The present invention provides an ambient light sensor with ultraviolet light detection function, which is adopted to receive external light for sensing. The ambient light sensor comprises a visible light sensing chip and a wavelength conversion layer. The visible light sensing chip is used for sensing light corresponding to the response band of visible light, and the visible light sensing chip includes a light receiving surface. The wavelength conversion layer is used to convert light corresponding to a specific ultraviolet light band of the external light into light corresponding to a response band of visible light, and the wavelength conversion layer covers at least a part of the light receiving surface.

Method, product and blocking element of short wavelengths in LED-type light sources consisting of a substrate with a pigment distributed on its surface and, in that said pigment has an optical density such that it allows the selective absorption of short wavelengths between 380 nm and 500 nm in a range between 1 and 99%.

The present disclosure relates to a method for high pressure regulation and control of photoelectric detection based on BiOBr, and relates to the technical field of photoelectric detection. An exemplary method includes inserting an insulation layer into a pressure chamber of a diamond anvil cell and adding BiOBr, putting a pressure-calibrating substance on a culet of the diamond anvil cell; pressurizing the pressure chamber by rotating a press bolt on the diamond anvil cell; and conducting photoelectric detection using the pressurized BiOBr, where two platinum sheets are disposed on the BiOBr as an electrode. The present disclosure enhances the photo-response speed and photo-responsivity of photoelectric detection.

The invention is a method for generating a radiation plan of a scene in particular for a disinfection robot adapted for radiating disinfection light, in the course which providing or generating a 3D model (136) with 3D elements, generating radiation plan candidates (112) for the first 3D model (136) based on artificial intelligence, each plan candidate (112) comprising one or more radiation position and respective radiation time, generating one or more respective irradiance ratio estimation (134) of the 3D model (136) for the plan candidates (112), and obtaining the radiation plan (135) from the plan candidates (112) based on the one or more respective irradiance ratio estimation (134) by means of the first radiation plan generator module (130).

The invention is, furthermore, a system for generating a radiation plan.

Method, sterilization system and robotic system for improving duty cycle of Ultraviolet (UV) emitter modules disinfecting closed environment. Sterilization system includes robotic system and plurality of UV emitter modules. Robotic system receives signal corresponding to discharge of battery from one of plurality of UV emitter modules. Each of plurality of UV emitter modules includes UV light source for disinfecting closed environment. Robotic system detects location of UV emitter module amongst plurality of UV emitter modules and maneuvers to location of UV emitter module, mounts UV emitter module and maneuvers UV emitter module to charging dock for charging battery of UV emitter module. After charging, robotic system maneuvers UV emitter module to pre-defined area for disinfecting pre-defined area of closed environment. Robotic system includes battery charged through UV emitter module when UV emitter module is getting charged, or when UV emitter module mounted to robotic system includes battery that is fully charged.

Ultraviolet systems and methods are described for capturing images depicting absorption or remittance of ultraviolet radiation (UVR). An example system includes a camera comprising a monochrome camera sensor that is configured to capture images, a radiation source that is configured to output a UVR waveband, a filter component that is configured to differentiate at least one of a UVA waveband and a UVB waveband of the UVR waveband, and a polarizer component that is configured to cross polarize each of the UVA waveband and the UVB waveband. Further, the camera is configured to capture an image depicting an UVA amount of UVA absorption or remittance as projected on a surface area and an UVB amount of UVB absorption or remittance as projected on the surface area.

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 UV radiator module includes a number of elongated UV radiators arranged with their longitudinal axes parallel to one another in the UV radiator module. The UV radiators are arranged in two parallel rows which are spaced apart from one another. A UV sensor is set up to detect UV radiation emitted by the UV radiators. The UV sensor is arranged between the two rows.

A flexible ultraviolet sensor circuit is provided comprising a number of solar cells, a reflective display device electrically connected to the solar cells, and a floating gate transistor electrically connected to the solar cells and reflective display device. A floating gate in the floating gate transistor discharges in response to ultraviolet light such that the floating gate transistor turns on when a threshold voltage of the floating gate transistor drops below a combined open circuit voltage of the solar cells minus a switching threshold of the reflective display device, thereby causing electrical current flow through the ultraviolet sensor circuit. The reflective display device changes as the electrical current flow increases, indicating total ultraviolet light exposure.

A thermally coupled imager includes a single photon detection pixel electrically isolated but in thermal communication with a thermal readout bus via a thermally conductive galvanic isolator, wherein the single photon detection pixel receives a single photon and produces thermal energy that is communicated to the thermal readout bus. A position and time of arrival of the single photon received by the single photon detection pixel is determined from voltage pulses produced by the thermal readout bus in response to receiving the thermal energy from the single photon detection pixel.