An integrated circuit apparatus includes a pad via which an AC signal is inputted or outputted, a circuit that overlaps with the pad in the plan view, protective wiring provided between the pad and the circuit, and a resistor having one end electrically coupled to the protective wiring and another end electrically coupled to an electric charge discharging path.

An integrated circuit apparatus includes a pad via which an AC signal is inputted or outputted, a circuit that overlaps with the pad in the plan view, protective wiring provided between the pad and the circuit, and a resistor having one end electrically coupled to the protective wiring and another end electrically coupled to an electric charge discharging path.

A resonator device includes: a resonator element; a heat generating unit; a first package including a first base at which the resonator element and the heat generating unit are disposed, and a first lid bonded to the first base so as to accommodate the resonator element between the first lid and the first base; and a low emissivity layer that is disposed at an inner surface of the first lid and that has an emissivity lower than an emissivity of the first lid. In addition, a constituent material of the first lid is silicon, and the emissivity of the low emissivity layer at room temperature is less than 0.5.

A resonator device includes: a resonator element; a heat generating unit; a first package including a first base at which the resonator element and the heat generating unit are disposed, and a first lid bonded to the first base so as to accommodate the resonator element between the first lid and the first base; and a low emissivity layer that is disposed at an inner surface of the first lid and that has an emissivity lower than an emissivity of the first lid. In addition, a constituent material of the first lid is silicon, and the emissivity of the low emissivity layer at room temperature is less than 0.5.

The present disclosure relates to an electronic device comprising a first capacitor and a quartz crystal coupled in series between a first node and a second node; an inverter coupled between the first and second nodes; a first variable capacitor coupled between the first node and a third node; and a second variable capacitor coupled between the second node and the third node.

The present disclosure relates to an electronic device comprising a first capacitor and a quartz crystal coupled in series between a first node and a second node; an inverter coupled between the first and second nodes; a first variable capacitor coupled between the first node and a third node; and a second variable capacitor coupled between the second node and the third node.

A low power crystal oscillator circuit having a high power part and a low power part. Oscillation is initialized using the high power part. Once the crystal is under stable oscillation, the circuit switches to the low power part and continue operation for a long duration.

A circuit device includes a first terminal to be coupled to one end of a resonator, a second terminal to be coupled to another end of the resonator, an amplifying element configured to amplify a signal from the first terminal to output the signal amplified to the second terminal, a first resistor element disposed on a signal path between an input node and an output node of the amplifying element, a capacitance element disposed on a signal path between the first terminal and the input node, and a first switch element configured to switch electrical coupling between the input node and a ground.

The application discloses a method, for building an oscillator frequency adjustment lookup table in a transceiver, wherein the transceiver generates a clock according to a crystal oscillator external to the transceiver for transceiving data. The transceiver includes adjustable capacitor arrays assembly connected to the crystal oscillator, wherein when an equivalent capacitance of the adjustable capacitor assembly is a reference value, the crystal oscillator has a reference frequency, and when the equivalent capacitance changes relative to the reference value, the crystal oscillator correspondingly has a frequency offset relative to the reference frequency. The method includes: performing an interpolation operation according to a first value, a second value, and a third value of the equivalent capacitance, and the corresponding frequency variations, so as to obtain the frequency variations corresponding to a first sub-value between the first value and the second values.

The application discloses a method, for building an oscillator frequency adjustment lookup table in a transceiver, wherein the transceiver generates a clock according to a crystal oscillator external to the transceiver for transceiving data. The transceiver includes adjustable capacitor arrays assembly connected to the crystal oscillator, wherein when an equivalent capacitance of the adjustable capacitor assembly is a reference value, the crystal oscillator has a reference frequency, and when the equivalent capacitance changes relative to the reference value, the crystal oscillator correspondingly has a frequency offset relative to the reference frequency. The method includes: performing an interpolation operation according to a first value, a second value, and a third value of the equivalent capacitance, and the corresponding frequency variations, so as to obtain the frequency variations corresponding to a first sub-value between the first value and the second values.