FR2785488A1 - Repeater for use with mobile telephones includes donor aerial and coverage aerial linked by repeater, with metal screen preventing unwanted aerial coupling - Google Patents

Abstract

The system uses a reflector adjacent to one aerial to prevent aerial-to-aerial coupling. The repeater for use in mobile telephone systems is installed on a single support (10). It includes at least one aerial called the donor aerial (AD) and a second aerial called the coverage aerial (AC). These serve to receive and re-transmit the signals, without transposition of frequency, between a central station and at least one telephone operating within a specific range of frequency. There is a repeater circuit and a decoupling device (D) mounted between the aerials. The decoupling between the aerials DEC is given by the equation DEC= Gmax + 10dB, where Gmax is the maximum gain of the repeater system. The maximum gain lies between 50dB and 80dB. Decoupling may be provided by a metallic reflector which is mounted in immediate proximity to one of the two aerials (AD and AC).

Description

REPEATER SYSTEM, PARTICULARLY IN THE FIELD OF
MOBILE TELEPHONY
The invention relates to a repeater system, in particular in the field of mobile telephony.

 In the telecommunications sector, a repeater system has the function of extending the coverage of a central transmitting and / or receiving station often called "Base Transceiver Station".

 In general, when there is a coverage hole between several central stations or when the coverage area of a central station has to be extended to a rural area of limited interest, along motorways for example , operators prefer to set up repeater systems rather than installing a central station which is a very heavy investment.

 Concretely, the repeater system is placed at the limit of coverage of the central station, and it is equipped with at least one antenna with high gain and great directivity which is pointed towards the central station.

 The function of this antenna or donor antenna is to recover an even weak electromagnetic field received at this location, and to route it by a coaxial link with minimum losses at the input of a repeater circuit. After switching, the signal received by the repeater circuit is significantly amplified, filtered and fed back to a so-called coverage antenna which has the function of covering an additional area that is imperfectly or not covered by the main station.

 In the repeater system considered here, there is no frequency transposition, that is to say that the frequency of the signal received from the central site is the same as that which is used to cover the complementary area and which is therefore received by the mobile in a mobile telephone system. Conversely, the transmission frequency of the mobile is communicated to the coverage antenna and the corresponding signal is routed by a coaxial cable in the repeater circuit where it is amplified, reinjected after filtering towards the donor antenna and routed to the central station. The repeater circuit is in a way a bidirectional switching system with amplification in each channel.

 In the present case, repeater systems operating in broadband are considered, that is to say systems which can repeat channels in transmission and in reception wherever these channels are in the allocated frequency band.

 The best coverage of the desired area is done when we know how to balance the uplink (towards the central station) and downlink (from the central station) so that communications are made as much in one direction as in the other. This is achieved by means of adjustable gains of the amplifiers of the two channels, and by integrating therein the gains of the associated antenna systems.

 The use of the most efficient outdoor repeater system is closely linked to the performance of the repeater itself, in particular its maximum gain and its maximum output power, and its operation is conditioned by a predominant quantity which is the decoupling between donor and cover antennas. Indeed, the reuse of the frequency imposes a significant decoupling between the input and the output of the repeater system, and therefore between the donor and coverage antennas.

In general, the decoupling between two antennas depends on:
- their horizontal and vertical radiation patterns,
-of their lateral and rear radiation,
-of their angular positioning in relation to each other, and
-of their vertical and / or horizontal distance from each other.

 Concretely, installing a high gain repeater system on a single support is a great difficulty. Indeed, if a gain of 80dB for the repeater circuit is current, on the other hand a decoupling of the order of 90dB is very difficult to obtain.

 The object of the invention is to design a repeater system which makes it possible to obtain the desired decoupling between the donor and covering antennas installed on the same support, knowing that the decoupling device must be designed to be able to be used with different types of 'antennas.

