HCPL-J314 Datasheet, PDF(15/17 Page) Agilent(Hewlett-Packard) – 0.4 Amp Output Current IGBT Gate Drive Optocoupler

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HCPL-J314 Datasheet, PDF (15/17 Pages) Agilent(Hewlett-Packard) – 0.4 Amp Output Current IGBT Gate Drive Optocoupler

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15

CMR with the LED On

(CMRH)

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 IFLH of 5 mA to

achieve 10 kV/Âµs CMR.

CMR with the LED Off

(CMRL)

A high CMR LED drive

circuit must keep the LED off

(VF â¤ VF(OFF)) during common

mode transients. For example,

during a -dVCM/dt transient in

Figure 23, the current flowing

through CLEDP also flows

through the RSAT and VSAT of the

logic gate. As long as the low

state voltage developed across

the logic gate is less than VF(OFF)

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 +dVCM/dt

transient, since all the current

flowing through CLEDN must be

supplied by the LED, and it is

not recommended for

applications requiring ultra high

CMR1 performance. The

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-J314 includes a

Propagation Delay Difference

(PDD) specification intended to

help designers minimize âdead

timeâ 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

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

-40Â° to 100Â°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-J314 is 1 Âµs

(= 0.5 Âµs - (-0.5 Âµs)) over the

operating temperature range of

-40Â°C to 100Â°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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