Systems and methods for adaptively adjusting a slew rate of a dejitter buffer in a remote device in a distributed access architecture. The slew rate may be adjusted based on measurements of a fullness state of a buffer made over time. The measurements may be used to calculate a frequency offset value between the rate at which data leaves the buffer relative to the rate at which data enters the buffer and/or used to calculate a current working depth of the buffer. The adaptive slew rate adjustments may be based on the frequency offset value and/or the current working depth.

An electronic atomization device and a control circuit therefor are provided. The control circuit includes an airflow sensor, a power supply capacitor and a control chip including a logic controller, a unidirectional conduction tube and a switch tube, a power supply pin, an atomization pin and a ground pin; the logic controller is connected to a first end of the airflow sensor and a first end of the switch tube; and through the power supply pin, is connected to a first end of the power supply capacitor and a second end of the switch tube; and through the ground pin, is connected to a positive electrode of the unidirectional conduction tube, a second end of the airflow sensor and a second end of the power supply capacitor; a negative electrode of the unidirectional conduction tube, through the atomization pin, is connected to a third end of the switch tube.

A duty timing detector includes: a control logic, the control logic being configured to: receive an input toggle signal and an output toggle signal that corresponds to the input toggle signal, and generate a difference signal using a difference between a duty of the input toggle signal and a duty of the output toggle signal; a first low-pass filter configured to output a DC input voltage based on a pulse width of the input toggle signal; a second low-pass filter configured to output a DC difference voltage based on a pulse width of the difference signal; a compensation circuit configured to compensate the duty of the output toggle signal using the DC input voltage and the DC difference voltage; and an oscillator configured to generate a duty-compensated output toggle signal, and to provide the duty-compensated output toggle signal to the control logic.

A method includes performing a duty-cycle correction. The method can include inputting a signal to a duty-cycle correction circuit. The method can further include transferring the signal through an alternating current-coupling (AC-coupling) component of the duty-cycle correction circuit. The method can further include transferring the signal through a feedback circuit, wherein the feedback circuit comprises a plurality of resistors. The method can further include outputting a signal that includes a corrected duty-cycle with a particular amount of duty-cycle distortion.

A clock circuit includes a set of level shifters, a duty cycle adjustment circuit and a calibration circuit. The set of level shifters is configured to output a first set of phase clock signals having a first duty cycle. Each level shifter is configured to output a corresponding phase clock signal of the first set of phase clock signals. The duty cycle adjustment circuit is configured to generate a first clock output signal responsive to at least one of a first or second phase clock signal of the first set of phase clock signals or a set of control signals. The first clock output signal has a second duty cycle. The calibration circuit is configured to perform a duty cycle calibration of the second duty cycle based on an input duty cycle, and generate the set of control signals responsive to the duty cycle calibration of the second duty cycle.

A method includes performing a duty-cycle correction. The method can include inputting a signal to a duty-cycle correction circuit. The method can further include transferring the signal through an alternating current-coupling (AC-coupling) component of the duty-cycle correction circuit. The method can further include transferring the signal through a feedback circuit, wherein the feedback circuit comprises a plurality of resistors. The method can further include outputting a signal that includes a corrected duty-cycle with a particular amount of duty-cycle distortion.

A wobulated signal generator includes a chain of delay elements and control circuitry. The chain of delay elements includes first delay elements, second delay elements, and third delay elements. The control circuitry, in operation, enables a number of the first delay elements, disables a number of the third delay elements, and enables a selected number of the second delay elements, defining a period of time between two consecutive rising edges of a digital wobulated signal at an output of the wobulated signal generator. The control circuitry monitors an average frequency of the digitally wobulated signal, and selectively modifies the number of enabled first delay elements and the number of disabled third delay elements based on the monitored average frequency of the digitally wobulated signal.

The present disclosure provides a signal transmission method and a signal transmission device, which are applied to a digital circuit including a plurality of circuit modules connected in series, and each circuit module is configured to perform corresponding operation processing based on a first clock signal provided by a first clock. The method includes: under driving of a second clock signal provided by a second clock, transmitting a first signal output by a current circuit module to a target circuit module in response to reception of the first signal, the first signal is a signal output by the current circuit module when operating based on the first clock signal, transmission of the first signal is completed within a current clock cycle of the first clock, and a clock rate of the second clock is greater than that of the first clock.

A duty cycle correction device includes a duty cycle correction circuit and a duty cycle control circuit. The duty cycle correction circuit corrects a duty cycle of an input clock signal based on a duty cycle control signal and a duty cycle resolution control signal to generate an output clock signal. The duty cycle control circuit generates the duty cycle control signal by detecting a duty cycle of the output clock signal, generates a duty cycle correction completion signal when duty cycle correction is completed, and recorrects the duty cycle of the input clock signal by activating the duty cycle resolution control signal when the duty cycle correction completion signal is activated at an earlier timing than a reference time.

A delay circuit for a clock signal includes a first signal generator, a first inverting circuit, a second signal generator and a second inverting circuit. The first signal generator is configured to generate a plurality of first switching signals based on a delay code. The first inverting circuit includes a plurality of first inverters that are selectively turned on in response to the plurality of first switching signals, respectively, and is configured to adjust a first delay time for both of a first edge and a second edge of the clock signal. The second signal generator is configured to generate a plurality of second switching signals based on a duty code. The second inverting circuit includes a plurality of second pull-up units and a plurality of second pull-down units, respective ones of the plurality of second pull-up units or respective ones of the plurality of second pull-down units are selectively turned on in response to respective ones of the plurality of second switching signals. The second inverting circuit is configured to adjust a second delay time for the first edge, the second edge, or both of the first edge and the second edge of the clock signal.