Systems and methods associated with reducing clock skew are disclosed. In some exemplary embodiments, there is provided circuitry associated with lock loop circuits such as a phase lock loop (PLL). Such circuitry may comprise output clock tree circuitry and phase averaging circuitry. In other exemplary embodiments, there is provided circuitry associated with delay lock loop (DLL) circuits. Such circuitry may comprise output clock tree circuitry and/or phase averaging circuitry.

The present invention provides a high-frequency delay-locked loop and a clock processing method for the high-frequency delay-locked loop. The high-frequency delay-locked loop comprises a DLL circuit and a DCC circuit that are sequentially connected in series, and a pulse generating circuit used for generating a clock having a fixed pulse width. The fixed pulse width is a high-level width of the clock having the fixed pulse width and not smaller than a minimum pulse width required by the DLL circuit. The fixed pulse width enables a low-level width of the clock having the fixed pulse width to be not smaller than the minimum pulse width required by the DLL circuit. The clock having the fixed pulse width is input into the DLL circuit.

A device includes a phase detector circuit, a charge pump circuit, a sample and hold circuit, a comparator, and a controller. The phase detector circuit detects a clock skew between a reference signal and an input signal. The charge pump circuit translates the clock skew into a voltage. A sample and hold circuit samples the voltage, at a first time, and maintain the sampled voltage until a second time. The comparator (i) detects a loop gain associated with the input signal based on the sampled voltage and the voltage at the second time and (ii) outputs a loop gain signal for adjustment of the input signal. The controller is coupled to the phase detector, the comparator, and the sample and hold circuit. The controller generates a plurality of control signals for automatically controlling operation of the phase detector, the comparator, and the sample and hold circuit.

An integrated circuit may include a receiver configured to receive a first data signal based on an m.sup.th (where m is an integer of 1 or more) transmitter preset setting among a plurality of transmitter preset settings through an external link, and equalize and sample the first data signal; a receiver setting table including a plurality of combinations including values of a plurality of parameters related to the receiver; and a receiver control circuit configured to sequentially select the plurality of combinations with reference to the receiver setting table and set the plurality of parameters with the selected combinations.

Described herein is an apparatus and a method for a low noise infinite radio frequency (RF) delayed-locked loop (DLL). The apparatus comprises a phase detector having a first input configured to receive a first RF signal, a second input, and an output; an infinite phase shifter having a first input configured to receive a second RF signal, an input bus, and an output connected to the second input of the phase detector; and a controller having a first input connected to the output of the phase detector and an output bus connected to the input bus of the infinite phase detector, wherein the output of the infinite phase shifter comprises a low noise signal in phase alignment with the first RF signal.

The present disclosure discloses a clock recovery circuit for a display, which recovers a clock from a clock data signal. The clock recovery circuit includes a clock recoverer configured to generate delayed clocks using a multi-stage delay chain including delay units; and a delay compensator configured to control a first delay time of a first delay unit to be the same as a second delay time of remaining delay units. The clock recovery circuit may compensate for a difference in delay time between the first delay time and the second delay time.

A phase-locked loop or delay locked loop provides a coarse alignment between an input clock and an output clock. A latch receiver circuit provides an indicator of a delay error between the input clock and the output clock. The delay error is used by a control circuit or state machine to adjust a fine delay that affects the output clock signal timing relative to the input clock signal. The fine delay is adjusted to minimize the timing difference between the output clock signal and the input clock signal.

A device for generating a duty cycle includes a converter, a corrector, and a control circuit. The converter is configured to generate a first output signal having a duty cycle to an output terminal according to an input signal. The corrector is coupled to the output terminal, and is configured to adjust the duty cycle of the first output signal according to a control signal. The converter is coupled in parallel with the corrector and between a first power source and a second power source. The control circuit is coupled to the output terminal, and is configured to generate the control signal according to the first output signal and a reference signal.

A semiconductor device may include a delay locked loop (DLL) control circuit coupled to an update trigger generator and a DLL update circuit. The DLL control circuit may receive an update trigger signal and an internal refresh signal and configured to activate the DLL update circuit responsive to an update trigger in the update trigger signal and deactivate the DLL update circuit responsive to an active internal refresh signal. The DLL update circuit may perform DLL update to one or more memory cell arrays when activated and not perform DLL update to the memory cell arrays when deactivated. The DLL control circuit may reactivate the DLL update circuit once the internal refresh signal becomes inactive. In other scenarios, once the DLL update circuit is deactivated, the DLL update circuit stays deactivated until the next update trigger in the update trigger signal.

A delay lock loop circuit includes a receiver, a delay line circuit, a clock signal generator and a phase detecting circuit. The receiver receives a clock signal and a reference voltage and generates a reference clock signal according to the clock signal and the reference voltage. The delay line circuit is coupled to the receiver and generates a delayed clock signal by delaying the reference clock signal with a delay indication signal. The clock signal generator generates an output clock signal according to the delayed clock signal. The phase detecting circuit generates a detection result by sampling the reference clock signal with a feedback clock signal generated by the output clock signal, and generates the delay indication signal according to a digital value of the detection result.