DD231694A1 - RECEPTION SWITCHING FOR OPTICAL IMPULSE - Google Patents

Abstract

The field of application of the receiving circuit for optical pulses is optical fiber short-range transmission. The aim of the invention is the largely undistorted signal generation for the high-data transmission. The object of the invention is the development of a receiving circuit for optical pulses with extreme Tastverhaeltnisverschiebungen, the circuit is based on the direct coupled Verstaerkerprinzip. According to the invention, the input amplifiers operating in parallel operation, of which only one is equipped with a photodiode, are connected on the output side via a voltage divider. The center tap of the voltage divider, at which the threshold voltage is present, is connected to the inverting input of the comparator via a one or two-stage peak detector and an impedance converter, and the signal voltage from the output of the active input amplifier is fed to the noninverting input of the comparator. Fig. 1

Description

Applicant: Berlin, 20.11.84

combine; VEB (P 1513)

Slektro-Apparate-Werke Berlin-Treptow Center for! Research and Technology 1055 Berlin Storkower Str. 101

Receiving circuit for optical pulses

HÖ3? 3.8

Field of application of the invention

The field of application of the receiving circuit for optical pulses is optical fiber short-range transmission in the field of automation, control and regulation technology, signal and safety engineering as well as computer technology.

Characteristic of the known technical solutions

An optical receiving circuit DE 31 23 919 _{7 is known} in which two identical transimpedance amplifiers are included whose outputs are connected to the inputs of a push-pull amplifier. The first transimpedance amplifier converts the current supplied by a potentiometer into voltage, the second serves to compensate for operational and temperature fluctuations. The amplifier concept with the following G-type clock amplifiers has the disadvantage that it does not use the information about the signal level level contained in the input signal for thresholding a decision step. Another circuit arrangement for the rapid detection of ground rectangular signals DE 30 33 565 is based on the delay principle for generating the output pulses. The signal from the input amplifier is given directly and a second time after a short delay to a comparator. In addition, the delayed signal from the output of the

Comparators still subjected to a hysteresis. Specialist part of this arrangement is the small signal difference with strong verschilffenen signals and a low signal to noise ratio. Another patent EP 00 63 448 describes a further possibility of swelling in a "digital waveform conditioning circut" using two peak detectors, each store only the positive or negative peak value of the signal and mutually via PET switch from the output of the circuit , a switched behind the comparator output D-Plip-Plop be controlled. Both peak detectors are connected to each other via two resistors. The voltage at the connection point of these two resistors is used to form the comparator threshold. Unfavorable in this Tariante is the increased technical effort. Perner is the principle tied to a clock, since the comparator itself still provides no temporally undistorted pulses and only on the clock and the D-Plip-flop, a synchronous and undistorted impulse exchange occurs.

Object of the invention

The aim of the invention is to achieve a largely undistorted signal regeneration for the high data rate transmission and to avoid settling times.

Essence of the invention

The object of the invention is to provide a receiving circuit for optical pulses for high-data-rate distortion-free transmission of pulses with extreme duty cycle shifts, the input circuit is based on the direct-coupled amplifier principle, the circuit complexity in the interest of a good Integrier- or Hybridisierbarke it remains low.

The object is achieved in such a way that the input amplifiers operating in parallel operation, of which only one is equipped with a photodiode, are connected together on the output side via a voltage divider. The output of the input amplifier at which the signal voltage is present is up

passed the noninverting input of a comparator. The center tap of the voltage divider, at which the threshold voltage is present, is fed to a peak detector, which is connected to further improve the hold time via an operational amplifier to the inverting input of the comparator. The hold capacitor is connected between the output of the peak detector and ground. The output of the operational amplifier is further fed back to its inverting input. The second input amplifier remains either unconnected or is equipped with a dummy diode for reasons of symmetry for the operating conditions. At its output, the signal quiescent voltage is provided to a voltage divider terminal.

In a first embodiment variant of the receiver circuit according to the invention, an operational amplifier is arranged as a peak value detector, to which a diode is connected downstream. Sound of the cathode of this diode is a feedback connected to the inverting input of this operational amplifier,

In a second embodiment of the receiver circuit is as a peak detector, a first transistor, connected to a holding capacitor for short-term storage and an operational amplifier with diode output, connected to a holding capacitor for long-term storage arranged. This operational amplifier is followed by a second operational amplifier with diode output for impedance conversion. The cathode terminal of the second diode is now connected to the inverting input of the comparator.

