LT3753
24
Rev. C
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APPLICATIONS INFORMATION
Programming Active Clamp Switch Timing: AOUT to
OUT (tAO) and OUT to AOUT (tOA) Delays
The timings tAO and tOA represent the delays between AOUT
and OUT edges (Figures 1 and 2) and are programmed
by a single resistor, RTAO, connected from analog ground
(Pin 18) to the TAO pin. Once tAO is programmed for the
reasons given below, tOA will be automatically generated.
Front-end timing tAO (M2 off, M1 on)
= AOUT(edge)-to-OUT(rising)
= 50ns + 3.8ns • RTAO
1k
⎛
⎝
⎜⎞
⎠
⎟,14.7 < RTAO < 125k
In order to minimize turn-on transition loss in M1 the drain
of M1 should be as low as possible before M1 turns on.
To achieve this, AOUT should turn M2 off a delay of tAO
before OUT turns M1 on. This allows the main transformer’s
magnetizing current to discharge M1 drain voltage quickly
towards VIN before M1 turns on.
As SWP falls below VIN, however, the rectifying diodes on
the secondary side are typically active and clamp the SWP
node close to VIN. If enough leakage inductance exists,
however, the clamping action on SWP by the secondary
side will be delayed—potentially allowing the drain of
M1 to be fully discharged to ground just before M1 turns
on. Even with this delay due to the leakage inductance,
LMAG needs to be low enough to allow IMAG to be negative
enough to slew SWP down to ground before M1 turns on.
If achievable, M1 will experience zero voltage switching
(ZVS) for highest efficiency. As will be seen in a later sec-
tion entitled Primary-Side Power MOSFET Selection, M1
transition loss is a significant contributor to M1 losses.
Back-end timing tOA (M1 off, M2 on) is automatically
generated
= OUT(falling)-to-AOUT(edge) = 0.9 • tAO
tOA should be checked to ensure M2 is not turned on until
M1 and M3 are turned off.
Programming Synchronous Rectifier Timing: SOUT to
OUT (tSO) and OUT to SOUT (tOS) Delays
The LT3753 includes a ±0.4A gate driver at the SOUT pin
to send a control signal via a pulse transformer to the
secondary side of the forward converter for synchronous
rectification (see Figures 1 and 2). For the highest efficiency,
M4 should be turned on whenever M1 is turned off. This
suggests that SOUT should be a non-overlapping signal
with OUT with very small non-overlap times. Inherent tim-
ing delays, however, which can vary from application to
application, can exist between OUT to CSW and between
SOUT to CG. Possible shoot-through can occur if both M1
and M4 are on at the same time, resulting in transformer
and/or switch damage.
Front-end timing: tSO (M4 off, M1 on)
= SOUT(falling)-to-OUT(rising) delay
= tSO = tAO – tAS
= 3.8ns • (RTAS – RTAO)
where:
tAS = 50ns + (3.8ns • RTAS/1k) , 14.7k < RTAS < 125k,
tAO = 50ns + (3.8ns • RTAO/1k), 14.7k < RTAO < 125k,
tSO is defined by resistors RTAS and RTAO connected from
analog ground (Pin 18) to their respective pins TAS and
TAO. Each of these resistor defines a delay referenced
to the AOUT edge at the start of each cycle. RTAO was
already programmed based on requirements defined in
the previous section Programming AOUT to OUT Delay.
RTAS is then programmed as a delay from AOUT to SOUT
to fulfill the equation above for tSO. By choosing RTAS less
than or greater than RTAO, the delay between SOUT falling
and OUT rising can be programmed as positive or nega-
tive. While a positive delay can always be programmed
for tSO, the ability to program a negative delay allows for
improved efficiency if OUT(rising)-to-CSW(rising) delay
is larger than SOUT(falling)-to-CG(rising) delay.
Back-end timing: tOS (M1 off, M4 on)
= OUT (falling)-to-SOUT (rising) delay
= tOS = 35ns + (2.2ns • RTOS/1k), 7.32k < RTOS < 249k