DE3607688A1 - Receiver (reception module) for an optical communications path - Google Patents

Abstract

A receiver 1, 23 for an optical communications path has an input amplifier (transimpedance amplifier 2, 5; high-impedance amplifier 17, 20) whose transmission function can be set along with internal transmission features by means of an assigned external matching resistor (negative feedback resistor 5; resistor 20 connected in parallel with the amplifier input 26). An opto-electrical photodetector (photodiode 6, 16) interacts optically with the coupling-out end 7, 15 of the optical transmission medium (optical waveguide 8, 30) and its output signal is fed to the input 4, 26 of the amplifier 2, 17. In order to develop the receiver so that it can be used in simple fashion at any points in optical communications systems, so that it is designed in simple and robust form and can function without expensive optical attenuation components, the matching resistor (negative feedback resistor 5; resistor 20 connected in parallel with the amplifier input 26) is designed as a photosensitive component (photoresistor) whose resistance value (RP) can be adjusted by feeding in controllable light intensity either manually or automatically. <IMAGE>

Description

The invention relates to a receiver or receiver component, also called a receiving module, for an optical Communication link, with the characteristics of The preamble of claim 1.

In the field of message transmission are alongside conventional transmission techniques recently ver more optical transmission systems are used because they differs from conventional transmission types are characterized by a variety of compelling advantages. For example, they are interference-free against electromagnetic cal waves, they enable total electrical engineering Isolation between transmitter and receiver, very high Bandwidth of the transmissible signals, a relatively ge rings damping and thus bridging large ent remote without the use of repeaters, what optical communication systems far less susceptible to failure than conventional systems, in particular re if digital technology, for example PCM technology turns.

Another advantage to be mentioned is that optical Communication links are relatively bug-proof and - a point that is becoming increasingly important - the lines are metal-free, which means a considerable amount saving of the raw material copper can be achieved can.

Serves as a receiver of the optical light signals in the Usually an optoelectric detector, for example in Form of a photodiode at the decoupling end of the opti  medium, usually in the form of one from one Glass fiber or a fiber optic bundle of existing light conductor with which light interacts. The Output signal of the light detector must be on amplifier of the receiver module.

For example, so-called "high impedance" amplifier conceivable, theoretically have a fairly good sensitivity; you will be however rarely used, because their bandwidth to Limiting the noise is kept low and the Amplifier acts as an integrator. This behavior If necessary, it must be followed by a downstream Equa lizer (equalizer) can be compensated.

In contrast, so-called transimpedance amplifiers have become Input amplifiers especially proven, their transmission by a amplifier output with the Input negative feedback resistor determined becomes.

Since the optical power incident on the light detector can change by up to 40 dB depending on the length of the optical waveguide paths in an optical transmission line, it is desirable to have receiver modules whose dynamic range is approximately 80 dB. Such a receiver module possess the significant advantage that it - may be used independently of the present at the respective position, incident on the receiver optical power at any point of the communications transmission link - without further circuitry or optical auxiliary measures (at play, optical attenuators). Conventional active adjustable resistance elements have to fail here because, on the one hand, their setting range is not sufficient to ensure a dynamic range of 80 dB and, on the other hand, high frequency and noise behavior of the transimpedance amplifier or "high impedance" amplifier are deteriorated by parasitic effects.

Attempts have already been made to use PIN diodes or FETs adjustable resistors, but this had to be done essentially fail because, for example, PIN diodes a high lower cutoff frequency and a too large parasi tary capacity to have a really trouble-free To ensure operation. The one by a capacity ar adjustable resistance formed by FET is capable of the desired dynamic range of the receiver mo duls not guarantee, moreover, bring FETs often non-linear distortions due to a characteristic line curvature with itself.

The invention has for its object a recipient ger of the type described above ver better that he is simple and without regard for existing signal intensity at any point used by optical communication systems can be. This task is characterized by the Features of claim 1 solved, advantageous Wei Further training results from the subclaims.

