DE2736966A1 - TRANSMITTER FOR OPTICAL RADIATION - Google Patents

Description

TRANSMITTER FOR OPTICAL RADIATION

The invention relates to a transmitter for optical Radiation with a laser diode and one of these upstream modulators, as well as a controller for the optimal modulation of the laser beam / its control signal is fed to an input of the modulator for controlling the modulation.

The ideal laser diode should have a normalized optical output signal for a standardized electrical one Provide input levels regardless of temperature and age. This can only be achieved with a regulation to which part of the emitted radiation is supplied as an actual value and which has a control signal for readjustment the electrical input values of the laser diode emits. The modulation of the laser diode is done in such a way that the laser diode is controlled by a current corresponding to the modulation signal. Here it is possible to always achieve the optimal modulation of the laser diode by regulating the modulator. A regulator for a transmitter for optical radiation with a laser diode that combines both of the control loops specified above, has already been proposed.

909809/0123

D.Böttle-1

Now it can happen that if there is no modulation signal the modulator is set to its maximum gain because it appears to the controller to as Cb the modulation signal is extremely small. Appears then the modulation signal is back in its normal size, the laser diode is amplified by the very high signal beginning far overdriven and destroyed.

It is the object of the present invention to specify a transmitter of the type mentioned at the outset, the laser diode thereof is protected against overload and thus failure due to excessive electrical stress.

This problem is solved with the means specified in the claim. Further training and developments can be found in the subclaims.

A simple additional measure makes the laser diode effective against destruction by the recurring Modulation signal protected. The specified detector can be constructed from a few inexpensive components.

The invention is explained in more detail below with reference to drawings of an exemplary embodiment. Show it:

1 shows a block diagram of a transmitter for optical Radiation and

Fig. 2 to 4 block diagrams for different versions a detector according to Fig.1.

909809/0123

D.Bottle-1

The transmitter for optical radiation shown in FIG. 1 has a modulator 1 , a laser diode 2, a controller and a detector 4. The modulator 1 has an input clone 5 to which a modulation signal M is applied. This arrives in modulator 1 via an amplifier 6 with controllable amplification factor to a driver circuit 7 for the laser diode 2. To modulate the laser diode 2, its anode is connected to the voltage V + and its cathode via the driver circuit 7 to the voltage V * . The laser diode 2 emits the laser beam indicated by two parallel arrows.

Part of the laser beam reaches a photodiode 8, which therefore supplies the controller 3 with a current corresponding to the actual value of the laser beam. The controller 3 obtains an actuating signal U1 from this in a known manner by comparing it with a setpoint value. The control signal U1 reaches an input 9 of the modulator 1 via the detector 4, and from there to the amplifier 6 and controls it such that an optimal modulation of the laser beam is achieved.

The modulation signal M and the control signal U1 are fed to the detector 4. If the modulation signal M is present, it switches the control signal U1 through to the input of the modulator 1. If the modulation signal M fails, the detector 4 switches a substitute signal U2 to the input 9, which the amplifier 6 in the modulator 1

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D.BÖttle-1

to a gain that is permissible even when the modulation signal M returns. This setting can happen for example to a medium value or to the value zero.

In FIGS. 2 to 4, the detector 4 is shown in detail in various possible designs. The detector 4 consists in each case of a monitoring circuit for the modulation signal M, one of these controlled, preferably electronic switch 10 and a source 11 for the substitute signal U2.

In the embodiment shown in FIG Monitoring circuit for a digital modulation signal M from a retriggerable monoflop 12. The service life of the Monoflop 12 is at least equal to the cycle time of the modulation signal M multiplied by the maximum permissible Number of successive binary "0" signals. In the case of a normal modulation signal M, the monoflop becomes 12 retriggered by each binary "1" signal, so that the Changeover switch 10 is held in the position shown by the output signal of the monoflop. The control signal U1 is switched through to input 9 of modulator 1. If the modulation signal M fails, for example, so switches the monoflop 12 back after its idle time. As a result, the switch 12 is in its other position brought and switches the substitute signal U2 of the source 11 to the input 9 of the modulator 1.

In the embodiment shown in Figure 3 there is the monitoring circuit for a digital modulation signal M from a shift register 13 with * (n + 1) stages with a downstream decoding, for example one

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D.BÖttle-1

NAND circuit 14. The stages are each with an input of the NAND circuit 14 tied together . Here, η is equal to the maximum permitted number of consecutive binary "0" signals. The output signal of the NAND circuit controls the position of the switch 10. Are more than η binary "0" signals in the shift register 13, the changeover switch 10 is brought into its other position.

In the embodiment shown in FIG Control signal U1 monitored. The actuating signal U1 and the signal from a voltage source 16 are fed to a threshold value circuit 15. The voltage source can be adjusted his and her value determines the threshold of the threshold value circuit 15. If the control signal U1 exceeds the Threshold value, it can indicate a failure of the modulation signal are closed and the switch 10 is from the threshold circuit in its other position brought.

6 claims 2 sheets drawing

909809/0123

Claims (6)

STANDARD ELECTRICS LORENZ SHARED COMPANY STUTTGART 2736966 D.BÖttle-1 Expectations 1 / transmitter for optical radiation with a laser diode and one of these upstream modulators, as well as a controller for the optimal modulation of the laser beam , whose control signal is fed to an input of the modulator to control the modulation, characterized in that in the absence of the modulation signal (M) the The input (9) for the control signal (U1) of the modulator (1) can be fed to a substitute signal (U2) that maintains a substitute signal (U2) that maintains a permissible operating value even when the modulation signal (M) reappears. 2. Transmitter according to claim 1, characterized in that the modulator (1) is switched off by the substitute signal (U2). 3. Transmitter according to claim 1, characterized in that between the controller (3) and the modulator (1) a modulation signal monitoring detector (4) with a switch (10) controlled by this, which the control signal (U1) of the controller ( 3) or the substitute signal (U2) switches to the input (9) of the modulator (1), is arranged. 4. Transmitter according to claim 3, characterized in that the detector (4) contains a retriggerable monoflop (12) to which the modulation signal (M) is fed and whose output signal controls the switch (10). Wr / Scho
7/12/77 909809/0123 ORIGINAL INSPECTED D.BÖttle-1 5. Transmitter according to claim 3, characterized in that »that the detector (4) contains a shift register (13) with a downstream decoding (14) to which the modulation signal (M) is fed and whose output signal controls the switch (10). 6. Transmitter according to claim 1, characterized / that between the controller (3) and the modulator (1) a control signal (U1) monitoring detector (4) with a switch (10) controlled by this, which controls the control signal (11) or the substitute signal (U2) switches to the input (9) of the modulator (1), is arranged and that the detector (4) contains a threshold value circuit (15) to which the control signal (U1) and a reference signal is fed and whose output signal is the Changeover switch (10) controls. 909809/0123