RU2205512C1 - Mobile radio communication system - Google Patents

Abstract

FIELD: mobile communication systems. SUBSTANCE: proposed system built around principles other than those used for cellular system which enables reducing its cost by about 1.5 times has functionally coupled ground- based main and additional base stations, mobile stations, repeaters, switching and radio pieces of equipment including transceiving devices. Main base stations are disposed in centers of grid that divides terrain into equal-size square cells with additional base stations installed in vicinity of their centers; coverage zones of main base stations are not intersecting on purpose. Main base stations, additional base stations, and repeaters related to additional base stations are disposed for joint complete coverage of terrain. Transceiving devices of main base stations operate at frequencies of at least one group of duplex frequencies. Transceiving devices of additional base stations servicing grid bands in relatively perpendicular directions jointly with repeaters operate at frequencies of at least two groups of duplex frequencies. Neither of three groups includes same frequencies. EFFECT: reduced manufacturing cost and maintenance charges. 1 cl, 4 dwg

Description

 The invention relates to the field of communications, and more particularly to mobile radio communication systems.

 The invention allows in some cases to simplify the construction of a communication system, provides additional opportunities for the design of a communication system, increases the technical and economic efficiency of the system, taking into account all the components that affect its technical performance and overall cost.

 A well-known mobile radio communication system comprising ground-based base stations, switching and radio equipment using the principle of frequency reuse, in which different frequency bands are used in systems that are close to one another (6-angle cell-cells), and after several cells, these frequency bands are repeated (M. V. Ratinsky. Fundamentals of cellular communication / edited by DB Zimin - M .: Radio and communications, 2000, p. 65 [1]). Cells partially overlap.

 A known communication system containing base stations and signal repeaters installed on or adjacent to them, the frequency range of which coincides with the frequency range of the mobile station of the corresponding radio communication system (RF Patent 2161866, N 04 V 7/26, 2000, "Noise-immune radio communication system" [ 2]).

 The disadvantages of the cellular communication system [1] and its various improvements, similar to [2], as compared to the claimed one, include the fact that in some cases the scheme of system construction adopted in them does not allow simplifications, does not provide additional opportunities for the design of systems in them not fully utilized the technical capabilities to reduce the cost of creating and operating the system.

 As a prototype, a well-known mobile communication system is selected, including, among other things, functionally connected ground base and mobile stations, repeaters, switching and radio equipment, including transceiver devices, and implementing the method according to the patent of the Russian Federation 2177672, Н 04 В 7/26, 7/208 , Н 04 Q 7/30, Н 04 L 7/00 "Method for connecting subscribers of a trunked communication system". In it, a repeater is used to connect mobile stations located in zones of different base stations.

 The disadvantage of the prototype compared with the claimed system is that it does not provide additional capabilities in the design of systems, does not simplify the construction of a communication system and therefore does not allow to increase the technical and economic efficiency of the communication system as a whole and reduce its cost.

 The invention is aimed at increasing the technical and economic efficiency of a communication system due to its new simpler construction, which allows to reduce the number of base stations serving the area, and thereby reduce the cost of a communication system while maintaining the quality of communication and frequency resource and provide additional opportunities for its design.

 A distinctive feature of the claimed invention from the prototype is the deliberate location of the main base stations of the system relative to each other at distances that exclude the intersection of their radio coverage zones, and in the vicinity of the grid nodes, dividing the served area into equal square cells forming parallel grid bands, and installing additional base stations mainly in the vicinity of the centers of square cells and the installation along the axis of the bands of the bands of the relay interacting with them tori with the possibility of joint provision of complete radio coverage of the served area, and at the main and additional base stations (BS) and repeaters installed transceiver devices (PPU) using at least three frequency groups (one for the main and two for additional BS and repeaters), This group does not contain the same frequencies.

