In some embodiments, a method may include receiving an input signal at an input stage of a circuit and amplifying the input signal using an amplifier of the circuit to produce a level-shifted output signal. The method may further include selectively controlling switches of an active load coupled to the input stage based on the level-shifted output signal to turn off current flow between transitions in the input signal.

A method includes providing a resonant attenuation circuit comprising a first active shorting device connected to a proximal end of an inductive element and a second active shorting device connected to a distal end of the inductive element. The method also includes providing a first control signal to the first active shorting device that places the first active shorting device in a region of operation where incremental increases or decreases in voltage change a shorting impedance of the second active shorting device. A signal attenuator includes a signal propagation path and a plurality of shorting units sequentially attached to the signal propagation path and a control circuit configured to control a level of attenuation provided by each shorting unit. The control circuit and a corresponding method activates subsequent shorting units only if all previous shorting units are at least partially activated.

A clock circuit and control method thereof to avoid missing the clock signal generated by the clock circuit when the generated clock signal is synced with an external clock signal, wherein the clock circuit comprises a current compensation circuit and a current control circuit. The clock signal is generated by alternately charging and discharging a capacitor with a charging current based on a sync current and a compensating current when an external clock signal is detected. The compensating current is generated based on a frequency of the external clock signal, and the sync current is provided based on a phase difference between the generated clock signal by the clock circuit and the external clock signal.

A clock circuit and control method thereof to avoid missing the clock signal generated by the clock circuit when the generated clock signal is synced with an external clock signal, wherein the clock circuit comprises a current compensation circuit and a current control circuit. The clock signal is generated by alternately charging and discharging a capacitor with a charging current based on a sync current and a compensating current when an external clock signal is detected. The compensating current is generated based on a frequency of the external clock signal, and the sync current is provided based on a phase difference between the generated clock signal by the clock circuit and the external clock signal.

A level shifting circuit operates at a high voltage level without stressing the transistors. The circuit has the ability to swing between large supply domains. Multiple output voltage levels are supported for the level shifted signal. Additionally, output nodes are stably driven to supply voltage levels that do not vary with respect to process corner and temperature.

A level shifter circuit is configured to receive first and second complementary input signals. Each of the first and second complementary input signals have a value of either a first supply voltage or a first reference voltage. The level shifter further includes a strong latch circuit operable in response to the first and second complementary input signals to drive one of first and second output signals to a second supply voltage and includes a weak latch circuit operable to drive the other of the first and second output signals to a second reference voltage.

A level shifter circuit with improved time response and a control method thereof are disclosed herein. The level shifter circuit includes the output stage circuit of a level shifter and a booster circuit. The output stage circuit of the level shifter includes a first pass switch configured to transfer a voltage level of the first power supply of the level shifter to an output node, and a second pass switch connected between a second power supply and the first pass switch. The booster circuit accelerates the switching operation of the level shifter by accelerating a time response during the turning on or off operation of the first pass switch using charge sharing between a first capacitor and the parasitic capacitance of the control node of the first pass switch, which occurs via a first switch.

An oscillator circuit (100) comprises a crystal oscillator (10) arranged to generate an oscillation signal, a bias current generator (20) arranged to supply a bias current to the crystal oscillator (10), and a feedback stage (30) arranged to generate a feedback signal in response to an amplitude of the oscillation signal reaching an amplitude threshold. The bias current generator (20) is arranged to: in response to a supply of power to the oscillator circuit (100) being switched on, generate the bias current at an increasing level commencing from a first level; in response to the feedback signal, terminate the increasing; and during subsequent oscillation of the crystal oscillator (10), supply the bias current at a second level dependent on a final level of the bias current reached when the increasing is terminated.

A clock signal generating circuit includes a detecting circuit configured to generate a first voltage based on first and second clock signals and adjust a level of the first voltage in response to first and second setup voltages and a resistance variable code, a comparing circuit configured to compare the first voltage and a reference voltage and output a check signal according to a comparison result, a code generating circuit configured to perform a first modulation operation for determining the resistance variable code in response to the check signal and perform a second modulation operation for determining a control code in response to the check signal, and an oscillator configured to adjust an amplitude of the first and second clock signals in response to the control code, and output the first and second clock signals having the adjusted amplitude.

A self-oscillation circuit includes a vibration unit having a vibrator, a positive feedback path which positively feeds back a signal based on vibration of the vibrator to the vibration unit, a negative feedback circuit which generates a pulse-width-modulated signal having a frequency lower than a vibration frequency of the vibrator, based on a comparison result between a value corresponding to an amplitude of the vibrator and a reference value, and a switch circuit which switches connection and disconnection of the positive feedback path to the vibration unit by the pulse-width-modulated signal.