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LT1300CS8 View Datasheet(PDF) - Linear Technology

Part Name
Description
MFG CO.
'LT1300CS8' PDF : 8 Pages View PDF
1 2 3 4 5 6 7 8
TEST CIRCUITS
Oscillator Test Circuit
5V
2V
100
VIN
IL
SEL
SW
fOUT
100µF
LT1300
SENSE
GND
SHDN
PGND
LT1300
U
OPERATION
Operation of the LT1300 is best understood by referring to
the Block Diagram in Figure 1. When A1’s negative input,
related to the Sense pin voltage by the appropriate resis-
tor-divider ratio, is higher that the 1.25V reference voltage,
A1’s output is low. A2, A3 and the oscillator are turned off,
drawing no current. Only the reference and A1 consume
current, typically 120µA. When the voltage at A1’s nega-
tive input decreases below 1.25V, overcoming A1’s 6mV
hysteresis, A1’s output goes high, enabling the oscillator,
current comparator A2, and driver A3. Quiescent current
increases to 2mA as the device prepares for high current
switching. Q1 then turns on in a controlled saturation for
(nominally) 5.3µs or until current comparator A2 trips,
whichever comes first. After a fixed off-time of (nominally)
1.2µs, Q1 turns on again. The LT1300’s switching causes
current to alternately build up in L1 and dump into capaci-
tor C2 via D1, increasing the output voltage. When the
output is high enough to cause A1’s output to go to low,
switching action ceases. C2 is left to supply current to the
load until VOUT decreases enough to force A1’s output
high, and the entire cycle repeats.
If switch current reaches 1A, causing A2 to trip, switch on-
time is reduced and off-time increases slightly. This allows
continuous mode operation during bursts. Current com-
parator A2 monitors the voltage across 3resistor R1
which is directly related to inductor L1’s current. Q2’s
collector current is set by the emitter-area ratio to 0.6%
of Q1’s collector current. When R1’s voltage drop exceeds
18mV, corresponding to 1A inductor current, A2’s output
goes high, truncating the on-time portion of the oscillator
cycle and increasing off-time to about 2µs as shown in
Figure 2, trace A. This programmed peak current can be
TRACE A
500mA/DIV
ILIM PIN
OPEN
TRACE B
500mA/DIV
ILIM PIN
GROUNDED
20µs/DIV
LT1300 F2
Figure 2. Switch Pin Current With ILIM Floating or Grounded
reduced by tying the ILIM pin to ground, causing 15µA to
flow through R2 into Q3’s collector. Q3’s current causes
a 10.4mV drop in R2 so that only an additional 7.6mV is
required across R1 to turn off the switch. This corre-
sponds to a 400mA switch current as shown in Figure 2,
trace B. The reduced peak switch current reduces I2R
loses in Q1, L1, C1 and D1. Efficiency can be increased by
doing this provided that the accompanying reduction in
full load output current is acceptable. Lower peak currents
also extend alkaline battery life due to the alkaline cell’s
high internal impedance. Typical operating waveforms are
shown in Figure 3.
VOUT
20mV/DIV
AC COUPLED
VSW
5V/DIV
ISW
IA/DIV
20µS/DIV
LT1300 F2
Figure 3. Burst Mode Operation in Action
5
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