SU1023670A1 - Method of switching channels in synchronous communication systems with time-division multiplexing - Google Patents

Abstract

METHOD OF SWITCHING CHANNELS IN SYNCHRONOUS COMMUNICATION SYSTEM WITH TIME ZSHLOTNENISCH, comprising the steps of which comprises the reception signals, storing the signals at a predetermined time during a connection by heteronymic channels and transmitting signals over channels required directions, in accordance with the control signals, characterized in that, in order to reduce the switching time, the received signals are temporarily shifted and stored for a while

Description

The invention relates to switching technology in communication systems with time channel multiplexing and can be used in pulsed transient nodes for switching both discrete and analog information presented in digital form. A known method of switching a channel in synchronous communication systems with time compaction consists in receiving signals, remembering signals for a specified time when establishing a connection on different channels and transmitting signals through channels of required research institutes in accordance with control signals. DQ U. t However, under conditions of high channel utilization, the presence of a direction with a small number of compacted lines (for example, with one line), and also under the condition of using compacted lines with a large number of times The time-divided channels drastically increase the percentage of connections required for storing signals, as under these conditions there is a low probability of connecting through channels with the same numbers. The signal storage time (for the forward and reverse directions) when using the known method is equal to C channel intervals, where C is the number of channels in compacted lines. An increase in the percentage of connections requiring signal storage leads to an increase in the storage capacity of the clip equipment. This is the main disadvantage of this method. The purpose of the invention is to reduce the switching time by reducing the average signal storage time. The goal is achieved by the method of switching channels in synchronous communication systems with time multiplexing, which consists in receiving signals by storing signals for a given time. interconnecting channels and transmitting signals over the Tpe6yeNSJx direction channels in accordance with the control signals, carry out the time and amp; gs of the received signals followed by their wounding on BpeiviH (2t + s) with the difference in the numbers of the channels of the forward and reverse directions, greater than w or 2tn at the difference, not exceeding yi, and the time shift of the received signals is determined by the ratio lgsa va iven / 01 where m - the number of timeslots by which the shift is made V - the average number of condensed lines in the direction} C is the number of channels in the sealing lines; O is the value of the average use of the channels; . p is the value of losses,. Figure 1 is a diagram explaining the switching method; Fig. 2 is a block diagram of the switching equipment, an example. A switching method is a set of operations for receiving signals of the channels to be switched, storing them at any. the difference in the number of channels used in a certain time, the value of which depends on the difference in the numbers of the channels of the forward and reverse directions, and if the indicated difference is not less than or equal to hi, then the storage time is 2 times channel intervals, and if the difference is greater than m, and the storage time is assumed to be 2hi + c ,. where About hn with / 2 and the subsequent transmission of signals through the channels of the required directions. The value of W can be predefined or determined analytically in accordance with relation (1). The value m can also be obtained by simulating on the computer the operation of switching equipment by the proposed method. The value of m can remain constant for the entire time SKcnnya tatsii equipment switching, using this method, and can be changed (both manually and automatically) when measuring the number of Y condensed lines in the direction and the value d of the average use of channels in compacted lines x ..; In Fig. 1, the numbers 1,2, ..., 32 denote the channel numbers in the compressed signals, measured along the reception time axis 33 and the switching and transmission time axis 34. Switching equipment (Fig. 2) consists of switching field 35 connected via lines 36 and synchronization receivers 37 to inputs 38 of switching equipment and connected via lines 39 and transmission device 40 to outputs 41 of switching equipment and generator equipment 42, outputs which is directly connected to the clock inputs 43 of the receiving device 37 synchronization and connected through the device 44 delay to the input 45 of the switching field 35 And to the inputs 46 of the transmission device 40. From the switching equipment inputs 38, the incoming signals compressed in time are fed to the synchronization receiving devices 37. In parallel from the generator equipment 42, the clock inputs 43 of the receiving devices 37. Synchronization provide channel counting signals. Receiving synchronization devices 37 provide for phasing of received signals in such a way that the counting of channels in signals, supplying xx by 36 in the switching field, is similar to the counting of kayals in the generator equipment 42. On the axis 33 of reception time (figure 1) the counting of channels at the inputs of the field 35 Jokoms. The signals of the counting of channels in the generator equipment 42 () through the device 44 delays are fed to the input 45 of the switching field 35, in which the switching operations are clocked. The delay device 44 can be implemented as m-bit shift registers, the number of these shift registers is equal todj c, rounded up to the nearest whole number, where e is the number of channels in the compressed lines, and O 411PP / 2. On the axis 34 of the time of transmission and switching (figure 1) marked the counting of the channels in the field 35 of switching and | W W 4 and C 32.. To ensure that the switching system is adaptable to varying operating conditions, delay device 44 may have means for manually or automatically adjusting the amount of delay. The value of the delay / is equal to the number of ka / nal1vlh intervals, be selected by the relation (1). In the switching field 35 (FIG. 2), the reception of the signals of the channels to be commited is carried out, the signal storage. - (forward and reverse directions) for any difference in the numbers of the channels used: channels and transmission of these signals. through the channels of the required directions via lines 39 and devices 40 to outputs 41 about satisfaction “1 tation. At the same time, the storage time of signals in the switching field 35 is assumed to be 2 tons of channel intervals, the difference in the numbers of the channels used in the forward and reverse directions is less than or equal to m or equal to 2 W + s, if the difference is greater than: m. , - -::: „- /. -,;; in the transmission devices 40, the signals connected in the switching field 35 complement the screen signals and the control and interaction signals. The timing of the sync and signaling channels is determined using the channel counting signals by supplying inputs 46 of the delay device 44 Before a more detailed examination of some of the operations performed in the switching circuit 35, it is necessary to clarify some concepts; Under the difference 8 in the channel numbers l and j respectively. Directly and indirectly, directly understood is the absolute minimum distance on axis 33 (Fig. 1) or, between the channels with the numbers i to f. For example (Fig. I, on channels 30 and 1, there are two intervals with a distance of 29 and 3 channel intervals. In this case, the distribution in this case is 8 3. The storage time of signals in the switching equipment means the storage time of the signals (forward and backward). directions) required to establish one two-way connection, i.e. a connection, between channel i at the input and channel j at the output and between channel j at the input and channel i at the output. Thus, the storage time t has two As an example, consider two special cases. for W 4. and C 32. Let it be necessary to establish a connection with the second and fourth channels, i.e. -2 4. In this case, a 2 (lig.1) and (. From the diagrams (FIG , 1) it can be seen that one component of the storage time (when transmitting signals from channel j 2 on axis 33 to channel j 4 on axis 34) is equal to the channel interval, and the other (when transmitting signals from the channel), 4 on axis 33 to channel with the number “2 at ICS 34) equals 4§ 4 + 2 6 channel intervals. The storage time is, (Neni signals equal to the sum of both two yugdi sums in this case is equal. For the second special case, the reception (10 and. In this case, Fr. In Fig. 1, it is clear that one component of the storage time is , the signals from channel -i 10 on axis 33 to channel j 15 on axis 34) are equal to mto channel intervals, and another (when transmitting signals from channel j 15 to axis 33. B channel g, 10 on axis 34 is P} 4 -C-o 4 + 32-5; ii CANILE interval. The storage time in this case is - 2w + from the time slots;. The implementation of the proposed switching method can be carried out by others ( those that azans PA1 in Figure 2 by means of, for example, by shifting the start point in the channel switching field 35 () relative to the reference kangshov in the received signals due to variations mode, operation of receivers 37 Positive synchronization effect provided by the use proposed..

