DE4432928C2 - TDMA mobile radio system - Google Patents

Description

The invention relates to a TDMA mobile radio system at least one fixed radio station (BTS) and several be mobile stations and radio transmission channels for the Si gnalization and voice transmission (BCCH and TCH).

Frequency hopping is used in transmission systems ping) is used to minimize interference effects. The use in mobile radio systems includes two effects, namely um to limit the multipath and co-channel interference Zen. TDMA systems are able to set the frequency between two to change active parts of the bursts. Here is the implementation tion in the mobile station is easier because of a pulse / pause ratio nis that gives enough time for the vote the mobile station to a new frequency during idle time. Implementing the base station (BTS) is more difficult. Each the burst of a TDMA frame can be active; therefore remain only the guard periods between the Bursts. This is in a base station with frequency hopping too consider.

The GSM mobile radio system has certain requirements the GSM system design. From the perspective of a mobile station the carrier that broadcasts the BCCH (broadcast channel = control channel) a cell, does not work in TDMA mode. The Mobilsta tion requires a beacon frequency per cell for the implementation All idle mode processes (cell selection, location up- date), also for the correction of the MS frequency offset and the Synchronization of the mobile station on the cell. This requires that the wearer is constantly present (CW mode = continous wave) has to be with the cell-specific maximum power and does not perform downlink performance monitoring. Time slots,  that are not filled in traffic, with Scheinmu filled in star.

The BTS implementation enables two options, namely Baseband hopping and synthesizer hopping.

Baseband hopping is implemented by dividing the trans ceivers (TRX) in two parts. Between the two parts of one Transceivers is a unit (multiplexer) arranged to the division of the baseband signal to different RF parts. The The advantage is that all RF parts with fixed frequencies work, d. H. there is no difference in complexity ver compared to a non-jumping application. This fixed fre Frequency assignment allows the use of frequency selective Antenna combining facility.

Synthesizer hopping does not require a base split band and radio frequency RF. The transceiver changes its fre sequence from time slot to time slot. This requires a high level Complexity in the RF hardware. The synthesizer must be used during the Protection time between two active parts of the bursts one Fre Carry out a change of frequency. For this, the performance must be rampant tig fall to temporarily contaminate the spectrum to prevent the power from spreading over the frequency band other.

As already stated above, it is GSM specific Carrier carrying the BCCH signal does not allow its Fre to switch quenz. Traffic channels (TCH) that are on this Bearers cannot participate in frequency hopping, unless hopping is done in the baseband. in the In the case of synthesizer hopping, the carrier of the BCCH may not on Participate in hopping. As a result, the area supply falls the carrier looks different. Baseband hopping is in turn  ineffective with a small number of channels, since the number of available standing frequencies is too small.

So in small base stations with a small number of channels Baseband hopping ineffective. On the other hand, synthesizer Hopping in the GSM system is not allowed for all carriers. The fol ge are different coverings per carrier and theirs assigned channels.

From WO 93/20625 is a base station for a cellular Fre quency-hopping TDMA radio communication system known to has at least two transmitters, each at least least contain a transmitter with different antennas are connected.

The invention has for its object to provide a solution ben for a good supply of space for base stations.

This task is the beginning of a mobile radio system written type solved by a combination of baseband Hopping and synthesizer hopping, with baseband hopping the voice channels are distributed among the different carriers and at least one of the carriers over time its frequency changes.

With a small base station with two carriers, this can be done in the way that the baseband hopping a traffic channel (TCH) cyclically distributed to both carriers and one of the both carriers also change its frequency over time different.

The invention based on one in the drawing illustrated embodiment explained in more detail.

In the figure, the combined synthesizer / baseband hopping architecture for a small base station BTS is shown in the block diagram. The circuit parts for the Ra diofrequenzen RF1 and RF2 with 1, the circuit parts of the baseband BB1 and BB2 with 3 and the intermediate multiplexer with 2. The circuit parts 1 for the Ra diofrequenzen RF1 and RF2 are connected to an antenna 4 , a Syn thesizer 5 is connected to the circuit part for the radio frequency RF2. The signal paths of the individual time slots T0, T1, T2 and T3 are drawn for a frame in a dotted line, a dashed line, a dashed line with double points inserted between them and a dashed line with individually inserted points. The signal path in the time slots T0 and T2 runs between the radio frequency part RF1 and the baseband part BB1, the signal paths of the time slots T1 and T3 between the radio frequency part RF2 and the baseband part BB1. In the following frame, the assignment of the time slots is interchanged by the multiplexers. Thus, voice channels TCH, which are assigned to a time slot, are cyclically distributed between carriers capable of hopping and those unable to hopping. The frequency allocation for a voice channel takes place, for example, in time slot number 2, which is represented over time in the following way: fα fκ fα fε fα fκ fα fε ...

Each voice channel (TCH) of such a base station is able to perform the hopping. For this purpose, a voice channel is cyclically distributed to the two carriers of the 2-carrier base station by base band hopping. It is a periodic sequence and every second time slot is assigned the same frequency. This also shows the frequency sequence described above, in which the frequency fα is repeated at every second position. In addition, one of the two carriers (in the exemplary embodiment the carrier for the radio frequency RF2) is changed over time by the synthesizer 5 . These are the frequencies fκ and fε, which are repeated at every fourth position of the frequency sequence shown above. The frequency sequence can also be larger, that is to say use the maximum remaining frequency supply of the system.

This configuration allows the use of synthesizer / frequency hopping without the disadvantage of different coverage areas for each carrier. The voice channels have the same jump option, regardless of their assignment to carrier 0 or carrier 1 . Compared to pure baseband hop ping, the statistical distribution is better because the number of frequencies that can be used is greater than two.

Claims (2)

1. TDMA mobile radio system with at least one fixed radio station (BTS) and several mobile stations (MS) and radio transmission channels for signaling and voice transmission (BCCH and TCH), characterized by a combination of baseband hopping and synthesizer hopping, the baseband Hopping the voice channels (TCH) distributed over the different carriers and at least one of the carriers changes its frequency over time. 2. Mobile radio system according to claim 1, characterized in that in a base station with two carriers, the baseband hop Ping a voice channel (TCH) cyclically distributed to both carriers and one of the two carriers additionally its frequency over the Time changed.