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A decision feedback equalizer (DFE) architecture uses feedback samples that are over-sampled with respect to the symbol rate. On-baud feedback samples are quantized with a slicer, while off-baud samples are linear, IIR samples. Both forward and feedback filters are fractionally-spaced, but adapted

A decision feedback equalizer (DFE) architecture uses feedback samples that are over-sampled with respect to the symbol rate. On-baud feedback samples are quantized with a slicer, while off-baud samples are linear, IIR samples. Both forward and feedback filters are fractionally-spaced, but adapted only at the baud instances.

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We claim: 1. In a communications receiver having a decision feedback equalizer filter, the communications receiver responsive to a received signal that is over-sampled with respect to a symbol rate, an apparatus comprising: a forward filter that receives the over-sampled signal and is adaptive base

We claim: 1. In a communications receiver having a decision feedback equalizer filter, the communications receiver responsive to a received signal that is over-sampled with respect to a symbol rate, an apparatus comprising: a forward filter that receives the over-sampled signal and is adaptive based on a first feedback signal; a first adder that sums an output of the forward filter with a second feedback signal to produce a new over-sampled signal; a de-interleaver, clocked at an over-sampling rate associated with the over-sampled signal, that receives the new over-sampled signal; a slicer, coupled to the de-interleaver, for quantizing on-baud samples from the new over-sampled signal; an estimator, coupled to receive off-baud samples from the de-interleaver and receive the guantized samples from the slicer, for calculating approximate mid-level voltages for off-baud samples from the new over-sampled signal; an error term calculator, coupled to receive the on-baud samples and the quantized samples from the new over-sampled signal, for calculating the first feedback signal; an interleaver, clocked at the over-sampling rate, and coupled to the de-interleaver, wherein the interleaver receives the quantized samples and receives off-baud samples from the new over-sampled signal; and a feedback filter coupled to receive an output signal from the interleaver and to produce the second feedback signal for the first adder, wherein the feedback filter is adaptive based on the first feedback signal from the error term calculator. 2. In a communications receiver having a decision feedback equalizer filter, the communications receiver responsive to a received signal that is over-sampled with respect to a symbol rate, an apparatus comprising: a forward filter that receives the over-sampled signal and is adaptive based on a first feedback signal; a first adder that sums an output of the forward filter with a second feedback signal to produce a new over-sampled signal; a de-interleaver, clocked at an over-sampling rate associated with the over-sampled signal, that receives the new over-sampled signal; a slicer, coupled to the de-interleaver, for quantizing on-baud samples from the new over-sampled signal; an error term calculator, coupled to receive the on-baud samples and the quantized samples from the new over-sampled signal, for calculating the first feedback signal; an interleaver, clocked at the over-sampling rate, and coupled to the de-interleaver, wherein the interleaver receives the quantized samples and receives off-baud samples from the new over-sampled signal; and a feedback filter coupled to receive an output signal from the interleaver and to produce the second feedback signal for the first adder, wherein the feedback filter is adaptive based on the first feedback signal from the error term calculator; a first multiplier, coupled to the de-interleaver, for multiplying the on-baud samples from the new over-sampled signal with a first error term from the error term calculator; a second multiplier, coupled to the slicer, for multiplying the quantized samples from the new over-sampled signal with a second error term from the error term calculator; a third multiplier, coupled to the de-interleaver, for multiplying the on-baud samples from the new over-sampled signal with a third error term from the error term calculator; a fourth multiplier, coupled to an output of the second multiplier, for multiplying the quantized samples from the new over-sampled signal with a fourth error term from the error term calculator; and a second adder for summing outputs from the third and fourth multipliers to produce an input signal to the interleaver. 3. In a communications receiver having a decision feedback equalizer filter, the communications receiver responsive to a received signal that is over-sampled with respect to a symbol rate, an apparatus comprising: a forward filter that receives the over-sampled signal and is adaptive based on a first feedback signal; a first adder that sums an output of the forward filter with a second feedback signal to produce a new over-sampled signal; a de-interleaver, clocked at an over-sampling rate associated with the over-sampled signal, that receives the new over-sampled signal; a slicer, coupled to the de-interleaver, for quantizing on-baud samples from the new over-sampled signal; an error term calculator, coupled to receive the on-baud samples and the quantized samples from the new over-sampled signal, for calculating the first feedback signal; an interleaver, clocked at the over-sampling rate, and coupled to the de-interleaver, wherein the interleaver receives the quantized samples and receives off-baud samples from the new over-sampled signal; and a feedback filter coupled to receive an output signal from the interleaver and to produce the second feedback signal for the first adder, wherein the feedback filter is adaptive based on the first feedback signal from the error term calculator; a first multiplier, coupled to the de-interleaver, for multiplying the on-baud samples from the new over-sampled signal with a first error term from the error term calculator; a second multiplier, coupled to the slicer, for multiplying the quantized samples from the new over-sampled signal with a second error term from the error term calculator; and a second adder for summing outputs from the first and second multipliers to produce an input signal to the interleaver. 