Invention-bearing is the use of a light temp sensitive component formed feedback or parallel input resistance, its resistance value by supplying adjustable light intensity manually or is automatically adjustable, in particular a low-capacity and high-frequency compatible photowider stand should be used. Through the "optical" and thus potential-free influence on the  Photoresistance and thus the gain will increase next the feeding of disturbances in the receiver avoided. This has a further advantageous effect Characteristic curve and the extremely large adjustment range of the Pho resistance. The regulation of the degree of amplification is - as already noted above - potential-free, see above that the interference from potential interference closed is. This reduces the number of errors Liability of repeaters quite significantly, so that the availability of optical communications distance can be further increased.

Advantageously, in the radiation receiving area photosensitive component, namely the photoresistor of a regulated electric light source for setting arranged the resistance value. This can be done by a control device can be supplied as ge closed loop is formed and dependent on the output voltage of the preamplifier works. At for example, the output voltage of the amplifier thereby be regulated constantly. But it is also possible Lich to provide a control device that directly on the on the optoelectric light detector, namely the incident radiation intensity rea yaws. However, this second solution is so far part, as optical communication systems in generally operated up to the noise limit and thus an optimal use of the available to strive for light intensity for signal transmission is, so that a coupling of a light portion to Re usually must be eliminated.

A characteristic curve component has a particularly advantageous effect tion according to claim 8, since then the optoelectri components do not cause fluctuations in regulation.  

The transimpedance amplifier or are advantageously "high impedance" amplifier, the light detector, the photosensitive component, the light source and the electronic components of the scheme in a common men housing arranged. This can be two light-tight have mutually separated chambers, the first at least the light detector, namely that of the light contains coupled photodiode, and the second at least the photosensitive component, namely the Photoresistor as well as the regulated electric light source contains. This is a mutual influence solution of the two light sources excluded.

It is also advantageous if the automatically regulating gain on a display device can be displayed or as an output signal at a measuring output gear is present. Then the receiving module can immediately as Measurement detector used to determine the optical quality of a Check the transmission link section fen.

Since it may be that the gain the frequency response of the receiver also changes, it can be advantageous if the scheme is an equali zerike device includes the readjustment of the Gain a selective influence, at for example a constant control or selective approach Exercise or lower the frequency response of the amplifier makes.

The invention is based on two exemplary embodiments in the drawing figures explained in more detail. These show:  

Figure 1 is a schematic diagram with indicated housing elements of a first embodiment of the invention.

Fig. 2 is a block diagram with indicated housing elements according to a second embodiment of the invention.

In Fig. 1, the overall designated as 1 receiver for an optical communication link has a transimpedance amplifier 2 designed as an input amplifier, the transfer function of which is determined by a negative feedback resistor connecting the amplifier output 3 to the inverting input 4 , which is designed as a low-capacitance and high-frequency suitable photoresistor 5 is.

With the input of the amplifier 2 is a trained as a photo diode 6 optoelectric light detector in connection, on which the incoming through the decoupling end 7 of the optical transmission medium (light guide 8 ) radiation and causes the flow of a photocurrent which is converted into the signal to be amplified .

In the radiation receiving area of the photoresistor 5 , a regulated electric light source 9 for adjusting the resistance value of the photoresistor 5 is arranged, which is operated via a closed-loop control 10 , the controlled variable of which depends on the output voltage U _{A of} the amplifier 2 .

The control 10 can also compensate for the characteristic line of the photoresistor 5 and / or the photodiode 6 overlay the amplified signal a non-linear Regelkomponen te, which is indicated by arrow 11 .

The schematically illustrated housing elements make it clear that the interior of the housing breaks down into two light-tightly separated chambers A and B , the first of which contains the photodiode 6 in the region of the coupling end 7 of the light guide 8 and the second chamber B of which contains the photoresistor 5 and the regulated light source 9 contains. This can be particularly necessary if a mutual influence of the two light sources, namely the end of the optical waveguide and the light source for controlling the photoresistor, should have a disruptive effect.

The automatically regulating degree of amplification of the amplifier 2 is shown on a display device 12 (not shown) or is present as an output signal at a measurement output 13 .

