Abstract: Techniques and mechanisms for an integrated circuit (IC) chip to generate a clock signal for use by one or more resources of the IC chip. In an embodiment, a clock signal is generated with phase-locked loop (PLL) circuitry of an IC chip based on a cyclical signal which is provided to the IC chip by an external source. A supply voltage provided to the PLL circuitry is automatically updated based on one of a requested frequency for the clock signal, a frequency of the received cyclical signal, or a voltage of a control signal used by a voltage controlled oscillator of the PLL circuitry. In another embodiment, a series of incremental changes to a frequency of the clock signal is automatically performed according to a predefined overclocking scheme or underclocking scheme.

Abstract: An apparatus is provided for autonomous security and functional safety (FUSA) of clock and voltages. The apparatus may include: a multiplexer having a first input communicatively coupled to a pin to receive a first clock external to a die, and a second input coupled to an output of a divider; an oscillator to provide a second clock; and a counter coupled to an output of the multiplexer and the oscillator, wherein the counter is to operate with the second clock and is to determine a frequency of the first clock. The apparatus may further include a voltage monitor circuitry for monitoring voltage(s) for FUSA, a reference generator for FUSA, a duty cycle monitor for FUSA, a frequency degradation monitor for FUSA, and a phase error degradation monitor for FUSA.

Abstract: Some embodiments include apparatuses and methods of operating such apparatuses. One of the embodiments includes an input node to receive an input voltage, a circuit portion to generate first, second, and third voltages based on the input voltage, a comparator circuit to compare the first voltage with the second voltage to generate a first signal and to compare the first voltage with the third voltage to generate a second signal, and an output circuit to generate an output signal based on the first and second signals.

Abstract: An apparatus is provided which comprises: a frequency locked loop (FLL) comprising an oscillator including a plurality of delay stages, wherein an output of each delay stage is counted to determine a frequency of the FLL; and one or more circuitries coupled to the FLL to adjust a power supply to the FLL according to the determined frequency of the FLL.

Abstract: Some embodiments include apparatuses and methods of operating such apparatuses. One of the embodiments includes an input node to receive an input voltage, a circuit portion to generate first, second, and third voltages based on the input voltage, a comparator circuit to compare the first voltage with the second voltage to generate a first signal and to compare the first voltage with the third voltage to generate a second signal, and an output circuit to generate an output signal based on the first and second signals.

Abstract: Some embodiments include apparatuses and methods of operating such apparatuses. One of the embodiments includes an input node to receive an input voltage, a circuit portion to generate first, second, and third voltages based on the input voltage, a comparator circuit to compare the first voltage with the second voltage to generate a first signal and to compare the first voltage with the third voltage to generate a second signal, and an output circuit to generate an output signal based on the first and second signals.

Abstract: Described is an integrated circuit (IC) with apparatus for dynamically adapting a clock generator, e.g., phase locked loop (PLL), with respect to changes in power supply. The apparatus comprises: a voltage droop detector coupled to power supply node, the voltage droop detector to generate a digital code word representing voltage droop on the power supply node; and a PLL including a ring oscillator coupled to the power supply node, the ring oscillator to generate an output clock signal, the ring oscillator operable to adjust frequency of the output clock signal according to the digital code word.

Abstract: Described herein are apparatus, method, and system for re-synthesizing a clock signal. The apparatus comprises: a first logic unit to detect a rising edge of an input clock signal and for generating a rising edge of an output clock signal based on the detected rising edge of the input clock signal, the input clock signal having a non-50% duty cycle and a first period; and a second logic unit to compute a falling edge of the output clock signal according to the detected rising edge of the input clock signal, the falling edge of the output clock signal being near half of the first period.

Abstract: In some embodiments, a tight loop mode is provided in which most, if not all of, the clock distribution circuitry may be bypassed during an initial frequency lock stage.

Abstract: Described is an integrated circuit (IC) with a phase locked loop with capability of fast locking. The IC comprises: a node to provide a reference clock; a digitally controlled oscillator (DCO) to generate an output clock; a divider coupled to the DCO, the divider to divide the output clock and to generate a feedback clock; and control logic operable to reset the DCO and the divider, and operable to release reset in synchronization with the reference clock. An apparatus for zeroing phase error is provided which comprises a first node to provide a reference clock; a second node to provide a feedback clock; a time-to-digital converter, coupled to the first and second nodes, to measure phase error between the reference and feedback clocks; a digital loop filter; and a control unit to adjust the measured phase error, and to provide the adjusted phase error to the digital loop filter.

