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LTC1922-1 Datasheet, PDF (13/24 Pages) Linear Technology – Synchronous Phase Modulated Full-Bridge Controller
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OPERATIO
Off-Line Bias Supply Generation
If a regulated bias supply is not available to provide VCC
voltage to the LTC1922-1 and supporting circuitry, one
must be generated. Since the power requirement is small,
approximately 1W, and the regulation is not critical, a
simple open-loop method is usually the easiest and lowest
cost approach. One method that works well is to add a
winding to the main power transformer, and post regulate
the resultant square wave with an L-C filter (see Figure␣ 5a).
The advantage of this approach is that it maintains decent
regulation as the supply voltage varies, and it does not
require full safety isolation from the input winding of the
transformer. Some manufacturers include a primary wind-
ing for this purpose in their standard product offerings as
well. A different approach is to add a winding to the output
inductor and peak detect and filter the square wave signal
(see Figure 5b). The polarity of this winding is designed so
that the positive voltage square wave is produced while the
output inductor is freewheeling. An advantage of this
technique over the previous is that it does not require a
separate filter inductor and since the voltage is derived
from the well-regulated output voltage, it is also well
controlled. One disadvantage is that this winding will
require the same safety isolation that is required for the
main transformer. Another disadvantage is that a much
larger VCC filter capacitor is needed, since it does not
VIN
VCC
RSTART
15V*
+
2k
CHOLD
0.1µF
*OPTIONAL
1922 F05a
Figure 5a. Auxiliary Winding Bias Supply
VIN
RSTART
LOUT
ISO BARRIER
VOUT
+
0.1µF
CHOLD
VCC
1922 F05b
Figure 5b. Output Inductor Bias Supply
LTC1922-1
generate a voltage as the output is first starting up, or
during short-circuit conditions.
Programming the LTC1922-1 Oscillator
The high accuracy LTC1922-1 oscillator circuit provides
flexibility to program the switching frequency, slope com-
pensation, and synchronization with minimal external
components. The LTC1922-1 oscillator circuitry produces
a 3.8V peak-to-peak amplitude ramp waveform on CT and
a narrow pulse on SYNC that can be used to synchronize
other PWM chips. Typical maximum duty cycles of 99%
are obtained at 300kHz and 97% at 1MHz. The large
amplitude ramp provides a high degree of noise margin. A
compensating slope current is derived from the oscillator
ramp waveform and sourced out of CS.
The desired amount of slope compensation is selected
with single external resistor (or no resistor), if not re-
quired. A capacitor to GND on CT programs the switching
frequency. The CT ramp discharge current is internally set
to a high value (>10mA). The dedicated SYNC I/O pin easily
achieves synchronization. The LTC1922-1 can be set up to
either synchronize other PWM chips or be synchronized
by another chip or external clock source. The 1.8V SYNC
threshold allows the LTC1922-1 to be synchronized di-
rectly from all standard 3V and 5V logic families.
Design Procedure:
1. Choose CT for the desired oscillator frequency. The
switching frequency selected must be consistent with the
power magnetics and output power level. This is detailed
in the Transformer Design section. In general, increasing
the switching frequency will decrease the maximum achiev-
able output power, due to limitations of maximum duty
cycle imposed by transformer core reset and ZVS. Re-
member that the output frequency is 1/2 that of the
oscillator.
CT = 1/(20k • fOSC)
Example: Desired fOSC = 330kHz
CT = 1/(20k • 330kHz) = 152pF, choose closest standard
value of 150pF. A 5% or better tolerance multilayer NPO
or X7R ceramic capacitor is recommended for best
performance.
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