In certain embodiments, a method may include receiving one or more equalized samples of an input signal. The method may further include mitigating one or more excursions in the one or more equalized samples based on one or more current decisions of an iterative decoding process to generate compensated equalized samples. In addition, the method may include performing iterative decoding operations based on the compensated equalized samples, updating the current decisions of the iterative decoding process and outputting the current decisions as a converged result when the iterative decoding operations have converged for the compensated equalized samples.

A more cost effective wander jitter filter utilizes an excursion detector that receives a timing difference between a first signal and a second signal and supplies a first adjustment amount if a magnitude of the timing difference is above a predetermined threshold and otherwise supplies a second adjustment amount of zero. A summing circuit adjusts a magnitude of the timing difference by the first or second adjustment amount. A loop filter receives the summing circuit output and controls an oscillator. The excursion detector output (first adjustment value or zero according to the magnitude of the timing difference) is low pass filtered and the low pass filtered is reintroduced into the oscillator output or the feedback loop. The excursion detector output is accumulated and used to adjust a phase of the feedback signal from the oscillator.

A serial input/output method and receiver include an receiver portion to receive an analog differential serial input and sample the input to provide data and error signals, an equalization feedback loop responsive to the data and error signals to adjust the receiver portion, a phase feedback mechanism separate from the equalization feedback loop to provide a phase error, and a clock data recovery block coupled to receive the phase error to perform timing recovery for the receiver portion independent of the equalization feedback to adjust the sampling.

An integrated circuit device includes an output driver having a data signal terminal, logic circuitry, and a driver circuit coupled to the logic circuitry and data signal terminal. The driver circuit is configured to drive a signal corresponding to a symbol onto the data signal terminal, wherein the symbol is an N-bit symbol, having one of 2N predefined values, N is an integer greater than 1, and the signal corresponding to the symbol has one of 2N signal levels. The driver circuit includes first, second and third driver sub-circuits, each driven by an input corresponding to one or more bits of the N-bit symbol, wherein the second and third driver sub-circuits are weighted, relative to the first driver sub-circuit, to reduce gds distortion in the signal.

A phase-locked loop (PLL) filter of a read channel includes a filter portion having an input coupled to delay circuitry having an output. The input of the filter portion is configured to receive a phase error signal. A look-up table is coupled to the filter portion. The look-up table comprises phase coefficients and frequency coefficients associated with a plurality of phase error magnitudes. The look-up table is configured to provide one or both of a selected phase coefficient and a selected frequency coefficient based on a magnitude of the phase error signal. The PLL filter is configured to adjust a bandwidth of the filter portion using one or both of the selected phase coefficient and the selected frequency coefficient. A phase signal indicative of estimated phase disturbance is produced at the output of the delay circuitry.

An apparatus includes a phase detector coupled to an output of a frequency multiplier. A digital loop filter is coupled to the phase detector, and a duty cycle correction circuit is coupled to the digital loop filter.

Techniques to operate circuitry in an integrated circuit are provided. The circuitry may include a receiver circuit and one of the provided techniques includes receiving a data stream at the receiver circuit. The receiver circuit may include a detector circuit that is used to determine the data rate of the received data stream. A controller block in the receiver circuit may accordingly configure a deserializer circuit in the receiver circuit based on the data rate of the received data stream. The circuitry may further include a transmitter circuit for transmitting data streams. The transmitter circuit may be configured during runtime based on the data rate of a data stream that is being transmitted. In some instances, irrespective of the data rate of the data stream being transmitted, a constant reference clock may be used in the transmitter circuit.

An integrated circuit receiver is disclosed comprising a data receiving circuit responsive to a timing signal to detect a data signal and an edge receiving circuit responsive to the timing signal to detect a transition of the data signal. One of the data or edge receiving circuits comprises an integrating receiver circuit while the other of the data or edge sampling circuits comprises a sampling receiver circuit.

A radio communication device has an analog control loop unit to generate an analog control signal, a digital control loop unit which has a frequency determined with the frequency of a reference signal and a predetermined frequency setting code signal, a voltage controlled oscillator to generate the voltage control oscillation signal, a data slicer to generate a digital signal obtained by digitally demodulating the reception signal, an automatic offset controller to generate a correction signal, a setting code adjuster to adjust the frequency setting code signal, based on the correction signal, and a direct-current level adjuster to adjust a direct-current level of the digital control signal, based on the correction signal. The data slicer compares the digital control signal adjusted by the direct-current level adjuster, with the threshold value.

Techniques to operate circuitry in an integrated circuit are provided. The circuitry may include a receiver circuit and one of the provided techniques includes receiving a data stream at the receiver circuit. The receiver circuit may include a detector circuit that is used to determine the data rate of the received data stream. A controller block in the receiver circuit may accordingly configure a deserializer circuit in the receiver circuit based on the data rate of the received data stream. The circuitry may further include a transmitter circuit for transmitting data streams. The transmitter circuit may be configured during runtime based on the data rate of a data stream that is being transmitted. In some instances, irrespective of the data rate of the data stream being transmitted, a constant reference clock may be used in the transmitter circuit.