Signal compression for serialized signal bandwidth reduction

The invention claimed is: 1. A communications link, including a transmit end and a receive end, comprising: at the transmit end, a transmit interface including: a data input to receive an input data signal with at least first and second signal components with respectively a higher and a lower signal to quantization noise ratio (SQNR) requirement or dynamic range requirement; compression logic including: decomposition logic to decompose the input data signal into the first and second signal components, quantization logic to quantize the first signal component with a defined first bit precision to provide a first quantized data signal, and to quantize the second signal component with a defined second bit precision to provide a second quantized data signal, the second bit precision less than the first bit precision, and bit-packing logic to assemble the first and second quantized data signals into a compressed digital data signal; at the receive end, a receive interface including: a communication input to receive the compressed digital data signal; decompression logic including: bit unpacking logic to separate the compressed digital data signal into the first and second quantized data signals; and combining filter logic to combine the first and second quantized data signals into a decompressed data signal corresponding to the input data signal including the first and second signal components. 2. The link of claim 1 , wherein: the compression logic further includes gain logic to apply a first gain to the first signal component, and a second gain to the second signal component, where the second gain is greater than the first gain; and the decompression logic further includes scaling logic to apply to the first quantized data signal a first inverse gain corresponding to an inverse of the first gain, and to apply to the second quantized data signal a second inverse gain corresponding to an inverse of the second gain. 3. The link of claim 1 , wherein: the compression logic further include format conversion logic to convert the first and second signal components from a first format to a second format; the decompression logic further includes format reconversion logic to convert the first and second quantized data signals from the second format to the first format. 4. The link of claim 3 , the second format is one of: a floating point format, or a polar format. 5. The link of claim 1 , wherein: the decomposition logic includes down-sampling the first and second signal components; and the combining filter logic includes up-sampling the first and second quantized data signals. 6. The link of claim 5 , wherein: the decomposition logic includes one of low pass filter logic or half-band filter logic; and the combining filter logic includes one of low pass filter logic or half-band filter logic. 7. The link of claim 1 , wherein the communications link is for radio frequency communications, and wherein the input data signal is a baseband digital data signal, and wherein: the first signal component is a transmit (TX) inband signal component; and the second signal component is a digital pre-distortion (DPD) signal component based on digital pre-distortion of the TX inband signal component. 8. The link of claim 1 , wherein the communications link is for radio frequency communications, and wherein: the transmit interface is included in a digital baseband transmitter: the digital baseband transmitter to generate the input data signal as an input baseband data signal, and the compression logic to generate a compressed baseband digital data signal; the receive interface is included in a front-end unit coupled to a radio frequency transmitter: the decompression logic to convert the compressed baseband digital data signal to a decompressed baseband digital data signal, for input to the radio frequency transmitter, the front-end unit including radio frequency conversion circuitry to convert the decompressed baseband digital data signal to an analog radio frequency signal, and the radio frequency transmitter to receive the analog radio frequency signal for transmission as a radio frequency wireless transmission; wherein the front-end unit and the radio frequency transmitter are configured as one of: (a) separate analog front-end integrated circuitry, and radio frequency transmitter integrated circuitry, or (b) a radio frequency transmitter integrated circuit including the front-end unit as an analog front end to the radio frequency transmitter. 9. The link of claim 1 , wherein the communications link communicates the compressed digital data signal as a serial compressed digital data signal. 10. An analog front end (AFE) for use in a radio frequency communications system including a digital baseband transmitter interfaced at a transmit end to a communications link, the transmitter to generate a compressed baseband digital data signal, the AFE comprising: a receive interface including an input communication port to interface at a receive end to the communications link; the receive interface configured to receive through the input communication port the compressed baseband digital data signal generated by the transmitter and communicated over the communications link; the compressed baseband digital data signal generated from a baseband discrete data signal that includes a transmit (TX) inband signal component, and a digital pre-distortion (DPD) signal component based on digital pre-distortion of the TX inband signal component, the TX inband signal component quantized with a defined first bit precision to provide a TX quantized data signal, and the DPD signal component quantized with a defined second bit precision to provide the DPD quantized data signal, the second bit precision less than the first bit precision, and the compressed baseband digital data signal generated with the TX inband and DPD quantized data signals; decompression logic including bit unpacking logic to separate the compressed baseband digital data signal into the TX inband and DPD quantized data signals; combining filter logic to filter the TX inband and DPD quantized data signals into TX inband and DPD filtered data signals, combined into a decompressed baseband digital data signal corresponding to the baseband digital data signal including the TX inband and DPD signal components; and radio frequency conversion circuitry to convert the decompressed baseband digital data signal to an analog radio frequency signal corresponding to the baseband discrete data signal including the TX inband and DPD signal components. 11. The AFE of claim 10 , wherein the compressed baseband digital data signal is generated with a first gain applied to the TX inband signal component, and a second gain applied to the DPD signal component, where the second gain is greater than the first gain, the decompression logic further including: scaling logic to apply to the TX quantized data signal a first inverse gain corresponding to an inverse of the first gain, and to apply to the DPD quantized data signal a second inverse gain corresponding to an inverse of the second gain. 12. The AFE of claim 10 , wherein the compressed baseband digital data signal is generated with conversion of the TX inband and DPD signal components from a first format to a second format, the decompression logic further including: format reconversion logic to convert the TX inband and DPD quantized data signals from the second format to the first format wherein the second format is one of: a floating point format, or a polar format. 13. The AFE of claim 10 , wherein the compressed baseband digital data s