To this end, the invention proposes a repeater system, in particular in the field of mobile telephony, this system being installed on the same support and comprising at least one so-called donor antenna and a so-called coverage antenna for receiving and retransmitting signals. without frequency transposition between a central station and at least one mobile phone in an assigned frequency range, and at least one repeater circuit and a decoupling device mounted between said antennas, characterized in that the DEC decoupling is such that:
DEC = Gmax + 10dB where Gmax is the maximum gain of the repeater circuit, and in that the maximum value of this gain is between 50dB and 80dB.

 The decoupling device consists of a metal reflector attached in the immediate vicinity of one of the two donor or cover antennas, and this reflector consists of a central panel which is bordered by two side panels, each side panel forming an angle internal a with the central panel of the order of 130 to 150, this angle preferably having a value of 135 to 140.

 In general, the reflective panel extends over a height of the order of lm to 1.20m, its central panel extends over a width equal to 0.6k-0.8k, X being the length d wave corresponding to the central frequency of the assigned frequency range, and each of its side panels extends over a width substantially equal to.

 Advantageously, the decoupling device is attached around the cover antenna.

 According to a preferred embodiment, the donor and cover antennas are mounted substantially at the same height and can be separated from each other by a horizontal distance of the order of 2 to 6 meters to obtain decoupling. at least 90dB between the antennas.

 To obtain such decoupling, the repeater system can be installed on the same support which consists of a mast with a height of the order of 12 meters, said antennas being mounted at the upper end of the mast, for example.

 According to another embodiment, the donor and coverage antennas can be separated from each other by a distance of the order of 10 meters vertically to obtain a decoupling of at least 110dB between the antennas.

 To obtain such decoupling, the repeater system can be installed on the same support which is constituted by a mast with a height of the order of 25 meters, the donor antenna being mounted at the end of the mast, for example.

 According to yet another embodiment, the donor and coverage antennas can be separated from each other by a distance of 2 to 8 meters horizontally and of the order of 1 to 4 meters vertically to obtain a at least 100dB decoupling between antennas.

 To obtain such decoupling, the repeater system can be installed on the same support which is constituted by a mast with a height of 18 meters, the donor antenna being mounted at the end of the mast, for example.

 Generally, the repeater circuit is bidirectional and includes an uplink when signals are sent from a mobile phone to the central station, and a downlink when signals are sent from the central station to a mobile phone, the phone mobile being located in the area covered by the coverage antenna.

 According to an exemplary embodiment, the uplink and downlink channels comprise at least one filtering circuit and one amplifier circuit, which are mounted between two switching circuits or duplexer circuits respectively connected to the donor and coverage antennas by coaxial links.

 The repeater system can be installed on a metal, concrete or wooden mast, self-supporting or guyed.

The repeater system according to the invention applies in particular to the field of mobile telephony in the GSM frequency range (900MHz or 1800MHz) or
UMTS (2000MHz or 2200MHz).

Other characteristics, advantages and details of the invention will emerge on reading the additional description which will follow with reference to the accompanying drawings, given solely by way of example and in which:
FIG. 1 represents a possible implementation of a repeater system according to the invention,
FIG. 2 is a simplified view of the decoupling device of the repeater system of the installation shown in FIG. 1,
FIG. 3 represents in the form of a schemabloc the electronic circuits of the repeater circuit, and
FIGS. 4 and 5 represent two other possible layouts of a repeater system according to the invention.

 Or a central transmitting / receiving station in the field of mobile telephony. The omnidirectional antenna which equips this station has a range which covers a certain area.

 To extend the coverage area of this station, a repeater system is provided installed on the edge of this area.

 The repeater system according to the invention is installed on the same support, and comprises at least one donor antenna AD, a coverage antenna AC, a repeater circuit CR and a decoupling device D.

The decoupling device D is designed to obtain a DEC decoupling such as:
DEC = Gmax + lOdb where Gmax is the maximum gain of the repeater circuit.

 According to the embodiment illustrated in FIG. 1, the repeater system is installed on a mast or pylon 10 which is advantageously of the telescopic type and comprises three sections 10a-10c with a height of the order of 6 meters each, for example .

