DE3135231A1 - Information transmission system - Google Patents

Abstract

The invention relates to an information transmission system having fixed and mobile transmitting and receiving stations. The fixed stations are each connected via a dedicated optical fibre to a switched telephone network, and exchange speech, address and identification in coded form in statistically distributed pulse packets by radio. The fixed stations all operate using a fixed carrier frequency for the transmitters and another fixed carrier frequency for the receivers. <IMAGE>

Description

Messaging system

The invention relates to a communication system according to the preamble of claim 1.

State of the art Such a communication system is from DE-AS 21 44 676 known. In this system, the fixed transmission and Receiving stations through a broadband transmission medium made of fiber optic cables connected with each other. The radio transmission of the messages takes place in the code division multiplex method.

Object The invention is based on the object; a messaging system to tackle the type mentioned at the beginning, which allows a very large number of participants and reduces the size and cost of the mobile stations.

Solution This problem is solved with those specified in claim 1 Means. Refinements can be found in the subclaims.

Advantages The invention provides a communication system high quality at low cost that is virtually saturation free and one has low frequency requirements. At the same time you get by the way without any further Effort to locate a vehicle.

Description The invention is explained below with reference to drawings an exemplary embodiment explained in more detail. The figures show: FIG. 1 a linear one Network and FIG. 2 schematically shows the overall structure of the system; 3 schematically the structure of a control center and FIG. 4 is a block diagram of a distance warning radar in the case of a mobile transmitting and receiving station.

In Fig. 1 is a line network of the communication system shown, for example, along roads, highways or the like Traffic routes can be built. 1 are stationary transmitting and receiving stations referred to, the radio stations with mobile send and receive 2 messages can exchange. The stationary transmitting and receiving stations 1 are each over an electro-optical converter connected to its own optical waveguide, which are summarized are shown as an optical fiber bundle 3 or optical cable in FIG. That The fiber optic bundle is connected to a central unit, not shown connected, in which the connection to the telephone network takes place. The distance between the stationary transmitting and receiving stations 1 is between 100 m and 10,000 m.

The radio transmission between the stationary and the mobile transmitter and receiving stations is done with mm waves, for example at 35 GHz and one Transmission power that is just sufficient, even under the most unfavorable conditions Establishing and maintaining a connection. The stationary transmitting and receiving stations 1 and then also the movable transmitting and receiving stations 2 are all working with the same carrier frequencies. The exchange of messages takes place digitally with statistical distributed pulse packets that contain the language, address and identifier in coded form. The statistically distributed pulse packets are generated in that the messages in digital form compressed in time when sending and decompression after receiving be subjected. In the resulting time gaps on the transmission path further messages from other stations can be transmitted. The pulse packets can for example 30 bits for the phone number, 10 bits for the language and 25 bits for the Identifier included.

There are a lot of stationary send and receive stations in the messaging system 1 available, so can each optical fiber 4 multiple stations 1 in one Sub-center can be summarized. The sub-centers are then with the center connected, and this connection can be by optical cables, or cables preferably Directional radio take place.

In Fig. 2 is a block diagram of the entire structure of the message end transmission system shown.

The mobile transmitting and receiving stations 2, only one of which As shown, a telephone 5 includes a transducer 6 and a transceiver 7 to which an antenna 8 is connected.

Used as a transceiver for a moving station in the vehicle for reasons of collision protection, an existing distance warning radar is provided, then exists - as also indicated in Figure 2 - the movable station again from a telephone 5, a transducer 6 and the collision protection radar 28. Den The relationship between 5, 6 and 2f is shown in FIG. 4.

The stationary transmitting and receiving stations 1, of which only three are shown, each have an antenna 9, a transceiver 10 and a already mentioned electro-optical converter 11, which is connected to the optical waveguide 4 connected.

All optical fibers 4 of this group of stationary transmitting and receiving stations 1 are led to a sub-center 12, the converter 13, memory 14 and converter 15 has for the subsequent transmission.

In the case of a directional radio transmission, the converter 15 is connected Directional radio transceiver 16 with an antenna 17. The number of substations depends on the size of the network of the communication system.

The control center has antennas 18 corresponding to the directional radio links from the sub-centers to which a directional radio transceiver t9 is connected. A converter 20 converts the message stream so that the connection to and from Telephone network is possible.

During the on-time of the mobile transmitting and receiving devices 2, these send their identification in a statistically distributed manner. This achieves that it is known where the movable transmitting and receiving stations 2 are located and via which stationary transmitting and receiving station 1 they can be reached. In Fig. 3 is a Central shown as a block diagram, and on it is to establish the connection and the location of the mobile transmitting and receiving stations explained.

Each constantly sent identifier is transmitted via a maximum of three stationary send and receiving stations 1 receive simultaneously. These on the optical fibers 4 incoming signals reach the control center via a modulator-demodulator multiple 22 and a manifold 23 in a memory 21. As a result, in the memory 21 always one storage location K1 for the identifier and three storage locations 01 to 03 occupied for the location of the sending station 2. This allocation of memory locations 01 to 03 changes constantly when the moving transmitting and receiving station emotional. By means of a location checking circuit 24, the changes in the occupancy of the storage locations O Direction of movement and speed of the movable transmission and receiving stations 2 are determined.

