SE525586C2 - A cellular cellular network and a method for optimizing the same - Google Patents

Abstract

The present invention relates to a procedure to, from a cost efficiency point of view and with regard to spectrum efficiency, optimize a cellular mobile telephone network, in which the base station (BS) of/for each cell is allocated a number of carrier frequencies (f1, ..., fn), where n is an integer, from the frequency band for the mobile telephone network to transmit the information to mobile stations within the cell. In the cellular mobile telephone network, carrier frequencies (f1, ..., fn) of a cell recur in another cell according to a predefined frequency reusing factor. The procedure includes the steps: to allocate to the pilot channel (fx -pilot channel) of a carrier frequency (fx), where x is an integer and 1<=x<=n, a very high share of the for the carrier frequency (fx) available power; and to allocate to the pilot channels of different carrier frequencies (f1, ..., fn) different power.

Description

0 0 0 0 0 0 0 0 0 0 0 0 00 000 0 OO 0 0 0 OO 00 OII 0 0 0 00 0000 10 15 20 25 30 'm IÃ V' '_ Ö f O 0 000 0 0 00 00 00 00 0 0000 0 0 «0 00 0 v 0 0 00 x xe .__ \. L \. * ....- 2 system. The purpose of the power control is to maintain a carrier frequency effect at a prescribed effect. The available power on a carrier frequency is distributed between active channels.

Document US-5,901,145 describes the handover for a mobile station between a spread spectrum communication system and a frequency division communication system. This solution uses a pilot channel that is not controlled by the base station.

None of the above-mentioned documents addresses or presents a solution to the above-mentioned problem.

Summary of the Invention The present invention aims to solve the above-mentioned problems. This is achieved according to a first aspect with a cellular mobile telephone network according to claim 1. The base station for each cell is allocated a number of carrier frequencies i- (f1, ..., f ,,), where n is an integer, from the frequency band of the mobile telephone network for to send information to mobile stations within the cell. Carrier frequencies (f1, ..., f ,.) of one cell recur in another cell according to a predetermined frequency reuse factor. In the cellular mobile telephone network, a carrier frequency (eg), where x is an integer and 1 gxgn, pilot channel (fx-pilot channel) is assigned a very high proportion of the power available for the carrier frequency (fx). In addition, pilot channels of different carrier frequencies (f1, ..., fn) are assigned different effects. With this solution, a cellular mobile telephone is obtained, which on the one hand meets the requirement that the signal strength with a certain probability, above the promised coverage range, does not fall below a certain predetermined signal level, and on the other hand is optimal in terms of traffic control capabilities and spectrum efficiency.

An additional advantage in this context is obtained if the fx pilot channel is allocated at least 70% of the power available for the carrier frequency (fx). In this context, it is also an advantage if the fX pilot channel is allocated at least 80% of the power available for the carrier frequency (fx).

An additional advantage in this context is obtained if the fx pilot channel is allocated at least 90% of the power available for the carrier frequency (fx).

II 0 0 0 0 0 0000 0000 00 00 0 00 0 0 0 0 0 0 0 00 0 0 0 0 0 0 0 0 0 0 0 00 0 0 0 0 0 0 0 0 0 0 0 0 00 0000 00 000 00 00 10 15 20 25 f '(\ _ i * f \ p' I O. 200.0. .O 00 .00- .000 '00 .z 000: ~ 00 0 0 0 0000 u. 0 0 \ 4 ..._ * - In this context, it is also an advantage if the fx pilot channel is allocated 100% of the power available for the carrier frequency (fx).

An additional advantage in this context is obtained if the carrier frequency (eg) is blocked for traffic.

In this context, it is also an advantage if the fx pilot channel is transmitted by means of a single transmitter.

An advantageous variant in this context is obtained if the traffic is directed away from the carrier frequency (e.g.) whose pilot channel has a high power to the other carrier frequencies (fi), where 15 in 5 n and irx, by means of inter-frequency handover and / or cell re- selection.

An additional advantage in this context is obtained if cells on the carrier frequency (eg) whose pilot channel has a high power do not appear in neighboring cell lists which are distributed to mobile stations in the mobile telephone network. In this context, it is also an advantage if an offset is added to the fx pilot channel during cell search so that the mobile stations end up on the carrier frequency (fx) only within the area where the traffic channel on the carrier frequency (fx) has service.

