Abstract: According to one general aspect, a method may include receiving a digital circuit model that includes models of a clock mesh and a plurality of logic circuits, each logic circuit associated with end-points of the logic circuit. The method may also include identifying a cluster of end-points, wherein the cluster is associated with a common version of the clock signal. The method may also include identifying an associated skew-schedule for each end-point. The method may include determining a timing slack and skew schedule for each end-point within the cluster. The method may include adjusting a clock-gater cell, based upon a common push/pull schedule associated with the cluster. The method may further include inserting, for at least one end-point of the cluster, a skew-buffer, wherein a variant of the skew-buffer for a respective end-point is based upon a difference between the end-point's skew schedule and the common push/pull schedule.

Abstract: According to one general aspect, a method may include receiving a digital circuit model that includes models of a clock mesh and a plurality of logic circuits, each logic circuit associated with end-points of the logic circuit. The method may also include identifying a cluster of end-points, wherein the cluster is associated with a common version of the clock signal. The method may also include identifying an associated skew-schedule for each end-point. The method may include determining a timing slack and skew schedule for each end-point within the cluster. The method may include adjusting a clock-gater cell, based upon a common push/pull schedule associated with the cluster. The method may further include inserting, for at least one end-point of the cluster, a skew-buffer, wherein a variant of the skew-buffer for a respective end-point is based upon a difference between the end-point's skew schedule and the common push/pull schedule.

Abstract: To implement a clock skew in an integrated circuit, end-point circuits are grouped into a push group and a pull group based on target latencies of local clock signals respectively driving the end-point circuits. The push group is driven by slow clock gates, and the pull group is driven by fast clock gates. The slow clock gates are determined such that delays of output clock signals are aligned to a base latency. The fast clock gates are determined such that delays of output clock signals are aligned to a minimum pull latency smaller than the base latency. Buffer networks are disposed between the fast and slow clock gates and the end-point circuits such that the local clock signals have the target latencies, respectively.

Abstract: A method and system for synchronizing video information derived from an asynchronously sampled video signals provide a mechanism for using asynchronous sampling in the front-end of digital video capture systems. A ratio between the sampling clock frequency and the source video clock frequency is computed via an all digital phase-lock loop (ADPLL) and either a video clock is generated from the ratio by another PLL, a number to clock converter or the ratio is used directly to provide digital synchronization information to downstream processing blocks. A sample rate converter (SRC) is provided in an interpolator that either acts as a sample position corrector at the same line rate as the received video, or by introducing an offset in the ADPLL, the video data can be converted to another line rate via the SRC.

Abstract: A method and system for video-synchronous audio clock generation from an asynchronously sampled video signal provides a mechanism for maintaining synchronization of audio sampling in digital video-audio systems. A ratio between the sampling clock frequency and an audio reference frequency clock is computed via an all digital phase-lock loop (ADPLL) and an audio clock is generated from the ratio by another PLL or a number to clock converter. In systems where a sampling clock to source video clock ratio has been computed for recovering a video signal, the audio ratio can be computed directly from the video ratio.

Abstract: A video quality adaptive variable-rate buffering method and system for stabilizing a sampled video signal reduces the buffer size required to compensate for line-to-line variations in an unstable video source. A video signal is sampled at a predetermined rate and decimated by a selectable decimation factor prior to buffering. By selecting different decimation factors, the effective length of the buffer is changed from short duration for stable input signals and to longer duration for unstable input signals. A video signal quality detector is employed to provide a selection input that adjusts the decimation factor and also the loop bandwidth of a clock generator that provides the output clock for the buffer, which is generated from the input signal via a phase-lock loop (PLL). The operation of the system automatically varies from highly responsive for stable video input signals to less responsive for unstable video input signals, providing improved stability in the video output.

Abstract: A method and apparatus for maintaining an ideal frequency ratio between numerically-controlled frequency sources provides a mechanism for maintaining coherence between multiple synchronization references where a known ideal rational relationship between the sources is known. Multiple numerically controlled oscillators (NCOs) generate the multiple synchronization references, which may be clock signals or numeric phase representations and the outputs of the NCOs are compared with a ratiometric frequency comparator that determines whether there is an error in the ratio between the NCO outputs. The frequency of one of the NCOs is then adjusted with a frequency correction factor provided by the ratiometric frequency comparator. The NCO inputs can represent ratios of the synchronization reference frequencies to a fixed reference clock and the NCOs clocked by the fixed reference clock.

Abstract: A method of gamma correction includes selecting lower and upper reference curves corresponding to selected reference gamma values. A gamma correction curve is generated from a corresponding gamma correction value and cross-correlated with the upper and lower reference curves to generate a corresponding set of cross-correlation factors. The set of cross-correlation factors are stored and indexed to the corresponding gamma value. An input value is received for gamma correction with the corresponding gamma value. Data from the upper and lower reference curves indexed by the input value are then operated one with the cross-correlation factors to generate a gamma corrected output value.

Abstract: Video decoder systems in which both the analog-to-digital converter and the composite decoder are driven by the stable sample clock, such as a crystal source. The outputs of the composite decoder are provided to a source rate converter, having an output that is provided to a digital output formatter. The digital output formatter is driven by the output clock, which may be locked to the source clock if desired. The output clock is developed by a clock generator which may be one of several different types, including a fractional N synthesizer, a direct digital synthesizer or a puncture clock.

Abstract: A video decoder in which the video source clock is generated entirely in the digital domain is disclosed herein. By creating a virtual version of the source clock in a numeric oscillator, the amount of noise in the system is substantially reduced. Furthermore, by transferring the digitized video signal, sampled with an asynchronous crystal clock, into the source clock domain, the accuracy of the brightness (amplitude) and color (phase) information can be greatly enhanced.

Abstract: A single-chip video decoder includes a primary data path for capturing and slicing vertical blanking interval information carried by a primary channel of video data received by a video decoder. Power control circuitry is operable during an inactive period of the video decoder to activate the primary data path during vertical blanking intervals of the received primary channel of video data for capturing and slicing the vertical blanking interval data; and to deactivate the primary data path between the vertical blanking interval and a subsequent vertical blanking interval of the received primary channel of video data to reduce power consumption. According to further inventive concepts, analog and/or digital circuitry which is unnecessary for capturing and slicing the vertical blanking information, including data paths processing secondary channels of video data, is deactivated during substantially the entire inactive period of the video decoder.