A wearable environmental sensor device includes a temperature/humidity sensor disposed on a wall surface of a housing that is exposed to an environment and configured to measure ambient environmental information around a living body, and a protective structure formed around the temperature/humidity sensor. The temperature/humidity sensor is disposed, directly or via a support structure, on or over the wall surface of the housing, wherein the wall surface faces substantially downward from the living body when the wearable environmental sensor device is attached to the living body and the living body is in a standing posture. The protective structure has respective ventilation holes provided in two or more pairs of opposed surfaces thereof each facing in a direction other than a vertical direction of the living body when the wearable environmental sensor device is attached to the living body and the living body is in the standing posture.

An apparatus comprises: a first circuitry to charge first and second capacitors to a predetermined voltage level; a second circuitry to discharge the first capacitor through a diode at a first time; a third circuitry to discharge the second capacitor through the diode at a second time, wherein the second time is greater than the first time; a comparator to compare a first voltage of the first capacitor with a second voltage of the second capacitor; and logic to adjust a scaling factor applied to the second voltage according to an output of the comparator.

A driver can be configured to provide sensed phase currents as feedback to a controller to indicate the output currents from each phase of a switch mode power supply (SMPS). The driver can be configured to temperature compensate the sensed currents in one of two ways. If a temperature sensor is directly coupled to the driver, then the driver may be configured to temperature compensate the sensed currents from each phase based on a temperature measurement made by the temperature sensor. If a temperature sensor is not directly coupled to the driver, then the driver may be configured to temperature compensate the sensed current from each phase based on a temperature signal received from a bus coupled to the driver. The bus can communicate the temperature signal so that multiple drivers can utilize one temperature sensor.

A temperature sensor circuits includes a temperature sensing module, a current generator, a current controlled oscillator, and a counter. The temperature sensing module is sensitive to temperature changes. The current generator respectively generates a positive temperature coefficient current positively related to temperature and a negative temperature coefficient current negatively related to temperature according to the temperature sensed by the temperature induction module. The current controlled oscillator oscillates according to the positive and the negative temperature coefficient currents respectively and outputs a positive and negative temperature coefficient oscillation signals. The counter receives a clock signal and calculates a first period accumulation number of the negative temperature coefficient oscillation signal and a second period accumulation number of the positive temperature coefficient oscillation signal in the same number of clock periods respectively, and acquires a temperature value based on the period accumulation numbers.

Disclosed herein is a temperature compensated crystal oscillator, TCXO, comprising: a crystal oscillator arrangement configured to generate an output signal of the temperature compensated crystal oscillator; and a temperature sensor arranged to generate a temperature sensor signal, wherein the output signal of the crystal oscillator arrangement is controlled in dependence on the temperature sensor signal; wherein: the temperature sensor comprises a plurality of transistor circuits; each transistor circuit comprises a transistor and a bias circuit; each transistor circuit is arranged to output a temperature signal that is dependent on the temperature of the transistor comprised by the transistor circuit; each bias circuit is configured such that the noise level in each output temperature signal is low; and the plurality of transistor circuits are arranged so that the temperature sensor signal is dependent on each of the plurality of output temperature signals.

Provided is a temperature measurement circuit. The temperature measurement circuit includes a comparator, a first voltage generation circuit, and a second voltage generation circuit. Inputs of the comparator are connected to a voltage output of the first voltage generation circuit and a voltage output of the second voltage generation circuit, respectively, to obtain a reference voltage and a comparison voltage. A comparison result is outputted, and an ambient temperature is determined based on the comparison result. The second voltage generation circuit includes a current generation circuit configured to generate a current signal correlated to the ambient temperature, and a current-to-voltage conversion circuit configured to convert the current signal into the comparison voltage.

Systems, devices, and methods related to temperature sensors for electronic devices are provided. An example temperature sensor device includes analog temperature sensor circuitry to generate a plurality of voltages indicative of a temperature; an analog-to-digital converter (ADC) disposed downstream of the analog temperature sensing circuitry; switched-capacitor amplifier circuitry disposed before the ADC, the switched-capacitor amplifier circuitry comprising a single-ended amplifier to amplify the plurality of voltages with respect to a common voltage; a first switch coupled between the analog temperature sensor circuitry and the switched-capacitor amplifier circuitry to provide a sampling phase and an integration phase; and digital calculation circuitry to calculate a temperature value based on the plurality of amplified voltages.

The temperature sensor module includes: a temperature sensor element and a signal processing circuit. The signal processing circuit includes: a series-connection resistor which is connected in series to the temperature sensor element; a temperature detection circuit which detects a temperature; a first analog-digital conversion circuit which converts an output signal from the temperature detection circuit into a digital signal; a memory which stores a series-connection resistor data piece about a relationship between a temperature and the resistance value of the series-connection resistor; a digital signal processing circuit which uses the series-connection resistor data piece, to calculate, on the basis of the digital signal indicating the temperature of the signal processing circuit, a digital command signal for keeping the resistance value of the series-connection resistor at a constant value, and outputs the digital command signal; and a digital-analog conversion circuit which outputs the digital command signal to the series-connection resistor.

A temperature sensor and method of temperature sensing is described. A first reference current is provided to a dual-slope ADC during a first slope time duration of a dual-slope ADC conversion cycle. A second reference current is provided to the dual-slope ADC during a second slope time duration of the dual-slope ADC conversion cycle. A digital codeword corresponding to a ratio of the first and second reference currents is then output by the dual-slope ADC. The first and second reference current ratio is related to the temperature.

A device, which includes an input, configured to read in an analog signal, an analog/digital converter, configured to convert the analog signal into a digital value, and a processor, configured to determine a digital measured value. The processor is further configured to derive a calibrated digital value from the digital value with the aid of a linear calibration function and to derive the digital measured value from the calibrated digital value with the aid of a nonlinear measurement function. The processor modifies the linear calibration function in response to a calibration signal, based on an algorithm, which is based on the nonlinear measurement function, and a number of predefined comparison measured values.