FR2789807A1 - Cellular mobile radio polarisation diversity base station having transmitters/hybrid couplers vertical/horizontal polarisation dividing and received orthogonal signals hybrid couplers single output combined. - Google Patents

Abstract

The radio base station has two antennas (1,2) which cover opposite sections. Each antenna receives and transmits circular polarisation. Hybrid couplers (3-1,3-2) provide the two orthogonal polarisations for the transmitter, and the two outputs (C1,D1;C2,D2) are passed through sets of hybrid couplers (5-1,5-2) to the receivers (R1,R2) combining orthogonal polarisation signals.

Description

RADIO STATION WITH CIRCULAR POLARIZATION ANTENNA

  The present invention relates to a radio station, usable in particular as a base station in cellular radiotelephony systems. More particularly, the invention relates to a radio station comprising means for processing radio signals, and at least one antenna associated with a hybrid polarization coupler, in which the polarization coupler has at least one input connected to the processing means and two outputs connected to the antenna such that when the two outputs of the polarization coupler deliver two respective radio signals in quadrature in response to a transmit signal received on an input of the polarization coupler, the antenna generates two field components electric orthogonal forming a

wave with circular polarization.

  Such an arrangement of circularly polarized antennas in a radio station is described in patent application WO 97/37440. In this radio station, the antennas emit a circularly polarized field. On reception, the waves picked up to produce the processed signals are linearly polarized. The receiver provides spatial diversity and linear polarization diversity processing to combat channel fading. In order to separate the transmission and reception paths, the antennas of the radiocommunication stations are associated with duplexers. In the case of circular polarization antennas of the type described in WO 97/37440, these duplexers are connected between the antenna and the polarization coupler. The object of the present invention is in particular to propose other arrangements of antennas in radio stations, in order to obtain good reception performance.

  and / or to simplify its design and implementation.

  To this end, in a radio station of the type indicated in the introduction, the radio signal processing means comprise at least one receiver arranged to process at least one input radio signal obtained from an input

  of the hybrid polarization coupler.

  Thanks to this simple station design, the receiver processes one or more signals obtained by mixing, in the hybrid coupler, different components of the electric field picked up by the antenna. This results in a certain smoothing of the disturbances which can affect these components, and therefore a lower sensitivity of the

receptor to these disturbances.

  The hybrid polarization coupler preferably has two inputs, from which two radio input signals supplied to the receiver are respectively obtained, the receiver then being arranged to provide diversity processing on the basis of said radio input signals. Another form of polarization diversity in reception is thus obtained. This version advantageously makes it possible to combat the effects of fading, in particular when the medium

  propagation creates relatively little diversity.

  The radio station may also include several antennas respectively associated with hybrid polarization couplers, the receiver being arranged to combine several radio input signals obtained from respective inputs of the hybrid polarization couplers. A spatial diversity is then obtained in reception, which can be cumulated with the polarization diversity if the radio input signals come from non-homologous inputs of the couplers. It can be noted that this is achieved without the need to incorporate duplexers in the

radio station.

  The antennas can be arranged so as to radiate towards distinct sectors. This type of antenna is particularly suitable for the use of a radio station along a railroad or a road axis, the sectors

  then being diametrically opposed.

  The antennas can also be arranged so as to radiate towards at least one common sector. The provisions of the invention then make it possible to increase in a way

  notable the gain in directivity at reception.

  When one or more duplexers are required, each of them can be connected between an input of the polarization coupler, an input of the receiver and the radio signal source. This provides greater flexibility in the design and choice of antennas. In particular, the duplexer can be placed in the main housing of the

  radio station rather than the antenna outside.

  In particular embodiments: the radio station comprises two antennas respectively associated with two hybrid polarization couplers, and two receivers each receiving two respective input radio signals, a first division means connected between an input of one of the couplers polarization hybrids and a respective first input of the two receivers and a second dividing means connected between an input of the other hybrid polarization coupler and a respective second input of the two receivers; the radio station comprises two other receivers each receiving two respective input radio signals, one of these two signals being supplied by the first division means and the other of these two signals being supplied by the second division means; the radio station comprises at least one radio signal source delivering said transmission signal to an input

of the polarization coupler.

