FR2921216A1 - Radio frequency signal treating device for air or space craft, has evacuation unit comprising antenna evacuating majority of power of radio frequency signal and arranged in satellite so that radiation from antenna does not reach earth - Google Patents

Abstract

The device (10) has a multiplexing/switching module (2) for receiving a radio frequency signal. An insulation module (60) is disposed on a connection between a terminal (b-A) and input (EA) of the multiplexing/switching module. An evacuation unit comprises an antenna (62) e.g. horn-type antenna, evacuating majority of power of radio frequency signal by a radio frequency radiation. The evacuation unit is arranged in a satellite so that the radiation from the antenna does not reach the earth. An independent claim is also included for a method for evacuation of energy of a radio frequency signal.

Description

The present invention relates to the field of radiofrequency signal processing devices. The present invention is particularly applicable to radiofrequency signal processing devices comprising first terminals and a switching module which comprises second terminals and at least one third terminal, each first terminal being connected by a link to a respective second terminal. , the device being adapted to be driven to selectively connect in the switching module at least a second terminal to the third terminal, for receiving a first selected radio frequency signal on the first terminal associated with the second connected terminal and thus transmit to the third terminal said first selected signal via the associated second terminal, for radiofrequency transmission from a first radiofrequency radiation means of at least said first selected signal.

Some of these devices are adapted to, when a control error occurs, corresponding to the reception of a second radio frequency signal on a second terminal not connected to the third terminal, to deliver this second radiofrequency signal to an evacuation means adapted to evacuate the undesirable energy of the second radiofrequency signal.

The evacuation means generally comprises a charge that absorbs the energy of the second radiofrequency signal by transforming it into heat. The repeaters installed in telecommunication satellites have the particular function of receiving radio frequency signals, amplifying them, possibly modifying them and retransmitting them. Some of these repeaters include such processing devices. For example, with reference to FIG. 1a, such a processing device 1 receives, via the first input terminals b5, bA, bB and bc, radio frequency signals, SS, SA, SB, SC corresponding to several processing channels, here four channels VS, VA, VB and VC, after amplification by an amplifier As, AA, AB and Ac arranged on each of the channels. The amplifiers are for example traveling wave tubes (in English traveling wave tube, or TWT). Some of the channels are spare channels intended to overcome a failure when supplying the signal on another channel, for example due to the non-operation of an amplifier. Here the VS channel is such a spare path and the signal SS is for example equal to the signal SA. The processing device 1 is adapted to process these signals, with a view to transmitting, via an antenna, a global multiplex signal S obtained by combining the signals corresponding to at least some of the different channels. In some cases, the processing device 1 performs switching and / or multiplexing operations of the signals received at the input. These operations can then be performed by the first module. In other cases, the multiplexing is performed by a device downstream of the processing device 1, the latter performing pre-multiplexing operations such as filtering on each of the signals flowing on the channels. Each channel corresponds, for example, to a respective radiofrequency sub-band for example in the Ku band (10.7 GHz to 12.75 GHz (gigahertz)). For example, the VA, VB and VC channels respectively correspond to the subbands centered on 12.2 GHz, 12.3 GHz and 12.4 GHz. The signals SS, SA, SB, SC received by the processing module 1 are then each delivered to respective inputs Es, EA, EB and Ec of the first module 2. The first module 2 comprises, in the particular case represented on FIG. 1a, a switching block 3 and a block of operations 4. The switching block 3 is adapted to select, according to commands C, from all the radio frequency signals received at the input of the processing device 1, the signals which are actually supplied to the inputs InA, InB and InC of the operation block 4. In the case represented in FIG. 1a, the switching block comprises 3 controllable switches S1, S2, S3, which are configured in the particular case represented, for to supply the input of the signal VA to the input InA, to the input InB the signal of the channel VB, to the input InC the signal of the channel VC. In the event of a fault for example of the amplifier AA, it is the signal SS of the channel VS that would replace the signal SA of the channel VA. The links carrying the radio frequency signals between the elements, in particular the amplifiers, the isolation modules, the switching block 3 and the operation block 4 are generally of the waveguide or coaxial cable type. The operation block 4 is adapted to perform processing on the signals selected by the switching block 3, for example to compose a global radiofrequency signal S comprising the selected multiplexed radio frequency signals and / or to carry out pre-multiplexing operations, by example of filtering type. The global signal S, composed by the processing device 1 or by a device downstream of the processing device 1, is supplied to a radiofrequency transmission antenna 5.

