A system for providing security in a computer system is provided. The system includes a ring oscillator including a plurality of logic gates connected in a ring configuration. The system also includes logic circuits to start the ring oscillator by a ring-enable signal and a clock signal provided to a clock input of at least one controlled logic gate of the plurality of logic gates. The clock signal controls the at least one controlled logic gate and thereby synchronizes the ring oscillator to the clock signal. The clock signal is provided to the clock input for a predetermined warm-up duration, and thereafter, the logic circuits restart and operate the ring oscillator without the clock signal.

A clock generation circuit having a deskew function and a semiconductor integrated circuit device including the same are provided. The clock generation circuit includes a clock gating circuit configured to gate an input clock signal based on a first waveform signal to generate a first output signal, a flip-flop configured to receive the input clock signal and a second waveform signal and to generate a second output signal, and an OR circuit configured to perform an OR operation on the first output signal and the second output signal to generate an output clock signal having a period which is N times a period of the input clock signal.

In a monitor circuit, a data signal is propagated from an FF to another FF via a data delay circuit. The data delay circuit selects any one from among data paths that delay the data signal in accordance with a selection signal. A clock signal that is input to the FF is input to the other FF via a clock delay circuit. The clock delay circuit selects any one from among clock paths that delay the clock signal in accordance with another selection signal.

A semiconductor apparatus includes a transmission device and a receiving device. The transmission device generates an output signal from a transmission signal in synchronization with a clock signal. The receiving device generates a reception signal from the output signal in synchronization with the clock signal and a delayed clock signal generated by delaying the clock signal by a preset time, based on an operating speed of the semiconductor apparatus.

A correction circuit includes a first detection unit, a second detection unit, a delay unit, and a waveform shaping unit. The first detection unit is configured to measure a first period of a high level of a first clock. The second detection unit is configured to measure a second period of a high level of a second clock that is complementary to the first clock. The delay unit is configured to generate a first delay clock and a second delay clock according to a difference between the first period and the second period. The waveform shaping unit is configured to generate a third clock having a logic level which is switched based on an edge of the first delay clock and an edge of the second delay clock.

A phase-locked loop (PLL) includes a selection circuit including a plurality of inputs, each input to receive a separate reference clock. A programmable reference clock divider divides down the reference clock selected by the selection circuit to generate a divided down reference clock. A feedback clock divider divides down an output clock from the PLL to generate a feedback clock. A time-to-digital converter (TDC) generates a digital output value based on a phase difference between the divided down reference clock and the feedback clock. A circuit including a finite state machine, causes, responsive to an indication to change reference clocks, the reference clock divider and the feedback clock divider to be held in a reset state, the divide ratio of the reference clock divider to be modified, and then to release the reset state.

Methods, systems, and devices for shifting voltage levels of electrical signals and more specifically for boosted high-speed level shifting are described. A boosted level shifter may include a driver circuit that generates a drive signal having a greater voltage swing than an input signal, and the drive signal may drive the gate of a pull-up transistor within the boosted level shifter. The lower bound of the drive signal may in some cases be a negative voltage. Driving the pull-up transistor with a drive signal having a greater voltage swing than the input signal may improve the operational speed and current-sourcing capability of the pull-up transistor, which may provide speed and efficiency benefits.

One embodiment relates to an integrated circuit with an array of modular physical layer (PHY) slice circuits that are configured into multiple synchronous groups. Each synchronous group receives a delayed synchronous pulse signal provided by a chain of synchronous delay circuits. Another embodiment relates to an array of modular PHY slice circuits, each of which includes a manager circuit that manages the modular PHY slice circuit, a remap circuit that remaps interconnect redundancy, and an input-output module that provides outbound control and data streams and receives inbound control and data streams.

A clock generation circuit having a deskew function and a semiconductor integrated circuit device including the same are provided. The clock generation circuit includes a clock gating circuit configured to gate an input clock signal based on a first waveform signal to generate a first output signal, a flip-flop configured to receive the input clock signal and a second waveform signal and to generate a second output signal, and an OR circuit configured to perform an OR operation on the first output signal and the second output signal to generate an output clock signal having a period which is N times a period of the input clock signal.

In certain aspects, a clock generation circuit couples to a first clock having a first duty cycle and a second clock having the first duty cycle. The second clock lags the first clock by 90 degrees in phase. The clock generation circuit is configured to couple the output terminal to a ground when the first clock and the second clock both are at logic high and decouple the output terminal from the ground when at least one of the first clock and the second clock is at logic low and couple a supply voltage to the output terminal only when the first clock is at logic low and decouple the supply voltage from the output terminal when the first clock is at logic high. The clock generation circuit generates clock signals having a second duty cycle.