Scalable architecture for digital signal processing

The invention claimed is: 1. Architecture for implementing digital signal processors, defined by a plurality of physically distinct processors connected by high speed digital interconnections in which: a first plurality of first signal processors have a plurality of analogue or digital signal inputs and are arranged to perform a first set of digital processing functions and produce a first plurality of digital interconnection outputs; a second plurality of second signal processors arranged to receive the first plurality of digital interconnection outputs and perform a second set of digital processing functions and produce a second plurality of digital interconnection outputs; and a third plurality of third signal processors arranged to receive the second plurality of digital interconnection outputs and perform a third set of digital processing functions and produce a plurality of analogue or digital signal outputs; wherein the architecture is scalable by selection of the number of first signal processors, the number of second signal processors and the number of third signal processors and the interconnections between the first, second and third signal processors such that the signal processing required of a digital signal processor is achieved through the distribution of the processing over the combination of the selected numbers of first, second and third signal processors, wherein the number of first signal processors is independent of the number of third signal processors. 2. Architecture according to claim 1 , where the first signal processors are arranged to process analogue input signals by performing at least one of: analogue-to-digital conversion, frequency conversion, amplification, filtering, combining, and splitting. 3. Architecture according to claim 1 wherein the third signal processors are arranged to process analogue output signals by performing at least one of: digital-to-analogue conversion, frequency conversion, amplification, filtering, combining, and splitting. 4. Architecture according to claim 1 , wherein each of the signal processors is electrically independent and each has its own power supply. 5. Architecture according to claim 1 , wherein each of the signal processors is mechanically and thermally independent. 6. Architecture according to claim 1 wherein the number of first signal processors, the number of second signal processors and the number of third signal processors is selected so as to include system redundancy against failure through switching individual signal processors on or off. 7. Architecture according to claim 1 wherein the high speed digital interconnections are serial connections and are electrical or optical methods of communication. 8. Architecture according to claim 1 , wherein the first signal processors perform digital channelisation and a first stage of transparent routing on the input signals and the first digital interconnection output signals represent channelised frequency bands of those signals. 9. Architecture according to claim 8 , wherein the second signal processors perform transparent routing of the channelised frequency bands. 10. Architecture according to claim 9 wherein the third signal processors perform a final stage of transparent routing and digital recombination of the channelized frequency bands. 11. Architecture according to claim 9 wherein the second signal processors perform digital beamforming of the channelised frequency bands on the digital input signals from an antenna to produce digital output signals representing beams. 12. Architecture according to claim 1 wherein the second signal processors perform a regenerative functions of demodulation, decoding, encoding or modulation. 13. Architecture according to claim 1 wherein the digital processing function is reprogrammable after manufacture. 14. Architecture according to claim 1 wherein control messages are routed along the high speed digital interconnections used to exchange signal data between signal processors. 15. Architecture according to claim 1 , wherein control messages are conveyed to or from each signal processor using dedicated control interfaces and means of distribution external to the signal processors. 16. Architecture according to claim 1 , in which the first signal processors and/or the second signal processors and/or the third signal processors are arranged in a plurality of sub-groups representing different processing functions. 17. Architecture according to claim 1 , wherein the processing signal processors are adapted for mounting on a satellite. 18. Architecture according to claim 1 , wherein the first signal processors have a plurality of digital interconnection inputs. 19. Architecture according to claim 1 , wherein the third signal processors have a plurality of digital interconnection outputs. 20. A method of testing a digital signal processor formed using the architecture of claim 1 , the method comprising: a phased testing of a plurality of the physically distinct processing signal processors or groups of signal processors, including environmental testing, before final testing of a full scale processor. 21. A method of configuring a digital signal processor using architecture comprising a plurality of physically distinct processing signal processors connected by high speed digital interconnections to combine to perform the processing required of the digital signal processor, the method comprising: arranging a first plurality of first signal processors, having a plurality of analogue or digital signal inputs, to perform a first set of digital processing functions and produce a first plurality of digital interconnection outputs; arranging a second plurality of second signal processors to receive the first plurality of digital interconnection outputs and perform a second set of digital processing functions and produce a second plurality of digital interconnection outputs; and arranging a third plurality of third signal processors to receive the second plurality of digital interconnection outputs and perform a third set of digital processing functions and produce a plurality of analogue or digital signal outputs; and scaling the architecture by selecting the number of first signal processors, the number of second signal processors and the number of third signal processors in accordance with the processing required of the digital signal processor, wherein the number of first signal processors is independent of the number of third signal processors.