Abstract: Systems and methods are provided for optimizing offset compensation in a receiver with multiple offset compensation D/A converters. At each stage where offset cancellation is applied, there is a fan-out of two or more. At the final stage, comparator offset compensation codes are summed and compared against a digital reference. In one version the digital reference is zero. A second implementation has a non-zero digital reference which is the sum of comparator offsets stored from start up. The difference between the sum of offsets and digital reference is applied to a digital accumulator. The most significant bits of the digital accumulator are applied to a digital D/A converter, which cancel analog offsets in an intermediate stage of amplifiers. The summation of offsets feeding into an accumulator is implemented for all preceding stages.

Abstract: Apparatus and methods for phasing detection of asynchronous dividers are provided herein. In certain embodiments, a clock and data recovery system includes a first divider that outputs a first divided clock signal, a second divider that outputs a second divided clock signal, and an asynchronous clock phasing detection circuit that generates a detection signal indicating a relative phase difference between the first divided clock signal and the second divided clock signal. The asynchronous clock phasing detection circuit includes a quantization and logic circuit that generates an output signal indicating when the first divided clock signal and the second divided clock signal are in different states, an oscillator that outputs a control clock signal, a first counter controlled by the control clock signal and configured to count the output signal, and a control circuit that processes a first count signal from the first counter to generate the detection signal.

Abstract: Systems and methods are provided for optimizing offset compensation in a receiver with multiple offset compensation D/A converters. At each stage where offset cancellation is applied, there is a fan-out of two or more. At the final stage, comparator offset compensation codes are summed and compared against a digital reference. In one version the digital reference is zero. A second implementation has a non-zero digital reference which is the sum of comparator offsets stored from start up. The difference between the sum of offsets and digital reference is applied to a digital accumulator. The most significant bits of the digital accumulator are applied to a digital D/A converter, which cancel analog offsets in an intermediate stage of amplifiers. The summation of offsets feeding into an accumulator is implemented for all preceding stages.

Abstract: Serial data transfer uses ever increasing transmission rates. The data transfer rate of a clock-and-data recovery (CDR) deserializer can be increased by using multiple independent sampler blocks that process serial input data in parallel. For this purpose, the clock output signals from the various independent blocks are first mutually aligned in proper order using a lower speed clock, and subsequently offset from one another such that sampling instances of the various sampler blocks are interleaved. Digitized data words corresponding to common input data and outputted by the various sampler blocks are compared after alignment of the clock output signals to correct additional timing misalignment between the multiple sampler blocks. The digitized data words need only be aligned once or at most infrequently after the clock output signals are aligned, since the additional timing misalignment is caused mainly path delays that are substantially invariant over time.

Abstract: A system can be configured to control an equalizer circuit to equalize a data signal without requiring prior knowledge of the data signal's data rate. In an example, the system includes an equalizer circuit configured to equalize a data signal based on an equalizer control signal to produce an equalized signal, and a pattern detector configured to detect a specified data pattern in the equalized signal at each of multiple sampling rates. A control circuit can be configured to generate a preferred equalization control signal based on a sampling rate, selected from the multiple sampling rates, at which the pattern detector detects the specified data pattern in the equalized signal.

Abstract: Serial data transfer uses ever increasing transmission rates. The data transfer rate of a clock-and-data recovery (CDR) deserializer can be increased by using multiple independent sampler blocks that process serial input data in parallel. For this purpose, the clock output signals from the various independent blocks are first mutually aligned in proper order using a lower speed clock, and subsequently offset from one another such that sampling instances of the various sampler blocks are interleaved. Digitized data words corresponding to common input data and outputted by the various sampler blocks are compared after alignment of the clock output signals to correct additional timing misalignment between the multiple sampler blocks. The digitized data words need only be aligned once or at most infrequently after the clock output signals are aligned, since the additional timing misalignment is caused mainly path delays that are substantially invariant over time.

Abstract: A system can be configured to control an equalizer circuit to equalize a data signal without requiring prior knowledge of the data signal's data rate. In an example, the system includes an equalizer circuit configured to equalize a data signal based on an equalizer control signal to produce an equalized signal, and a pattern detector configured to detect a specified data pattern in the equalized signal at each of multiple sampling rates. A control circuit can be configured to generate a preferred equalization control signal based on a sampling rate, selected from the multiple sampling rates, at which the pattern detector detects the specified data pattern in the equalized signal.

