Abstract: Receiver circuitry for receiving a data signal includes summation node circuitry that predicts an error value of the received data signal. The receiver circuitry also includes adaptation engine circuitry coupled to the summation node circuitry. The adaptation engine circuitry determines a transmitter adjustment based on the error value and sends a freeze signal to one or more components of the receiver to cause the receiver to continue operating without changing current settings of the one or more components. The receiver circuitry further includes a user interface and sequence controller, coupled to the adaptation engine circuitry, wherein the user interface and sequence controller sends a signal indicative of the transmitter adjustment to the transmitter.

Abstract: Receiver circuitry for receiving a data signal includes summation node circuitry that predicts an error value of the received data signal. The receiver circuitry also includes adaptation engine circuitry coupled to the summation node circuitry. The adaptation engine circuitry determines a transmitter adjustment based on the error value and sends a freeze signal to one or more components of the receiver to cause the receiver to continue operating without changing current settings of the one or more components. The receiver circuitry further includes a user interface and sequence controller, coupled to the adaptation engine circuitry, wherein the user interface and sequence controller sends a signal indicative of the transmitter adjustment to the transmitter.

Abstract: An integrated circuit may include receiver circuitry that receives data from an external device. Such receiver circuitry may include, among other things, equalization circuitry that may reconstruct the received data before transmitting the received data to other parts of the integrated circuit. The receiver circuitry may include two different equalization circuits. A first equalization circuit may perform equalization on the received data to generate a first equalized output while a second equalization circuit may generate a second equalized output. The receiver circuitry may further include an amplifier circuit that selectively amplifies either the first or second equalized output from the respective first and second equalization circuits based on the data rate of the received data.

Abstract: Disclosed is a circuit architecture for cancellation of threshold voltage offsets for an array of sense amplifiers. An offset calibration controller, which may be embedded as a hard-wired circuit in the transceiver core circuits, writes the offset adjustment values to a memory-mapped interface circuit. The memory-mapped interface circuit outputs the offset adjustment values to offset adjustment circuits for the sense amplifiers. The offset adjustment circuits may utilize a body bias technique. Advantageously, the disclosed circuit architecture provides for the minimization of residual offset without sacrificing bandwidth. Other embodiments, features and advantages are also disclosed.

Abstract: One embodiment relates to a method performed by on-die instrumentation. Speculative-high and speculative-low error signals are generated using first and second sense amplifiers. The speculative-high and speculative-low error signals are deserialized to generate speculative-high and speculative-low error data. A subset of bits in the speculation-high and speculation-low error data are determined to be invalid based on prior bits in recovered data obtained using a clock-data recovery and decision feedback equalizer circuit. Another embodiment relates to an integrated circuit with on-die instrumentation for obtaining bit error data for an eye-opening diagram. The integrated circuit includes a voltage multiplexer, a clock multiplexer and first and second sense amplifiers. Other embodiments, aspects and features are also disclosed.

Abstract: Systems and methods are described that include adaptation circuitry for processing a data signal. The adaptation circuitry may include summation node circuitry for processing an error value associated with the data signal. The adaptation circuitry may also include adaptation engine circuitry, coupled to the summation node circuitry, for controlling the operation of the summation node circuitry.

Abstract: An integrated circuit having transceiver circuitry is provided. The transceiver circuitry may include an equalization circuit such as a decision feedback equalizer (DFE). The DFE may include a variable gain amplifier (VGA) that is coupled to a summation node circuit and a digital sampler. The DFE may also include an operational amplifier that is coupled in a negative feedback loop and that provides a controlled power supply voltage to the VGA so that the VGA is able to provide a stable common mode output voltage to the digital sampler. The operational amplifier may be a self-biased operational amplifier with an output stage that includes miller compensation circuitry for enhanced stability.

Abstract: An integrated circuit includes a duty cycle detection circuit, a comparator circuit, and a tuning circuit. The duty cycle detection circuit receives a clock signal, such as a system clock signal, and detects the level of duty cycle distortion in the clock signal. The comparator circuit then generates an output based on the level of duty cycle distortion that is detected in the clock signal. The tuning circuit may accordingly adjust the clock signal based on the output generated by the comparator circuit to produce an adjusted clock output signal. As an example, the clock output signal produced by the tuning circuit after the adjustment may have a 50% (or significantly close to 50%) duty cycle.