Methods and systems of specifying coaxial resource allocation across a MAC/PHY interface

What is claimed is: 1. A communication device, comprising: a multi-point media access controller (MAC) controller to allocate coax resources for signals to be transmitted over a cable plant; a coax physical layer device (PHY) to transmit the signals over the cable plant using the allocated coax resources; and a MAC, coupled to the multi-point MAC controller and the coax PHY, to provide a bitstream comprising data for the signals and information specifying the allocated coax resources to the coax PHY, the bitstream further comprising data frames to convey the data for the signals and idle character sequences between the data frames, wherein times between successive data frames in the bitstream specify the allocated coax resources; wherein: a respective data frame in the bitstream is followed by a respective idle character sequence; and the coax PHY is to map the respective data frame to an amount of coax resources determined by a ratio of a sum of durations of the respective data frame and the respective idle character sequence to a predefined symbol duration. 2. The communication device of claim 1 , further comprising an interface, coupled to the MAC and the coax PHY, to convey the bitstream to the coax PHY at a fixed rate. 3. The communication device of claim 1 , wherein the bitstream comprises: data frames to convey the data for the signals; and control frames to convey the information specifying the allocated coax resources. 4. The communication device of claim 3 , wherein the control frames further specify modulation and coding schemes that the coax PHY is to use to generate the signals. 5. The communication device of claim 3 , wherein: respective groups of the data frames correspond to respective orthogonal frequency-division multiplexing (OFDM) symbols; and respective control frames correspond to respective OFDM symbols and specify the allocated coax resources for the respective groups of the data frames. 6. The communication device of claim 3 , wherein: the coax PHY is to transmit the signals downstream to a plurality of coax network units on the cable plant; the control frames are downstream control frames; and the bitstream further comprises upstream control frames to specify coax resources allocated for upstream transmissions from the plurality of coax network units. 7. The communication device of claim 6 , wherein the upstream control frames further specify modulation and coding schemes for the plurality of coax network units to use for the upstream transmissions. 8. The communication device of claim 1 , wherein: a respective data frame in the bitstream is followed by a respective idle character sequence with a duration greater than or equal to a predefined inter-frame gap; and the coax PHY is to select a modulation and coding scheme for the respective data frame based on a ratio of a sum of durations of the respective data frame and the predefined inter-frame gap to a sum of durations of the respective data frame and the respective idle character sequence. 9. The communication device of claim 1 , wherein: the bitstream is divided into time slices; respective time slices comprise respective data frames to convey the data for the signals; respective time slices correspond to respective coax resources; and the coax PHY is to map the respective data frames in the respective time slices to the respective coax resources. 10. The communication device of claim 9 , wherein the coax PHY is to select modulation and coding schemes for the respective data frames based on positions of the respective data frames in the respective time slices. 11. The communication device of claim 1 , wherein the coax resources comprise blocks of contiguous subcarriers for OFDM symbols. 12. The communication device of claim 1 , wherein the coax resources comprise logical channels. 13. A signal generation method in a communication device, comprising: allocating coax resources for signals to be transmitted over a cable plant; generating a bitstream comprising data for the signals and information specifying the allocated coax resources, the bitstream further comprising data frames to convey the data for the signals and idle character sequences between the data frames, wherein times between successive data frames in the bitstream specify the allocated coax resources; generating the signals based on the bitstream by mapping the data frames to coax resources based on the times between successive data frames in the bitstream; and transmitting the signals over the cable plant using the allocated coax resources; wherein: a respective data frame in the bitstream is followed by a respective idle character sequence; and an amount of coax resources for the respective data frame is determined based on a ratio of a sum of durations of the respective data frame and the respective idle character sequence to a predefined symbol duration. 14. The signal generation method of claim 13 , wherein the bitstream comprises: data frames to convey the data for the signals; and control frames to convey the information specifying the allocated coax resources. 15. The signal generation method of claim 14 , wherein: the control frames further specify modulation and coding schemes; and generating the signals comprises modulating and encoding the data for the signals in accordance with the specified modulation and coding schemes. 16. The signal generation method of claim 14 , wherein: respective groups of the data frames correspond to respective OFDM symbols; and respective control frames correspond to respective OFDM symbols and specify the allocated coax resources for the respective groups of the data frames. 17. The signal generation method of claim 14 , wherein: transmitting the signals comprises sending the signals downstream to a plurality of coax network units on the cable plant; the control frames are downstream control frames; and the bitstream further comprises upstream control frames to specify coax resources allocated for upstream transmissions from the plurality of coax network units. 18. The signal generation method of claim 17 , wherein the upstream control frames further specify modulation and coding schemes for the plurality of coax network units to use for the upstream transmissions, the method further comprising: receiving the upstream transmissions on the coax resources specified by the upstream control frames; and demodulating and decoding the upstream transmissions in accordance with the modulation and coding schemes specified by the upstream control frames. 19. The signal generation method of claim 13 , wherein: a respective data frame in the bitstream is followed by a respective idle character sequence with a duration greater than or equal to a predefined inter-frame gap; and generating the signals comprises selecting a modulation and coding scheme for the respective data frame based on a ratio of a sum of durations of the respective data frame and the predefined inter-frame gap to a sum of durations of the respective data frame and the respective idle character sequence. 20. The signal generation method of claim 13 , wherein: the bitstream is divided into time slices; respective time slices comprise respective data frames to convey the data for the signals; respective time slices correspond to respective coax resources; and generating the signals comprises mapping the respective data frames in the respective time slices to the respective coax resources. 21