Wireless communication unit, modulation circuit and method for frequency-dependent adjustment thereof

The invention claimed is: 1. A communication unit comprising: at least one antenna; a plurality of radio frequency (RF) circuits respectively coupled to the at least one antenna; at least one sigma-delta modulator comprising a number of stages, each stage comprising at least one signal-feedforward coefficient, a filter and a feedback gain element, the at least one sigma-delta modulator coupled to the plurality of RF circuits and configured to perform sigma-delta modulation; and a controller operably coupled to the at least one sigma-delta modulator; wherein the at least one sigma-delta modulator comprises an input configured to receive multiple multi-phase input signals and the controller is configured to adjust the at least one signal-feedforward coefficient of the at least one sigma-delta modulator when combining the multiple multi-phase input signals. 2. The communication unit of claim 1 wherein each of the at least one signal-feedforward coefficients in at least one stage of the at least one sigma-delta modulator is individually adjustable by the controller. 3. The communication unit of claim 1 wherein the at least one antenna is a plurality of antennas and the controller is configured to identify beam steering parameters of wireless signals received by or transmitted from the plurality of antennas and in response thereto adjust the at least one signal-feedforward coefficient of the at least one sigma-delta modulator to effect a beam steered signal. 4. The communication unit of claim 3 wherein at least one signal-feedforward coefficient in at least one stage of the at least one sigma-delta modulator is adjusted by the controller to reduce a level of at least one interference signal. 5. The communication unit of claim 4 wherein the controller is configured to identify a signal level and frequency of the at least one interference signal and in response thereto adjust the at least one signal-feedforward coefficient of the at least one sigma-delta modulator to effect a beam-formed signal. 6. The communication unit of claim 4 wherein the controller is configured to perform an angle of arrival estimation calculation between respective antenna array elements of a phased antenna array and in response thereto adjust the at least one signal-feedforward coefficient of the at least one sigma-delta modulator to assist beam steering of the phased antenna array. 7. The communication unit of claim 1 wherein the input configured to receive multiple multi-phase input signals comprises a quadrature input, and the controller is configured to identify image signals of the quadrature input and in response thereto adjust the at least one signal-feedforward coefficient of the at least one sigma-delta modulator ( 816 ) to effect image signal reduction. 8. The communication unit of claim 1 wherein the respective antennas coupled to the plurality of transceiver circuits are configured to operate as a phased antenna array. 9. The communication unit of claim 1 wherein the at least one sigma-delta modulator is constructed as one from a group of: a feedforward type, a feedback type, a 1-bit modulation type, a multi-bit modulation type, a MASH modulator, discrete-time type modulator, a continuous-time modulator. 10. A sigma-delta modulator comprising: a number of stages, each stage comprising at least one signal-feedforward coefficient, a filter and a feedback gain element, where the at least one sigma-delta modulator is coupled to a controller and at least one antenna via a plurality of RF circuits and configured to perform sigma-delta modulation; wherein the at least one sigma-delta modulator comprises an input configured to receive multiple multi-phase input signals and the controller is configured to adjust the at least one signal-feedforward coefficient of the at least one sigma-delta modulator when combining the multiple multi-phase input signals. 11. The sigma-delta modulator of claim 10 , wherein each of the at least one signal-feedforward coefficients in at least one stage of the at least one sigma-delta modulator is individually adjustable by the controller. 12. The sigma-delta modulator of claim 10 , wherein the at least one antenna is a plurality of antennas and the controller is configured to identify beam steering parameters of wireless signals received by or transmitted from the plurality of antennas, and in response thereto, adjust the at least one signal-feedforward coefficient of the at least one sigma-delta modulator to effect a beam steered signal. 13. The sigma-delta modulator of claim 12 , wherein at least one signal-feedforward coefficient in at least one stage of the at least one sigma-delta modulator is adjusted by the controller to reduce a level of at least one interference signal. 14. The sigma-delta modulator of claim 10 , wherein the input configured to receive multiple multi-phase input signals comprises a quadrature input, and the controller is configured to identify image signals of the quadrature input, and in response thereto, adjust the at least one signal-feedforward coefficient of the at least one sigma-delta modulator to effect image signal reduction. 15. A method for frequency-dependent adjustment of at least one of: gain, phase in a communication unit that comprises at least one antenna coupled to a plurality of radio frequency, RF, circuits and at least one sigma-delta modulator that comprises a number of stages, each stage comprising at least one signal-feedforward coefficient, a filter and a feedback gain element, wherein the method comprises: receiving or transmitting at least one signal via the at least one antenna; and performing sigma-delta modulation by the at least one sigma-delta modulator; receiving multiple multi-phase input signals by the at least one sigma-delta modulator; identifying from the multiple multi-phase input signals at least one of: a wanted signal, an interference signal; and adjusting the at least one signal-feedforward coefficient of the at least one sigma-delta modulator when combining the multiple multi-phase input signals. 16. The method of claim 15 wherein the at least one antenna is a plurality of antennas and the method further comprises: identifying beam steering parameters of wireless signals received by or transmitted from the plurality of antennas; and in response thereto adjusting the at least one signal-feedforward coefficient of the at least one sigma-delta modulator to effect a beam steered signal. 17. The method of claim 15 wherein receiving multiple multi-phase input signals by the at least one sigma-delta modulator comprises receiving at least one quadrature input signal; wherein the method further comprises: identifying at least one image signal of the quadrature input and, in response thereto adjusting the at least one signal-feedforward coefficient of the at least one sigma-delta modulator to effect image signal reduction. 18. The method of claim 15 , further comprising adjusting the at least one signal-feedforward coefficient of the at least one sigma-delta modulator to reduce a level of at least one interference signal. 19. The method of claim 18 , further comprising: identifying a signal level and frequency of the at least one interference signal; and adjusting the at least one signal-feedforward coefficient of the at least one sigma-delta modulator to affect a beam-formed signal. 20. The method of claim 18 , further comprising: performing an angle of arrival estimation calculation between respective antenna arr