Abstract: A clock calibration module, a high-speed receiver, and an associated calibration method are provided. The calibration method is applied to the high-speed receiver having the clock calibration module and a sampler. The sampler samples an equalized data signal with a sampler-input clock. The clock calibration module includes multiple clock generation circuits and a clock calibration circuit. Each of the clock generation circuits includes a phase interpolator, a duty cycle corrector, and a phase corrector. In a calibration mode, the phase interpolator interpolates a reference input clock and generates an interpolated clock accordingly. The duty cycle corrector generates a duty cycle corrected clock based on the interpolated clock. The phase corrector generates the sampler-input clock based on the duty cycle corrected clock. The phase interpolator is controlled by a phase interpolator calibration signal, and the phase corrector is controlled by a phase corrector calibration signal.

Abstract: A clock calibration module, a high-speed receiver, and an associated calibration method are provided. The calibration method is applied to the high-speed receiver having the clock calibration module and a sampler. The sampler samples an equalized data signal with a sampler-input clock. The clock calibration module includes multiple clock generation circuits and a clock calibration circuit. Each of the clock generation circuits includes a phase interpolator, a duty cycle corrector, and a phase corrector. In a calibration mode, the phase interpolator interpolates a reference input clock and generates an interpolated clock accordingly. The duty cycle corrector generates a duty cycle corrected clock based on the interpolated clock. The phase corrector generates the sampler-input clock based on the duty cycle corrected clock. The phase interpolator is controlled by a phase interpolator calibration signal, and the phase corrector is controlled by a phase corrector calibration signal.

Abstract: A calibration circuit, including a duty cycle correction circuit and a phase correction circuit and associated calibrating method, are provided. Firstly, a first duty cycle adjusted clock and a second duty cycle adjusted clock are generated by the duty cycle correction circuit based on a first input clock and a second input clock, respectively. Then, a first delay adjusted clock and a second delay adjusted clock are generated by the phase correction circuit based on a phase of the first duty cycle adjusted clock, and a detection signal is generated. The detection signal is related to a duty cycle of the first input clock, a duty cycle of the second input clock, and a phase difference between the second delay adjusted clock and the first delay adjusted clock. Later, the duty cycle correction circuit and the phase correction circuit are controlled in response to the detection signal.

Abstract: According to embodiments of the present invention, a phase-locked loop (PLL) may include circuitry to select a wide pulse width for the phase-frequency detector control signal when the PLL is in a frequency acquisition stage, a narrow pulse width for the phase-frequency detector control signal when the PLL is in a phase capture stage, and a wide pulse width of the phase-frequency detector control signal when the PLL is in a lock stage.

Abstract: According to embodiments of the present invention, a phase-locked loop (PLL) may include circuitry to select a wide pulse width for the phase-frequency detector control signal when the PLL is in a frequency acquisition stage, a narrow pulse width for the phase-frequency detector control signal when the PLL is in a phase capture stage, and a wide pulse width of the phase-frequency detector control signal when the PLL is in a lock stage.

Abstract: An input circuit includes a comparator circuit and a multi-reference circuit. The input circuit receives an input signal and generates an output signal as a function of the input signal and a reference signal received from the multi-reference circuit. The comparator circuit detects a crossing of the input signal relative to the reference signal and causes a corresponding transition of the output signal. In response to the transition of the output signal, the multi-reference circuit provides a different reference signal to the comparator circuit. The reference signals provided by the multi-reference circuit are selected to create hysteresis in the operation of the input circuit.

Abstract: Input/output (I/O) clock phase adjustment circuitry for use with I/O buffer circuitry of an integrated circuit chip. In one embodiment, an integrated circuit chip includes a phase adjustment circuit coupled to receive a system clock. The phase adjustment circuit generates an I/O clock coupled to be received by an I/O buffer circuit of an integrated circuit chip for I/O data transfers in a system. The phase adjustment circuit includes a phase locked loop (PLL) circuit coupled to receive the system clock through a first delay circuit. The I/O clock generated by the PLL circuit is received through a second delay circuit at a feedback clock input of the PLL circuit. The first and second delay circuits are used to control the phase of the I/O clock generated by the PLL circuit relative to the system clock. In one embodiment, a third delay circuit is included in an I/O data path of the I/O buffer circuit of the integrated circuit.

Abstract: An integrated circuit includes circuitry to test input/output (I/O) devices. Test data is provided to a loopback circuit that drives data through the output buffer to the pad, and back onto the integrated circuit through the input buffer. Separate clock signals, with varying phase, are generated for input synchronous elements and output synchronous elements. The phase, and the relative time delay between the separate clocks, changes as an external clock is varied. The external clock is varied to verify the performance parameters of the I/O devices. Each I/O device includes a shift register that can be coupled to the other buffers in a chain, or can be configured to be in a loop.

Abstract: An input circuit that receives an input signal and generates an output signal as a function of the input signal includes a latching circuit and a time blanking circuit. The latching circuit detects a transition of the input signal and causes a corresponding transition of the output signal. The time blanking circuit prevents the output signal from transitioning again for a predetermined period. This period begins with essentially no delay from the transition of the output signal, which can reduce the input circuit's sensitivity to high frequency noise that may be present on transitions of the input signal.

Abstract: An input circuit includes a comparator circuit and a multi-reference circuit. The input circuit receives an input signal and generates an output signal as a function of the input signal and a reference signal received from the multi-reference circuit. The comparator circuit detects a crossing of the input signal relative to the reference signal and causes a corresponding transition of the output signal. In response to the transition of the output signal, the multi-reference circuit provides a different reference signal to the comparator circuit. The reference signals provided by the multi-reference circuit are selected to create hysteresis in the operation of the input circuit.

Abstract: An input circuit that receives an input signal and generates an output signal as a function of the input signal includes a latching circuit and a time blanking circuit. The latching circuit detects a transition of the input signal and causes a corresponding transition of the output signal. The time blanking circuit prevents the output signal from transitioning again for a predetermined period. This period begins with essentially no delay from the transition of the output signal, which can reduce the input circuit's sensitivity to high frequency noise that may be present on transitions of the input signal.

Abstract: A dual mode clock input buffer is disclosed. The input buffer includes a first portion for handling a single ended high voltage clock signal and a second portion for handling a differential low voltage clock signal.

Abstract: A clocked sense amplifier flip flop includes at least one keeper unit to prevent the occurrence of a floating data node.