Subsequently, in the exemplary embodiments described with reference to the figures, the first module 2 is called switching / multiplexing module 2. The higher the number of channels, the greater the complexity of the switching block 3. When one of the switches of the switching block is incorrectly positioned, for example due to an error in a C command or a malfunction of a switch mechanism, several failure situations may occur. In a first situation (situation a), the output of an amplifier on one of the channels is connected directly to the output of an amplifier on another channel. For example, in the case shown in FIG. 1b, following a bad positioning of the switch S2, the radiofrequency signal SB at the output of the amplifier AB on the channel VB is returned to the output of the amplifier AA of the channel VA while that the radiofrequency signal SA at the output of the amplifier AA on the channel VA is returned to the output of the amplifier AB of the channel VB. In another situation (situation b), the output of an amplifier on one of the channels is connected to a bad input of the operation block 4. For example, in the case shown in FIG. 1c, following a bad positioning of the switch S2, the radiofrequency signal output from the amplifier AA on the VA channel is supplied to the InB input of the operation block 4 instead of the radiofrequency signal at the output of the amplifier AB of the channel VB. When the input InB is not adapted to accept the radio frequency signal of the channel A, the radiofrequency signal SA output of the amplifier AA on the channel VA is returned to the output of the amplifier AA. In another situation (situation c), the output of an amplifier on one of the channels is connected to a closed input of a switch. For example, still in the case represented in FIG. 1c, following a mispositioning of the switch S2, the radiofrequency signal SB output from the amplifier AB on the channel VB is connected to a closed input. The radiofrequency signal SB output from the amplifier AB on the channel VB is then returned to the output of the amplifier AB. Other situations due to mis-positioning of the switches may occur. Among all these failure situations, some, including situations a, b and c described above, have the consequence that a radio frequency signal from the processing device 1 is mistakenly supplied to the output of an amplifier. This is referred to as a reflected radio frequency signal or reflected power. However, the amplifiers are not adapted to tolerate the reception of such power reflected by their output and in this case suffer significant damage. In order to avoid such degradations, an input terminal, for example the terminal bA, and the switching / multiplexing module 2, is provided in the processing device 1, an isolation module protecting the output of the device. amplifier for the arrival of signals reflected by the processing device 1. For example, with reference to FIG. 2 only showing the processing chain for the VA channel of the processing device 1 as well as the amplifier upstream of the device 1 on the channel A, an isolation module 6 has been arranged, in the processing device 1, between the terminal bA receiving the signal output of the amplifier AA and the input EA of the switching / multiplexing module 2.

Similar modules are for example arranged on the VS, VB and VC channels, in the processing device 1, respectively between the terminals bs, bs and bc and the inputs Es, EB, Ec of the switching / multiplexing module 2.

The isolation module 6 generally comprises a circulator 7 and a load 8. The circulator 7 comprises means for separating, on the waveguide or coaxial cable between the terminal bA and the input EA, a radiofrequency signal SA coming from the terminal bA for the switching / multiplexing module 2, a reflected radio frequency signal R, from the switching / multiplexing module 2 to the terminal bA. The circulator 7 comprises for example 3 ports P1, P2, P3. The port P1 is connected to the terminal bA, the port P2 is connected to the input EA of the switching / multiplexing module 2 and the port P3 is connected to the load 8.

The circulator 7 is adapted to, when it receives, on the port P1 a radiofrequency signal SA (fine dash) from the terminal bA, transfer this signal to the port P2 for supply to the input EA of the switching / multiplexing module 2. The circulator 7 is further adapted to, when it receives on the P2 port, a signal R reflected by the switching / multiplexing module 2 (bold dashes), transfer this signal to the port P3, for supply to the load 8. The circulator 7 is further adapted to, if it receives on the port P3, a signal from the load 8 (solid line), transfer this signal to the port P1. The load 8 comprises for example a dielectric or semiconductor material. It is generally adapted to absorb all the power of the incident radio frequency signal R, by transforming it into heat energy. No radio frequency signal is therefore sent back by the load from the port P3 towards the terminal BA and the amplifier AA via the port P1. For example, in the case where the power of an amplified radio frequency signal is 300 watts (W), the load 8 must be adapted to absorb such power.

It is furthermore necessary to provide means for evacuating the heat generated by the load 8 during the absorption operation. The thermal control of this load 8 then presents a specific problem: this load must be designed to absorb all the radiofrequency power of the incident radio frequency signal while the wavelength of this signal constrains the size of the load. With the current trend towards higher frequencies (or equivalently lower wavelengths), the charge 8 must be smaller and smaller while having to absorb higher powers. The resulting power concentration causes significant problems in the thermal dimensioning of the load. In addition, the heat energy dissipated by the load must be absorbed by the thermal control system of the satellite so as not to cause overheating of neighboring equipment. This induces important constraints on the design of the thermal control system.

The present invention aims to propose a radio frequency signal processing device comprising a module for evacuating the energy of a useless radiofrequency signal of a new type, making it possible to remove constraints relating to the problem of heat dissipation. generated in the prior art.

