Architecture of a wideband distributed amplification device

The invention claimed is: 1. A distributed amplification device, intended for a communications payload of a satellite, comprising: a distributed amplification reservoir for amplifying a first plurality of a first integer number p greater than or equal to 2 of radio frequency amplifier input signals, received by a first input port of input terminals, mutually identical to within a phase, into a second plurality of respective p amplified RF signals supplied by a second output port of output terminals, associated respectively with the input terminals of the first input port, the distributed amplification reservoir comprising: a set of a second integer number n, greater than p and less than or equal to 2p+1, of amplifiers arranged electrically in parallel and respectively forming internal amplification pathways, mutually insulated electromagnetically and equalized, and respectively numbered by a row index varying from 1 to the second integer number n, the set of the n amplifiers being composed of a first series of p nominal radio frequency amplifiers and of a second series of n p back-up amplifiers, an input redundancy ring, formed by a first array of four pole rotary switches, and an output redundancy ring, formed by a second array of four pole rotary switches, the input and output redundancy rings being connected respectively between the first input port and a third port of input terminals of the set of the n amplifiers and between a fourth port of output terminals of the set of the n amplifiers and the second output port, to implement a family of routing configurations having a nominal routing configuration which uses the p nominal amplifiers of the first series as active amplifiers, and one or more back-up routing configurations, which each use at least one of the n p back-up amplifiers out of the p active amplifiers selected from the set of the n amplifiers, the distributed amplification device wherein: the input and output redundancy rings use similar propagation conditions; and the input and output redundancy rings are topologically and geometrically configured such that each routing configuration of the family comprises a set of p independent distributed amplification paths, each amplification path individually including an input terminal of the first port, the output terminal of the second port associated with the input terminal of the first, an active amplifier and its row number, first passive links connected in series and passing through at least three rotary switches of the input redundancy ring and linking the input terminal of the first port to the input terminal of the active amplifier, and second passive links connected in series and passing through at least one switch of the output redundancy ring and linking the output terminal of the active amplifier to the output terminal of the second port; and electrical lengths of all the paths of one and the same routing configuration of the family are equal. 2. The distributed amplification device according to claim 1 , wherein the input and output redundancy rings are topologically and geometrically configured and the family of the routing configurations is chosen such that electrical lengths of all the paths of all the family are equal. 3. The distributed amplification device according to claim 1 , wherein, upon a reconfiguration of a first routing configuration of the family to a second routing configuration of the family, the differences in electrical lengths deriving from the reconfiguration of the input ring are compensated by the reconfiguration of the output redundancy ring for each modified distributed amplification path. 4. The distributed amplification device according to claim 1 , wherein same technology is shared by the input and output redundancy rings, and is included in the set formed by coaxial technology and waveguide technology. 5. The distributed amplification device according to claim 1 , wherein independently of all the paths of all the routing configurations of the family of the reservoir, the rotary switches of one and the same amplification path are passed through globally in same way in terms of the number of rotary switches passed through of one and the same path and the numerical distribution of the switching configurations of the rotary switches activated in this path. 6. The distributed amplification device according to claim 1 , wherein the family of the routing configurations comprises a nominal routing configuration which uses the p nominal amplifiers of the first series as active amplifiers, and one or more back-up routing configurations which each use at least one of the n p back-up amplifiers out of the p active amplifiers selected from the set of the n amplifiers; the back-up routing configuration or configurations being determined to maintain a maximum amplification capacity of the reservoir in all failure cases of at most p amplifiers out of the set of the n amplifiers when p is less than or equal to n, and at most p+1 amplifiers out of the set of the n amplifiers when n is equal to 2p+1. 7. The distributed amplification device according to claim 1 , wherein the first array of the interconnected switches of the input redundancy ring is arranged according to a first matrix of which elements are the input four pole rotary switches and form first nodes arranged in at least two columns and n rows, the n rows corresponding to the n rows of the internal amplification pathways, p first upstream end nodes of a first upstream end column being connected to the p input terminals of the first port and n first downstream end nodes of a first downstream end column being connected respectively one by one to the input terminals of the n amplifiers; and the second array of the interconnected switches of the output redundancy ring is arranged according to a second matrix of which the elements are the output rotary switches and form second nodes arranged in at least one column and n rows, the n rows corresponding to the rows of the n internal amplification pathways with the same numbering, p second downstream end nominal nodes of a second downstream end column being connected to the p output terminals of the second port and n second upstream end nodes of a second upstream end column being connected upstream respectively to the output terminals of the amplifiers according to the same rank, when the second matrix comprises at least two second columns; or p second downstream and upstream end nodes of a single second end column connected downstream to the output terminals of the second port and connected upstream respectively to the output terminals of the nominal amplifiers according to same rank, and n-p second remaining upstream end nodes connected upstream respectively to the output terminals of the amplifiers when the second matrix comprises a single second column. 8. The distributed amplification device according to claim 7 , wherein at least one switch out of the switches of the first upstream end column and of the second upstream end column is replaced by a link of a same electrical length. 9. The distributed amplification device according to claim 7 , wherein the first matrix comprises two or three columns and the second matrix comprises a single column. 10. The distributed amplification device according to claim 1 , wherein the distributed amplification reservoir comprises amplitude and phase setting means, arranged upstream and/or downstream of each amplifier between the input and output redundancy rings, preferably upstream when the amplifiers are power amplifiers and preferably downstream when the amplifiers are low noise amplifiers; and the amplitude and phase setting means are configured to balance all the distributed int