InnoSwitch3-EP
voltage of 1.5 V to 2.5 V are ideal although MOSFETs with a threshold
voltage (absolute maximum) as high as 4 V may be used provided
their data sheets specify RDS(ON) across temperature for a gate voltage
of 4.5 V.
There is a slight delay between the commencement of the flyback
cycle and the turn-on of the SR FET. During this time, the body diode
of the SR FET conducts. If an external parallel Schottky diode is
used, this current mostly flows through the Schottky diode. Once the
InnoSwitch3-EP IC detects end of the flyback cycle, voltage across
SR FET RDS(ON) reaches 0 V, any remaining portion of the flyback cycle
is completed with the current commutating to the body diode of the
SR FET or the external parallel Schottky diode. Use of the Schottky
diode parallel to the SR FET may provide higher efficiency and
typically a 1 A surface mount Schottky diode is adequate. However,
the gains are modest. For a 5 V, 2 A design the external diode adds
~0.1% to full load efficiency at 85 VAC and ~0.2% at 230 VAC.
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The voltage rating of the Schottky diode and the SR FET should be at
least 1.4 times the expected peak inverse voltage (PIV) based on the
turns ratio used for the transformer. 60 V rated FETs and diodes are
suitable for most 5 V designs that use a VOR < 60 V, and 100 V rated
FETs and diodes are suitable for 12 V designs.
Figure 12. Unacceptable FORWARD Pin Waveform before Handshake with Body
Diode Conduction During Flyback Cycle.
Note:
If t1 + t2 = 1.5 ms ± 50 ns, the controller may fail the handshake and
The interaction between the leakage reactance of the output
windings and the SR FET capacitance (COSS) leads to ringing on the
voltage waveform at the instance of voltage reversal at the winding
due to primary MOSFET turn-on. This ringing can be suppressed
using an RC snubber connected across the SR FET. A snubber
resistor in the range of 10 Ω to 47 Ω may be used (higher resistance
values lead to noticeable drop in efficiency). A capacitance value of
1 nF to 2.2 nF is adequate for most designs.
trigger a primary bias winding OVP latch-off.
Output Capacitor
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Low ESR aluminum electrolytic capacitors are suitable for use with
most high frequency flyback switching power supplies, though the
use of aluminum-polymer solid capacitors have gained considerable
popularity due to their compact size, stable temperature characteristics,
extremely low ESR and high RMS ripple current rating. These
capacitors enable the design of ultra-compact chargers and adapters.
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Typically, 200 mF to 300 mF of aluminum-polymer capacitance per
ampere of output current is adequate. The other factor that
influences choice of the capacitance is the output ripple. Ensure that
capacitors with a voltage rating higher than the highest output
voltage plus sufficient margin be used.
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Figure 13 Acceptable FORWARD Pin Waveform before Handshake with Body
Diode Conduction During Flyback Cycle.
Output Voltage Feedback Circuit
SR MOSFET Operation and Selection
The output voltage FEEDBACK pin voltage is 1.265 V [VFB]. A voltage
divider network should be connected at the output of the power
supply to divide the output voltage such that the voltage at the
FEEDBACK pin will be 1.265 V when the output is at its desired
voltage. The lower feedback divider resistor should be tied to the
SECONDARY GROUND pin. A 300 pF (or smaller) decoupling
capacitor should be connected at the FEEDBACK pin to the
SECONDARY GROUND pin of the InnoSwitch3-EP IC. This capacitor
should be placed close to the InnoSwitch3-EP IC.
Although a simple diode rectifier and filter works for the output, use
of an SR FET enables the significant improvement in operating
efficiency often necessary to meet the European CoC and the U.S.
DoE energy efficiency requirements. The secondary-side controller
turns on the SR FET once the flyback cycle begins. The SR FET gate
should be tied directly to the SYNCHRONOUS RECTIFIER DRIVE pin
of the InnoSwitch3-EP IC (no additional resistors should be connected
in the gate circuit of the SR FET). The SR FET is turned off once the
VDS of the SR FET reaches 0 V.
A FET with 18 mΩ RDS(ON) is appropriate for a 5 V, 2 A output, and a
FET with 8 mΩ RDS(ON) is suitable for designs rated with a 12 V, 3 A
output. The SR FET driver uses the SECONDARY BYPASS pin for its
supply rail, and this voltage is typically 4.4 V. A FET with a high
threshold voltage is therefore not suitable; FETs with a threshold
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Rev. D 08/18
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