JP2002530958A - Channel allocation method and cellular radio system - Google Patents

Abstract

(57) [Summary] The present invention relates to a cellular radio network and a channel assignment method. In this way, the assignment of a cellular radio network channel to a subscriber is controlled based on the mutual interference between a given cell (200) and neighboring cells (220-250). In the solution of the present invention, a neighboring cell connection subject to interference from a given cell (200), wherein the neighboring cell (220-250) at least partially has the same frequency setting as the given cell (200) The neighbor cell connection to use is determined based on the measurements that subscriber terminals located within that neighbor cell (220-250) report on their strongest neighbor cells, and with the given cell (200). -250) based on the common frequency used. Therefore, the decision to assign a channel to the subscriber terminal can be made based on the optimal data.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

【Technical field】

The present invention relates to a method for allocating channels of a cellular radio system to terminals and to a cellular radio system.

[0002]

[Background Art]

One of the key issues in configuring and maintaining a cellular wireless network is the limited range of available wireless spectrum. Careful planning for radio frequency use aims to minimize co-channel and adjacent channel interference. Various complex methods divide the cells into different frequency cells with the intention of minimizing interference to the wireless connection and thus maximizing network capacity. In the cell repetition pattern, the same or adjacent frequencies must not be too close to each other. This causes excessive interference in the system. As the use of mobile phones and other subscriber terminals becomes increasingly common, the capacity of the network must be constantly increased.
This leads to high costs in frequency planning and various measurements.

In known mobile systems, the assignment of a traffic channel to a given subscriber terminal generally depends on whether the radio cell can then use the traffic channel. In other words, if the wireless channel has a free traffic channel, it is assigned to the subscriber terminal when needed. The GSM system (global system for mobile communications) is an example of a system in which traffic channel allocation is performed as described above. Since the GSM system is time division, a traffic channel containing a time slot on a given frequency channel is assigned to a subscriber terminal. Alternatively, if frequency hopping is used, the frequency channel of the traffic channel changes from one time slot to another based on a predetermined frequency hopping sequence. Thus, the subscriber terminal transmits alternately on all frequency channels included in the frequency hopping sequence. Thus, when the reuse factor of a channel in a network using frequency hopping is less than 9, the capacity is no longer limited by available traffic channels (so-called "hard blocking"), but by interference (so-called "soft blocking"). blocking"). Therefore, the network can be considered as interference limited. As the load in this interference limiting network increases, the quality decreases correspondingly. The so-called dynamic hot spot feature (DHS
The basic idea is to control the traffic load of a cellular wireless network using frequency hopping based on interference and thus achieve high network capacity. Thus, the dynamic hotspot feature is used to control the load in interference limited cellular wireless networks. If the load of a given cell exceeds a predetermined value, and thus the interference in the rest of the cellular radio network increases, so-called soft blocking can be used for channel assignment. The blocking criterion is checked at each new call assignment and inter-cell handover. The decision to allow a new call to enter the network is made based on the connection quality of neighboring cells. If there is a large number of bad connections in neighboring cells that are subject to interference, the call will be blocked even if there are available free channels in the cell.

In known dynamic channel assignment methods, the channel assignment is based, for example, on the average quality of the currently connected calls in the interfering cell, ie the quality of each cell is the average quality of all calls in that cell. be equivalent to. The quality class of each cell is determined based on the average value of the quality of the already connected calls, and this quality class of the cell determines the probability of getting the call. The final probability of specifying a channel is the product of the probabilities of neighboring cells.

[0005] No progressive method for determining the actual cell to be interfered has hitherto been known. The problem with the above configuration is that, for example, each interfering cell has to be defined case-specific, i.e. in order to determine the neighboring cells to be interfered with, the information for each individual serving cell must be manually entered, e.g. from the network configuration. It was necessary to collect and send that information to the channel assignment process. The interfering cell is not necessarily the same cell having the strongest signal level in the cell to which a connection is established based on the measurements of the subscriber terminal. The reason is that the above method can only be used for measuring uplink interference lower than downlink interference,
This is because it is not possible to use a method for evaluating a cell receiving interference with desired accuracy.