 The mast 10 is deployed so that the antennas AD and AC are mounted at a height H of the order of 12 meters to obtain the best possible coverage, knowing that this height has the advantage of not requiring a permit to build in France to do this installation.

The donor antennas AD and of coverage AC are situated substantially at the same height and can be separated from each other horizontally by a distance of the order of 2 to 6 meters to obtain a decoupling DEC of at least 90dB between the AD antennas and
AC. To obtain the desired distance horizontally, the antennas AD and AC are fixed on intermediate supports 15, in the shape of an L for example, which are mounted at the end of the upper section 10c of the mast 10.

 The donor antenna AD is a directive antenna oriented towards the central station. It has an opening in horizontal and vertical radiation of the order of 25, and a front / rear ratio of the order of 25dB minimum, for example. This donor antenna AD can be of the rake type.

 The coverage antenna AC is for example of the panel type whose horizontal radiation depends on the area to be covered, it is most often between 60 and 100 approximately.

 The mast 10 is held in a vertical position by a guy, the guys 12a of the lower section 10a of the mast being metallic while the guys 12b of the upper sections 10c-10e are made of fiberglass, for example.

The repeater system working without frequency transposition, it is necessary to provide a decoupling device D between the donor antennas
AD and AC coverage.

The decoupling device D shown in FIG. 2 is attached around the cover antenna
AC, and it is constituted by a metallic reflector.

 The metal reflector comprises a central panel 20 bordered by two side panels 22 which form an internal angle ss of the order of 135 with the central panel 20.

 The central panel 20 extends over a width of the order of 0.6 to 0.8S, X being the wavelength corresponding to the central frequency of the allocated frequency range, while each side panel 22 s' extends over a width of the order of k. The reflector extends over a height of the order of 1 m to 1.20 m, which corresponds to a panel antenna whose height generally does not exceed such a value.

 By way of example, for a central frequency of 913 MHz which corresponds to a wavelength of about 0.33 m, the central panel 20 will have a width of around 20 cm and each side panel 22 a width of around 33cm. This central frequency corresponds to that of the GSM band of 900MHz and more precisely 870MHz-960MHz.

 In Figure 3, there is shown the repeater circuit CR which is divided into two transmission paths VE and reception VR.

 The coverage antenna AC is connected by a coaxial link C1 to the input of a switching circuit constituted by a duplexer circuit DPX. In transmission, when a signal is transmitted by a mobile and received by the coverage antenna AC, the signal is routed by the DPX duplexer to a filter circuit F, amplified by an amplifier circuit A with high gain and transmitted to the input of a second DPX duplexer connected to the donor antenna AD by a coaxial link C2 to be routed to the central station.

The reception channel VR is similar to the transmission channel VE and also includes a filtering circuit
F and an amplifier circuit A.

 The gains of the two amplifiers A are paid on site at the time of installation.

 In Figure 4, there is shown another installation of the repeater system on a mast with a height H of the order of 18 meters.

 The mast 10 consists of four telescopic sections 10a-10d. The donor antenna AD is installed towards the end of the upper section 10d of the mast 10, while the cover antenna AC is installed towards the end of the section 10c of the mast 10.

 Concretely, the antennas AD and AC are mounted on intermediate supports 15 so as to separate them from each other both horizontally and vertically.

 The donor and AD coverage antennas AC can be separated from one another by a distance of 2 to 8 meters horizontally and a height h from 1 to 4 meters to obtain a DEC decoupling of at least 100dB between the AD and AC antennas.

 In Figure 5, there is shown another installation of the repeater system on a mast with a height H of the order of 25 meters.

 The mast 10 is always of the telescopic type and comprises five 10-axis sections with a height of the order of 6 meters, for example.

 The donor antenna AD is installed on the upper section 10e of the mast 10 by a vertical antenna mast 15, while the cover antenna AC is installed against the intermediate section 10c of the mast. The two antennas AD and AC are therefore separated from each other by a height h of at least 10 meters to obtain a cutting of at least 110 dB between the antennas.

