SC1154CSW 데이터 시트보기 (PDF) - Semtech Corporation
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SC1154CSW
Semtech Corporation
SC1154CSW Datasheet PDF : 20 Pages
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SC1154
POWER MANAGEMENT
Applications Information - .unctional Description
PRELIMINARY
Reference/Voltage Identification
The reference/voltage identification (VID) section con-
sists of a temperature compensated bandgap reference
and a 5-bit voltage selection network. The 5 VID pins
are TTL compatable inputs to the VID selection network.
They are internally pulled up to +5V generated from the
+12V supply by a resistor divider, and provide program-
mability of output voltage from 2.0V to 3.5V in 100mV
increments and 1.3V to 2.05V in 50mV increments.
Refer to the Output Voltage Table for the VID code set-
tings. The output voltage of the VID network, VRE. is
within 1% of the nominal setting over the full input and
output voltage range and junction temperature range.
The output of the reference/VID network is indirectly
brought out through a buffer to the VRE.B pin. The volt-
age on this pin will be within 3mV of VRE.. It is not rec-
ommended to drive loads with VRE.B other than setting
the hysteresis of the hysteretic comparator, because the
current drawn from VRE.B sets the charging current for
the soft start capacitor. Refer to the soft start section
for additional information.
veloped from the DRV regulator. The internal bootstrap
diode, connected between the DRV and BOOT pins, is a
Schottky for improved drive efficiency. The maximum
voltage that can be applied between the BOOT pin and
ground is 25V. The driver can be referenced to ground
by connecting BOOTLO to PGND, and connecting +12V
to the BOOT pin.
Deadtime Control
Deadtime control prevents shoot-through current from
flowing through the main power .ETs during switching
transitions by actively controlling the turn-on times of the
.ET drivers. The high side driver is not allowed to turn on
until the gate drive voltage to the low-side .ET is below 2
volts, and the low side driver is not allowed to turn on
until the voltage at the junction of the two .ETs (VPHASE)
is below 2 volts. An internal low-pass filter with an 11MHz
pole is located between the output of the low-side driver
(DL) and the input of the deadtime circuit that controls
the high-side driver, to filter out noise that could appear
on DL when the high-side driver turns on.
Hysteretic Comparator
Current Sensing
The hysteretic comparator regulates the output voltage
of the synchronous-buck converter. The hysteresis is
set by connecting the center point of a resistor divider
from VRE.B to AGND to the HYST pin. The hysteresis of
the comparator will be equal to twice the voltage differ-
ence between VRE.B and HYST, and has a maximum
value of 60mV. The maximum propagation delay from
the comparator inputs to the driver outputs is 250ns.
Low Side Driver
The low side driver is designed to drive a low RDS(ON)
N-channel MOS.ET, and is rated for 2 amps source and
sink. The bias for the low side driver is provided inter-
nally from VDRV.
High Side Driver
The high side driver is designed to drive a low RDS(ON)
N-channel MOS.ET, and is rated for 2 amps source and
sink. It can be configured either as a ground referenced
driver or as a floating bootstrap driver. When configured
as a floating driver, the bias voltage to the driver is de-
Current sensing is achieved by sampling and holding the
voltage across the high side .ET while it is turned on.
The sampling network consists of an internal 50Ω switch
and an external 0.1µ. hold capacitor. Internal logic con-
trols the turn-on and turn-off of the sample/hold switch
such that the switch does not turn on until VPHASE tran-
sitions high and turns off when the input to the high side
driver goes low. Thus sampling will occur only when the
high side .ET is conducting current. The voltage at the
IOUT pin equals 2 times the sensed voltage. In applica-
tions where a higher accuracy in current sensing is re-
quired, a sense resistor can be placed in series with the
high side .ET and the voltage across the sense resistor
can be sampled by the current sensing circuit.
Droop Compensation
The droop compensation network reduces the load tran-
sient overshoot/undershoot at VOUT, relative to VRE..
VOUT is programmed to a voltage greater than VRE. equal
to VRE. (1+R7/R8) (see Typ. App. Circuit, Pg 1) by an
external resistor divider from VOUT to the VSENSE pin to
reduce the undershoot on VOUT during a low to high load
2001 Semtech Corp.
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