WO2001091347A1 - Mobile radio system with synchronised base stations - Google Patents

Abstract

Amongst other things, a time synchronisation of the base stations (1, 2) is provided for novel mobile radio standards. A direct synchronisation by radio, by control cable or by telephone or data networks leads in many cases to significant problems. According to the invention, synchronisation of the base stations may be achieved in a manner analogous to the conventional centralised ripple control system, whereby synchronisation commands are transmitted in the power supply network (11, 13) by network superimposition.

Description

description

Mobile radio system with synchronized base stations

The invention relates to a mobile radio system with radio base stations distributed over the service area, with which mobile stations can connect and which are connected to a power supply network for energy supply. Furthermore, the bass stations can be connected individually or in groups with base station

Control stations connected, at least some of the base stations being time psychronized at least in groups.

In the context of current efforts to universalize mobile radio systems and to accelerate the services that can be carried out, further developed standards are being considered. A system with the name EDGE is in the definition phase, which is being discussed in two variants, namely ETSI-EDGE ("EDGE Classic") and "EDGE Compact". The "EDGE Compact" version should manage with a bandwidth of no more than 600 kHz. However, one of the technical requirements for this is that the radio base stations are time-synchronized (ETSI SMG2 orking session on EDGE, August 24-27, 1999, Paris, TDoc SMG2 EDGE 322/99). For this purpose, the base stations must not only receive clock information, but precise time information.

A solution that may be obvious for this, namely the control of the synchronization via a respective base station control station, has proven to be unfavorable for the following reasons. First, the corresponding interface, the so-called A _b i ₃ interface, is based on a grid with 125 μs. A frame can therefore travel around i 125 μs. Second, the control stations can be connected in a loop or in a star configuration. In the case of loop switching, the control stations cause time-variable delays due to an implemented elastic data buffering. In the case of the star Circuit are point-to-point connections between the control station and the individual base station, which are rented by an operator, so that their properties are mostly unknown. For example, an intermediate amplifier can be interposed in the line, which also generates unknown time-variable delays by means of an elastic buffer.

A known solution is the use of a special synchronization module, e.g. B. a GPS receiver or a DCS77 receiver at the base station, which issues synchronous commands to them. However, this also proves to be problematic in many circumstances. The GPS receiver requires an antenna location with the best possible 360 ° view to receive satellite signals. This is usually only possible on the roof of buildings. For high-rise buildings, you sometimes get very long antenna cables if the receiver is integrated in the control station, or long connection cables if they are installed externally. In particular for indoor house systems with small cells, problematic installations result. In the subway area in inner cities, the outdoor installation of the GPS antenna is usually impossible due to the long distances. If each base station is assigned its own time signal receiver, there are correspondingly many time signal receivers with a corresponding number of antennas or antenna lines / connecting lines for each floor of a high-rise building in the case of small cells supplied by a microbase station, while when using a central time signal receiver there is one for each base station special line for the synchronous commands must be laid.

The invention is therefore based on the object of providing a system for synchronizing the base stations which can be implemented easily and inexpensively and operates largely without problems. The object is achieved by the features of a mobile radio system according to claim 1. Preferred embodiments of the invention are the subject of the dependent claims.

According to the invention, the time synchronization of the base stations takes place by means of synchronous commands which are transmitted by network overlay in the power supply network.

The basics of the corresponding technology have long been known, in particular in connection with ripple controls (e.g. DE-AS 21 24 870, 23 04 734, 24 56 344; DE-PS 197 14 386). Systems are also known in which ripple control signals are transmitted synchronously by several transmitting stations and the transmitting stations themselves are synchronized by corresponding signals (DE-AS 19 51 444, 25 31 470). The corresponding

Signal transmission through network overlay is possible both single-phase and three-phase (DE-AS 21 33 180). The implementation of corresponding synchronization systems in mobile radio systems is therefore not opposed to any fundamental problems.

Various coded switching commands, for example for switching on or switching off certain loads, can be superimposed on the industrial frequency alternating current. The synchronous commands intended for the base stations therefore require a sufficient length in order to make them clearly identifiable. In order to arrive at a defined synchronous point in time, a certain point of the synchronous command for the synchronization must therefore be defined, for example a synchronizing pulse following a digital identification pulse sequence or, in the case of even higher demands on the timing, a given edge of this synchronizing pulse.

In the case of networks of conventional size, the use of a plurality of timers is required, which initiate the synchronous commands into the power supply network at different locations and which in turn are time-controlled by a central timer, for example by radio. If you start from a or three-phase supply of the base stations by 20 kV / 230 V transformers, the timers with a respective time signal pfanger, for example a GPS receiver, are each on the secondary side, ie the 230 V side of the transformers. All base stations that are powered by the same transformer can be synchronized by a single timer. This saves an otherwise much higher number of timers and the effort for own time signal lines between the timer and the base station.

