DE4438817A1 - Cellular, digital, mobile radio network - Google Patents

Abstract

Several base stations are each associated with a cell and consists of a transmitter, receiver and transceiver systems. To several base stations in allocated and base station control, and several controls are coupled to a switch coupling system, forming a link to another radio and/or fixed network. The handover of stations in the mobile network is controlled by the handover algorithm in each base station control. The interference weighting in different cells (1, 2) is carried out, based on network specific parameters within a computerised planning of the mobile radio network.

Description

The invention relates to a mobile radio network as a cellular digital radio network, with a A large number of base stations (BT1, BT2,... BTn), each of which is assigned to a cell and each consisting of a transmitter, a receiver as well as transmitting and Receiving devices are formed, furthermore with a base station controller (BSC), which are each assigned to a plurality of base stations (BT1, BT2,... BTn) and these control, with several base station controls (BSC) with one Switching connection system (SS) are connected, which is the connection to another Radio and / or landline (PSTN, ISDN) manufactures, and also in each Base station control (BSC) a handover algorithm is implemented that the Controls handover of mobile stations (MS1, MS2,... MSn) in the mobile radio network, whereby cell areas arise, in each of which a base station (BT1, BT2,.. BTn) is available.

An interference analysis has so far been carried out with such mobile radio networks, in which no or only a cell-specific evaluation of the interferences was carried out was and thus a non-optimal frequency allocation was obtained (R. Simon et al. "Computer-aided integrated radio network design for cellular radio systems", NTG- Conference, Munich, November 25-27, 1985).

The present invention is therefore based on the object of optimal To get frequency allocation as to which base stations which same frequencies can be assigned without adjacent Interfere with base stations.  

The task is given in the cellular network referred to above solved according to the invention in that a weighting of interference in different cells based on network-specific parameters within one computer-based planning of the mobile network is carried out. At a Allocation is weighted based on network-specific parameters the frequencies considered to be optimally improved.

According to other features of the invention it is proposed that in the determination the interferences calculated the interferences between two cells and then be evaluated.

In a further development of the invention it is provided that the traffic on the whole considered mobile network weighting for area elements of the same Importance is based on an equal weight. Taking into account that Interference in certain cases cannot be avoided for physical reasons this measure helps to standardize the overall network. The known principle of building on cell traffic within a cell leave.

According to other features, it is proposed that for a weighting of Interference with the probability of assignment to cells or similar network-specific parameters for surface elements of the same meaning the same Weight is taken as a basis. This advantageously means that the weighting does not need to be calculated continuously, but classes are formed that stand alone considered to represent surface elements of the same meaning, to which the same Weight is taken as a basis.  

A further development of the invention is that the weighting of the Interference based on network traffic, the likelihood of assignment Cells or similar network-specific parameters for surface elements of the same Importance is based on an equal weighting. Between two cells there are problems with the assignment probability which base station reaches can be. For this purpose, surface elements that, for. B. square areas of 400 × Can take 400 m, divided. For each surface element, the Field strength calculated. This field strength is from the respective antenna of a cell dependent. The size of the field strength is initially unknown.

The interferences are considered area by area. Known the field strength of two base stations, the interference of the surface elements can be calculated will.

A particularly advantageous combination is that the evaluation of Interference between two cells by weighting the interference is made.

It is also advantageous that the weighting of the interference between two cells based on network-specific parameters.

A further development of the invention results from the fact that the weighting of the Interference between two cells is normalized to network-specific parameters.

In this regard, further stipulations can be made that the Weighting of the interference between two cells is quantized and that the Weighting classes are assigned.

A particularly advantageous combination also arises in that the weighting of the interference between two cells normalized to network-specific parameters and are quantized and weight classes are assigned.

Further, the accuracy of the value-enhancing elements are given in that the weighting of the interference between two lines by a minimum weighting and / or a maximum weighting is limited.  

Another possible variation is achieved in that the weighting of the Interference between two cells is normalized to all network traffic.

This idea can now be expanded so that the weighting of interference between two cells on all network traffic and the Assignment probability to cells is normalized.

Finally, it is suggested that the weighting of the interference between two Cells is normalized to the combination of various network-specific parameters.

An embodiment of the invention is shown in the drawing and is in following described in more detail.

The only figure in the drawing shows two adjacent cells, between which, with appropriate frequency allocation, will cause the interference mentioned.

Between cells 1 and 2 there are problems of the assignment probability as to which base station BT1, BT2,. . ., can be reached. For this purpose, surface elements 3 , 4 , which are in reality square surfaces of z. B. 400 × 400 m, divided. For each surface element 3 ; 4 , the field strength is first calculated. This field strength depends on the respective antenna of a cell 1 , 2 . The size of the field strength is initially unknown.

The interferences are considered area by area. If the field strength of two base stations BT1, BT2 is known, the interference of the surface elements 3 ; 4 can be calculated.

