A clock signal generation circuit for a switched capacitor circuit with a chopping function unit includes: first and second synchronous clock circuits that generate first and second synchronous clock signals, respectively; an edge signal generation circuit that generates one or more rise and fall edge signals by delaying the first synchronous clock signal; a first clock generator that generate a first clock signal group for driving the switched capacitor circuit; and a second clock generator that generates a second clock signal group for driving the chopping function unit. Frequencies of the first and second clock signal groups are respectively defined by the first and second synchronous clock circuits. Rise and fall edges of the first and second clock signal groups are defined by the edge signal generation circuit.

Apparatuses and methods to relay a clock signal to clock loads are presented. An apparatus includes a clock spine to conduct a clocking signal. The clock spine includes multiple taps points distributed unevenly on the clock spine. The apparatus further includes multiple clock buffers. Each of the multiple clock buffers is connected to a corresponding one of the multiple tap points. The method includes conducting a clocking signal on a clock spine having multiple taps points. The multiple tap points are distributed unevenly on the clock spine. The method further includes buffering the clocking signal at each of the multiple tap points. Another method includes forming a clock spine to conduct a clocking signal. The clock spine includes multiple taps points. The multiple tap points are distributed unevenly on the clock spine. The method further includes forming multiple clock buffers.

A signal may be arbitrarily delayed in discrete steps by an arbitrary delay buffer having an analog delay and a digital delay. An analog delay may have a number of selectable delay stages (e.g. ring oscillator with VCDL stages). A digital delay may have rising and falling edge detectors, resettable ring oscillators that oscillate in response to rising or falling edges and counters to count oscillations and generate rising and falling edge delay signals when oscillation counts reach rising and falling edge delay counts. A resettable ring oscillator may have a resettable stage (e.g. VCDL) that may be enabled and disabled. Selection of one or both digital and analog delays and respective delay times may be based on one or more characteristics. For example, an analog delay may delay an input signal or a delayed input signal received from the digital delay based on input signal frequency or total delay.

A clock generator that outputs multiphase clocks comprises a ring oscillator that includes a plurality of inverter circuits connected in a circular pattern and outputs, from the inverter circuits, clocks provided with a delay time based on a delay control signal, a first frequency divider that divides an injection clock by a first value and outputs the clock as a reference clock, a second frequency divider that divides one of the multiphase clocks by a second value and outputs the clock as a comparison clock, and a frequency comparator that compares frequencies of the reference clock and the comparison clock and output the delay control signal based on a result of the comparison. The ring oscillator is configured to adjust the delay time based on the delay control signal.

The present disclosure provides a low-jitter frequency division clock circuit, including: a clock control signal generation circuit, to generate clock signals having different phases; a low-level narrow pulse width clock control signal generation circuit, to generate a low-level narrow pulse width clock control signal; a high-level narrow pulse width clock control signal generation circuit, to generate a high-level narrow pulse width clock control signal; and a frequency division clock generation circuit, to generate a frequency division clock signal according to low-level narrow pulse width clock control signal and high-level narrow pulse width clock control signal. The delay from a clock input end to an output end of low-jitter frequency division clock circuit is up to three logic gates. Compared with traditional divide-by-2 frequency division clock circuits based on D-flip-flop, the low-jitter frequency division clock circuit of the present disclosure has fewer logic gates, a shorter delay, and lower jitter.

The present disclosure provides a low-jitter frequency division clock circuit, including: a clock control signal generation circuit, to generate clock signals having different phases; a low-level narrow pulse width clock control signal generation circuit, to generate a low-level narrow pulse width clock control signal; a high-level narrow pulse width clock control signal generation circuit, to generate a high-level narrow pulse width clock control signal; and a frequency division clock generation circuit, to generate a frequency division clock signal according to low-level narrow pulse width clock control signal and high-level narrow pulse width clock control signal. The delay from a clock input end to an output end of low-jitter frequency division clock circuit is up to three logic gates. Compared with traditional divide-by-2 frequency division clock circuits based on D-flip-flop, the low-jitter frequency division clock circuit of the present disclosure has fewer logic gates, a shorter delay, and lower jitter.

A clock signal generation circuit for a switched capacitor circuit with a chopping function unit includes: first and second synchronous clock circuits that generate first and second synchronous clock signals, respectively; an edge signal generation circuit that generates one or more rise and fall edge signals by delaying the first synchronous clock signal; a first clock generator that generate a first clock signal group for driving the switched capacitor circuit; and a second clock generator that generates a second clock signal group for driving the chopping function unit. Frequencies of the first and second clock signal groups are respectively defined by the first and second synchronous clock circuits. Rise and fall edges of the first and second clock signal groups are defined by the edge signal generation circuit.

A semiconductor device includes: a first semiconductor die and a second semiconductor die connected on the first semiconductor die, in which the first semiconductor die includes buffers in a second-stage configuration to an Nth-stage configuration (N being an integer of 3 or more) in a clock tree structure, and the second semiconductor die includes a logic circuit electrically connected to the buffer in the Nth-stage configuration.

A signal may be arbitrarily delayed in discrete steps by an arbitrary delay buffer having an analog delay and a digital delay. An analog delay may have a number of selectable delay stages (e.g. ring oscillator with VCDL stages). A digital delay may have rising and falling edge detectors, resettable ring oscillators that oscillate in response to rising or falling edges and counters to count oscillations and generate rising and falling edge delay signals when oscillation counts reach rising and falling edge delay counts. A resettable ring oscillator may have a resettable stage (e.g. VCDL) that may be enabled and disabled. Selection of one or both digital and analog delays and respective delay times may be based on one or more characteristics. For example, an analog delay may delay an input signal or a delayed input signal received from the digital delay based on input signal frequency or total delay.

A circuitry for generating output clock signals with increasing phase delays comprises: an input receiving input clock signals with increasing phase delays, wherein the output clock signals are twice as many as the input clock signals; logic components connected in a loop with an output from a component connected as a first input to a following component, wherein the output is further connected as a second input to an oppositely positioned component; wherein each component receives the first, the second and a third input signal; wherein pairs of oppositely positioned components receive a common input clock signal and mask out the third input clock signal based on logic state of first and second input signals such that the outputs are phase shifted by 180 degrees; and wherein the circuitry outputs the output clock signals based on outputs from each component.