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LTC3630 Datasheet, PDF (9/26 Pages) Linear Technology – High Efficiency, 65V 500mA Synchronous
LTC3630
OPERATION (Refer to Block Diagram)
The LTC3630 is a synchronous step-down DC/DC con-
verter with internal power switches that uses Burst Mode
control. The low quiescent current and high switching
frequency results in high efficiency across a wide range
of load currents. Burst Mode operation functions by using
short “burst” cycles to switch the inductor current through
the internal power MOSFETs, followed by a sleep cycle
where the power switches are off and the load current is
supplied by the output capacitor. During the sleep cycle,
the LTC3630 draws only 12μA of supply current. At light
loads, the burst cycles are a small percentage of the total
cycle time which minimizes the average supply current,
greatly improving efficiency. Figure 1 shows an example
of Burst Mode operation. The switching frequency and the
number of switching cycles during Burst Mode operation
are dependent on the inductor value, peak current, load
current, input voltage and output voltage.
BURST
CYCLE
SLEEP
CYCLE
SWITCHING
FREQUENCY
INDUCTOR
CURRENT
BURST
FREQUENCY
OUTPUT
VOLTAGE
ΔVOUT
3630 F01
Figure 1. Burst Mode Operation
Main Control Loop
The LTC3630 uses the VPRG1 and VPRG2 control pins to
connect internal feedback resistors to the VFB pin. This
enables fixed outputs of 1.8V, 3.3V or 5V without increas-
ing component count, input supply current or exposure to
noise on the sensitive input to the feedback comparator.
External feedback resistors (adjustable mode) can still
be used by connecting both VPRG1 and VPRG2 to ground.
In adjustable mode the feedback comparator monitors
the voltage on the VFB pin and compares it to an inter-
nal 800mV reference. If this voltage is greater than the
reference, the comparator activates a sleep mode in which
the power switches and current comparators are disabled,
reducing the VIN pin supply current to only 12μA. As the
load current discharges the output capacitor, the voltage
on the VFB pin decreases. When this voltage falls 5mV
below the 800mV reference, the feedback comparator
trips and enables burst cycles.
At the beginning of the burst cycle, the internal high side
power switch (P-channel MOSFET) is turned on and the
inductor current begins to ramp up. The inductor current
increases until either the current exceeds the peak cur-
rent comparator threshold or the voltage on the VFB pin
exceeds 800mV, at which time the high side power switch
is turned off and the low side power switch (N-channel
MOSFET) turns on. The inductor current ramps down until
the reverse current comparator trips, signaling that the
current is close to zero. If the voltage on the VFB pin is
still less than the 800mV reference, the high side power
switch is turned on again and another cycle commences.
The average current during a burst cycle will normally be
greater than the average load current. For this architecture,
the maximum average output current is equal to half of
the peak current.
The hysteretic nature of this control architecture results
in a switching frequency that is a function of the input
voltage, output voltage, and inductor value. This behavior
provides inherent short-circuit protection. If the output is
shorted to ground, the inductor current will decay very
slowly during a single switching cycle. Since the high side
switch turns on only when the inductor current is near
zero, the LTC3630 inherently switches at a lower frequency
during start-up or short-circuit conditions.
Start-Up and Shutdown
If the voltage on the RUN pin is less than 0.7V, the LTC3630
enters a shutdown mode in which all internal circuitry is
disabled, reducing the DC supply current to 5μA. When the
voltage on the RUN pin exceeds 1.21V, normal operation
of the main control loop is enabled. The RUN pin com-
parator has 110mV of internal hysteresis, and therefore
must fall below 1.1V to stop switching and disable the
main control loop.
3630fb
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