[0006]

DISCLOSURE OF THE INVENTION

Accordingly, it is an object of the present invention to provide a method and a cellular radio system that can solve the above problems. This is achieved by the solution of the present invention.
The present invention relates to at least one base station of a given cell, at least one subscriber terminal communicating with the base station, neighboring cells of the given cell, and a subscriber terminal communicating with these neighboring cells. A method for allocating channels in a cellular wireless network, comprising receiving a request to allocate a traffic channel of a given cell to a subscriber terminal, wherein the subscriber terminal comprises a base station. And reports the measurement of the broadcast control channel detected by the terminal and transmits the assignment of the cellular radio network channel to the terminal in the above manner to the mutual interference between a given cell and its neighboring cells. According to the channel allocation method as controlled Zui. In this method, a neighboring cell connection that is subject to interference from a given cell, wherein the neighboring cell uses at least partially the same frequency setting as the given cell, is included in the neighboring cell It is determined based on the measurements that the located subscriber terminals report on their strongest neighbor cells and on the common frequency used by the neighbor cells with a given cell.

[0007] The present invention also provides at least one base station for a given cell, at least one subscriber terminal communicating with the base station, a neighbor cell for the given cell, and communication with the neighbor cell. A wireless terminal comprising: a subscriber terminal configured to receive a request to assign a traffic channel of a given cell to the subscriber terminal, wherein the cellular wireless system comprises: The subscriber terminal in communication with the base station is configured to report a measurement of the broadcast control channel transmitted by the base station to neighboring cells, and the cellular radio system allocates the cellular radio network channel to the terminal. , A cellular wireless system configured to control based on the mutual interference between a given cell and its neighbors. The cellular radio system may include a neighbor cell connection that is subject to interference from a given cell, the neighbor cell connection at least partially using the same frequency settings as the given cell. The subscriber terminals located within are configured to determine based on measurements reported for their strongest neighbor cells and based on a common frequency used by neighbor cells with a given cell.

[0008] Preferred embodiments of the invention are set out in the dependent claims. According to the prior art, the interference that occurs for cells using the same frequency setting is estimated, for example, by calculating the average quality of all current calls in progress. In this case, assume that all poor quality results from interference. this is,
Poorly, but not necessarily, poor quality can also result from the subscriber terminal being in a weak electric field, for example indoors. Therefore, the method of the present invention is based on performing interference estimation by using only interference-sensitive connections. This is concluded by whether the broadcast control channel of the interfering cell is heard by the subscriber terminal, and if the answer is yes, the traffic channel frequencies of said cells with common channel or adjacent channel interference will interfere with each other. A conclusion is drawn.

According to the present invention, the function of the dynamic hot spot method can be improved in a cellular wireless network. The method of the present invention is a better method than the prior art for selecting neighboring cells subject to interference. As used herein, a neighbor cell refers to a cell that is close to the cell to which a traffic channel is being assigned and for which a new traffic channel can be assumed to affect the ongoing connection of that neighbor cell. In other words, the neighbor cells need not necessarily be located adjacent to the cell to which the channel is assigned, but may be one or more other cells between those cells. According to the method of the present invention, it is also possible to calculate the ratio of poor quality in the cells subject to interference. The method of the present invention effectively uses a new type of weighting factor, which can also be used to further improve the original DHS algorithm.

[0010] A number of advantages are achieved with the method and system of the present invention. The method of the present invention comprises:
It is an automatic method of determining the cells that are interfered with for a given cell and the ratio of poor quality to the total quality of the cells that are affected. Thus, this method can give a good overall picture of the interference and thus increase the capacity of the cellular wireless network. The DHS method allows for very tight frequency reuse without loss of quality, with transceivers preferably using frequency hopping. This is because the base station controller can limit the traffic load to areas where the value of the interference variable is within an acceptable range.
Further, traffic can be controlled dynamically. This feature is very useful, especially when the traffic volume increases occasionally and temporarily. Thus, if the quality of the interfering cell remains at an acceptable level, local peaks in traffic load can be tolerated.

