LTC1873EG#TR Linear Technology, LTC1873EG#TR Datasheet - Page 20
LTC1873EG#TR
Manufacturer Part Number
LTC1873EG#TR
Description
IC REG SW 2PH DUAL SYNC 28SSOP
Manufacturer
Linear Technology
Datasheet
1.LTC1873EG.pdf
(32 pages)
Specifications of LTC1873EG#TR
Pwm Type
Voltage Mode
Number Of Outputs
2
Frequency - Max
750kHz
Duty Cycle
93%
Voltage - Supply
3 V ~ 7 V
Buck
Yes
Boost
No
Flyback
No
Inverting
No
Doubler
No
Divider
No
Cuk
No
Isolated
No
Operating Temperature
-40°C ~ 85°C
Package / Case
28-SSOP
Frequency-max
750kHz
Lead Free Status / RoHS Status
Contains lead / RoHS non-compliant
Available stocks
Company
Part Number
Manufacturer
Quantity
Price
APPLICATIO S I FOR ATIO
LTC1873
OUTPUT BYPASS CAPACITOR
The output bypass capacitor has quite different require-
ments from the input capacitor. The ripple current at the
output of a buck regulator like the LTC1873 is much lower
than at the input, due to the fact that the inductor current
is constantly flowing at the output whenever the LTC1873
is operating in continuous mode. The primary concern at
the output is capacitor ESR. Fast load current transitions
at the output will appear as voltage across the ESR of the
output bypass capacitor until the feedback loop in the
LTC1873 can change the inductor current to match the
new load current value. This ESR step at the output is often
the single largest budget item in the load regulation
calculation. As an example, our hypothetical 1.6V, 10A
switcher with a 0.01 ESR output capacitor would expe-
rience a 100mV step at the output with a 0 to 10A load
step—a 6.3% output change!
Usually the solution is to parallel several capacitors at the
output. For example, to keep the transient response inside
of 3% with the previous design, we’d need an output ESR
better than 0.0048 . This can be met with three 0.014 ,
470 F tantalum capacitors in parallel.
INDUCTOR
The inductor in a typical LTC1873 circuit is chosen prima-
rily for value and saturation current. The inductor value
sets the ripple current, which is commonly chosen at
around 30% of the anticipated full load current. Ripple
current is set by:
In our hypothetical 1.6V, 10A example, we'd set the ripple
current to 30% of 10A or 3A, and the inductor value would
be:
The inductor must not saturate at the expected peak
current. In this case, if the current limit was set to 15A, the
20
I
L
with t
RIPPLE
t
ON QB
ON QB
(
I
RIPPLE
(
t
)
ON QB
)
V
(
OUT
U
1
)
L
V
OUT
1 6
5
.
V
U
1 2
V
.
/
4
s
550
A
1 6
.
W
kHz
V
1 2
0 5
.
.
U
s
H
1
Stability Analysis and Synthesis” by H. Dean Venable, Venable Industries, Inc. For complete paper,
see “Reference Reading #4” at www.linear-tech.com.
inductor should be rated to withstand 15A + 1/2 I
or 16.5A without saturating.
FEEDBACK LOOP/COMPENSATION
Feedback Loop Types
In a typical LTC1873 circuit, the feedback loop consists of
the modulator, the external inductor and output capacitor,
and the feedback amplifier and its compensation network.
All of these components affect loop behavior and need to
be accounted for in the loop compensation. The modulator
consists of the internal PWM generator, the output MOSFET
drivers and the external MOSFETs themselves. From a
feedback loop point of view, it looks like a linear voltage
transfer function from COMP to SW and has a gain roughly
equal to the input voltage. It has fairly benign AC behavior
at typical loop compensation frequencies with significant
phase shift appearing at half the switching frequency.
The external inductor/output capacitor combination makes
a more significant contribution to loop behavior. These
components cause a second order LC roll-off at the
output, with the attendant 180 phase shift. This roll-off is
what filters the PWM waveform, resulting in the desired
DC output voltage, but the phase shift complicates the
loop compensation if the gain is still higher than unity at
the pole frequency. Eventually (usually well above the LC
pole frequency), the reactance of the output capacitor will
approach its ESR, and the roll-off due to the capacitor will
stop, leaving 6dB/octave and 90 of phase shift (Figure 8).
The information in this section is based on the paper “The K Factor: A New Mathematical Tool for
Figure 8. Ideal Transfer Function of Buck Modulator
GAIN
(dB)
A
V
0
GAIN
PHASE
–12dB/OCT
1
–6dB/OCT
1873 F08
0
–90
–180
PHASE
(DEG)
RIPPLE
,
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