Photonic beamforming for active antennas

The invention claimed is: 1. A photonic beamforming system for a satellite payload, comprising: a modulation stage configured to modulate a plurality of N electrical signals from a plurality of N antenna elements receiving one or more signal beams, onto an optical carrier, to output a respective plurality of N optical signals, wherein N=2 L for integer L>1; and a network having an input to receive the plurality of N optical signals, the network arranged to resolve the one or more signal beams into each of a predetermined plurality of N beam angles with respect to the N antenna elements to output, from an output of the network, a plurality of N beamformed signals corresponding to each of the predetermined plurality of N beam angles by, for each one of the plurality of N optical signals, summing the one of the plurality of N optical signals with each of the other N−1 of the plurality of optical signals phase shifted relative to the one of the plurality of N optical signals by a respective phase shift; wherein each of the respective phase shifts is such that the one of the plurality of N optical signals interferes with each of the other N−1 phase shifted plurality of optical signals when summed, to form a beamformed signal having a respective one of the predetermined N beam angles; wherein the network comprises a plurality of L·2 L−1 2×2 optical couplers, each of the plurality of 2×2 optical couplers having two optical signal inputs and two optical signal outputs, each 2×2 optical coupler having a control input to control a phase shift applied by the 2×2 optical coupler between a respective pair of the plurality of N optical signals input to the two optical signal inputs of the 2×2 coupler; wherein an optical fast Fourier transform, OFFT, is applied to the plurality of N optical signals by controlling the respective phase shift applied at each of the plurality of 2×2 optical couplers, and by arranging the plurality of 2×2 optical couplers in a sequence of L ranks of 2 L−1 couplers between the input and the output of the network, wherein the L ranks comprise an output rank at the output of the network, and one or more further ranks preceding the output rank in the sequence, such that, for each of the plurality of 2×2 optical couplers in the one or more further ranks, a first of the two optical outputs is connected to an input of a first coupler in a subsequent rank in the sequence, and a second of the two optical outputs is connected to an input of a second coupler in the subsequent rank in the sequence. 2. The photonic beamforming system of claim 1 , wherein each of the plurality of 2×2 optical couplers comprises a tuneable phase shifter at each of its inputs, wherein each tuneable phase shifter is controlled by a respective beamforming control input. 3. The photonic beamforming system of claim 1 , wherein each of the plurality of 2×2 optical couplers comprises a tuneable phase shifter at one of its inputs, and a fixed phase shifter at the other of its inputs, wherein the tuneable phase shifter is controlled by a respective beamforming control input. 4. The photonic beamforming system of claim 1 further comprising a switching stage, configured to select a subset of the beamformed signals output by the network for processing at the payload. 5. The photonic beamforming system according to claim 4 , wherein the switching stage is configured to select the subset of the beamformed signals according to a beamhopping scheme. 6. An interference cancellation system, comprising: the photonic beamforming system of claim 1 ; an interference monitoring stage configured to monitor the output of the network of the photonic beamforming system for one or more interfering signals, and determine a one or more respective interfering beam angles of the one or more interfering signals; a nulling stage, configured to null the one or more interfering beam angles in the output of the network; and a further network, configured to reconstruct the signal input to the photonic beamforming system by applying an inverse OFFT without the one or more interfering beam angles. 7. A photonic beamforming system for a satellite payload, comprising: a network, having an input to receive a plurality of N optical signals, the network arranged to generate, from the plurality of N input optical signals at an output of the network, one or more beamformed signals at a respective one or more of a predetermined plurality of N beam angles with respect to the N antenna elements, by, for each one of the plurality of N optical signals, summing the one of the plurality of N optical signals with each of the other N−1 of the plurality of optical signals phase shifted relative to the one of the plurality of N optical signals by a respective phase shift, wherein N=2 L for integer L>1; wherein each of the respective phase shifts is such that the one of the plurality of N optical signals interferes with each of the other N−1 phase shifted plurality of optical signals when summed, to form a beamformed signal having a respective one of the predetermined plurality of N beam angles; and a conversion stage configured to convert the one or more beamformed optical signals into one or more electrical signals for transmission in the one or more beams by a plurality of antenna elements; wherein the network comprises a plurality of L·2 L−1 2×2 optical couplers each of the plurality of 2×2 optical couplers having two optical signal inputs and two optical signal outputs, each 2×2 optical coupler having a control input to control a phase shift applied by the 2×2 optical coupler between a respective pair of the plurality of N optical signals input to the two optical signal inputs of the 2×2 coupler; wherein an optical inverse fast Fourier transform, OIFFT, is applied to the plurality of N optical signals by controlling the respective phase shift applied at each of the plurality of 2×2 optical couplers, and by arranging the plurality of 2×2 optical couplers in a sequence of L ranks of 2 L−1 couplers between the input and the output of the network, wherein the L ranks comprise an output rank at the output of the network, and one or more further ranks preceding the output rank in the sequence, such that, for each of the plurality of 2×2 optical couplers in the one or more further ranks, a first of the two optical outputs in connected to an input of a first coupler in a subsequent rank in the sequence, and a second of the two optical outputs is connected to an input of a second coupler in the subsequent rank in the sequence. 8. The photonic beamforming system of claim 7 , wherein each of the plurality of 2×2 optical couplers comprises a tuneable phase shifter at each of its inputs, wherein each tuneable phase shifter is controlled by a respective beamforming control input. 9. The photonic beamforming system of claim 7 , wherein each of the plurality of 2×2 optical couplers comprises a tuneable phase shifter at one of its inputs, and a fixed phase shifter at the other of its inputs, wherein the tuneable phase shifter is controlled by a respective beamforming control input. 10. The photonic beamforming system of claim 7 , further comprising an optical switch and/or splitter configured to switch and/or split at least one of the input signals into a plurality of input signals for provision to the network. 11. A photonic satellite payload comprising: a first photonic beamforming system according to claim 1 arranged to receive a plurality of signals from a first plurality of antenna elements; one or more photonic signal processors arranged to process the plurality of beamformed signals output by the first photonic beamforming system; and a second photonic beamfor