DE19748756A1 - Receiver for receiving optical signals from optical communications network - Google Patents

Abstract

The receiver (EMP1) receives signals from a network (NET) for transmitting coded multiplexed optical signals using a device (DEK1) for detecting the signals to be received and a processing device (O/E1, O/E2) for compensation of noise in the signals by combining the detected optical signals with compensation signals. The detection device passes the optical signals to be received and reflects signals which are not to be received. A further device (K1) derives the compensation signal from a part of the reflected optical signals and feeds it to the processing device.

Description

The invention is based on a receiver for spectrally coded optical Signals, as well as a method for the compensation of different Propagation factors in signal branches of a differential amplifier after Genre of independent claims.

Such a receiver is known, for example, from "Proceedings of the Thirteen's Annual Conference on European Fiber Optic Communication and Networks, Brighton, England, 1995, pages 178ff ". It is a recipient for a CDMA system described, which is used to detect the to be received optical signals contains a periodic filter that the detected forwards optical signals to a photodiode, where they are optical / electrical be implemented. In addition, an optical coupler is provided, the one Part of the optical signals transmitted over the CDMA network is coupled out and forwards to another photodiode. The decoupled signals serve as compensation signals after the optical / electrical Implementation initially dampened and then the negative input a differential amplifier are supplied. At the positive entrance of the The electrically converted detected signals become differential amplifiers created. Compensation for interference in the detected signals is by comparing the detected signals with the Compensation signals reached.  

The use of such a push-pull receiver is thereby limited that the optimal suppression of unwanted channels Transit times of the signals from the optical filter to the input of the Differential receiver for both signal arms of the receiver very precisely have to match. Likewise, the level of the interference signals on Receipt of the receiver must be identical. However, small ones It is difficult to avoid differences in terms and levels.

The receiver according to the invention for spectrally coded optical signals according to the features of the main claim has the advantage that the different propagation factors in the signal arms of the Receiver, namely amplitude reduction and delay time of the Signals that can be balanced. For this, the light becomes one LED as a test signal fed into the two signal branches. about Control options in a signal branch are advantageously the different propagation factors of the signal arms adapted and so an optimal suppression of the interference signals at the output of the Differential amplifier reached. For this purpose, the recipient contains one Runtime adjustment and an amplitude adjustment, which over a Control loop effect the coordination of the two signal branches.

By the measures listed in the subclaims advantageous developments and improvements of the main claim specified recipient possible.

It is particularly advantageous to adjust the inputs of the runtime adjustment Amplitude adjustment and the control of the LED with the To connect output of the differential amplifier, and not to detect suppressed portion of the test signal. With perfect adaptation the test signal is thus advantageously completely suppressed and thus the interference signals are also eliminated.

The test signal is modulated with a frequency f ₀ , which is in the range of the useful signal and thus allows an optimal measurement of the differences in the two signal branches. The test signal can also be modulated with a characteristic pattern.

Advantageously, the runtime adjustment and the Amplitude adjustment can be implemented both as electronic components and can also be built optically. It is also an advantage if in one of the two signal branches permanently adjustable compensation means, d. H. a fixed phase shift and a fixed amplitude gain are present, while the other signal branch adjustable adjustment of the spreading factors.

An embodiment of the invention is shown in the drawing and explained in more detail in the following description.

It shows Fig. 1 schematically shows input and output of the differential amplifier, and Fig. 2 shows the structure of a receiver for optical, spectrally encoded signals.

Fig. 1 shows the two input signal paths of the differential amplifier 5. The upper signal branch A contains signal components which consist of the signal U ₀ actually to be detected as well as an interference signal component U _S and the test signal U _e . These signal components undergo a phase delay Φ ₁ in signal branch A with a change in amplitude of amplitude A ₁ . The second signal branch B contains signal components from the interference signal U _S , test signal U _e and a somewhat different signal component δU _{0 of} the signal to be detected. The two signal branches are at the differently polarized inputs of the differential amplifier 5 . The output signal is U _a . The differences in the propagation factors A ₁ and A ₂ as well as Φ ₁ and Φ ₂ should be measured and compensated for using appropriate control loops. The signal obtained from the above mixture of signal components is the output signal:

It is assumed that the additional test signal of the amplitude U _e z. B. is intensity modulated with ω ₀ = 2πf ₀ . U _S denotes the interference signals to be suppressed, U ₀ and δU ₀ the signal to be received. If you only consider the additional test signal, the result is its amplitude

It can be seen from the above-mentioned relationship that the test signal can be eliminated by suitable compensation of the amplitude difference and phase difference. If U _{e is} corrected, the interference signals U _S are also corrected, but not U ₀ and δU ₀ .

FIG. 2 shows the above arrangement in a receiver 1 , which is used for the detection of spectrally coded signals. The signal which is received by the receiver 1 consists of a large number of different spectra which are transmitted by different transmitters onto the transmission link. These spectrally coded individual channels are separated in the receiver 1 .

