FR2895196A1 - UNTERFERENCE FACTOR EVALUATION FOR PLANNING A RADIO COMMUNICATION NETWORK - Google Patents

Abstract

In a cellular network modeled in regular cells centered on base stations, base station transmit power and attenuation are defined as continuous functions of the position of a point on the network with respect to a given station. a given cell, a stationary continuous density and a ring sector including stations disturbing the reception in a mobile. The product of the sector number per cell, the base station density, the transmission power and the attenuation is integrated on the crown sector in the power received by the mobile due to the base stations in the others. cells. The power received by the mobile and due to at least one base station of the given cell different from the given base station is determined according to the product of the transmission power of the given base station and the attenuation at the base station. mobile compared to the different base station. The determined received powers are summed to an interference factor to derive a number of base stations per cell satisfying a network capacity.

Description

Interference factor evaluation to plan a network of

radiocommunication

  The present invention relates to a method of evaluating an interference factor for planning a digital cellular radio network.

  Radiocommunication network operators seek to maximize the number of mobile mobile user terminals, called "mobile", that can be served by a given network and for a given quality, this quality being variable depending on the users. The precise planning of a radiocommunication network and the increase of the capacity and the coverage area of the network satisfy the imperatives of network traffic and network evolution.The planning aims at estimating the number of station sites. This is based on the coverage and capacity requirements imposed by the operator.Radio propagation and the network environment are also factors to be considered.A particular technique of network dimensioning is sectoring which consists in deploying directional antennas for a base station Planning is fundamental to the construction of a network that requires the use of a number of techniques, and in particular: theoretical calculations of capacity and coverage, computer simulation tools that perform complex calculations that take into account a large number of network parameters, and field measurements to refine the mod These are used in simulation tools, including propagation according to the environment of the network.

  It is also essential for an operator to optimize the number of base station sites in the network to minimize the cost of the network infrastructure.

  Theoretical calculations use cellular network models, usually with a hexagonal mesh in which the base stations are located in the center of hexagons ("Wireless Downlink Data Channels: User Performance and Cell Dimensioning", Thomas Bonald and Alexandre Proutiere, MobiCom '03, September 14-19, 2003, San Diego, California, USA). For CDMA (Coded Division Multiple Access) type radiocommunication networks, the fundamental quantities limiting the capacity of a network are the power of the server base station and the interferences received at each point in the network. each cell of the network. It is therefore important to be able to evaluate these quantities. Analytical calculations are complex because they involve a large number of base stations. The evaluation of the power received at one point of the network depends on the distance of each of the base stations at this point. When the number of stations is large, calculating the total power at a point, equal to the sum of all the powers received from the stations of the network at this point, requires a calculation by computer to size the network.

  It is therefore necessary to complete the computational calculations by computer numerical calculations and / or to develop simulation tools.

  The analytical approach, generally based on hexagonal type network models, leads to numerical calculations and / or extremely complex simulations. The calculations are all the more complex as the area where base stations near a given base station are considered is large and the number of neighboring base stations is high. At the present time, the characteristic quantities of the network are calculated by means of simulators. Because of the large computation times, the existing techniques do not explore a whole set of possible schedules / densifications in an instant manner, depending on the requirements of the network operator. The comparison of different strategies to achieve specific capacity objectives requires series of computer simulations or numerical calculations that are necessarily costly in time and development. Sectorization of the network is not currently treated today by an exclusively analytical method. Only long and complex simulations are likely to produce numerical results.

  An object of the invention is to overcome the above-mentioned drawbacks by proposing an analytical method for evaluation of interference factor taking into account the sectorization of a cellular radiocommunication network and intended for the planning thereof, and in particular offering time reduced calculations. The method allows the network operator to test different strategies in order to select the most appropriate one. The method is also suitable for the choice of admission control strategies favoring flow rates, mobile admission rates per cell

  or a compromise between the two, depending on the requirements of the operator.

