HCPL-3140-000E Avago Technologies US Inc., HCPL-3140-000E Datasheet - Page 14
HCPL-3140-000E
Manufacturer Part Number
HCPL-3140-000E
Description
OPTOCOUPLER IGBT DRIVE 0.4A 8DIP
Manufacturer
Avago Technologies US Inc.
Datasheet
1.HCPL-3140-000E.pdf
(16 pages)
Specifications of HCPL-3140-000E
Package / Case
8-DIP (0.300", 7.62mm)
Voltage - Isolation
3750Vrms
Number Of Channels
1, Unidirectional
Current - Output / Channel
600mA
Propagation Delay High - Low @ If
300ns @ 8mA
Current - Dc Forward (if)
25mA
Input Type
DC
Output Type
Push-Pull, Totem-Pole
Mounting Type
Through Hole
Isolation Voltage
3750 Vrms
Maximum Fall Time
0.05 us
Maximum Forward Diode Current
25 mA
Minimum Forward Diode Voltage
1.2 V
Output Device
Logic Gate Photo IC
Configuration
1 Channel
Maximum Forward Diode Voltage
1.8 V
Maximum Reverse Diode Voltage
5 V
Maximum Power Dissipation
250 mW
Maximum Operating Temperature
+ 100 C
Minimum Operating Temperature
- 40 C
No. Of Channels
1
Optocoupler Output Type
Gate Drive
Input Current
12mA
Output Voltage
30V
Opto Case Style
DIP
No. Of Pins
8
Common Mode Ratio
10 KV/uS
Rohs Compliant
Yes
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Lead Free Status / RoHS Status
Lead free / RoHS Compliant, Lead free / RoHS Compliant
Other names
516-1583-5
Available stocks
Company
Part Number
Manufacturer
Quantity
Price
Company:
Part Number:
HCPL-3140-000E
Manufacturer:
AVAGO
Quantity:
40 000
Part Number:
HCPL-3140-000E
Manufacturer:
AVAGO/安华高
Quantity:
20 000
CMR with the LED On (CMR
A high CMR LED drive circuit
must keep the LED on during
common mode transients. This is
achieved by overdriving the LED
current beyond the input
threshold so that it is not pulled
below the threshold during a
transient. A minimum LED
current of 8 mA provides
adequate margin over the
maximum I
achieve 10 kV/ s CMR.
CMR with the LED Off (CMR
A high CMR LED drive
circuit must keep the LED off
(V
mode transients. For example,
during a -dV
Figure 23, the current flowing
through C
through the R
logic gate. As long as the low
state voltage developed across
the logic gate is less than V
the LED will remain off and no
common mode failure will occur.
The open collector drive circuit,
shown in Figure 24, can not keep
the LED off during a +dV
transient, since all the current
flowing through C
14
F
V
F(OFF)
LEDP
FLH
CM
SAT
) during common
/dt transient in
also flows
of 5 mA to
and V
LEDN
SAT
must be
H
L
CM
)
)
of the
F(OFF)
/dt
supplied by the LED, and it is
not recommended for
applications requiring ultra high
CMR
alternative drive circuit which
like the recommended
application circuit (Figure 19),
does achieve ultra high CMR
performance by shunting the
LED in the off state.
IPM Dead Time and Propagation
Delay Specifications
The HCPL-3140/HCPL-0314
includes a Propagation Delay
Difference (PDD) specification
intended to help designers
minimize “dead time” in their
power inverter designs. Dead
time is the time high and low
side power transistors are off.
Any overlap in Ql and Q2
conduction will result in large
currents flowing through the
power devices from the high-
voltage to the low-voltage motor
rails. To minimize dead time in a
given design, the turn on of
LED2 should be delayed (relative
to the turn off of LED1) so that
under worst-case conditions,
transistor Q1 has just turned off
when transistor Q2 turns on, as
shown in Figure 26. The amount
of delay necessary to achieve this
1
performance. The
condition is equal to the
maximum value of the
propagation delay difference
specification, PDD max, which is
specified to be 500 ns over the
operating temperature range of
-40 to 100 C.
Delaying the LED signal by the
maximum propagation delay
difference ensures that the
minimum dead time is zero, but it
does not tell a designer what the
maximum dead time will be. The
maximum dead time is equivalent
to the difference between the
maximum and minimum
propagation delay difference
specification as shown in
Figure 27. The maximum dead
time for the HCPL-3140/HCPL-
0314 is 1 s (= 0.5 s - (-0.5 s))
over the operating temperature
range of –40 C to 100 C.
Note that the propagation delays
used to calculate PDD and dead
time are taken at equal
temperatures and test conditions
since the optocouplers under
consideration are typically
mounted in close proximity to
each other and are switching
identical IGBTs.
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