FR2932340A1 - DEVICE FOR AMPLIFYING THE LOAD POWER OF A SATELLITE, AND SATELLITE EQUIPPED WITH SUCH A DEVICE - Google Patents

Abstract

A payload power amplification device of a multi-beam data broadcast satellite, wherein each power amplification block (7, 8) has a plurality of outputs connected to a plurality of antennas (4, 5), each output (11, 12, 13, 14) being connected to one and only one diffusion antenna (4, 5), and at least two switches adapted to be able to selectively and independently connect: others, different subsets of said individual amplifier circuits to any one of said diffusion antennas (4, 5). The invention extends to a satellite equipped with such an amplification device.

Description

SATELLITE PAYLOAD POWER AMPLIFICATION DEVICE, AND SATELLITE EQUIPPED WITH 1JN SUCH DEVICE

The invention relates to a device for amplifying the payload power of an artificial satellite in orbit with respect to a planet -in particular the multi-beam data broadcast earth, comprising: a plurality of broadcast antennas each adapted to being able to broadcast a data signal to be broadcast, each antenna thereby forming a beam, to a plurality of inputs each receiving a data signal to be broadcast, downstream of each input, a power amplification block comprising a plurality individual amplification circuits connected in parallel, each power amplification block being connected to one and only one input which supplies it, and being adapted to deliver a corresponding amplified signal, connecting means between the individual circuits of the amplification circuit; amplification of each power amplification block and the antennas, these connecting means being adapted to allow the diffusion, by the antennas , amplified signals delivered by the amplification blocks.

Such a satellite payload can be used, for example, to broadcast multimedia content (audio and / or video, television programs, etc.) from a geostationary satellite and to mobile terminals located on the ground. For example, the plurality of broadcast antennas may correspond to a plurality of linguistic areas to be covered.

The payload of such a multibeam broadcast satellite must have a relatively high scattering power for each antenna. In particular, in the case of a geostationary satellite, the transmission power of the downlink is all the more important that the satellite is away from the ground, and the ground receivers are mobile terminals. Typically, for a geostationary multimedia broadcasting satellite, the equivalent isotropically radiated power (EIRP) required is of the order of 60 to 72 dBW per spot, that is to say by broadcast antenna. Similarly, in the case of a multibeam satellite in medium or low orbit, it may also be useful to minimize the performance of the power amplification circuits which are components whose bulk, mass and consumption are relatively important. in the general design of the satellite.

In order to optimize the use of the power available on board the satellite, it is considered necessary to be able to have flexibility in allocating power between the different spots in order to adapt to the traffic for example. In other words, the payload must be reconfigurable in orbit, according to the needs of each spot. For example :

- in the event of uncertainty about the market potential in the different beams / countries, the operator may wish to switch from the power allocated to France (for example) to Germany (for example) to meet an increase in demand on the latter; this demand for power can come either from the need to increase the number of TV channels (or radio or data stream), or to improve the availability of the signal on the ground, or to propose terminals of smaller dimensions,

- in the event of a change in the market during the life of the satellite, which is changing power demand by beam / country,

- in the case of broadcasting of television programs, to take into account a variation of the needs according to the time zones. Thus, in general, the broadcast of a television program of large audience induces a high need for broadcast power of a spot. On the contrary, a spot oriented towards a zone in which the local time corresponds to the night to a need of reduced power.

In traditional payload architectures, each broadcast antenna is powered from a power amplification block of its own. Typically, each power amplification block comprises a plurality of amplifier circuits, such as traveling wave tubes, connected in parallel.

