Provided are a stretchable humidity-sensitive composite material for a humidity sensor that can be applied to clothing as wearable device, and the humidity sensor. The humidity-sensitive composite material is characterized by containing a deliquescent inorganic compound in closed pores inside a base material made of a porous silicone resin. The humidity sensor is characterized in that a bulk made of a humidity-sensitive composite material containing a deliquescent inorganic compound in closed pores inside a base material made of a porous silicone resin is sandwiched between a pair of counter electrodes made of a moisture-permeable material.

The present invention relates to a method of manufacturing a relative humidity sensor comprising the step of; a) providing a first electrode on or over a substrate, b) providing a non-porous inorganic dielectric layer over the first electrode, c) providing a second electrode over the inorganic dielectric layer, and d) forming a pattern of voids in the second electrode and the inorganic dielectric layer through the second electrode. The invention also relates to a relative humidity sensor, in particular one obtained by the inventive method.

The present invention provides a humidity sensor, comprising a substrate having a coating wire and at least one humidity detecting portion S, each humidity detecting portion S comprises at least two electrodes, and each of electrodes is connected to their respective coating wires, and an electrochemical medium which is electrically insulated when dry and conductive when wet is provided between electrodes. This kind of humidity sensors can be used to monitor humidity in a highly sensitive manner, especially monitor the amount and extent of urine.

A method for forming a cellulose acetate based reduced graphene oxide (CA-rGO) layer includes selecting a substrate; spin-coating a cellulose acetate dispersion on the substrate to obtain a cellulose acetate layer; and applying a given temperature profile to the cellulose acetate layer to transform it into the CA-rGO layer.

Provided is a button device including a humidity sensor. The button device includes a substrate having a plurality of sensing regions, a housing on the substrate, the housing separating a first sensing region of the plurality of sensing regions from other sensing regions, a porous structure within the housing, the porous structure having through-holes, a first electrode on the porous structure, a second electrode on the porous structure, the second electrode being electrically connected to the first electrode through the porous structure, and a temperature sensor disposed adjacent to the first sensing region to sense a temperature of the first sensing region, The porous structure includes a body having an outer surface defining the through-holes, the body having an air gap therein.

A nanomaterial-based gas sensor system comprising a low voltage circuitry which includes a transducer to detect changes in electrical properties of a multi-channel gas sensor array, analog signal conditioning, and an A/D conversion to provide a signal to a digital back-end.

In one aspect, there is provided a moisture detection system that includes: a moisture detection unit including: a moisture sensor configured to obtain a measurement that indicates an amount of moisture, and a Radio Frequency Identification (RFID) module coupled to the moisture sensor through multiple wires, where the RFID module includes an antenna and is configured to wirelessly transmit a telemetry message based on the measurement from the moisture sensor through the antenna and is further configured to wirelessly receive energy for powering the moisture detection unit through the antenna; and a control unit communicatively coupled to the moisture detection unit, where the control unit is configured to wirelessly receive the telemetry message from the RFID module and process the telemetry message to determine the amount of moisture measured by the moisture sensor.

A gas sensor includes a biomaterial comprising electrically-conductive protein nanowires and at least two electrodes. The at least two electrodes are in operative arrangement with the protein nanowires and configured to provide a signal indicative of a change in conductivity of the protein nanowires. The conductivity of the protein nanowires is responsive to a change in concentration of a gas exposed to the biomaterial, such as ammonia, or to a change in relative humidity.

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.

Provided is a method, computer program product, and drying system for determining a dryness level of a garment. A processor of a controller may receive location data from a position sensor. The location data indicates a position of one or more garments on a drying rack. The processor may register the location of the one or more garments on a virtual map of the drying rack displayed on a user interface of the controller. The processor may receive dryness data for the one or more garments from a moisture sensor. The processor may compare the dryness data to a dryness threshold. In response to the dryness data meeting the dryness threshold, the processor may push a notification to a user.