[0011] According to the prior art, poor quality data is collected from cells that are interfered by the cell to which the new call is connected. However, cellular wireless networks do not update the list for these interfering cells. The method of the present invention comprises:
It can be used to find interference for each cell under one base station controller. In known methods, poor quality data was collected from all connections of the interfering cell. In the method of the present invention, the connection quality of only the connection that actually receives the interference is measured. Further, the method of the present invention uses a new frequency weighting factor that takes into account the situation where the frequency of the interfering cells only partially overlaps, whereas in known solutions the interference in different cells is reduced. It was assumed to be the same and independent of the number of common frequencies.

The solution of the invention can be advantageously applied, for example, to GSM-type cellular radio networks. This solution does not require any changes in the current GSM specification. All necessary changes are obtained in the base station controller. This method can be adopted by changing only the software, that is, updating the software of the network device. The actual device does not need to be changed. The system of the present invention has the same effect as the above method. Various combinations of the preferred embodiment and its details can be used to achieve the desired technical effect.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 shows an example of the structure of a general cellular wireless network. This figure shows the coverage areas or cells of the base stations 100, 102, 130 in hexagons. Base stations 100, 102, 130 communicate with base station controller 114 via connection line 112. The task of the base station controller 114 is to control the operation of its subordinate base stations. Typically, the base station controller 114 is connected to a mobile services switching center 116 and from there to a public switched telephone network 118. In an office system, the functions of the base station 100, the base station controller 114, and the mobile services switching center 116 may be combined into one device from which the switching of a public switched telephone network 118, for example, a public switched telephone network 118, may be performed. Can be connected to the center. The subscriber terminals 104, 106 in the cell 200 have a two-way wireless connection 108, 110 to the cell's base station 100. Cell 22
0 at the base station 13 of the cell.
It has two-way wireless connections 126, 128 to zero. In addition, the network portion, the fixed portion of the cellular wireless network, can include additional base stations, base station controllers, transmission systems, and various levels of network management systems. Cellular wireless networks also
It will be apparent to those skilled in the art that various other structures need not be described in detail here.

FIG. 2 shows a broader example of a cellular wireless network to which the dynamic hot spot algorithm of the present invention can be applied to control traffic load. The wireless network comprises a set of cells each assigned a set of frequency bands for a subscriber terminal connection. The cells 200, 220, 230 of FIG.
, 240, 250 at least partially use the same frequency group or the same frequency. In this example, it is assumed that the used frequency is cell-specific as follows. Table 1 Cell frequencies 200 f ₄ , f ₅ , f ₆ , f ₇ 220 f ₁ , f ₂ , f ₃ , f ₄ , f ₅ 230 f ₂ , f ₃ , f ₄ , f ₅ , f ₆ 240 f ₅ , f ₆ , f ₇ , f ₈ 250 f ₁ , f ₂ , f ₃ , f ₄

In a cellular wireless network, a base station generally transmits a so-called broadcast control channel that contains general information related to the base station, so that a subscriber terminal can contact the base station. The broadcast control channel is also used when assessing the subscriber terminal's need for handover. For example, in the GSM system, the broadcast control channel is called BCCH. Conveniently, the broadcast control channel also includes an identifier that the subscriber terminal knows from which base station the signal comes from. In the GSM system, this identifier data is a so-called recognition code BSIC (base station recognition code).

In the wireless system of the present invention, a subscriber terminal measures a broadcast control channel from a neighboring cell. Each subscriber terminal that has a connection to its own base station continuously measures the BCCH signal of the strongest neighbor cell to evaluate possible handover candidates. This measurement information conveniently includes the received signal level and the base station identification code. Since the measurement capacity and measurement time of the subscriber terminal are finite, the number of base stations to be measured is limited. One effective maximum number of base stations to be measured is six used in GSM systems. For example, subscriber terminal 122 of cell 220 measures the strength of the BCCH channels of the six strongest receiving neighbor cells and reports the measurement to its base station 130, which sends them to base station controller 114. Transfer to

Suppose that subscriber terminal 120 in cell 200 attempts to establish a connection to base station 100. According to the DHS principle, if the number of free traffic channels in a cell is below a given threshold,
The decision of the subscriber terminal 120 to accept the configuration request depends on the interference that the cell 200 causes to neighboring cells using the same frequency. The basic idea of the invention is that the BCCH measurements performed in neighboring cells are used for estimating interference effects. When a call is connected to a cell 200, it is transmitted to neighboring cells 220, 230
, 240, 250 also affect the quality of other calls using the same frequency.

