FR2670052A1 - RECONFIGURABLE TRANSMITTING ANTENNA. - Google Patents

Abstract

The invention relates to a reconfigurable transmit antenna comprising a reflector (10) focusing energy, an array (11) of elementary sources located in the focal zone of the reflector, so as to synthesize the electromagnetic field in this zone, in which the production of a spot (SPi) results from the radiation of a fixed and identical number of sources for all the spots; a source participating at most in the radiation of a spot; high-level switching making it possible to reconfigure the spots by selecting the sources participating in a given spot. Application in particular to the field of space telecommunications

Description

Reconfigurable broadcast antenna.

  The invention relates to a reconfigurable transmission antenna multi-access and multispot.

  In the general case of space missions, the evolution of satellite transmissions to users with reduced capacity implies an increase in the reception quality of the segment

  embedded This increase in capacity is achieved by increasing antenna gains, which reduces their coverage.

  These coverage reductions require, in order to ensure the continuity of the service, to generate several beams: Such multispots covers make possible a better management of edge capacities according to: different densities of traffic,

  changes over time in traffic densities.

  For a global coverage satellite system, it is advantageous to be able to replace a failed satellite, or at the end of its life, with a satellite occupying another orbital position. This has the effect of requiring multispot covers.

Reconfigurable.

  Active antennas of the direct radiation network or focal network type make it possible to solve such problems of

  reconfigurability of coverage and exchange of capacity between spots They have, however, the disadvantage of a complexity 25 important They also allow a power exchange and reduced reconfigurability.

  Thus, a French patent application, filed on March 18, 1988 under the number 8803547, describes an electronically reconfigured transmission antenna comprising a reflector focusing the energy, an array of elementary sources located in the focal zone of this reflector, a control electronics. power supply and control system comprising first and second generalized couplers arranged on either side of a plurality of amplifiers, and beamforming circuits each corresponding to an emitted beam; the amplitude and the relative phase of the signals leaving -2- of these circuits being controlled respectively by an adjustable phase shifter and an adjustable attenuator. This type of solution has the disadvantage of a reconfigurability limited to spots generated by sources or groups of separate sources. The object of the present invention is to offer the flexibility of traffic exchange and reconfiguration, required for the missions mentioned, without the disadvantages of the previous solutions.10 It proposes for this purpose a reconfigurable transmitting antenna comprising a focusing reflector energy, a network of elementary sources located in the focal zone of the reflector, so as to achieve the synthesis of the electromagnetic field in this area, characterized in that the realization of a spot (S Pi) results from the radiation of a fixed and identical number of sources for all spots; a source participating at most in the radiation

  a spot and in that a high level switching reconfigures the spots by selecting the sources participating in a given spot.

  Advantageously, such an antenna makes it possible to exchange power between several spots with an optimum amplification efficiency while allowing them to be reconfigured. Each spot being constituted by the juxtaposition of the beams of N sources (for example 3), each of these sources and all the

  associated connectors support the power transmitted by the spot divided by n.

  The features and advantages of the invention will become apparent from the following description, by way of nonlimiting example, with reference to the appended figures in which: FIG. 1 schematically illustrates a scanning antenna of the prior art ;

  FIG. 2 illustrates the operation of the antenna according to the invention; Figures 3 to 5 schematically illustrate several embodiments of a power supply electronics and control of -3-

the antenna according to the invention.

  The antenna of the known art shown in FIG. 1 comprises an off-center parabolic reflector 10 illuminated by a plane array 11 of sources situated in the vicinity of the focal point F of the reflector, the network 12 representing a network of virtual sources corresponding to this In this antenna, we play only on the phase of each elementary source; this makes it possible to achieve the optimum synthesis of each elementary source as if it were at the focal point F of the reflector. Such an operation makes it possible to produce an antenna whose gain does not depend on the pointing direction, while keeping the reflector 10 and the network 11 of elementary sources. When the specified coverage is achieved using multiple spots, antenna directivity performance is defined

  by the level of recovery of the spots.

  In the multi-access and multispots antenna according to the invention, the generation of a spot results from the radiation of N sources by

  Example 3, located in a planar network close to the focal point F of the reflector. This number is identical for all the spots, a source participating at most in the radiation of a single spot.

