Method of allocating frequency bands to different cells, and...

Multiplex communications – Communication over free space – Having a plurality of contiguous regions served by...

Reexamination Certificate

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Details

C370S337000, C370S347000, C455S063300

Reexamination Certificate

active

06233229

ABSTRACT:

BACKGROUND OF THE INVENTION
The present invention relates to a method of allocating available frequency bands to different cells in a TDMA cellular radio system wherein at least some of the receivers within the system use interference cancellation methods to cancel the effects of co-channel interference in a desired signal.
As far as narrow-band cellular radio systems are concerned, co-channel interference is one of the most significant factors limiting system capacity. The term, co-channel interference, refers to interference in the desired signal caused by signals transmitted in nearby cells on the same frequency. For this reason, cellular radio systems have conventionally been designed so that the same frequency is only used in cells located at a sufficient distance from each other, whereby the interfering signals remain within acceptable limits as a result of propagation attenuation of the signals. This leads to a re-use pattern in the cellular structure. For example, re-use pattern seven is one in which one seventh of all available frequency bands is allocated to every cell, and the same frequencies are re-used at a relative re-use distance of 21 from each other.
The system capacity is to be increased, the need arises to shorten the re-use distance without, decreasing transmission quality. Conventionally, an increase in system capacity has been achieved by decreasing cell sizes and reducing transmission power levels. Another method for solving the problems concerning capacity is to keep up with the fast development of digital signal processing, and utilize the interference cancellation algorithms developed. Cancelling cancellation of co-channel interference in the receiver enables a more efficient frequency re-use within the network.
In the present-day cellular radio systems, co-channel signals are approximated in the receiver as a random additive white Gaussian noise. This approximation is sufficient as long as interfering co-channel signals are not too strong. It is an aim of conventional cell planning to ensure this by a sufficient re-use distance.
In interference limited cellular radio systems, however, co-channel interference is typically of a deterministic nature, suggesting that it should be possible to cancel, at least partly, its effects on the desired signal.
Previously, interference cancellation methods have been developed for use in code division multiple access (CDMA) systems, which are interference limited type. It is, however, much more difficult to apply interference cancellation techniques to TDMA systems. The Finnish patent publication 944736, discloses a method for utilizing interference cancellation methods in TDMA systems.
Thus, interference cancellation methods are based on detecting some interfering signals and canceling their effect in the desired signal. The interference cancellation algorithms function better, the more accurately the interfering signals can be detected. Hence, the most advantageous situation for implementation of interference cancellation algorithms is where the receiver is receiving, along with the desired signal, a number of interfering signals which are clearly stronger than the other sources of interference, and can be canceled by the algorithms.
In frequency and cell planning of conventional cellular radio systems, however, the aim is that all the interfering signals will be as weak as possible from the point of view of the desired signal. As a result, interference cancellation methods do not function in an optimum manner in systems designed by conventional methods.
SUMMARY OF THE INVENTION
It is an object of the present invention to provide a cellular radio system in which the use of interference cancellation methods is taken into account at the planning stage of the system, and in which an efficient application of such methods, as a result of network planning carried out according to the invention, enables a higher capacity than what has been possible heretofore.
This object is achieved by a method set forth in the foregoing background section. The available frequency bands of the cellular radio systems are allocated to different cells that in each cell so at least one co-channel signal interfering with the desired signal is significantly stronger than other co-channel interfering signals.
The invention further relates to a TDMA cellular radio system which includes in each cell, at least one base station communicating with the subscriber terminal equipments within its service area, is allocated a group of frequency bands, and at least some of the receivers of the system use interference cancellation methods to cancel the effects of co-channel interference in the desired signal. In the TDMA cellular radio system in accordance with the invention, the available frequency bands in each cell of the cellular radio system have been selected so that at least one co-channel signal interfering with the desired signal is significantly stronger than the other co-channel interfering signals.
According to the basic idea of the method of the invention, the available frequency bands of the cellular radio system are allocated to different cells so that several groups of adjacent service areas are formed in the system, each group uses the same frequency band within the service areas. Thus, for each group, a situation is intentionally created in which one co-channel signal interfering with the desired signal is significantly stronger than co-channel interfering signals originating in other signal sources. This enables an efficient application of interference cancellation algorithms, which leads to the terminal equipment and the base stations being capable of operating at a lower signal to noise ratio, but at the same transmission quality as before.
As a result of use the method according to the invention, a better sensitivity of the receiver is achieved. It is possible to utilize the improved sensitivity in a multitude of ways. The increase in the capacity of the cellular network was already mentioned above. In addition, it is possible to improve the quality of the connections as a result of the receivers tolerating a higher level of interference. Furthermore, cell sizes and data transmission rates may be increased.


REFERENCES:
patent: 4384362 (1983-05-01), Leland
patent: 4914651 (1990-04-01), Lusignan
patent: 5067147 (1991-11-01), Lee
patent: 5375123 (1994-12-01), Andersson et al.
patent: 5499386 (1996-03-01), Kalsson
patent: 5546443 (1996-08-01), Raith
patent: 5548809 (1996-08-01), Lemson
patent: 5551064 (1996-08-01), Nobbe et al.
patent: 5581548 (1996-12-01), Ugland et al.
patent: 5640677 (1997-06-01), Kalsson
patent: 5655217 (1997-08-01), Lemson
patent: 470 831 (1992-02-01), None
patent: 96/11533 (1996-04-01), None

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