Abstract: Described herein are apparatus, method, and system for re-synthesizing a clock signal. The apparatus comprises: a first logic unit to detect a rising edge of an input clock signal and for generating a rising edge of an output clock signal based on the detected rising edge of the input clock signal, the input clock signal having a non-50% duty cycle and a first period; and a second logic unit to compute a falling edge of the output clock signal according to the detected rising edge of the input clock signal, the falling edge of the output clock signal being near half of the first period.

Abstract: In some embodiments, a tight loop mode is provided in which most, if not all of, the clock distribution circuitry may be bypassed during an initial frequency lock stage.

Abstract: In some embodiments, a tight loop mode is provided is which most, if not all of, the clock distribution circuitry may be bypassed during an initial frequency lock stage.

Abstract: Described is an integrated circuit (IC) with a phase locked loop with capability of fast locking. The IC comprises: a node to provide a reference clock; a digitally controlled oscillator (DCO) to generate an output clock; a divider coupled to the DCO, the divider to divide the output clock and to generate a feedback clock; and control logic operable to reset the DCO and the divider, and operable to release reset in synchronization with the reference clock. An apparatus for zeroing phase error is provided which comprises a first node to provide a reference clock; a second node to provide a feedback clock; a time-to-digital converter, coupled to the first and second nodes, to measure phase error between the reference and feedback clocks; a digital loop filter; and a control unit to adjust the measured phase error, and to provide the adjusted phase error to the digital loop filter.

Abstract: Described herein are apparatus, method, and system for re-synthesizing a clock signal. The apparatus comprises: a first logic unit to detect a rising edge of an input clock signal and for generating a rising edge of an output clock signal based on the detected rising edge of the input clock signal, the input clock signal having a non-50% duty cycle and a first period; and a second logic unit to compute a falling edge of the output clock signal according to the detected rising edge of the input clock signal, the falling edge of the output clock signal being near half of the first period.

Abstract: Described herein is apparatus and system for a digitally controlled oscillator (DCO). The apparatus comprises a voltage regulator to provide an adjustable power supply; and a DCO to generate an output clock signal, the DCO including one or more delay elements, each delay element operable to change its propagation delay via the adjustable power supply, wherein each delay element comprising an inverter with adjustable drive strength, wherein the inverter is powered by the adjustable power supply. The apparatus further comprises a digital controller to generate a first signal for instructing the voltage regulator to adjust a voltage level of the adjustable power supply.

Abstract: Described herein is apparatus and system for a digitally controlled oscillator (DCO). The apparatus comprises a voltage regulator to provide an adjustable power supply; and a DCO to generate an output clock signal, the DCO including one or more delay elements, each delay element operable to change its propagation delay via the adjustable power supply, wherein each delay element comprising an inverter with adjustable drive strength, wherein the inverter is powered by the adjustable power supply. The apparatus further comprises a digital controller to generate a first signal for instructing the voltage regulator to adjust a voltage level of the adjustable power supply.

Abstract: Described herein are apparatus, method, and system for re-synthesizing a clock signal. The apparatus comprises: a first logic unit to detect a rising edge of an input clock signal and for generating a rising edge of an output clock signal based on the detected rising edge of the input clock signal, the input clock signal having a non-50% duty cycle and a first period; and a second logic unit to compute a falling edge of the output clock signal according to the detected rising edge of the input clock signal, the falling edge of the output clock signal being near half of the first period.

Abstract: In some embodiments, a tight loop mode is provided is which most, if not all of, the clock distribution circuitry may be bypassed during an initial frequency lock stage.

Abstract: Apparatuses, systems, and a method for providing a PLL architecture with scalable power are described. In one embodiment, a system includes one or more processing units having a voltage regulator to generate a controllably adjustable supply voltage for a phase-locked loop (PLL) circuit coupled to the voltage regulator. The PLL circuit compares a phase and frequency of the reference clock signal to a phase and frequency of a generated feedback clock signal and generates an output signal based on the comparison. A tracking unit adjusts the controllably adjustable supply voltage based on an operating frequency of the system.