To achieve the power flexibility mentioned above, it has been envisaged to integrate switches at the output of each power amplification block, so as to orient the amplified signal towards one or other of the antennas of the power amplifier. diffusion (cf for example US 6438354). Nevertheless, these switches must be capable of switching to a high power radio frequency signal. Indeed, each switch is crossed by a signal whose power corresponds to all the power of diffusion of an antenna. Such components are very expensive, have a limited life (the lifetime of an electronic component depending on its power of operation), and, because they are added specifically in the payload circuit (and are not integrated electronic components and manufactured in series simultaneously with the entire electronic circuit), affect the general reliability of the payload. In addition, they can induce parasitic phenomena (arcs, breakdowns or inductive phenomena at switching, electronic surface avalanche effects (multipactor), Corona effects, transient oscillations ...) all the more significant that the power transmitted is important. In particular, they require the use of filtering to prevent the propagation of transient intensity oscillations at switching. The presence of such a filtering itself has the consequence of inducing a significant duration of switching and energy consumption. In addition, the use of switches operating at high power implies, in itself, reduced dynamic performance in that the switching requires a longer time than in the context of a low power switching.

Moreover, this known solution offers only a small flexibility of power allocation, since each broadcast antenna can be powered only by a power level which is an integer multiple of the power delivered individually by a block of power. power amplification, and at most by the power delivered by all the power amplification blocks.

Moreover, with this known solution, each broadcast antenna receives one or more data signal (s) to be broadcast, that is to say one or more channel (aux), but, conversely, the same signal data to be broadcast can not be distributed over multiple broadcast antennas.

Another solution envisaged to obtain a power allocation flexibility between the beams consists in modifying the gain of each amplification circuit, by varying a control voltage of this gain (bias voltage (US 6091934) or voltage of anode of a traveling wave tube (US 7181163)) as a function of the power level of the input signal to be broadcast or of a control signal transmitted by the ground. This solution has several disadvantages. First, it is complex and cumbersome in its implementation when the number of amplification circuits is important. In addition, the influence of the gain control voltage on the gain value is in practice subject to a number of variations from one circuit to another and therefore can not be determined with great precision, so that for a given command signal, the power delivered can vary to a certain extent, which affects the accuracy of the control. Such a performance uncertainty is in practice not compatible with the integration onboard a space system.

Moreover, this solution assumes that the amplification circuits are all designed to be able to transmit all of the maximum power, whereas each amplification circuit operates most of the time only for a lower power depending on the voltage of the amplifier. control. In other words, it makes it possible to reduce the power delivered by an amplification circuit on an antenna, but on the contrary does not make it possible to supply an antenna with a power that can be greater than the maximum power that can be delivered by a single amplification circuit. Therefore, it does not provide a real flexibility of power allocation to optimize the design of the different amplification circuits by reducing the performance of each of them to a strictly minimum value, the range of flexibility being limited to 3 dB power reduction when the anode voltage is varied. In addition, such a solution is not efficient in terms of efficiency. Indeed, the variations of the anode voltage of the traveling wave tubes induce yield losses.

In this context, the invention aims at providing a device for amplifying multi-beam data transmission payload power, in which the power diffused by each broadcasting antenna can be modified in real time according to the needs, in particular by sending remote controls to the satellite, finely, may be greater than the power delivered by each power amplification block fed by a data signal (that is to say by a channel), the device having in besides improved reliability, perfect stability of performance, longer life and improved dynamic response.

The invention aims in particular to provide such a power amplification device that provides a great flexibility of power allocation with a variation of relatively fine power levels, especially less than 500 W.

The invention also aims more particularly at providing such a power amplification device that makes it possible to broadcast the same data signal on several different broadcast antennas, the scattering power of this signal being distributed between these antennas.

The invention also aims at providing such a power amplification device that is otherwise compatible with its integration onboard a satellite, including a geostationary satellite.

The invention also aims at providing such a power amplification device whose design and manufacture is otherwise simple and does not impose new specific design steps with respect to the power amplification device itself. More particularly, the invention aims to provide such a power amplification device that can be composed of standard circuits manufactured in series and whose performance and reliability are controlled.

