Abstract: An integrated circuit is provided that includes via-configured structured logic circuitry and an embedded arithmetic block that interfaces with the via-configured structured logic circuitry to perform an arithmetic function. The embedded arithmetic block includes at least one monolithic arithmetic circuit that can perform the arithmetic function more efficiently or taking up less die space than a comparable circuit formed from the via-configured structured logic circuitry.

Abstract: A method of analyzing a phase of a clock signal for receiving data is described. The method comprises identifying an end of an eye pattern associated with received data; testing points along a contour of the eye pattern to establish a margin for an opening of the eye pattern; and determining whether a phase of the clock signal is acceptable for receiving the received data. A circuit for analyzing a phase of a clock signal for receiving data is also described.

Abstract: Circuits and methods characterize a receiver. The circuit includes a decision feedback equalizer (DFE) circuit, a clock and data recovery (CDR) circuit, a data checker, and an eye-scan controller. The DFE circuit generates a filtered signal from the communication signal. The filtered signal is a sum of the communication signal and a variable weighting of a symbol recently sampled from the filtered signal. The CDR circuit samples a sequence of sampled symbols from the filtered signal. The CDR circuit samples the filtered signal at a variable phase relative to a clock signal. The data checker generates an indication of an error in the sequence of sampled symbols. The eye-scan controller varies the variable weighting and the variable phase through multiple value combinations. The eye-scan controller checks for the indication of the error for each of the value combinations.

Abstract: A receiver circuit includes an analog front-end circuit, a first adaptation circuit, and a second adaptation circuit. A method operates the receiver circuit. The analog front-end circuit is configured to resolve an output signal from an input signal as a function of adjustable parameters. The first adaptation circuit is coupled to the analog front-end circuit and is configured to determine values of the adjustable parameters responsive to the output signal. The second adaptation circuit is coupled to the analog front-end circuit and to the first adaptation circuit. The second adaptation circuit is configured to adjust the values of the adjustable parameters responsive to one or more operating conditions of the receiver circuit. These operating conditions include a temperature and/or a power supply voltage of the receiver circuit.

Abstract: A receiver circuit includes an analog front-end circuit, a first adaptation circuit, and a second adaptation circuit. A method operates the receiver circuit. The analog front-end circuit is configured to resolve an output signal from an input signal as a function of adjustable parameters. The first adaptation circuit is coupled to the analog front-end circuit and is configured to determine values of the adjustable parameters responsive to the output signal. The second adaptation circuit is coupled to the analog front-end circuit and to the first adaptation circuit. The second adaptation circuit is configured to adjust the values of the adjustable parameters responsive to one or more operating conditions of the receiver circuit. These operating conditions include a temperature and/or a power supply voltage of the receiver circuit.