Another object of the present invention is to provide a method for optimizing, in terms of cost and spectrum efficiency, a cellular mobile telephone network, in which the base station (BS) for each cell is allocated a number of carrier frequencies (f1, .. ., f ,,), where n is an integer, from the frequency band of the mobile telephone network for transmitting the information to mobile stations within the cell, and in which the carrier frequencies (f1, ..., fn) of a cell return in another cell according to a predetermined frequency reuse factor. The method comprises the steps of: - assigning a carrier frequency (fx), where x is an integer and 15x5n, pilot channel (fx-pilot channel) a very high proportion of the power available for the carrier frequency (fx); and - assigning different effects of the pilot channels of different carrier frequencies (f1, ..., f ,,).

With this method a cellular mobile telephone network is obtained which on the one hand meets the requirement that the signal strength with a certain probability, above the promised coverage range, does not fall below a certain predetermined signal level, and on the other hand is optimal with respect to traffic control possibilities and spectrum efficiency. A further advantage in this context is obtained if the fx pilot channel is allocated at least 70% of the power available for the carrier frequency (fx).

In this context, it is also an advantage if the fx pilot channel is allocated at least 80% of the power available for the carrier frequency (fx).

A further advantage in this context is obtained if the fx pilot channel is allocated at least 90% of the power available for the carrier frequency (fx). In this context, it is also an advantage if the fx pilot channel is allocated 100% of the power available for the carrier frequency (fx).

A further advantage in this context is obtained if the method further comprises the step: - blocking the carrier frequency (fx) for traffic In this context it is also an advantage if the method further comprises the step: - transmitting the fx pilot channel by means of a single transmitter.

An advantageous variant in this context is obtained if the method further comprises the step of: - directing the traffic away from the carrier frequency (e.g.) whose pilot channel has a high power to the other carrier frequency (fi), where 1 _ <_ i 5 n and i == x, by means of inter-frequency handover and / or cell reselection.

A further advantage in this context is obtained if the method further comprises the step: 10 f-f fi f '' _ n: o-: 0o.0. c .co. .In. oc. no u ___ ._} v e. .J: u zu. t: 5 not to allow cells on the carrier frequency (e.g.) whose pilot channel has a high power to appear in gfanncell lists which are distributed to mobile stations in the mobile telephone network. In this context, it is also an advantage if the method also includes the step of: - in cell-search adding an offset on the fX pilot channel so that the mobile stations end up on the carrier frequency (e.g.) only within the area where the traffic channel on the carrier frequency (e.g. ) has service.

Another object of the present invention is to provide a computer program product directly chargeable in the internal memory of at least one digital computer. The at least one computer program product comprises software code batches for performing the steps of the method of the present invention when said product / products are run on said at least one computer. With this computer program product, a cellular mobile telephone network is obtained which on the one hand fulfills the requirement that the signal strength with a certain probability, above the promised coverage range, does not fall below a certain predetermined signal level, and on the other hand is optimal in terms of traffic control possibilities and spectrum efficiency.

It should be noted that when the term “includes / includes” is used in this specification, it shall be construed to indicate the presence of specified properties, steps or components, but does not exclude the presence of one or more other properties, parts, steps, components or groups thereof.

Embodiments of the invention will now be described with reference to the accompanying drawings, in which: Brief Description of the Drawings Fig. 1 schematically shows the cells of a cellular mobile telephone network and their frequency groups when the frequency reuse factor is 4; Fig. 2 shows a flow chart of a method for optimizing a cellular mobile telephone network in terms of cost and spectrum efficiency; 10 15 20 25 30 r- a _, - \ _ J »z O.: ao-o. .o so '.on- .nn- .oo »uqx / 0 o o: 6 Fig. 3 shows a flow chart of further steps in the method according to Fig. 2 according to a first embodiment; Fig. 4 shows a flow chart of some further steps in the method according to Fig. 2 according to a second embodiment; Fig. 5 shows a flow chart of a further step in the method of Fig. 2 according to a third embodiment; Fig. 6 shows a schematic view of some computer program products according to the present invention.