The incoming signal passes through a coupler 11 , which is connected to a light-emitting diode 6 and its control 7 , realized with an HF current source. The signal passes through an optical isolator 12 and a further coupler 10 , which divides the incoming signal. Furthermore, the incoming signal passes through an optical filter 2 , a photodiode 4 and an amplifier 13 and is connected to the positive input of the differential amplifier 5 . Signal branch A contains no other components. The divided signal component also passes through a photodiode 4 , an amplifier 13 , and in the signal branch B a transit time adjustment 8 and an amplitude adjustment 9 , and is applied to the negative input of the differential amplifier. The output of the differential amplifier 5 delivers the output signal U _a . The output of the differential amplifier 5 is connected to the input of an evaluation circuit 15 , in which the output signal is broken down into an in-phase component I and a quadrature component Q. The I signal passes through a low-pass filter 6 and an integrator 16 of the amplitude adjustment 9 . The signal of the amplitude adjustment 9 controls an adjustable amplifier 10 . The Q signal passes through a low-pass filter 11 , an integrator 12 and serves as a control signal for the phase adjustment 14 . A setting component 3 for the rough phase position is connected to the evaluation circuit 15 and serves to roughly determine the phase position. The evaluation circuit 15 can be implemented as a quadrature demodulator or as an IQ demodulator. It only requires a rough pre-setting of the phase position in order to be able to distinguish between the I and Q components, since the signal to be compensated does not have a fixed phase position.

The fine tuning 17 of the optical filter 2 is also shown .

The incoming optical spectrally coded signal first passes through the coupler 11 , in which the test signal U _{e is} injected. This test signal is generated by a light-emitting diode 6 , which is operated at a frequency f ₀ by the controller 7 (HF current source). The optical signal, which is last extended by the test signal U _e , passes through the optical isolator 12 , which prevents back-reflected signal components from being scattered back into the transmission network. In the second coupler 10 , the signals are separated into two signal branches. In an ideal case, the optical filter 2 should only let the desired signal U ₀ into the signal branch A and suppress all interference. In general, however, it is the case that a large part of the signal U ₀ to be detected is fed into the signal branch A, while a small part δU _{0 is} transmitted into the signal branch B. The interference signal is partially reflected in the optical filter and fed into the signal branch B. Likewise, the test signal U _e . divided into both signal branches. Both signal mixtures in both signal branches are converted into an electrical signal by photodiodes 4 and then amplified via an amplifier unit 13 . The signal in the lower signal branch B now undergoes a runtime adjustment 8 and an amplitude adjustment 9 until it is present at the negative input of the differential amplifier 5 . The transit time and the amplitude of the signal on the lower receiver arm can each be set via a control loop. For this purpose, the detected test signal of the light-emitting diode 6 is measured after the differential amplifier via an evaluation circuit 15 . The signal is set via the rough setting of the phase by the setting unit 3 , the fine adjustment of the phase takes place via the low-pass filter 14 and the integrator 12 . The phase in the signal branch B is influenced by the phase setting 14 . The signal is then amplified in the signal branch B, the degree of amplification being obtained from the I signal, which passes through the low-pass filter 9 and the integrator 16 .

Once the runtime and level have been compared, only the desired signal remains as the output signal of the differential amplifier (A ₁ = A ₂ = A, ϕ ₁ = ϕ ₂ = ϕ):

U _a (t) = Ae ^jϕ . (U ₀ (t) -δU ₀ (t))

As in the exemplary embodiment, the intervention on the transit times and signal levels can also take place optically, as not explained in more detail. It is also possible to provide fixed compensation elements for transit time and amplitude in the upper arm of the receiver. The modulation of the light-emitting diode 6 can be sinusoidal, but any other type of modulation, such as data modulation, is permissible as long as the test signal can be filtered out of the signal mixture.

The fine adjustment 17 of the optical filter 2 enables adjustment to different spectra of the spectrally coded signal. This makes it easy to separate the channels.

Claims (7)

1. Differential receiver for two signal branches (A, B) with a differential amplifier ( 5 ) for detecting the differential signal of the signal branches (A, B), characterized in that it has a light-emitting diode ( 6 ) and a controller for the light-emitting diode ( 7 ) contains, and the light of the light-emitting diode as a test signal (U _e ) is present in both signal branches in addition to the useful signal and is applied to the two inputs of the differential amplifier ( 5 ) and the signal in signal branch B undergoes a runtime adjustment and an amplitude adjustment before being coupled into the differential amplifier . 2. Receiver according to claim 1, characterized in that the inputs of the delay adjustment, the amplitude adjustment and the control ( 7 ) of the light-emitting diode ( 6 ) are connected to the output of the differential amplifier, at which the remaining test signal is detected. 3. Receiver according to one of the preceding claims, characterized in that the light of the light-emitting diode ( 6 ) is modulated with a frequency f ₀ and / or a characteristic pattern. 4. Receiver according to one of the preceding claims, characterized characterized in that the compensation elements runtime adjustment and Amplitude adjustment are constructed optically or electrically. 5. Receiver ( 1 ) according to one of the preceding claims, characterized in that in one of the two signal branches permanently adjustable compensation means and in the other signal branch adjustable compensation means ( 8 , 9 ) are present. 6. Receiver ( 1 ) according to one of the preceding claims, characterized in that the compensation elements contain a quadrature demodulator or IQ demodulator ( 15 ), which is preset by a coarse phase setting ( 3 ). 7. A method for compensating for different propagation factors in the two signal branches (A, B) of a differential receiver, for the detection of optical spectrally coded signals which are separated from one another with the aid of an optical filter ( 2 ), characterized in that the propagation factors in at least a signal branch can be adapted to one another by adapting the transit time of the signal and by adapting the amplitude, the signal strength of a test signal (U _e ) present in both signal arms (A, B) being used as parameters for the adaptation of both signal branches.