A control arrangement is disclosed for providing a plurality of phase-coherent oscillating signals. It comprises a reference clock signal arrangement for providing a high-frequency reference clock signal and a plurality of modules each comprising a plurality of channels for providing the plurality of phase-coherent oscillating signals.

A control arrangement is disclosed for providing a plurality of phase-coherent oscillating signals. It comprises a reference clock signal arrangement for providing a high-frequency reference clock signal and a plurality of modules each comprising a plurality of channels for providing the plurality of phase-coherent oscillating signals.

Various embodiments include methods and systems for providing sleep clock edge-based global counter synchronization in a multiple-chiplet system. A system-on-a-chip (SoC) may include a first chiplet including a first chiplet global counter subsystem, and a second chiplet including a second chiplet global counter subsystem. The SoC may further include an interface bus communicatively coupling the first chiplet and the second chiplet, and a power management integrated circuit (PMIC) configured to supply a sleep clock to the first chiplet and the second chiplet. The first chiplet may be configured to transmit a global counter synchronization pulse trigger to the second chiplet across the interface bus. The second chiplet may be configured to load a global counter synchronization value into the second chiplet global counter subsystem at a sleep clock synchronization edge of the sleep clock in response to receiving the global counter synchronization pulse trigger.

Various embodiments include methods and systems for providing sleep clock edge-based global counter synchronization in a multiple-chiplet system. A system-on-a-chip (SoC) may include a first chiplet including a first chiplet global counter subsystem, and a second chiplet including a second chiplet global counter subsystem. The SoC may further include an interface bus communicatively coupling the first chiplet and the second chiplet, and a power management integrated circuit (PMIC) configured to supply a sleep clock to the first chiplet and the second chiplet. The first chiplet may be configured to transmit a global counter synchronization pulse trigger to the second chiplet across the interface bus. The second chiplet may be configured to load a global counter synchronization value into the second chiplet global counter subsystem at a sleep clock synchronization edge of the sleep clock in response to receiving the global counter synchronization pulse trigger.

Clock multiplexer circuitry outputs one of a first or second clock signal. First selection circuitry is connected in series with first counter circuitry. The first selection circuitry and the first counter circuitry receive a first clock signal and a first selection signal. A first control signal is generated based on the first clock signal and the first selection signal. Second selection circuitry is connected in series with second counter circuitry. The second selection circuitry and the second counter circuitry receive a second clock signal and a second selection signal. A second control signal is generated based on the second clock signal and the second selection signal. The output circuitry is connected to the first counter circuitry and the second counter circuitry. The output circuitry outputs one of the first clock signal and the second clock signal based on the first control signal and the second control signal.

Clock multiplexer circuitry outputs one of a first or second clock signal. First selection circuitry is connected in series with first counter circuitry. The first selection circuitry and the first counter circuitry receive a first clock signal and a first selection signal. A first control signal is generated based on the first clock signal and the first selection signal. Second selection circuitry is connected in series with second counter circuitry. The second selection circuitry and the second counter circuitry receive a second clock signal and a second selection signal. A second control signal is generated based on the second clock signal and the second selection signal. The output circuitry is connected to the first counter circuitry and the second counter circuitry. The output circuitry outputs one of the first clock signal and the second clock signal based on the first control signal and the second control signal.

Apparatus and methods for clock duty cycle correction and deskew are provided. In certain embodiments, a clock distribution circuit includes a clock driver that provides a differential clock signal to a clock slicer over a pair of transmission lines. The clock distribution circuit further includes a resistor-inductor-capacitor (RLC) tuning circuit for providing termination between the pair of transmission lines and a differential input to the clock slicer. The RLC tuning circuit includes a pair of resistor digital-to-analog converters (resistor DACs or RDACs) coupled to the pair of transmission lines and a pair of controllable inductor-capacitor (LC) circuits coupled to the pair of transmission lines.

Apparatus and methods for clock duty cycle correction and deskew are provided. In certain embodiments, a clock distribution circuit includes a clock driver that provides a differential clock signal to a clock slicer over a pair of transmission lines. The clock distribution circuit further includes a resistor-inductor-capacitor (RLC) tuning circuit for providing termination between the pair of transmission lines and a differential input to the clock slicer. The RLC tuning circuit includes a pair of resistor digital-to-analog converters (resistor DACs or RDACs) coupled to the pair of transmission lines and a pair of controllable inductor-capacitor (LC) circuits coupled to the pair of transmission lines.

Aspects of the present disclosure control aging of a signal path in an idle mode to mitigate aging. In one example, an input of the signal path is alternately parked low and high over multiple idle periods to balance the aging of devices (e.g., transistors) in the signal path. In another example, a clock signal (e.g., a clock signal with a low frequency) is input to the signal path during idle periods to balance the aging of devices (e.g., transistors) in the signal path. In another example, the input of the signal path is parked high or low during each idle period based on an aging pattern.

Aspects of the present disclosure control aging of a signal path in an idle mode to mitigate aging. In one example, an input of the signal path is alternately parked low and high over multiple idle periods to balance the aging of devices (e.g., transistors) in the signal path. In another example, a clock signal (e.g., a clock signal with a low frequency) is input to the signal path during idle periods to balance the aging of devices (e.g., transistors) in the signal path. In another example, the input of the signal path is parked high or low during each idle period based on an aging pattern.