4. In a communications receiver responsive to a received signal that is over-sampled with respect to a symbol rate of the received signal, an apparatus for at least combating inter-symbol interference (ISI) in the received signal, the apparatus comprising: a decision feedback equalizer, wherein the decision feedback equalizer includes: an error term calculator that determines error values based on the over-sampled signal; a slicer for quantizing samples in a feedback signal that are on-baud; an estimator configured to estimate quantized samples from the received signal when the received signal includes symbols that are off-baud with respect to an ideal symbol rate for the received signal; a fractionally-spaced forward, transversal filter that processes the over-sampled signal, wherein the fractionally-spaced forward, transversal filter is adaptive based on the error values produced by the error term calculator; and a fractionally-spaced feedback filter that processes the over-sampled signal, wherein the fractionally-spaced feedback filter is coupled to the fractionally-spaced forward, transversal filter, and is adaptive based on the error values produced by the error term calculator. 5. The apparatus of claim 4, wherein the apparatus employs samples in the feedback signal that are off-baud under a linear, infinite impulse response (IIR) filter. 6. The apparatus of claim 4 wherein the fractionally-spaced forward, transversal filter and fractionally-spaced feedback filter are adaptive only at baud instances. 7. The apparatus of claim 4, further comprising an initializing section configured to generate initial feedback filter coefficients for at least the fractionally-spaced feedback filter. 8. The apparatus of claim 4, further comprising: a tuner configured to receive a digital television signal; a front end processor configured to process the digital television signal; and a decoder for decoding the processed digital television signal. 9. In a communications receiver that receives a signal, a method for at least combating inter-symbol interference (ISI) in the received signal, the method comprising: receiving an input signal that is over-sampled with respect to a symbol rate of the received signal; and decision feedback equalizing the over-sampled input signal, wherein the decision feedback equalizing includes: forward, transversal filtering the over-sampled input signal based on first equalizer coefficients, wherein first equalizer coefficients adjacent in time are less than a symbol interval apart with respect to the received signal; feedback filtering the over-sampled input signal with second equalizer coefficients, wherein second equalizer coefficients adjacent in time are less than a symbol interval apart with respect to the received signal, calculating error values based on the over-sampled input signal; adapting the forward, transversal filtering and the feedback filtering based at least in part on the calculated error values; and wherein the method further comprises quantizing samples in a feedback signal that are on-baud with respect to an ideal symbol rate for the received signal, and wherein the feedback filtering includes infinite impulse response (IIR) filtering employing samples off-baud with respect to the ideal symbol rate for the received signal. 10. The method of claim 9 wherein the adapting is performed only at the symbol rate. 11. The method of claim 9 further comprising estimating quantized samples from the received signal when the received signal includes symbols that are off-rate with respect to an ideal symbol rate for the received signal. 12. The method of claim 9 further comprising initializing at least the feedback filtering. 13. The method of claim 9 further comprising: tuning to a desired frequency to receive a digital television signal; front end processing the received digital television signal; and decoding the processed digital television signal. 14. a communications receiver that receives a signal, a method for at least combating inter-symbol interference (ISI) in the received signal, the method comprising: receiving an input signal that is over-sampled with respect to a symbol rate of the received signal; and decision feedback equalizing the over-sampled input signal, wherein the decision feedback equalizing includes: forward, transversal filtering the over-sampled input signal based on first equalizer coefficients, wherein first equalizer coefficients adjacent in time are less than a symbol interval apart with respect to the received signal; feedback filtering the over-sampled input signal with second equalizer coefficients, wherein second equalizer coefficients adjacent in time are less than a symbol interval apart with respect to the received signal, calculating error values based on the over-sampled input signal; adapting the forward, transversal filtering and the feedback filtering based at least in part on the calculated error values; wherein the method further comprises quantizing samples in a feedback signal that are on-baud with respect to an ideal symbol rate for the received signal; and wherein the method further comprises estimating quantized samples from the received signal when the received signal includes symbols that are off-baud with respect to an ideal symbol baud for the received signal. 15. The method of claim 14, wherein the feedback filtering includes infinite impulse response (IIR) filtering employing samples off-baud with respect to the ideal symbol rate for the received signal. 16. The method of claim 14 wherein the adapting is performed only at the symbol rate. 17. The method of claim 14, further comprising initializing at least the feedback filtering. 18. The method of claim 14, further comprising: tuning to a desired frequency to receive a digital television signal; front end processing the received digital television signal; and decoding the processed digital television signal.