DE3525172C2 - - Google Patents

Description

The invention relates to a circuit arrangement for Generation of a signal quality from one Frequency-modulated signal received by the receiver, especially a frequency-modulated AC tele grafiesignals, representative quality assessment si gnals, which has an amplitude demodulator circuit, the frequency-modulated receiver signal at its input is present.

In DE 29 29 679 A1 an FM receiver with a automatic noise blanking described. With this one an AM demodulator connected to the IF part via a Bandpass connected to a rectifier stage, which at Presence of multipath reception produces an output signal. This gets to a threshold-dependent electro African switch, which with a multipath reception the automatic noise blanking switches ineffective, whereby the reception signal which is already distorted by multipath reception gnal is not additionally distorted by blanking gaps. With a multi-way reception with this FM receiver Distortion is not eliminated, which causes this to be full to step.

DE 28 27 572 B1 describes an arrangement for shrinkage elimination of polarization interference as well known from interference due to reflection.

DE 25 37 190 A1 describes a circuit for monitoring of the carrier in the intermediate frequency level of frequency modulated directional radios described, part the intermediate frequency is coupled out and almost two branches of the same structure are divided.

The object of the invention is from a signal of Receiver to derive an evaluation signal so that the Amplitude of this frequency-modulated receiver signal as  Criterion for the quality of the received signal is evaluated.

The object is achieved by an as Output signal delivering the quality evaluation signal Comparator circuit with one of its inputs on the Output of the amplitude modulator circuit connected and at which there is a further input Reference voltage is present.

In this way, a in the comparator circuit digital quality assessment signal are generated, once the amplitude of the input to the amplitudes demodulator circuit a signal through the Reference voltage predeterminable lower limit below and therefore the input signal of the receiver as is to be assessed disrupted. About this evaluation signal can e.g. B. automatically on a replacement transmission path can be switched or it can be a less disturbing sensitive transmission method can be chosen, such as e.g. B. by reducing the transmission speed.

Between the threshold-dependent electronic scarf ter in DE 29 29 679 A1 and the comparator circuit there is no connection because of the exit the amplitude demodulator circuit directly with the compa rator circuit is connected and further the output this comparator circuit emits a signal with shares that the amplitude of the received signal for an evaluation is too small.

A particularly advantageous form of training from the inventor Invention circuit arrangement is that the Input of the amplitude demodulator circuit with the Output of a filter circuit is connected.  

With noisy input signals from the receiver due to the noise voltage the presence of an unsung interfered with the received signal as soon as that Noise signal has sufficiently high amplitude values. Becomes the input of the amplitude modulator circuit with a Receiver signal already through a receiver channel filter is limited, is applied in the Amplitude demodulator circuit only the band limited Noise signal demodulated. Because noise signals in general are very broadband, the amplitude of the bandbe limited noise signals only at extremely high noise levels plitudes larger than the reference value of the comparator circuit. There is therefore no pretense disturbed input signals due to noise signals with large Amplitude.

Another advantageous embodiment of the Invention according circuit arrangement is that the Reference voltage input of the comparator circuit via a circuit for generating an average union value of the output signal of the amplitude demodula gate circuit proportional signal, such as. B. over a Averager, a low-pass filter circuit or the like, to the output of the amplitude demodulator circuit is closed.

Doing so is below an average value output signal of the amplitude modulator circuit Understand the amplitude of the undisturbed signal, d. H. without noise signals superimposed or amplitude drop che are available. When there is an undisturbed transmission this is a constant value (corresponding to the amplitude), of which a certain percentage (e.g. 10%) as a reference value and thus as the lower bound of the Amplitude for a response of the comparator circuit is used. In the event of brief reception disturbances, such as B. drops in amplitude or noise  the output signal of the amplitude demodulator circuit Follow instantaneous amplitudes quickly, taking the reference value remains approximately constant. This makes it special short-term reception interference preferably recognized. At slow changes in amplitude, such as. B. for longer constant changes in the transmission channel (caused e.g. B. by aging-related deterioration of Transmission properties), the reference value itself actively tracks the mean amplitude of the signal.

Another embodiment of the invention Circuit arrangement is in connection with receivers, which are equipped with adjustable amplifiers, characterized in that the input of the amplitudes demodulator circuit to the output of the controllable Amplifier is guided, and that, if necessary, over a control amplifier, to the control input of the regulba ren amplifier the output of a comparison circuit is connected, at which at a first input the output signal of the amplitude demodulator circuit and a reference voltage is present at a second input.

Such receiver circuits contain an amplitude the control loop for controlling the amplitude of the Fre signal supplied by the frequency demodulation circuit. Through the Using the amplitude demodulator circuit and the Reference voltage source for both the amplitude rule circuit as well as for the circuit arrangement for generation an evaluation signal for the signal quality results a simple realization of such receivers circuits.