Abstract: Apparatus and methods for continuous-time equalization are provided. In one aspect, an apparatus includes an integrator configured to track and process an asynchronous input signal according to actual or approximated frequency-dependent subtraction. The apparatus further includes a comparator or subtractor configured to compare a threshold, output by the integrator, with the asynchronous input signal. In various embodiments, the integrator can include a leaky integrator configured to apply a transform in the form 1/(1+s/?), wherein s can be adjusted based on the complex angular frequency of the asynchronous input signal. In various embodiments, the integrator can include a programmable network having a resistance R and a capacitance C, and ? can include 1/(RC). In various embodiments, the integrator can include one or more programmable current sources configured to adjust a level of boost in said frequency-dependent subtraction.

Abstract: A system and method are described herein that provide for the calibration of the offset of a comparator on a per-comparator basis. An injection is made to the comparator at determined injection points using a low-power DAC, to calibrate the offset of the comparator. The DAC can be selectively controlled by a digital codeword that is generated based on an output of the comparator and the comparator's offset. Further embodiments of the invention present a system and method for calibrating the offset of a comparator of a flash ADC in each stage of a pipeline ADC. The system and method may provide for the calibration in a manner without affecting the speed of the pipeline ADC or adding significant power to the pipeline ADC.

Abstract: Apparatus and methods for quadrature clock signal generation are provided. In certain implementations, a quadrature clock signal generator includes a sine-shaping filter and a polyphase filter. The sine-shaping filter can receive an input clock signal such as a square or rectangular wave and can filter the input clock signal to generate a sinusoidal clock signal. Additionally, the polyphase filter can use the sinusoidal clock signal to generate in-phase (I) and quadrature-phase (Q) clock signals, which can have a phase difference of about ninety degrees. In certain configurations, the in-phase and quadrature-phase clock signals generated by the polyphase filter can be buffered by a buffer circuit to generate in-phase and quadrature-phase sinusoidal reference clock signals suitable for use in a clock and data recover (CDR) system.

Abstract: Apparatus and methods for quadrature clock signal generation are provided. In certain implementations, an apparatus includes an invertible sine shaping filter configured to receive an in-phase clock signal, a quadrature-phase clock signal, and an inversion control signal. The invertible sine-shaping filter is further configured to filter the in-phase and quadrature-phase clock signals to generate sinusoidal in-phase and quadrature-phase clock signals. The invertible sine-shaping filter is further configured to selectively invert one or both of the in-phase and quadrature-phase clock signals based on an inversion control signal. The apparatus further includes a phase interpolator configured to generate an interpolated clock signal based on a weighted sum of the selectively inverted sinusoidal in-phase clock signal and the quadrature-phase sinusoidal clock signal. The in-phase clock signal and the quadrature-phase clock signal have a quadrature-phase relationship.

Abstract: Apparatus and methods for quadrature clock signal generation are provided. In certain implementations, a quadrature clock signal generator includes a sine-shaping filter and a polyphase filter. The sine-shaping filter can receive an input clock signal such as a square or rectangular wave and can filter the input clock signal to generate a sinusoidal clock signal. Additionally, the polyphase filter can use the sinusoidal clock signal to generate in-phase (I) and quadrature-phase (Q) clock signals, which can have a phase difference of about ninety degrees. In certain configurations, the in-phase and quadrature-phase clock signals generated by the polyphase filter can be buffered by a buffer circuit to generate in-phase and quadrature-phase sinusoidal reference clock signals suitable for use in a clock and data recover (CDR) system.

Abstract: A system and method are described herein that provide for the calibration of the offset of a comparator on a per-comparator basis. An injection is made to the comparator at determined injection points using a low-power DAC, to calibrate the offset of the comparator. The DAC can be selectively controlled by a digital codeword that is generated based on an output of the comparator and the comparator's offset. Further embodiments of the invention present a system and method for calibrating the offset of a comparator of a flash ADC in each stage of a pipeline ADC. The system and method may provide for the calibration in a manner without affecting the speed of the pipeline ADC or adding significant power to the pipeline ADC.