KR0180114B1 - Data triple system in a full electronic exchanger - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an all-electronic exchange, wherein when triplening the data between circuit blocks provided in the all-electronic exchange, the data tripleization system in the all-electronic exchange is configured to uniformly select the neutralized data and transmit it to the receiving side. It is about.

In the case where the circuit blocks are tripled by applying the conventional method, for example, an alarm occurs when the first transmitting side is in an active state, and when both the second transmitting side and the third transmitting side are not in an alarm state, Priority should be given to the transmitting side or the third transmitting side, so that the active state is biased on either side, which makes it difficult to efficiently use the tripled circuit block.

In the present invention, when the circuit block in the all-electronic exchanger is tripled, the selection of the active is made to have a uniform probability so as not to be biased, and thus the tripled circuit block is efficiently used.

Description

Data Triplexing System in Electronic Switching System

1 is a configuration diagram of a data redundancy system in a conventional all-electronic exchange.

2 is a truth table for explaining a duplication selection method of the data duplication system shown in FIG.

3 is a block diagram of a data triplexing system in an electronic switching system according to the present invention.

4 is a truth table for explaining the operation of the data triplexing system shown in FIG.

* Explanation of symbols for main parts of the drawings

30, 40, 50: transmitting side SL: triple selection circuit

TB: Transmission buffer

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an all-electronic exchange, and in particular, to triple the data between circuit blurs provided in the all-electronic exchange, to triple the data in the all-electronic exchange such that the tripled data is equally selected and transmitted to the receiving side. It's about the system.

In general, in an all-electronic exchange, each circuit block is duplicated, so that even if one of the circuit blocks fails, the operation may continue with the other circuit block.

In the case of duplication of circuit blocks in an electronic switching system, duplication can be done in various ways, and the duplication selection can be divided into two methods depending on whether the transmitting side or the receiving side is performed. (A) of FIG. 1 shows that the receiving side (11, 12) transmits data and the redundant signal to the receiving side (13, 14) in such a manner that the receiving side makes a redundancy selection. Select and receive data based on the redundant signal. As a redundant signal transmitted from the transmitting side 11, 12 to the receiving side 13, 14, an alarm signal for notifying whether a failure has occurred is used, and the transmitting side 11, 12 receives the corresponding alarm signal from the receiving side 13 By providing a redundant signal to, 14, the receiving side 13, 14 selects and receives data of the transmitting side without an alert.

On the other hand, (b) of FIG. 1 is a method of performing duplication selection on the transmitting side, and only one of the two transmitting sides 16 and 17 is selected to transmit data to the receiving side 18 and 19. There is no need to send a redundant signal from the 16, 17 to the receiving side (18, 19). When duplication is selected on the transmitting side 16, 17, the transmitting side 16, 17 operates in an active / standby state, and the transmitting side in the active state transmits data to the receiving side 18, 19, and standbys. The sender in the state does not transmit data to the receivers 18 and 19. As described above, in order for the transmission side 16 and 17 to select duplication and transmit data, whether the transmission side 16 and 17 exchanges the redundancy signal between the transmission side 16 and 17 and operates in an active or standby state based on the state of the other party and its own state. Determined and operated.

In the case of redundancy in the manner shown in (a) of FIG. 1, the receiving side 13, 14 selects the redundancy based on the truth table as shown in (a) of FIG. 2, and in the manner shown in (b) of FIG. In the case of redundancy, the transmitting side 16, 17 is based on the truth table as shown in Fig. 2 (b). Based on the duplication operation, data is transmitted to the receiving sides 18 and 19. In the truth table as shown in (a) of FIG. 2, the redundancy signal '0' indicates a state where no alarm occurs, and the redundancy signal '1' indicates a state where an alarm occurs. That is, if the alarm state of the transmitting side 11, 12 is '00', the receiving side 13, 14 continues to maintain the previous redundancy selection, and the '01' or '10' receiving side 13, 14 The transmitting side without an alert is selected, and if it is '11', the receiving side 13 or 14 does not select both transmitting sides 11 and 12.

In addition, when the transmitting side 16, 17 determines redundancy based on the truth table as shown in FIG. 2 (b), only the transmitting side in the active state receives the data by selecting the redundancy in advance on the transmitting side 16,17. Since transmission to the sides 18 and 19 is necessary, a circuit for redundancy selection is required at the transmitting side 16 and 17, and no redundancy selection is required at the receiving side 18 and 19, and only the received data is accepted. Necessary signals for redundancy at the transmitting side 16 and 17 are ACT signals indicating the active / standby state of the self and the counterpart, and ALM signals indicating the alarm state to the self and the counterpart. In the active state, the ACT signal is '0'. In standby mode, the ACT signal becomes '1'. When not in the current alarm state, the ALM signal becomes '0' and in the current alarm state, the ALM signal becomes '1'. In addition, in FIG. 2B, 'E' indicates that the user operates in an active state, and 'F' indicates that the user operates in a standby state. That is, the transmitting side 16, 17 always checks the active / standby state and the alarm state of the other side, and generates an alarm on the other side, and operates in the active state when the alarm is not generated on the other side.