To this end, the invention relates to a device for amplifying the payload power of a multibeam data broadcasting satellite, comprising: a plurality of broadcast antennas each adapted to broadcast a data signal to be broadcast; a plurality of inputs each receiving a data signal to be broadcast, downstream of each input, a power amplification block comprising a plurality of individual amplification circuits connected in parallel, each amplification block the power supply being connected to one and only one input which supplies it, and being adapted to deliver a corresponding amplified signal, connecting means between the individual amplification circuits of each power amplification block and the antennas, these connecting means being adapted to enable the antennas to broadcast the amplified signals delivered by the amplification blocks,

characterized in that: each power amplification block has a plurality of outputs connected by said connecting means to a plurality of broadcast antennas, each output being connected to one and only one broadcast antenna, each power amplification unit comprises a switch device comprising at least two switches, and adapted to be able to connect selectively and independently of each other, different subsets of said individual amplification circuits of this power amplification block to the any of said diffusion antennas connected to the outputs of this power amplification block. Thus, in a device of the invention, for each data signal to be broadcast, several switches are provided to direct the power delivered by the power amplification block corresponding to this signal to one or more broadcast antennas. Consequently, the power traversed by each switch is even lower, which improves the performance of the switching, in particular reduces the effects of parasitic phenomena and transients, improves the lifetime and reliability of the whole circuit. In addition, the same data signal can be distributed over several separate antennas.

The switches integrated in each amplification block may be arranged in any appropriate manner making it possible to vary the number of subsets of said individual amplification circuits connected to each diffusion antenna connected to this amplification block, and therefore the power the signal supplied to each broadcast antenna. Preferably, advantageously and according to the invention, each switch is disposed downstream of said subassembly, in series with the latter. Thus, advantageously, a device according to the invention is characterized in that each power amplification block comprises, downstream of the individual amplification circuits, at least two switches, each switch having a plurality of output terminals, and an input terminal connected to a single subset of individual amplifier circuits whose output is connected to the input terminal of a single switch, each switch being adapted to electrically connect its input terminal to the input terminal. one or the other of its output terminals, and in that said connecting means are adapted to connect each output terminal of each switch to one of the outputs of the power amplification block, and therefore to the one of the diffusion antennas, so that each switch allows, according to its state, to connect a subset of individual amplifier circuits selectively and independently to one or the other of the diffusion antennas connected to the outputs of this power amplification block. In a device according to the invention, each individual amplification circuit may be formed of a traveling wave tube (in particular in the case of a geostationary multibeam satellite), or of a solid state amplifier circuit (integrated circuit). when the total power to be delivered is less important, for example in the case of a multibeam satellite in low orbit or when the frequency band imposes this choice of technology.

Moreover, in a device according to the invention, the power conveyed in each branch of the wiring formed by said connecting means between the individual amplification circuits and the antennas being reduced, it is possible, also in the context of a geostationary satellite payload, to overcome the use of waveguides to achieve these means of connection. Thus, a device according to the invention is advantageously characterized in that said connecting means are formed of coaxial cables, and in that each switch is formed of a coaxial switch of spatial quality. Furthermore, preferably, each power amplification block comprises 2 ° individual amplification circuits, n being a non-zero integer. In addition, advantageously and according to the invention, each subset of individual amplification circuits comprises 2m individual amplification circuits, m being an integer ranging between 0 and 2 and less than n. In an advantageous embodiment, and according to the invention, each subset comprises a single individual amplification circuit (m is equal to 0). For example, each subset comprising a single individual amplification circuit, a single switch being provided immediately downstream of this individual amplification circuit. In a preferred embodiment of a device according to the invention more particularly intended for the payload of a geostationary satellite, each individual amplification circuit provides a power of between 200 W and 500 W. The invention extends to also a multibeam data broadcast satellite characterized in that it comprises at least one payload comprising at least one power amplification device according to the invention supplying each of its broadcast antennas. Advantageously and according to the invention, it is a geostationary satellite. However, the invention is equally applicable to a multibeam satellite in non-geostationary orbit, including a satellite in medium or low or elliptical orbit.

