LT1375/ LT1376
U
W
U U
APPLICATIONS INFORMATION
pin voltage is equal to input voltage plus output voltage,
but when the boost diode is connected to the regulator
input, peak BOOST pin voltage is equal to twice the input
voltage. Be sure that BOOST pin voltage does not exceed
its maximum rating.
regulatorinputvoltage.Averageforwardcurrentinnormal
operation can be calculated from:
IOUT V − V
(
)
IN
OUT
ID(AVG
=
)
V
IN
For nearly all applications, a 0.1uF boost capacitor works
just fine, but for the curious, more details are provided
here. The size of the boost capacitor is determined by
switch drive current requirements. During switch on time,
drain current on the capacitor is approximately 10mA +
This formula will not yield values higher than 1A with
maximum load current of 1.25A unless the ratio of input
tooutputvoltageexceeds 5:1. Theonlyreasontoconsider
a larger diode is the worst-case condition of a high input
voltageandoverloaded(notshorted)output.Undershort-
circuit conditions, foldback current limit will reduce diode
current to less than 1A, but if the output is overloaded and
does not fall to less than 1/3 of nominal output voltage,
foldback will not take effect. With the overloaded condi-
tion, output current will increase to a typical value of 1.8A,
determined by peak switch current limit of 2A. With
IOUT/75. At peak load current of 1.25A, this gives a total
drain of 27mA. Capacitor ripple voltage is equal to the
product of on time and drain current divided by capacitor
value; ∆V = tON • 27mA/C. To keep capacitor ripple voltage
toless than0.5V(aslightlyarbitrarynumber)attheworst-
case condition of tON = 1.8µs, the capacitor needs to be
0.1µF. Boost capacitor ripple voltage is not a critical
parameter, but if the minimum voltage across the capaci-
tor drops to less than 3V, the power switch may not
saturate fully and efficiency will drop. An approximate
formula for absolute minimum capacitor value is:
V = 15V, VOUT = 4V (5V overloaded) and IOUT = 1.8A:
IN
1.8 15 − 4
(
)
ID(AVG
=
= 1.32A
)
15
10mA +I /75 V /V
(
)(
)
OUT
OUT IN
This is safe for short periods of time, but it would be
prudent to check with the diode manufacturer if continu-
ous operation under these conditions must be tolerated.
CMIN
=
f V − 3V
( )(
)
OUT
f = Switching frequency
BOOST PIN CONSIDERATIONS
VOUT = Regulated output voltage
V = Minimum input voltage
IN
For most applications, the boost components are a 0.1µF
capacitor and a 1N914 or 1N4148 diode. The anode is
connected to the regulated output voltage and this gener-
ates a voltage across the boost capacitor nearly identical
to the regulated output. In certain applications, the anode
may instead be connected to the unregulated input volt-
age. This could be necessary if the regulated output
voltage is very low (< 3V) or if the input voltage is less than
6V.Efficiencyis notaffectedbythecapacitorvalue,butthe
capacitor should have an ESR of less than 2Ω to ensure
that it can be recharged fully under the worst-case condi-
tion of minimum input voltage. Almost any type of film or
ceramic capacitor will work fine.
This formula can yield capacitor values substantially less
than 0.1µF, but it should be used with caution since it does
not take into account secondary factors such as capacitor
series resistance, capacitance shift with temperature and
output overload.
SHUTDOWN FUNCTION AND UNDERVOLTAGE
LOCKOUT
Figure 4 shows how to add undervoltage lockout (UVLO)
to the LT1376. Typically, UVLO is used in situations where
the input supply is current limited, or has a relatively high
source resistance. A switching regulator draws constant
power from the source, so source current increases as
source voltage drops. This looks like a negative resistance
loadtothesourceandcancausethesourcetocurrentlimit
WARNING! Peak voltage on the BOOST pin is the sum of
unregulated input voltage plus the voltage across the
boost capacitor. This normally means that peak BOOST
14
Linear [ Linear ]