  Other special features and advantages of this

  invention will appear in the description below

  non-limiting exemplary embodiments, with reference to the accompanying drawings, in which: - Figure 1 is a diagram of a radio station according to the invention having a transceiver unit; - Figure 2 is a diagram of a radio station according to the invention having two antennas and a transceiver unit; - Figure 3 is a diagram of an alternative embodiment of the station of Figure 2; - Figure 4 is a diagram of a radio station according to the invention having an antenna and two transceiver units; - Figure 5 is a diagram of a radio station according to the invention having two antennas and two transceiver units; - Figure 6 is a diagram of a radio station according to the invention having two antennas and four transceiver units. With reference to all of FIGS. 1 to 6, the radio stations according to the invention described here by way of example comprise either an antenna 1, or two antennas 1 and 2. Each antenna is for example constituted by two coplanar dipoles Pl , P2 oriented perpendicular to each other. As an example, the Pi dipole can be placed

  horizontally and the dipole P2 vertically.

  Each antenna 1, 2 is associated with a respective hybrid polarization coupler 31, 32. Each of these couplers 31, 32 has two inputs A1, A2 and B1, B2 and two outputs, one Cl, C2 attacking the dipole P1 of its associated antenna 1, 2, the other Dl, D2 attacking the dipole P2 of its

associated antenna 1, 2.

  Each polarization coupler 31, 32 is chosen so that it produces two radio signals in quadrature on its two outputs C1 and D1, C2 and D2. For this purpose, hybrid couplers, called "branchline" couplers, are used, as in patent application WO 97/37440

to which we can refer.

  The components delivered by the outputs Ci and Di of the coupler 3i are thus always in quadrature with respect to each other, so that when they respectively attack the dipoles P1, P2 of the associated antenna, the latter generates two orthogonal electric field components forming a circularly polarized wave. The left or right direction of the circular polarization depends on that of the inputs Ai, Bi of the coupler from which the signal comes. Consider for example the case where a signal attacking the input Ai of the coupler 3i generates a wave with left circular polarization (PCG), while a signal attacking the other input Bi of the coupler 3i generates a wave with

  right circular polarization (PCD).

  In the example of embodiment shown in FIG. 1, the radio station comprises an antenna 1 associated with a hybrid polarization coupler 31, the polarization coupler 31 has its input A1 connected, via a duplexer 41, to a source or transmitter

  radio signal Tl forming part of a transmitting unit-

  reception TR1, and its input Bl connected to an input Fl of a

  receiver Rl forming part of said transmitting unit-

  reception. In order to provide circular polarization diversity processing, the duplexer 41 supplies a second radio signal to another input El of the radio signal receiver R1. The duplexer 41, associated with the polarization coupler 31, separates the transmission and

reception.

  This arrangement of the duplexer provides the advantage, compared with the arrangement which is adopted in radio stations of the type described in WO 97/37440, of being able to house the transceiver unit, together with the duplexer 41, in the main box 6 of the radio station, which is shown in dotted lines in FIG. 1, the antenna 1 and the hybrid coupler 31 then being outside this box. As a result, the installer of the station will be much more free when it comes to the design and choice of antennas. He may also choose to integrate the duplexer into a microwave circuit providing other functions, such as filtering, in order to

limit the cost of the radio stage.

  In the embodiment shown in Figure 2, the radio station includes another antenna 2 which is similarly associated with another hybrid polarization coupler 32 'The antennas 1 and 2 are arranged

  so as to radiate towards the same sector of space.

  In the assembly of FIG. 2, the polarization coupler 31 always has its input Al connected this time directly to the radio signal source Tl, and its input Bl connected to the input El of the receiver Rl. The polarization coupler 32, meanwhile, has its input A2 connected by a coaxial cable to the input F1 of the receiver R1. Its other input B2 is connected to a resistor 10 for

impedance matching.

  The presence of the two antennas 1 and 2 in the radio station makes it possible to combine the advantages of a spatial diversity and a diversity of polarization of the type

  circular in the two input signals of the receiver R1.

  This is due to the fact that the radio signals supplied to the inputs El, F1 of the receiver R1 come from inputs not

  homologs B1, A2 of the polarization couplers.

  In the variant of FIG. 3, the signals processed by the receiver Ri come from homologous inputs B1, B2 of the two couplers so that the diversity processing applied by the receiver R1 provides only diversity

  spatial, possibly associated with a gain in directivity.

