AN-3001 Datasheet, PDF(1/7 Page) Fairchild Semiconductor – Application Note AN-3001 Optocoupler Input Drive Circuits

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AN-3001 Datasheet, PDF (1/7 Pages) Fairchild Semiconductor – Application Note AN-3001 Optocoupler Input Drive Circuits

Application Note AN-3001

Optocoupler Input Drive Circuits

www.fairchildsemi.com

An optocoupler is a combination of a light source and a

photosensitive detector. In the optocoupler, or photon

coupled pair, the coupling is achieved by light being

generated on one side of a transparent insulating gap and

being detected on the other side of the gap without an

electrical connection between the two sides (except for a

minor amount of coupling capacitance). In the Fairchild

Semiconductor optocouplers, the light is generated by an

infrared light emitting diode, and the photo-detector is a

silicon diode which drives an ampliï¬er, e.g., transistor. The

sensitivity of the silicon material peaks at the wavelength

emitted by the LED, giving maximum signal coupling.

Where the input to the optocoupler is a LED, the input

characteristics will be the same, independent of the type of

detector employed. The LED diode characteristics are shown

in Figure 1. The forward bias current threshold is shown at

approximately 1 volt, and the current increases exponen-

tially, the useful range of IF between 1 mA and 100 mA

being delivered at a VF between 1.2 and 1.3 volts. The

dynamic values of the forward bias impedance are current

dependent and are shown on the insert graph for RDF and

âR as deï¬ned in the ï¬gure. Reverse leakage is in the nano-

ampere range before avalanche breakdown.

The LED equivalent circuit is represented in Figure 2, along

with typical values of the components. The diode equations

are provided if needed for computer modeling and the con-

stants of the equations are given for the IR LEDâs. Note that

the junction capacitance is large and increases with applied

forward voltage. An actual plot of this capacitance variation

with applied voltage is shown on the graph of Figure 3. It is

this large capacitance controlled by the driver impedance

which inï¬uences the pulse response of the LED. The capaci-

tance must be charged before there is junction current to

create light emission. This effect causes an inherent delay of

10-20 nanoseconds or more between applied current and

light emission in fast pulse conditions.

The LED is used in the forward biased mode. Since the

current increases very rapidly above threshold, the device

should always be driven in a current mode, not voltage

driven. The simplest method of achieving the current drive is

to provide a series current-limiting resistor, as shown in

Figure 4, such that the difference between VAPP and VF is

dropped across the resistor at the desired IF, determined from

other criteria. A silicon diode is shown installed inversely

parallel to the LED. This diode is used to protect the reverse

breakdown of the LED and is the simplest method of achiev-

ing this protection. The LED must be protected from exces-

sive power dissipation in the reverse avalanche region. A

small amount of reverse current will not harm the LED, but it

must be guarded against unexpected current surges.

The forward voltage of the LED has a negative temperature

coefï¬cient of 1.05 mV/Â°C and the variation is shown in

Figure 5.

The brightness of the IR LED slowly decreases in an expo-

nential fashion as a function of forward current (IF) and time.

The amount of light degradation is graphed in Figure 6

which is based on experimental data out to 20,000 hours.

A 50% degradation is considered to be the failure point.

This degradation must be considered in the initial design of

optoisolator circuits to allow for the decrease and still remain

within design speciï¬cations on the current-transfer-ratio

(CTR) over the design lifetime of the equipment. Also, a

limitation on IF drive is shown to extend useful lifetime of

the device.

In some circumstances it is desirable to have a deï¬nite

threshold for the LED above the normal 1.1 volts of the

diode VF. This threshold adjustment can be obtained by

shunting the LED by a resistor, the value of which is

determined by a ratio between the applied voltage, the

series resistor, and the desired threshold. The circuit of

Figure 7 shows the relationship between these values.

The calculations will determine the resistor values required

for a given IFT and VA. It is also quite proper to connect

several LEDâs in series to share the same IF. The VF of the

series is the sum of the individual VFâs. Zener diodes may

also be used in series.

Where the input applied voltage is reversible or alternating

and it is desired to detect the phase or polarity of the input,

the bipolar input circuit of Figure 8 can be employed. The

individual optocouplers could control different functions or

be paralleled to become polarity independent. Note that in

this connection, the LEDâs protect each other in reverse bias.

REV. 4.00 4/30/02

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