The invention also relates to a power amplification device and a satellite characterized in combination by all or some of the characteristics mentioned above or below. Other objects, features and advantages of the invention will be apparent from the following description which refers to the appended figures in which: FIG. 1 is a schematic view of a satellite according to the invention, FIG. 2 is a general diagram of a satellite payload according to one embodiment of the invention, Figures 3 to 5 are diagrams respectively showing three alternative embodiments of a power amplification device according to the invention.

FIG. 1 represents an example of a geostationary satellite 1 according to the multibeam invention, that is to say comprising a plurality of diffusion antennas 4, 5 (namely two diffusion antennas only in the example represented).

The data signals to be broadcast are transmitted from at least one ground station 20 by at least one uplink 21, the satellite 1 having at least one receiving antenna (or beam) 19.

FIG. 1 represents only one example, and it is understood that the invention applies to any other configuration, for example to each satellite of a satellite constellation, in the case of multibeam satellites comprising a number of antennas of broadcasting greater than 2, to non-geostationary satellites ...

The payload 3 of a multimedia broadcast satellite 1 compatible with the 3G standards comprises a plurality of broadcast antennas each covering a region, for example a country, and receives ground 2 digital data to be broadcast on different regions. This data is converted into a plurality of channels to be broadcast, each channel being amplified and delivered to a broadcast antenna.

FIG. 2 represents an exemplary configuration of the payload 3 of such a satellite 1 according to the invention, which constitutes a repeater.

The data to be broadcast are received on at least one reception antenna 19. A first stage 22 processes this data in reception by performing a filtering for suppressing the interfering signals from other systems, and keeping only the useful signal arriving at the payload level 3, this useful signal can be transmitted either by a high-speed carrier or by a group of adjacent carriers Io. The first stage 22 forms a plurality of parallel channels, i.e. a plurality of data signals to be broadcast, the number of which corresponds to the number of satellite broadcast antennas 4, 5. Each channel feeds a second stage 23 in which the signals are amplified by a low noise amplifier LNA (Low Noise Amplifier) whose active elements are adapted to provide a very low noise factor, while amplifying the signal to a sufficient level for subsequent stages of the payload. A third stage 24 of the payload makes it possible to carry out a frequency transposition so that each channel is transmitted on a carrier frequency of its own. This frequency transposition converts the signal from the allocated uplink frequency band into the frequency band allocated to the downlink frequency. The different channels are then processed in a fourth stage 25 whose function is, on the one hand, to process the signals possibly up to demodulation, reshaping and then remodulation, then to distribute the different channels on the different inputs 9 , 10 different power amplification blocks 7, 8 of a power amplifier device 6 according to the invention. The power amplification device 6 according to the invention comprises for each input 9, 10 and downstream of this input 9, 10, a power amplification block 7, respectively 8. Each power amplification block 7 , 8 thus has an input 9, 10 thus receiving a channel, that is to say a data signal to be broadcast on each broadcast antenna 4, 5 connected to this power amplification block 7, 8.

The device 6 of power amplification according to the invention comprises a number of inputs 9, 10, and therefore a number of power amplification blocks 7, 8, which corresponds to the number of diffusion antennas 4, 5 which must to be able to operate simultaneously. Thus, each of the broadcast antennas 4, 5 capable of operating simultaneously can be powered from a single power amplification block 7, 8 if necessary.

Each data signal to be broadcast is formed of a signal modulated on a carrier frequency, and the frequencies of the different distinct data signals can be different so that the payload 3 can simultaneously transmit without interference a plurality of data signals at a time. from each of its different diffusion antennas 4, 5. Each power amplification block 7, 8 comprises, downstream of the corresponding input 9, a plurality of individual amplification circuits 15 connected in parallel. Each individual amplification circuit may be formed of a traveling wave tube or a solid state amplifier circuit (integrated circuit). Each individual amplification circuit preferably provides a power of between a few Watts and 500 W. The coupling of a plurality of individual amplification circuits in parallel makes it possible to use for each of the elements (switches, guides, combiners, ...) located downstream of these circuits 15, a technology requiring a lower performance, and therefore simpler and more reliable and more technologically accessible. Each individual amplification circuit 15 may or may not incorporate a pre-amplification stage, a linearization circuit, a phase shifter circuit and a power supply. Each individual amplifier circuit has an input terminal 26 and an output terminal 27.

