A processor, comprising a first data input configured to receive a stream of samples of a first signal having a spectral space, the stream having a data rate of at least 4 GHz; a second data input configured to receive a stream of samples of a second signal; a multitap correlator, configured to rece
A processor, comprising a first data input configured to receive a stream of samples of a first signal having a spectral space, the stream having a data rate of at least 4 GHz; a second data input configured to receive a stream of samples of a second signal; a multitap correlator, configured to receive the first stream of samples and the second stream of samples, and producing at least one correlation output for each respective sequential sample of the first signal received; and a programmable control configured to alter a relationship of the stream of samples of the first signal and the stream of samples of the second signal, to thereby select, under program control, an alterable correlation output.
대표청구항▼
1. A radio transceiver system for receiving communications in a band concurrently with transmissions from a transmitter transmitting in the band, comprising: (a) an input port, configured to receive a first signal comprising the communications in the band and the transmission in the band from the tr
1. A radio transceiver system for receiving communications in a band concurrently with transmissions from a transmitter transmitting in the band, comprising: (a) an input port, configured to receive a first signal comprising the communications in the band and the transmission in the band from the transmitter;(b) a receiver, having a dynamic range sufficient to concurrently represent the communications in the band and the transmissions as a first analog signal;(c) a plurality of analog time delay elements, each being configured to receive, selectively weight and combine an analog representation of the received first analog signal, to produce a second analog signal;(d) a digitizer configured to produce a digitized signal from the second analog signal; and(e) a processing subsystem, comprising at least one of a digital correlator and a Fourier transform processor, configured to: control a respective weight of respective ones of the plurality of analog time delay elements in dependence on the digitized signal, to produce the second analog signal representing at least partial cancellation of the transmission in the band while preserving the communications in the band; anddigitally cancel at least a portion of a residual transmission in the band in dependence on at least digitized signal; and(f) an output port configured to communicate the received communications. 2. The radio transceiver according to claim 1, wherein the transmitter is co-located with the receiver. 3. The radio transceiver according to claim 1, wherein the digitizer has a dynamic range insufficient to fully represent information in the received communications in the first analog signal. 4. The radio transceiver according to claim 3, wherein the digitizer has a sufficient dynamic range to fully represent information in the received communications present in the second analog signal the at least partial cancelled transmission in the band. 5. The radio transceiver according to claim 1, wherein the processing system comprises at least one digital correlator. 6. The radio transceiver according to claim 5, wherein the at least one digital correlator comprises an autocorrelator. 7. The radio transceiver according to claim 5, wherein the at least one digital correlator comprises a cross correlator. 8. The radio transceiver according to claim 1, wherein the input port comprises a plurality of input ports, each receiving a respective signal from an antenna element of an antenna array, the plurality of analog time delay elements being arranged into a plurality of sections, each respective section receiving an analog representation of a respective received first signal from a respective antenna element. 9. The radio transceiver according to claim 1, wherein the transmissions in the band comprise intermodulation distortion components in the band. 10. A method of receiving communications in a band concurrently with emission of transmissions in the same band, comprising: (a) receiving a first signal through an input port, comprising the communications in the band and the transmission in the band;(b) providing a plurality of analog time delay elements, each receiving an analog representation of the received first signal, the plurality of analog time delay elements being selectively weighted and combined to produce a processed analog signal;(e) controlling the weighting of the plurality of analog time delay elements, to produce the processed analog signal representing at least partial cancellation of the transmission in the band while preserving information of the communications in the band;(f) digitizing the processed analog signal with a digitizer to produce a digitized signal;(g) at least one of digitally correlating and digitally Fourier transforming at least a portion of the digitized signal;(h) generating a digital cancellation signal in dependence on at least the digitized signal; and(i) further cancelling the transmission in the band from the digitized signal, while preserving the information of the communications in the band. 11. The method according to claim 10, wherein the transmissions in the same band are emitted by a transmitter co-located with the input port. 12. The method according to claim 10, wherein the digitizer has a dynamic range insufficient to fully represent information of the received communications in the band and the transmission in the same band. 13. The method according to claim 12, wherein the digitizer has a sufficient dynamic range to represent the information of the communications in the band and the at least partially cancelled transmission in the band. 14. The method according to claim 10, wherein said at least one of digitally correlating and digitally Fourier transforming at least a portion of the digitized signal comprises digitally correlating at least a portion of the processed analog signal. 15. The method according to claim 14, wherein the digitally correlating is performed with at least one autocorrelator. 16. The method according to claim 14, wherein the digitally correlating is performed with at least one cross correlator. 17. The method according to claim 10, wherein the communications in the band are received through an antenna array, the input port comprises a plurality of input ports, each receiving a respective signal from an antenna element of the antenna array, and the plurality of analog time delay elements are arranged into a plurality of sections, each respective section receiving an analog representation of a respective received first signal from a respective antenna element, and producing a respective processed analog signal. 18. A radio receiver for receiving information from radio frequency communications in a same band as a concurrently operating transmitter is transmitting interfering signals in, comprising: (a) an input port, configured to receive a first signal comprising the communications in the band received through an antenna and the transmissions in the band from the transmitter;(b) a plurality of analog time delay elements, each respective analog time delay element receiving an analog representation of the received first signal and applying a delay and a selectively controlled weighting, and together producing a combined analog signal;(c) a digitizer producing a digitized signal based on the combined analog signal; and(e) a processing subsystem, comprising at least one of a digital correlator and a processor configured to digitally compute a Fourier transform, configured to: selectively control a weighting of a combined output of the plurality of analog time delay elements, to achieve a second signal representing at least a partial cancellation of the interfering signals, while preserving the information; anddigitally cancel residual components of the interfering signals in the digitized signal; andan output port configured to communicate an output signal comprising the information. 19. The radio receiver according to claim 18, wherein the transmitter is co-located with the receiver. 20. The radio receiver according to claim 18, wherein the digitizer has a dynamic range insufficient to fully represent the information in the first signal, and has a dynamic range sufficient to represent the information in the combined analog signal.
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