According to a clock generator, an oscillator outputs source oscillation clocks which are trimmed according to a trimming code. A first frequency divider generates X frequency division clocks by frequency-dividing the source oscillation clocks by a first frequency division ratio X. A trimming controller changes the trimming code within a period of the X frequency division clocks and supplies the changed trimming code to the oscillator.

To provide a filter circuit and a semiconductor device capable of preventing circuit malfunction even when power supply voltage fluctuates. A filter circuit includes: a latch circuit configured to latch a set signal input to a first input terminal and a reset signal input to a second input terminal, respectively; and a rise adjustment unit configured to make a rise time of the set signal or the reset signal at power-on shorter than a time specified by a time constant circuit arranged in a preceding stage of the latch circuit.

To provide a filter circuit and a semiconductor device capable of preventing circuit malfunction even when power supply voltage fluctuates. A filter circuit includes: a latch circuit configured to latch a set signal input to a first input terminal and a reset signal input to a second input terminal, respectively; and a rise adjustment unit configured to make a rise time of the set signal or the reset signal at power-on shorter than a time specified by a time constant circuit arranged in a preceding stage of the latch circuit.

The present disclosure provides a phase shifter, an antenna including the phase shifter, and a control method of the phase shifter. The phase shifter includes a first base substrate; a plurality of microstrip lines arranged on the first base substrate and configured to transmit an electromagnetic wave signal and apply a common voltage; a dielectric layer arranged on a side of the plurality of microstrip lines away from the first base substrate; and a plurality of separate voltage control layers correspondingly arranged with the plurality of microstrip lines respectively on a side of the dielectric layer away from the first base substrate. The separate voltage control layers are configured to apply a control voltage. A dielectric constant of the dielectric layer varies with the control voltage applied to the voltage control layers and the common voltage applied to the microstrip lines.

According to an embodiment, a semiconductor device includes a differential input circuit suitable for receiving first and second input signals respectively inputted to first and second input transistors, and outputting an output signal; a comparison circuit suitable for generating a first judge signal by comparing the output signal with a first comparison voltage, and generating a second judge signal by comparing the output signal with a second comparison voltage, in a calibration mode; an offset control circuit suitable for adjusting coarse codes and fine codes, according to the first and second judge signals; and an offset adjusting circuit suitable for adjusting a drivability of each of the first and second input transistors by a first strength, according to the coarse codes, and adjusting the drivability of each of the first and second input transistors by a second strength smaller than the first strength, according to the fine codes.

According to an embodiment, a semiconductor device includes a differential input circuit suitable for receiving first and second input signals respectively inputted to first and second input transistors, and outputting an output signal; a comparison circuit suitable for generating a first judge signal by comparing the output signal with a first comparison voltage, and generating a second judge signal by comparing the output signal with a second comparison voltage, in a calibration mode; an offset control circuit suitable for adjusting coarse codes and fine codes, according to the first and second judge signals; and an offset adjusting circuit suitable for adjusting a drivability of each of the first and second input transistors by a first strength, according to the coarse codes, and adjusting the drivability of each of the first and second input transistors by a second strength smaller than the first strength, according to the fine codes.

Methods, systems, and devices for compensating for kickback noise are described. A regulator may include an input circuit, a bias circuit, and an enable circuit. The regulator may be configured so that the enable circuit is positioned between the input circuit and the bias circuit. A balance resistor may be included in a path between an input of the regulator and a gate of a bias transistor included in the bias transistor. A size of the balance resistor may be based on an amount of charge drawn by the bias transistor during an activation event. Dimensions of the bias transistor may be modified based on an amount of charge drawn by the bias transistor during an activation event.

A system includes a level shifter coupled to a voltage source, a first transistor, and a second transistor. The system also includes a first current source coupled to the first transistor and the second transistor and configured to bias the first transistor and the second transistor. The system includes a slew detector coupled to the voltage source and to the first current source, where the slew detector is configured to detect a change in voltage of the voltage source, and further configured to provide current to the first current source responsive to detecting the change. The system also includes a second current source coupled in parallel to the first current source, where the second current source is configured to provide current to the first current source responsive to a control signal.

A system includes a level shifter coupled to a voltage source, a first transistor, and a second transistor. The system also includes a first current source coupled to the first transistor and the second transistor and configured to bias the first transistor and the second transistor. The system includes a slew detector coupled to the voltage source and to the first current source, where the slew detector is configured to detect a change in voltage of the voltage source, and further configured to provide current to the first current source responsive to detecting the change. The system also includes a second current source coupled in parallel to the first current source, where the second current source is configured to provide current to the first current source responsive to a control signal.

An oscillator circuit includes a current controller, a first capacitor and a second capacitor. A current generator is coupled to the current controller, the first and the second capacitor, and is operable, under control of a control signal of the current controller, provide charging currents. A comparator stage comprises a first input coupled to the first capacitor, a second input coupled to the second capacitor and a reference input to be supplied with the reference voltage. The comparator stage further includes an oscillator output to provide a clock signal based on a comparison of the capacitor voltages and the reference voltage, respectively. A modulation circuit comprises an oscillator input to input the clock signal, a reference output is connected to the current generator, and is operable to alternate between the charging currents, such that a charging current is provided as reference current at the reference output and at least one charging current is provided to alternately charge/discharge the first capacitor and the second capacitor to respective capacitor voltages.