Abstract: A clock data recovery (CDR) apparatus can include an interpolator circuitry to interpolate an input received signal and to generate an output signal removing the sampling clock offsets. The apparatus can include timing error detector (TED) circuitry coupled to process the output signal and to provide a timing error as feedback to the interpolator circuitry, the timing error being adjusted by gain factors used in at least one of an automatic gain control (AGC) circuitry and an orthogonalization circuitry. The apparatus can include loop filter (LF) circuitry to filter the timing error to remove noise effects. The apparatus can include numerically controlled oscillator (NCO) circuitry to adjust for a basepoint and fractional interval used to adjust resampling coefficients within the interpolator circuitry.

Abstract: A method for calibrating an optical transceiver. The method can include configuring optical switches to enable routing at least one output signal of modulator circuitry operably coupled to a first receive path of a coherent optical transceiver. The method can include configuring the input to at least one modulator to generate at least one first stimulus signal. The method can include configuring a path from the first receiver analog-to-digital converter to an adaptive algorithm circuitry. The method can include adapting at least one bias setting of a photodiode associated with the first receiver in response to at least one first stimulus detected at the first receiver analog-to-digital converter to an adaptive algorithm circuitry. The method can include determining an optimum value of a photodiode associated with the first receiver.

Abstract: An apparatus can include at least two circuit portions having separate power sequencer circuitry. The apparatus can further include processing circuitry configured to control at least one portion of the at least two circuit portions to operate at an initial low power level and subsequent higher power levels to full operation.

Abstract: A converter can include a number of time-to-voltage converters (TVCs) each receiving an input time-domain signal. The input time-domain signal can represent a different sample than input time-domain signals of the other TVCs. The converter can also include a capacitive element coupled to outputs of the TVCs to receive a combined output signal of the TVCs. The capacitive element can provide an input capacitance of an analog-to-digital converter (ADC). Other methods and apparatuses are described.

Abstract: An apparatus, system, and method for are provided. A device includes a time-to-digital converter (TDC) situated to convert a time-domain signal to a digital value, a delay circuit situated in parallel with the TDC and to delay the time-domain signal by a specified amount of time resulting in a delayed time-domain signal, a time-to-voltage converter (TVC) situated to produce a voltage-domain signal based on the delayed time-domain signal, and a successive approximation (SAR) circuit situated to receive the digital value and the voltage-domain signal and produce a digital-domain version of the input signal.

Abstract: An apparatus can include a digital-to-analog converter (DAC) and calibration circuitry including an oscillator. The calibration circuitry can be coupled to an output of the DAC, the calibration circuitry to sample and count DAC output pulses for at least two consecutive pulses using at least two separate counter circuits. The calibration circuitry can determine error between at least two consecutive pulses and provide a correction value based on the error. The apparatus can further include correction circuitry to provide a calibration signal to the DAC based on the correction value.

Abstract: A differential voltage-to-time converter (VTC) architecture and method of providing VTC signals are disclosed. The VTC includes a ramp generator that generates a ramp voltage, capacitors having a bottom plate coupled with the ramp generator to receive the ramp voltage, and inverters having inputs coupled to top plates of the capacitors to provide signals based on a sampled signal. A threshold voltage or supply voltage of the inverters tracks a minimum input signal voltage.

Abstract: A time-to-digital converter (TDC) that combines the energy efficiency of a successive approximation (SAR) design with the high speed of pipelined converters by leveraging the inherently pipelined nature of time-domain signaling. The TDC achieves high speed by removing a comparator decision from a signal path, instead using AND/OR gates to separate early and late edges. The TDC uses a pipelined SAR architecture to digitize a differential delay between two incoming clock edges with high speed and low power consumption. Described is a modular digital reference voltage generator that can be used for a capacitive digital-to-analog converter (DAC). The generator comprises a decoupling capacitor, one or more clocked comparators, and power transistor(s). A simplified digital low dropout (LDO) circuitry is used to provide fast reference voltage generation with minimal overhead. The LDO circuitry is arrayed using time-interleaved synchronous clocks or staggered asynchronous clocks to provide finer timing resolution.