  FIG. 2 shows a spot with two successive instants, namely S P 1 and SP 1 ', while retaining, for example, a

  source 513 common to these two spots. The following description of Figure 3 is intended to

  To facilitate the understanding of the invention, it is related to the routing and the radiation of a signal injected at an input E of the block diagram of the antenna subsystem according to the invention. E 1 signal at the first input of the subsystem This signal E 1 is amplified with an amplification gain controllable by the variable gain amplifier 18 This amplified signal is divided into three components E 1 1, E 12, E 13, of equal amplitude, in the divider 26 Each of these three components E 1, E 12, E 13 is routed respectively to one of the three inputs e 1 1, e 12, e 13 of three blocks 20 of The signal E 1 1 is divided into four equal-amplitude components by the coupler 21. These components are amplified by the four amplifiers 23, recombined by the coupler 22, and routed to the output 51 i. Similarly, the components E 12 and E 13 are amplified and routed to the outputs 512 and 513 '. Thus, the signals Eil, E 12 and E 13 are routed to the radiating elements Sil, S, 21532 respectively through the switching matrices 24. radiation from these sources S l, 521 'and 532 of the signals E1, E2 and E3 constitute the cover S P1 by

  the three elementary spots sp 1 l, sp 21, sp 32.

  It is then possible to modify the coverage and, for example, for the signal E 1, the radiation zone of the antenna is the cover S.sub.P1 is modifiable into an area corresponding to the cover S.sub.P1 (sp 12 , sp 21, sp 31) by respectively switching the sources (Sil, 532 to 512 '531) This switching corresponds to a reconfiguration of two matrices of

  switching 24; The last matrix not being reconfigured This antenna reconfiguration does not affect the operation of the amplifiers 23.

  In multispot operation (SP 1, SP 2), identical to the operation described above for a signal injected at the first input of the subsystem, a second signal can be injected simultaneously to the second input without the

  operation for the first signal is affected.

  The restriction for this second signal is that it does not use the radiation sources used for the first signal.

  Thus this two-input amplifier stage system 20 is compatible with two radiated signals simultaneously if and only

  if the sources used by these two signals at a given time are distinct.

  It is, of course, possible to generalize this concept to m spots: An embodiment of an electronic supply and control of such an antenna according to the invention, as shown in FIG. m entries E 1 to E corresponding to m spots S P1 to S Pm delimiting m covers on the earth's surface; a variable amplifier 18 being disposed on each of these inputs; a number N of channels; N corresponding to the number of sources per spot (n = 3 in FIG. 3) and on each channel (Vi): an amplifier stage 20 with m inputs corresponding to the m inputs E to E and m outputs comprising a first and a second generalized couplers 21 and 22 arranged on either side of amplifiers 23 arranged in parallel; a high-level connection and switching circuit 24 making it possible to correspond to each spot SP 1 S Pm N elementary sources; This circuit being formed of a number of fixed links, and a number of switches to allow variable input or output connections or not in time. p filters 25 arranged in series between the p outputs of the circuit 24 and p sources S ij of the network corresponding to this path Vi. The amplification stage 20 comprises a first and a second generalized couplers 21 and 22 respectively formed of an association of hybrid couplers, on either side of amplifiers 23 so that each input of the first coupler 21 is distributed in all the amplifiers 23 In this amplification stage 20 a signal applied to the first input, for example, amplified spring on the first output Thus if a signal is applied to one of the inputs of a stage (of rank i for example), at the corresponding output (of rank i) the signal will be amplified by all the amplifiers and no other output will receive a signal at a significant level The power amplifiers 23 receive on their respective inputs a signal from each beam, at a quasi-identical level A quasi-uniform load distribution is obtained on all the inputs of the amplifiers 23. The signals are then reconstituted using the two x generalized coupler 22 which has a reverse structure from that of the first amplifier 23 and have a constant input power and can thus operate at their

nominal capacity.

  This arrangement of hybrid couplers and amplifiers is known to those skilled in the art under the term "multiport amplifier". For this type of amplifier stage, if a constant sum of power of non-input signals is considered, consistent, the input load of the amplifiers is constant regardless of the distribution of the input signals On the other hand, this distribution

  is reproduced at the exit of the floor.

