VT300CT PerkinElmer Optoelectronics, VT300CT Datasheet - Page 39

VT300CT

Manufacturer Part Number

VT300CT

Description

Photoconductive Cells and Analog Optoisolators (Vactrols)

Manufacturer

PerkinElmer Optoelectronics

Datasheet

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Characteristics of Analog Optical Isolators

Transfer Characteristics

The light output of an LED is proportional to the input drive current, I

Some LEDs will begin to radiate useful amounts of light output at

forward currents as low as 10 µA. These same LEDs can be driven at

50 mA with no degradation in performance.

A transfer curve of output resistance versus input light current for a

typical AOI is shown in Figure 1. AOIs not only possess a large

dynamic range, but the output resistance tracks the input current in a

somewhat linear manner over a range of two or more decades.

This characteristic makes the AOI suitable for use in a very broad

range of applications, especially in audio circuits where they are used

for switching, limiting, and gating. For a more extensive discussion on

AOIs in audio circuits, refer to Application Notes #1.

Response Time

AOIs are not high speed devices. Speed is limited by the response

time of the photocell. With rise and fall times on the order of 2.5 to

1500 msec, most AOIs have bandwidths between 1 Hz and 200 Hz.

One of the characteristics of photocells is that their speed of response

increases with increasing levels of illumination

Vactrols is somewhat dependent upon the input drive level to the LED.

In general, the higher the input drive the wider the bandwidth.

The turn-off time and turn-on time of photocells are not symmetrical.

The turn-on time can be an order of magnitude faster than the turn-off

time. In the dark (no input), the resistance of the cell is very high,

typically on the order of several megohms. When light is suddenly

1. For a more comprehensive discussion on the turn-on and turn-

off characteristics of photocells and how response time is effect-

ed by light level, see the Photoconductive Cell section of this cat-

alog.

Figure 1. Transfer Curves (25°C)

Thus the bandwidth of

applied, the photocells resistance drops very fast, typically reaching

63% (1-1/e conductance) of its final values in under 10 msec.

When the light is removed, the resistance increases initially at an

exponential rate, approximately tripling in a few milliseconds. The

resistance then increases linearly with time.

The fast turn-on and slow turn-off characteristics can be used to

advantage in many applications. This is especially true in audio

applications where a fast turn-on (attack) and a slow turn-off (release)

is preferred. For example, the typical AOI can be made to turn-on in

100 to 1000 µsec. In a limited circuit this is fast enough to catch high

peak amplitudes but not so fast as to cause obvious clipping. The turn-

off will take as much as 100 times longer so the audio circuit will return

to a normal gain condition without a disturbing “thump” in the speaker.

Noise

The sources of electrical noise in the output element of AOIs are the

same as for any other type of resistor.

One source of noise is thermal noise, also known as Johnson or

“white” noise, which is caused by the random motion of free electrons

in the photoconductive material.

Figure 2. Resistance vs. Time

VT300CT PerkinElmer Optoelectronics, VT300CT Datasheet - Page 39

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