SU1177934A1 - Device for simulating arrival curve distortions of telegraph signals - Google Patents

Abstract

A DEVICE FOR SIMULATION OF EDGE TEXTING OF TELEGRAPH SIGNALS containing the driver of significant moments of telegraph signals, the first output of which is connected to the input “Installation of the first RS-flip-flop, the output of which is connected to the first input of the frequency divider with a variable division factor, the second input of which is connected to the output of the generator of the chimeters, the second input of which is connected to the output of the chromogen generator, the second input of the frequency generator, which is connected to the output of the generator of the frequency divider and the output is with the counting input of the first counter, the second counter, the second RS flip-flop, the first AND element and the OR element, characterized in that, in order to increase the accuracy of simulation In order to ensure the random nature of the distortions, two AND elements, two RS flip-flops, a D-flip-flop and a pseudo-random sequence sensor, whose input is connected to the second output of the significant moments of the telephony g, graphical signals, and the output to the " Installing the second RS flip-flop and the input “Reset the fourth RS flip-flop, input“ The installation of which is connected to the output of the second element AND, the first input of the OR element and the input “Reset the third RS-flip-flop, input“ Setting which is connected to the output of the first element AND, sec m input element OR input "Reset the second RS-flip-flop, the output of which is connected to the first input of the first element And, while the output of the third RS-flip-flop is connected to the first input of the second element And the output of the fourth RS-flip-flop to the first input of the third element And The second input is connected to the first output of the second counter, the counting input of which is connected to the first output of the first counter, the second outputs of the first and second counters are connected (L respectively to the second and third inputs of the first element And, the third outputs of the first and The second counter, respectively, with the second and third inputs of the second element And, and the output of the third element And with the third input of the OR element, the output of which is connected to the installation inputs of the first and second counters, the input "C6pocj of the first RS-flip-flop and C-input of the D-flip-flop, The D-input of which is connected to the input of the driver of the significant moments of the telegraph signals. from 4

Description

The invention relates to telecommunications and can be used as an integral part of sensors, telegraph signals simulating edge distortion in a real communication channel.

The purpose of the invention is to improve the accuracy of imitation by ensuring the random nature of the distortion.

FIG. Figure 1 shows the structural electrical circuit of the device for simulating the edge distortion of telegraph signals; in fig. 2 - timing diagrams explaining the principle of operation of the device.

The device contains a generator of 1 clock pulses, a divider 2 frequencies with a variable division factor, the first counter 3, the first element AND 4, the first RS flip-flop 5, the second counter 6, the second element And 7, the element OR 8, the third element And 9, the second 10 , third 11, fourth 12 RS-triggers, pseudo-random sequence sensor 13, shaper of 14 significant moments of telegraph signals, D-flip-flop 15.

The clock pulse generator 1 is designed to generate pulses whose frequency is many times higher than the wiring speed VT.

Divider 2 frequency with a variable division factor is designed to reduce the frequency of clock pulses. The division factor of the frequency divider can vary depending on the set speed of work in the communication channel and is set so that the pulses at the output of the divider repeat with a period of 0.01Te,

where ge, is the duration of an elementary link; Vp is the speed of wiring.

The first counter 3 is designed to count the pulses coming from the output of the splitter 2 frequency. When pulses with period 0 arrive at its input, pulses are formed at its output, the duration of which is a multiple of 0.01 fa.

The second counter 6 is designed to count the pulses coming from the decimal output of the first counter 3. At the outputs of the second counter 6, pulses are formed, the duration of which is a multiple of 0.1 (Sa. The third output of counter 6 produces pulses whose delay relative to the input signals is 0, .

The pseudo-random sequence sensor 13 is designed to generate pulses that determine the appearance at the output of a device of edge distortion of the dominant type in accordance with a pseudo-random normal distribution law.

D-flip-flop 15 is designed to form the output telegraph parcels whose duration and fronts have changed

regarding input parcels under the influence of distortion.

The device works as follows.