It is particularly advantageous if the output si Signal of the amplitude control loop for the evaluation of the Signal quality is used. The reference voltage the comparator circuit is in turn one percentage of the reference voltage for the  Comparison circuit that the setpoint for the amplitudes control loop of the receiver.

The comparator responds when the amplitude of the receiver signal falls below the minimum value specified by the reference voltage U _R ; This means that the receiver amplitude control loop can no longer correct the signal fluctuations at the input of the receiver and therefore other measures for improving the receiver signal can be initiated via the evaluation signal.

The amplitude demodulator circuit can also be two qua three circuits and a sum connected after them Have lubrication circuit. This is especially true then partial if two signal processing ka in the receiver channels are available whose signals can only be Differentiate phase shift of 90 °. It is by squaring the two signals and trailing Summation of the two squares directly one of the amplitude DC voltage proportional to the input voltage testifies. This circuit therefore compares to the commonly used envelope rectifier circuits for amplitude demodulation through a particularly inexpensive Time behavior.

The invention with reference to the drawing for example. It shows

Figure 1 shows the block diagram of an interconnection of an AC telegraphy device with an inventive circuit arrangement for generating an evaluation signal for the signal quality of the received signal.

Figure 2 shows the vector diagram of a frequency-modulated sine wave, as it is used in such transmission systems ver.

FIG. 3 shows the time course of such a signal;

Figure 4 is a circuit arrangement with a low pass filter circuit for generating the reference value.

5 shows a circuit arrangement according to the invention with a receiver circuit with an amplitude control loop.

FIG. 6 shows an implementation of a circuit according to FIG. 5, which is economical in particular with regard to component expenditure, the amplitude demodulator circuit and the reference voltage source for the amplitude control loop and the circuit for generating the evaluation signal being implemented together, and

Fig. 7 shows a particularly advantageous implementation of an amplitude demodulator circuit of the circuit arrangement according to the invention for generating the evaluation signal in receivers, in which the received signal and a similar 90 ° phase shifted signal are simultaneously available.

Fig. 1 shows the block diagram of an AC telegraphy device consisting of the AC telegraph transmitter 1 and the AC telegraph receiver 2 , which are connected via a transmission line. Since there are generally several AC telephony graphics connections in frequency division multiplexing on the same transmission line, the AC telegraph receiver comprises a filter circuit 6 . A frequency-modulated signal U _DE is available at the output of the filter circuit 6 . In the case of frequency shift keying, this signal can be represented according to FIG. 2 by a vector with the amplitude A, which rotates at the angular velocity ω _K ± ω _H. Fig. 3 shows the representation of this signal U _DE in the time domain as a sine wave, in which the period corresponds to the digital signal just transmitted

is.

Due to the influence of interference on the transmission line, the amplitude A of the signal U _{DE can} be reduced so that the receiver 2 is no longer able to process the signal U _DE correctly.

The circuit according to the invention ensures that in the event that the vector length A falls below the value U _R , a signal quality evaluation signal (SQ signal) is emitted to the AC telegraph receiver. This signal tells the AC telegraph system that the signal received at that time is e.g. B. must not be evaluated or that it must be switched from an existing transmission path to another transmission path.

This signal, which is important for the operational safety of an AC telegraphy system, is generated by amplitude-demodulating the frequency-modulated received signal and comparing it with a suitable reference amplitude. Accordingly, the circuit for generating the signal quality evaluation signal comprises an amplitude demodulator circuit 3 , the input of which is connected to an output of the receiver circuit 6 and at whose output a signal U _{DA can be} tapped, which represents a measure of the amplitude of the AC telegram signal U _DE .

This signal is present at one input of a comparator circuit 5 , at the second input of which a reference voltage U _{R is present} as the output signal of a reference voltage source 4 . At the output of the comparator 5 , the signal quality evaluation signal SQ can be tapped.

FIG. 4 shows a further development of the invention a circuit for generating the signal quality evaluation signal. An amplitude demodulator circuit 3 is connected with its input to the output of the filter circuit 6 of an AC telegraph receiver 2 . The output signal of the amplitude demodulator circuit 3 is present directly at a first input of a comparator circuit 5 and at the input of a low-pass filter circuit 7 , the output of which is connected to the second input of the comparator circuit 5 . At the output of the comparator circuit 5, the signal quality evaluation signal SQ can be tapped.

In this circuit arrangement, the reference amplitude U _R , with which the signal amplitude is compared in the comparator circuit 5 , is derived from the signal amplitude itself by low-pass filtering. If the cut-off frequency of the low-pass filter circuit 7 is chosen so low that the breakdowns which usually occur in AC telegraphy devices due to transmission interference in the transmission line no longer occur in the output signal U _{R of} the low-pass filter circuit, these short-term interferences are particularly well recognized without slow changes in the transmission behavior of the transmission line affect the generation of the SQ signal.

