Various arrangements for assessing an installation of a smart home device are presented. An orientation of the smart home device may be analyzed to determine whether the orientation of the smart home device is unsuitable for one or more features of the smart home device to function properly. An indication of whether the orientation of the smart home device is unsuitable may be output, such as by the smart home device using voice or lighting.

An electronic component comprises a carrier (3), a sensor device (2) mounted on the carrier (3), which sensor device (2) comprises a sensor chip (21), and an electrostatic discharge protection element (1) for protecting the sensor chip (21) from an electrostatic discharge, which protection element (1) is mounted on the carrier (3).

The invention provides a humidity sensor and a manufacturing method thereof. The humidity sensor comprises a substrate, an electrode structure, and a humidity sensing structure. The electrode structure is disposed on the substrate. The humidity sensing structure is disposed on the electrode structure. The humidity sensing structure includes a first humidity sensing layer and a second humidity sensing layer. The first humidity sensing layer is in direct contact with the electrode structure and has a first oxygen vacancy number. The second humidity sensing layer is disposed on the first humidity sensing layer and has a second oxygen vacancy number. The second oxygen vacancy number is greater than the first oxygen vacancy number.

A humidity detection device includes a humidity sensor, a resistor connected to one-side of the humidity sensor, a first switching part connected to the resistor; a diode connected to the first switching part; a second switching part connected to the other-side of the humidity sensor, a potential difference generating part connected to the second switching part, a power supply supplying a voltage, and a control part applying the voltage as an alternating voltage to the humidity sensor by controlling the first switching part and the second switching part. The control part applies a current to the diode, the resistor and the humidity sensor in a first direction by connecting the second switching part to the ground, and applies the current to the resistor and the humidity sensor in a second direction, which is an opposite direction from the first direction, by connecting the first switching part to the ground.

A monolithic sensor arrangement, a manufacturing method and a measurement method are disclosed. In an embodiment a monolithic gas sensor arrangement includes a sensor including a first transducer with a first sensitive layer and a second transducer with a second sensitive layer, and a readout circuit configured to generate a first measurement signal and a second measurement signal depending on the first and second transducers, wherein the sensor arrangement is a humidity sensor arrangement, wherein the first and second sensitive layers are configured to absorb water molecules, and wherein the first and second sensitive layers differ from each other in at least one property.

A humidity sensor device includes a substrate and a pair of interdigitated electrodes formed over the substrate.

A humidity sensor is provided with a first electrode electrically connected to a first terminal, and a moisture-sensitive member. The first electrode may include a first internal electrode unit. The first internal electrode unit may include a first main surface covered with the moisture-sensitive member, and a second main surface covered with the moisture-sensitive member. The humidity sensor may further include a second electrode electrically connected to the second terminal. The second electrode may include a second internal electrode unit. The second internal electrode unit may include a third main surface covered with the moisture-sensitive member, and a fourth main surface covered with the moisture-sensitive member. The first internal electrode unit may include a portion facing at least a part of the second internal electrode unit across the moisture-sensitive member.

A sensor tube according to the present disclosure includes a body including a body extension having opposite ends connected to measurement air connection pipes and an opening, the measurement air connecting pipes being connected to a humidity sensor to deliver moisture to the humidity sensor using measurement air or allow the measurement air released from the humidity sensor to flow therethrough, and the opening being formed in the body extension to cause an interior space of the body extension and the outside to be in communication with each other such that the moisture is introduced into the interior space of the body extension from the outside through the opening, and an opening/closing part that selectively opens or closes the opening by being operated by a difference in pressure between the interior space of the body extension and the outside.

A moisture monitoring system with internes of things devices. The system includes at least one irrigating device having a moisture sensor, a temperature sensor, a valve connected to a water source, a wireless transmitter that sends sensor information to a cloud server via a first internet-of-things establishing a first channel of communication, and a wireless receiver configured to receive valve actuation signals from the cloud server via a second internet-of-things device establishing a second channel of communication. A valve actuator opens the valve upon receiving an actuation signal via the second internet-of-things device. The duration of the valve remaining open and other parameters are adjustable by a user utilizing a user interface of the second internet-of-things device. The moisture monitoring system can be customized and applied to various use cases depending on the irrigation needs of the user.

The present invention is directed to a sensor having continuous and discontinuous regions of conductive metallic nanoparticles capped with an organic coating which enables the detection of volatile organic compounds and/or water vapor. Continuous regions may exhibit a positive response upon exposure to volatile organic compounds and to water vapor, while discontinuous regions exhibit a positive response upon exposure to volatile organic compounds and a negative response upon exposure to water vapor.