This example will be described in detail with reference to FIGS. Each subscriber terminal with a connection to the base station continuously measures the BCCH signal of the strongest neighbor cell. Accordingly, subscriber terminals located in cells surrounding cell 200 also perform measurements. What is important in this regard is a cell that uses the same frequency as cell 200, in which a decision must be made about a new connection between the subscriber terminal and the base station.

In principle, the method of the invention has two steps. First, interference information is collected from neighbor cells 220, 230, 240 and 250 of cell 200 as follows. For example, start with cell 220. The base station controller
Collect the BCCH measurement results from the subscriber terminal communicating with the cell 220.
Each subscriber terminal preferably performs independent measurements on the six strongest BCCH signals. At terminals located on different sides of the cell, the six signals are different. The number of common frequencies between the cell 220 and the reported neighboring cell is calculated. It is then checked whether the number of common frequencies exceeds zero.
If not, there is no significant interference between the cells. For example, neighbor cell 210 uses a different frequency than cell 220. Thus, reporting of the base station's BCCH signal is omitted at this point, but the terminals located on that side of the cell will probably measure the signal. Based on the BCCH measurements made by the subscriber terminal, neighboring cells having at least one common frequency with the serving cell 220 are tabulated for the strongest cell. Therefore, in this example, cells using the same frequency are 200, 230, 24
0 and 250. In other words, if the number of common frequencies exceeds zero, the table of neighboring cells 200, 230, 240 and 250 interfered by cell 220 is updated, for example, the neighboring cells using the same frequency 200
, 230, 240 and 250, the common frequency of cell 220 and its neighbors, ie, the ratio of the same frequency to the total available frequencies in its neighbors (added from cell 220 and each neighbor at once), and all samples Shows poor quality samples proportional to. The table of the cell 200 is, for example, as follows.

Table 2 Same frequency group Number of common frequencies Poor quality sun loop cell / Number of all frequencies Pull / All samples (cell 220 + cell X) PQ% TS Cell 230 4/6 2/50 Cell 240 1/8 3/60 Cell 250 4/5 20/80 Cell 200 2/7 7/70 or less, poor quality samples proportional to all samples are abbreviated as “PQ%” Indicated by Similar tables are drawn for each of the neighboring cells 220, 230, 240 and 250 of the cell 200.

A so-called frequency weighting factor TS can also be calculated in the table so that it can be used as an interference weighting factor. Its use is described below.
The weighting factor is calculated by using information about the number of common frequencies between the interfering cell and the interfering cell. One way to form the weighting factors is to determine the ratio of the common frequency to the total available frequencies as shown in the table above. Another effective way to form the weighting factors is to calculate them with the following formula: TS = (f _all * TRXLKM _interferer ) / (f _interferer * f _interfered
Where f _all = number of common frequencies (cells causing and receiving interference), TRXLKM _interferer = number of transceivers in the cell generating _interference , f _interferer = number of frequencies in the cell generating _interference , and f _interfered = Number of frequencies in the interfering cell. Therefore, in the above table, the cell that causes interference is a cell in which the broadcast control channel is detected among the strongest cells, and the cell that receives interference is a cell whose table is updated correspondingly.

