LTC1922EG-1#PBF Linear Technology, LTC1922EG-1#PBF Datasheet - Page 19
LTC1922EG-1#PBF
Manufacturer Part Number
LTC1922EG-1#PBF
Description
IC CTLR PWM SYNC 20SSOP
Manufacturer
Linear Technology
Datasheet
1.LTC1922EG-1PBF.pdf
(24 pages)
Specifications of LTC1922EG-1#PBF
Pwm Type
Voltage/Current Mode
Number Of Outputs
1
Frequency - Max
1MHz
Duty Cycle
99%
Buck
No
Boost
No
Flyback
No
Inverting
No
Doubler
No
Divider
No
Cuk
No
Isolated
Yes
Operating Temperature
-40°C ~ 85°C
Package / Case
20-SSOP
Frequency-max
1MHz
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Voltage - Supply
-
Available stocks
Company
Part Number
Manufacturer
Quantity
Price
OPERATIO
where:
For a 48V to 3.3V/5V, 200W converter, the following
values were derived:
Output Capacitors
Output capacitor selection has a dramatic impact on ripple
voltage, dynamic response to transients and stability.
Capacitor ESR along with output inductor ripple current
will determine the peak-to-peak voltage ripple on the
output. The current doubler configuration is advanta-
geous because it has inherent ripple current reduction.
The dual output inductors deliver current to the output
capacitor 180 degrees out of phase, in effect, partially
canceling each other’s ripple current. This reduction is
maximized at high duty cycle and decreases as the duty
cycle reduces. This means that a current doubler con-
verter requires less output capacitance for the same
performance as a conventional converter. By determining
the minimum duty cycle for the converter, worse-case
V
where:
OUT
V
C
l
f
D
L
f
L
L
L
Turns Ratio (N) = 2.5
D
f
L
ESR = output capacitor series resistance
ORIPPLE
MAG
SW
SW
SW
L
MAG
COM
OUT
O
OSS
ripple can be derived by the formula given below.
= minimum duty cycle
= oscillator frequency
= output inductance
= MOSFET D-S capacitance
= magnetizing inductance
= switching frequency
= duty cycle
= leakage inductance
: 300kHz
: 100 H
: 0.9 H
: 2.2 H
I
RIPPLE
U
•
ESR
L
O
V
O
• •
2
•
ESR
f
SW
( – )( –
1
D
1 2
D
)
The amount of bulk capacitance required is usually system
dependent, but has some relationship to output induc-
tance value, switching frequency, load power and dynamic
load characteristics. Polymer electrolytic capacitors are
the preferred choice for their combination of low ESR,
small size and high reliability. For less demanding applica-
tions, or those not constrained by size, aluminum electro-
lytic capacitors are commonly applied. Most
DC/DC converters in the 100kHz to 300kHz range use 20 F
to 25 F of bulk capacitance per watt of output power.
Converters switching at higher frequencies can usually
use less bulk capacitance. In systems where dynamic
response is critical, additional high frequency capacitors,
such as ceramics, can substantially reduce voltage tran-
sients,
Power converter stability is, to a large extent, determined
by the choice of output capacitor. A zero in the converter’s
transfer function is given by 1/(2 • ESR • C
electrolytic ESR is highly variable with temperature, in-
creasing by about 4 at cold temperatures, making the
ESR zero frequency highly variable. Polymer electrolytic
ESR is essentially flat with temperature. This characteris-
tic simplifies loop compensation and allows for a much
faster responding power supply compared to one with
aluminum electrolytic capacitors. Specific details on loop
compensation are given in the Compensation section of
the data sheet.
Power MOSFETs
The full-bridge power MOSFETs should be selected for
their R
rated MOSFET available for a given input voltage range
leaving at least a 20% voltage margin. Conduction losses
are directly proportional to R
has two MOSFETs in the power path most of the time,
conduction losses are approximately equal to:
Switching losses in the MOSFETs are dominated by the
power required to charge their gates, and turn-on and
turn-off losses. At higher power levels, gate charge power
is seldom a significant contributor to efficiency loss. ZVS
operation virtually eliminates turn-on losses. Turn-off
losses are reduced by the use of an external drain to source
2 • R
DS(ON)
DS(ON)
and BV
• I
2
, where I = I
DSS
ratings. Select the lowest BV
DS(ON)
O
/2N
. Since the full-bridge
LTC1922-1
O
). Aluminum
19
DSS
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