Use of vectoring and time- and/or frequency—division multiple access in a multi-user connection

What is claimed is: 1. An apparatus comprising a data transmitter that comprises an analog front end connectable to proximal ends of a plurality of subscriber lines and a digital signal processor configured to process digital samples corresponding to a plurality of distinct groups of output signals and to drive the analog front end to cause the plurality of distinct groups of output signals to be transmitted on the subscriber lines using frequency-division multiplexing, with each of the distinct groups of the output signals being transmitted on a corresponding distinct group of the subscriber lines, at least one of the distinct groups of the subscriber lines including at least two of the subscriber lines; wherein the digital signal processor comprises a vector processor configured to precode the digital samples in a manner that causes effects of crosstalk between the distinct groups of the subscriber lines to be substantially mitigated at distal ends of the plurality of subscriber lines; wherein the vector processor is further configured to precode the digital samples in a manner that causes each of the distinct groups of the output signals to convey a different respective data block to the distal ends of the corresponding distinct group of the subscriber lines, said different respective data block being conveyed to each of the distal ends of the corresponding distinct group of the subscriber lines; and wherein the apparatus further comprises a scheduler configured to control flows of data through the digital signal processor such that, during a given symbol period, a given resource block of any of the distinct groups of the output signals carries data corresponding to a single respective subscriber. 2. The apparatus of claim 1 , wherein the vector processor is configured to precode the output signals using a fixed precoder matrix during two or more symbol periods during which a tone is allocated to different respective subscribers. 3. The apparatus of claim 1 , wherein the vector processor has G inputs and N outputs, where the number G is the number of the distinct groups, and the number N is the number of the subscriber lines, the number N being greater than the number G, the number G being greater than one; wherein each of the N outputs is connected to a respective one of the subscriber lines; and wherein the G inputs are connected to N different data sources. 4. The apparatus of claim 3 , wherein the digital signal processor further comprises G multiplexers, each connected to transmit data to a respective one of the G inputs in response to data received from a respective subset of the N different data sources. 5. The apparatus of claim 3 , wherein the vector processor is configured to precode the output signals using a N×G precoder matrix; and wherein the data transmitter is configured to compute the N×G precoder matrix in response to measurements of an N×N downlink channel matrix corresponding to the N subscriber lines. 6. The apparatus of claim 1 , wherein the scheduler is configured to control said flows of data using one or both of time-division multiple access and frequency-division multiple access. 7. The apparatus of claim 1 , wherein the vector processor is configured to precode the output signals using a precoder matrix that is fixed during two or more different time or frequency allocation patterns implemented using the scheduler. 8. The apparatus of claim 1 , wherein the digital signal processor further comprises a plurality of encapsulation modules, a plurality of framers, a plurality of symbol encoders, and a plurality of modulators connected to the vector processor. 9. The apparatus of claim 8 , wherein the digital signal processor further comprises a multiplexer configured to multiplex outputs of at least two of the encapsulation modules. 10. The apparatus of claim 8 , wherein the digital signal processor further comprises a multiplexer configured to multiplex outputs of at least two of the symbol encoders. 11. An apparatus comprising a data receiver that comprises an analog front end and a digital signal processor configured to process digital samples corresponding to a plurality of input signals received by the analog front end at input ports connectable to proximal ends of a corresponding plurality of subscriber lines, the input signals being received in response to data signals applied to distal ends of the subscriber lines, the data signals having been encoded with data using frequency-division multiplexing; wherein the digital signal processor comprises a vector processor configured to postcode the digital samples in a manner that causes effects of crosstalk between distinct groups of the subscriber lines to be substantially mitigated, at least one of said distinct groups including at least two of the subscriber lines; wherein the vector processor is further configured to postcode the digital samples in a manner that causes each distinct group of the data signals to convey the data thereof to a different respective data block formed by the vector processor, each of said distinct groups of the data signals being applied to the distal ends of a corresponding one of said distinct groups of the subscriber lines; and wherein the apparatus further comprises a scheduler configured to control flows of data through the digital signal processor such that, during a given symbol period, a given resource block of any of the distinct groups of the data signals carries data corresponding to a single respective subscriber. 12. The apparatus of claim 11 , wherein the vector processor is configured to postcode the digital samples using a fixed postcoder matrix during two or more symbol periods during which a tone is allocated to different respective subscribers. 13. The apparatus of claim 11 , wherein the vector processor has N inputs and G outputs, where the number G is the number of the distinct groups, and the number N is the number of the subscriber lines, the number N being greater than the number G, the number G being greater than one; wherein each of the N inputs is connected to a respective one of the subscriber lines; and wherein the G outputs are connected to G different output data paths. 14. The apparatus of claim 13 , wherein the digital signal processor further comprises G demultiplexers, each connected to transmit data received from a respective one of the G outputs to a respective set of N different data sinks. 15. The apparatus of claim 13 , wherein the vector processor is configured to postcode the digital samples using a G×N postcoder matrix; and wherein the data receiver is configured to compute the G×N postcoder matrix in response to measurements of an N×N uplink channel matrix corresponding to the N subscriber lines. 16. The apparatus of claim 11 , wherein the digital signal processor further comprises a plurality of decapsulation modules, a plurality of deframers, a plurality of symbol decoders, and a plurality of demodulators connected to the vector processor. 17. The apparatus of claim 16 , wherein the digital signal processor further comprises a demultiplexer configured to feed at least two of the decapsulation modules in response to a received input. 18. The apparatus of claim 16 , wherein the digital signal processor further comprises a demultiplexer configured to feed at least two of the symbol decoders in response to a received input.