For this purpose, according to a first aspect, the invention proposes a radio frequency signal processing device adapted to be disposed in an aerial or space craft comprising a first radiofrequency radiation means arranged to radiate towards the earth, the processing device. comprising first terminals and a routing module comprising second terminals and at least one third terminal, each first terminal being connected by a link to a respective second terminal. The device is adapted to be driven to selectively connect in the routing module at least a second terminal to the third terminal, to receive a first selected radio frequency signal on the first terminal associated with the second connected terminal and thereby transmit to the third terminal said first signal selected via the associated second terminal, for radiofrequency transmission from the first radiofrequency radiation means of at least said first selected signal; the device is further adapted for, when a control error or a failure switch occurs, corresponding to the reception of a second radio frequency signal on a second terminal not connected to the third terminal, delivering the second radio frequency signal to an evacuation means adapted to evacuate the energy of said second radiofrequency signal. The device is characterized in that the evacuation means comprises a second radiofrequency radiation means distinct from the first radiofrequency radiation means and is arranged to allow evacuation of the majority of the power of the second radiofrequency signal received by radiofrequency radiation from said second radiation means, the second means being further arranged not to transmit to the earth. Thus, the invention proposes a solution for evacuating energy from radiofrequency signals that are erroneously generated and not exploited, and thus makes it possible to limit the constraints on the dimensions of the thermal control system. In one embodiment, the processing device comprises at least one isolation module disposed on a link connecting a first terminal and a second terminal, said isolation module comprising: the means of evacuation; a circulator block comprising at least three ports, wherein the first port is connected to the first terminal, the second port is connected to the second terminal and the third port is connected to the evacuation means; the circulator block being adapted to, when receiving a first radio frequency signal through the first port, transferring said first signal to the second port; the circulator block being adapted to, when receiving a second radio frequency signal through the second port, transferring said second signal to the third port. In one embodiment, the routing module has a plurality of third terminals. The device is adapted to be driven to selectively connect second terminals to third terminals and further comprises a module adapted to receive first radiofrequency signals delivered by the switch module to respective third terminals and to combine at least some of the first signals received on third terminals for providing a global radiofrequency signal to be transmitted. In embodiments, the processing device according to the invention further comprises one or more of the features below. the evacuation means further comprises a load adapted to, when a radiofrequency signal is supplied to it, absorb the majority of the power of said radiofrequency signal supplied and in which the circulator block comprises a fourth port connected to said load, the block circulator being adapted for, when receiving a third radio frequency signal through the third port, transferring said third signal to the fourth port; this arrangement makes it possible to absorb the power of a signal which would be reflected by the radiation means and which could degrade an amplifier; the processing device further comprises a filter adapted to filter the frequency components other than those of the first radiofrequency signal, disposed on the connection between the third port and the radiating means, which has the effect of preventing any interference between the signals radiated by the means of radiation and the signals for example received by the satellite or other satellites; the circulator block comprises two circulators with 3 ports, one port of one of the two circulators being connected to a port of the other circulator; in other embodiments, the circulator block comprises a 4-port circulator; a filter adapted to filter the frequency components other than those of the first radiofrequency signal, is placed on the link between the first circulator and the second circulator; the means of radiation is directional, which further reduces the risk of interference between the radiofrequency signals radiated by the radiating means and the radio frequency signals received by the satellite or other satellites; the processing device comprises another isolation module for isolating another input terminal from among the plurality of input terminals, the radiofrequency radiation means of the other isolation module being the radiating means of the module of insulation to isolate the first terminal; this arrangement makes it possible to reduce the number of equipment necessary to isolate each of the signal input terminals. According to a second aspect, the invention proposes an aerial or spacecraft comprising a processing module according to the first aspect of the invention. According to a third aspect, the invention proposes a method of evacuating the energy of useless radiofrequency signals in a radio frequency signal processing device arranged in an aerial or spacecraft comprising a first radiofrequency radiating means arranged for radiating to of the earth, the processing device comprising first terminals and a routing module comprising second terminals and at least one third terminal, each first terminal being connected by a link to a respective second associated terminal, this device being adapted to be controlled to selectively connect in the routing module at least a second terminal to the third terminal, to receive a first selected radio frequency signal on the first terminal associated with the second connected terminal and thereby transmit to said third terminal said selected first signal via the second associated terminal, e in view of the radiofrequency emission from the first radiofrequency radiation means of at least said first selected signal. According to the method, when a control error occurs, corresponding to the reception of a second radio frequency signal on a second terminal not connected to the third terminal, this second radiofrequency signal is delivered to an evacuation means adapted to evacuate the second radio frequency signal. energy of said second radiofrequency signal, the method is characterized in that the evacuation means comprises a second means of radiofrequency radiation distinct from the first radiofrequency radiation means and is arranged to allow evacuation of the majority of the power of the second radiofrequency signal received by radiofrequency radiation from the second radiation means, the second means being further arranged not to transmit to the earth. Other features and advantages of the invention will become apparent on reading the description which follows. This is purely illustrative and should be read with reference to the accompanying drawings in which: FIGS. 3a, 3b and 3.c show a radiofrequency signal processing device in a first embodiment of the invention; FIG. 4 represents a processing chain on the VA channel, comprising a processing device 10 in a second embodiment of the invention; FIG. 5 represents a processing line on the VA channel comprising a processing device 11 in a third embodiment of the invention; Fig. 6 shows a processing line on the VA path having a processing device 12 in a fourth embodiment of the invention; Fig. 7 shows a processing line on the VA channel including a processing device 11 'in a fifth embodiment of the invention; FIG. 8 shows a radiofrequency signal processing device in a sixth embodiment of the invention. In the various figures 1a, 1b, 1c, 2, 3a, 3b, 3c and 4-8, similar elements are identified. by the same references. FIG. 3a shows a processing device 100 and transmission means 105 comprising a radiofrequency transmission antenna 30 embedded in a satellite orbiting the earth. These elements compo. The processing device 100 comprises two signal sources 110, 111, a switch 101, an energy evacuation means 163 comprising a radiofrequency emission antenna 162 and an optional operation block 102. The radiofrequency transmission means 105 are adapted to radiate on at least part of the earth the signal they receive as input. The source 110 is adapted to deliver, when selected, a radiofrequency signal to the input terminal bE of the switch 101.

