IL300 Datasheet, PDF(1/8 Page) Siemens Semiconductor Group

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IL300 Datasheet, PDF (1/8 Pages) Siemens Semiconductor Group – LINEAR OPTOCOUPLER

IL300

LINEAR OPTOCOUPLER

FEATURES

â¢ Couples AC and DC signals

â¢ 0.01% Servo Linearity

â¢ Wide Bandwidth, >200 KHz

â¢ High Gain Stability, Â±0.005%/C

â¢ Low Input-Output Capacitance

â¢ Low Power Consumption, < 15mw

â¢ Isolation Test Voltage, 5300 VACRMS,

1 sec.

â¢ Internal Insulation Distance, >0.4

for VDE

â¢ Underwriters Lab File #E52744

â¢ VDE Approval #0884 (Optional with

Option 1, Add -X001 Sufï¬x)

â¢ IL300G Replaced by IL300-X006

APPLICATIONS

â¢ Power Supply Feedback Voltage/

Current

â¢ Medical Sensor Isolation

â¢ Audio Signal Interfacing

â¢ Isolate Process Control Transducers

â¢ Digital Telephone Isolation

DESCRIPTION

The IL300 Linear Optocoupler consists of

an AlGaAs IRLED irradiating an isolated

feedback and an output PIN photodiode

in a bifurcated arrangement. The feed-

back photodiode captures a percentage

of the LED's ï¬ux and generates a control

signal (IP1) that can be used to servo the

LED drive current. This technique com-

pensates for the LED's non-linear, time,

and temperature characteristics. The out-

put PIN photodiode produces an output

signal (IP2) that is linearly related to the

servo optical ï¬ux created by the LED.

The time and temperature stability of the

input-output coupler gain (K3) is insured

by using matched PIN photodiodes that

accurately track the output ï¬ux of the

LED.

A typical application circuit (Figure 1)

uses an operational ampliï¬er at the circuit

input to drive the LED. The feedback

photodiode sources current to R1 con-

nected to the inverting input of U1. The

photocurrent, IP1, will be of a magnitude

to satisfy the relationship of (IP1=VIN /R1).

Dimensions in inches (mm)

.268 (6.81)

.255 (6.48)

Pin One I.D.

56 78

.390 (9.91)

.379 (9.63)

.045 (1.14) .150 (3.81)

.030 (.76) .130 (3.30)

.305 Typ.

(7.75) Typ.

4Â° Typ.

.022 (.56)

.018 (.46)

.040 (1.02)

.030 (.76 )

.100 (2.54) Typ.

10 Â° Typ.

3Â°â9Â°

.012 (.30)

.008 (.20)

.135 (3.43)

.115 (2.92)

DESCRIPTION (continued)

The magnitude of this current is directly proportional to the feedback transfer gain

(K1) times the LED drive current (VIN /R1=K1 â¢ IF). The op-amp will supply LED cur-

rent to force sufï¬cient photocurrent to keep the node voltage (Vb) equal to Va

The output photodiode is connected to a non-inverting voltage follower ampliï¬er. The

photodiode load resistor, R2, performs the current to voltage conversion. The output

ampliï¬er voltage is the product of the output forward gain (K2) times the LED current

and photodiode load, R2 (VO=IF â¢ K2 â¢ R2).

Therefore, the overall transfer gain (VO/VIN) becomes the ratio of the product of the

output forward gain (K2) times the photodiode load resistor (R2) to the product of the

feedback transfer gain (K1) times the input resistor (R1). This reduces to VO/VIN=

(K2 â¢ R2)/(K1 â¢ R1). The overall transfer gain is completely independent of the LED

forward current. The IL300 transfer gain (K3) is expressed as the ratio of the ouput

gain (K2) to the feedback gain (K1). This shows that the circuit gain becomes the

product of the IL300 transfer gain times the ratio of the output to input resistors [VO/

VIN=K3 (R2/R1)].

Figure 1. Typical application circuit

Va +

Vin

Vb -

VCC

lp 1

IL300

6 VCC

lp 2 R2

VCC

Vout

5â1

▷