DE3203678C2 - - Google Patents

Description

The invention relates to a single-frequency radio network according to the Preamble of claim 1.

A single-wave radio network with relay points and a radio center is known for example from DE 26 45 901 A1, wherein in for Common wave radio commonly used time equalization elements in the relay points are provided.

From DE 29 23 265 A1 is known in such Same wave radio network the relay points with an additional To provide radio, through which the relay points on a single frequency or a single frequency pair with each other and if necessary are connected to a control center. The Relay points exchange short over the additional radio Data telegrams about the respective reception quality of mobile Stations. The telegrams are compared with each other and based on the result, Relay point with the best reception quality alone Connection to the other relay points and the control center.

A single-wave radio network is known from DE-29 31 923 A1, at which is the connection from the relay points to a control center also takes place on a single frequency. The transmission power for this connection is regulated in the relay points in Dependence on the reception level of that from a mobile station comes from. In the control center, the HF Suppression effect a recipient selection of the largest Level falling relay point.

The object of the invention is to provide a single-frequency radio network To provide the preamble of claim 1 mentioned type which is a without additional organizational effort Broadband radio coverage allowed in larger areas.  

This object is achieved by the features specified in claim 1.

The Subclaims contain advantageous further developments or Embodiments of the invention.

The invention allows the same radio coverage Area of the size of several conventional radio networks, approximately the area of an average large government district. The Application lies particularly in the area of the authorities and Organizations with security tasks (BOS) where a uniform call channel or a local guide channel is required.

The invention is explained in more detail below with reference to the figures explained.

Fig. 1 and Fig. 2 show two versions of relay points according to the invention.

Fig. 3 shows a section of an inventive single-frequency wireless network.

The so-called "small" relay point according to FIG. 1 has a radio for a frequency pair f ₁ / fZ, which is common to the entire radio network, which extends over the area of several conventional single-wave radio networks. Mobile or fixed radio stations, e.g. B. control centers, transmit on frequency f ₂ . The programs are taken up from all accessible relay points with the receiver Ef ₂ switched to the transmitter Sf ₁ , and emitted again in the same radio. The transmitters Sf ₁ are stabilized with a highly precise frequency standard FN. Since the radio receives and transmits at the same time, an antenna soft W is necessary. The relay station also contains an intercom radio with antenna relay, for a frequency f ₃ . The signals recorded with the receiver Ef ₂ are also fed to the transmitter Sf ₃ , radiated via the common antenna, and recorded by all neighboring relay points with the receiver Ef ₃ , provided that these do not also transmit with Sf ₃ . Of course, the two radios can also be connected to separate antennas instead of the coupler shown in FIG. 1 to the common antenna. A feedback within the radio network is excluded due to the antenna relay on the additional radio. The signals received by the receiver Ef ₃ are fed to the transmitter Sf ₁ and transmitted in synchronism with the directly receiving relay points. Two conditions have to be met. 1. The transmitter Sf ₃ must also work in synchronous operation. They are preferably stabilized with the same frequency standard FN. 2. Between receiver Ef ₂ and transmitter Sf ₁ , a delay element LAG must be switched who the. This compensates for the following transit times: the transit time in the transmitter Sf ₃ , plus the transit time in the receiver Ef ₃ , plus an average value for the RF transit time between two neighboring relay points.

The so-called "large" relay station according to FIG. 2 contains, in addition to the radio devices already described, a further duplex walkie-talkie as a radio feeder from and to a control center. In a radio network with such "large" relay points, all connections run via control points. The signals received by the receivers Ef ₂ or Ef ₃ are fed to the transmitter Sf ₄ and transmitted to the control center by radio. There is accordingly DE-OS 29 31 923 on the RF suppression effect, make a receiver selection and the signals are then sent on the frequency f ₅ to all relay points in the area of the relevant control center. The relay points in turn emit the transmitter Sf ₁ and - unless the receiver Ef _{3 had} addressed the transmitter Sf ₃ in the neighboring areas. The transmitter Sf ₄ is also stabilized with the frequency standard FN. Runtime elements LAG compare the different possible routes so that all transmitters Sf ₁ transmit synchronously in the entire radio network.

The antennas of the feeder and / or the two-way radio devices Sf ₃ / Ef ₃ can optionally be designed as directional antennas.

According to a development of the invention, signal tone evaluators SA1 and SA2 are provided in the relay points, via which the two-way radio devices Sf ₃ / Ef _{3 are switched on} by sound signals or coded signals only when required. e.g. B. from a control center.

Fig. 3 shows a section of a single-wave radio network according to the invention with relay points R, control centers control and mobile radio stations MS.

A mobile station MS in the left area of the figure transmits on frequency f ₂ . One or more relay points R receive this consignment with the receiver Ef ₂ and forward it via the transmitter Sf ₄ to the responsible control center Leit. This sends with Sf ₅ to all relay points in their area. There, the consignment reaches the transmitters Sf ₁ and Sf ₃ via the receiver Ef _5. It is picked up in the neighboring areas by the receivers Ef ₃ and reaches the corresponding control centers via the feeder (on the frequencies f ₄ / f ₅ ) and again in all relay points of these areas, where it is emitted synchronously via the transmitter Sf ₁ . The broadcast can thus be received by mobile stations MS in the entire radio network with a receiver Ef ₁ .

The operating frequencies f ₁ to f ₅ can be chosen freely and, if necessary, also be switchable.

Claims (5)

1.Single-wave radio network with fixed and mobile radio stations and relay stations which use a frequency pair (f ₁ / f ₂ ) which is common to several neighboring radio networks and whose transmitters operate in single-wave mode and which each additionally have an intercom radio operated at a further common frequency (f ₃ ), Via which radio signals received with the receiver (E f ₂ ) of the respective relay station are forwarded to other relay stations, characterized in that the _two-way radio devices also work in synchronous operation and that in the relay stations (R) in the connecting lines between the receiver (Ef ₂ ) and Transmitter (Sf ₁ ) delay compensation elements (LAG) are connected with such a delay time that the transmitters of all neighboring radio networks transmit synchronously. 2. single-wave radio network according to claim 1, characterized in that the relay points (R) in addition to the two-way radio have a suitable for single-wave radio duplex radio (Sf ₄ , Ef ₅ ) as a radio feeder to control centers (control), and that all connections via the control centers (control ) to run. 3. single-wave radio network according to claim 1 or 2, characterized in that the antennas of the duplex radio devices (Sf ₄ , Ef ₅ ) and / or the alternating radio devices (Sf ₃ , Ef ₃ ) are directional antennas. 4. single-wave radio network according to one of the preceding claims, characterized in that the relay points (R) beep evaluators (SA1, SA2), via which the two-way radios (Sf ₃ , Ef ₃ ) can be switched on or off. 5. single-wave radio network according to one of the preceding claims, characterized in that all transmitters (Sf ₁ , Sf ₃ , Sf ₄ ) of a relay point (R) are stabilized with a common frequency standard (FN).