LTC1647-3 Ver la hoja de datos (PDF) - Linear Technology
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LTC1647-3 Datasheet PDF : 20 Pages
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LTC1647-1/LTC1647-2/LTC1647-3
APPLICATIO S I FOR ATIO
The circuit breaker trip voltage has a tolerance of 20%;
combined with a 5% sense resistor, the total tolerance is
25%. Therefore, calculate R1 based on a trip current ITRIP
of no less than 125% of the maximum operating current.
Do not neglect the effect of ripple current, which adds to
the maximum DC component of the load current. Ripple
current may arise from any of several sources, but the
worst offenders are switching supplies.
A switching regulator on the load side will attempt to draw
some ripple current from the backplane and this current
passes through the sense resistor. Similarly, output ripple
from a switching regulator supplying the backplane will
flow through the sense resistor and into the load capacitor.
Minimize the effects of ripple current by either filtering the
VOUT line or adding an RC filter to the SENSE pin. A series
inductance of 1µH to 10µH inserted between Q1 and CLOAD
is adequate ripple current suppression in most cases.
Alternatively, a filter, consisting of R3 and C3(Figure 3),
simply filters the ripple component from the SENSE pin at
the expense of response time. The added delay is given by
tDELAY = – R3•C3•ln[1 – (VCB/R1 – IAV)/(IPK – IAV)]
VCC
FAULT
R1
0.01Ω
Q1
IRF7413
+
VOUT
CLOAD
R3
R2
10k
10Ω
1
15
13
VCC
SENSE GATE
2
ON
ON1
3
LTC1647-3
FAULT
8
GND
C1
10nF
1647-1/2/3 F01
Figure 1. Supply Control Circuitry
VON
VCC – VSENSE
VGATE
tFAULT
tRESET
VFAULT
1647-1/2/3 F02
Figure 2. Current Fault Timing
R1
Q1
0.01Ω
IRF7413
VCC
+
VOUT
CLOAD
C3
R3
R2
10nF 1.5k
10Ω
C1
10nF
IPK = 7.5A
IAV = 2.5A
ITRIP = VCB/R1 = 5A
tDELAY = 10µs
VCC
SENSE GATE
LTC1647
1647-1/2/3 F03
Figure 3. Filtering Current Ripple/Glitches
Power MOSFET Selection
Power MOSFETs are classified into two catagories: stan-
dard MOSFETs (RDS(ON) specified at VGS = 10V) and logic-
level MOSFETs (RDS(ON) specified at VGS = 5V). The
absolute maximum rating for VGS is typically 20V for
standard MOSFETs. The maximum rating for logic-level
MOSFETs is lower and ranges from 8V to 16V depending
on the manufacturer and specific part number. Some
logic-level MOSFETs have a 20V maximum VGS rating. The
LTC1647 is primarily targeted for standard MOSFETs; low
supply voltage applications should use logic-level
MOSFETs. GATE overdrive as a function of VCC is illus-
trated in the Typical Performance Curves. If lower GATE
overdrive is desired, connect a diode in series with a Zener
between GATE and VCC or between GATE and VOUT as
shown in Figure 4.
The RDS(ON) of the external pass transistor must be low to
make VDS a small percentage of VCC. At VCC = 3.3V, VDS +
VCB = 0.1V yields 3% error at maximum load current. This
restricts the choice of MOSFETs to very low RDS(ON). At
higher VCC voltages, the RDS(ON) requirement can be
relaxed. MOSFET package dissipation (PD and TJ) may
restrict the value of RDS(ON).
R1
Q1
VCC
VOUT
D2
D1* 1N4148
D2
1N4148 D4*
*USER SELECTED VOLTAGE CLAMP
1N4688 (5V)
1N4692 (7V): LOGIC-LEVEL MOSFET
1N4695 (9V)
1N4702 (15V): STANDARD-LEVEL MOSFET
1647-1/2/3 F04
Figure 4. Optional Gate Clamp
10
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