The following relationships then result:
Traffic in cell 1 at the location of the interference: T1 (x) = 1
Traffic in cell 1 : Σ T1 (x) = ST1
Traffic in cell 2 at the location of the interference: T2 (x) = 1
Traffic in cell 2 : Σ T2 (x) = ST2 »ST1

Description of an embodiment:

a) If the weighting of the interferences in a cell is related to the entire cell traffic, different weights for the interferences are obtained for different cells with different cell traffic.
Weighting g1 of the interference in cell 1 : g1 = T1 (x) / ST1
Weighting g2 of the interference in cell 2 : g2 = T2 (x) / ST2

⇒ g1 ≠ g2

In the event that the surface elements, however, from radio or frequency planning point of view have the same meaning (g1 should be equal to g2), this is not taken into account when weighting the interference.

If, on the other hand, the weighting is based on the traffic of the entire mobile radio network under consideration, an equal weighting is calculated for cells of the same meaning.
Weighting g1 of the interference in cell 1 : g1 = T1 (x) / (ST1 + ST2)
Weighting g2 of the interference in cell 2 : g2 = T2 (x) / (ST1 + ST2)

⇒ g1 = g2

The same situation applies to a weighting of the interferences with the Allocation probability of cells or similar network-specific Parameters.

b) When weighting interference according to the previously known methods, the weight can assume any positive real number, as a result of which very small or large network-specific parameters produce very small or large weights.
Traffic at the location of the interference in the cell under consideration: T (x)

Traffic in the cell under consideration: ST
Weighting of the interference: g = T (x) / ST
⇒ if T (x) is small or large, then g is small or large.

From a radio or frequency planning perspective, however, it may be necessary a minimum or maximum weight for the interference is T (x) small or large, then g should be limited). This is achieved by using network-specific Parameters are quantized and weight classes for the interference are defined will. Traffic T (x) is used here as an example of network-specific parameters. considered.

Quantization:
T (x) <threshold 1
Threshold 1 <T (x) <threshold 2
Threshold 2 <T (x) <threshold 3
. . . .
Threshold n <T (x)
Weight classes:
Class I has weight gI
Class II has weight gII
Class III has weight gIII
. . . .
Class n has weight gn
⇒ if T (x) <threshold 1 , then weight gI from class I,
⇒ is threshold 1 <T (x) <threshold 2 , then weight gII from class II etc.

Claims (14)

1. Cellular network as a cellular, digital radio network, with a multiplicity of base stations (BT1, BT2,... BTn), which are each assigned to a cell and are each formed from a transmitter, a receiver and transmitting and receiving devices, and also with one Base station controller (BSC), which is assigned to and controls a plurality of base stations (BT1, BT2,... BTn), whereby several base station controllers (BSC) are connected to a switching connection system (SS) that connects to another radio and / or or fixed network (PSTN, ISDN), and a handover algorithm is also implemented in each base station controller (BSC), which controls the handover of mobile stations (MS1, MS2,... MSn) in the mobile radio network, which results in cell areas in which each have a base station (BT1, BT2,... BTn), characterized in that a weighting of interference in different cells ( 1 , 2 ) based on network-specific para meters within a computer-aided planning of the mobile network. 2. Mobile network according to claim 1, characterized in that the interference between two cells ( 1 , 2 ) is calculated and then evaluated in the determination of the interference. 3. Mobile network according to one of claims 1 or 2, characterized, that with respect to the traffic of the entire considered mobile network Weighting for surface elements of the same meaning has the same weighting is the basis. 4. Mobile network according to one of claims 1 to 3, characterized, that for a weighting of the interference with the assignment probability on cells or similar network-specific parameters for surface elements of equal importance, the same weighting is used.   5. Mobile network according to one of claims 1 to 4, characterized in that in the weighting of the interference on the basis of network traffic, the assignment probability to cells ( 1 ; 2 ) or similar network-specific parameters for area elements ( 3 ; 4 ) of equal importance the same weighting is used. 6. Mobile radio network according to one of claims 1 to 5, characterized, that the evaluation of interference between two cells by weighting of interference. 7. Mobile network according to one of claims 1 to 6, characterized, that the weighting of the interference between two cells is based network-specific parameters is made. 8. Mobile network according to one of claims 1 to 7, characterized in that the weighting of the interference between two cells ( 1 , 2 ) is standardized to network-specific parameters. 9. Mobile network according to one of claims 1 to 8, characterized in
that the weighting of the interference between two cells ( 1 , 2 ) is quantized
and that weighting classes are assigned. 10. Mobile network according to one of claims 1 to 9, characterized in that the weighting of the interference between two cells ( 1 , 2 ) is standardized and quantized to network-specific parameters and weighting classes are assigned. 11. Mobile network according to one of claims 1 to 10, characterized in that the weighting of the interference between two cells ( 1 , 2 ) is limited by a minimum weighting and / or a maximum weighting. 12. Mobile network according to one of claims 1 to 11, characterized in that the weighting of the interference between two cells ( 1 , 2 ) is standardized to the entire network traffic. 13. Mobile network according to one of claims 1 to 12, characterized in that the weighting of the interference between two cells ( 1 , 2 ) is standardized to the entire network traffic and the assignment probability to cells. 14. Mobile network according to one of claims 1 to 13, characterized in that the weighting of the interference between two cells ( 1 , 2 ) is standardized to the combination of different network-specific parameters.