  To achieve this objective, a method of evaluating an interference factor in a radio communication network having cells divided into sectors and modeled by regular surfaces centered on base stations, wherein the transmission power for a given downlink from a given base station to a mobile located in a given sector of a given cell covered by at least the given base station is evaluated according to a ratio of the power received by the mobile and due to the base stations in cells other than that including the base station given on the received power from the given base station, is characterized in that it comprises the following steps of. define a base station transmit power and attenuation as continuous functions of the position of a point on the network relative to the given base station, express a continuous base station density at each point on the network, define a sector of crown where are located base stations disturbing the reception in the mobile, determine a first power received by the mobile and due to the base stations in said other cells by integrating the product of the number of sector per cell , base station density, transmit power and attenuation on the surface of the crown sector, determine a second power reviewed by the mobile and due to at least one base station of the given cell different of the given base station according to the product of the transmitting power of the given base station and the attenuation to the mobile with respect to the different base station, and evaluating an interfering factor by summing said first and second determined periodic powers.

  The number of base stations per cell of the cellular network necessary to satisfy a determined network capacity, i.e., a mobile density selected by the operator, is deduced from the interference factor evaluated according to the method of 1 'invention. This interference factor evaluation method is used to accurately and rapidly evaluate a number of base stations with directional antennas to be added, locally or globally, in an existing network, to accommodate increased traffic. The method also serves to estimate parameters such as the load and transmit power in each cell of the network and the receive power of a mobile.

  The interference factor evaluation method can be used to test different sectoring strategies, admission control favoring rates, admission rates or a compromise between the two, depending on requirements of the operator of the network. The criteria which must be respected for the admission of a mobile in the network are criteria of charge and power:

  - the load of each base station, and in particular that of the "given" base station which has established a downlink with the mobile, shall not exceed a maximum permissible load, and - the power demanded by the: all base stations, and in particular the data base station which has established a downlink with the mobile, must not exceed a maximum permissible power.

  The method can be used as is in a computer system, or title implant in a simulator to increase the speed of calculation of the latter. An interference factor computing system for planning a cellular radio network may be designed for carrying out the interference factor evaluation method according to the invention. The invention also relates to a computer program on a recording medium, comprising adapted program instructions for implementing the interference factor evaluation method according to the invention when said program is executed by a processor. .

  The invention also relates to a method for planning a radio communication network using the interference factor evaluation method according to the invention, as well as to a radiocommunication network obtained by implementing the method of planning according to the invention.

  Other features and advantages of the present invention will become more apparent upon reading the following description of a number of preferred embodiments of the invention given in the following:

  As nonlimiting examples, with reference to the corresponding appended drawings in which: FIG. 1 is a diagram of a model of a cellular radio network with base stations; FIG. 2 is a diagram of a sectored cellular radiocommunication network model according to the invention; and FIG. 3 is an algorithm of the interference factor evaluation method according to the invention.

  Some definitions relating to the sectorization of a digital cellular radio network are indicated below. A sector is an area covered by a directional antenna of a base station, theoretically bounded by the dimensions of an angular sector inferior to 360 at the top of which the base station is substantially located. A cell is either an area covered by an omnidirectional antenna of a base station, or a set of adjacent or non-adjacent areas respectively covered by directional antennas of co-located base stations that have a common vertex or where the stations are located. basic co-located. For example, a tri-sectorized cell includes three sectors attributed to three colocalized base stations.

  A sectorization of at least one cell in the network consists of dividing the cell at least into sectors when the cell is covered by an omnidirectional antenna and modifying at least the sectors of the cell when it is already sectored, notably to modify the cell. number of sectors

  of the cell. Sectorization increases the performance of the network, such as the maximum number of terminals served in a cell. A local sectorization is a sectorization of a cell of a network, and a global sectorization is a sectorization of several cells of the network. The invention relates to local and / or global sectorization.