From the timers to the base stations, however, the synchronous commands require a runtime that is dependent on the respective installations, in particular the line lengths. This runtime must be measured each time the base stations are installed and their compensation must be set, with the aid of adjustable time delay elements in the way of the synchronous commands. The timing elements are preferably positioned in the individual base stations after a synchronizing command decoupling point located in the base station. For several base stations that have the same signal paths due to the local architecture, however, a runtime adjustment on the feed side could also be considered.

Further details, advantages and developments of the invention result from the following description of an exemplary embodiment with reference to the drawing. The only figure shows schematically a section of the fixed installation of a mobile radio network.

The area of the network shown schematically in the drawing comprises a first number of base stations 1 with a smaller line, with single-phase AC power supply, and a number of base stations 2 with higher power and three-phase AC power supply. The base stations are symbolically represented as radio towers, especially in the case of smaller stations Operation of smaller cells, which are only parts of the building, for example, is only a transmitter circuit with an antenna.

The base stations are controlled individually or in groups by a respective base station control station 3, and these stations are connected to a fixed network with a switching and operator network 4, according to the local conditions and the network standard. An interface is defined between the base stations 1, 2 and the control stations 3, which is usually referred to as A _b ι _S.

In the drawing, as far as the power supply is concerned, only that of base stations 1 and 2 is shown. The base stations 1 are supplied with a single phase, that is to say via two current conductors, from a transformer station 10 via a power supply network 11. The base stations 2 are supplied with three phases from a transformer station 12 via a power supply network 13.

Base stations 1 and 2 are synchronized with each other and with the entire network of the system. The synchronization is based on a schematically represented central timer 17, which is provided with a transmitter and reaches decentralized timers 19, 20 via radio waves 18, which are assigned to the transformer stations 10 and 12, respectively. The timer 19 assigned to the transformer station 10 is connected to the power supply network 11 for a single-phase initiation of synchronous commands, and the timer 20 assigned to the transformer station 12 is switched to a three-phase initiation of the synchronous commands into the power supply network 13. The introduction is in each case an initiation circuit 21. The respective synchronous command is then in the power supply network with a deviating, generally higher frequency than the industrial frequency of 50 or 60 Hz

Alternating current is superimposed and contains a digital symbol sequence modulated as a characteristic pulse sequence. The characteristic pulse sequence of the synchronous command is recognized at base station 1 or 2 and extracted with the aid of a decoupling circuit 24. The entire synchronous command or at least the separated synchronizing pulse now passes through an individually adjusted time correction circuit 25, which essentially contains a timing element which compensates for the various delays caused by the running time on the power supply network and any delay points present there, namely in particular to one for all base stations 1 and 2 same total term expands. The resulting synchronizing pulse occurring at all base stations at the same time then carries out the synchronous time control of the base stations in a manner known per se.

Claims

claims

1. Mobile radio system with radio base stations (1, 2) distributed over the service area, with which mobile stations can connect and which are connected to a power supply network (11, 13) for energy supply and also individually via a respective interface (A _bιs ) or connected to several with base station control stations (3), which in turn are connected to a switching system (4), and with at least group time synchronization of at least some of the base stations, characterized in that the time synchronization of the base stations (1, 2) is carried out by synchronous commands which are transmitted by network overlay in the power supply network (11, 13).

2. Mobile radio system according to claim 1, characterized in that the synchronous commands consist of a characteristic pulse sequence and a subsequent synchronizing pulse.

3. Mobile radio system according to claim 1 or 2, characterized in that the synchronous commands in the power supply network (11, 13) from locally located at different locations timers (19, 20) are initiated, which in turn is time-controlled by a central timer (17) are.

4. Mobile radio system according to claim 3, characterized in that the synchronous commands emitting timers (19, 20) from the central timer (17) via radio (18) are time-controlled.

5. Mobile radio system according to claim 3 or 4, characterized in that the synchronizing commands emitting timer (19, 20) via initiation points (21) with the

Power supply network (11, 13) are connected, the secondary are on the side of the last power transformer (10, 12) of the power supply network.

6. Mobile radio system according to claim 5, characterized in that in each case a single timer (19, 20) sends the synchronous commands to all the base stations (1, 2) connected to the same secondary connections of the respective network transformer (10, 12) on the secondary side.

7. Mobile radio system according to one of claims 1 to 6, characterized in that adjustable Zeitlaufglied (25) are arranged in the path of the synchronous commands.

8. Mobile radio system according to claim 7, characterized in that the timing elements (25) in the individual base stations (1, 2) are positioned after a synchronizing command decoupling point (24) located in the base station.