Methods and devices are provided for circuits. One device includes an adjustment circuit having an adjustable resistor for modifying a resistance value of a resistive device, the adjustment circuit connected to an adjustment terminal of the resistive device. The resistance value of the adjustable resistor changes, when a voltage or charge on the adjustment terminal of the adjustable resistor is changed. The adjustable resistor is a phase change element with an adjusting terminal to which different voltage values are applied for adjusting a conversion device threshold value.

An atmospheric turbulence detection method includes: providing a temperature difference measuring device including a thermocouple element and two sensing probes, wherein the thermocouple element has two opposite end portions, the two sensing probes are respectively disposed at the two end portions, and there is an ambient distance between the two end portions; placing the temperature difference measuring device in an atmospheric environment to generate an electromotive force by a temperature difference between the two end portions; analyzing the electromotive force to convert the electromotive force into an ambient temperature difference of an environment where the two end portions of the thermocouple element are located, an atmospheric refractive index structure constant is calculated according to the ambient temperature difference and the ambient distance, and a value of the atmospheric refractive index structure constant corresponds to an ambient disturbance of an atmospheric turbulence. An atmospheric turbulence detection device is also provided.

The digital temperature sensing circuit includes a temperature voltage generator configured to generate a temperature voltage varying with a temperature in response to a first reference voltage, divide a supply voltage in response to a second reference voltage, and generate a high voltage and a low voltage, a code voltage generator configured to divide the second reference voltage based on the high voltage and the low voltage and output divided voltages having different voltage levels, and a mode selector supplied with the temperature voltage and the divided voltages, and configured to output a first code or a second code in response to a mode select signal, wherein the first code and the second code have different numbers of bits.

A thermal sensor for an integrated circuit including: a Proportional To Absolute Temperature (PTAT) circuit comprising n-type MOS transistors and providing a first voltage; and a voltage generator circuit comprising a p-type MOS transistor and providing a second voltage. A reference voltage is based on the first voltage and the second voltage. At least one thermal output signal is based on the reference voltage together with the first voltage and/or the second voltage. In another aspect, an integrated circuit has a power routing arrangement, providing a power supply core voltage (VDDcore) to operate functional circuitry on the integrated circuit. One or more local thermal sensors are located on the integrated circuit, each comprising a PTAT circuit having MOS transistors using the power supply core voltage to generate a temperature-dependent voltage that varies independently of power supply core voltage variation.

A temperature sensing circuit includes a current generation circuit generating an initial current proportional to absolute temperature (Iptat), and a voltage generation circuit configured to mirror Iptat using an adjustable current source to produce a scaled current and to source the scaled current to a first terminal of a resistor to produce a reference voltage at the first terminal. A second terminal of the resistor has a voltage complementary to absolute temperature (Vctat) applied thereto. An analog-to-digital converter (ADC) has a reference input receiving the reference voltage, and a data input receiving Vctat or an externally sourced voltage. The ADC generates an output code indicative of a ratio between: a) either Vctat or the externally sourced voltage, and b) the reference voltage. A digital circuit determines a temperature readout from the output code and calibrates the reference voltage and the temperature readout determination based upon the output code.

A current digital-to-analog converter may be used in a system for measuring temperature of a thermistor, with mismatch reduction techniques applied to digital-to-analog converter elements of the digital-to-analog converter in order to maximize accuracy and precisions of the temperature measurement.

A system and method provide on-line, wafer-level, die-level, or package-level thermal calibration of an integrated measurement resistor with a single temperature insertion. The system includes a measurement resistor integrated on a substrate with an unknown temperature coefficient and a temperature reference sensor thermally coupled to the measurement resistor. A measurement circuit measures an indication of a resistance of the measurement resistor. An electrically-controllable integrated heat source is operated by a controller to change a temperature of the measurement resistor and the temperature reference sensor and stores values of the resistance indication and the sensed temperature corresponding to multiple temperatures of the temperature of the measurement resistor and the temperature reference sensor. The controller generates or approximates a mathematical relationship between the resistance of the measurement resistor and the temperature of the measurement resistor and the temperature reference sensor from the stored values.

A temperature sensor system for an integrated circuit includes at least one sensor configured to generate a sensor signal indicative of a temperature in a respective location of the integrated circuit and a sensing module configured to receive the sensor signal, determine a temperature of the at least one sensor based on the sensor signal, an electrical characteristic of the at least one sensor, and a relationship between the electrical characteristic and the temperature of the at least one sensor, the relationship corresponding to variations in the electrical characteristic at a known calibration temperature, and generate a temperature signal based on the determined temperature.

The digital-output temperature sensor includes a temperature sensor circuit, a current mirror circuit which makes a mirror current of a temperature detection current flow and pulls in a mirror current of a reference current to thereby output a first difference current from a first output node and output a second difference current from a second output node, a chopping circuit, and an A/D conversion circuit. The chopping circuit performs a chopping operation of making the mirror current of the reference current flow in a second state through a transistor of the current mirror circuit through which the mirror current of the temperature detection current flows in a first state, and making the mirror current of the temperature detection current flow in the second state through the transistor of the current mirror circuit through which the mirror current of the reference current flows in the first state.

A temperature measurement circuit for measuring a temperature using a temperature sensitive element includes a voltage control circuit configured to apply a control voltage to the temperature sensitive element. The temperature measurement circuit includes a first switching circuit configured to switch levels of the control voltage based on a current flowing through the temperature sensitive element. The temperature measurement circuit includes a conversion circuit configured to convert the current flowing through the temperature sensitive element into a voltage level corresponding to the measured temperature, by using predetermined conversion gain. The temperature measurement circuit includes a second switching circuit configured to switch values of the conversion gain based on the voltage level.