The source 111 is adapted to deliver, when selected, a radiofrequency signal to the input terminal bF of the switch 101. The switch 101, having input terminals bE and bF, is adapted to selectively connect, on command one of the terminals bE and bF at the input EK of the operation block 102 and for connecting the other of the terminals bE and bF to a radiofrequency energy removal means 163. The operation block 102 is adapted to perform operations on the signal provided by the switch 101 on the EK input of the operation block 102, for example of filtering type or to compose a global radiofrequency signal S according to several radio frequency signals, and to provide the signal resulting from operations carried out by the block 102 to the radiofrequency transmission means 105. In nominal operation, only one of the sources 110, 111 is selected and supplies a radio frequency signal to the switch 101: the source 110, source incipale, is selected by default. The source 111, backup source, is selected instead of the source 110 when a failure occurs in the supply of the signal by the source 110. The source 110 is the for the supply of the radiofrequency signal In nominal operation, the device of processing 100 is adapted to control the switch 101 so as to connect the radiofrequency signal supplied by the selected source to the input EK of the operation block 102. For example, the configuration shown in FIG. 3a corresponds to a nominal operating case wherein the selected source 110 provides a non-zero radiofrequency signal, shown in bold lines, to the input terminal bF. The switch 101 is in a state to provide this signal to the input EK. The unselected source 111 provides no radio frequency signal to the terminal bF then connected to the evacuation means 163.

Certain control errors may nevertheless occur: for example a source may be selected by mistake, the switch 101 may be improperly controlled or it may be placed in a state not corresponding to the received command.

For example, with reference to FIG. 3b, the source 110 is selected and supplies a non-zero radiofrequency signal, shown in bold lines, to the input terminal bE. Unselected source 111 provides no radio frequency signal to terminal bF. The switch 101 is in an unsuitable state for the current signal supply configuration since it does not provide the received radio frequency signal to the operation block 102. The switch 101 connects the input terminal bF to the input EK and not the input terminal bE at the input EK. The input terminal bE is then connected to the evacuation means 163, which is adapted to evacuate the energy of the radiofrequency signal supplied by the source 110 by radiofrequency radiation from the antenna 162. For example, with reference to FIG. , the source 110 is selected and provides a radiofrequency signal, shown in bold lines, to the input terminal bE of the switch 101. The source 111 is also selected by mistake and provides a non-zero radiofrequency signal, shown in bold lines, at the terminal bF. The switch 101 is in a state such that it provides the radio frequency signal received on the input terminal bE to the operation block 102 and that it delivers the radio frequency signal received on the input terminal bF to the evacuation means 163, which is adapted to evacuate the energy of the radiofrequency signal supplied by the source 111 by radiofrequency radiation from the antenna 162. Such a means of evacuation 163 thus makes it possible to dissipate the energy of the unused radiofrequency signal, which avoids the reflection, in the direction of the sources 110, 111 and may give rise to damage to equipment, all or part of signals not transmitted to the block of operations 102. The evacuation means 163 can significantly limit the need for regulation temperature for the evacuation of the radiofrequency signal, compared with the evacuation means of the prior art based on a heat transfer.

