Feedback control systems for wireless devices

What is claimed: 1. An apparatus for a mobile communication device adapted for digital pre-distortion (DPD), the apparatus comprising: a memory; a processor operatively coupled to the memory the processor to: receive a first input signal; receive a first output signal from a power amplifier (PA) based on the first input signal; vary compression applied to a second input signal, prior to DPD, based on the first output signal of the PA; generate a distortion compensation vector for the second input signal based on the first output signal of the PA; and vary an input excitation signal supplied to the PA to vary compression of the PA based on the first output signal of the PA, wherein the processor is configured to coordinate the variation of the compression applied to the second input signal with the variation of the compression of the PA based at least in part on an Adjacent Channel Leakage Ratio (ACLR). 2. The apparatus according to claim 1 , wherein the processor is configured to: receive the first input signal at a crest factor reduction system; and compress the first input signal within the crest factor reduction system to reduce a peak-to-average ratio (PAR) of the first input signal. 3. The apparatus according to claim 2 , wherein the processor is configured to: update the distortion compensation vector based on the first output signal; and modify the first input signal compressed within the crest factor reduction system based on the updated distortion compensation vector. 4. The apparatus according to claim 3 , wherein updating the distortion compensation vector comprises: scaling a sequence of input samples to generate a sequence of output samples for input to the PA; and generating the distortion compensation vector based on vector outputs of predetermined distortion compensation functions; wherein a sample of the input samples is based on the first input signal. 5. The apparatus according to claim 4 , wherein the processor is configured to: generate per-sample scale factors to scale the sequence of input samples, the per-sample scale factors based on per-sample inner products between a common weight vector and the per-sample distortion compensation vectors, the per-sample scale factors to compensate for distortion of the PA; and update the common weight vector based on a distortion error sequence between the sequence of output samples and a sequence of feedback samples generated from the first output signal of the PA. 6. The apparatus according to claim 1 , wherein the input excitation signal supplied to the PA is one of voltage or biasing current. 7. An apparatus for a mobile communication device adapted for digital pre-distortion (DPD), the apparatus comprising: a memory; a processor operatively coupled to the memory the processor to: receive a first input signal; receive a first output signal from a power amplifier (PA) based on the first input signal; vary compression applied to a second input signal based on the first output signal of the PA; generate a distortion compensation vector for the second input signal based on the first output signal of the PA; and vary an input excitation signal supplied to the PA based on the first output signal of the PA, wherein the processor is configured to: receive the first input signal at a crest factor reduction system; and compress the first input signal within the crest factor reduction system to reduce a peak-to-average ratio (PAR) of the first input signal, and wherein the crest factor reduction system includes at least a first crest factor reduction subsystem and a second crest factor reduction subsystem, and wherein the first input signal is separated into at least a first input signal component and a second input signal component such that the first input signal component is received by the first crest factor reduction subsystem and the second input signal component is received by the second crest factor subsystem. 8. The apparatus according to claim 7 , wherein the first and second crest factor subsystems each includes an error detection system, the error detection system comprising: a comparator configured to compare the first input signal with a compressed signal to generate an error signal indicating distortion between the first input signal and the compressed signal; an in-band filter configured to filter the error signal based on an in-band frequency range to generate an in-band error signal indicating in-band distortion of the compressed signal with respect to the first input signal from which the compressed signal is generated; an out-of-band filter configured to filter the error signal based on an out-of-band frequency range to generate an out-of-band error signal indicating out-of-band distortion of the compressed signal with respect to the first input signal; an in-band gain circuit configured to apply an in-band gain to the in-band error signal to generate an adjusted in-band error signal; an out-of-band gain circuit configured to apply an out-of-band gain to the out-of-band error signal to generate an adjusted out-of-band error signal; and a combining system configured to combine the compressed signal with the adjusted in-band error signal and the adjusted out-of-band error signal to generate an output signal, the combining system configured to combine the compressed signal with the adjusted in-band error signal and the adjusted out-of-band error signal, the in-band gain circuit configured to apply the in-band gain based on the output signal, and the out-of-band gain circuit configured to apply the out-of-band gain based on the output signal such that distortion of the output signal is reduced with respect to distortion of the compressed signal. 9. The apparatus according to claim 8 , wherein the crest factor reduction system further comprises a shared adaptation system configured to receive the output signal of each of the first and second crest factor subsystems and determine out-of-band distortion of each output signal. 10. The apparatus according to claim 9 , wherein the shared adaptation system is configured to determine in-band distortion of the output signal of each of the first and second crest factor subsystems based on transmitted spectral mask of the output signal of each of the first and second crest factor subsystems with respect to the first input signal, and configured to adjust the in-band gain, the out-of-band gain, or both the in-band gain and the out-of-band gain based on the transmitted spectral mask. 11. The apparatus according to claim 10 , wherein the shared adaptation system is configured to determine in-band distortion of the output signal of each of the first and second crest factor subsystems based on an error vector magnitude (EVM) of the output signal of each of the first and second crest factor subsystems with respect to the first input signal and configured to adjust the in-band gain, the out-of-band gain, or both the in-band gain and the out-of-band gain based on the EVM and transmitted spectral mask. 12. The apparatus according to claim 11 , further comprising the shared adaptation circuitry configured to determine out-of-band distortion of the output signal of each of the first and second crest factor subsystems based on an adjacent channel leakage ratio (ACLR) of the output signal of each of the first and second crest factor subsystems and configured to adjust the in-band gain, the out-of-band gain, or both the in-band gain and the out-of-band gain based on the ACLR, EVM, and transmitted spectral mask. 13. The apparatus according to claim 9 , wherein the crest factor reduction system further comprises a multiplex