Communication units and methods for power supply control

We claim: 1. A communication unit comprising: a decimator configured to sample a variable control signal and output a reduced bandwidth variable control signal; a multi-level power supply, MLPS, comprising an input and an output, wherein the input is coupled to the decimator and configured to receive the reduced bandwidth variable control signal and, in response thereto, the output delivers multi-level output voltages to supply a power amplifier, PA, module, a controller operably coupled to the decimator and configured to dynamically select and inform the decimator of at least one decimation factor to be applied by the decimator to adapt the sampling rate applied to the variable control signal, wherein the decimator is configured to dynamically adapt a sampling rate applied to the variable control signal to reduce a control signal bandwidth, a digital pre-distortion, DPD, circuit configured to receive and distort an input transmit signal, and output the distorted transmit signal; and an RF transmit circuit configured to amplify and up-convert the distorted transmit signal and apply the amplified, up-converted distorted transmit signal to the PA module; wherein the controller is operably coupled to and arranged to set power levels in the RF transmit circuit and DPD circuit and wherein a portion of the reduced bandwidth variable control signal output from the decimator is input to the DPD circuit such that the DPD circuit distorts the input transmit signal to compensate for PA non-linearity at least partly based on the reduced bandwidth variable control signal. 2. The communication unit of claim 1 wherein the MLPS is configured to select an output supply voltage for the PA module from a plurality of sets of available output voltages based at least partly on the reduced bandwidth variable control signal output from the decimator. 3. A communication unit comprising: a decimator configured to sample a variable control signal and output a reduced bandwidth variable control signal; and a multi-level power supply, MLPS, comprising an input and an output, wherein the input is coupled to the decimator and configured to receive the reduced bandwidth variable control signal and, in response thereto, the output delivers multi-level output voltages to supply a power amplifier, PA, module, wherein the decimator is configured to: sample the received variable control signal using at least one decimation factor, to thereby form a plurality of subsets of samples, and select a sample from the plurality of subsets of samples of a sample sequence as an output reduced bandwidth variable control signal; wherein a location of the selected sample from the sample sequence is not fixed and is dependent upon one or more other sample values within a decimated subset. 4. The communication unit of claim 3 wherein the decimator is configured to select a maximum sample value from each decimated subset as an output reduced bandwidth variable control signal. 5. The communication unit of claim 3 wherein the decimator is configured to output the reduced bandwidth variable control signal at a 1/DF rate of an input signal. 6. The communication unit of claim 3 wherein a decimation factor is selected based at least partly on an efficiency measurement of the communication unit. 7. The communication unit of claim 1 comprising an envelope detector configured to detect an envelope of a signal to be transmitted by the PA module and output a detected ET signal to the decimator as the variable control signal. 8. The communication unit of claim 7 further comprising a quantizer configured to apply quantization threshold values to the detected ET signal and output a quantized detected ET signal to the decimator. 9. A method for providing a power supply to a power amplifier, PA, module in a transmitter configured to convert digital signals into radio frequency, RF, signals, the method comprising: configuring multi-level output voltages in a multi-level power supply, MLPS, to be provided to the PA module; receiving a variable control signal; applying decimation using at least one decimation factor by sampling the received variable control signal and outputting a reduced bandwidth variable control signal in a form a plurality of subsets of samples; selecting a sample from the plurality of subsets of samples of a sample sequence as an output reduced bandwidth variable control signal; wherein a location of the selected sample from the sample sequence is not fixed and is dependent upon one or more other sample values within a decimated subset; receiving the decimated reduced bandwidth variable control signal at the MLPS, and, in response thereto, delivering multi-level output voltages by the MLPS to a supply of the PA module based on at least the decimated reduced bandwidth variable control signal. 10. A communication unit comprising: an adaptive quantizer comprising: an input configured to receive an input signal; a control input configured to receive quantization threshold adaptation information; a quantizer configured to adaptively change one or more quantization threshold values applied to the received input signal in response to the received quantization threshold adaptation information and generate a quantized variable control signal; and an output configured to output the quantized variable control signal; and a multi-level power supply, MLPS, comprising an input and an output, wherein the input is configured to receive the quantized variable control signal and, in response thereto, the output delivers multi-level output voltages to a supply of a PA module. 11. The communication unit of claim 10 wherein the MLPS is configured to select an output supply voltage to be applied to the PA module from a set of available multi-level output voltages based at least partly on the quantized variable control signal output from the adaptive quantizer. 12. The communication unit of claim 10 further comprising a transmit power control, TPC, circuit coupled to the MLPS and the adaptive quantizer and configured to select at least one quantization threshold level to be applied to the input signal based on a target PA output power. 13. The communication unit of claim 12 wherein the TPC circuit is configured to determine required levels of supply voltages to be applied to the PA module by the MLPS and send quantization threshold values to the adaptive quantizer for the adaptive quantizer to apply to the input signal. 14. The communication unit of claim 10 further comprising an envelope detector configured to detect an envelope of a signal to be transmitted by the PA module and output a detected ET signal as the input signal for the adaptive quantizer. 15. The communication unit of claim 14 wherein the adaptive quantizer is configured to quantize the detected ET signal to generate the quantized variable control signal according to a set of quantization threshold levels. 16. The communication unit of claim 10 further comprising a decimator coupled to the output of the adaptive quantizer and an input of the MLPS and configured to sample the quantized variable control signal and output a reduced bandwidth quantized variable control signal to the MLPS. 17. The communication unit of claim 10 further comprising: a digital pre-distortion, DPD, circuit configured to receive and distort an input transmit signal, and output the distorted transmit signal; and an RF transmit circuit configured to amplify and up-convert the distorted transmit signal and apply the amplified, up-converted distorted transmit signal to the PA module;