Embodiments herein describe a self-biased divider for a clock in an integrated circuit. In one embodiment, the clock includes a VCO that generates a clock signal that is output to the self-biased divider. However, because the VCO may generate an analog clocking signal (e.g., a low amplitude sine wave of unknown common mode) to reduce jitter, the amplitude can vary which means it may not sufficiently track CMOS parameters. The clocking signals generated by the self-biased divider are used as feedback signals for DC biasing (or DC leveling). In this manner, the divider is referred to a self-biased divider since signals generated by the divider are used to perform DC biasing/leveling.

Techniques and apparatus for reducing low frequency power supply spurs in clock signals in a clock distribution network. One example circuit for clock distribution generally includes a plurality of logic inverters coupled in series and configured to drive a clock signal and a current-starved inverter coupled in parallel (or in series) with a logic inverter in the plurality of logic inverters.

A clock selector circuit includes a first input for receiving a reference clock signal having a reference frequency, a second input for receiving an offset clock signal having an offset frequency, a clock output for outputting the reference or offset clock signal, and switching circuitry. The switching circuitry includes a switching input and sign detector circuitry that outputs a sign signal indicating whether the reference clock signal is leading the offset clock signal in phase. In response to receiving a switching signal, the switching circuitry detects when like edges of the reference clock signal and the offset clock signal are aligned to within a predetermined tolerance, with the new signal leading the current signal if the offset frequency is lower than the reference frequency, or with the new clock signal trailing the current clock signal if not. In response, the switching circuitry switches to outputting the new clock signal.

A multiple operating-mode comparator system can be useful for high bandwidth and low power automated testing. The system can include a gain stage configured to drive a high impedance input of a comparator output stage, wherein the gain stage includes a differential switching stage coupled to an adjustable impedance circuit, and an impedance magnitude characteristic of the adjustable impedance circuit corresponds to a bandwidth characteristic of the gain stage. The comparator output stage can include a buffer circuit coupled to a low impedance comparator output node. The buffer circuit can provide a reference voltage for a switched output signal at the output node in a higher speed mode, and the buffer circuit can provide the switched output signal at the output node in a lower power mode.

A multiple operating-mode comparator system can be useful for high bandwidth and low power automated testing. The system can include a gain stage configured to drive a high impedance input of a comparator output stage, wherein the gain stage includes a differential switching stage coupled to an adjustable impedance circuit, and an impedance magnitude characteristic of the adjustable impedance circuit corresponds to a bandwidth characteristic of the gain stage. The comparator output stage can include a buffer circuit coupled to a low impedance comparator output node. The buffer circuit can provide a reference voltage for a switched output signal at the output node in a higher speed mode, and the buffer circuit can provide the switched output signal at the output node in a lower power mode.

A system for generating a sub-harmonically injection locked phase interpolated output signal. The system comprises ring oscillator (RO) circuitry to generate an output oscillator signal in response to a periodic input signal. The RO circuitry includes a plurality of differential delay RO stages interconnected in cascade within a closed loop, where each RO stage is configured to establish a corresponding delayed version of the output oscillator signal successively shifted in phase by a predetermined phase difference based on a predetermined interpolation mapping scheme. The system further comprises signal injection circuitry coupled to the RO circuitry to apply a first signal having a first input phase and a second signal having a second input phase to the plurality of differential delay RO stages based on the predetermined interpolation mapping scheme to lock a frequency of the output oscillator signal at one half the frequency of the periodic input signal.

A system for generating a sub-harmonically injection locked phase interpolated output signal. The system comprises ring oscillator (RO) circuitry to generate an output oscillator signal in response to a periodic input signal. The RO circuitry includes a plurality of differential delay RO stages interconnected in cascade within a closed loop, where each RO stage is configured to establish a corresponding delayed version of the output oscillator signal successively shifted in phase by a predetermined phase difference based on a predetermined interpolation mapping scheme. The system further comprises signal injection circuitry coupled to the RO circuitry to apply a first signal having a first input phase and a second signal having a second input phase to the plurality of differential delay RO stages based on the predetermined interpolation mapping scheme to lock a frequency of the output oscillator signal at one half the frequency of the periodic input signal.

A voltage-controlled delay buffer includes a plurality of inverters configured in a cascade topology to receive an input signal from a source circuit and output an output signal to an output circuit. The plurality of inverters includes a voltage-controlled inverter controlled by a control signal having a first voltage and a second voltage. The voltage-controlled inverter includes a PMOS transistor configured to assist a low-to-high transition of an outgoing signal, and an NMOS transistor configured to assist a high-to-low transition of the outgoing signal. Two varactors, one forward connected and the other backward connected are configured to adjust a delay of a transition of an incoming signal. Another two varactors, one forward connected and the other backward connected, configured to adjust a delay of a transition of the outgoing signal in accordance with the first voltage and the second voltage.

A voltage-controlled delay buffer includes a plurality of inverters configured in a cascade topology to receive an input signal from a source circuit and output an output signal to an output circuit. The plurality of inverters includes a voltage-controlled inverter controlled by a control signal having a first voltage and a second voltage. The voltage-controlled inverter includes a PMOS transistor configured to assist a low-to-high transition of an outgoing signal, and an NMOS transistor configured to assist a high-to-low transition of the outgoing signal. Two varactors, one forward connected and the other backward connected are configured to adjust a delay of a transition of an incoming signal. Another two varactors, one forward connected and the other backward connected, configured to adjust a delay of a transition of the outgoing signal in accordance with the first voltage and the second voltage.

The application provides a dispersed carrier phase-shifting method and system. The method includes connecting at least two power modules to form a modular system; each power module including a control module for sampling at least twice a common state variate, signs of slopes of the common state variate at a first and second sampling time are opposite, and a reference time of the first sampling time for each control module is the same; and regulating a carrier frequency of the power module according to a relative size between a sampled values at the first and second sampling time. According to embodiments herein, carrier phase-shifting of modular system may be implemented without communication between respective modules. Under closed-loop control, optimal carrier phase-shifting can be automatically achieved under various duty ratios, thereby having good stability.