A method includes connecting inputs of a first plurality of interpolation branches to a first clock signal, connecting inputs of a second plurality of interpolation branches to a second clock signal, and connecting inputs of a third plurality of interpolation branches to a third clock signal. The method also includes combining outputs of the first plurality of interpolation branches, the second plurality of interpolation branches, and the third plurality of interpolation branches to produce an output clock signal and adjusting a phase of the output clock signal by connecting an input of an interpolation branch of the third plurality of interpolation branches to the second clock signal.

A method includes connecting inputs of a first plurality of interpolation branches to a first clock signal, connecting inputs of a second plurality of interpolation branches to a second clock signal, and connecting inputs of a third plurality of interpolation branches to a third clock signal. The method also includes combining outputs of the first plurality of interpolation branches, the second plurality of interpolation branches, and the third plurality of interpolation branches to produce an output clock signal and adjusting a phase of the output clock signal by connecting an input of an interpolation branch of the third plurality of interpolation branches to the second clock signal.

Systems, methods, and devices are provided for a circuit for generating a pulse output having a controllable pulse width. Systems and methods may include a delay line having a plurality of stages. A delay per stage calculation circuit is configured to determine a per-stage delay of the delay line using a first clock input. A pulse generation circuit is configured to generate the pulse output using the delay line based on the per-stage delay using a second clock input, the second clock input having a lower frequency than the first clock input.

Systems, methods, and devices are provided for a circuit for generating a pulse output having a controllable pulse width. Systems and methods may include a delay line having a plurality of stages. A delay per stage calculation circuit is configured to determine a per-stage delay of the delay line using a first clock input. A pulse generation circuit is configured to generate the pulse output using the delay line based on the per-stage delay using a second clock input, the second clock input having a lower frequency than the first clock input.

An integrated circuit includes a clocking transistor, a first enabling transistor, a second enabling transistor, a branch-one transistor, a branch-two transistor, and a clock gating circuit. The first enabling transistor is coupled between the clocking transistor and a first node. The second enabling transistor is coupled between the clocking transistor and a second node. The branch-one transistor is coupled between a first power supply and the first node. The gate terminal of the branch-one transistor is electrically connected to the second node. The branch-two transistor is coupled between the first power supply and the second node. The gate terminal of the branch-two transistor is electrically connected to the first node. The clock gating circuit for generating a gated clock signal receives a latch output signal which is latched to a logic level of either a first node signal or a second node signal.

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.

A delay circuit provides a programmable delay and includes an input selector circuit to select between a loop delay output signal and an input signal. A loop delay circuit provides a loop delay to the input signal and supplies the loop delay output signal. The input signal can be recirculated through the loop delay circuit to extend the range of the delay. The input selector circuit selects the feedback signal during recirculation. A variable delay circuit provides a variable delay to the loop delay output signal after the recirculation is complete and supplies a variable delay output signal. An output selector circuit selects the output of the output selector circuit during the recirculation and selects the variable delay output signal after the recirculation is complete to thereby provide a delayed signal with the delay based on the loop delay, the number of loops of recirculation, and the variable delay.

A delay circuit provides a programmable delay and includes an input selector circuit to select between a loop delay output signal and an input signal. A loop delay circuit provides a loop delay to the input signal and supplies the loop delay output signal. The input signal can be recirculated through the loop delay circuit to extend the range of the delay. The input selector circuit selects the feedback signal during recirculation. A variable delay circuit provides a variable delay to the loop delay output signal after the recirculation is complete and supplies a variable delay output signal. An output selector circuit selects the output of the output selector circuit during the recirculation and selects the variable delay output signal after the recirculation is complete to thereby provide a delayed signal with the delay based on the loop delay, the number of loops of recirculation, and the variable delay.

A serializer clock delay optimization system comprising a multiplexer configured to receive two or more low-rate data signals and a multiplexer control signal. The multiplexer generates a full-rate data signal by combining the two or more low-rate data signals such that the multiplexer control signal determines sampling time of the low-rate data signals. A data monitor monitors and evaluates the full-rate data signal to generate a quality value representing the quality of the full-rate data signal. The quality of the full-rate data signal is based on the accuracy of the sampling time of the low-rate data signals. A delay controller processes the quality value to generate a delay control signal or value. A delay receives a clock signal and the delay control signal or value. Responsive to the delay control signal or value, the delay modifies the timing of the clock signal to create the multiplexer control signal.

A serializer clock delay optimization system comprising a multiplexer configured to receive two or more low-rate data signals and a multiplexer control signal. The multiplexer generates a full-rate data signal by combining the two or more low-rate data signals such that the multiplexer control signal determines sampling time of the low-rate data signals. A data monitor monitors and evaluates the full-rate data signal to generate a quality value representing the quality of the full-rate data signal. The quality of the full-rate data signal is based on the accuracy of the sampling time of the low-rate data signals. A delay controller processes the quality value to generate a delay control signal or value. A delay receives a clock signal and the delay control signal or value. Responsive to the delay control signal or value, the delay modifies the timing of the clock signal to create the multiplexer control signal.