A sensor for detecting pressure, filling level, density, temperature, mass and/or flow rate, wherein at least one central sensor component is coupled to a further component by nanowires and wherein the sensor component is stiffened, fixed and/or electrically contacted this way.

A sensor for detecting pressure, filling level, density, temperature, mass and/or flow rate, wherein at least one central sensor component is coupled to a further component by nanowires and wherein the sensor component is stiffened, fixed and/or electrically contacted this way.

A temperature sensor is disclosed. In one aspect, the temperature sensor provides a digital output having a precise degree/code step. For example, each step in the digital output code may correspond to one degree Celsius. In one aspect, a temperature sensor comprises a precision band-gap circuit and a sigma delta modulator (SDM) analog-to-digital convertor (ADC). A bandgap voltage and a PTAT voltage may be provided from the band-gap circuit as an input to the SDM ADC. The SDM ADC may produce an output based on the difference between the PTAT voltage and the bandgap voltage. The temperature sensor may also have logic that outputs a temperature code based on the output of the SDM ADC.

A temperature sensor is disclosed. In one aspect, the temperature sensor provides a digital output having a precise degree/code step. For example, each step in the digital output code may correspond to one degree Celsius. In one aspect, a temperature sensor comprises a precision band-gap circuit and a sigma delta modulator (SDM) analog-to-digital convertor (ADC). A bandgap voltage and a PTAT voltage may be provided from the band-gap circuit as an input to the SDM ADC. The SDM ADC may produce an output based on the difference between the PTAT voltage and the bandgap voltage. The temperature sensor may also have logic that outputs a temperature code based on the output of the SDM ADC.

In an embodiment, an ADC converter includes a first injection branch and a second injection branch, a first feedback branch and a second feedback branch, an integration node connected to the first and second injection branches and the first and second feedback branches, an integrator connected to the integration node and a comparator connected downstream of the integrator and configured to generate a comparator output signal to control the first and second feedback branches, wherein the first and second injection branches are configured to provide a charge injection dependent on a respective input quantity to the integration node, wherein the input quantity of the first injection branch is selected from a differential voltage signal, a capacitance dependent signal and a current dependent signal, wherein the input quantity of the second injection branch is selected from another one of the differential voltage signal, the capacitance dependent signal and the current dependent signal, and wherein the first and second feedback branches are configured to provide a feedback charge injection dependent on the comparator output signal to the integration node, the first and second feedback branches configured to receive one of a fixed voltage signal or a differential voltage signal.

In an embodiment, an ADC converter includes a first injection branch and a second injection branch, a first feedback branch and a second feedback branch, an integration node connected to the first and second injection branches and the first and second feedback branches, an integrator connected to the integration node and a comparator connected downstream of the integrator and configured to generate a comparator output signal to control the first and second feedback branches, wherein the first and second injection branches are configured to provide a charge injection dependent on a respective input quantity to the integration node, wherein the input quantity of the first injection branch is selected from a differential voltage signal, a capacitance dependent signal and a current dependent signal, wherein the input quantity of the second injection branch is selected from another one of the differential voltage signal, the capacitance dependent signal and the current dependent signal, and wherein the first and second feedback branches are configured to provide a feedback charge injection dependent on the comparator output signal to the integration node, the first and second feedback branches configured to receive one of a fixed voltage signal or a differential voltage signal.

A capacitance sensor circuit is provided, including: a capacitance variable capacitor changing from a first capacitance to a second capacitance corresponding to environmental change; a reference capacitor; and an amplifier circuit charging the capacitance variable capacitor via a first node and the reference capacitor via a second node, and outputting a determination signal. In the amplifier circuit, a differential amplification part generates a potential difference signal obtained by amplifying the potential difference between the first and the second nodes; an output part outputs the determination signal based on the potential difference signal; and when the difference between the increase degrees of the potentials of the first and the second nodes is less than a predetermined value, the output part holds and outputs the determination signal immediately before that state and a bias control part stops a current flowing through the differential amplification part.

A capacitance sensor circuit is provided, including: a capacitance variable capacitor changing from a first capacitance to a second capacitance corresponding to environmental change; a reference capacitor; and an amplifier circuit charging the capacitance variable capacitor via a first node and the reference capacitor via a second node, and outputting a determination signal. In the amplifier circuit, a differential amplification part generates a potential difference signal obtained by amplifying the potential difference between the first and the second nodes; an output part outputs the determination signal based on the potential difference signal; and when the difference between the increase degrees of the potentials of the first and the second nodes is less than a predetermined value, the output part holds and outputs the determination signal immediately before that state and a bias control part stops a current flowing through the differential amplification part.

Method, apparatus, and computer program product are provided for determining a maximum temperature to which a perishable good or other temperature sensitive item was exposed. In some embodiments, a capacitance of a circuit provided on a substrate is measured. The circuit includes capacitor(s) each having first and second plates separated from each other by an ionic liquid (IL) in a solid state. The IL melts at a predetermined temperature and flows away from the first and second plates into a void. In some embodiments, the predetermined temperature at which the IL melts is different for each capacitor. For example, each capacitor in the circuit may employ a different N-alkyl bezothiazolium salt. A maximum temperature of exposure is determined based on the measured capacitance. In some embodiments, a decision of whether to discard the perishable good or other temperature sensitive item may be based on the determined maximum temperature.

A stretchable sensor, electronic skin, and a method of manufacturing the same are proposed. The stretchable sensor includes a first stretchable electrode including a first elastomer and a first conductor dispersed in the first elastomer, a stretchable active layer formed on the first stretchable electrode and including a third elastomer and an ion conductor dispersed in the third elastomer, and a second stretchable electrode formed on the stretchable active layer and including a second elastomer and a second conductor dispersed in the second elastomer. The stretchable sensor and the method of manufacturing the same are effectively capable of sensing a temperature without being affected by strain and recognizing strain without being affected by temperature.