decreases linearly from
ON
), input voltage (V
DIS
), all the energy
o
COMI
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technique,
m
F
), which
)× N
). Then,
s
). This
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m
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DL
F
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), is
/N
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s
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s
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.
10
Of the two error voltages, V
determines the duty cycle. During constant voltage
regulation mode, V
V
regulation mode, V
V
Figure 23. Simplified PSR Flyback Converter Circuit
COMI
COMV
Figure 24. Key Waveforms of DCM Flyback
is saturated to HIGH.
is saturated to HIGH. During constant current
V
F
⋅
N
N
A
S
COMV
COMI
V
I
O
determines the duty cycle while
pk
determines the duty cycle while
I
⋅
pk
N
N
⋅
A
S
COMV
Converter
N
N
P
S
and V
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