The input terminals 26 of the various individual amplification circuits 15 of each power amplification block 7, 8 are connected to the input 9, 10 of this power amplification unit 7, 8 by branches of pair derivation to ensure identical path length for all individual amplification circuits.

Each power amplification block 7, 8 preferably comprises 2 ° individual amplification circuits, n being a non-zero integer. Moreover, each power amplification block 7, 8 has a number of outputs 11, 12, 13, 14 corresponding to the number of diffusion antennas 4, 5 to be connected simultaneously to this power amplification unit 7. 8. In the embodiments shown, the payload 3 comprises two broadcast antennas 4, 5, and the power amplification device 6 according to the invention comprises two power amplification blocks 7, 8. The first block (power amplification 7 has a first output 11 connected to the first diffusion antenna 4 and a second output 12 connected to the second diffusion antenna 5, and the second power amplifier block 8 has a first output 13 connected to the first diffusion antenna 4 and a second output 14 connected to the second diffusion antenna 5. It goes without saying that any other embodiment variant can be envisaged with a different number of diffusion antennas and power amplification blocks. Each power amplification block 7, 8 comprises, downstream of the individual amplification circuits, at least two switches 16, 17, 18. Each switch 16, 17, 18 having a plurality of output terminals 33, 34; 40, 41; 47, 48, and an input terminal 32, 39, 46 connected to a single subassembly 28, 35, 42 of individual amplification circuits. The output of each subassembly 28, 35, 42 is connected to the input terminal 32, 39, 46 of a single switch 16, 17, 18, each switch 16, 17, 18 being adapted to electrically connect said terminal input 32, 39, 46 at one or other of its output terminals 33, 34; 40, 41; 47, 48. In addition, each output terminal 33, 34; 40, 41; 47, 48 of each switch 16, 17, 18 is connected to one of the outputs 11, 12, 13, 14 of the power amplifier block 7, 8, and therefore to one of the diffusion antennas 4, 5 , so that each switch 16, 17, 18 allows, according to its state, to connect a subassembly 28, 35, 42 of individual amplifier circuits selectively and independently to one or the other of the diffusion antennas 4, 5 connected to the outputs 11, 12, 13, 14 of this power amplification block 7, 8. The different power amplification blocks 7, 8 are all identical, comprise the same number of individual circuits of the power amplifier block. amplification power and the same number of switches 16, 17, 18. Preferably, each switch 16, 17, 18 has a number of output terminals 33, 34; 40, 41; 47, 48 equal to two, and each power amplification block 7, 8 has a number of switches 16, 17, 18 adapted to allow each of the outputs of each subassembly 28, 35, 42 to be connected to each other. one or the other of the diffusion antennas 4, 5 connected to this power amplification block 7, 8. In the first embodiment shown in FIG. 3, each power amplification block 7, 8 comprises eight individual circuits 15 amplification, each subassembly 28 comprises four individual amplification circuits. Each power amplification block 7, 8 comprises two switches 16. The input terminal 32 of a first switch 16 is connected to the output terminal of a first subassembly 28, and the input terminal 32 a second switch 16 is connected to the output terminal of a second subassembly 28.

Each switch 16 has a first output terminal 33 connected to the first diffusion antenna 4, and a second output terminal 34 connected to the second diffusion antenna 5. As shown in FIG. 3, the links between the different output terminals 33, 34 of each switch 16 and each diffusion antenna 4, 5 respectively are preferably adapted to have identical lengths. These connections can be made in the form of three-dimensional waveguides or in the form of coaxial cables. The same applies to the connection between the output terminal 27 of each individual amplifier circuit 15 and the input terminal 32 of each switch 16.

