Described herein are systems and methods for coupling environmental hazard detection and actuation of a wearable chemical sensor at a molecular level. The chemical sensor may be a wearable chemical sensor implemented as a powder, cream, lacquer or other wearable construct. The wearable chemical sensor may detect exposure to various environmental hazards and provide an analog means (e.g., a range of color changes) of indicating the level of environmental hazard exposure.

An ultraviolet index measuring method and apparatus includes preparing a first photosensor having spectral response only in a first section of a wavelength between 250 nm and 298 nm, a second photosensor having spectral response only in a second section of a wavelength between 298 nm and 328 nm, and a third photosensor having spectral response only in a third section of a wavelength between 328 nm and 400 nm. An output signal of the first photosensor, an output signal of the second photosensor, and an output signal of the third photosensor are calibrated using spectral irradiance of reference solar light. First photocurrent of the first photosensor, second photocurrent of the second photosensor, and third photocurrent of the third photosensor are measured under a measurement environment. An ultraviolet index is calculated using the first photocurrent, the second photocurrent, and the third photocurrent under the measurement environment.

A semiconductor device for flame detection, including: a semiconductor body having a first conductivity type conductivity, delimited by a front surface and forming a cathode region; an anode region having a second conductivity type conductivity, which extends within the semiconductor body, starting from the front surface, and forms, together with the cathode region, the junction of a photodiode that detect ultraviolet radiation emitted by the flames; a supporting dielectric region; and a sensitive region, which is arranged on the supporting dielectric region and varies its own resistance as a function of the infrared radiation emitted by the flames.

A sensitivity parameter storing portion stores, as known sensitivity parameters owned by a flame sensor, a reference received light quantity, a reference pulse width, a probability of regular discharge, and probabilities of non-regular discharge in advance. The discharge probability is calculated based on a number drive pulses applied to the flame sensor and a number of discharges determined to have occurred in the flame sensor having received the drive pulses. The calculated discharge probability and the known sensitivity parameters are used to calculate a received light quantity per unit time received by the flame sensor. A pulse width correcting portion is provided to correct the pulse width of the drive pulses generated by an applied voltage generating circuit so that the discharge probability equals a target discharge probability.

A hybrid fiber for detection of UV light is described. The hybrid fiber includes a conductor, a first layer, a photoactive layer, a second layer, and a transparent electrode. The conductor includes a conductive material. The first layer includes a first material deposited onto the conductor. The first material is configured to transport holes and block electrons. The photoactive layer includes a photoactive material coating the first layer. The photoactive material includes a first submaterial and a second submaterial. The second layer includes a second material deposited onto the photoactive layer. The second material is configured to block holes and transport electrons. The transparent electrode includes a transparent electrode material deposited onto the second layer.

Disclosed are devices, systems, and methods for remote and quantitative monitoring of, analysis of, and/or response to the internal conditions of a physical object (e.g., an artistic work) and the external microenvironment impacting the physical object. In some aspects, an art tracker device for monitoring health of an artwork includes a substrate inconspicuously, unobtrusively, and noninvasively attachable to the artwork: one or more of sensors that monitor an internal condition of the artwork itself and/or an external condition from a microenvironment surrounding a portion of or the whole artwork: a controllable power supply unit to selectively power device components: a processing unit that processes sensor outputs as data associated with the detected conditions of the artwork; and a communications unit to wirelessly transmit the data to a remote device.

A solar radiation protective band for a driver that includes a housing and an armband. The housing includes a front panel, a side panel, and a microcontroller. The front panel includes a front panel UV light sensor, a front panel IR phototransistor, and an LCD. The side panel includes a side panel UV light sensor, and a side panel IR phototransistor. A temperature sensor measures a skin temperature and generates a temperature signal. A skin color sensor detects a skin color of the driver and generates a skin color signal. The microcontroller requests an input of a SPF of a sunscreen used by the driver; calculates an exposure time threshold; generates a UV exposure warning when an exposure time exceeds the exposure time threshold; calculates an updated skin temperature; and generates an IR exposure warning when the updated skin temperature exceeds a maximum skin temperature threshold.

An optoelectronic device includes a flexible substrate, a cerium oxide (CeO.sub.2) layer arranged on the flexible substrate, a single crystal -III-oxide layer arranged on the CeO.sub.2 layer, and a metallic contact layer arranged on the single crystal -III-oxide layer.

A vehicle including: (a) a water generator configured to generate water; (b) a water storage container configured to store the water that the water generator generates; (c) an ultraviolet light emitter configured to emit ultraviolet light into the water storage container; (d) a sensor configured to detect the ultraviolet light that the ultraviolet light emitter has emitted; and (e) a human-machine interface configured to issue a notification to a user of the vehicle regarding the ultraviolet light emitter. The sensor can detect a wavelength range of the ultraviolet light that the ultraviolet light emitter has emitted. The sensor can detect an intensity of the ultraviolet light at a predetermined wavelength or wavelength range that the ultraviolet light emitter has emitted. The vehicle further comprises a controller in communication with the ultraviolet light emitter, the sensor, and the human-machine interface.

A retroreflector includes an arrangement of triples, each having three side surfaces, which are disposed in the manner of a cube corner and stand approximately perpendicular on one another. The retroreflector can be produced from a carrier material by injection molding. An optical silicone resin is used as the carrier material. The retroreflector is based on triple mirrors that are both easily unmolded from a die and easily applied to curved surfaces even after unmolding or are usable for reflection of ultraviolet light.