LTC3775 Linear Technology, LTC3775 Datasheet - Page 18
LTC3775
Manufacturer Part Number
LTC3775
Description
High Frequency Synchronous Step-Down Voltage Mode DC/DC Controller
Manufacturer
Linear Technology
Datasheet
1.LTC3775.pdf
(32 pages)
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LTC3775
APPLICATIONS INFORMATION
After the calculations have been completed, it is impor-
tant to measure the gate drive waveforms and the gate
driver supply voltage (INTV
conditions (low V
as from light load to full load) to ensure adequate power
MOSFET enhancement. Consult the power MOSFET data
sheet to determine the actual R
V
the component temperatures using an infrared camera
or thermal probe.
Operation at High Supply Voltage
At high input voltages, the LTC3775’s internal LDO can
dissipate a signifi cant amount of power, which could
cause the maximum junction temperature to be exceeded.
Conditions such as a high operating frequency, or the use
of more than one power MOSFET in parallel, could push
the junction temperature rise to high levels. To prevent
the maximum junction temperature from being exceeded,
the input supply current must be checked while operating
in continuous conduction mode at maximum V
the Thermal Considerations section for calculation of the
maximum junction temperature.
Low Duty Cycle Operation
The LTC3775 uses a leading edge modulation architec-
ture. Because the top MOSFET turns on when the PWM
comparator trips, the top MOSFET minimum on-time
is not dependent on the propagation delay of the PWM
comparator; it is only limited by the internal delays of the
gate drivers and the rise/fall time of the power MOSFET
gate. This allows the LTC3775 to operate in very low duty
cycle applications with a large step-down ratio. Figure 11
shows minimum on-time waveforms for forced continuous
mode operation.
If pulse-skipping mode is selected, the LTC3775 allows
the controller to skip pulses at light load, thereby reducing
switching losses and improving the effi ciency. Figure 12
shows waveforms of the minimum on-time in pulse-skip-
ping mode.
If the TG on-time is less than the blanking time of the topside
current limit comparator, CTLIM, the topside comparator
never trips during normal operation. The blanking time
18
GS
, and verify your thermal calculations by measuring
IN
, nominal V
CC
to PGND) over all operating
IN
DS(ON)
and high V
for the measured
IN
, as well
IN
. See
is 200ns for R
resistor is used. For TG on-times smaller than the topside
blanking times, the LTC3775 relies on the bottom current
limit comparator, CBLIM, to monitor the inductor current.
If CBLIM trips, the LTC3775 starts to skip pulses and at
the same time pulls down the soft-start capacitor to limit
the duty cycle. If V
can increase enough to turn on CTLIM and limit the peak
inductor current. The minimum on-time of the application
circuit can be calculated at maximum V
t
ON MIN
(
10V/DIV
10V/DIV
10V/DIV
10V/DIV
V
V
Figure 12. Minimum On-Time Waveforms
in Pulse-Skipping Mode
)
Figure 11. Minimum On-Time Waveforms
in Forced Continuous Mode
SW
SW
TG
TG
=
V
V
LOAD = 1A
MODE/SYNC = 0V
SW FREQ = 1MHz
V
V
LOAD = 1A
MODE/SYNC = INTV
SW FREQ = 1MHz
f
IN
OUT
IN
OUT
SW
DS(ON)
= 28V
= 28V
= 0.6V
= 0.6V
•
V
OUT
V
OUT
IN MAX
sensing and 100ns when a sense
(
drops suffi ciently, the TG on-time
20ns/DIV
20ns/DIV
CC
)
3775 F11
3775 F12
IN
:
3775f
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