The threshold voltage at the center tap of the voltage divider is guided to the base of the first transistor, whose collector is applied to the operating voltage and whose emitter is connected via the parallel connection of a first emitter resistor and the Haltekondensairors for short-term storage to ground and is fed directly to the inverting input of the comparator , To compensate for the potential shift, which causes the base-emitter diode with its voltage U ^ ^ at the first transistor, a second emitter follower is arranged, whose output to the non-inverting input of

- 4 comparator is switched.

The advantage of such a circuit is the utilization of the high charging rate of the holding capacitor, especially after a long pause of LOW conditions for immediate adjustment of the comparator threshold still within the time of the first pulse and the holding time of the voltage at the peak detector.

The operational amplifier peak detector has an extremely long hold time. The comparator, but the threshold voltage is provided at high speed.

All embodiments have the generation of signal voltage and threshold voltage via two input amplifiers and the voltage divider in common. In principle, this concept provides the information as to which signal state is present at the input of the receiver. It can be sampled statically, since the signal arrest voltage is an absolute fixed quantity. In principle, any voltage difference between the input amplifiers is greater than Hull, which is equivalent to an H signal at the comparator output. The Pail signal voltage is equal to the signal quiescent voltage L level. However, in the interests of immunity to interference, a slight shift in the signal arrest voltage over the signal voltage for the Pail is typical, since the optical L state is present at the input. The comparator thus evaluates the I-state. Another reason for the use of 'two input amplifiers is that operating and temperature fluctuations in the influence on the threshold and signal evaluation of the comparator are largely compensated. For the dynamic operation, the center tap of the threshold voltage at the voltage divider acquires significance, since an undistorted evaluation of the optical input signals is only possible in the middle of the signal (assuming the same plank steepnesses LH / EL once).

The embodiments differ with respect to the provision of the threshold voltage from the center tap of the voltage divider for the comparator. The first variant stores the threshold voltage with the aid of the peak detector (operational amplifier), the diode and the holding capacitor. The downstream operational amplifier operates as an impedance converter

and prevents the load of the peak detector and accelerated discharge of the holding capacitor. Due to the high input resistance, PET operational amplifiers allow extremely long hold times and thus low impulse distortion to be achieved even with high duty cycles.

The second embodiment variant has in principle the same type of peak value storage for extremely long holding times. However, it allows, with the additional peak detection via the: first transistor, its emitter resistor and the holding capacitor for short times, a detection of extremely short pulses and due to the Eurzzeitspeicherung, but long enough for the downstream operational amplifier, a secure transfer into the long-term memory , Pur the time since the holding capacitor of this operational amplifier is not charged, the signal is delivered directly to the comparator from the emitter of the first transistor, Thus, the comparator is able to work properly even before the long-term nwert detector is charged. Prerequisite, however, is the diode additionally added in this impedance in the impedance converter output. In the case of a higher voltage at the emitter resistor, the Haitespannung at its output, no load may cause the emitter. A receiver circuit of this kind is thus able to start high-data-rate transmissions without distortion with the 1st bit.

embodiment

The invention will be described below with reference to the Pig. 1 and 2 are explained in more detail.

The receiving circuit for optical pulses according to Pig. 1 consists of a first input amplifier E1, in the Eegel a transimpedance amplifier, at the input of the anode of a potentiometer PD is connected. The cathode is connected to the operating voltage υ _α . A second input amplifier E2, at the Eino

gang to compensate for the dark current of the potentiometer PD a dummy diode may be connected, runs parallel to the first input amplifier and supplies the signal arresting voltage U3. The output of the input amplifier E1 is connected directly to the non-inverting input of the output pulse generating comparator K. Perner he is over the voltage divider

R1 and R2 are connected to the output of the input amplifier E2. At the center tap of the voltage divider E1 and R2, the threshold voltage TJ2, which generally corresponds to the mid-signal voltage, tapped and the non-inverting input. gear of a first operational amplifier OV1 switched. The output of the operational amplifier 0V1 is applied to the anode of the diode D, whose cathode is led to the inverting input thereof, to the non-inverting input of the operational amplifier 0V2 and to one terminal of the capacitor C. The other terminal of the holding capacitor C is grounded. The output of the second, used as an impedance converter, operational amplifier 0V2 is located at the inverting input of the co-operator K and is fed back to its own inverting input. The threshold voltage U2 guided in this way to the comparator is stored by the operational amplifier for a very long time and the voltage divider R1, R2 is only minimally loaded.

