HU213503B - Long-distance telephone network without exchanges - Google Patents

Abstract

The invention is a long-distance network, which does not require hierarchically organized, expensive equipment for the previous build-up and subsequent breaking of connections and ensures the permanent availability of transmission routes, independently of the degree to which transmission capacity is utilized. The arrangement proposed in this invention is characterized by comprising cable networks (4), each connecting a number of output devices (1), not far from each other, to an interface (2), and a two-dimensional, preferably hexagonal or square, switching field of net topology. In the interface units (2), to each of which output devices (1) are connected by a cable network (4), acoustic converters are connected, through a routing unit, a temporary information store and a time slot access unit, to a long-distance signal transmitter-receiver. The two-dimensional switching field of net topology contains nodal units (3) in which nodal units (3) long-distance signal transmitter-receivers are connected, through a time slot access unit, and a temporary information store, to a directional coupler controlled by an address decoder. The network may also contain an operation supervision unit (5) and/or an operation supervision and network data base (6), connected to the cable network (4).

Description

The present invention relates to an arrangement for realizing a long distance telephone network without using centralized switching 4.

Solutions that allow computers to be connected to data communication networks are known. From the outset, computer data communication networks 5 have been designed to avoid the need for switching centers. Instead of switching centers, the network was created by interconnecting peer-to-peer communication equipment on a multipoint or radio channel, solving the same information transmission 10 channels over time, and creating an infinitely structured network of communication equipment and information channels. By establishing packet switched networks, it has been possible to send messages of any length of 15 without any communication equipment occupying the information channels for a long time, excluding other communication equipment from accessing the information channel. Packet switched networks are theoretically capable of transmitting digitally encoded speech information, but since the primary purpose is to maximize the capacity of the information transmission channels, it is not assured in conventional networks that all 25 data packets of speech information reach their destination within the time required by normal human dialogue. moreover, a data packet launched later in time may precede the data packet that was started earlier due to different transmission paths, or, if this is eliminated, the quality of the basic function of the system 30 will deteriorate.

Telephone networks are line-switched networks where the exchange provides each user with exclusive access to an information channel for the duration of the call. Transmission only takes 35 weeks if a connection has already been established, and after the transmission is completed, the connection must be disconnected so that the transmission channel is available to another user. Such systems require expensive, hierarchically-structured interconnection devices - 40 which make it difficult to expand and spatially expand.

Based on the foregoing, a long distance telephone network that does not require expensive, centralized, hierarchically organized central equipment and transmission paths at all times, irrespective of the utilization of information transmission capacity, is not solved. The present invention is directed to solving such a telephone network arrangement. 50

The present invention has led to the discovery that it is possible to implement connections without a hub and backbone network using a two-dimensional mesopology time-multiplex switching field, if its nodes are self-controlled, geographically distributed, and capable of long-distance signaling.

The arrangement according to the invention consists of a wired network interface interface unit and a two-dimensional mesh topology switching field for proximity terminals. Together, the interface units connected to the terminals via a cable network are acoustic transducers connected to a remote transceiver via a routing unit, a temporary information store, a time slot access unit. The two-dimensional mesh topology switch field comprises node units that are connected in a node unit to a directional switch in control connection with the address encoder via a remote transceiver slot access unit, a temporary information store.

According to a preferred embodiment of the invention, the cable network connecting the terminals to the interface unit is comprised of a time-multiplex multipoint line.

According to a preferred embodiment of the invention, the path mapping unit is a microcomputer located in the terminal.

In a preferred embodiment of the invention, the sets of interface units connected to the terminals by cable network include analog-to-digital and digital-to-analog converters.

In a preferred embodiment of the invention, the long-range transceiver surface is a microwave radio transceiver.

In a preferred embodiment of the invention, the node unit comprises a variable directional transceiver receiver.

A preferred embodiment of the invention is that the variable directional transceiver has an electronically rotated directional characteristic.

According to a preferred embodiment of the invention, one of the interface units connected to the terminals via a cable network is connected to the cable network to the operation monitoring unit and / or to the operation monitoring and network database.

In a preferred embodiment of the invention, the switching field with two-dimensional mesh topology has a hexagonal topology.

Detailed Description of the Arrangement of the Invention According to a preferred exemplary embodiment, the figures will be described.

Fig. 1 shows a circuit diagram of an exemplary terminal 1.

Fig. 2 shows a circuit arrangement of an exemplary interface unit 2.

Figure 3 shows a circuit arrangement of an exemplary node unit 3.

Figure 4 shows a circuit layout of a portion of an exemplary long distance network.

Figure 5 shows an exemplary topology of a switching field.

In the exemplary telephone network arrangement, in the terminal 1 of FIG. 1, the acoustic converter 1.1 is connected via the A / D converter 1.2 and the D / A converter 1.3 to the routing unit 1.4 which is connected to the cable network 4 via slot 1.5 and line adapter 1.6. is connected, which is a multipoint line. The multi-point line connects to the interface unit 2 to the terminal 1, which is locally close to each other, e.g.