Detailed Description of Embodiments Fig. 1 shows a schematic representation of a geographical area covered by the cells of a cellular mobile telephone network. For ease of description, it is assumed that the cells have the same size and can be represented by circles having the same radius; The base stations BTS indicating with black circles are located in the center of a cell. The distance from one base station BTS to another is d. It is assumed that the frequency reuse factor is 4, from which follows the known fact that four frequency groups are needed. The four frequency groups in Fig. 1 are frequency group A, frequency group B, frequency group C and frequency group D. The same frequency group can thus be reused in such a way that a cell for another frequency group is located between cells for the same frequency group, for example in that in Figs. 1 showed the method. The carrier frequency is thus reused at a distance D. Assume that two carrier frequencies exist for one cell, i.e. that each frequency group comprises two carrier frequencies, the total number of carrier frequencies thus being 8, and assume that a carrier frequency requires a band of 200 kHz as in the GSM system. Thus, the system shown in Fig. 1 would require a frequency band of 1.6 MHz.

According to an embodiment of a cellular mobile telephone network according to the present invention, the base station (BS) for each cell is allocated a number of carrier frequencies (f1,..., F ,,), where n is an integer, from the frequency band of the mobile telephone network for to send infcnnation to mobile stations within the cell. The leg / yoke frequencies (f1, ..., fn) of one cell recur in another cell according to a predetermined frequency reuse factor. The cellular mobile telephone network is characterized by a carrier milling cutter; F-Pf ”: osund o oo oo t x. ... xJ o- ~. J æs'. =. S as »7 frequency (fx), where x is an integer and 1 _ <_ x5n, pilot channel (fx-pilot channel) is assigned a very high proportion of the power available for the carrier frequency (fx). In addition, the cellular mobile telephone network is characterized by the fact that different carrier frequencies (f1, ..., f ,.) pilot channels are assigned different effects.

In other words, it can be said that the cellular mobile telephone network is built so that the fx pilot channel of each cell meets the license requirement, i.e. the criterion for the signal strength of the UMTS pilot channel. The pilot channels of other carrier frequencies are dimensioned in terms of power according to market requirements, in the usual way.

According to an advantageous embodiment of the cellular mobile telephone network, the fx pilot channel is allocated at least 70% of the power available for the carrier frequency (fx).

According to another advantageous embodiment of the cellular mobile telephone network, the fx pilot channel is allocated at least 80% of the power available for the carrier frequency (fx).

According to yet another advantageous embodiment of the cellular mobile telephone network, the fx pilot channel is allocated at least 90% of the power available for the carrier frequency (fx).

According to yet another advantageous embodiment of the cellular mobile telephone network, the fx pilot channel is allocated 100% of the power available for the carrier frequency (fx). In this case, the carrier frequency (eg) can be blocked for traffic. Then there is no need to direct the traffic to the other carrier frequencies in the cell, or to penalize the fx pilot channel, during cell search. An additional advantage is then also obtained by being able to use a simple inexpensive transmitter for the fx pilot channel. This means lower requirements for linearity of the transmitter, as well as no power control. In cases where the fx pilot channel is assigned less than 100% of the power available for the carrier frequency (fx), the traffic is directed away from the band / yoke frequency (fx) whose pilot channel has a high power to the other leg / yoke frequencies (fi), where 15 i 5 n and iaßx, by means of inter-frequency handover and / or cell reselection. This control of mobile stations is allowed in the "Physical Channel Reconfiguration" message, in which the UARFCN for the new carrier frequency can be specified, if the message is sent to a mobile station in the CELL_DCH state it initiates an inter-frequency handover. however, sent to a mobile station in the CELL_FACH state, an inter-frequency cell reselection is initiated.

According to a preferred embodiment of the cellular mobile telephone network according to the present invention, cells on the carrier frequency (e.g.) whose plot channel has a high power are not present in neighboring cell lists which are distributed to mobile stations in the mobile telephone network. This prevents already active mobile stations from performing handovers / cell reselections to the carrier frequency (eg). This applies to the neighboring cell lists contained in (i) the system information on the BCH and (ii) in any dedicated “Measurement Control” messages to specific mobile stations.