Table 2 shows the poor quality ratio PQ% that is updated periodically.
Thus, when the subscriber terminal reports a cell that has a common frequency with the serving cell 220 and is in the strongest, for example, in the group of the six strongest neighbors, that cell is no longer the strongest (6 in this example). The ratio of poor quality to total quality is updated until it is no longer in the (strongest) neighbors. If the neighbor cells 200, 230, 240, 250 reported in the list operate at the same frequency as the six strongest neighbor cells, the poor quality percentage PQ% for each neighbor cell in the table is Be updated. Therefore, the method of the present invention measures only poor quality resulting from interference caused by cells of the same frequency group. For example, poor quality resulting from the low signal level of the serving cell 220 can be ignored.

In the second step of the method of the present invention, the procedure is as follows. FIG. 3 is a flowchart of an advanced dynamic hot spot algorithm in which the method of collecting poor quality information and calculating the frequency weighting factor of cell 200 is used. The frequency weighting factor and the poor quality ratio PQ% are collected from each neighboring cell 220, 230, 240, 250 that suffers from interference by using the above method. What is new, what invention, and in particular how, is that the poor quality information of the interfering cells 220, 230, 240, 250 is collected based on the above tabulation principles and the use of frequency weighting factors. It is.

According to the DHS algorithm of FIG. 3, the subscriber terminal 120
Send a service request to. Then, the traffic channel in use (TCH
) Is checked if it exceeds the desired preset limit. If this number does not exceed the desired limit, subscriber terminal 120 is connected to cell 200 that received the service request. However, if the number of traffic channels already in use exceeds the desired limit, the neighboring cell 22
0-250 is searched. For each cell, it is checked whether the table of cells 220-250 contains the cell 200 that received the service request. Then, the connection ratio is determined by the poor quality ratio PQ% calculated in Table 2 for each neighboring cell that receives interference. This ratio indicates the strength of the interference. This ratio is to scale the quality value within a given range. Determining the connection ratio based on the PQ% value can be performed by, for example, the following table. Table 3 Poor quality ratio (PQ%) Connection ratio PQ%> Poor quality limit value 0 Poor quality limit value ≥ PQ% Prob1 > Signal quality limit value 1 Signal quality limit value 1 ≥ PQ% Prob2 > Signal quality limit value 2 Signal quality limit value 2 ≧ PQ% Prob3> good quality limit value good quality limit value PQ% 1

The value of the connection ratio is determined as follows. If the calculated so-called excess poor quality ratio PQ% exceeds a preset standard poor quality limit, the connection ratio in the table is zero. When the measured poor quality ratio PQ% is equal to or less than the preset poor quality limit value and exceeds the preset signal quality limit value 1, the ratio of the table becomes a constant "Prob1". The measured poor quality ratio PQ% is equal to the preset signal quality limit 1
If it is less than or equal to the preset signal quality limit value 2, the ratio of the table becomes a constant “Prob2”. Similarly, if the measured poor quality ratio PQ% is less than or equal to the preset signal quality limit 2 and exceeds the preset good quality limit, then the ratio in the table is a constant "P
rob3 ". When the good quality limit value exceeds the poor quality ratio PQ%, the ratio becomes 1. If necessary, the table can be scaled finer or coarser, i.e. the ratio can be changed in any desired step between 0 and 1.

The ratio obtained is then weighted by a frequency weighting factor TS (the calculation of which has already been described), and the total probability PROB of the allocation is, for example, between 0 and 1 for each neighboring cell 220, It is calculated by multiplying the ratio of 230, 240, 250 as follows. _{PROB = TS 200/220 * Prob (Cell220} ) * TS 200/2 30 * Prob (Cell230) * TS 200/240 * Prob (Cell 240) * TS 200/250 * Prob (Cell250) However, the terms Prob (Cell ) Is the connection ratio of the cells, and the term TS _{200 / N} is the frequency weighting factor between cell 200 and cell n. With this frequency weighting factor, the importance of each cell in proportion to the number of common frequencies can be improved. Note that the above method for calculating the total probability PROB is only one option. The value corresponding to the total probability can be calculated by other known methods.