HU 213 503 Β c. The multipoint line connecting the terminals 1 is connected to the slot slot access unit 2.2 in the interface unit 2 of FIG. 2 via its line adapter 2.1. The time slot access unit 2.2 is connected to the input of the temporary information store 2.3 and the output of the temporary information store 2.4. The output of the temporary information store 2.3 is connected to the time slot access unit 2.5. The time slot access unit 2.5 is connected to the input of the temporary information store 2.4 via the address decoder 2.7. The time slot access unit 2.5 is coupled to a remote encoder, preferably a microwave transceiver 2.6, with a high gain antenna pointing to the node unit 3. The variable directional transceiver receiving surface of the node unit 3 of Fig. 3 is an electronically rotated high gain antenna of a microwave transceiver 3.1, which is alternately directed to an interface unit 2. The microwave transceiver 3.1 is connected to the address decoder input 3.2 and its outputs to the directional switch 3.5. Also connected to the microwave transceiver 3.1 is the output of the time slot access unit 3.3, the input of which is connected to the directional switch 3.5 via the temporary information store 3.4. One of the remote transceivers of the node unit 3 is the microwave transceiver 3.11, which is connected to the input of the address decoder 3.12 and its outputs to the directional switch 3.5. Connected to the microwave transceiver 3.11 is the output of the time slot access unit 3.13, the input of which is connected to the directional switch 3.5 via the temporary information store 3.14. A further transceiver for the node unit 3 is the microwave transceiver 3.21, which is connected to the input of the address decoder 3.22 and its outputs to the directional switch 3.5. Connected to the microwave transceiver 3.21 is the output of the time slot access unit 3.23, the input of which is connected to the directional switch 3.5 via the temporary information store 3.24. Node units 3 of this arrangement form a switching field with a two-dimensional mesh topology as shown in FIG.

In the terminal 1, the route mapping unit 1.4 is preferably a microcomputer comprising a processor, memory and an I / O unit. Using the program, the microcomputer generates a binary coded bit sequence that directly determines the path, and is composed in the following order: - The network coordinate difference of the node unit 3 of the given terminal 1 transmitting the information relative to the node unit 3 of the given terminal 1 . - Address of interface unit 2 connected to receiving terminal 1, e.g. bearing angle with respect to 3 nodal units. - Receiving terminal 1 serial number of a given slot.

Figure 4 shows a circuit arrangement of a detail of a long distance network as described previously. The multi-point cable network 4 which connects the terminals 1 to the interface unit 2 is also connected to a network monitoring unit 5 and a network monitoring database 6. Preferably, the terminals 1 have sufficient read-write memory for their flexible programmability. The configuration of the operation monitoring unit 5 differs from the terminal 1 only in that it is supplemented with an additional microcomputer equipped with a series of trial call routines. 6 operational monitoring and networking databases with a large memory.

In a preferred embodiment, 10-1000 terminal units 1 are connected to each cable network 4 or interface unit 2, while each node unit 3 serves 10-100 terminal units 2.

During operation of the telephone network according to the invention, the speech signal at the output of the acoustic converter 1.1 of the sending device 1 is digitally encoded by the A / D converter 1.2. The digital signal sequence representing the speech signal is supplemented by the routing unit 1.4 with path information stored in its memory, i.e., a digital path sequence for accessing the terminal 1 of the interlocutor. The routing unit 1.4 transmits the digital signal sequence thus supplemented, containing the path information at the front, to the time slot access unit 1.5. If the information is addressed to a terminal 1 which is connected to the same own interface unit 2 or to a multi-point multiplex line, it transmits the speech information to the multi-line multiplex line in the receiving slot of the other party's terminal 1.

If the other party's terminal 1 is not connected to its own interface unit 2, it places the digital signal complete with path information in the receiving slot of the interface unit 2 for the sending terminal 1. The information received from the time-multiplex multipoint line to the interface unit 2 is transmitted through the line adapter 2.1 and the time slot access unit 2.2 to the temporary information store 2.3, where it remains until the node unit 3 communicating with the interface unit 2 is located. The information is then transmitted to the node unit 3 via the time slot access unit 2.5 and the microwave transceiver 2.6. The transmission and reception time slots of the interface unit 2 are selected to coincide with the time when the electronically rotated high gain antenna of the microwave transceiver 3.1 in the node unit 3 is directed towards the information unit interface unit 2. The data exchange between the interface unit 2 and the node unit 3 and the node units is preferably carried out at a higher transmission rate than between the interface units 2 and the terminals 1.