, R равно радиусу зоны радиопокрытия базовой станции, а L больше

, но меньше

, при этом установлены дополнительные базовые станции, преимущественно в окрестности центров квадратных ячеек сетки и предпочтительно вблизи узлов коммутации других наземных сетей связи при их наличии на обслуживаемой местности и, в первую очередь, в ячейках, находящихся на пересечениях полос А- и В-направлений и обслуживающих их, а при необходимости и в других ячейках, обслуживающих полосы только А- и только В-направления, в том числе находящихся на полосах, не обслуживаемых установленными указанными дополнительными базовыми станциями, с возможностью обеспечения полного радиопокрытия обслуживаемой местности совместно с основными базовыми станциями и во взаимодействии с расположенными вдоль осей полос А- и В-направлений ретрансляторами с шириной полосы радиопокрытия h, большей L, но меньшей d, при этом на основных базовых станциях установлены приемопередающие устройства с дуплексно разнесенными частотами приема и передачи по крайней мере из одной группы дуплексных частот f, на дополнительных базовых станциях, находящихся на пересечениях полос А- и В-направлений, установлены приемопередающие устройства обслуживания полос А-направления с дуплексно разнесенными частотами приема и передачи по крайней мере из одной группы дуплексных частот FA и приемопередающие устройства обслуживания полос В-направления с дуплексно разнесенными частотами приема и передачи по крайней мере из одной группы дуплексных частот FB, на дополнительных базовых станциях, находящихся в других ячейках полос А-направления, установлены приемопередающие устройства обслуживания полос А-направления с дуплексно разнесенными частотами приема и передачи по крайней мере из одной группы дуплексных частот FA, на дополнительных базовых станциях, находящихся в других ячейках полос В-направления, установлены приемопередающие устройства обслуживания полос В-направления с дуплексно разнесенными частотами приема и передачи по крайней мере из одной группы дуплексных частот FB, причем частоты приемопередающих устройств основных и дополнительных базовых станций обслуживания полос А-направления не совпадают друг с другом, частоты приемопередающих устройств основных и дополнительных базовых станций обслуживания полос В-направления не совпадают друг с другом, частоты приемопередающих устройств дополнительных базовых станций обслуживания полос А-направления и В-направления не совпадают друг с другом, а на ретрансляторах установлены приемопередающие устройства с возможностью ретрансляции сигналов дополнительных базовых станций, обслуживающих полосы А- и/или В-направлений соответственно, и обеспечения работы подвижных станций через указанные ретрансляторы и дополнительные базовые станции обслуживания полос А- и/или В-направлений.A mobile radio communication system is proposed, including, among other things, functionally connected ground base and mobile stations, repeaters, switching and radio equipment, including transceiver devices. Significant distinguishing features from the prototype are the following: the main base stations are located with the possibility of providing disjoint radio coverage zones on the served area in the vicinity of grid nodes covering and dividing, including borders, this area into equal square cells forming parallel stripes of this A-direction grid and parallel B-direction bands perpendicular to A-direction bands, the side of the square cell d being greater than 2R but less than

, R is equal to the radius of the radio coverage of the base station, and L is greater

but less

at the same time, additional base stations have been installed, mainly in the vicinity of the centers of square grid cells and preferably near switching nodes of other terrestrial communication networks, if available on the served area and, first of all, in cells located at the intersections of A- and B-direction bands and serving them, and if necessary in other cells serving the bands of only A- and only B-directions, including those located on the bands not served by the specified additional base stations, with the possibility of providing complete radio coverage of the served area in conjunction with the main base stations and in cooperation with repeaters located along the axis of the A- and B-direction bands with a radio coverage bandwidth h greater than L but less than d, with transceivers installed on the main base stations with are duplexed by the frequencies of reception and transmission from at least one group of duplex frequencies f, at additional base stations located at the intersections of the bands of A- and B-directions, is set transceiver devices for servicing A-direction bands with duplex diversity of receive and transmit frequencies from at least one duplex frequency group FA and transceiver devices for servicing B-direction bands with duplex diversity of receive and transmit frequencies of at least one group of duplex frequencies FB, on additional base stations located in other cells of the A-direction bands, transceiver service devices for A-direction bands with duplex spaced frequencies are installed Receiving and transmitting from at least one group of FA duplex frequencies, at additional base stations located in other cells of the B-direction bands, transceiver devices are installed for servicing B-direction bands with duplex diversity of the reception and transmission frequencies of at least one group of duplex frequencies FB, and the frequencies of the transceivers of the main and additional base stations serving the A-direction bands do not coincide with each other, the frequencies of the transceivers of the main and additional base stations serving B-direction bands do not coincide with each other, the frequencies of the additional base stations serving A-direction and B-direction bands do not coincide with each other, and transponders are equipped with transceivers with the ability to relay signals from additional base stations serving bands of A- and / or B-directions, respectively, and ensuring the operation of mobile stations through these repeaters and additional base stations serving bands - and / or B-lines.

 Below the invention is described in more detail with reference to the drawings, schematically illustrating the implementation of the claimed system.

 The proposed communication system, thanks to the adopted arrangement of the main base stations, the installation of additional BS and repeaters and the installation of the transceiver devices of the above frequency groups corresponding to this scheme, makes it possible to simplify the construction of the communication system, provides additional opportunities for the design of the communication system, reduces the number of base stations required to service the terrain, increases the technical and economic efficiency of the system.

 In Fig.1 shows a diagram of the construction of the inventive communication system, Fig.2 is a fragment of a communication system with radio coverage areas of the main and additional base stations and repeaters, Fig.3, 4 presents fragments of a communication system with two limit locations of the main base stations: radio coverage areas of the main BS and with mutual contact of the radio coverage areas of the main and additional BS.