  The number p of sources Sij corresponding to a path Vi can

  be equal to or greater than the number m of outputs of the amplifier stage 20.

  Each spot S P1 being made with a constant number N of sources, for example 3, these N sources, for reasons of no

  coherences of the signals in the multiport stages, are connected to N "multiport" stages 20.

  As shown in FIG. 4, all the first couplers 21 can be grouped into one, and consequently, after the amplifiers 23, each amplifier output is divided into

  supply the second couplers 22 Thus the power handling of the high power stages is respected.

  Thus, an access Ei of spot S P1 of the input coupler corresponds to N antenna access The radiation of the beam corresponding to this spot S P1 is obtained by the connection through circuit 24 corresponding to a switching matrix of each of these N access to the N sources of the primary network corresponding to the coverage to be achieved A reconfiguration of coverage for this spot is therefore obtained by switching one, two or N sources: In FIG. 2 for example, with N equal to three the transition in two successive instants of the spot S P1 to spot SPF 1 requiring the switching of two sources. An advantage of such a system is to ensure an optimum exchange of capacity: namely that the sum of the powers distributed in the spots whatever the relative ratios of distribution, is

  equal to the maximum available power.

  It is also necessary to reduce the radiation of a spot on neighboring spots induced by a uniform illumination of the sources. The solution adopted is to superpose the main radiation of the sources with the radiation of at least one additional source S 'of insulation as shown in FIG. 4. Such sources S' have a position in the network, such that their radiation can act. predominantly in the area to be isolated Is thus provided isolation using a source S 'cancellation outside the sources of the switched network We adjust the amplitude (27) and the phase (28) thereof to obtain a energy in opposition of phase and of same amplitude to that which

we want to cancel.

  Thus by respecting external laws such that the energy of the main radiation (n sources) and the radiation of additional sources are minimum in the zones to be isolated, it is possible to be compatible with the isolation requirements. source of insulation, is usually less than 12 d B, which allows to derive a small portion of

  the energy of the beam concerned before the amplifier stage; the fine adjustment of amplitude and phase being ensured by the phase-shifter 28 and the variable attenuator 27.

  It is understood that the present invention has been described and shown only as a preferred example and that it will be possible

  replace its constituent elements by equivalent elements without departing from the scope of the invention.

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Claims (6)

CLAIMS:   A reconfigurable emission antenna comprising a reflector (10) focusing the energy, a network (11) of elementary sources located in the focal zone of the reflector, so as to achieve the synthesis of the electromagnetic field in this area, characterized in that the realization of a spot (S Pi) results from the radiation of a fixed and identical number of sources for all the spots; a source participating at most in the radiation of a spot and in that a high level switching makes it possible to reconfigure the spots in   selecting the sources participating in a given spot.   2 / Antenna according to claim 1, characterized in that it comprises a power supply and control electronics comprising: m inputs (E 1 to E) corresponding to m spots delimiting m covers on the earth's surface; a variable amplifier (18) being arranged on each of these inputs;   a number N of channels; N corresponding to the number of sources per spot.   and on each channel (Vi) an amplification stage (20) with m inputs and m outputs a high-level connection and switching circuit (24) making it possible to correspond to each spot (SP 1 SP) n elementary sources; p filters (25) arranged in parallel between the p outputs of the   switching and switching circuit (24) and p network sources.   3 / Antenna according to claim 2, characterized in that the amplification stage (20) comprises a first and a second generalized couplers (21 and 22) arranged on either side of amplifiers (23) in parallel, in such a way that a signal applied to the   first input comes out amplified on the first output.   4 / Antenna according to claim 3, characterized in that the first and second generalized couplers (21 and 22) are respectively formed of an association of hybrid couplers (25), so that each input of the first coupler (21 ) is distributed over all the amplifiers (23) and therefore all outputs of the hybrid couplers of the first generalized coupler (21), the second generalized coupler (22) having a reverse structure of that of the first. 5 / Antenna according to claim 2, characterized in that it comprises for all channels only one first generalized coupler (21), and in that the output of each amplifier   (23) can be connected to the same input of N second generalized couplers (22).   6 / Antenna according to any one of the preceding claims,   characterized in that it comprises at least one additional source (S ') of insulation.