 In the examples described above, the mast 10 is metallic, but it could also be made of concrete or wood, the choice being a function of the environment.

Claims (17)

 1. Repeater system, in particular in the field of mobile telephony, this system being installed on the same site and comprising at least one so-called donor antenna (AD) and one so-called coverage antenna (AC) for receiving and re-transmitting signals without frequency transposition between a central station and at least one mobile telephone in an assigned frequency range, and at least one repeater circuit (CR) and a decoupling device (D) mounted between said antennas, characterized in that decoupling DEC is such that:  DEC = Gmax + 10dB where Gmax is the maximum gain of the repeater circuit (CR), and in that the value of this maximum gain is between 50dB and 80dB.  2. repeater system according to claim 1, characterized in that the decoupling device (D) is constituted by a metal reflector attached in the immediate vicinity of one of the two donor antennas (AD) or cover (AC).  3. repeater system according to claim 2, characterized in that the reflector consists of a central panel (20) which is bordered by two side panels (22), each side panel (22) forming an internal angle (a) with the central panel (20) of the order of 130 to 150.  4. repeater system according to claim 3, characterized in that the internal angle (a) has a value of 135 to 140.  5. repeater system according to claim 3 or 4, characterized in that the reflective panel extends over a height of the order of lm to 1.20m.  6. repeater system according to any one of claims 3 to 5, characterized in that the central panel (20) of the reflector extends over a width equal to 0.6R-0.8k, X being the wavelength corresponding to the center frequency of the assigned frequency range.  7. repeater system according to claim 3 to 6, characterized in that each side panel (22) of the reflector extends over a width substantially equal to X, A. being the wavelength corresponding to the center frequency of the assigned frequency range.  8. repeater system according to any one of the preceding claims, characterized in that the decoupling device (D) is attached around the cover antenna (AC).  9. repeater system according to any one of the preceding claims, characterized in that the donor (AD) and cover (AC) antennas are mounted substantially at the same height and are separated from each other by a distance of the order of 2 to 6 meters to obtain a decoupling of at least 90dB between the antennas.  10. repeater system according to claim 9, characterized in that the repeater system is installed on the same support which consists of a mast (10) with a height of the order of 12 meters, said antennas (AD, AC) being mounted towards the upper end of the mast (10).  11. repeater system according to any one of claims 1 to 8, characterized in that the donor (AD) and coverage (AC) antennas are separated from each other by a distance of the order of 10 meters vertically to obtain a decoupling of at least 11OdB between the antennas.  12. repeater system according to claim 11, characterized in that the repeater system is installed on the same support which is constituted by a mast (10) with a height of the order of 25 meters, the donor antenna (AD) being mounted towards the end of the mast.  13. repeater system according to any one of claims 1 to 8, characterized in that the donor (AD) and coverage (AC) antennas are separated from each other by a distance of 2 to 8 meters in horizontal and of the order of 1 to 4 meters vertically to obtain a decoupling of at least 110dB between the antennas.  14. repeater system according to claim 13, characterized in that the repeater system is installed on the same support which is constituted by a mast (10) with a height of 18 meters, the donor antenna (AD) being mounted towards the end of the mast.  15. repeater system according to any one of the preceding claims, characterized in that the repeater circuit (CR) is bidirectional and comprises an uplink channel (VE) when the signals are transmitted from a mobile telephone to the central station, and a channel downlink (VR) when signals are transmitted from the central station to a mobile phone, the mobile phone being located in the area covered by the coverage antenna (AC).  16. Repeater system according to claim 15, characterized in that the uplink (VE) and downlink (VR) channels include at least one filter circuit (F) and one amplifier circuit (A), which are mounted between two circuits of switch or duplexer circuits (DPX) respectively connected to the donor (AD) and cover (AC) antennas by coaxial links (C1, C2).  17. Repeater system according to any one of the preceding claims, characterized in that the repeater system is installed on a mast (10) of metal, concrete or wood.