 The mobile radio communication system contains (Fig. 1) functionally connected ground-based base stations (black circles), additional base stations (renumbered 1 to 8 white circles with arrows showing the direction of signal transmission along the A-direction and B-direction), mobile stations (for example, one mobile station is marked with an asterisk), repeaters (white rectangles - A-direction service, black - B-direction service), the system includes, as usual, switching and radio equipment dovanie, including polyurethane foam. The designations of BS and repeaters are repeated in other figures. In FIG. 1 shows the boundaries (contour) of the terrain served by the radio communication system. A conditional grid is imposed on this area, which covers and subdivides it, including borders, into equal-sized square cells. The mesh cells form the A-direction and B-direction bands shown in FIG.

 The main BSs are located in the vicinity of the grid nodes. Additional BSs are installed mainly in the vicinity of the centers of square grid cells at approximately equal distances from the nearest main BSs and preferably near switching nodes of other terrestrial communication networks, if they are available on the served area (to reduce the distance between them). Repeaters are installed along the axis of the bands of both directions. Transceiver devices are installed on the main BSs, additional BSs, and repeaters.

(этот нижний предел соответствует расположению основных БС на расстоянии 2R друг от друга, показанному на фиг.3). Также L должно быть меньше

(этот верхний предел соответствует такому расположению основных и дополнительных БС, показанному на фиг. 4, при котором окружность зоны радиопокрытия дополнительной БС касается четырех окружностей зон радиопокрытия основных БС). Выход L за указанный нижний предел не позволит уменьшить количество основных БС, а при выходе L за указанный верхний предел появятся участки без радиопокрытия.In FIG. 2 shows an enlarged fragment of a radio communication system. The main and additional BS have the same radius of the radio coverage zone R. The distance d between the main BS is deliberately taken more than 2R to eliminate the intersection of their radio coverage zones. Such an arrangement of the BS is directly opposite to that adopted in cellular communication systems, where the radio coverage areas of the BS overlap to eliminate shading areas. The distance L between the intersection points of the diagonals of the square at the vertices of which the main BSs are located, with the circumferences of their radio coverage zones

(this lower limit corresponds to the location of the main BS at a distance of 2R from each other, shown in figure 3). Also L must be less

(this upper limit corresponds to the arrangement of the main and additional BS shown in Fig. 4, in which the circumference of the radio coverage area of the additional BS touches the four circles of the radio coverage zones of the main BS). Leaving L for the specified lower limit will not allow to reduce the number of main BS, and when L exceeds the specified upper limit, areas without radio coverage will appear.

 Repeaters have a width h of radio coverage bands shown in FIG. 2 and limited by wavy lines, which should be greater than L to exclude the formation of unattended sites on the ground, and should not exceed d to prevent interference of repeaters of adjacent bands in the same direction.

 The operation of the inventive mobile radio communication system is illustrated by the example of the location of the mobile station, shown by an asterisk in figures 1 and 2.

 Let the mobile station (PS) be located outside the radio coverage areas of the primary and secondary BS closest to it. Since the main additional BSs and repeaters are installed with the possibility of joint complete radio coverage of the served area, the PS falls into the radio coverage of the nearest A- or B-directional relay with access to the communication system.

 On the main BSs, FACs are installed with duplex spaced frequencies of reception and transmission from at least one group of duplex frequencies f (if necessary, they can be supplemented with frequencies of other groups). On additional BS serving two intersecting bands of A- and B-directions (in Fig. 1, these are stations 1 ÷ 6), service control panels of A-direction bands with duplex spaced reception and transmission frequencies from at least one group of duplex frequencies FA are installed and BCP service bands with duplex diversity of the reception and transmission frequencies of at least one group of duplex frequencies FB (if necessary, these frequencies can be supplemented with frequencies of other groups). For additional BS serving the bands of one A- or B-direction (in Fig. 1, these are stations 7, 8), PPUs have been installed that serve the corresponding bands with duplex-spaced receive and transmit frequencies from at least one group of duplex frequencies FA or FB respectively (which, if necessary, can also be supplemented by frequencies of other groups).

 In the claimed system, the conditions of electromagnetic compatibility are not violated, since the frequencies of the PUFs of the main BS and additional BSs serving the A-direction bands do not coincide with each other, the frequencies of the PUFs of the main BS and additional BSs serving the B-directional bands do not coincide, also do not coincide with each other and the frequencies of the PUFs of additional BS serving the A-direction and B-direction bands.

 The cells for installing additional BSs in them are selected in a particular area so as to ensure that all bands are served with a sufficient minimum number of additional BSs. On the example of the terrain shown in figure 1, we illustrate how this can be done.

