CS243248B1 - Bus system connection for transmission of messages with different priority - Google Patents

Abstract

The connection of a bus system for the transmission of alarm and diagnostic messages with different priorities in modular design devices, especially telecommunications devices, allows for one-way and two-way transmission of these messages, which it combines into a uniform format suitable for remote transmission and central processing. The essence of the solution lies in the fact that the clock input (53) of the address decoder (50) is connected to the central clock gate (2] of the bus (lj) and the output (6) of the clock pulse source (5) is connected to the output of the communication detector (13) and the counter (23) is connected by the counting input (24) of the counter (23) to the clock gate (14) of the bus (lj, and to the clock input (20) of the transmitter (17), while the output (27) of the counter (23) is connected to the release input (19) of the transmitter (17), and the signaling gate (21) of the transmitter (17) is connected to the signaling gate (15) of the bus (1).

Description

BACKGROUND OF THE INVENTION The invention relates to a bus system for transmitting messages of different priority in modular, especially telecommunication, devices comprising a clock pulse source and a bus with a central bus gate and a central bus gate to which a central receiver data gate equipped with a communication detector is connected. provided with at least one communication unit, each connected to one of the three gateways, consisting of a bus clock gate, a bus signal gate and a bus data gate equipped with a counter and a transmitter connected by its transmitter data gate to the bus data gate.

Currently, the transmission of alarm messages in telecommunications equipment is usually handled by assigning one wire to priority alarm messages and, for non-priority messages, all alarms from the rack are transmitted to the surveillance center by one common wire or are not transmitted at all.

This method of transmitting alarm messages has the disadvantages of modular rack construction, where different units can transmit a different number of priority messages, and centralized computer control and control, where a large number of individual wires is not a convenient means of communication with a computer that is virtually impossible.

The solution to remedy these shortcomings is to use a bus system. The disadvantage of the known bus systems, however, is that they are quite complex because they are designed to transmit large numbers of messages quickly and furthermore that they are not adapted to sort the transmitted messages into an "ordered waiting queue" according to their importance.

These disadvantages are eliminated by the circuit according to the invention, which is based on the fact that an address decoder input and a clock pulse source output are connected to the central bus clock gate, the clock pulse source control input is connected to the communication detector output and the counter is connected to the counter count input. on the one hand to the bus clock gate, and on the other hand to the clock input of the transmitter, wherein the counter output is connected to the enable input of the transmitter, and to the bus signaling gate the signaling gate of the transmitter is connected.

In a preferred embodiment, the circuit according to the invention is provided with a central transmitter and a release member, wherein the clock input of the central transmitter is connected to the internal clock output of the clock pulse source, the clock input of the central transmitter is connected to the control input of the clock pulse source. the latch input of the release member is connected to the central clock gate of the bus, and the data gate of the central transmitter is connected to the central data gate of the bus, while the communication unit is provided with a receiver citation.

According to a further preferred embodiment of the invention, the blocking output of the central transmitter is connected to the blocking input of the central receiver. It is further preferred that the receiver blocking input is connected to the transmitter blocking output.

It is also advantageous if, in the circuit according to the invention, the bus is provided with a bus central signaling gateway, to which its output is connected a synchronizing member, the input of which is connected to the bus central clocking gate. a reset command detector whose output is connected to the reset input of the counter.

Advantageously, the circuit according to the invention can be designed such that an address member is connected to the address input of the counter.

In a further preferred embodiment of the circuit according to the invention, the signal input of the clock pulse source is connected to the bus central signaling gate.

The wiring of the bus system according to the invention has the main advantages in that it can provide unidirectional and bidirectional transmission of alarm and diagnostic messages of different priority, grouping them into a single format suitable for remote transmission and central processing. The monitored telecommunication devices can thus be easily connected to the monitoring system of the unified telecommunication network. The wiring of the bus system according to the invention allows for flexible construction and extension of the alarm and diagnostic system and requires minimal installation work. By reducing the wires between the supervised devices and the supervising center, non-ferrous metals are saved.

The invention is explained in more detail below on two exemplary embodiments in conjunction with the drawing. 1 shows a schematic example of a basic circuit according to the invention with one communication unit. FIG. 2 schematically shows an example of a circuit according to the invention, enabling two-way transmission of messages with two communication units, where only one of them is illustrated for simplicity. FIG. 3 is a graphical representation of the waveforms of the signals on the individual bus conductors where

C is the waveform display on the clock wire,

S is a waveform display on the signal wire,

D is a waveform display on data lines,

243243

K indicates the start of the non-priority message transmission by the communication unit of address K,

L indicates the transmission of a non-priority message by the communication unit of address L,

M indicates the start of transmission of the priority message by the communication unit of address M,

X denotes the point at which a priority message a appeared on the signal wire

N denotes the start of the non-priority message transmission by the central transmitter to the receiver connected in the communication unit.

