An electronic device may include a light sensor system. The light sensor system may have a light source that emits light and a light detector that receives the emitted light after the emitted light has interacted with an external object. The light source may include a ring of light-emitting diodes or other light-emitting devices surrounding the light detector or may have light-emitting devices that are surrounded by a ring-shaped light detector. Polarizer structures may be incorporated into the light sensor system. Control circuitry in the device may control the light source so that different polarizations of light are emitted at different times. The control circuitry may process signals from the light detector that are gathered under different polarizations to discriminate between specular and non-specular reflections from the external object.

Methods and apparatus for using an indicator window of a handheld scanner as a trigger are disclosed herein. An example handheld scanner includes: a housing; an image sensor to capture image data through a front-facing opening; an indicia decoder; an indicator window positioned to face generally away from the front-facing opening and toward a user when the handheld scanner is in a handheld position; a light source disposed inside the housing to emit indication light through the window to provide an indication; a light detector disposed inside the housing and positioned to detect a reflection of the indication light received from an object positioned in front of or on the window outside the housing; and a processor configured to control a mode of the handheld scanner and/or a device in communication with the handheld scanner in response to the light detector detecting the reflection of the emitted indication light.

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 foldable display device includes a display module in which a panel hole is defined, a sensor device disposed in the panel hole, and a panel lower cover which is disposed on a surface of the display module and in which a cover hole is defined such that the sensor device is disposed in the cover hole, the panel lower cover including a buffer member and a first adhesive member, which attaches the buffer member to the surface of the display module where a minimum distance between the first adhesive member and the sensor device is greater than a minimum distance between the buffer member and the sensor device.

According to an embodiment disclosed in this specification, an electronic device may include a camera including an image sensor, a display panel, a display driver integrated circuit (DDI) that drives the display panel at a first frame rate, a memory, and a processor operatively connected to the camera, the display panel, the DDI, and the memory. The DDI may drive the display panel in a plurality of cycles to output one frame corresponding to the first frame rate. The camera may perform exposure of the image sensor in a section, in which one or more lines among lines constituting the display panel do not emit light, in the plurality of cycles. The memory may store instructions that, when executed, cause the processor to determine illuminance around the electronic device using image data according to the exposure. Moreover, various embodiment found through the disclosure are possible.

An electronic device is provided which includes a light emitting module that radiates infrared light, a window disposed on the light emitting module and having a specific refractive index with respect to the infrared light, wherein the window includes a refraction part that totally reflects the infrared light inside the window in correspondence with the specific refractive index, and a fingerprint sensor disposed under the window and obtaining a fingerprint of a user based on a user input on the window by using scattered light of the infrared light.

The invention relates to a light sensing device for sensing ambient light intensity, comprising at least one ambient light sensor and an occlusion detector for detecting an object occluding the ambient light sensor. The invention is further related to a corresponding method for sensing ambient light intensity.

A system and method for preventing sight deterioration caused by prolonged use of electronic visual displays in low-light conditions is provided. The system includes a camera directed towards a user, a processing circuitry, control circuitry and, optionally, a light sensor. The processing circuitry determines the illuminance of a user's face, and in case it falls outside of a predefined range (putting the user at risk of future sight deterioration and progression of myopia), the device stores the illuminance data and/or sends a control signal to circuitry operative to notify the user. If processing circuitry determines that the illuminance is equal or greater than the predefined illuminance, the circuitry operative can stop the notification. The notification can be modulated by any combination of the illuminance and the time of use.

A method, apparatus, and a computer program is provided. The method comprises: determining an ambient light value from ambient light data provided by at least one ambient light sensor, in dependence upon the spectral distribution of the ambient light data provided by the at least one ambient light sensor and a manufacturer of the at least one ambient light sensor.

Computing devices and methods for controlling light output of a display are disclosed. In one example, a default brightness setting is set to an indoor light output level. A UV light sensor is activated to detect UV radiation levels. Based on determining that one or more of the UV radiation levels exceed a UV threshold, the default brightness setting is updated to correspond to an outdoor light output level that is greater than the indoor light output level. Without using information from an ambient light sensor, the display is activated from a deactivated state to illuminate at the updated default brightness setting corresponding to the outdoor light output level.