FIG. 5 shows the interconnection of a circuit arrangement according to the invention for generating a signal quality signal with a Wechselstromtelegrafieempfängerschaltung 2, which has a controlled amplifier 8.

The control circuit of the AC telegraph receiver 2 includes the regulated amplifier 8 , a demodulator circuit 9 for obtaining the amplitude of the receiver signal as a control variable, a reference voltage source 10 as a setpoint device and a comparator circuit 11th The circuit for obtaining the SQ signal consists, according to FIG. 1, of the amplitude demodulator circuit 3 , the reference voltage source 4 and the comparator circuit 5 .

Fig. 6 shows a development of the invention corresponding to FIG. 5, which consists in arranging the function elements occurring twice in the circuit of FIG. 5, reference voltage source 10 and 4 and demodulator circuit 9 and 3 , respectively, so that with only one reference voltage source 4 or one demodulator circuit 3 is found to be sufficient. This is achieved in that the demodulator circuit 3 is included in the control circuit of the AC telegraph receiver.

At the output of the amplitude demodulator circuit 3 , the input of which is led to the output of the controlled amplifier 8 , a signal U _{DA can be} tapped, the size of which is proportional to the amplitude of the receiver signal. The reference voltage source 4 serves simultaneously as a reference voltage for obtaining the SQ signal by the comparator 5 and as a setpoint for the setpoint-actual value comparator V _E ( 12 ), in which the control deviation is formed as a manipulated variable and is fed to the controlled amplifier 8 as a gain control signal .

Fig. 7 shows a detailed block diagram of an amplitude control circuit and circuit for generating a signal quality evaluation signal corresponding to Fig. 6 in an AC telegraph receiver circuit which has two signal processing channels arranged in parallel, each comprising a controlled amplifier and the output signals U _B1 '' and U _B2 '' The controlled amplifier are orthogonal harmonic signals of the same amplitude (e.g. sine and cosine vibrations of the same frequency and amplitude). Details of this receiver circuit are not shown since they are not essential to the invention. The inputs of two squaring circuits 15 and 16 are connected to the outputs of the regulated amplifiers and thus carry the signals U _B1 '' and U _B2 ''. The squares of the respective input signals are formed in the squaring circuits and added in a summing circuit 17 , the two inputs of which are connected to the outputs of the two squaring circuits. The output signal of the summing circuit 17 is a measure of the square of the amplitude of the input signal U _{EE of} the receiver circuit and represents the actual value of the controlled variable.

The actual value is summed in a further summing circuit 18 with a target value, which appears as an output signal from a reference source 19 , and is fed to the integrator 21 as a control difference. The output signal U _{R of} the integrator forms the manipulated variable for the controlled amplifier, via which the amplitude control loop is closed.

Through this control loop, the amplitude of the voltage U _B1 '' and U _B2 '' is kept constant regardless of the amplitude of the input voltage U _EE .

The sum output signal of the summing circuit 17 is in a comparator 20 with a reference voltage, for. B. a voltage derived from the reference voltage of the reference voltage source 19 , compared. If the sum signal proportional to the square of the amplitude of the input signal falls below the minimum value specified by the reference voltage, an error message is output by the comparator 20 at the output SQ via the signal quality evaluation signal. This error message can e.g. B. evaluated by an external monitoring circuit or displayed optically or acoustically.

Claims (4)

1.Circuit arrangement for generating a quality evaluation signal which represents the signal quality of a frequency-modulated signal received by a receiver, in particular a frequency-modulated AC telegraphy signal and which has an amplitude demodulator circuit at the input of which the frequency-modulated receiver signal is present, characterized in that an output signal which supplies the quality evaluation signal (SQ) Comparator circuit ( 5 ) is provided which is connected with one of its inputs to the output of the amplitude demodulator circuit ( 3 ) and in which a reference voltage (U _R ) is present at a further input. 2. Circuit arrangement according to claim 1, characterized in that the input of the amplitude demodulator circuit ( 3 ) is connected to the output of a filter circuit ( 6 ). 3. Circuit arrangement according to claim 1 or 2, characterized in that the reference voltage input of the comparator circuit ( 5 ) via a circuit ( 7 ) for generating an average value of the output signal (U _DA ) of the amplitude demodulator circuit proportional signal, such as. B. via an averager, a low-pass filter circuit or the like., Is connected to the output of the amplitude demodulator circuit ( 3 ). 4. Circuit arrangement according to claim 1 or 3, in which the receiver has at least one controllable amplifier, characterized in that the input of the amplitude demodulator circuit ( 3 ) is guided to the output of the controllable amplifier ( 8 ), and that, optionally via a control amplifier, the output of a comparison circuit ( 12; 18 ) is connected to the control input of the controllable amplifier ( 8 ), in which the output signal (U _DA ) of the amplitude demodulator circuit ( 3 ) is present at a first input and a reference voltage is present at a second input ( Fig. 6 ; Fig. 7).