SU307527A1 - METHOD FOR DETECTING SITES FOR THE EMERGENCE OF PULSE INTERFERENCE IN COMMUNICATION CHANNELS - Google Patents

Description

The invention relates to the field of telecommunications.

Methods are known for detecting areas of occurrence of impulse noise in communication channels by distorting the frequency characteristics of the channel at reception points with subsequent analysis of the interference spectrum at the terminal station.

A disadvantage of the known methods lies in the fact that additional equipment is turned on in the re-receiving areas, which reduces their economic efficiency and reduces the reliability of the used drip. The accuracy of the known methods depends on the number of points in which the low-pass filters are included and is practically limited to one downstream region. In addition, the known methods do not allow to determine the portions of the occurrence of impulse noise in the channels occupied by the transmission of information.

To improve the accuracy of determining the location of the impulse noise in the proposed method, the frequency selection of the interference is performed in two frequency subbands of the channel selected with different dependences of the residual attenuation on the channel length, while during the operation of the interference the energy accumulated in each of the subchannels is determined the ratio of the energy and, by analyzing the magnitude of the ratio obtained, the distance to the place of occurrence of the interference is determined.

FIG. 1 is a flow chart illustrating the proposed method; in fig. 2 - frequency characteristics of the studied channel of the tone frequency, characteristics of filters and interference spectra at the output and input of filters depending on the frequency characteristics of the channel.

According to the proposed method, the block diagram contains the terminal station of the equipment 1 in the tonal frequency of telephony, the first reception area 2, the intermediate equipment 3 of the high-frequency telco, the second reception area 4, the terminal station of the equipment 5 of the high-frequency telephony, output 6 of the voice frequency channel, low frequency filter 7, bandpass filter 8, analysis unit 9, recording

device 10, amplitude-frequency characteristic // of a tone frequency from intermediate equipment to an equipment terminal station, amplitude-frequency characteristic 12 of a tone frequency channel from a border station of a tone frequency equipment to a terminal station of high-frequency telephony equipment, frequency response 13 of a low-pass filter, frequency response 14 strip to determine the area in which opa occurs. Terminals 7 and 5 of high-frequency telephony, intermediate equipment of high-frequency telephony 3, and relay stations 2 and 4 form a communication channel. A low-pass filter 7 and a band-pass filter 8 are connected to the output 6 of the tone frequency channel. In analysis block 9, the accumulation of the interference energies selected by the filters 7 and 8 is determined. The energy ratio signal enters the recording device 10, where each value of the ratio corresponds to a certain part of the high-frequency telephone line. The impulse noise in the channel of the tonal frequency has a uniform amplitude spectrum (Fig. 2, curve 15). The appearance of the frequency characteristics depends on the number of perepem on the lower frequencies, and the residual attenuation of the channel on the lower and upper frequencies varies significantly, and the change of pro .-., .... j.,. ..J .... is proportional to the number of receiverships (channel filters of high-frequency telephony equipment). When the number of plots in the middle of the frequency range changes, the residual attenuation of the channel remains almost unchanged. If the output of channel 6 of the tone frequency includes a band-pass filter 8 and a low-pass filter 7, then the frequency response of the sub-channel formed by the low-pass filter has a pronounced dependence on the number of reception areas (Fig. 2, curves 11-13 and 12-13}, then as a frequency characteristic of a subchannel formed by a bandpass filter, it has no such dependence (Fig. 2, curve 14). The interference energy at the output of the low-pass filter depends on the number of re-use sections, and therefore, the ratio of the interference energy at the outputs of the lower filters is often The t 7 and the band pass filter 8 are also determined by the number of transference plots.The measurement of the interference energy ratio (amplitudes) is performed in the analysis unit 9. The analysis results are recorded in the recording device W. To determine the area of occurrence of impulse interference with an accuracy of one transceiver section the signals induced by this interference in both subchannels or, since there is a proportional relationship between the interference energy and its amplitude, and the ratio of the amplitudes th transmission speed, the working width and type of spectrum modulation in parallel channel filters are included, the selected portions of the spectrum in which the signal energni insignificant. For example, with a transmission rate of 1200 baud, the signal energy in the frequency range up to 600-700 Hz and above 3000 Hz is insignificant, and in these parts of the spectrum monitoring of impulse noise and determination of their origin can be organized. This method can be applied not only to determine the areas of occurrence of impulse noise in the tone frequency channels, but also to determine the areas in the group and linear paths. Object of the Invention A method for detecting areas of occurrence of impulse noise in communication channels occupied by the transmission of discrete information, characterized in that, in order to improve the accuracy of determining the location of the occurrence of impulse interference, frequency selection of interference is performed in two frequency subbands of the channel, chosen in such a way that they had different dependences of the residual attenuation on the channel length; during the duration of the interference, an accumulation of energy that falls into each of the subchannels is made, the energy ratio is determined and, by analyzing the value of the received ratio, the distance to the place of occurrence of the interference is determined.