In one embodiment, the evacuation means 163 is arranged in the satellite so that the radiation from the antenna 162 does not reach the ground and does not interfere with signals transmitted to the earth from the antenna 105.

FIG. 4 represents a processing device 10 embedded in a satellite in a second embodiment of the invention. This processing device 10 corresponds to the processing device 1 shown in FIG. 2 with the exception of the isolation module 6 which has been replaced by the isolation module 60.

On the VA channel, the radiofrequency signal SA amplified by the amplifier AA is delivered to the input terminal bA of the processing module 10. On the link between this terminal bA and the input EA of the switching / multiplexing module 2 is disposed an insulation module 60, comprising a pump 3 with 3 ports P10, P20, P30.

The circulator 61 is adapted to separate, on the link between the terminal bA and the input EA, a radiofrequency signal SA coming from the terminal bA destined for the switching / multiplexing module 2, of a radiofrequency signal R (reflected signal). from the switching / multiplexing module 2 to the terminal bA.

The port P10 is connected to the terminal BA, the port P20 is connected to the input EA of the switching / multiplexing module 2 and the port P30 is connected to an antenna 62. The connections between the different elements are realized using waveguide type links or coaxial cable. The circulator 61 is adapted to, when it receives, on the port P10 a radiofrequency signal SA (fine dashes) from the terminal bA, to transfer this signal to the port P20 for supply to the input EA of the switching / multiplexing module 2. The circulator 61 is further adapted to, when it receives on the port P20, a radiofrequency signal R reflected by the switching / multiplexing module 2 (bold dashes), transfer this signal to the port P30, for supply to the antenna 62.

The circulator 61 is further adapted to, if it receives on the port P30, a signal (alternations of dots and dashes) from the antenna 62, transmit this signal to the port P10. The antenna 62 is arranged to radiate directly in space a radiofrequency signal supplied to it, and thus evacuate most of the power of the signal by radiofrequency radiation. The antenna 62 is for example a horn type antenna. In one embodiment, the antenna 62 is a directional antenna, set to direct radiation outside the satellite, in opposite directions to the Earth and / or other satellites, to minimize interference. with these other satellites or with ground stations. In such a processing device 10, a radiofrequency signal R reflected by the switching / multiplexing block 2 on the VA channel will not be sent to the output of the amplifier AA, but will be supplied to the antenna 62. The terminal bA , and therefore the amplifier AA, are well isolated from the reflected signal R. The invention thus proposes a system for dissipating and evacuating the energy of a radiofrequency signal reflected by the switching / multiplexing module 2, which does not require no high power load, nor complex thermal regulation means. In another processing device 11 shown in FIG. 5 corresponding to another embodiment of the invention, the isolation module 60 of FIG. 4 is replaced by the isolation module 70.

In addition to the first circulator 61 comprising the 3 ports P10, P20, P30, the isolation module 70 comprises a second circulator 63 comprising the 3 ports P1, P21, P31. The port P10 of the circulator 61 is connected to the terminal BA, the port P20 of the circulator 61 is connected to the input EA of the switching / multiplexing module 2 and the port P30 of the circulator 61 is connected to the port P1 of the circulator 63. P21 port of the circulator 63 is connected to an antenna 62. The port P31 of the circulator 63 is connected to a load 64.

The connections between the different elements are made using waveguide type links or coaxial cable. The circulator 61 is adapted to, when it receives, on the port P10 a radiofrequency signal SA (fine dashes) from the terminal bA, to transfer this signal to the port P20 for supply to the input EA of the switching / multiplexing module 2. The circulator 61 is further adapted to, when it receives on the port P20, a radiofrequency signal R reflected by the switching / multiplexing module 2 (bold dashes), transfer this signal to the port P30, for supply to the port P11 of the circulator 63. The circulator 63 is adapted to, when it receives, on the port P1, this radiofrequency signal R (bold line) coming from the terminal bA, to transfer this signal to the port P21 for supply to the antenna 62. The circulator 63 is adapted to, when receiving, on the port P21 a radio frequency signal P (alternating point / line) from the antenna 61 to transfer this signal to the port P31 for supply to the load 64. The circulator 63 is adapted for, in case he receives on the port P31 a signal (solid line) from the load 64, transfer this signal to the port P11 for supply to the port P30 of the circulator 61, which would transfer it to the final port P10 of the circulator 61. Such a module isolation limits the problems of reflection of the signal by the antenna 62. Indeed, the antenna 62 may not be a perfect transmission antenna: a small portion of the radio frequency signal R supplied to it on the link the Connecting to the circulator can be reflected on this same link by the antenna 62. In addition, the antenna 62 receives radio frequency signals, in particular transmitted by the main antenna 5. These two phenomena can give rise to transmission from the antenna. antenna 62 to the isolation module 60 (FIG. 4) or 70 (FIG. 5), of parasitic radiofrequency signals P reflected or picked up by the antenna 62 (represented by lines alternating dashes and dots). In the case of the processing module 10 of FIG. 4, such parasitic signals P supplied at the port 30 of the circulator P30 will be presented at the output of the amplifier AA (alternation point / line). Their power is low (for example 1W), they will not cause degradation of the amplifier AA. On the other hand, they can create interference problems. The isolation module 70 of the processing module 11 of FIG. 5 makes it possible to prevent these parasitic signals P from being presented at the output of the amplifier AA. Indeed, the spurious signals P transmitted from the antenna 62 to the isolation module 60 are supplied by the circulator 63 to the load 64, which absorbs the power of the incident radio frequency signals P by transforming it into heat. The load 64 is sized to absorb the power of the radiofrequency signals supplied to it.