The invention is illustrated by example. numbering system with a small number of channels, in the direction-; laziness (and with 30) and relatively high utilization of channels (a 0.7); From relation (1), we get m; 3. The average storage time of signals in the switching equipment in this case is 8.4 channel intervals. Using the famous

The "4" method under the same condition is characterized by an average signal storage time of 20.3 channel intervals. Reducing the average signal storage time by more than 2 times with the proposed method provides the possibility of a corresponding reduction in the amount of storage equipment in the switching equipment.

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Claims (1)

CHANNEL SWITCHING METHOD IN SYNCHRONOUS SYSTEMS OF COMMUNICATION WITH A TEMPORARY SEAL, which consists in the fact that they receive signals, store signals for a predetermined time when establishing a connection through opposite channels and transmit signals through channels of the required directions in accordance with control signals, characterized in that, in order to reduce time switching, carry out a temporary shift of the received signals with their subsequent storage for a time (2m + s) with a difference in the channel numbers of the forward and reverse directions, greater than tn, or for a time of 2 Hz at this Difference of not more than u, the time shift of the received signals is given by VcaCnVa · ^{m =} ϊητ '' 2Vtn </ a where m is the number of channel intervals by which the shift ·,. '' V is the average number of packed lines in the direction; C is the number of channels in the packed lines, ’a is the average utilization of the channels; p is the amount of loss. where m - the number of channel intervals by which the shift; - the average number of packed lines in the direction; - the number of channels in the sealed lines; 0 - the value of the average use of channels ;. p is the magnitude of the losses. Figure 1 shows a diagram