An ostomy bag can include one or more sensors for measuring one or more metrics. An ostomy wafer can also include one or more sensors for measuring one or more metrics. The sensors can be temperature sensors and/or capacitive sensors, for example, and the metrics can include bag fill, leakage, skin irritation, and phase of stoma output, among others.

A method includes using a thermistor as a temperature sensor and connecting a pull-up resistor in series to the thermistor in a voltage divider circuit. The pull-up resistor is fabricated in an integrated circuit and includes a series of resistor segments connected to selectable voltage output tabs. The method further includes selecting an output voltage tab for a selected resistance segment having a selected resistance value to match a target resistance value for the pull-up resistor that is smaller than the as-fabricated resistance value of the pull-up resistor, calculating a ratio of a voltage on the thermistor and a voltage on the selected output voltage tab in the voltage divider circuit, and mapping the calculated ratio to a temperature value of the thermistor based on a temperature-resistance relationship of the thermistor in combination with the target resistance value of the pull-up resistor.

There is provided a temperature sensor element including a pair of electrodes and a temperature-sensitive film disposed in contact with the pair of electrodes, in which the temperature-sensitive film includes a conductive polymer, the conductive polymer includes a conjugated polymer and a dopant, and the dopant includes a dopant having a molecular volume of 0.08 nm.sup.3 or more.

A method of manufacturing a sensor include depositing a metal layer on a substrate and fabricating a calibration structure on the metal layer. The calibration structure can include a first calibration portion and a second calibration portion. The method may further include, performing a first calibration of the sensor by modifying the first calibration portion. In addition, the method can include placing a cover layer on a portion of the first calibration portion after the first calibration and then performing a second calibration of the sensor by modifying the second calibration.

The present invention enables the achievement of: high density mounting by means of an electronic component for welding; and improvement of thermal responsivity and tensile strength at high temperatures by means of reduction in size and thickness of a temperature sensor. An electronic component for welding, which has a function of a resistor, a capacitor, an inductor or the like, comprises: an insulating substrate; a function part and a bonding electrode part, which are provided on the insulating substrate; and a lead which is electrically connected to the bonding electrode part. The bonding electrode part is configured of: an adhesive active metal layer which is formed from a high-melting-point metal on the insulating substrate; a barrier layer which is formed from a high-melting-point metal on the active metal layer; and a bonding metal layer which is mainly composed of a low-melting-point metal and is formed on the barrier layer.

This disclosure describes a slide comprising a substrate, a wireless communication element, and a sensing element, wherein the slide is capable of communicating with an external communications device via the wireless communication element. In some implementations, the wireless communication element comprises an antenna, an integrated circuit, and a memory unit, that are powered wirelessly by an external device, such that it is capable of measuring, logging, and communicating data. The data, such as time and temperature, may be collected via the sensing element connected to the wireless communication element.

An ostomy bag can include one or more sensors for measuring one or more metrics. An ostomy wafer can also include one or more sensors for measuring one or more metrics. The sensors can be temperature sensors and/or capacitive sensors, for example, and the metrics can include bag fill, leakage, skin irritation, and phase of stoma output, among others.

This disclosure describes a slide comprising a substrate, a WISP, and a temperature sensor, wherein the slide is capable of communicating with an external communications device via the WISP. In some implementations, the WISP comprises an antenna, an integrated circuit, and a memory unit, that are powered wirelessly by an external device, such that it is capable of measuring, logging, and communicating data. The data, such as time and temperature, may be collected via sensors connected to the WISP. In some implementations, the WISP and temperature sensor are embedded in the substrate to prevent direct contact with mounted specimens. In some implementations the slide further comprises displayed content. In some implementations, the displayed content is linked to a database of information. The various implementations of this invention may describe a slide utilizing any number of the features described above in any combination.

An attachment structure for a temperature sensor that is attached to a flexible thin plate-shaped cable and detects the temperature of a unit cell of a battery pack having a plurality of unit cells connected with each other includes: the flexible thin plate-shaped cable; a chip-shaped temperature measuring element that is incorporated on a conductor exposed portion of the flexible thin plate-shaped cable and detects the temperature of the unit cell; and a metal leaf spring that is placed around the conductor exposed portion of the flexible thin plate-shaped cable and has a plurality of legs surrounding the temperature measuring element, and an elastic piece configured to energize the plurality of legs toward the unit cell. The temperature measuring element is sheathed with a moisture-proof material between the plurality of legs of the metal leaf spring.

A temperature sensing tape including a flexible, electrically insulating substrate, a plurality of temperature sensing elements disposed on the substrate, each temperature sensing element including a first electrode and a second electrode arranged in a confronting, spaced-apart relationship to define a gap therebetween, and a variable resistance material disposed within the gap and connecting the first electrode to the second electrode, wherein the first electrode of at least one of the temperature sensing elements is connected to the second electrode of an adjacent temperature sensing element by a flexible electrical conductor.