As can be seen from FIG. 1, the clock 6 of the clock pulse source 5, the clock input 53 of the address decoder 50 and the input of the synchronization member 29 are connected to the central clock gate 2 of the bus 1. to the reset input 52 of the address decoder 50 provided with the address output 51 of the address decoder 50, both to the signal input 7 of the clock pulse source 5 and to the signal input 10 of the central receiver 9 provided with the output 12 of the transmitted messages of the central receiver 9 bus 1 is connected both to the data gate 11 of the central receiver 9 and to the input of the communication detector 13, the output of which is connected to the control input 8 of the clock pulse source 5. A communication unit 54 is connected to one of the three edges formed by the bus gate 14, the bus 1 signaling gate 15 and the bus 1 data gate 1B.

A clock input 20 of the transmitter 17 connected to the counting input 24 of the counter 23 is connected to the clock gate 14 of the bus 1. A clock gate 21 of the transmitter 17 connected to the input of the reset command detector 49 is connected to the gate signal 15. input 25 counter, 23. Connected to the data gate 16 of the bus 1 is the data gate 2.2 of the transmitter 17 provided with the input 18 of the broadcast messages of the transmitter 17. The output 27 of the counter 23 is connected with the release input 19 of the transmitter 17 and the address input 26 of the counter 23.

The circuit according to the invention shown in Fig. 2 is virtually identical except that it is supplemented by a central transmitter 30 provided with a control transmitter input 48 and a release member 38 and comprising two communication units, one of which is The simplification is only indicated and each of which is connected to one of the three gateways, each comprising a bus gate 14, a bus 1 signaling gate 15 and a bus data gate 16, wherein each of the communication units 54 is complemented identically with respect to the connection shown in FIG. a connected receiver 42 provided with a receiver 47 of control receiver messages 42.

The clock input 34 of the central transmitter 30 is connected to the internal clock output 37 of the clock pulse source 5 and the block output 32 of the central transmitter 30 is connected to the block input 33 of the central receiver 9. The data gate 3B of the central transmitter is connected to the data gate 11 of the central receiver 9 the gateway 35 of the central transmitter 30 is connected to the output of the synchronization member 29. The release input of the central transmitter 30 is connected both to the output 39 of the release member 38 which is provided with the address input 41 of the release member 38 and to the control input 8. The latch input 40 of the release member 38 is connected to the central clock gate 2 of the bus 1. The receiver 42 is connected to the data gate 16 of the bus 1 with its data gate 4B of the receiver 42, the latch input 44 of the receiver 42 is connected to the block output 35 the receiver 42 is connected to the output 27 of the counter 23.

It is also possible to alternate the synchronization member 29 and the reset command detector 49, in which the output of the synchronization member 29 is connected to the central data gate 4 of bus 1 and the input of the reset command detector 49 is connected to the data gate 16 of bus 1.

The control messages are fed to this circuit at the control transmitter input 48 of the central transmitter 30 and the address input 41 of the release member 38, and are taken from the control output 47 of the receiver 42.

In the idle state without message transmission, the clock pulse source 5 transmits a clock signal on bus 1 via the central clock gate 2 of bus 1. The clock pulses are filled with counters 23 which, at their moment of filling, release the counter 17 via the transmitter 17. The individual transmitters 17 are distinguished so that each transmitter 17 can start transmitting a message only at the clock time when its counter 23 is filled. The address of the transmitter 17 is set by the address member 28 through which the counter 23 is set via the address input 26 of the counter 23. A communication detector 13 responds to the leading edge of the signal at the central data gate 4 of the bus 1, which interrupts the transmission of the pulse pulses through the control input 8 of the pulse source 5 while the message is present on the central data gate 4 of the bus 1. If the message is processed, the communication detector 13 releases the retransmission of the clock signal via the control input 8 of the clock pulse source 5. Transmitter 17 responds to the rising edge of the first clock pulse and interrupts transmission of the message. At the moment of need to send a priority message, the transmitter 17 ground via the signaling gate 243248 nu 21 of the transmitter 17 the signaling gate 15 of the bus 1. This blocks all priority transmitters 17 without sending priority messages. immediately interrupts this message. This resumes transmission of the clock pulses and bus 1 is ready for priority message transmission. The synchronization of resetting the counters 23 is controlled by a synchronization member 29 which sends a reset command to the central signaling gateway 3 of bus 1 or alternatively to the central data gateway 4 of the bus 1. The resetting command may be in the form of a selected data combination transmitted over data wires or with the closing edge parallel to the closing edge of the clock pulse transmitted over the signal wire. The address analysis of the transmitter 17 transmitting the transmitted message is performed by the address detector 50 by counting the pulse pulses, also synchronized by a reset command. The decoded address is transmitted by the address detector 50 at the address output 51 of the address decoder 50.