The switches 16 may be formed of coaxial switches of spatial quality, for example of the reference type SPDT, DPDT, DP3T, T type marketed by Radian (Rosny-sous-Bois, France). The embodiment of FIG. 4 differs from that of FIG. 3 in that each subassembly 35 comprises only two individual amplification circuits 15, and each power amplifier block 7, 8 then has four switches 17 whose input terminal 39 is connected to the output terminal of a subset. Each switch 17 has a first output terminal 40 connected to the first diffusion antenna 4, and a second output terminal 41 connected to the second diffusion antenna 5.

The embodiment of FIG. 5 differs from that of FIG. 3 in that each subassembly 35 comprises a single amplifying individual circuit, and each power amplification block 7, 8 then has eight switches 18 whose input terminal 46 is connected to the output terminal of a subassembly. Each switch 18 has a first output terminal 47 connected to the first diffusion antenna 4, and a second output terminal 48 connected to the second diffusion antenna 5. The configuration of the embodiment shown in FIG. to obtain the best power allocation flexibility, since each individual amplification circuit 15 is connected to a specific switch 18 and can supply its power to one or other of the diffusion antennas 4, 5. But this configuration requires more switches installed. When the number of diffusion antennas 4, 5 to be connected to each output 11, 12, 13, 14 of each power amplification block 7, 8 is different from 2, each switch 16, 17, 18 must be formed. not by a single switching circuit, but by a circuit stage connected bypass so as to present the number of appropriate outputs, with an identical line length between each output, so as to introduce no phase shift. Each switch 16, 17, 18 is controlled from a remote-type signal sent from a remote control ground station. If necessary, filtering components may be incorporated in each power amplification block 7, 8, downstream of the switches 16, 17, 18, and / or between the power amplification blocks 7, 8 and the antennas 4, 5. By way of example, a power amplification device according to FIG. 5 can be realized in the case of S-band audio or video type broadcasting on the basis of amplifiers of the type traveling wave tubes. In the case where the amplification is envisaged in the S-band, high power levels can be achieved with traveling wave tubes (TWTs), such as those marketed by Thales Electron Devices in Europe. For the S-band, such traveling wave tubes have the following characteristics: Frequency of use: 2.3 to 27 GHz Saturation power: 230 W - Bandwidth of the tube: 200 MHz Saturation efficiency: 64% Gain: 35 dB Phase shift: 45 ° At saturation, such a tube consumes 399 W and dissipates 166 W. At the thermal level, traveling wave tubes can be conductive or radiative.

For some signals with complex modulations, a high linearity is required, which requires to provide a decline in power relative to the saturation, for example 4 dB. The output of the traveling wave tube is then of the order of 40%. The tube provides an RF power of 90 W. Under these conditions the amplifier consumes 250 W and dissipates 160 W (including the performance of power supplies, typically of the order of 90%). An architecture based on Solid State Power Amplification (SSPA) circuits in place of traveling wave tubes provides similar benefits. The typical performances of the L20 and C-band SSPA amplifiers are given in the following table: Band L Band C Frequency band 1575 MHz 3.714,: 2 GHz Bandwidth 10 MHz 300 MHz Output power 34 W mc / 55 W cw 20 W nominal cw 70 dB nominal gain 79 dB The invention makes it possible in particular to avoid high power output, and therefore to minimize the so-called Multipactor microwave discharge discharge phenomena in the presence of high power. More generally, the invention makes it possible: to achieve equivalent targeted RF power, to overcome expensive tests concerning Multipactor phenomena, for equivalent equipment performance used, to increase the number of amplification circuits to be recombined in the field. payload. The invention may be the subject of numerous alternative embodiments with respect to the embodiments which are described above and shown in the figures, solely by way of non-limiting examples. In particular, the numbers of broadcast antennas, power amplification blocks, individual amplification circuits in each power amplification block, and in each subset, as well as the number of switches, the location and the arrangement of these switches may vary.

