An example device comprising: first clock divider circuitry to be coupled to a first clock; first counter circuitry configured to be coupled to the first clock divider circuitry, the first counter circuitry configured to increment based on the first clock and a second clock; second clock divider circuitry to be coupled to a third clock; second counter circuitry configured to be coupled to the second clock divider circuitry, the second counter circuitry configured to increment based on the third clock and the second clock; and comparison circuitry coupled to the first and second counter circuitry.

An example device comprising: first clock divider circuitry to be coupled to a first clock; first counter circuitry configured to be coupled to the first clock divider circuitry, the first counter circuitry configured to increment based on the first clock and a second clock; second clock divider circuitry to be coupled to a third clock; second counter circuitry configured to be coupled to the second clock divider circuitry, the second counter circuitry configured to increment based on the third clock and the second clock; and comparison circuitry coupled to the first and second counter circuitry.

The present document relates to a timer which is counter-based and uses an asynchronous circuitry to improve the accuracy between the available clock cycles. In particular, a timer is presented which may comprise a first timer circuit configured to receive a clock signal and a trigger signal, wherein an edge of the trigger signal arrives after a first edge of the clock signal and before a second edge of the clock signal. The first timer circuit may be configured to determine, in a capture phase, a time offset interval for approximating a time interval between the first edge of the clock signal and the edge of the trigger signal.

The present document relates to a timer which is counter-based and uses an asynchronous circuitry to improve the accuracy between the available clock cycles. In particular, a timer is presented which may comprise a first timer circuit configured to receive a clock signal and a trigger signal, wherein an edge of the trigger signal arrives after a first edge of the clock signal and before a second edge of the clock signal. The first timer circuit may be configured to determine, in a capture phase, a time offset interval for approximating a time interval between the first edge of the clock signal and the edge of the trigger signal.

A data synthesizer includes a first input circuit, a second input circuit, and an output circuit. The first input circuit is configured to latch a first data under control of a first latch clock signal. The second input circuit is configured to latch a second data under control of the first latch clock signal. A phase of the first data is the same as a phase of the second data. The output circuit is connected to the first input circuit and the second input circuit. The output circuit is configured to output the first data and the second data in sequence.

A low-power phase interpolator circuit has a phase generator that receives an input clock signal and uses the input clock signal to generate multiple intermediate clock signals with different phase shifts; a phase rotator circuit that outputs phase-adjusted clock signals, each phase-adjusted clock signal having a phase that lies within a range bounded by phases of two of the intermediate clock signals; a frequency doubler circuit that receives a plurality of the phase-adjusted clock signals and outputs two frequency-doubled clock signals having a 180° phase difference; and a quadrature clock generation circuit that receives the two frequency-doubled clock signals and provides four output signals that include in-phase and quadrature versions of the two frequency-doubled clock signals.

A method for reception of a signal by a subscriber of a real-time network. The signal includes a signal clock having a signal clock frequency and the subscriber includes a counter, which has a counter clock with a counter clock frequency and which maps a local time of the subscriber. The method includes sampling the signal with a reception clock of a reception counter of the subscriber, the reception clock being derived from the counter clock, whereby the reception counter maps the local time of the subscriber, adapting a phase position of the reception clock to a phase position of the signal clock when said reception clock is derived from the counter clock, and sampling the signal at a reception clock frequency of the reception counter

A semiconductor chip capable of improving signal quality includes a host device, a first memory device which is spaced part from the host device and connected to the host device, a repeater module which is connected to the host device and the first memory device, and a second memory device which is spaced apart from the host device and connected to the repeater module. The first memory device receives a data signal from the host device and generates a recovery clock signal, using the data signal. The repeater module receives the recovery clock signal from the first memory device, receives a first input signal from the host device, and samples the first input signal on the basis of the recovery clock signal to generate a sampling signal. The second memory device receives the sampling signal.

A semiconductor chip capable of improving signal quality includes a host device, a first memory device which is spaced part from the host device and connected to the host device, a repeater module which is connected to the host device and the first memory device, and a second memory device which is spaced apart from the host device and connected to the repeater module. The first memory device receives a data signal from the host device and generates a recovery clock signal, using the data signal. The repeater module receives the recovery clock signal from the first memory device, receives a first input signal from the host device, and samples the first input signal on the basis of the recovery clock signal to generate a sampling signal. The second memory device receives the sampling signal.

An electronic device includes a dock dividing circuit configured to generate sampling clocks, alignment clocks and output clocks by dividing a frequency of a write clock; and a data alignment circuit configured to, in a first operation mode, receive input data having any one level among a first level to a fourth level and generate alignment data by aligning the input data in synchronization with the sampling clocks, the alignment clocks and the output clocks, and to, in a second operation mode, receive the input data having any one level of the first level and the fourth level and generate the alignment data by aligning the input data in synchronization with the sampling clocks, the alignment clocks and the output clocks.