  Referring to FIG. 1, a CDMA-type CDMA digital cellular radio network comprises J base stations BSI to BSJ, with J a natural integer greater than 1. A mobile m is located under the cover of a given base station BSb of the network, with the index b such that 1 b <- J. The mobile m is a mobile terminal equipment capable of communicating in the network. It includes a transceiver and a control logic. For example, a mobile is a mobile cellular radio terminal. The interference signal ratio CIR ("Carrierto-Interference Ratio"), that is to say the ratio of the power demand in a traffic channel by the mobile m on the interference power received by the mobile is greater than or equal to a signal to interference ratio ym = (C / I) t, target m (t = "target" in English), ie: Pr, m U Iown + 'other + Noise (1) In the relation (1 ). Pr, m is the power received by the mobile m; Iown is the interference power intrastation reviewed by the mobile m and due to the common channels and traffic channels of other mobiles having active downlinks with the BSb station; and

  'other is the interference power interstation reviewed by the mobile m and due to BS1 BSJ base stations other than the BSb BS BS; a is an orthogonality factor between 1 and 0 and equal to 1 if there is no orthogonality between the codes of the descending channels from the same

  base station BSb, and equal to 0 if their orthogonality is perfect; Noise is the thermal noise power of a mobile receiver.

  The relation (1) is written by specifying the powers.

  PTCH, mgb, m j = J a (Pb ù PTCH, m) gb, m + E Pjgj, m + Noise j = 1, jib In relation (2).

  Pb is the total transmit power of the base station BSb; PTCH, m is the transmission power of the traffic channel for the downlink allocated by the base station BSb to the mobile m; and

  gj, m is the attenuation between 0 and 1 equal to the ratio of the power reviewed by the mobile receiver m on the power transmitted in the traffic channel of the downlink from the base station BSj to the mobile m, 1 ' index j being such as

  1 5 J; The attenuation gj, m depends on (2) the distance-based attenuation, shadowing effects, mobile antenna loss and gains m and BSj base station, and additional losses possible.

  If the mask effect is neglected, the attenuation occurring in the reviewed power Pu, m by the mobile ma the distance uj, m of the base station BSj is expressed inversely in proportion to a power of this distance and therefore according to a negative exponent r) of this distance, instead of the attenuation gj, m. The powers in relation (1) are then expressed in a manner similar to those in relation (2): Pr, m ù PTCH, mub, m 'own ù (Pb-PTC: H, m) ub, mj The negative exponent II is referred to as the attenuation factor and is typically in the range of about -3 to about -4. The relation (2) is then written: 1 / Ph -1 1 J_J P '' + Noise a + Juh, mn \ PTCH, m, J PTCH, mub, m J = 1, PTC'H, muh, m jxh Relation (3) shows that the interference signal ratio C / I is strongly dependent on the interference power Iother due to the other stations BSj with j ~ b, expressed by the second member of 25> ym (3).

  denominator. Interference power is an important factor in limiting the capacity of the network. For each mobile check m in the CDMA network RE, an interference factor fm is defined as the ratio of the interference power Iother reviewed by the mobile m coming from the other stations on the reviewed power from the respective base station BSb: 'other 1 j = J __ ~ Pjgjm' own + PTCH, mgb, m Pbgb, mj = 1, fm = (4) jib

  The interference factor fm strongly depends on the position of the mobile. When the traffic from the base stations is uniform, it is reasonable to consider that all the stations have the same total power of emission, ie Pb = Pi with 1 5 j <_ J. The factor fm becomes: j = J fm = gj, mj = 1 gb, rn ub mj * bj = J

  (5) j = 1, jtb The difficulty and complexity of the calculations for determining the load on the network derive mainly from the expression of the fm factor according to the prior art. Indeed, the mathematical expression of the distances rj, m depends on the positions of the base stations. The greater the number J of considered base stations, the more complex the calculation.

