A temperature sensor supplying a measurement signal varying linearly to within 10% as a function of the temperature at least over a temperature range, including an oscillator supplied by a supply voltage and supplying a first oscillating signal, said oscillator including first MOS transistors, the voltage at each internal node of the oscillator having a dynamic range equal to the supply voltage, the measuring signal corresponding to the supply voltage.

A switching transformer includes a drive amplifier configured to output an input signal by amplifying a source signal, a primary circuit including a set of primary inductors, a primary switch, and a first primary connecting wire, the set of primary inductors being configured to receive the input signal at a first primary input/output terminal, the primary switch being configured to adjust an inductance of the set of primary inductors based on a first switching operation, and the first primary connecting wire being configured to electrically connect the first primary input/output terminal to an end of the primary switch, and a secondary circuit configured to mutually electrically couple to the first primary connecting wire and at least one primary inductor among the set of primary inductors.

An integrated circuit includes a semiconductor substrate and a plurality of circuit elements in or on the substrate. The circuit elements are defined by standard layout cells selected from a cell library. The circuit elements including a plurality of flip-flops. Each flip-flop has a data input terminal, a data output terminal, a clock input terminal, and a clock output terminal. A first one of the flip-flops directly abuts a second flip-flop such that the clock output terminal of the first flip-flop electrically connects with the clock input terminal of the second flip-flop.

A circuit includes an oscillator having a driver and a resonator. The driver receives a supply voltage at a supply input and provides a drive output to drive the resonator to generate an oscillator output signal. A power converter receives an input voltage and generates the supply voltage to the supply input of the driver. A temperature tracking device in the power converter controls the voltage level of the supply voltage to the supply input of the driver based on temperature such that the supply voltage varies inversely to the temperature of the circuit.

A circuit includes an oscillator having a driver and a resonator. The driver receives a supply voltage at a supply input and provides a drive output to drive the resonator to generate an oscillator output signal. A power converter receives an input voltage and generates the supply voltage to the supply input of the driver. A temperature tracking device in the power converter controls the voltage level of the supply voltage to the supply input of the driver based on temperature such that the supply voltage varies inversely to the temperature of the circuit.

A charge pump method and apparatus is described having various aspects. Noise injection from a charge pump to other circuits may be reduced by limiting both positive and negative clock transition rates, as well as by limiting drive currents within clock generator driver circuits, and also by increasing a control node AC impedance of certain transfer capacitor coupling switches. A single-phase clock may be used to control as many as all active switches within a charge pump, and capacitive coupling may simplify biasing and timing for clock signals controlling transfer capacitor coupling switches. Any combination of such aspects of the method or apparatus may be employed to quiet and/or simplify charge pump designs over a wide range of charge pump architectures.

A semiconductor device includes a resistor element connected to one and another end of a crystal oscillator, and an adjustable current type inverter element having an input connected to one end of the resistor element and an output connected to another end of the resistor element. A first capacitor element is connected to the input of the inverter element and to ground, and a second capacitor element has one end connected to ground. A first switching element switches a connection state of the one end of the first capacitor element and another end of the second capacitor element. A third capacitor element is connected to the output of the inverter element and to ground, and a fourth capacitor element has one end connected to ground. A second switching element switches a connection state of the one end of the third capacitor element and another end of the fourth capacitor element.

A semiconductor device includes a resistor element connected to one and another end of a crystal oscillator, and an adjustable current type inverter element having an input connected to one end of the resistor element and an output connected to another end of the resistor element. A first capacitor element is connected to the input of the inverter element and to ground, and a second capacitor element has one end connected to ground. A first switching element switches a connection state of the one end of the first capacitor element and another end of the second capacitor element. A third capacitor element is connected to the output of the inverter element and to ground, and a fourth capacitor element has one end connected to ground. A second switching element switches a connection state of the one end of the third capacitor element and another end of the fourth capacitor element.

An oscillator and an operation method thereof are provided. The oscillator includes a current source, a memristor, a switching circuit, and a control circuit. The switching circuit is coupled to the current source and the memristor. The switching circuit is configured to transmit a bias current provided by the current source to the memristor, and determine a flow direction of the bias current in the memristor according to at least one control signal. The control circuit is coupled to the switching circuit to provide the at least one control signal. The control circuit is configured to detect a representative voltage of the memristor. The control circuit changes the at least one control signal according to a relationship between the representative voltage, a first threshold voltage, and a second threshold voltage to change the flow direction of the bias current in the memristor.

An oscillator and an operation method thereof are provided. The oscillator includes a current source, a memristor, a switching circuit, and a control circuit. The switching circuit is coupled to the current source and the memristor. The switching circuit is configured to transmit a bias current provided by the current source to the memristor, and determine a flow direction of the bias current in the memristor according to at least one control signal. The control circuit is coupled to the switching circuit to provide the at least one control signal. The control circuit is configured to detect a representative voltage of the memristor. The control circuit changes the at least one control signal according to a relationship between the representative voltage, a first threshold voltage, and a second threshold voltage to change the flow direction of the bias current in the memristor.