A TFT display screen device includes at least one active zone whose pixels are used for the display of an instrument cluster and the display of one or more warning or alarm), optionally icons inlaid in the instrument cluster. The screen also includes at least one dead zone not visible to the user. At least one dead zone is provided-with at least one light sensor and at least one control pixel which is activated when the single icon or at least one icon with which it is associated, is displayed in the active zone of the screen. The sensor is adapted to detect the activation of said at least one control pixel and to deliver a signal.

Various embodiments disclosed relate to an assembly. The assembly includes a compound parabolic concentrator including an exit aperture that has a generally circular perimeter, which defines a circumference of the exit aperture. The assembly further includes a photodiode sensor generally that is aligned with the exit aperture of the compound parabolic concentrator. An optical adhesave layer adheres the exit aperture of the compound parabolic concentrator to the photodiode sensor. A protrusion extends between at least a portion of the perimeter of the compound parabolic concentrator exit aperture and the photodiode.

A head mounted device including an environment sensing module configured to sense at least one parameter of an environment of the user of the head mounted device, the sensing module including: a sensor configured to sense a parameter of the environment of the user of the head mounted device, and a communication component configured to send data sensed by the sensor indicative of the parameter to an analyzing module, wherein the parameter relates to the air in the direct environment of the user and/or the electromagnetic wave in the direct environment of the user and/or the acoustic wave in the direct environment of the user.

An optical sensor includes a first LED, a second LED, a first PD, and a second PD. The first LED and the second LED are configured to irradiate an optical-axis center point of an intermediate transfer belt. The first PD is arranged at a position at which specularly reflected light of light emitted from the first LED and diffused reflected light of light emitted from the second LED are received. The second PD is arranged at a position at which diffused reflected light of the light emitted from the first LED is received.

A photocell cover, including a jacket that defines a jacket cavity and a jacket opening, that is operable to be used by the user at any time of day and in any level of ambient light. The invention achieves this object by providing a photocell cover to cover a photocell and its housing, blocking any ambient light from reaching the photocell, in order to provide an environment in which the photocell can be tested. The jacket cavity and jacket opening receive a housing of a photocell and simulate a low level of ambient light in the area surrounding the photocell in order to test the functionality of the photocell. The method of using the photocell cover allows the user to test the photocell during any time of day or night, including from a ground level position.

A sensor is disclosed that provides measurements in multiple degrees of freedom without significantly increasing size, complexity, or cost. The sensor can include a light component in support of a first light source operable to direct a first beam of light, and a second light source operable to direct a second beam of light. The sensor can also include an imaging device that can directly receive the first beam of light and the second beam of light and convert these into electric signals. The imaging device and the light component can be movable relative to one another. The sensor can further include a light location module and/or a position module configured to receive the electric signals and determine locations of the first beam of light, the second beam of light on the imaging device and a relative position of the imaging device and the light component.

Various embodiments of a light detection device and a method of using such device are disclosed. In one or more embodiments, the light detection device can include a housing including a top surface and a bottom surface, where the housing extends along a housing axis between the top surface and the bottom surface; and a support member connected to the housing and adapted to be selectively moved from a closed position to an open position. The support member is further adapted to maintain the light detection device in an upright position when the bottom surface and the support member are in contact with a working surface and the support member is in the open position.

A protection system and operating method thereof promotes the longevity of components of a control subsystem. The protection apparatus may include a first connector for connecting to the control system and a second connector for connecting to a target system. The protection apparatus detects states of a component of the control subsystem over time and causes a state transition of a switching circuit of the protection apparatus based on the detected states of the control subsystem. The state transition of the switching circuit of the protection system may be initiated after a defined period of time has elapsed after detecting states of the control subsystem component. The state transition of the switching circuit may be a transition between an open state in which power is not provided to a node of the second connector and a closed state in which power is provided to the node of the second connector.

An optical sensor assembly is provided. The optical sensor assembly includes a circuit board, an optical sensor positioned on the circuit board, and a front cover attached to the circuit board and covering the optical sensor. The front cover includes an optical element configured to guide or condense an incident light of a predetermined wavelength onto the optical sensor. The front cover is made of polypropylene or polyethylene. The predetermined wavelength is in a range from 8 micrometers to 12 micrometers.

To provide a solid-state light-receiving device for ultraviolet light which can measure the amount of irradiation with ultraviolet light harmful to the human body using a simplified structure and properly and accurately, which can be readily integrated with a sensor of a peripheral circuit, which is small, light-weight, and low-cost, and which is suitable for mobile or wearable purposes. One solution is a solid-state light-receiving device for ultraviolet light which is provided with a first photodiode (1), a second photodiode (2), and a differential circuit which receives respective signals based on outputs from these photodiodes, wherein a position of the maximum concentration of a semiconductor impurity is provided in each of the photodiodes (1,2) and in a semiconductor layer region formed on each photodiode, and an optically transparent layer having a different wavelength selectivity is provided on a light-receiving surface of each photodiode.