  According to the invention, the interference factor is evaluated by means of an analytical calculation taking into account

  account the sectorization of at least one cell of the network so as to satisfy the capacity of the cell represented by the maximum number of mobiles in the cell, i.e. the maximum traffic intensity in the cell, according to the number of co-located base stations that the cell counts, that is to say according to the number of sector of the cell. The interference factor is determined according to different sectoring strategies or hypotheses, such as bi-sectoring or tri-sectorization, in order to select the sectorization resulting in the most efficient network.

  Referring to FIG. 2, the digital cellular radio network RE comprises base stations BS1 through BSJ and C1 cells CI with I a natural integer greater than 1 and I J. Each of C1 to C1 cells is susceptible to to understand N base stations among the J base stations BSI to BSJ, with N a natural integer and N <_ J. For example, N is less than four. The mobile m is located under the coverage of a given base station BSsb of a given sector Ss of a given cell Cb of the network RE, with the index s such that 1 s QN and the index b such that 1 b. Q is the number of sectors of the given cell Cb, and may be different from one cell to another in the network. For example, the network RE comprises in particular cells C1 and Ci each covered by a single omnidirectional base station BSI, BSj, with 1 <- I and 1 J, an IC cell covered by two directional base stations BSJ_I and BSJ, and a cell Cb covered by three directional base stations. The directivity of each of the base stations BSI at BSJ is represented by a thick arrow.

  As shown in FIG. 3, the interference factor evaluation method according to the invention comprises steps E1 through E6. The method is implemented in a computer or workstation or other computer system. The steps of the interference factor evaluation method are executable for any sectorization hypothesis, i.e. for any desired sector number. Once the process executes according to a sectorization hypothesis, the interference factor evaluation method can be executed for other sectorization hypotheses and thus plan the sectorization of a cell or a network that is the most efficient and thus obtain a planned radiocommunication network. At the preceeding step E1, the base station transmit power P (u, 0), without neglecting the mask effect, and the attenuation g (u, 0) at a point (u, 0). on the network surface RE where the mobile is likely to be are defined as continuous functions. The coordinates of the point are, for example, polar coordinates u and 0 originating from the given base station BSsb. The construction of a network model is based on the invention on the replacement of the discrete base station distribution according to the prior art by a pBS base station density which is a continuous function. The calculation of the fm factor is considerably simplified by the continuous base station density function.

  At the previous stage E, the attenuation g (u, 0) ("path loss" in English) of the mobile m with respect to a base station is expressed, on the one hand, inversely in proportion to a power of the distance u of the mobile ma the base station, therefore as a function of a negative exponent r) of this distance u, and on the other hand, as a function of an angular propagation term G (0) depending on the antenna gain directional of the base stations: g (u, 0) = a G (0). In step E2, the base station continuous density pBs (u, 0) is expressed as a number of base stations of the network per surface unit at each point on the network surface. The base station density being variable on the network, it is a priori variable according to the coordinates (u, 0) of the point. For example, the base station density PBS may be stepwise variable, equal to constants respectively in predetermined areas such as concentric rings centered on the given base station BSsb, or may be more simply constant over the entire area covered by the network. The power reviewed by the mobile in the sector gives Ss not only depends on the distance r = rsb, m between the given base station BSsb server of the given sector and the mobile m, but also with angles 0 characterizing the relative positions of base stations, other than the given base station BSsb, with respect to the mobile m, and thus depends on the directivity of the mobile antenna m. In the area covered by the base station BSsb, the mobile reception m situated at a distance r from the base station BSsb is disturbed by the transmissions of the base stations of the other cells and the transmissions of the base stations daps. the other sector (s) of the given cell Cb. Thus, when the mobile m is positioned at a distance r from the given base station] 3Ssb, there are notably NS (u, 0) u of the base stations which contribute to the IOST interstation interference power in a sector of crown angle dO and width of the. The elementary power reviewed by the mobile m under the coverage of these base stations is: pBS (u, 0) u dO P (u, 0) g (u, 0). In step E3, each cell Ci, with 1 i I, is modeled by a regular coverage surface having as a center a respective base station BSj of the network or co-located base stations. The regular surface may be polygonal, but is preferably a circle so as to simplify the calculations. The sectors S1 to SQ are then circular with a predetermined radius Rs, as shown in FIG.