Similarly, while the invention is advantageously applicable for broadcasting data representing multimedia contents from a geostationary satellite to mobile terminals on the ground, it can however find many other applications in which it has the same advantages. For example, the invention can be used for producing a power amplification device of a multibeam satellite payload in low or medium orbit.

Claims (1)

CLAIMS 1 / - A payload power amplification device of a multibeam data broadcasting satellite, comprising: a plurality of broadcasting antennas (4, 5) each adapted to broadcast a data signal to be broadcast, a plurality of inputs (9, 10) each receiving a data signal to be broadcast, - downstream of each input (9, 10), a power amplification block (7, 8) comprising a plurality of individual amplification circuits (15) connected in parallel, each power amplification block (7, 8) being connected to one and only one input (9, 10) which supplies it, and being adapted to deliver a signal amplified corresponding, connecting means between the individual amplification circuits (15) of each block of power amplification (7, 8) and the antennas (4, 5), these connecting means being adapted to allow the broadcasting, by the antennas (4, 5), amplified signals delivered s by the amplification blocks (7, 8), characterized in that: each power amplification block (7, 8) has a plurality of connected outputs (11, 12, 13, 14) by said means link, to a plurality of broadcast antennas (4, 5), each output (11, 12, 13, 14) being connected to one and only one scattering antenna (4, 5), to each block (7 8) comprises a switch device (16, 17, 18) having at least two switches, and adapted to selectively and independently connect to each other different subassemblies (28, 35, 42). ) of said individual amplification circuits (15) of said power amplification block (7, 8) to any one of said diffusion antennas (4, 5) connected to the outputs (11, 12, 13, 14) of this power amplification block. 2 / - Device according to claim 1, characterized in that each block (7, 8) of power amplification comprises, downstream of the individual amplification circuits (15), at least two switches (16, 17 , 18), each switch having a plurality of output terminals (33, 34, 40, 41, 47, 48), and an input terminal (32, 39, 46) connected to a single subset (28, 35, 42) of individual amplification circuits (15) whose output (27) is connected to the input terminal of a single switch (16, 17, 18), each switch being adapted to electrically connect its terminal input (32, 39, 46) at one or other of its output terminals (33, 34, 40, 41, 47, 48), and in that said connecting means are adapted to connect each terminal output (33, 34, 40, 41, 47, 48) of each switch (16, 17, 18) to one of the outputs (11, 12, 13, 14) of the amplification block (7, 8) of power, and therefore to one of the antennas (4, 5) of diffusion, so that each mutator (16, 17, 18) allows, according to its state, to connect a subset (28, 35, 42) of individual amplification circuits (15) selectively and independently to one or other of the antennas ( 4, 5) connected to the outputs of this block (7, 8) of power amplification. 3 / - Device according to one of claims 1 or 2, characterized in that said connecting means are formed of coaxial cables, and in that each switch (16, 17, 18) is formed of a coaxial switch quality Space. 4 / - Device according to one of claims 1 to 3, characterized in that each circuit (15) individual amplification is formed of a traveling wave tube. 5 / - Device according to one of claims 1 to 3, characterized in that each amplification circuit (15) is formed of a solid state amplifier circuit. 6 / - Device according to one of claims 1 to 5, characterized in that each block (7, 8) of power amplification comprises 2 'circuits (15) individual amplification, n being an integer between 1 and an integer. 7 / - Device according to claim 6, characterized in that each subassembly (28, 35, 42) of individual amplification circuits (15) comprises 2m individual amplification circuits (15), m being an integer which can vary between 0 and 2 and less than n. 8 / - Device according to claims 1 to 7, characterized in that each individual amplification circuit (15) provides a power of between a few watts and 500 W. 9 / - satellite multibeam data broadcast characterized in that it comprises at least one payload comprising at least one power amplification device according to one of claims 1 to 8, supplying each of its diffusion antennas (4, 5). 10 10 / - Satellite according to claim 9, characterized in that it is a geostationary satellite.