The present application discloses a UV radiation monitoring apparatus, method, and system. The monitoring apparatus includes a case, an authenticator disposed on the case and configured to identify a user, a controller in the case coupled to the authenticator to enable a first mode for an authenticated user, a detector on the case coupled to the controller and configured to measure an intensity of ultraviolet radiation and generate ultraviolet index (UVI) value at the present time, a memory coupled to the controller and configured to store the UVI values over an exposure time added into historical UVI data for the authenticated user, and a display unit to display the UVI value at the present time and the personal health instructions on UV protection for the authenticated user. The monitoring apparatus further is configured to be paired with a mobile terminal for providing updated personal health instructions.

The present technology relates to an imaging apparatus and a manufacturing method which enables sensitivity of an imaging apparatus using infrared rays to be improved. The imaging apparatus includes: a light-receiving element array in which a plurality of light-receiving elements including a compound semiconductor having light-receiving sensitivity in an infrared range are arrayed; a signal processing circuit that processes a signal from the light-receiving element; an upper electrode formed on a light-receiving surface side of the light-receiving element; and a lower electrode that is paired with the upper electrode, in which the light-receiving element array and the signal processing circuit are joined to each other with a film of a predetermined material, the upper electrode and the signal processing circuit are connected to each other through a through-via-hole penetrating a part of the light-receiving element, and the lower electrode is made as an electrode common to the light-receiving elements arrayed in the light-receiving element array. The present technology can be applied to an infrared sensor.

A wearable or attachable device comprising a UV sensor configured to provide user-specific burn rate times providing an indication to the user when they are exposing themselves to harmful levels of UV radiation.

One variation of a system for tracking and responding to Sun exposure includes: a housing configured to transiently attach to a port on a first garment; a jack coupled to the housing configured to transiently engage a port on the first garment; a radiation sensor arranged in the housing and configured to detect solar radiation incident on the housing; and a controller configured to: read an identifier of the first garment from the port via the jack; based on the identifier, estimate a skin exposure of a user wearing the first garment; read an solar radiation value from the radiation sensor at a first time; and, based on the solar radiation value and the skin exposure, estimate an solar radiation exposure of the user at the first time.

Embodiments of the invention are directed to a method for determining a pseudo location of a user. The method includes collecting, by a processing device, ultraviolet (UV) sensor data from a UV sensor of a user device of the user. The method further includes analyzing, by the processing device, the UV sensor data by comparing the UV sensor data to a UV profile for a geographic area. The method further includes determining, by the processing device, the pseudo location of the user based at least in part on the UV sensor data and the UV profile.

Field balancing may be performed with an irradiation system including a plurality of adjustable radiant-energy emitters. The irradiation system powers the radiant-energy emitters from a power source and radiant energy is emitted from the radiant-energy emitters, where an amount of radiant energy emitted from each emitter is capable of being varied based on power received from the power source. A plurality of radiant-energy sensors detects an amount of radiant energy which includes radiant energy created directly by at least one of the radiant-energy emitters. The amount of radiant energy detected at at least two of the radiant-energy sensors is compared, and at least one of the radiant-energy emitters is adjusted by varying the power received from the power source so that the amount of radiant energy detected at each of the radiant-energy sensors tends towards becoming approximately equal. The emitting of radiant energy from each radiant-energy emitter is terminated when a total amount of radiant energy emitted from the plurality of adjustable radiant-energy emitters exceeds a predetermined threshold value, where the threshold value is sufficient to allow the total amount of radiant energy emitted from the plurality of adjustable radiant-energy emitters to sanitize a particular area in which the emitters are located.

Embodiments of the invention are directed to a method for determining a pseudo location of a user. The method includes collecting, by a processing device, ultraviolet (UV) sensor data from a UV sensor of a user device of the user. The method further includes analyzing, by the processing device, the UV sensor data by comparing the UV sensor data to a UV profile for a geographic area. The method further includes determining, by the processing device, the pseudo location of the user based at least in part on the UV sensor data and the UV profile.

Eyewear having radiation monitoring capability is disclosed. Radiation, such as ultraviolet (UV) radiation, infrared (IR) radiation or light, can be measured by a detector. The measured radiation can then be used in providing radiation-related information to a user of the eyewear. Advantageously, the user of the eyewear is able to easily monitor their exposure to radiation.

A printer includes an ultraviolet (UV) curing device having UV light emitting diodes (LEDs) to cure UV curable inks ejected onto a surface after the surface travels past a plurality of printheads in the printer. A UV detector having UV sensors is positioned opposite the UV curing device so the UV sensors and UV LEDs are opposite one another in a one-to-one correspondence. A controller operates the UV curing device to direct UV light into the UV detector and receives electrical signals generated by the UV sensors. The controller compares these electrical signals to a predetermined threshold to identify defective LEDs in the UV curing device. The controller then determines how to move the UV curing device across the path of the surface to irradiate areas of the surface previously opposite the defective UV LEDs.

A solid-state radiation detector includes a pattern of conductive metal on a zinc oxide substrate. The pattern provides an arrangement of interdigitated electrode fingers. The wide band gap substrate is sensitive to UV light, which can cause a conductivity change in the substrate. The electrode fingers are configured to sense a difference in substrate conductivity resulting from UV light. The detector has a fast response time, which enables it to detect Cherenkov light. The compact detector provides savings on size, weight, and required power. Thus, the solid-state detector can be used to replace photomultiplier tubes in Cherenkov detectors. The features of the novel detector allow for an improved system to detect and monitor UV radiation, especially during deep space missions.