  The arrangement of FIG. 2 or 3 is advantageous in the sense that there is no longer any need for a duplexer to separate the transmission and reception paths. However, depending on the performance of the coupler used and the standing wave rate of the antenna in the direction of circular polarization used on transmission, filters not shown, less bulky and expensive than duplexers, may be provided upstream of the inputs E1 and F1 of the receiver Ri, in order to eliminate the

  components of coupling with the powerful emission signal.

  In the embodiment shown in FIG. 4, the radio station comprises a single antenna 1 associated with a polarization coupler 31, and two transceiver units TR1, TR2, with a radio signal source Tl, T2 and a diversity receiver RI, R2. The advantages set out above can be fully obtained for the two transceiver units TR1, TR2. In the assembly shown, the inputs A1 and B1 of the polarization coupler 31 are respectively connected to the radio signal sources Ti, T2 via a corresponding duplexer 41, 42. The input A1 of the polarization coupler 31 is in further connected by a coaxial cable, via the duplexer 41, to an input II of a division module 51 which is incorporated in the main unit 6 of the radio station and which is for example a coupler of the "Wilkinson" type, while the other input Bl of the coupler 31 is also connected by a coaxial cable, via the duplexer 42, to an input I2 of a division module 52 which is identical to the module 51. The division module 51 has two outputs Gi, Hi, one of which, Gl, is connected to the input E2 of the receiver R2 and the other, HI, is connected to the input El of the receiver R1. The division module 52 also has two outputs G2, H2, one of which, G2, is connected to the input F2 of the receiver R2 and the other of which, H2, is connected to the input Fl of the receiver R1. This embodiment has the additional advantage of obtaining, with only one antenna 1, a gain in polarization diversity for each of the two receivers Ri and R2. Again, duplexers can be

  housed in the main box 6 of the station.

  The exemplary embodiment shown in FIG. 5 combines the advantages of the embodiments shown respectively in FIGS. 2 and 4. In this example, there are two antennas, but no duplexers. The inputs A1 and B2 of the polarization couplers 31 and 32 are connected directly to the radio signal sources Tl and T2. The other inputs B1 and A2 of these polarization couplers are, for their part, connected respectively to division modules 51 and 52 which are for example of the same type as those mentioned above. The division module 51 has its outputs G1, Hl connected respectively to the input El of the receiver R1 and to the input E2 of the receiver R2, while the division module 52 has its outputs G2, H2 connected respectively to the input F1 of receiver R1 and input F2 of receiver R2. This embodiment thus provides a gain in diversity, spatial and polarization, for each of the two receivers R1 and R2 if the two antennas radiate

towards the same sector of space.

  An arrangement such as that of FIG. 5 can also be used in elongated cells such as those which run along railway tracks or road axes. In this case, the two antennas 1, 2 are arranged head to tail, so as to radiate towards two sectors

diametrically opposite.

  It is also noted that in this example, the installer of the station has the option of choosing the option of a gain in directivity at reception instead of a gain in polarization diversity. For this, it will suffice, for example, to reverse the connection of the coaxial cable which connects the input A2 of the coupler 32 to the output I2 of the division module 52 with the connection of the coaxial cable which connects the input B2 of the coupler polarization 32

to the T2 radio signal source.

  In the example shown in FIG. 6, the radio station comprises two antennas 1, 2 associated respectively with two polarization couplers 31 and 32, two duplexers 41 and 42, four transceiver units

  TR1, TR2, TR3 and TR4 and two division modules 5'1 and 5'2.

  The division modules 5'1 and 5'2 have a structure similar to that of the division modules 51 and 52 mentioned above, except that they have four outputs G'i1, H'2, J'l, respectively, K'l and G'2, H'2, J'2, K'2 instead of two outputs. They can for example each consist of three "Wilkinson" couplers arranged in two stages. The inputs A1, B1 of the polarization coupler 31 are connected respectively to the radio signal sources Tl, T2, while the inputs A2, B2 of the polarization coupler 32 are connected respectively to the radio signal sources T3, T4. The duplexer 41 is connected between the input A1 of the polarization coupler 31, the radio signal source Tl and the input I'l of the division module 5'1, while the duplexer 42 is connected between the input B2 of the polarization coupler 32, the radio signal source T4 and the input I'2 of the division module 5'2. The four outputs G'l, H'l, J'l, K'l of the division module 5'1 are respectively connected to the inputs E4 of the receiver R4, E3 of the receiver R3, E2 of the receiver R2 and Fl of the receiver Rl, while the four outputs G'2, H'2, J'2, K'2 of the division module 5'2 are respectively connected to the inputs El of the receiver R1, F2 of the receiver R2, F3 of the receiver R3 and F4 of the receiver R4. It is thus possible with this embodiment to further increase the gain in polarization diversity for the four receivers R1, R2, R3 and R4 compared to what it was in the embodiment shown in FIG. 5. One can also envisage, in a manner analogous to what has been described above, to obtain a gain in directivity for this embodiment, by differently connecting the coaxial cables which respectively connect the polarization couplers 31, 32 respectively to the

  radio signal sources Tl, T2 and T3, T4.