The modified game Ausführungsbei shown in Fig. 2 essentially corresponds to that shown in Fig. 1 Darge. However, the receiver 23 , which is housed in a housing 27 with housing sections C and D un, a so-called "high impedance ampli fier" or high-ohmic amplifier, whose input 26 , which is connected to the photodiode 16 , continues to be connected in parallel with a resistor is connected, which is designed as a photoresistor 20 and can be irradiated by a controllable light source 21 . The light source 21 is - like in the first game Ausführungsbei - with a control 19 connected to and supplied with power by this. The control 19 speaks - as indicated by arrow 22 - on the output signal U _{A of} the amplifier 17 . The controlled variable of the control 19 can be read off by a display device 24 and / or a measuring output 25 or can be tapped at the housing.

Claims (13)

1. Receiver (receiving module) for an optical communication link with the following features:

• - The receiver ( 1 , 23 ) has an input amplifier (transimpedance amplifier 2, 5 ; "high impedance amplifier" = high-impedance amplifier 17, 20 ),
  • - Its transmission function, in addition to the internal transmission characteristics, can be adjusted by an external adaptation resistor assigned to it (negative feedback resistor 5 ; resistor 20 connected in parallel with amplifier input 26 );
• with the decoupling end ( 7 , 15 ) of the optical transmission medium (light guides 8 , 30 ), an optoelectric converter (photodiode 6, 16 ) is in optical interaction,
  • - The output signal of the input ( 4 , 26 ) of the amplifier ( 2 , 17 ) is supplied, characterized by the following features :.
• The matching resistor (negative feedback resistor 5 ; resistor 20 connected in parallel to the amplifier input 26 ) is designed as a light-sensitive component (photoresistor),
  • - Its resistance value ( R _P ) can be adjusted manually or automatically by adding adjustable light intensity.

2. Receiver according to claim 1, characterized in that the input amplifier of the receiver ( 1 ) is designed as a transimpedance amplifier ( 2 ) and the matching resistor as an associated negative feedback resistor ( 5 ). 3. Receiver according to claim 1, characterized in that the input amplifier of the receiver ( 23 ) is designed as a "high impedance amplifier" (= high-ohmic amplifier 17 ) and the matching resistor as an associated resistor ( 20 ) connected in parallel with the amplifier input ( 26 ) . 4. Receiver according to one of the preceding claims, characterized in that a regulated light source ( 9 , 21 ) for setting the resistance value ( R _P ) is arranged in the radiation receiving region of the light-sensitive component (photoresistor 5, 20 ). 5. Receiver according to one of the preceding claims, characterized in that the light-sensitive component was a high-frequency and low-noise photowider ( 5 , 20 ). 6. Receiver according to claim 4, characterized in that the control ( 10 , 19 ) is designed as a closed control loop and is dependent on the output voltage U _A. 7. Receiver according to claim 4, characterized in that the control ( 10 , 19 ) is dependent on the incident on the optoelectric converter (photodiode 6, 16 ) radiation intensity. 8. Receiver according to claim 6 or 7, characterized in that the control ( 10 , 19 ) for compensating the characteristic of the light-sensitive component (photoresistor 5, 20 ) or the opto-electrical converter's (photodiode 6, 16 ) the amplified signal a non-linear Control component overlaid. 9. Receiver according to claim 8, characterized, that the non-linearity of the control component is adjustable.   10. Receiver according to one of the preceding claims, characterized in that the transimpedance amplifier ( 2 , 17 ), the light detector (photodiode 6, 16 ), the light-sensitive component (photoresistor 5, 20 ), the light source ( 9 , 21 ) and the electronic components of the control ( 10 , 19 ) are arranged in a common housing ( 14 , 27 ). 11. Receiver according to claim 8, characterized in that the housing ( 14 , 27 ) two light-tight against each other separated chambers ( A , B ; C , D ), the first (A; C) at least the light detector (photodiode 6th , 16 ) and their two parts (B; D) at least the light-sensitive construction part (photoresistor 5, 20 ) and the regulated light source ( 9 , 21 ). 12. Receiver according to one of the preceding claims, characterized in that the automatically regulating degree of gain on a display device ( 12 ; 24 ) can be shown or is present as an output signal at a measuring output ( 13 ; 25 ). 13. Receiver according to one of the preceding claims, characterized in that the control ( 10 ; 19 ) comprises a device (equalizer) by means of which the frequency response of the amplifier can be selectively adjusted (for example constantly adjustable) when readjusting.