Since the power of the parasitic signals P is small, the rise in temperature in the event of a failure of the switching unit is very limited and does not require complex thermal control means. The isolation module 70 comprises two circulators 61 and 63 with 3 ports in cascade. In another embodiment corresponding for example to the isolation module 71 of the processing module 11 'shown in FIG. 7, the function exerted by these two circulators 61 and 63 in the isolation module 70 of FIG. a four-port pump 73 P15, P25, P35, P45, in which the port P15 is connected to the terminal bA, the port P25 is connected to the input EA of the switching / multiplexing module 2 and the port P35 to the antenna 62, and the port P45 is connected to the load 64. In one embodiment, the antenna 62 is adapted to selectively transmit the frequency band associated with the overall signal combining the signals of the channels VA, VB and VC (12, 2 - 12.4 GHz in the example).

In another embodiment, filtering is applied to the reflected signals R to be emitted by the antenna 62, appearing in bold indents in the embodiments shown in FIGS. 4, 5 and 7, so that the signals outside the frequency band associated with the overall signal are not transmitted by the antenna 62. The corresponding filter is for example arranged, with reference to Figure 5, on the connection between the port P21 of the circulator 63 and the antenna 62 in the module 70. In the isolation module 71 shown in FIG. 7, the filter 72, adapted not to transmit signals to the antenna 62, outside the frequency band associated with the overall signal, is arranged on the connection between the port P35 of the circulator 73 and the antenna 62. Each of these embodiments has the advantage of reducing the risk of interference between the signals R radiated by the antenna 62 and signals received or transmitted by the satellite considered or other satellites or surrounding ground stations. The power of the signals not transmitted by the selective filtering is absorbed by the load 64, in the embodiments shown in FIGS. 5 and 6.

FIG. 6 represents a processing device 12 corresponding to another embodiment of the invention, the isolation module 60 of FIG. 4 being replaced by the isolation module 80. The processing device 12 comprises a first circulator 66 comprising the 3 ports P12, P22, P32 and a second circulator 67 comprising the three ports P14, P24, P34. The port P22 of the circulator 66 is connected to the input EA of the switching / multiplexing module 2 and the port P32 of the circulator 66 is connected to an antenna 62. The port P12 of the circulator 66 is connected to the port P24 of the circulator 67. The port P34 of the circulator 67 is connected to a load 64. The port P14 of the circulator 67 is connected to the terminal bA. The connections between the various elements are generally made using waveguide or cable type connections. coaxial. The circulator 67 is adapted to receive a radiofrequency signal SA (fine line) from the terminal bA on the port P14, to transfer this signal to the port P24 for supply, to the circulator 66 via its port P12. The circulator 66 is adapted for following reception of said signal SA by the port P12, to transfer the signal to the port P22 for supply to the input EA of the switching / multiplexing module 2. The circulator 66 is adapted for, when receives on the port P22, a signal R reflected by the switching / multiplexing module 2 (bold line), transfer this signal to the port P32, for supply to the antenna 62.

The circulator 66 is adapted to, when it receives, on the port P32 a parasitic radiofrequency signal P (alternating point / line) from the antenna 62 to transfer this signal to the port P12 for supplying the port 24 of the circulator 67.

The circulator 67 is adapted to, when it receives, on the P12 port this parasitic radiofrequency signal P (alternation point / line), transfer this signal to the port P34 for supply to the load 64. The circulator 67 is adapted for, in case where it would receive on the P34 port a signal, transfer this signal to the port P14 for supply to the terminal bA Thus the processing module 12 is adapted to isolate the terminal bA of radiofrequency signals R reflected by the switching / multiplexing module 2, while by dissipating the power of these signals reflected by radiation in space. It also allows the absorption of spurious signals P by a low power load.