Should be telephoned from the mobile transmitting and receiving station 2 the desired subscriber number along with your own ID sent out.

After conversion, this subscriber number is stored in the memory 21 written in a memory location TN, and the call arrives via a distribution manifold 25 into the telephone network. At the same time will the call also to transmitting back to the calling sending and receiving station 2.

When the called party picks up and starts speaking, will its language via the distribution manifold 25 and an analog / digital and digital / analog manifold 26 (A / D, D / A multiple) digitized into a memory location in participant language TS registered; after that, the storage space is then with a statistically fluctuating sequence TS read out again and via the distribution manifold 23 and the modem manifold 22 connected to the associated optical fiber 4 and thus to the movable transmission and receiving station 2. The correct fiber optic cable is determined by the location testing circuit 24 determined. The language coming from the mobile transmitting and receiving station 2 is written into a memory location AS after appropriate demodulation.

It is read out again in such a way that a continuous stream of messages arises, which is via the A / D-D / A multiple 26 and the distribution multiple 25 to the subscriber is transmitted in the telephone network.

When the connection is terminated, the memory locations are in memory 21 TN, TS and AS deleted.

Will a subscriber of the switched telephone network with a mobile Call the sending and receiving station, then this chooses the Special number of the headquarters of the message transmission system and then afterwards the number of the mobile sending and receiving station. In memory 21 in the headquarters it is checked whether the desired number is available as an identifier by the storage locations O can be queried. If a corresponding identifier is not found because the The sending and receiving station is not switched on or because they are outside the network this message transmission system is, then, for example, a certain Announcement sent to the calling subscriber.

If the corresponding identifier is found, a second one becomes associated Storage location K2 and one storage location TN occupied. Now the call goes over that of the location checking circuit 24 determined optical waveguide addition. Will the conversation request received in the mobile transmitting and receiving station, then the Connection as described above.

When the call is ended, the storage locations K2, TN, TS and AS deleted again.

If in the telephone network a digitized transmission of the messages takes place, the A / D-D / A multiple 26 can be omitted, which is indicated by a dashed line 27 is indicated.

With the message system described are in addition to communication between the participants also two for example the following services possible: - locating and identifying the mobile transmitting and receiving stations; - Location-based information transfer from the control center to the mobile transmitter and receiving stations; - Automatic calculation of usage fees for traffic routes.

In Figure 4, the distance warning radar 28 is in a block diagram and the interconnection with the telephone 5 and the converter 6 is shown. That Range warning radar 21 has an antenna and an RF part, a signal processing part and an ad. In the RF part, a modulator controls its signal from a Synthesizer in the signal processing part and from the converter 6 receives a transmitter that A Gunn oscillator. The transmitter is connected to the antenna via a circulator connected, which is also connected to a mixer via the circulator. Of the Mixer sets the received signal in the video frequency range LLm and is there via a video preamplifier to the signal processing unit; it continues. To the video preamplifier the converter is also connected. The processed signal arrives at the Display of where the raw radar data and a warning display are located. The warning indicator can also trigger an audible alarm.

The distance warning radar can be operated with continuous wave modulation or with pulse modulation work.

Claims (8)

Claims 1 Message transmission system with stationary transmission and t / receiving stations erected along roads and connected to a switched telephone network are connected, and with mobile transmitting and receiving stations that use radio can exchange messages with the fixed stations, one permanently installed Network of fiber optic cables between the stationary transmitting and receiving stations is provided to which the stationary stations are connected at relatively short intervals are all with one fixed carrier frequency for the transmitter and another fixed carrier frequency for the receiver work, and at which the radio transmission of the messages takes place digitally, characterized in that the stationary transmission and Receiving stations (1) each with their own fiber optic cable (4) with a control center, in which the connection to the telephone network takes place, are connected and that the Radio transmission between the fixed and mobile stations in statistical terms distributed pulse packets in coded form language, address and identifier he- keep. 2. Message transmission system according to claim 1, characterized in that that the distance between the stationary transmitting and receiving stations (1) along of roads is between 100 m and 10,000 m. 3. Message transmission system according to claim 1, characterized in that that the optical waveguide (4) each of some stationary transmitting and receiving stations (1) in one of several sub-centers (12) are combined with the Central are connected. 4. Message transmission system according to claim 3, characterized in that that the transmission between the sub-centers (12) and the center by radio links he follows. 5. Message transmission system according to claim 1, characterized in that that the mobile transmitting and receiving stations (2) are statistically distributed constantly send your identifier. 6. Message transmission system according to claim 5, characterized in that that the center in a memory (21) has a location memory (0) in which the mobile transmitting and receiving stations (2) based on their transmitted identifiers and according to the stationary transmitting and receiving stations that receive these identifiers (1) are written and that a location checking circuit (24) is present which according to the content of the location memory (0) the connection between the individual Optical fibers (4) and the telephone network producing distribution manifold (23) control. 7. Message transmission system according to claim 1, characterized in that that the radio transmission takes place in the mm wave range. 8. Message transmission system according to claim 1, characterized in that that the radio transmission by means of collision protection in the mobile transmission and receiving stations used distance warning radars, which are also in the mm wave range work.