According to another preferred embodiment of the cellular mobile telephone network according to the present invention, in cell search, an offset is added on the fx pilot channel so that the mobile stations end up on the carrier frequency (fx) only t within the range where the traffic channel on the carrier frequency (fx) is serviced . * This can be achieved by setting parameters via system information on BCH.

Fig. 2 shows a flow chart of a method for optimizing a cellular mobile telephone network in terms of cost and spectrum efficiency. In the cellular mobile telephone network, the base station (BS) for each cell is allocated a number of carrier frequencies (f1, ..., fn), where n is an integer, from the frequency band of the mobile telephone network to transmit information to mobile stations within the cell. In the cellular mobile telephone network, carrier frequencies (f1, ..., f ,,) of one cell in another cell are repeated according to a predetermined frequency reuse factor. The process starts at block 10. The process then continues, at block 12, with the step: assigning a carrier frequency (fx) where x is an integer 15x5n, pilot channel (fx-pilot channel) a very high proportion of that for the carrier frequency (fx) available effect. Thereafter, the process continues, at block 14, with the step: to assign different effects of different carrier frequency (f1, ..., fn) pilot channels. The process then ends at block 16.

According to a preferred embodiment of the method according to the present invention, at least 70% of the power of the leg / yoke frequency (fx) available is allocated to the fx pilot channel. 10 15 '20 25 30 r o r e. A- v? rP-f '. o oo ooo o n. q ° v J o oo os. o o q '"' ° V one ooø a. 5 g ..: °" 'I II IIII Cg fl .OQ. According to another advantageous embodiment of the method, the fx pilot channel is assigned at least 80% of the power available for the carrier frequency (fx).

According to yet another advantageous embodiment of the method, the fx pilot channel is allocated at least 90% of the power available for the carrier frequency.

According to yet another embodiment of the method, the fx pilot channel is assigned 100% of the power available for the carrier frequency.

Fig. 3 shows a flow chart of some further steps in the method according to Fig. 2 according to a first embodiment. The process starts at block 20. The process then continues, at block 22, with the step: to block the carrier frequency (eg) for traffic. Thereafter, the process continues at block 24, with the step: to transmit the fx pilot channel by a single transmitter. The process then ends at block 26; Fig. 4 shows a flow chart of some further steps in the method according to Fig. 2 according to a second embodiment. The process starts at block 30. The process then continues, at block 32, with the step: to steer the traffic away from the carrier frequency (e.g.) whose pilot channel has a high power to the other carrier frequencies (fi) where 15 i 5 n and i = f = x, by means of inter-frequency handover and / or cell reselection. Thereafter, the procedure continues, at block 34, with the step: not to allow cells on the carrier frequency (eg) whose pilot channel has a high power to appear in neighboring cell lists which are distributed to mobile stations in the mobile telephone network. The process is then terminated at block 36. Fig. 5 shows a flow chart of a further step in the process of Fig. 2 according to a third embodiment. The method starts at block 40. The method then continues, at block 42, with the step: to add an offset on the fx pilot channel during cell search so that the mobile stations end up on the carrier frequency (fx) only in the area where the traffic channel on the carrier frequency (eg) has service.

Fig. 6 shows a schematic view of some computer program products according to the present invention. Fig. 6 shows n pcs. various computer products 1021, ..., 102.1, where n is an integer. The computer program products 1021, 102.1, are directly loadable in the internal memory of at least one digital computer 1001, 100.1. Fig. 6 also shows n pcs. computers. Each computer software product 1021, 10211 includes software r-r'- P 'fw, f - f * i' = ° -..- '= "== :: -s °': = o. Gon oo o:: oov '__. a: t. ._ - z .., OIIOIIQI' 'UIQ I' O. .UI I '000000 cn OQQIQO 10 code panes for performing some or all of the steps of Fig. 2 when the product (s) 1021, ..., 102.1, run on the computer / computers 1001, ..., 1001, The computer program products 1021, ..., 102.1 may, for example, be in the form of diskettes, RAM disks, magnetic tapes , optomagnetic disks or any other suitable products.

The invention is not limited to the embodiments described above.

It will be apparent that many different modifications are possible within the scope of the appended claims.