Thereafter, the calculated value of the total probability PROB is compared with a connection threshold value formed in a predetermined manner. This threshold value is, for example, a random number within a given range, or more preferably, a preset value (eg,
0.5). If PROB is smaller than the above value, the subscriber terminal 1
20 is connected to the cell 200 that has received the service request. If PROB exceeds the above value, the call will be blocked and not connected to the cell 200. In a cellular wireless network, the functions according to the invention can preferably be implemented in the base station controller 114 or in a corresponding unit which serves to allocate channels to the terminals. This method can be adopted by changing only the program, that is, by updating the software of the network device to carry out the method steps required for the invention. No device changes are required. As described above, the present invention has been described in detail with reference to examples of the accompanying drawings. However, the present invention is not limited thereto, and various changes can be made within the scope of the present invention described in the claims. It is clear that.

[Brief description of the drawings]

FIG. 1 is a diagram generally illustrating a cellular wireless network.

FIG. 2 illustrates a cellular wireless network of the present invention.

FIG. 3 illustrates the method of the present invention.

[Procedural Amendment] Submission of translation of Article 34 Amendment of the Patent Cooperation Treaty

[Submission date] January 15, 2001 (2001.1.15)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Claims

[Correction method] Change

[Correction contents]

[Claims]

──────────────────────────────────────────────────続 き Continuation of front page (81) Designated country EP (AT, BE, CH, CY, DE, DK, ES, FI, FR, GB, GR, IE, IT, LU, MC, NL, PT, SE ), OA (BF, BJ, CF, CG, CI, CM, GA, GN, GW, ML, MR, NE, SN, TD, TG), AP (GH, GM, KE, LS, MW, SD, SL, SZ, TZ, UG, ZW), EA (AM, AZ, BY, KG, KZ, MD, RU, TJ, TM), AE, AL, AM, AT, AU, AZ, BA, BB, BG, BR, BY, CA, CH, CN, CR, CU, CZ, DE, DK, DM, EE, ES, FI, GB, GD, GE, GH, GM, HR, HU, ID , IL, IN, IS, JP, KE, KG, KP, KR, KZ, LC, LK, LR, LS, LT, LU, LV, MA, MD, MG, MK, MN, MW, MX, NO, NZ, PL, PT, RO, RU, SD, SE, SG, SI, SK, SL, TJ, TM, TR, TT, TZ, UA, UG, US, UZ, VN, YU, ZA, ZWF terms (Reference) 5K067 AA03 BB03 BB04 CC04 DD17 DD44 EE02 EE10 EE16 EE61 HH22 JJ01 JJ11 LL11

Claims (18)

