A delay selector includes a first multiplexer, a first inverter, a second multiplexer, and a second inverter. The first multiplexer has a first input coupled to an input of the delay selector. The first inverter is coupled between the input of the delay selector and a second input of the first multiplexer. The second multiplexer has a first input coupled to an output of the first multiplexer. The second inverter is coupled between the output of the first multiplexer and a second input of the second multiplexer.

A delay selector includes a first multiplexer, a first inverter, a second multiplexer, and a second inverter. The first multiplexer has a first input coupled to an input of the delay selector. The first inverter is coupled between the input of the delay selector and a second input of the first multiplexer. The second multiplexer has a first input coupled to an output of the first multiplexer. The second inverter is coupled between the output of the first multiplexer and a second input of the second multiplexer.

A method includes determining a phase error for a first clock signal and a second clock signal and determining an offset based on the phase error for the first clock signal and the second clock signal. The method also includes adding the offset to a phase of the first clock signal to produce a first adjusted clock signal and subtracting the offset from a phase of the second clock signal to produce a second adjusted clock signal. A phase error for the first adjusted clock signal and the second adjusted clock signal is smaller than the phase error for the first clock signal and the second clock signal.

A system includes a first park circuit having a signal input, an output, and a control input. The system also includes a first signal path having an input and an output, wherein the input of the first signal path is coupled to the output of the first park circuit. The system also includes a second park circuit having a signal input, an output, and a control input, wherein the signal input of the second park circuit is coupled to the output of the first signal path. The system further includes a second signal path having an input and an output, wherein the input of the second signal path is coupled to the output of the second park circuit.

A delay control device for controlling a delay circuit includes an oscillator, a counter, and an output control circuit. The oscillator generates an internal clock signal according to an external clock signal. The counter generates an accumulative signal according to the internal clock signal. The counter is selectively reset by the external clock signal. The output control circuit generates a delay indication signal according to the accumulative signal. The delay time of the delay circuit is adjusted according to the delay indication signal.

A delay control device for controlling a delay circuit includes an oscillator, a counter, and an output control circuit. The oscillator generates an internal clock signal according to an external clock signal. The counter generates an accumulative signal according to the internal clock signal. The counter is selectively reset by the external clock signal. The output control circuit generates a delay indication signal according to the accumulative signal. The delay time of the delay circuit is adjusted according to the delay indication signal.

A delay line includes first to n-th delay cells and a dummy delay cell, ‘n’ being an integer greater than or equal to 3. The first to n-th delay cells sequentially delay an input signal to respectively generate first to n-th output signals. The dummy delay cell delays the n-th output signal based on a delay control voltage to generate a dummy output signal. A delay amount of each of the first to (n−1)-th delay cells is adjusted on a basis of the delay control voltage and the output signal of the delay cell of a next stage of the corresponding delay cell, and a delay amount of the n-th delay cell is adjusted on a basis of the delay control voltage and the dummy output signal.

A delay line includes first to n-th delay cells and a dummy delay cell, ‘n’ being an integer greater than or equal to 3. The first to n-th delay cells sequentially delay an input signal to respectively generate first to n-th output signals. The dummy delay cell delays the n-th output signal based on a delay control voltage to generate a dummy output signal. A delay amount of each of the first to (n−1)-th delay cells is adjusted on a basis of the delay control voltage and the output signal of the delay cell of a next stage of the corresponding delay cell, and a delay amount of the n-th delay cell is adjusted on a basis of the delay control voltage and the dummy output signal.

An example digital to time converter includes: a first switch having a first terminal, a second terminal, and a first control terminal configured to receive a control signal. A second switch having a third terminal coupled to second terminal, a fourth terminal, and a second control terminal configured to receive a divided clock signal. A third switch having a fifth terminal coupled to the second terminal and the third terminal, a sixth terminal, and a third control terminal configured to receive an inverted version of divided clock signal. A fourth switch having a seventh terminal coupled to the second terminal, an eighth terminal, and a fourth control terminal configured to receive an inverted version of control signal. A fifth switch having a ninth terminal coupled to the eighth terminal and a fifth control terminal configured to receive the inverted divided clock signal. A capacitor coupled to the sixth terminal.

Various implementations described herein refer to a device having an integrated circuit with multiple tiers including a first tier and a second tier that are arranged vertically in a stacked configuration. The first tier may have first functional components, and the second tier may have second functional components. The device may have a three-dimensional (3D) connection within the first tier that allows for synchronous signaling between the first functional components and the second functional components for reducing latency between the multiple tiers including the first tier and the second tier.