NO160957B - RADIO CALL PLANT. - Google Patents

Description

The invention relates to a radio paging system of the type stated in the introduction to patent claim 1.

A radio paging system according to the preamble to patent claim 1 is known from DE-OS 1 591 556. With this known radio paging system, it is a disadvantage that for the supply of a large area, thirty transmission frequencies must be made available.

For the supply of urban areas, it is from Technische Mitteilungen AEG-TELEFUNKEN 68, (1978) 6/7, pages 287 -

296 known to arrange synchronous co-frequency operation within an urban area. As a result, problems do not arise with neighboring cities, not even when the same transmission frequency is used there again, because the spatial distance is sufficiently large (page 287, right-hand column, third section). If this sufficient distance was not present, different transmission frequencies would again have to be made available, or when using the same transmission frequencies, the high-frequency synchrony would have to be provided via synchronous signal connections, and high costs would therefore arise (e.g. wiring costs or costs for distribution filters ).

A completely different way is described in Zeitschrift Elektrizitatswirtschaft, volume 80 (1981), booklet 6, pages 187 - 198. It is recommended there to remove the compulsion to have to use different transmission frequencies such as in DE-OS 1 591 556, by for the entire system uniform frequency in each of the transmitters is pre-treated with a highly stable oscillator (frequency normal). This is present as an independent building group in each stationary transmitter, and the carrier frequency is thus independent of external reference frequency sources and their availability (e.g. atmospherically disturbed normal frequency reception).

However, in the case of a large area to be supplied, and thus a large number of transmitters, the financial cost for the same number of frequency standards is very significant.

Based on this known technique and in particular the technique according to DE-OS 1 591 556, the purpose of the invention is therefore to provide a radio paging system for a region that is larger than a supply area for a transmitter, on the one hand having to manage with only a only transmission frequency, and on the other hand also the costs for synchronization connections or distribution filters or frequency standards must be as low as possible.

The above-mentioned purpose is achieved by means of a radio paging system which is characterized by the characterizing features specified in patent claim 1.

A radio call system according to the invention can also serve to supply an urban area or an entire region or even several regions.

The invention is based on the following considerations: When the region is divided into several supply areas with a respective exchange and the transmitters within each supply area work in synchronous co-frequency operation synchronized from their exchange, it is sufficient when the exchanges themselves are not synchronized from a main exchange and thus become dependent on the latter's operational capability with regard to synchronisation, but instead, due to their relatively small number, the centrals can be supplied with frequency standards at a small cost, and then in such a way that mutually adjacent supply areas which intentionally intersect at their edges, work in quasi-synchronous co-frequency operation. A workable compromise has thus been found between the required operational reliability on the one hand and the price for this operational reliability on the other hand.

The invention will be described in more detail below with reference to the drawing which shows a preferred embodiment.

Within the shown region there are several centers 1-5 with a respective assigned supply area, for example 6. In each supply area there are several transmitters, for example 7-13, for sending radio calls to mobile radio call receivers. Within each supply area 6, work is carried out in synchronous co-frequency operation.

Thereby, both modulation signals and synchronization signals are supplied to the transmitters 7-13 via two-wire or four-wire connections 7å - 13a, starting from the exchange 2. After equalizing the duration differences within the supply area, it is ensured that these transmitters simultaneously emit the call signals due to the modulation signals arriving from the exchange 2, and that the transmitters 7 - 13 due to the existing synchronous signal connections with regard to the high-frequency transmit-carrier frequency are mutually precisely synchronized. Techniques that are known in connection with synchronous co-frequency operation can be used in this connection.

A main switchboard 14 is assigned to several switchboards 1-5. However, this does not serve for high-frequency synchronization of the central stations 1 - 5, but only delivers the modulation signals via connections 15 - 19 (for example two-wire connections or directional radio lines) and via the central stations 1-5 to the transmitters, for example 7-13, for far-reaching simultaneous and phase rigid dispatch. The maturity differences within the region (and also within several regions) are thereby equalised. A high-frequency synchronization of the exchanges 1-5 from the main exchange 14, on the other hand, occurs: not or at most occasionally, for example daily, weekly or monthly. The centrals 1-5 contain, as frequency standards, very stable oscillators over a long period of time in order to achieve a quasi-synchronous co-frequency drive. You can here again go back to. known technique, for example as described in Zeitschrift Elektrizitatswirtschaft, volume 80 (1981), booklet 6, pages 187 ff. It is recommended there to design the frequency standards in exchanges 1 - 5 so stable that the frequency deviations between the individual supply areas amount to a maximum of 20 Hz for the carrier frequency used there. For this purpose, the relative frequency deviation for each of the frequency normals should be less than 2 x 10 per day in a temperature range from -20 to +65 C.

From the public telephone network there is access to the main exchange 14 via a transition point 20, so that a user of a public telephone over the shown radio call system can reach a mobile radio call receiver.

In a telephone network, several of the radio call facilities shown may be present, so that a transition takes place from the telephone network to one of several main exchanges, and more precisely to the main exchange where the desired mobile radio call receiver is currently staying, or to several main exchanges when the location is reached is not known.

Claims (2)

1. Radio call facility for sending out radio calls in a region with several mutually adjacent supply areas that mutually intersect at their edges and have stationary transmitters for sending out the radio calls to mobile radio receivers, CHARACTERIZED BY a) that within each of these supply areas there are several, over the supply area (6) distributed transmitters (7-13) and a central (2), and that there are synchronous signal connections to synchronizing devices in the transmitters for maintaining a synchronous co-frequency operation within each supply area, since due to modulation signals which are compensated in duration and which comes from the relevant switchboard, from the respective, associated transmitters at the same time mutually identical call signals can be sent out, b) that each switchboard (1-5) exhibits a frequency standard, so that mutually adjacent supply areas in relation to each other can be operated in quasi-synchronous co-frequency operation, and c) that a main switchboard (14) is arranged which transmits to the switchboards (1-5) modulation signals for simultaneous transmission via the transmitters. 2. Radio call system according to claim 1, CHARACTERIZED IN THAT a telephone network has access to the main exchange (14).