  It goes without saying that the embodiments which have been described above have been given for purely indicative and in no way limitative, and that many modifications can be easily made by those skilled in the art without departing from the scope of the invention. Thus, a person skilled in the art could adopt antennas whose geometry differs from that shown for antennas 1 and 2, provided that these make it possible to generate two orthogonal electric field components in

  response to two quadrature radio signals.

  Besides, it could use various types

  known from polarization couplers.

Claims (14)

  1. Radio station, comprising radio signal processing means, and at least one antenna (1) associated with a hybrid polarization coupler (31), in which the polarization coupler (31) has at least one input (A1) connected to the processing means and two outputs (Cl, D1) connected to the antenna (1) in such a way that when the two outputs (Ci, D1) of the polarization coupler (31) deliver two respective radio signals in quadrature in response to an emission signal received on an input of the polarization coupler, the antenna (1) generates two orthogonal electric field components forming a circularly polarized wave, characterized in that the means for processing radio signals comprise at least one receiver (Rl) arranged to process at least one input radio signal obtained from an input (Al, B1)   of the hybrid polarization coupler (31).   2. Radio station according to claim 1, characterized in that the hybrid polarization coupler (31) has two inputs (A1, B1), from which two radio input signals are supplied respectively to the receiver (R1) and in which receiver (R1) is arranged to provide diversity processing based on said input radio signals.   3. Radio station according to claim 1 or 2, characterized in that it comprises several antennas (1, 2) respectively associated with hybrid polarization couplers (31, 32), and in which the receiver (R1) is arranged for combine several radio input signals obtained from respective inputs (A1 or B1, A2 or B2)   hybrid polarization couplers (31, 32) -   4. Radio station according to claim 3, characterized in that the antennas (1, 2) are arranged so as to radiate towards distinct sectors. 5. Radio station according to claim 4, characterized in that said sectors are diametrically opposite. 6. Radio station according to claim 3, characterized in that the antennas (1, 2) are arranged   so as to radiate towards at least one common sector.   7. Radio station according to claim 6, characterized in that at least two radio input signals are obtained from non-homologous inputs (B1, A2) of   separate polarization couplers (31, 32) -   8. Radio station according to any one of   Claims 1 to 7, characterized in that it comprises   two antennas (1, 2) respectively associated with two hybrid polarization couplers (31, 32), two receivers (Rl, R2) each receiving two respective input radio signals, a first dividing means (51) connected between an input (A1 or B1) of one of the hybrid polarization couplers and of the first respective inputs (El, E2) of the two receivers (Rl, R2), and a second dividing means (52) connected between an input (A2 or B2) from the other hybrid polarization coupler (32) and seconds   respective inputs (Fl, F2) of the two receivers (Rl, R2).   9. Radio station according to claims 6 and 8,   in which each of the receivers is arranged to provide diversity processing based on the radio signals input it receives.   10. Radio station according to claim 8 or 9, characterized in that it comprises two other receivers (R3, R4) each receiving two respective input radio signals, one of these two signals being supplied by the first means of division (51) and the other of these two   signals being provided by the second dividing means (52) -   11. Radio station according to any one of   Claims 1 to 10, characterized in that it comprises   at least one radio signal source (T1) delivering said transmission signal to an input (Ai or B1) of the coupler polarization (31).   12. Radio station according to claim 11, characterized in that it comprises at least one duplexer (41) connected between an input (Ai or B1) of the polarization coupler (31), an input (El or F1) of the receiver ( Rl) and the radio signal source (Ti).   13. Radio station according to claim 12, characterized in that the radio processing means and the duplexer (41) are housed in a main housing of the radio station, each antenna (1, 2) and each hybrid polarization coupler (31 , 32) being external to said audit main housing.   14. Radio station according to claim 13, characterized in that the duplexer (41) is incorporated into a radio circuit further incorporating part of the means for radio processing.