In the case where the circuit blocks are tripled by applying the conventional method as described above, for example, an alarm occurs when the first transmitting side is in an active state, and at this time, both the second transmitting side and the third transmitting side are in an alarm state. If not, the priority should be given to the second transmitting side or the third transmitting side, and since the active state is biased on either side, there is a problem in that the tripled circuit block cannot be efficiently used.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and when triplening each circuit block inside the electronic exchanger, the triplet circuit block can be efficiently made by making the selection of active at a uniform probability unbiased. It is intended to be used.

In order to achieve the above object, the present invention relates to an all-electronic exchanger that triples and operates a transmitting side for transmitting data, wherein each transmitting side corresponds to an operation state signal, an alarm signal, and an identification signal applied from each transmitting side. And a triplet selection circuit for outputting the triplet selection signal, and a buffer for transmitting data to the receiving side in accordance with the triplet selection signal applied from the triplet selection circuit.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The data triplexing system in the electronic exchanger according to the present invention is constructed as shown in FIG. That is, each transmitting side 30, 40, 50 has a triplet selection circuit SL and a transmission buffer TB, and the operation state signals ACT0, 1, 2 applied to the triplet selection circuit SL. Denotes an active / standby state of the transmitting side 30.40, 50, and an operating state signal ACT0 is an operating state signal of the transmitting side 30, and an operating state signal ACT1 is an operating state of the transmitting side 40. Signal, and the operation state signal ACT2 is the operation state signal of the transmitting side 50. As shown in FIG. Each operation state signal (ACT0, 1, 2) becomes '0' when each transmission side (30, 40, 50) is in an active state, and each operation state signal when each transmission side (30, 40, 50) is in a standby state. (ACT 0,1,2) becomes '1'. In addition, the alarm signals ALM0, 1, 2 applied to the triplet selection circuit SL are signals indicating whether an alarm has occurred at each of the transmission sides 30, 40, 50, and the alarm signal ALM0 is a transmission side ( 30 is an alarm signal, an alarm signal ALM1 is an alarm signal of the transmitting side 40, and an alarm signal ALM2 is an alarm signal of the transmitting side 50, wherein each transmitting side 30, 40, 50 is connected to the alarm signal ALM2. Each alarm signal ALM0, 1, 2 is set to '0' when not in an alarm state, and each alarm signal ALM0, 1, 2 is set to '1' when each transmitter 30, 40, 50 is in an alarm state. do. On the other hand, the identification signals ID 0, 1, 2 applied to the triplex selection circuit SL are signals for distinguishing the transmission side 30, 40, 50, and the identification signal ID0 is the transmission side 30. The identification signal ID1 is an identification signal of the transmitting side 40, and the identification signal ID2 is an identification signal of the transmitting side 50. The new star signal ID0, 1, 2 consists of 2 bits. For example, the transmitting side 30 is assigned to '00', the transmitting side 40 is assigned to '01', and the transmitting side 50 is assigned to ' Assigned to 10 '. Each triplet selection circuit SL is supplied with operation status signals ACT0, 1, 2, alarm signals ALM0, 1, 2, and identification signals ID0, 1, 2, respectively, to each transmitting side 30, 40, The operation of the transmission buffer TB is controlled by determining the active / standby state of the control unit 50) and outputting a triplet selection signal corresponding to the active / standby state to the transmission buffer TB. Each transmission buffer TB is a buffer for storing data transmitted to the receiving side, and transmits data to the receiving side according to the triplet selecting signal applied from the triplet selecting circuit SL. In addition, since only one signal of the operation state signals ACT0, 1, and 2 applied to the triplex selection circuit SL is enabled, only one of the three transmission buffers TB is enabled to receive data to the receiver. send. When the active state is changed, the identification signals ID0, 1, and 2 are used to uniformly distribute the active state to each of the transmission side 30, 40, 50 side, and each triplet selection circuit SL. Allocates the active states of the transmitters 30, 40, and 50 with equal probability by the identification signals ID0, 1, 2, the operation state signals ACT0, 1, 2, and the alarm signals ALM0, 1, 2; do.

