Discrete time filter, communication unit, and method for resonant charge transfer

I claim: 1. A discrete time filter, DTF, for effecting a resonant charge transfer, the DTF comprising: a summing node; N parallel branches, each branch having a set of input unit sampling capacitances where each input unit sampling capacitance is independently selectively coupleable to the summing node; and an output capacitance connected to the summing node such that a resonant charge transfer is effected; wherein the output capacitance has a value equal to a sum of the sampling capacitances that are to be selectively connected to the summing node; and the discrete time filter further comprises a series inductance connected between the summing node and the output capacitance. 2. The discrete time filter of claim 1 , wherein the series inductance, in combination with the output capacitance and the input unit sampling capacitances located at either side of the series inductance are configured to effect resonance at a frequency to facilitate a resonant charge transfer. 3. The discrete time filter of claim 2 , wherein each input unit sampling capacitance is independently selectively coupleable to the summing node via a respective output switch, wherein the resonance frequency of an output resonant circuit that comprises the set of input unit sampling capacitances coupled to the output capacitance via the inductance, is based on a time interval τ during which the output switches are closed. 4. The discrete time filter of claim 2 , wherein the resonant charge transfer comprises all of the charge being transferred from the respective set of input unit sampling capacitances to the output capacitance, C out . 5. The discrete time filter of claim 1 , wherein the output capacitance, C out , is equal to a total capacitance of the set of unit sampling capacitances that are individually and selectively connected to an output node of the DTF at an instant in time. 6. The discrete time filter of claim 1 , wherein each input unit sampling capacitance of each of the N parallel branches, is coupled to an input switch, a reset switch and an output switch, and the output capacitance, C out , is coupled to an output capacitor reset switch. 7. The discrete time filter of claim 6 , wherein the series inductance, in combination with the output capacitance and the input unit sampling capacitances located at either side the series inductance are configured to effect a resonant charge transfer during a period of time between a rising clock event whereby the sampling capacitances of a number of selected N parallel branch are coupled to the output capacitance and a falling clock event that disconnects the sampling capacitances of the number of selected N parallel branch from the output capacitance. 8. The discrete time filter of claim 6 , further comprising a controller coupled to each switch and configured to effect a switch close time of the output switches that is one half of a period of a resulting resonant charge transfer. 9. The discrete time filter of claim 1 , wherein the set of input unit sampling capacitances, C s , is configured to form a decimate-by-2 finite impulse response, FIR, DTF. 10. The discrete time filter of claim 1 wherein the set of input unit sampling capacitances, C s , is configured to form a cascade-by N decimate-by-N cascaded integrator-comb (CIC) finite impulse response, FIR, DTF. 11. The discrete time filter of claim 10 wherein the series inductance in the CIC FIR DTF is used to build a filter where weighting coefficients of a z-Transform representative of the CIC FIR DTF are not all equal. 12. A wireless communication unit comprising a discrete time filter, DTF, for effecting a resonant charge transfer, the DTF comprising: a summing node; N parallel branches, each branch having a set of input unit sampling capacitances where each unit sampling capacitance is independently selectively coupleable to the summing node; and an output capacitance connected to the summing node such that a resonant charge transfer is effected; wherein the output capacitance has a value equal to a sum of the sampling capacitances that are to be selectively connected to the summing node; and the discrete time filter further comprises a series inductance connected between the summing node and the output capacitance. 13. The wireless communication unit of claim 12 , wherein the series inductance in combination with the output capacitance and the input unit sampling capacitances located at either side of the series inductance are configured to effect resonance at a frequency to facilitate a resonant charge transfer. 14. The wireless communication unit of claim 13 , wherein each input unit sampling capacitance is independently selectively coupleable to the summing node via a respective output switch, wherein the resonance frequency of an output resonant circuit that comprises the set of input unit sampling capacitances coupled to the output capacitance via the inductance, is based on a time interval, τ, during which the output switches are closed. 15. The wireless communication unit of claim 13 , wherein the resonant charge transfer comprises all of the charge being transferred from the respective set of input unit sampling capacitances to the output capacitance, C out . 16. A method of effecting a resonant charge transfer in a discrete time filter comprising a summing node and N parallel branches, each branch having a set of input unit sampling capacitances and an output capacitance connected to the summing node; the method comprising: independently selectively coupling a plurality of unit sampling capacitances to the summing node, which is connected to an output capacitance via an inductance, wherein the output capacitance has a value equal to a sum of the sampling capacitances that are selectively coupled to the summing node; and effecting a resonant charge transfer from the selected plurality of unit sampling capacitances to the output capacitance. 17. The method of claim 16 , wherein the output capacitance, inductance, and sampling capacitances that are selectively coupled to the inductance form an output resonant circuit where the resonant frequency is based on a time interval, τ, during which output switches of the DFT coupling the plurality of unit sampling capacitances to the output capacitance are closed. 18. The method of claim 17 , wherein the time interval, τ, corresponds to half a resonance period of the output resonant circuit formed by the inductor and the capacitors connected to it. 19. The method of claim 16 , wherein effecting a resonant charge transfer from the selected plurality of unit sampling capacitances to the output capacitance comprises the resonant charge transfer transferring all of the charge from the respective set of input unit sampling capacitances to the output capacitance. 20. The method of claim 16 , wherein the output capacitance, C out , is equal to a total capacitance of the set of unit sampling capacitances that are individually and selectively connected to an output node of the DTF at an instant in time.