SU1279075A1 - Analyzer of conditions of communication channel - Google Patents

Abstract

The invention relates to telecommunications. The purpose of the invention is to increase the accuracy of analysis of the state of the communication channel. The analyzer contains two forms, a pulse shifter (PI) 1 and 2, a shift register 3, three triggers 4, 10 and 11, a reversible counter 5, two decoders (LH) 6 and 7, and two elements AND 8 and 9. Channel condition analysis The communication is carried out upon receipt of an input signal consisting of alternating sequences of information. parcels and noise pulses. In this section of information. The assignment corresponds to the state. The channel is occupied, and the portion of noise pulses corresponds to the state. The channel is free. The goal is achieved by the introduction of FI 2, LH 6 and 7, and elements 8 and 9, with the help of which the initial installation pulses are processed and the sections are revealed. The channel is free and the channel is closed. 2 Il. WITH

Description

112 The invention relates to telecommunications and can be used in systems for automatic processing of digital messages to determine the boundaries between the useful information and noise. The purpose of the invention is to improve the accuracy of the analysis of the state of the communication channel. Figure 1 shows a structural electrical circuit of the communication network analyzer; figure 2 - timing charts of his work. The link state analyzer contains drivers 1 and 2 pulses, shift register 3, first trigger 4, reversible counter 5, decoders 6 and 7, elements-8 and 9, second trigger 10 and third trigger 11. zi works as follows. Before starting, the device is set to the initial field (the corresponding condition for the Channel is free. At this, the triggers 10 and 11 are set to 1, the reversible counter 5 is set to 01 11, and the code corresponding to the Channel section is written to the shift register 3 free (for example, 100100 ...). Chain start) o installation is not shown. Let the 7shift of the 3 shift register and the first input of the shaper receive the input signal (Fig. 2a), consisting of alternating sequences of information parcels and noise pulses. The information parcel section corresponds to the state. The channel is occupied and is a sequence of alternating signs, located at quite definite places, spaced apart from each other by a period that is a multiple of the transmission rate period. The portion of the noise pulses corresponds to the state. The channel is free and is a sequence of randomly located signs of change O-1, 1. The second inputs of the formers 1 and 2 (Fig. 2) receive a strobe signal located in the central zone of the elementary parcel and produced by the trigger 4 using SI synchromes 1 and 2, which are synchronized and follow the frequency transmitted in the Dean information channel (Fig. 2 6) is ahead, and the other (fig.2g) is delayed relative to the .adal values of the differential of the basic parcels by the value of / K, where the duration of the elementary parcel, and K depends on the channel in z. Thus, when transmitting the information sequence, the transitions O-1, 1 do not fall into the central zone of the premise and therefore there are no signals at the output of the driver 1 (Fig. 23). At the same time, from the removal of the register 3 of the motor to the first input of the imaging unit 2 (Fig. 2e), the initial installation pulses come in, the corresponding state of the Channel is free and located both outside and inside the central parcel zone. In the shaper 2, of all the pulses that hit the central zone, there is one first that is synchronized with the SI sync pulses 2. The generated signal from the first output of the shaper 2 (FIG. 2g :) goes to the subtracting input of the reversing counter 5, polls the decoder 7 and through element 10 opened from trigger 10 and confirms state 1 of trigger 11. In the same way, from the first output of shaper 2 (FIG. 2xc) all subsequent signals coming from shift register 3 are output, and the state of reversing counter 5 decreases each time mc per 1 At a certain point in time the signal from the first output of the imager. 2 (Fig. 2ls) passes through the decoder 7 and sets in O a trigger 10 (Fig. 2p, which indicates the termination of the signals Ouch, the channel is free on register tap 3. The trace of the EE package belongs to the section The channel is occupied, therefore in the central zone of the elementary There are no transitions. In this case, the sync pulse SI 2 (FIG. 2d) in Former 2 generates a signal that from the second input (FIG. 2i) through element 9, opened from the trigger 10, sets the trigger 11 to O (FIG. . 2t), at the moment of switching which from the output / yes of register 3 enters the first pos Channel sections are occupied at the same time. Pulses of the noise section begin to enter the shift register 3 and the first input of shaper 1. They fall both on the edges and in the central sending zone, in shaper t. of all pulses One first is allocated to the central zone, which is synchronized by the SI frequency 2. The signals from the generator 1 (Fig. 23) are fed to the summing input of the reversible counter 5 and interrogate the decoder 6, which is triggered by a certain state of the reversible counter 5. trigger 10 mustache tanted to 1 (fig. 2) that corresponds to the detection of the site The channel is free.

Further, the device works in the same way as in the processing of the pulses of the initial setup from the output of the shift register 3.

The volume of the reversible counter 5, the shift register 3 (the analysis base) and the deciphering decoder 6 and 7 are selected depending on the permissible probabilities of false detection or failure. The channel is free and the channel is occupied.

Claims (1)

Invention Formula The link state analyzer contains the first, second and third triggers, the first pulse generator, the shift register and the reversible counter, the first and second inputs of the first trigger being sync pulses, in order to improve the accuracy of the channel state analysis connection, introduced two elements And, the first and second decoders and the second pulse shaper, the output of the first trigger is connected to the first input of the first pulse shaper, the second input of which is combined with the input of the shift register ha, is the input of the link state analyzer, and the output is connected to the summing input of the reversible counter and the input of the first decoder, the output of which is connected to the first input of the second trigger, another input connected to the output of the second decoder, and the first and second outputs are connected to the first inputs of the first and second elements, respectively, whose outputs are connected to the corresponding inputs of the third trigger, the output of which is the signal output of the link state analyzer, reject the shift register The output of which is the information output of the link state analyzer is connected to the first input of the second pulse shaper, the first output of which is connected to the second input of the first element AND, the subtracting input of the reversing counter and the first input of the second decoder, and the second output is connected to the second to the input of the second element And, the output of the reversible counter is connected to the second inputs of the first and second decoders, the output of the first trigger is connected to the second input of the second driver, the third input of which connects ene with a second input of the first flip-flop and the third -Log first shaper. . riTL.jnL-.ji janfn Ijl. .JL. ". 2 Uj.J ".JL .. JLJljI L .. JtJL.IL..jJL .. UlMML-JlML JJllL JlIliL JL.A. JL.-J. Length L {Ania Delay JL, .JL, .. ... JU ... JL..JL .... JL. 0w3.2 l- ™. jn.