A time-to-digital converter includes a delay unit into which a first signal is input and a sampling unit into which a second signal is input. The delay unit includes a first delay chain, a second delay chain, and a third delay chain that are connected in series in sequence. The delay unit delays the first signal. The first delay chain includes at least one first delayer. The second delay chain includes at least three second delayers. The third delay chain includes a third delayer. The delay duration of the first delayer and the delay duration of the third delayer are greater than delay duration of the second delayer. The sampling unit samples output signals of first delayers in the first delay chain, second delayers in the second delay chain, and third delayers in the third delay chain at a preset time point of the second signal.

A random number generator includes a ring oscillator, an inversion selecting circuit, and controller. The ring oscillator includes an inverter chain having at least one inverter and generates an output signal. The inversion selecting circuit controlling a phase inverter configured to invert a signal of the inverter chain. The controller is configured to operate the inversion selecting circuit to provide an output of the first phase inverter to the inverter chain during a first operation mode to measure a frequency of the ring oscillator and operate the inversion selecting circuit to not provide the output of the phase inverter during a second operation mode for generating a random number.

Apparatuses and methods of DLL measurement initialization are disclosed. An example apparatus includes: a clock enable circuit that provides a first clock signal having a half frequency of an input clock signal and second clock signals having a quarter frequency of the input clock signal; a coarse delay that provides the first clock signal with a coarse delay; a fine delay that provides the first clock signal with the coarse delay and a fine delay as an output clock signal; a model delay having a feedback delay equivalent to a sum of delays of an input stage and an output stage, and provides a feedback signal that is the output clock signal with the feedback delay; and a measurement initialization circuit that performs measurement initialization. The measurement initialization circuit includes synchronizers that receive the feedback signal and the second clock signals, and provide a stop signal to the coarse delay.

The present disclosure relates to the technical field of integrated circuits, and specifically to a delay-locked loop, a control method for a delay-locked loop, and an electronic device. The delay-locked loop includes: a secondary path configured to perform frequency division on an input clock signal to generate a frequency-divided clock signal, adjust the frequency-divided clock signal having a first frequency to obtain an output clock signal in a locking process of the delay-locked loop, and adjust the frequency-divided clock signal to make the frequency-divided clock signal have a second frequency when the delay-locked loop is locked in a standby state, wherein the second frequency is lower than the first frequency; and a primary path configured to output, when obtaining a target instruction, an output clock replica signal having a same phase as the output clock signal.

An apparatus has a plurality of multi-level comparison circuits, each coupled to a pair of wires in a three-wire communication link, a plurality of first-level clock recovery circuits and a second-level clock recovery circuit. Each multi-level comparison circuit provides a multibit signal as an output. Each first-level clock recovery circuit includes a plurality of first-level flipflops clocked by transitions in a multibit signal received from one multi-level comparison circuit of the plurality of multi-level comparison circuits, and a first delay circuit that delays an output of the each first-level clock recovery circuit to provide a first reset signal that resets the each first-level clock recovery circuit. The second-level clock recovery circuit includes a second-level flipflop clocked by transitions in the outputs of the plurality of first-level clock recovery circuits, and a second delay circuit that delays an output of the second-level clock recovery circuit to provide a second reset signal to the second-level flipflop.

A delay-locked loop (DLL) and corresponding method improve frequency of a chip. The DLL comprises a first programmable delay element configured to output a first clock, a second programmable delay element configured to output a second clock a phase detector. The phase detector includes a first clock input and a second clock input. The first and second programmable delay elements are further configured, in combination, to introduce a controllable skew between the first and second clocks. The DLL is configured to input the first and second clocks to the first and second clock inputs of the phase detector, respectively. The controllable skew is configured to improve the frequency of the chip.

Various implementations described herein are directed to a device with a voltage-controlled oscillator that receives an enable signal, receives a reset signal, and provides internal pulse signals including one or more coarse internal pulse signals and multiple fine internal pulse signals. The device may have a coarse sampler that receives the one or more coarse internal pulse signal and provides a coarse sampled output signal. The device may have a fine sampler that receives the multiple fine internal pulse signals and provides a fine sampled output signal.

Methods and apparatus for an arrayed time to digital converter (TDC) having matched delay line sampling. In embodiments, a TDC includes a coarse counter circuit to provide an event coarse timing measurement for an event, a coarse counter delivery network to deliver a count value in the coarse counter circuit to a memory storage element circuit, and an array of matched delay lines to provide an event fine timing measurement to the memory storage element circuit. An array of event sample signal generators can generate signals for the event and an array of encoders can encode fine timing measurement information from the memory storage element circuit, where an output of the encoder and the event coarse timing measurement information provide a timestamp for the event. A global delay-locked loop can incorporate a matched delay line coupled to the array of matched delay lines.

A circuit for delaying an electric signal (CI), comprises an input for the electric signal (CI); an input for a control signal (EI); a first storage element (U5) for storing the control signal; a delay element for delaying the electric signal; and an output for the delayed electric signal (CO). According to the invention, the electric signal is delayed, based on the stored control signal. The delay circuit is employed in a fast all-digital clock frequency adaptation circuit for voltage droop tolerance.

In an embodiment of the present disclosure, an integrated circuit includes: a first interface suitable for receiving first to N.sup.th data, where N is an even number equal to or greater than 2, and first to N.sup.th multi-phase clocks; an interface conversion circuit suitable for generating serial data based on the first to N.sup.th data that are received through the first interface, and generating a data strobe signal for strobing the serial data based on the first to N.sup.th multi-phase clocks that are received through the first interface; and a second interface suitable for receiving the serial data and the data strobe signal.