  Emissions from other base stations disturbing reception in the mobile m are located in a sector of crown [01r 02] defined in step E4. The crown sector is concentric to the given cell or sector Ss.The inner radius of the crown sector is equal to 2Rs - r since the distance between two stations is at least 2Ro and the cells and circular sectors do not overlap and have their contours at best tangential or adjacent. The outer radius R of the crown sector [01, 02] is at most equal to the very large radius of the area covered by the network RE. The angle [01, 02] of the crown sector depends on the orientation and directivity of the mobile antenna m.

  In the previous modeling, the determined interstation power is the interstation power between the given base station BSsb and the base station of one of the other cells. But each of the co-located base stations of another cell interferes with the base station given BSsb. Therefore, the interstation power between the given base station and the base station of the other cell is multiplied by the number of base stations of said other cell q (u, 0), equal to the number of sectors of said other cell cell to take into consideration all base stations in each cell. For example, one of said other cells is covered by a single base station with an omnidirectional antenna, the sector number q of that cell being equal to 1. In another example, one of said other cells, called a bi-directional cell, -sectorisee, is covered by two base stations each with a directional antenna, the number of sector q of this cell being equal to 2. In step E5, the sum of the power interstations between the given base station and the stations of basis in other cells that the

  given cell Cb is determined by integrating the product of the number of sectors q (u, 0) per cell, the continuous density of co-located base station pBs (u, 0), the base station transmitting power P (u, 0) and of the attenuation g (u, 0) = a G (0) on all the points (u, 0) positioned on the surface of the crown sector defined above [01, 02]: Iother = 'q (u, 0) pBs (u, 0) P (u, 0) unG (0) u of the dO ~ 2 RS - r

  The q (u, 0) pBs (u, 0) u of the base stations are the base stations of the network RE other than those covering the given cell Cb, without omitting the contribution of the base stations co-located in cells different from that Cb of the given base station BSsb due to sectorization. Since the base stations in the given cell are co-located, the interstation power of each base station of the BS is different from the base station. The given given cell is equal to the mobile and the following term is then added to the expression of the interstation power other s = Q Psb (u,) a 1 G (0), s = 1 s sb Psb (u , 0) being the transmission power of any co-located base station of the given cell Cb Q being the total number of sectors of the given cell Cb; and Gs being the directional antenna gain of said each base station of the given cell in the direction of the mobile m, and the product u'1Gs being the attenuation at the reception, the mobile m is positioned relative to 1 '. transmitting from said each base station of the given cell. Therefore, the sum of the interstation powers between the given base station and all the base stations of the network is equal to = Q 30 Iother = fR-sr_r q (u, 0) pBS (u, O) P (u, 0 ) uIG (0) udud0 + Psb (u, 0) u1 Gs (0) s = 1 stsb In step E6, the interference factor fm of the mobile m located in the given sector Ss of the given cell CID is defined as the ratio of the interference power Iother reviewed by the mobile m from all other base stations on the reviewed power from the base station gives BSsb s = Q rq (u, 0) pB S (u, 0 ) P (u, 0) u 11G (0) udud0 + Psb (u, 0) u 11 G s (0) 2 Rs - rs = 1 s tsb Psb (u, 0) u 1Gsb (0) In the above formula Psb (u, 0) denotes the transmission power of the given base station BSsb or of one of the base stations of the given cell and Gsb (u, 0) is the attenuation due to the antenna of the station. basic BSsb data.