In the embodiment considered in FIG. 6, a filter 68 has also been disposed on the connection between the port P24 of the circulator 67 and the port P12 of the circulator 66. The filter 68 is adapted so that the signals outside the frequency band associated with the global signal S are not transmitted. This arrangement makes it possible to reduce the risk of interference between the signals radiated by the antenna 62 and signals received by the satellite in question or other surrounding satellites. In the embodiments shown in FIGS. 5 and 6, the power of the non-transmitted signals by the selective filtering is absorbed by the load 64.

Figures 4, 5 and 6 show only the portion of the processing module relating to the VA channel. Modules similar to the modules 60, 70 or 80 are also interposed, in embodiments of the invention, respectively between the terminals b5, bB, bc of the processing module 1 and the inputs ES, EB, Ec of the switching module. / multiplexing 2 shown in Figure la. In one embodiment, isolation modules arranged on different paths comprise a common antenna. This arrangement has the advantage of limiting the necessary size.

In the embodiments considered with reference to the figures, the isolation module is arranged upstream of the module 2 performing switching and / or multiplexing operations. In embodiments, the module 2 performs further processing on the signals received at the input (instead of or in addition to switching and / or multiplexing), for example filtering, etc. Thus, the present invention proposes an advantageous solution for isolating the equipment upstream of the processing module, in particular the amplifiers, from radiofrequency signals reflected by equipment of said module, and thus to avoid damage. The proposed solution has the advantage of being easy to implement and not requiring significant heat regulation means. Fig. 8 shows a radio frequency signal processing device 200 in another embodiment. This processing device 200 comprises a first switching block 211, two multiplexers 212, 213, a second switching block 214, radiofrequency transmission means comprising a radiofrequency transmission antenna 205 and a radiofrequency energy evacuation block. 263 having a radio frequency transmitting antenna 262.

The radiofrequency transmission antenna 205 is adapted to radiate on at least part of the earth the signal it receives as input. In nominal operation, three radiofrequency signals S1, S2 and S3 are delivered to the input of the switching block 211. The switching block 211 is adapted, on command, to route all the signals to a selected multiplexer, that is to say that is, it is adapted to either direct all the signals S1, S2 and S3 to the multiplexer 212, or to route them all to the multiplexer 213. When it receives input signals, each multiplexer 212, respectively 213, is adapted to combine these received signals into a single global radio frequency signal and to deliver this global signal to an input terminal bG, respectively bH, of the second switching block 214. The switching block 214 is adapted to connect almost simultaneously, as a function of a received command, namely the input terminal bG to the radiofrequency transmission means comprising the transmitting antenna 205 and the input terminal bH to the evacuation means 263, or the input terminal bH to the mo radiofrequency emission yen comprising the transmit antenna 205 and the input terminal bG by the evacuation means 263.

In nominal operation, the switching block 214 is adapted to connect the radiofrequency transmission means comprising the transmitting antenna 205 to the input terminal bG or bH which is connected to the selected multiplexer, in view of the radio frequency emission by the transmit antenna 205 of the overall signal provided by the selected multiplexer.

Control errors of the device 200 may occur, resulting in the provision of a radio frequency signal by one of the multiplexers 212, 213, on a terminal bG or bH not connected by the switching block 214 to the radiofrequency transmission means comprising transmitting antenna 205.

For example, in the case shown in FIG. 8, the multiplexer 212 delivers a non-zero radiofrequency signal, represented in bold lines, to the input terminal bG of the switching block 214, which is in a state such that it connects the input terminal bH to the radiofrequency transmission means comprising the transmitting antenna 205, whereas no radio frequency signal is supplied by the multiplexer 213, the input terminal bG being connected to the evacuation means 263 The radiofrequency signal delivered by the multiplexer 212 to the bG terminal is supplied via the switching block 214, to the evacuation means 263, which is adapted to evacuate the energy (up to several hundred watts) of the radiofrequency signal supplied by the multiplexer 212 radiofrequency radiation from the antenna 262. The invention thus provides a solution for dissipating the energy of an undesirable radio frequency signal without requiring significant thermal load accompanied by embedded equipment for heat exchange.

The invention thus makes it possible to decrease the mass and the complexity of the satellite. In the examples described above, the radiofrequency energy transmitted from the evacuation means was emitted by the antenna in space. In another embodiment, it is transmitted in the satellite structure.

The invention has been described above in the context of an application to a satellite. It can obviously be implemented in any field presenting the same problems relating in particular to congestion. It can in particular be implemented in an aerial vehicle.