 First, additional BSs are installed in cells located on the diagonal of the largest square that can be distinguished on the grid (stations 1, 2, 3, 4, 5). Each of these additional BSs, together with the transponders, serves two intersecting bands. In FIG. Repeaters serving an additional BS 3 are numbered 1 by 3. Then, other cells are found, when installed in which additional BSs will serve two intersecting bands (station 6). After that, additional BSs are installed in those cells in which one direction is served by the already specified additional BSs. On these additional BS, the control panel will serve only another direction (stations 7, 8). The location of additional BS strictly along the diagonal of the selected square is optional. Additional BS can be shifted to a cell located, for example, closer to the switching node. For example, station 5 can be shifted up, then station 4 must be shifted down, i.e. change their B-direction service bands.

 The minimum required number of frequency groups for servicing the claimed system is three (one group for the main base stations and two groups for additional BSs and relays interacting with them). If it is necessary to exclude inter-channel interference, the number of frequency groups can be increased by 1-3 groups, for example, due to the alternation of the frequency groups of the frequency band of both primary and secondary BS in the bands.

 Using the proposed mobile radio communication system allows, due to a deliberate increase in the distance between the main base stations, to reduce the total number of main and additional BSs providing complete radio coverage of the terrain, compared to the cellular communication system [1], by 1.5-1.6 times with the same inter-channel noise immunity. At the same time, the cost and costs of operating base stations will be reduced. The number of repeaters in the system is approximately three times less than the total number of main and additional BSs, but the cost of repeaters is several times less than the cost of BSs. Therefore, the total cost of the claimed system is approximately 1.4 times less than the cost of the corresponding cellular communication system.

 An example of the implementation of the claimed system is shown in figure 1. Conditionally, 54 primary and 8 additional BS and 25 repeaters are used in this area. When using a cellular structure system, about 115 BS would be required. The cost of creating and operating the claimed system for this particular example is 1.5-1.6 times lower than the corresponding cellular system.

 Thus, the distinctive features of the claimed communication system provide the emergence of new properties that are not achieved in the prototype and analogues.

 The analysis of the prior art made it possible to establish: analogues with a set of features identical to all the features of the claimed technical solution are absent, which indicates the compliance of the claimed communication system with the condition of "novelty."

 The results of the search for known solutions in the field of communication in order to identify signs that match the distinctive features of the prototype of the claimed communication system showed that they do not follow explicitly from the prior art. Also, the popularity of the influence of the actions provided for by the essential features of the claimed invention on the achievement of the specified technical result was not revealed. Therefore, the claimed invention meets the condition of patentability "inventive step".

Claims (1)

A mobile radio communication system comprising, inter alia, functionally connected ground-based base and mobile stations, repeaters, switching and radio equipment, including transceiver devices, characterized in that the main base stations are located with the possibility of providing disjoint radio coverage areas on the served area in the vicinity of the grid nodes covering and dividing this area, including its borders, into equal-sized square cells forming parallel stripes of this grid directions and parallel B-directional strips perpendicular to the A-directional strips, with the side of the square cell d more than 2R, but less

, R is equal to the radius of the radio coverage of the base station, and L is greater

but less

at the same time, additional base stations are installed, mainly in the vicinity of the centers of square grid cells and preferably near switching nodes of other terrestrial communication networks, if available on the served area, and additionally, additional base stations are installed in the cells located at the intersection of A- and B-directions, with each of these additional base stations serving two intersecting bands, then, if necessary, establish additional base stations in those cells in which one direction is served by already installed additional base stations, on these installed additional base stations, transceiver devices serve only the other direction not served by previously installed additional base stations, with the possibility of providing complete radio coverage of the served area together with the main base stations and in cooperation with transponders located along the axis of the A- and B-direction bands with a radio bandwidth Existence h, greater than L, but less than d, with transceivers installed at the main base stations with duplexed transmit and receive frequencies from at least one group of duplex frequencies f, at additional base stations located at the intersections of bands A- and B- directions, transceiver devices for servicing A-direction bands with duplex spaced receive and transmit frequencies from at least one group of duplex frequencies FA and transceiver devices for servicing B-band At the additional base stations located in other cells of the A-direction bands, transceivers for servicing A-direction bands with duplex-separated reception and transmission frequencies of at least duplex diversity transmit and receive frequencies from at least one group of duplex frequencies FB are installed from one group of duplex frequencies FA, at additional base stations located in other cells of B-direction bands, transceiver devices for servicing B-direction bands with duplexed frequencies of reception and transmission of at least one group of duplex frequencies FB, the frequencies of the transceivers of the main and additional base stations serving A-bands do not coincide with each other, the frequencies of the transceivers of the main and additional base stations serving B-bands coincide with each other, the frequencies of the transceiver devices of the main and additional base service stations of the bands of the A-direction and B-direction do not coincide with each other hom, and transponders are equipped with transceivers with the ability to relay the signals of additional base stations serving the bands of A- and / or B-directions, respectively, and ensure the operation of mobile stations through these repeaters and additional base stations of serving the bands of A- and / or B-directions .

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