The data triplexing system of the present invention configured as described above operates as follows. For example, the identification signal ID0 of the transmitting side 30 is assigned '00', the identification signal ID0 of the transmitting side 40 is assigned to '01', and the identification signal of the transmitting side 50 is assigned. If (ID2) is assigned to '10', the operation status signals (ACT 0, 1, 2) and alarm signals (ALM 0, 1, 2) are identified when the sending side (30, 40, 50) exchanges with each other. Since it is possible to send and receive according to (ID 0, 1, 2), each triplet selection circuit SL can recognize the operation state and the alarm state of the transmitting side 30, 40, 50. In addition, when the triple selection circuit SL selects the active state, the active state is selected with the same probability in order for each transmitting side 30, 40, 50. For example, when the transmitting side 30 is in an active state, an alarm is generated and transitions to a standby state. At this time, when both of the transmitting sides 40 and 50 have no alarm, the transmitting side 40 is switched to the active state. Thereafter, an alarm is generated on the transmitting side 40 to transition to the standby state, and if an alarm is not generated on the transmitting side 30, 50, the transmitting side 50 is switched to the active state. By triple selection in this manner, it is possible to prevent the active state from being allocated to a specific transmitting side unbiased, thereby allocating the active state with equal probability to all transmitting sides 30, 40, and 50.

FIG. 4 shows an operation truth table of the triplet selection circuit SL of the transmitting side 30. FIG. 4A shows that the alarm signal ALM0 of the transmitting side 30 is '0' at the same time. The operation truth table when the status signal ACT0 is '0', and (b) of FIG. 4 shows that the alarm signal ALM0 of the transmitting side 30 is '0' and the operation status ACT0 is '1'. Is the operation truth table in the case of ', and (c) of the drafting is the case where the alarm signal ALM0 of the transmitting side 30 is' 1' and the operation state signal ACT0 is' 0 'or the alarm signal ALM0. Is the truth table when the signal is set to '1' and the operation signal state ACT0 is '1'. The output value shown in this truth table indicates the state of the operation state signal ACT0 of the transmitting side 30, and at this time, the signal of '0' indicates that it is active, and the signal is applied to the transmitting buffer TB side to transmit the transmitting buffer ( By enabling TB), the data of the transmission buffer TB is transmitted to the receiving side. In the case of configuring the digital logic in this manner, the operation state signal ACT0 of the transmitting side 30 is output based on the following logic equation. In the active state, the operation state signal ACT0 becomes '0', so By using the Karnaugh Map method known in the truth table of (a), (b), and (c), sum the logical expressions derived when the truth values of '0' are combined to find the logical expression for / ACT0. Can be. However, in the following logical expression, / represents negative logic, · represents logical product, and + represents logical OR.

In addition, in the truth table of FIGS. In the set state, when the truth values of '0' are bundled using the known carnomap method (the active state signal ACT1 becomes '0' in the active state, the truth values of '0' are bundled) By adding the logical expressions derived from the truth tables of each of (a), (b) and (c) shown in the figure, the following logical expressions for / ACT1 can be obtained. The operation state signal ACT1 of the transmitting side 40 is The output is based on the logical expression of.

Then, in the truth table of FIGS. In the state, when the truth values of '0' are bundled using the known Carnot map method (the active state signal ACT2 becomes '0' in the active state, the truth values of '0' are bundled) By adding the logical expressions derived from the truth tables of each of (a), (b), and (c) shown in the following, the following logical expressions for / ACT2 can be obtained, and the operation state signal ACT2 of the transmitting side 50 is The output is based on the logical expression of.

Incorporating the above three logical expressions are as follows.

Accordingly, in order to determine the active state by each triplet selection circuit SL, one of different identification signals ID0, ID1, and ID2 is assigned to each triplet selection circuit SL, and the identification signal ID0 is assigned. ) Is determined based on the logical expression of / ACT0, active is determined based on the logical expression of / ACT1 for identification signal ID1, and based on the logical expression of / ACT2 for identification signal ID2. By determining the active state, each tripleization selection circuit SL determines the active state by the logical expressions of the corresponding / ACT0, / ACT1, and / ACT2 when the identification number assigned thereto is inputted. It is possible to have a uniform probability of not biasing the choice. That is, each tripleization selection circuit SL determines the active state according to the logical expressions of the corresponding / ACT0, / ACT1, and / ACT2 when the identification signals ID0, ID1, and ID2 assigned thereto are applied to the transmission buffer. (TB) is enabled to transmit data to the receiving side.

As described above, the present invention makes it possible to use the tripled circuit block efficiently since the selection of the active is made to be uniformly unbiased when the circuit block in the all-electronic exchange is tripled.

Claims (1)

In an all-electronic exchanger that triples and operates a transmitting side for transmitting data, each transmitting side outputs a triplet selection signal according to an operation state signal, an alarm signal, and an identification signal applied from each transmitting side. And a selection circuit and a buffer for transmitting data to a receiving side in accordance with a triplet selection signal applied from said triplet selection circuit.