Claims (12)

10 15 20 25 30 PATENT REQUIREMENTS A cellular mobile telephone network, in which the base station (BS) for each cell is allocated a number of carrier frequencies (f1, ._., Fn), where n is an integer, from the frequency band of the mobile telephone network to transmit information to mobile stations within the cell, and in which carrier frequency (h, fn) of one cell reappears in another cell according to a predetermined frequency reuse factor, characterized in that a carrier frequency (fx), where x is an integer and 1 _ <_ x _ <_ n, pilot channel (fx-pilot channel) is assigned at least 70% of the power available for the carrier frequency (fx), and that different carrier frequencies (f1, fn) pilot channels are assigned different effects, by controlling the distance from the carrier frequency (fx) whose pilot channel has a high power to other carrier frequencies (fi) where 15 i _ <_ n and ia fi x, by means of inter-frequency handover and / or cell re-selection. A cellular mobile telephone network according to claim 1, characterized in that the fx pilot channel is allocated at least 80% of the power available for the carrier frequency (fx). A cellular mobile telephone network according to any one of claims 1-2, characterized in that the fx pilot channel is assigned at least 90% of the power available for the carrier frequency (fx). A cellular mobile telephone network according to any one of claims 1-3, characterized in that the pilot channel is allocated 100% of the power available for the carrier frequency (e.g.). A cellular mobile telephone network according to claim 4, characterized in that the carrier frequency (e.g.) is blocked for traction. A cellular mobile telephone network according to any one of claims 4-5, characterized in that the fx pilot channel is transmitted by means of a single transmitter. 10 15 20 25 30 l2 A cellular mobile telephone network according to claim 1, characterized in that cells at the carrier frequency (e.g.) whose pilot channel has a high power do not appear in neighboring cell lists which are distributed to mobile stations in the mobile telephone network. A method for optimizing, in terms of cost and spectrum efficiency, a cellular mobile telephone network, in which the base station (BS) for each cell is allocated a number of carrier frequencies (f1, fn), where n is an integer, from the frequency band of the mobile telephone network for transmitting information to mobile stations within the cell, and in which carrier frequencies (f1, fn), of a cell return in another cell according to a predetermined frequency reuse factor, which method comprises the steps of: - assigning a carrier frequency (e.g.), where x is an integer and 15 in 5 n, pilot channel (ffpilot channel) at least 70% of the power available for the carrier frequency (fx), - to steer the track away from the carrier frequency (fx), whose pilot channel has a high power to other carrier frequencies (fl) , where 15 in 5 n and biscuits, by means of inter-frequency handover and / or cell reselection. -; and assigning different effects of the pilot channels of different carrier frequencies (f1, fn). A method for optimizing a cellular mobile telephone network according to claim 8 for cost and spectrum efficiency, characterized by assigning at least 80% of the power available for the carrier frequency (fx) to the fx pilot channel. Space efficiency optimize a cellular mobile telephone network according to any one of claims 8-9, characterized by assigning at least 90% of the power available for the carrier frequency (fx) to the fx pilot channel. A procedure for cost-cutting and spectral Spectrum efficiency optimize a cellular mobile telephone network according to any one of claims 8-10, characterized by assigning 100% of the power available for the carrier frequency (fx) to the fx pilot channel. A method for cost-wise and with respect to 10 15 20 * ÖF- f-Pa f 'x., _ .. .J e ~ - .f l3 A space for optimizing a cellular mobile telephone network according to claim 11, characterized in that the method further comprises the step of: - blocking the carrier frequency (e.g.), for traction. Optimizing a cellular mobile telephone network according to any one of claims 11- A method for cost-wise and with respect to spectrum 12, characterized in that the method further comprises the step of: - transmitting the fx-pilot channel by means of a single transmitter. A method for optimizing a cellular mobile telephone network according to claim 13, characterized in that the method further comprises the step of: - not allowing cells on the carrier frequency (e.g.) whose pilot channel has a high power to occur. in neighboring cell lists which are distributed to mobile stations in the mobile telephone network. The internal memory of at least one digital computer (1001, at least one computer program product (1021, 102 ,.) directly rechargeable 100n), comprising software code portions for performing the steps of claim 8 when said at least one product (1021, .. 100n) . ., 102,.) Is run on the at least one computer (1001,