In the initial state, at the outputs of the first 5, second 10 and third 11 RS-flip-flops, the logical level "O" is held, and at the output of the fourth 12 RS-flip-flop level is maintained at the logical level "1.

The probability of occurrence of a single signal at the output of the sensor 13 pseudo-random sequence is about 50%.

In the absence of a single signal at the output of the sensor 13, a telegraphic parcel is formed at the output of the device, delayed relative to the input one by 0.

FIG. 2 shows a diagram of the formation of the output telegraph message in the absence of a single pulse at the output of the sensor 13 and if present.

The input signal in the form of a binary sequence (Fig. 2a) is fed to the D input of the D-flip-flop 15 and to the input of the driver 14 significant moments, the first output of which produces short pulses coinciding with each front of the input burst (Fig. 26), and the second - coinciding only with the positive front of the input package (Fig. 2c).

The impulse formed on the leading edge of the telegraph parcel from the second output of the imaging unit 14 goes to the sensor 13, and from the first output to the first RS flip-flop 5.

Consider the case when the output of the sensor 13 no single impulse.

The output of the first RS flip-flop 5 sets the logical level "I (Fig. 2d), which enables the divider 2 to work, the second input of which receives the clock pulses from the generator 1. The divider 2 starts working, and from its output

a frequency that is a multiple of 0, goes to the counting input of the first counter 3 (Fig. 2e). Every tenth pulse from its third output goes to the counting input of the second counter 6 (Fig. 2e). The corresponding outputs of the counter 3 and 6 are connected to the inputs

the first element And 4 and with the inputs of the second element And 7. Such a connection makes it possible to install at the inputs of the elements And 4 and 7 any numerical combination from O to 99. The numerical combination is selected depending on the specified coefficient of edge distortion.

Upon receipt from the output of the divider 2 pulses with a period t 0.01Ue3OHa of the distortion of the fronts of the telegraph parcels entering the device, it is established

from O to 99%.

The impulse from the first output of the counter 6, delayed by 0.5 Relative to the leading edge of the input parcel (Fig. 2g), through the third element AND 9 (Fig. 2o) and the element OR 8 (Fig. 2p) is fed to the C-input of the D-trigger 15 and the inputs "Installation of counters 3, 6 and input" Reset RS-flip-flop 5. At the output of D-flip-flop 15, the logical level "1 forming the leading edge of the telegraph parcel at the device output is set, counters 3 and 6 are set to zero state level, and the output of the first RS-flip-flop 5 sets the logical level "O, prohibiting the operation of 2 numerator.

When a trailing telegraphic parcel arrives at the input of the device, the pulse from the first output of shaper 14 (Fig. 26) again sets the logical 1 1 level at the output of the first RS-flip-flop 5, which enables the divider 2, the pulses from which go to counters 3 and 6 , impulse from the first output of counter 6, delayed by 0.5Te; through the third element AND 9 and the element OR 8 enters the C-input of the D-flip-flop 15, at the output of which the trailing edge of the telegraph parcel is formed, which further goes to the output of the device.

Thus, in those cases when there is no single impulse at the output of the pseudo-random sequence sensor 13, an undistorted message is formed at the device output shifted relative to the input by 0.5Te.

Consider the case when upon receipt of the leading edge of a telegraphic package, at the output of the sensor 13 of a pseudo-random sequence, a single pulse will occur.

Under the action of a pulse from the first output of the imager 14, the first RS flip-flop 5, divider 2 and counters 3 and 6 are similarly triggered.

Under the action of a pulse from the second output of the shaper 14, a pulse appears at the output of the pseudo-random sequence sensor 13 (Fig. 2h), which sets the logical level "1, at the output of the second RS flip-flop 10 and the logic level O at the output of the fourth RS flip-flop 12 As a result, signals are allowed to pass from the second outputs of the first and second counters 3 and 6 through the first element 4 and prohibit the passage of pulses delayed 0.5T9 from the first output of the counter 6 through the third element 9.

