A temperature detection device includes a thermistor element that includes a thermosensitive body configured to sense heat of a coil element and an electric wire electrically connected to the thermosensitive body, and a holder assembling the thermistor element to the coil element. The holder includes a thermosensitive body holder that holds a reinforcing portion of the thermosensitive body disposed sideways along a front surface of the coil element and is provided with a first resin reservoir enclosing a thermosensitive body contact portion of the thermosensitive body, and an electric wire holder holding the electric wire. The thermosensitive body contact portion is in contact with the coil element while being enclosed with the first resin reservoir. According to the temperature detection device, it is possible to more accurately detect temperature of a coil with high responsiveness while promoting miniaturization of the temperature detection device.

Provided is a vibration actuator including: a vibrator including an elastic body and an electro-mechanical energy conversion element; a contact body provided so as to be brought into contact with the vibrator; a flexible printed board configured to feed power to the electro-mechanical energy conversion element; and a temperature detection unit provided on a region of the flexible printed board, in which the flexible printed board and the electro-mechanical conversion element overlap each other.

Provided are: a gas sensor which is able to have improved gas detection performance, while being capable of suppressing variation in the output characteristics among individual gas sensors; a gas detection device; a gas detection method; and a device which is provided with a gas sensor or a gas detection device. This gas detection device (10) is provided with: a heat sensitive resistive element (2); a lead part (22b) which is connected to the heat sensitive resistive element (2) by welding, while having no material being interposed therebetween; a gas sensor (1) which is thermally coupled to the heat sensitive resistive element (2), while comprising a porous gas molecule adsorption material (3) from which specific gas molecules are desorbed by means of heating; and an electric power supply unit which supplies electric power to the heat sensitive resistive element (2), thereby heating the heat sensitive resistive element (2).

A device having a first terminal region and a second terminal region. The first terminal region includes fine-tune (FT) metal stripes that are separated from each other by a first distance along the longitudinal direction. The second terminal region is spaced apart from the first terminal region by at least an inter-terminal distance. The second terminal region includes coarse-tune (CT) metal stripes that are separated from each other by a second distance along the longitudinal direction. The second distance is greater than the first distance, and the inter-terminal distance greater than the second distance. Each of the FT metal stripes may be selected as a first access location, and each of the CT metal stripes may be selected as a second access location. A pair of selected first and second access locations access a sheet resistance defined by a distance therebetween.

Various examples provide an electronic device that includes first and second resistor segments. Each of the resistor segments has a respective doped resistive region formed in a semiconductor substrate. The resistor segments are connected between first and second terminals. The first resistor segment is configured to conduct a current in a first direction, and the second resistor segment is configured to conduct the current in a second different direction. The directions may be orthogonal crystallographic directions of the semiconductor substrate.

This disclosure describes a slide comprising a substrate, a RFID or WISP, and a temperature sensor, wherein the slide is capable of communicating with an external communications device via the RFID or WISP. In some implementations, the RFID or WISP of the slide comprises an antenna, an integrated circuit, a memory unit, and a power source, such that it is capable of measuring and logging data related to time and temperature. In some implementations, the RFID or 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.

A sensor module includes a first contact, a second contact, and a sensing element made from an iono-conductive material having a conductivity that varies at least in response to variations in an environmental factor. The sensing element is electrically coupled to the first contact and to the second contact, and a first resistance of the sensing element, measured between the first contact and the second contact, varies in response to the variations in the environmental factor.

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 temperature sensor having excellent humidity resistance and responsivity is provided. The temperature sensor according to the present invention includes an insulating substrate 2; a thin film thermistor portion 3 made of a thermistor material formed on either surface of the insulating substrate; and an opposed electrode pair 5 consisting of a pair of opposed electrodes 4 formed so as to be opposed to each other on at least either one of the top and bottom surfaces of the thin film thermistor portion, wherein a plurality of the opposed electrode pairs are provided and connected to one another in series. As a result, a voltage applied to a unit thermistor composed of one opposed electrode pair becomes 1/n fold, which can suppress the electrode corrosion due to humidity load.

A temperature sensor can include a resistor, a first electrical contact at a first end of the resistor, a second electrical contact at a second end of the resistor, and a resistance measuring device. The resistor can be formed of a matrix of sintered elemental transition metal particles interlocked with a matrix of fused thermoplastic polymer particles. The resistance measuring device can be connected to the first electrical contact and the second electrical contact to measure a resistance of the resistor.