Claims (13)

A radiofrequency signal processing device (10; 100) adapted to be disposed in an aerial or space apparatus comprising first radiofrequency radiation means (5; 105) arranged to radiate to the earth, the processing device comprising first terminals (bA, bE; 110, 111) and a routing module (2; 101) comprising second terminals (EA, EB; bE) and at least one third terminal (InA; EK), each first terminal being connected by a link to a respective second terminal, said device being adapted to be driven to selectively connect in the routing module at least a second terminal to the third terminal, for receiving a first selected radio frequency signal on the first terminal associated with the second connected terminal and thus transmit to the third terminal said selected first signal via the second associated terminal, for the purpose of radiofrequency transmission from the first m radiofrequency radiation of at least said first selected signal, said device being further adapted for, when a control error or a switching failure occurs, corresponding to the reception of a second radio frequency signal on a second terminal not connected to the third terminal, outputting said second radio frequency signal to an evacuation means adapted to evacuate the energy of said second radiofrequency signal, said device being characterized in that the evacuation means (62; second radiofrequency radiation means distinct from the first radiofrequency radiation means and is arranged to allow evacuation of the majority of the power of the second radiofrequency signal received by radiofrequency radiation from said second radiating means, the second means (62) being furthermore arranged not to transmit to the earth. 23 2. Device according to claim 1, comprising at least one isolation module (60) disposed on a link connecting a first terminal and a second terminal, said isolation module comprising. the evacuation means (62); a circulator block (61) comprising at least three ports (P10, P20, P30), wherein the first port is connected to the first terminal, the second port is connected to the second terminal and the third port is connected by means of evacuation; the circulator block being adapted to, when receiving a first radiofrequency signal (SA) through the first port (P10), transferring said first signal to the second port (P20); the circulator block being adapted to, when receiving a second radio frequency signal (R) through the second port (P20), transferring said second signal to the third port (P30). 3. Device according to claim 2, wherein the switching module comprises a plurality of third terminals, said device being adapted to be driven to selectively connect second terminals to third terminals and further comprising a module (4) adapted for receiving first radiofrequency signals delivered by the switching module on respective third terminals and for combining at least some of said first received signals on third terminals to provide a global radiofrequency signal to be transmitted (S). 25 The device (10) according to claim 2 or 3, wherein the isolation module (70) further comprises a load adapted to, when a radiofrequency signal is supplied to it, absorb the majority of the power of said supplied signal and wherein the circulator block comprises a fourth port connected to said load, the circulator block being adapted to, when receiving a third radio frequency signal through the third port, transferring said third signal to the fourth port. 5. Device according to any one of claims 2 to 4, further comprising a filter adapted to filter the frequency components other than those of the first radiofrequency signal disposed on the connection between the third port and the second radiating means. 6. Device (11) according to one of claims 2 to 5, wherein the circulator block comprises two circulators (61, 63) with 3 ports, a port of one of the two circulators being connected to a port of the other circulator. 7. Device (12) according to claim 6, wherein a filter adapted to filter the frequency components other than those of the first radiofrequency signal, is disposed on the connection between the first circulator and the second circulator. 8. Device according to any one of the preceding claims, wherein the second radiating means (62) is directional. 9. Device according to one of claims 2 to 8, comprising two isolation modules disposed between respective first and second terminals, the second radiofrequency radiation means of the two insulation modules being common. 25 10. Device according to any one of the preceding claims, comprising at least two multiplexing modules each adapted to receive radiofrequency signals as input, for combining said received signals and outputting a global radiofrequency signal to an output on a respective first terminal. The device is adapted to be driven in a manner to provide RF signals to the two multiplexing modules alternately. 11. Air or space apparatus comprising a treatment device according to one of the preceding claims, and further comprising the first radiation means (5) arranged to radiate to the earth. 12.Engine air or space according to claim 11, wherein the radiating means is adapted to radiate the radiofrequency signal to the outside of the machine. 13. A method of evacuating the energy of useless radio frequency signals in a radiofrequency signal processing device disposed in an aerial or space apparatus comprising a first means (5; 105) of radiofrequency radiation arranged to radiate towards the earth, the processing device comprising first terminals and a routing module comprising second terminals and at least one third terminal, each first terminal being connected by a link to a respective second associated terminal, said device being adapted to be driven to selectively connect in the referral module at least a second terminal at the third terminal, for receiving a first selected radio frequency signal on the first terminal associated with the second connected terminal and thereby transmitting to the third terminal said selected first signal via the associated second terminal, in view of the radiofrequency emission since the first radiofrequency radiation means of at least said first selected signal, wherein, when a control error or a switch failure occurs, corresponding to the reception of a second radio frequency signal on a second terminal not connected to the third terminal, said second radiofrequency signal is delivered to an evacuation means adapted to evacuate the energy of said second radiofrequency signal, said method being characterized in that the evacuation means comprises a second radiofrequency radiation means (62) distinct from the first means radiofrequency radiation and is arranged to allow evacuation of the majority of the power of the second radiofrequency signal received by radiofrequency radiation from said second means of radiation, the second means (62) being further arranged not to transmit to the earth .