  In a preferred example, the network is homogeneous. The base station density pBs (u, 0) is then constant in the network RE, or at least on the surface of radius R, ie PBS (U, 0) = PBS, and the number of sectors per cell is identical aq (u, 0) = Q for all the cells of the network. The base station transmit power is constant and noted P in the following equations, ie P (u, 0) = P. The interference factor fm of the mobile m lies in the sector Ss of a given cell Cb covered by an antenna of a given base station BSsb of the given cell is: fm (u, 0) = 30 s = o ~ zn r QpBsPu G (0) ududO + Phu "EGs (0) RS - rs = l stsb Phu G.rb (0) By putting f (u) = fn, (u, 0) _ -r IRS -, Pu udu

  P hu'l s = G. (0) .rz G (0) dO + * sb Gsh (0) Gsh (0) We obtain fm (u, 0) = Q pBS f (u) 1 21c Finally the factor d interference fm can be written in dependence on a function of the polar coordinate u: fm (u, 0) = ae f (u) + be with: 1 r G (0) dO ae = Q PBS 2n G. sb (e), and s = Q

  For example, when Q = 3, we can derive from the interference factor fm the capacity of a cell site at three co-located base stations. .

15

  The invention described herein relates to a method of evaluating an interference factor in a radio communication network. According to a preferred implementation, the steps of the method of

  The invention is determined by the instructions of a computer program incorporated into a processor. The program includes program instructions which, when said program is loaded and executed in the processor whose operation is then controlled by the execution of the program, perform the steps of the method according to the invention. Accordingly, the invention also applies to a computer program, especially a computer program on or in an information recording medium, adapted for carrying out the invention. This program can use any programming language, and be in the form of source code, object code, or intermediate code between source code and object code such as in a partially compiled form, or in any other form desirable to implement the method according to the invention. The information recording medium may be any entity or device capable of storing the program. For example, the medium may comprise storage means or recording medium on which is stored the computer program according to the invention, such as a ROM, for example a CD ROM or a microelectronic circuit ROM, or a USE key, or a magnetic recording means, for example a diskette (floppy disc) or a hard disk. On the other hand, the information medium can be a transmissible medium such as an electrical or optical signal, which can be conveyed via an electrical or optical cable, by radio or by other means. The program according to the invention can in particular be downloaded on an internet-type network. Alternatively, the information carrier may be an integrated circuit in which the program is incorporated, the circuit being adapted to execute or to be used in the execution of the method according to the invention.

Claims (8)

  1 Method for evaluating an interference factor in a radio communication network (RE) having sector-divided (C3) cells modeled (E3) by regular base station-based (BSS) surfaces, according to which transmission power for a downlink from a given base station (BSsb) to a mobile (m) located in a given sector (Ss) of a given cell (Cb) covered by at least the given base station is evaluated based on a ratio of the mobile received power from the base stations in cells other than that including the given base station on the reviewed power from the given base station, characterized in that comprises the following steps of: defining (E1) a base station transmitting power and an attenuation as continuous functions of the position of a point on the network with respect to the given base station (BSb), to express ( E2) a continuous density of base station in cha that point on the network, define (E4) a sector of crown where are located base stations disturbing the reception in the mobile (m), determine (E5) a first power received by the mobile and due to the base stations in said other cells by integrating the product of the sector number per cell, the base station density, the transmitting power and the attenuation on the surface of the crown sector, determining (E5) a second power reviewed by the mobile and due to at least one base station of the given cell different from the given base station according to the product of the transmission power of the given base station and the attenuation to the mobile with respect to the station of different base, and evaluate (E6) an interference factor by summing said first and second determined powers.   2 - Method according to claim 1, wherein the base station density is constant.   3 - Method according to claim 1 or 2, wherein the sector number per cell is identical for all cells.   4 - A method according to any one of claims 1 to 3, wherein the attenuation at a point on the network is a function of a power of the distance between the point and the base station in the given cell, with a negative exponent.   A computer program comprising program instructions adapted to implement the method of any one of claims 1 to 4 when said program is executed by a processor.   6 - Recording medium on which is stored a computer program according to claim 5.   7 - A method of planning a radio communication network using an interference factor evaluation method according to any one of claims 1 to 4   8 - Radiocommunication network obtained by the implementation of a planning method according to claim 7.