The optical pulse receiving circuit of Fig. 2 also consists of the input amplifier E1, to the input of which the anode of the photodiode YD is connected. The second input amplifier E2 supplies the signal arresting voltage U3, as in variant 1. The output of the first input amplifier E1 is connected to the output of the input amplifier E2 via the resistors R1 and R2 of the voltage divider. At the center tap of this voltage divider, the threshold voltage Ü2 is tapped and fed to the base of a transistor T1 connected as an emitter follower. Parallel to its emitter resistor RE1, a short-time hold capacitor CE1 is connected to ground. In this way, a first fast peak value storage of the threshold voltage U2 is realized and effective at the comparator K. The emitter of the transistor T1 is further connected to the inverting input of the comparator K and the non-inverting input of the first operational amplifier 0V1. The output of this operational amplifier is connected to the anode of a first diode Ώ1 whose cathode feeds the signal back to the inverting input thereof and to the non-inverting input of the second operational amplifier 0V2 and to one of the other holding capacitors C ' capacitor

lies on earth. The output of the operational amplifier 0V2 is at the anode of diode D2. The cathode of this diode is returned to the non-inverting input of the operational amplifier and further connected to the non-inverting terminal of the comparator E. In this way, the threshold voltage U2, which has been stored for a long time via the operational amplifiers, is fed to the comparator K and, due to the connection to the emitter of T1, the capacitor C-B1 is recharged. The diode D2 prevents the output of operational amplifier _: 072 from loading the emitter whose potential is higher than that of the operational amplifier. The base of the second transistor T2 is connected to the output of the input amplifier E1. Also, transistor T2 is connected as an emitter follower. The emitter is located at the non-inverting input of the comparator K and is connected to ground via its emitter resistor ES2. The. Transistor T2 compensates for the shift of the threshold voltage due to the base-emitter voltage of the first transistor for the signal voltage U1. Variant 2 enables very fast receive circuits with high long-term storage of the threshold voltage and the resulting extremely low width distortions of the regenerated pulses »

- 8th

Claims (2)

Invention claim. 1. An optical pulse reception circuit for optical fiber short-range transmission using the arrangement of two input amplifiers connected in parallel, characterized in that the output of the input amplifier (E1) carrying the signal voltage (U1) 'is connected to the output of the second input amplifier (E1). E2), which carries the Signalruhespannung (UB), via a voltage divider (E1; R2) is connected, that, the center tap of the voltage divider (E1, E2) is connected to a peak detector whose output via a holding capacitor to ground and via a Impedance converter used operational amplifier with downstream diode is guided on a Koniparatoreingang at whose second input the signal voltage (ü1) is applied. 2. optical pulse receiving circuit according to item 1, characterized in that as a peak detector, an operational amplifier (0V1) with downstream diode (D) is arranged that the Eatodenanschluß the diode (D) to the non-inverting input of the operational amplifier used as an impedance converter (0Y2) , on the holding capacitor (C) to ground and on the. inverting input of the peak detector (0V1) is guided t. Receiving circuit for optical pulses according to item 1, characterized in that as the peak detector, a transistor (T1) in emitter circuit in series with an operational amplifier (071) with a downstream diode (D1) is arranged, wherein the emitter terminal of the transistor (TI) continues to the inverting Input of the comparator, via a resistor (EE1) and a holding capacitor (0E1) for the temporary storage of the threshold voltage (U2) is grounded, that the cathode terminal of the diode (D1) with the non-inverting input of the connected as an impedance converter operational amplifier (0Y2) with connected diode (D2), via a holding capacitor (G) for the long-term storage with ground and with the inverting input of the first operational amplifier (0Y1) is connected and that the cathode terminal of the second diode (D2) to the inverting input of the comparator and to the inverting input of the second operational amplifier (0V2) is connected. - For this 1 sheet drawings.