The information received by the microwave transceiver 3.1 is transmitted to the address decoder 3.2 where it decodes and decodes the first few bits of the bit sequence for selecting the next path node. Address decoder 3.2 then sets the directional switch 3.5 and forwards the rest of the received bit sequence to the directional switch 3.5. Depending on the setting of the directional switch 3.5, the information may proceed either directly to another interface unit 2 or to another node unit 3.

HU 213 503 Β

If the information travels directly to another interface unit 2, it is placed in the temporary information store 3.4, where it is grouped by interface unit 2, waiting until the time slot access unit 3.3 transmits via the microwave transceiver 3.1 to the destination interface unit 2.

As the information proceeds to another node unit 3, it is stored in the temporary information store 3.14 or the temporary information store 3.24. From the temporary information store 3.14, through the time slot access unit 3.13, the microwave transceiver 3.11 enters one of the adjacent node units 3w. The information stored in the temporary information store 3.24 may pass through the time slot access unit 3.23 and the microwave transceiver 3.21 to the other adjacent node unit 3. Information from adjacent node units 3 is transmitted via microwave transceiver 3.11 or 3.21 to address decoder 3.12 and address decoder 3.22, respectively, where the information is interpreted and transmitted and the directional switch 3.5 is set up in the same way as for address decoder 3.2.

The information from the node unit 3 to the interface unit 2 passes through the microwave transceiver 2.6 and the time slot access unit 2.5 to the address decoder 2.7, where it disconnects the information location bits and groups it in the temporary information store 2.4 according to the destination terminals 1. . The time slot access unit 2.2 places the bits corresponding to the speech information in the receiving time slot of the receiving terminal 1 and transmits it via the line adapter 2.1 to the multipoint line.

On the multipoint line, the bit slot access unit 1.5 selects from the bit sequence received through the line adapter 1.6 the speech information received in its own receive slot which is transmitted to the acoustic converter 1.1 via the D / A converter 1.3.

The operational monitoring unit 5 monitors the functionality of the interface units 2 and node units 3 in the available time slots via the multipoint line, and places the malfunction information in the operational management and network database 6, while the flexible programmable terminals 1 routing units 1.4 in the operational management network 6 load current directions and / or operational programs.

The long distance telephone network according to the invention does not require central equipment and a backbone network, thus reducing the investment cost of the terminal. The transmission paths shall be provided at all times regardless of the utilization of the information transmission capacity. An unexpected advantage is that the network can be expanded with standardized units virtually unlimitedly, simply and inexpensively to the current demand, both in terms of terminals and supply area. Another unexpected advantage is that the network monitoring of the network can be easily accomplished by means of terminally connected equipment which, in the event of a transmission failure, can be immediately avoided. In a further preferred embodiment, the terminals may also be connected to the interface units to a network for cable television utilizing a frequency range below the frequency used by television broadcasting.

Claims (9)

PATENT CLAIMS An arrangement for implementing a remote telephone network comprising terminals without centers, characterized in that the arrangement comprises interface units (2) connected to a terminals (1) by a cable network (4) and a two-dimensional mesh topology switching field, wherein the acoustic transducers of the terminals (1) (1.1) are connected to the long-distance sales receiver j of the interface unit (2) via a routing unit (1.4), a cable network (4) and temporary information stores (2.3, 2.4), and intermediate time slot access units (1.5, 2.2, 2.5); a switch field comprising node units (3), which in the node units (3) comprise a directional switching device via a time slot access unit (3.3, 3.13, 3.23) and temporary information stores (3.4, 3.14, 3.24) and an address decoder (3.2, 3.12, 3.22). z (3.5) are connected. (Priority 04/04/1995) Arrangement according to claim 1, characterized in that the cable network (4) is composed of a multi-point multiplex line. (Priority 04/04/1995) Arrangement according to Claim 1 or 2, characterized in that the routing unit (1.4) is a microcomputer located in the terminal device (1). (Priority 04/04/1995) 4. Arrangement according to one of Claims 1 to 3, characterized in that the terminal units (1) also comprise an A / D converter (1.2) and a D / A converter (1.3) connected to the cable network (4). (Priority 04/04/1995) 5. An arrangement according to any one of claims 1 to 4, characterized in that the transceiver is a microwave transceiver (2.6, 3.1, 3.11, 3.21). (Priority 04/04/1995) 6. An arrangement according to any one of claims 1 to 3, characterized in that the node unit (3) comprises a variable directional transceiver. (Priority 04/04/1995) Arrangement according to Claim 6, characterized in that the antenna of the variable directional transceiver has an electronically rotated directional characteristic. (Priority: 04/04/1995) 8. Arrangement according to one of Claims 1 to 3, characterized in that one of the interface units (2) with the cable network (4) EN 213 503 Β units (5) and / or operational monitoring and network 60 databases (6). (Priority 04/04/1995) 9. Arrangement according to any one of claims 1 to 4, characterized in that the switching field with two-dimensional mesh topology has a hexagonal topology. (Priority 04/04/1995)