ACPL-P456-020E Avago Technologies US Inc., ACPL-P456-020E Datasheet - Page 9

ACPL-P456-020E

Manufacturer Part Number

ACPL-P456-020E

Description

Optocoupler(1MBd),UL+LF

Manufacturer

Avago Technologies US Inc.

Datasheet

1.ACPL-P456-500E.pdf (12 pages)

Specifications of ACPL-P456-020E

Voltage - Isolation

5000Vrms

Number Of Channels

1, Unidirectional

Current - Output / Channel

15mA

Propagation Delay High - Low @ If

200ns @ 10mA

Current - Dc Forward (if)

25mA

Input Type

Output Type

Open Collector

Mounting Type

Surface Mount

Package / Case

SO-6

Number Of Elements

Forward Voltage

1.8V

Forward Current

25mA

Output Current

15mA

Isolation Voltage

5000Vrms

Operating Temp Range

-40C to 100C

Current Transfer Ratio

90%

Power Dissipation

145mW

Propagation Delay Time

550ns

Pin Count

Mounting

Surface Mount

Reverse Breakdown Voltage

Operating Temperature Classification

Industrial

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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Figure 11. Propagation Delay vs. Input Current.

Applications Information

LED Drive Circuit Considerations For Ultra High CMR

Performance

Without a detector shield, the dominant cause of opto-

coupler CMR failure is capacitive coupling from the input

side of the optocoupler, through the package, to the

detector IC as shown in Figure 13. The ACPL-P456/W456

improve CMR performance by using a detector IC with

an optically transparent Faraday shield, which diverts the

capacitively coupled current away from the sensitive IC

circuitry. However, this shield does not eliminate the ca-

pacitive coupling between the LED and the optocoupler

output pin and output ground as shown in Figure 14.

This capacitive coupling causes perturbations in the LED

current during common mode transients and becomes

the major source of CMR failures for a shielded optocou-

pler. The main design objective of a high CMR LED drive

circuit becomes keeping the LED in the proper state (on

or off ) during common mode transients. For example,

the recommended application circuit (Figure 12), can

achieve 15 kV/μs CMR while minimizing component

complexity. Note that a CMOS gate is recommended in

Figure 12 to keep the LED off when the gate is in the high

state.

Figure 12. Recommended LED Drive Circuit.

Figure 13. Optocoupler Input to Output Capacitance Model for Unshielded

Optocouplers.

500

400

300

200

100

CMOS

+5 V

310 Ω

= 100 pF

= 25 C

= 20 kΩ

= 15 V

LEDP

LEDN

– FORWARD LED CURRENT – mA

SHIELD

0.1 μF

* 100 pF TOTAL

CAPACITANCE

PLH

PHL

20 kΩ

OUT

= 15 V

Another cause of CMR failure for a shielded optocoupler

is direct coupling to the optocoupler output pins through

magnitude of the direct coupling including: the position

of the LED current setting resistor and the value of the

capacitor at the optocoupler output (C

Figure 14. Optocoupler Input to Output Capacitance Model for Shielded

Optocouplers.

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. The recommended minimum LED current of 10

mA provides adequate margin over the maximum I

4.0 mA (see Figure 1) to achieve 15 kV/μs CMR.

The placement of the LED current setting resistor effects

the ability of the drive circuit to keep the LED on during

transients and interacts with the direct coupling to the

optocoupler output. For example, the LED resistor in

Figure 15 is connected to the anode. Figure 16 shows

the AC equivalent circuit for Figure 15 during common

mode transients. During a +dV

current available at the LED anode (Itotal) is limited by

the series resistor. The LED current (I

DC value by an amount equal to the current that flows

through C

because the current through C

trying to pull the output high (toward a CMR failure) at

the same time the LED current is being reduced. For this

reason, the recommended LED drive circuit (Figure 12)

places the current setting resistor in series with the LED

cathode. Figure 17 is the AC equivalent circuit for Figure

12 during common mode transients. In this case, the

LED current is not reduced during a +dV

because the current flowing through the package capaci-

tance is supplied by the power supply. During a -dV

dt transient, however, the LED current is reduced by the

amount of current flowing through C

CMR performance is achieved since the current flowing

in C

output low.

Figure 15. LED Drive Circuit with Resistor Connected to LED Anode (Not

Recommended).

LEDO1

+5 V

LEDO1

CMOS

in Figure 14. Many factors influence the effect and

310 Ω

LEDP

LEDN

LEDP

during a negative transient acts to keep the

and C

SHIELD

LEDO1

SHIELD

LED01

. The situation is made worse

)

LEDO1

0.1 μF

/dt in Figure 16, the

* 100 pF TOTAL

CAPACITANCE

) is reduced from its

has the effect of

LEDN

20 kΩ

. But, better

/dt transient

OUT

= 15 V

ACPL-P456-020E Avago Technologies US Inc., ACPL-P456-020E Datasheet - Page 9

ACPL-P456-020E

Specifications of ACPL-P456-020E

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