The numerical combination from the second exit, :: counters 3 to 6, through the elements 11 4 (fig. And OR 8 (fig. 2ii) enters i; gh-, r of D-flip-flop 15, at the output of KOTOpcic ivi- :. Lip) the leading front of the telegraph parcel is formed, shifted in time relative to the input telegraph parcel nl insr shaft, corresponding to the numerical combination of the second outputs of the counters 3 n (i.

The signal from the output of the element OR is also supplied to the input "Reset the first RS trigger 4, set at its output the logical level" O, and the inputs "Install counters 3 and b, which are also set to zero.

5 The signal from the output of the first element And 4 is also fed to the input "Resetting the second RS-flip-flop 10 and to the input" Installing the third RS-flip-flop 11, setting them to the initial position (Fig. 2i, k).

Thus, the time of appearance of the front of the distorted telegraph parcel at the device output is determined by the presence at the input of the first element AND 4 of a numerical combination from the second outputs of counters 3 and 6 and a logic level "1 from the output of the second RS flip-flop 10, which is formed upon receipt to its installation input of a single pulse from the output of the sensor 13 of a pseudo-random sequence according to a random normal distribution law.

0 When the trailing edge of the considered telegraph parcel arrives, the pulse from the first output of the driver 14 allows the first RS-trigger 5, divider 2, counters .3 and 6 to work, as described above. The logical level "About the output of the second

 RS-flip-flop 10 prohibits the passage of signals through the first element I 4, and from the output of the fourth RS-flip-flop 12 - through the third element AND 9. The logic level "1 from the output of the third RS-flip-flop 11 prevents the passage of signals through the second element I 7, to which comes a numerical combination from the three outputs of the counters 3 and 6. From the output of the second element And 7 (Fig. 2n), the signal goes through the element OR 8 to the C input of the D-flip-flop 15, the output of which

 the rear front of the distorted telegraph package (Fig. 2p) is formed, and at the inputs of the first RS flip-flop 5 and counters 3 and 6, they are reset to their initial position, as well as at the inputs of the "Installation of the fourth RS flip-flop 12 and" Reset of the third RS -trigger 11, setting them to their original position (Fig. 2n, k).

Claims (1)

A DEVICE FOR SIMULATING TELEGRAPHIC SIGNALS EDGE BARS, containing a telegraph signal significant moment generator, the first output of which is connected to the “Installation” input of the first RS-trigger, the output of which is connected to the first input of the frequency divider with a variable division factor, the second input of which is connected to the output of the generator pulses, and the output is with the counting input of the first counter, the second counter, the second RS-trigger, the first AND element and the OR element, characterized in that, in order to increase the accuracy of the simulation by To ensure the random nature of distortion, two AND elements, two RS-flip-flops, a D-flip-flop and a pseudo-random sequence sensor are introduced into it, the input of which is connected to the second output of the signal generator of significant telegraph signals, and the output is connected to the “Installation” input of the second RS- the trigger and the “Reset” input of the fourth RS-trigger, the “Installation” input of which is connected to the output of the second AND element, the first input of the OR element and the “Reset” input of the third RS-trigger, the “Setup” input of which is connected to the output of the first AND element, the second input e OR gate and the “Reset” input of the second RS-trigger, the output of which is connected to the first input of the first And element, while the output of the third RS-trigger is connected to the first input of the second And element, the output of the fourth RS-trigger - with the first input of the third And element, a second input coupled to the first output of the second counter, the counting input of which is connected to _a per- vym output of the first counter, the second passages ® You are a first and second counters are connected respectively to second and third inputs of the first aND gate, the third outputs of the first and second ELAPSED kV respectively with the second and third inputs of the second AND element, and the output of the third AND element with the third input of the OR element, the output of which is connected to the installation inputs of the first and second counters, with the input "Reset the first RS-trigger and C-input of the D-trigger, D - the input of which is connected to the input of the shaper of significant moments of telegraph signals. SU ,,,, 1177934