CATV video and data transmission system with automatic parameter control

The invention claimed is: 1. A head end transmitter for processing a signal for propagation down a fiber optical link in a transmission system, the transmitter comprising: an input for receiving a plurality of channels of cable television (CATV) content processed by a head end device; an output for emitting a digital bit stream into a network to at least one node over a fiber optic link, said digital bit stream representing an entire radio frequency (RF) spectrum of said plurality of channels of CATV content input to said head end transmitter by including a series of digital codewords, each digital codeword representing an instantaneous power level of the RF spectrum, the instantaneous power level representing a relative power level of a composite RF spectrum comprised of said plurality of channels of CATV content at intervals of a conversion clock, wherein said digital codewords are generated using the conversion clock without a corresponding RF waveform; a transmit subsystem operatively located between said input and said output, the transmit subsystem comprising: an analog-to-digital converter for digital conversion of the entire RF spectrum to the digital bit stream; a forward error correction encoder for forward error correction encoding of bits of the digital bit stream; at least one software routine which, when executed by the transmit subsystem, causes the transmit subsystem to: monitor performance attributes of the transmission system; evaluate one or more dependencies between the analog-to-digital converter and forward error correction module on the performance attributes of the transmission system to determine whether to adjust at least one digital parameter of at least one of the analog-to-digital converter or forward error correction module, wherein adjustment of said at least one digital parameter changes said performance attributes. 2. The transmitter of claim 1 where said forward error correction (FEC) encoder selectively modulates based on said performance attributes. 3. The transmitter of claim 2 where said performance attributes include at least one of pre-FEC bit-error ratio (BER), post-FEC BER, modulation error ratio (MER), signal to noise (SNR) ratio, and a transmission data rate. 4. The transmitter of claim 1 where at least one of the analog-to-digital converter (ADC) or a Direct Digital Synthesis (DDS) module included in the transmit subsystem selectively increases or decreases a bit depth used to encode said signal based on said performance attributes. 5. The transmitter of claim 4 where said performance attributes include at least one of pre-FEC (forward error correction) bit-error ratio (BER), post-FEC BER, modulation error ratio (MER), signal to noise (SNR) ratio, and a data rate. 6. The transmitter of claim 1 where said conversion clock has a rate that selectively increases or decreases based on said performance attributes. 7. The transmitter of claim 1 where said transmitter is capable of entering a power saving mode based on said performance attributes. 8. A method of configuring a head end transmitter, at a head end, that emits a cable television (CATV) signal into a transmission network to at least one node, said method comprising: receiving, at the head end transmitter, a plurality of channels of CATV content; emitting a digital bit stream from said head end transmitter into a network for transmission to at least one node over a fiber optic link, said digital bit stream representing an entire RF spectrum of said plurality of channels of CATV content received at said head end transmitter by including a series of digital codewords, each digital codeword representing an instantaneous power level of the RF spectrum, the instantaneous power level representing a relative power level of a composite RF spectrum comprised of said plurality of channels of CATV content at intervals of a conversion clock, wherein said digital codewords are generated using the conversion clock without a corresponding RF waveform; monitoring at least one first performance attribute of said digital bit stream; evaluating one or more dependencies between an analog-to-digital conversion and a forward error correction based on one or more digital parameters of an analog-to-digital converter or forward error correction module; and responsive to the monitored at least one first performance attribute of said digital bit stream and the one or more dependencies evaluated between the analog-to-digital converter and the forward error correction module, configuring said transmitter to improve at least one second performance attribute of said transmitter. 9. The method of claim 8 where said transmitter is automatically configured to selectively improve signal to noise ratio (SNR) based on monitoring at least one of a bit depth, pre-FEC (forward error correction) bit error rate (BER), and post-FEC BER. 10. The method of claim 8 where said transmitter is automatically configured to reduce post-FEC (forward error correction) bit error rate (BER). 11. The method of claim 8 where said transmitter is automatically configured to selectively improve bit depth based on a pre-FEC (forward error correction) bit error rate (BER). 12. The method of claim 8 where said transmitter is automatically configured to selectively adjust sampling clock based on at least one of pre-FEC(forward error correction) bit error rate (BER), and post-FEC BER. 13. The method of claim 8 where said transmitter is automatically adjusted to selectively increase bit rate to at least 1024 Quadrature Amplitude Modulation (QAM) based on the monitored said at least one performance attribute. 14. The method of claim 8 where said transmitter is automatically adjusted to selectively increase bit rate to at least 4096 Quadrature Amplitude Modulation (QAM) based on the monitored said at least one performance attribute. 15. A method of configuring a transmitter, at a head end, that emits a cable television (CATV) signal into a transmission network to at least one node, said method comprising: receiving an entire radio frequency (RF) spectrum including a plurality of channels of CATV content; emitting a digital bit stream into a network to at least one node over a fiber optic link, said digital bit stream representing a digitization of the entire RF spectrum of said CATV content received at said head end transmitter by including a series of digital codewords, each digital codeword representing an instantaneous power level of the RF spectrum, the instantaneous power level representing a relative power level of a composite RF spectrum comprised of said plurality of channels of CATV content at intervals of a conversion clock, wherein said digital codewords are generated using the conversion clock without a corresponding RF waveform; monitoring at least one first performance attribute of said digital bit stream; evaluating one or more dependencies between an analog-to-digital conversion and a forward error correction based on one or more digital parameters of an analog-to-digital converter or forward error correction module; and responsive to the monitored at least one performance attribute of said digital bit stream and the one or more dependencies evaluated between the analog-to-digital converter and the forward error correction module, selectively modulating a data rate of said digital bit stream over a full range of 256 Quadrature Amplitude Modulation (QAM) to 1024 QAM. 16. The method of claim 15 where said data rate is modulated over the full range of 256 QAM to 4096 QAM. 17. The method of claim 15 where said