Receiver, communication unit, and method for down-converting a radio frequency signal

I claim: 1. A radio frequency, RF, communication receiver comprising: an input for receiving a RF input signal; and at least one finite impulse response, FIR, discrete time filter, DTF, that comprises: an input circuit comprising an input shunt reactive component and an input port for sampling the RF input signal at a sampling frequency that is comparable to the RF input signal; and N parallel branches, each branch having a set of input unit sampling capacitances, where each unit sampling capacitance is independently selectively coupleable to an output summing node; and wherein the input circuit of the at least one FIR DTF is a first stage of the communication receiver and configured to convert an equivalent input impedance of the at least one FIR DTF around the sampling frequency to a real impedance and a combination of the input shunt reactive component and the sampling capacitances of each of the N parallel branches forms a filter that concurrently limits a bandwidth of the input circuit. 2. The communication receiver of claim 1 , wherein the at least one FIR DTF is configured to directly perform down conversion of the RF input signal. 3. The communication receiver of claim 1 , wherein the input shunt reactive component is a parallel input shunt inductance configured to resonate a reactive part of the equivalent input impedance around the sampling frequency. 4. The communication receiver of claim 1 , wherein the input circuit comprises a network of radio frequency components configured to resonate a reactive part of the equivalent input impedance around the sampling frequency. 5. The communication receiver of claim 1 , wherein the sampling capacitances of each of the N parallel branches, are linear passive capacitors such that the input signal is sampled across multiple linear passive capacitors. 6. The communication receiver of claim 1 , wherein the sampling capacitances of each of the N parallel branches are non-linear Metal-Oxide-Semiconductor, MOS, capacitors. 7. The communication receiver of claim 1 , wherein the at least one FIR DTF comprises multiple FIR DTFs connected in parallel each one with their respective input port connected to receive the same RF input signal. 8. The communication receiver of claim 7 , wherein the multiple FIR DTFs are configured to filter samples of the same RF input signal at the same sampling frequency, but at interleaved time instants. 9. The communication receiver of claim 8 , wherein the multiple FIR DTFs comprise two FIR DTFs configured to act on quadrature representations of the RF input signal. 10. A radio frequency, RF, communication unit comprising a receiver having: an input for receiving a RF input signal; and at least one finite impulse response, FIR, discrete time filter, DTF, that comprises: an input circuit comprising an input shunt reactive component and an input port for sampling the RF input signal at a sampling frequency that is comparable to the RF input signal; and N parallel branches, each branch having a set of input unit sampling capacitances, where each unit sampling capacitance is independently selectively coupleable to an output summing node; wherein the input circuit of the at least one FIR DTF is a first stage of the receiver and configured to convert an equivalent input impedance of the at least one FIR DTF around the sampling frequency to a real impedance and a combination of the input shunt reactive component and the sampling capacitances of each of the N parallel branches forms a filter that concurrently limits a bandwidth of the input circuit. 11. The communication unit of claim 10 , wherein the at least one FIR DTF is configured to directly perform down conversion of the input RF signal. 12. The communication unit of claim 10 , wherein the input shunt reactive component is a parallel input shunt inductance configured to resonate a reactive part of the equivalent input impedance around the sampling frequency. 13. The communication unit of claim 10 , wherein the input circuit comprises a network of radio frequency components configured to resonate a reactive part of the equivalent input impedance around the sampling frequency. 14. The communication unit of claim 10 , wherein the sampling capacitances of each of the N parallel branches, are at least one from a group of: linear passive capacitors such that the input signal is sampled across multiple linear passive capacitors, non-linear Metal-Oxide-Semiconductor, MOS, capacitors. 15. The communication unit of claim 10 , wherein the at least one FIR DTF comprises multiple FIR DTFs connected in parallel each one with their respective input port connected to receive the same RF input signal. 16. The communication unit of claim 15 , wherein the multiple FIR DTFs are configured to filter samples of the same RF input signal at the same sampling frequency, but at interleaved time instants. 17. The communication unit of claim 16 , wherein the multiple FIR DTFs comprise two FIR DTFs configured to act on quadrature representations of the RF input signal. 18. A method of down conversion of a radio frequency signal in a radio frequency, RF, communication receiver comprising at least one finite impulse response, FIR, discrete time filter, DTF that comprises an input coupled to N parallel branches, each branch having a set of input unit sampling capacitances, the method comprising: receiving a RF input signal; converting an equivalent input impedance of the at least one FIR DTF around a sampling frequency to a real impedance; sampling, at the input of the at least one FIR DTF, configured as a first stage of the communication receiver comprising an input shunt reactive component as part of an input circuit, the RF input signal at the sampling frequency, wherein the sampling frequency is comparable to the RF input signal; and independently selectively coupling a set of unit sampling capacitances to an output summing node of the at least one FIR DTF to provide a frequency down-converted signal, such that a combination of the input shunt reactive component and the set of input unit sampling capacitances forms a filter that concurrently limits a bandwidth of the input circuit. 19. The method of claim 18 further comprising performing down conversion of the input RF signal directly by the at least one FIR DTF. 20. The method of claim 18 further comprising resonating a reactive part of the equivalent input impedance around the sampling frequency.