LTC1693-5CMS8 Linear Technology, LTC1693-5CMS8 Datasheet - Page 6
LTC1693-5CMS8
Manufacturer Part Number
LTC1693-5CMS8
Description
IC MOSFET DVR P-CH SINGLE 8-MSOP
Manufacturer
Linear Technology
Datasheet
1.LTC1693-5CMS8.pdf
(8 pages)
Specifications of LTC1693-5CMS8
Configuration
High-Side
Input Type
Inverting and Non-Inverting
Delay Time
38ns
Current - Peak
1.5A
Number Of Configurations
1
Number Of Outputs
1
Voltage - Supply
4.5 V ~ 13.2 V
Operating Temperature
0°C ~ 70°C
Mounting Type
Surface Mount
Package / Case
8-MSOP, Micro8™, 8-uMAX, 8-uSOP,
Lead Free Status / RoHS Status
Contains lead / RoHS non-compliant
High Side Voltage - Max (bootstrap)
-
Available stocks
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Part Number
Manufacturer
Quantity
Price
Company:
Part Number:
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Manufacturer:
LT
Quantity:
10 000
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Manufacturer:
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APPLICATIONS
LTC1693-5
Overview
The LTC1693-5 single driver allows 3V- or 5V-based digi-
tal circuits to drive power P-channel MOSFETs at high
speeds. A power MOSFET’s gate-charge loss increases with
switching frequency and transition time. The LTC1693-5
is capable of driving a 1nF load with 16ns rise and fall times
using a V
voltage supplies, such as 18V, to reduce the gate charge
losses.
The LTC1693-5’s 360 A quiescent current is an order of
magnitude lower than most other drivers/buffers. This
improves system efficiency in both standby and switching
operation. Since a power MOSFET generally accounts for
the majority of power loss in a converter, addition of the
LT1693-5 to a high power converter design greatly im-
proves efficiency, using very little board space.
Input Stage
The LTC1693-5 employs 3V CMOS compatible input thresh-
olds that allow a low voltage digital signal to drive standard
power P-channel MOSFETs. The LTC1693-5 incorporates
a 4V internal regulator to bias the input buffer. This allows
the 3V CMOS compatible input thresholds (V
= 1.4V) to be independent of variations in V
hysteresis between V
due to ground noise during switching transitions. The
LTC1693-5’s input buffer has a high input impedance and
draws less than 10 A during standby.
Output Stage
The LTC1693-5’s output stage is essentially a CMOS
inverter, as shown by the P- and N-channel MOSFETs in
Figure 1 (P1 and N1). The CMOS inverter swings rail-to-
rail, giving maximum voltage drive to the load. This large
voltage swing is important in driving external power
P-channel MOSFETs, whose R
tional to its gate overdrive voltage (V
6
CC
of 12V. This eliminates the need for higher
U
IH
and V
INFORMATION
U
IL
DS(ON)
eliminates false triggering
W
GS
is inversely propor-
– V
T
IH
CC
).
= 2.6V, V
. The 1.2V
U
IL
The LTC1693-5’s peak output currents are 1.4A (P1) and
1.7A (N1) respectively. The N-channel MOSFET (N1) has
higher current drive capability so it can charge the power
MOSFET’s gate capacitance during high-to-low signal
transitions. When the power MOSFET’s gate is pulled high
by the LTC1693-5, its drain voltage is pulled low by its load
(e.g., a resistor or inductor). The slew rate of the drain
voltage causes current to flow back to the MOSFETs gate
through its gate-to-drain capacitance. If the MOSFET
driver does not have sufficient source current capability
(low output impedance), the current through the power
MOSFET’s Miller capacitance (C
the gate low, turning the MOSFET back on.
Rise/Fall Time
Since the power MOSFET generally accounts for the ma-
jority of power lost in a converter, it’s important to quickly
turn it either fully “on” or “off” thereby minimizing the tran-
sition time in its linear region. The LTC1693-5 has rise and
fall times on the order of 16ns, delivering about 1.4A to 1.7A
of peak current to a 1nF load with a V
The LTC1693-5 rise and fall times are determined by the
peak current capabilities of P1 and N1. The predriver,
shown in Figure 1 driving P1 and N1, uses an adaptive
method to minimize cross-conduction currents. This is
done with a 6ns nonoverlapping transition time. N1 is fully
turned off before P1 is turned-on and vice-versa using this
6ns buffer time. This minimizes any cross-conduction
currents while N1 and P1 are switching on and off yet is
short enough to not prolong their rise and fall times.
Figure 1. Capacitance Seen by OUT During Switching
LTC1693-5
GND
V
CC
P1
N1
OUT
GD
) can momentarily pull
C
C
GS
GD
CC
LOAD
of only 12V.
POWER
MOSFET
1693-5 F01
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