[Claims] At least one base station (10) of a given cell (200).
0), at least one subscriber terminal (104, 106) communicating with the base station (100), neighboring cells (220-250) of the given cell (200), and subscribers communicating with these neighboring cells. A method for allocating channels in a cellular wireless network comprising terminals (122, 124), the method comprising receiving a request to assign a traffic channel of a given cell (200) to a subscriber terminal (120), In a wireless system, a subscriber terminal (104, 106) reports measurements of a broadcast control channel transmitted by the base station and detected by the terminal, and in the above method, given a cellular assignment of a wireless network channel to the terminal. Based on the mutual interference between a cell (200) and its neighbors (220-250) In the channel allocation method as Gosuru, a neighboring cell connections receiving interference from the given cell (200), adjacent cells (220-25
0) uses at least partially the same frequency settings as the given cell (200), and the subscriber terminals located within that neighbor cell (220-250) have their strongest neighbor cells. And determining based on a common frequency used by neighboring cells (220-250) with a given cell (200). 2. The base station controller (114) collects a broadcast control channel measurement result from a subscriber terminal communicating with the cell (220), and the cell (200) and a broadcast control channel measured by the terminal. Calculate the number of common frequencies between adjacent cells transmitting the same, and among the strongest adjacent cells of the cell (220), cells (200, 230, 240) having at least one common frequency with the cell (220) 2. The method according to claim 1, which tabulates: 3. The base station controller (114) receives a connection setup request for a subscriber terminal (120) and a given cell (200) and determines whether the number of traffic channels in use exceeds a preset limit. Check, thereby searching for a neighboring cell (220,230,240,250) to be interfered by checking whether or not the cell (200) appears in the table of neighboring cells (220,230,240,250). Calculate the connection ratio according to the quality ratio, calculate the total probability, compare the calculated total probability with the connection threshold value formed in a predetermined manner, and make a call connection or rejection decision based on the comparison The method of claim 2, comprising the steps of: 4. The method according to claim 3, wherein when calculating the total probability, the connection ratio is weighted by a frequency weighting factor calculated by the number of common frequencies between the interfering cell and the interfering cell. . 5. The method according to claim 2, wherein the subscriber terminal reports a desired number of only neighboring cells receiving the strongest interference. 6. The method according to claim 1, wherein the measurement results are compiled in a table or similar cell-specific manner. 7. The method according to claim 1, wherein the ratio of the number of common frequencies to the total frequency between the cell (220) and neighboring cells and the poor quality ratio are compiled in a table or the like. 8. The method of claim 3, wherein the connection threshold value is a random number. 9. The method according to claim 3, wherein the connection threshold value is a preset limit value. 10. The method according to claim 1, wherein the method is applied to a so-called dynamic hot spot algorithm. 11. The base station of at least one given cell (200).
100), at least one subscriber terminal (104, 106) communicating with the base station (100), neighboring cells (220-250) of the given cell (200), and subscribers communicating with these neighboring cells. A cellular wireless system comprising a terminal (122, 124), the cellular wireless system configured to receive a request to assign a traffic channel of a given cell (200) to a subscriber terminal (120); In the cellular wireless system, a subscriber terminal (104, 106) communicating with a base station is configured to report a measurement result of a broadcast control channel transmitted by the base station to a neighboring cell (220, 230, 240, 250), and the cellular wireless system Allocates the cellular radio network channel to the terminal for a given cell (200) and its neighbors. Contact cell (220,230,240,
250) in a cellular radio system configured to control based on the mutual interference between adjacent cells (220-25) that are subject to interference from a given cell (200).
0) uses the same frequency setting as the given cell at least in part, and the subscriber terminals (122,124) located within that neighbor cell (220-250) have their strongest neighbor cells. A cellular radio system characterized in that the cellular radio system is configured to determine based on a measurement that reports on a common frequency used by neighboring cells (220-250) with a given cell (200). 12. The base station controller (114) includes a cell (220).
A cellular control system configured to collect broadcast control channel measurements from a subscriber terminal (122,124) in communication with the cellular terminal, wherein the cellular radio system calculates a number of common frequencies between the cell (200) and neighboring cells. And the cellular radio system is configured to represent, among the strongest neighbor cells of the cell (220), cells (200, 230-250) having at least one common frequency with the cell (220). The cellular radio system according to claim 11, wherein the cellular radio system is configured as follows. 13. The base station controller (114) receives a connection setup request for a subscriber terminal (120) and a given cell (200), wherein the cellular radio system has a preset number of traffic channels in use. Check if the limit value is exceeded, so that the cellular radio system can check if the cell (200) appears in the table of neighbor cells (220-250) by receiving interference from the neighboring cells (220-250). Wherein the cellular radio system is configured to calculate a connection ratio according to a poor quality ratio for neighboring cells (220-250) subject to interference, and wherein the cellular radio system calculates an overall probability. The cellular radio system compares the calculated total probability to a connection probability value and determines whether to call or reject the call. 13. The cellular radio system according to claim 12, configured to perform: 14. The cellular radio system according to claim 11, wherein the subscriber terminal is configured to report a desired number of only neighboring cells receiving the strongest interference. 15. The cellular radio system according to claim 12, wherein the measurement results are compiled in a table or similar cell-specific. 16. The system is configured to compile in a table or the like data on the ratio of the number of common frequencies to the total frequency between a given cell (220) and neighboring cells (200, 230-250), and the poor quality ratio. 14. The cellular radio system according to claim 12. 17. The cellular radio system according to claim 13, wherein said connection probability value is a random number. 18. The cellular wireless system according to claim 13, wherein the connection probability value is a preset limit value.