Abstract: In a 1000 BASE-T transceiver, a timing error detector (TED, 5) receives its inputs directly from the output of an ADC (2) and from a decision device (4). Timing recovery is acquired in three stages: a non-decision directed (NDD) stage during which only the output of an ADC (2) are used for acquisition; a stage for acquiring the remote scrambler and predicting symbols; and a decision-directed (DD) stage during which locally predicted symbols are also used for acquisition. Because the timing error detector (TED, 5) does not take inputs from the FFE (3) there is no information about cable length, and so an input of gain from an AGC is used to indicate cable length.

Abstract: Channel equalization in a 1000BASE-T receiver is performed by a fixed mode analog filter 2 suitable for the longest possible cable length, by a FFE (3), and by a digital filter 4. The digital filter (4) has two sets of taps. One set is optimal for shorter cable lengths and so cancels adaptation for long cable lengths and assists operation of the analog filter. A decision block (5) selects an appropriate set of taps.

Abstract: A Gigabit transceiver (1) has a receiver (2) and a transmitter (3). There is an ADC (5) in the receiver (2) for each channel (A, B, C, D). The ADCs (5) oversample at a factor of 2. However the remainder of the digital circuitry and transmitter DACs (2) operate off half of the oversampling rate. In the receiver (2) fractionally spaced equalisers (FSES, 6) ensure that the optimum sampling phase is selected digitally. The invention avoids the need for a PLL in the receiver for each channel and associated interference and retiming problems.

Abstract: A Gigabit transceiver (1) has a receiver (2) and a transmitter (3). There is an ADC (5) in the receiver (2) for each channel (A, B, C, D). The ADCs (5) oversample at a factor of 2. However the remainder of the digital circuitry and transmitter DACs (2) operate off half of the oversampling rate. In the receiver (2) fractionally spaced equalisers (FSES, 6) ensure that the optimum sampling phase is selected digitally. The invention avoids the need for a PLL in the receiver for each channel and associated interference and retiming problems.

Abstract: In a 1000 BASE-T transceiver, a timing error detector (TED, 5) receives its inputs directly from the output of an ADC (2) and from a decision device (4). Timing recovery is acquired in three stages: a non-decision directed (NDD) stage during which only the output of an ADC (2) are used for acquisition; a stage for acquiring the remote scrambler and predicting symbols; and a decision-directed (DD) stage during which locally predicted symbols are also used for acquisition. Because the timing error detector (TED, 5) does not take inputs from the FFE (3) there is no information about cable length, and so an input of gain from an AGC is used to indicate cable length.

Abstract: Channel equalization in a 1000BASE-T receiver is performed by a fixed mode analog filter 2 suitable for the longest possible cable length, by a FFE (3), and by a digital filter 4. The digital filter (4) has two sets of taps. One set is optimal for shorter cable lengths and so cancels adaptation for long cable lengths and assists operation of the analog filter. A decision block (5) selects an appropriate set of taps.