In the bidirectional transmission, messages relating to the pair 17 transmitter-receiver 42 are addressed by the same clock interval, see Fig. 3. However, the message from the central transmitter 30 starts to be transmitted with a delay of half clock interval to avoid possible interference with these messages. By this arrangement, for example, messages transmitted by transmitter 17 may also be preferred over messages transmitted by central transmitter 30. The transmission of the message by central transmitter 30 is controlled by a release member 38 that operates as a preconfiguration clock pulse counter controlled by a signal supplied to the address input 41 of the release member 38. the transmission of the message of the central transmitter 30 starts at the moment of the rising edge of the clock pulse, which, however, is to be suppressed, see Fig. 3, avoiding the clock signal transmission by connecting the output 39 of the release member 38 to the control input 8 of the clock pulse source 5. However, to precisely maintain the origin of the message of the central transmitter 30, a clock signal is necessary and therefore the clock input 34 of the clock transmitter 30 is coupled to the clock clock output 37 of the clock pulse source 5, where the clock signal is never suppressed. Incorrect evaluation of the message of the central transmitter 39 by the central receiver 9 is prevented by connecting the blocking output 32 of the central transmitter 30 to the blocking input 33 of the central receiver 9. On the receiver 42 the resolution of the correct message transmitted by the central transmitter 39 is provided by a counter 23. 43 of the receiver 42. A connection between the blocking output 45 of the transmitter 17 and the blocking input 44 of the receiver 42 prevents the transmitter 17 from being coupled with the coupled receiver 42 to erroneously evaluate the message.

Claims (7)

Subject 1. Connection of a bus system for transmitting messages of different priority, comprising a clock pulse source and a bus with a central bus clock gate and a central bus gateway to which a central receiver data gateway equipped with a communication detector connected with at least one communication unit connected to one of the three gateways comprising a bus clock gate, a bus signal gate and a bus data gate equipped with a counter and a transmitter connected by its transmitter data gate to the bus data gate, characterized in that the central bus gate (2) is the clock input (53) of the address decoder (50) is connected and the clock output (6) of the clock pulse source (5) is connected, the control input (8) of the clock pulse source (5) is connected to the output of the communication detector (13); input (24) of the counter (23) connected to the clock on the other hand, to the clock input (20) of the transmitter (17), the counter output (27) being connected to the enable input (19) of the transmitter (17), and to the signaling gate (15) the signaling gate (21) of the transmitter (17) is connected to the bus (1). 2. The circuit according to claim 1, characterized in that it is provided with a central transmitter (30) and a release member (38), the clock input (34) of the central transmitter (30) being connected to the internal clock output (37) of the source (5). clock pulse, the release input (31) of the central transmitter (30) is connected both to the control input (8) of the clock pulse source (5) and to the output (39) of the release member (38); 38) is connected to the central clock gate (2) of the bus (1) and the data gate (36) of the central transmitter (30) is connected to the central data gate (4) of the bus (1), while the communication unit (54) is provided with 42), which is connected by its data gateway (46) to the receiver (42) to the data gateway (16) of the bus (1) and the release input (43) of the receiver (42) is connected to the output (27) of the counter (23). Connection according to claim 2, characterized in that the blocking output (32) of the central transmitter (30) is connected to the blocking input (33) of the central receiver (9). Connection according to claim 2 or 3, characterized in that the blocking input (44) of the receiver (42) is connected to the blocking output (45) of the transmitter (17). 243218 Connection according to any one of the preceding claims, characterized in that the bus (1) is provided with a central signaling gateway (3j of the bus (11j) to which its output is connected a synchronization member (29) whose input is connected to the central clock gate ( 2) the bus (1), wherein a reset command detector (49) is connected to the signaling gate (15) of the bus (1) or to the data gate (16) of the bus (1), whose output is spo10 only with the reset input (25) ) counters (23). Connection according to any one of the preceding claims, characterized in that an address member (28) is connected to the address input (26) of the counter (23) by its output. Connection according to one of the preceding claims, characterized in that a signaling input (7) of the pulse pulse source (5) is connected to the central signaling gate (3) of the bus (1).