An imaging system includes a light source that, in operation, emits an emitted light containing a near-infrared light in a first wavelength region, an image sensor, and a double-band pass filter that transmits a visible light in at least a part of a wavelength region out of a visible region and the near-infrared light in the first wavelength region. The image sensor includes light detection cells, a first filter that selectively transmits the near-infrared light in the first wavelength region, second to fourth filters that selectively transmit lights in second to fourth wavelength regions, respectively, which are contained in the visible light, and an infrared absorption filter. The infrared absorption filter faces the second to fourth filters and absorbs the near-infrared light in the first wavelength region.

Methods and apparatus for the stitching of images from a multi-camera array. In one embodiment, stitching is performed for a first image and a second image with an overlapping field of view by: encoding the first image to produce a first encoded image; encoding the second image to produce a second uncompressed encoded image; stitching the first image with the second image by: decoding the first encoded image to produce a decoded first image; storing the decoded first image in memory; accessing, by a stitching engine, the decoded first image from memory; accessing, by the stitching engine, the second uncompressed encoded image; stitching, by the stitching engine, the decoded first image with the accessed second uncompressed encoded image to produce a stitched image; and outputting, by the stitching engine, the stitched image.

Example embodiments relate to microlensing for real-time sensing of stray light. An example device includes an image sensor that includes a plurality of light-sensitive pixels. The device also includes a first lens positioned over a first subset of light-sensitive pixels selected from the plurality of light-sensitive pixels. Further, the device includes a controller. The controller is configured to determine a first angle of incidence of a first light signal detected by the first subset of light-sensitive pixels. The controller is also configured to, based on the first determined angle of incidence, determine an amount of stray light incident on the image sensor.

Example embodiments relate to microlensing for real-time sensing of stray light. An example device includes an image sensor that includes a plurality of light-sensitive pixels. The device also includes a first lens positioned over a first subset of light-sensitive pixels selected from the plurality of light-sensitive pixels. Further, the device includes a controller. The controller is configured to determine a first angle of incidence of a first light signal detected by the first subset of light-sensitive pixels. The controller is also configured to, based on the first determined angle of incidence, determine an amount of stray light incident on the image sensor.

Apparatus, systems and methods for managing a workforce working from a single or multiple locations through software and hardware components integrated under a modular solution for workforce management tasks, such as worker's biometric recognition, hiring, enrollment, time and attendance capturing, access control, tracking and managing schedules, overtime, leaves, holidays, absence, breaks, official and personal time-outs, trainings, assets, vehicles and transport, work orders and tasks, payroll and performance management, and reporting.

A sealed active marker apparatus of a performance capture system is described to provide protective housing for active marker light components coupled to a strand and attached via a receptacle, to an object, such as via a wearable article, in a live action scene. The receptacle includes a protrusion portion that permits at least one particular wavelength range of light emitted from the enclosed active marker light component, to diffuse in a manner that enables easy detection by a sensor device. A base portion interlocks with a bottom plate of the receptacle to secure the strand within one or more channels. A sealant material coating portions of the apparatus promotes an insulating environment for the active marker light component.

An imaging apparatus and an imaging method are provided. The imaging apparatus includes an imager configured to output image data for a subject, a motion detector configured to detect motion of the imaging apparatus, and a controller configured to control the imager to suspend output of the image data in response to the motion detector detecting the motion.

The present disclosure relates to a solid-state imaging device and an electronic device that can be provided with phase difference pixels with a lower degree of difficulty in manufacturing.

Provided is a solid-state imaging device including a pixel array unit in which a plurality of pixels is two-dimensionally arrayed, in which the pixel array unit has an array pattern in which a plurality of pixel groups each including neighboring pixels of an identical color is regularly arrayed, and among the plurality of pixel groups arrayed in the array pattern, pixels configuring a light-shielded pixel group are shielded in an identical direction side from light, the light-shielded pixel group being a pixel group including pixels each being shielded in a part of a light incident side from the light. The present technology can be applied to, for example, a CMOS image sensor including pixels for phase difference detection.

A night vision apparatus having a camera assembly with a camera housing that has a charge-coupled device image sensor, an infrared illuminator assembly, and a first base assembly. Further having a switch assembly and a display assembly. The camera housing has a top face, a bottom face, a front face, a lens, and an adaptor. The lens has a focal length of approximately 25 mm or 50 mm. The infrared illuminator assembly has a housing, an infrared illuminator lens, an infrared illuminator, and a supporting structure. The infrared illuminator is an approximately 2.5 watt illuminator that produces an approximately 10° main beam pattern. The infrared illuminator assembly is attached to the camera housing. The first base assembly has a suction cup secures the camera assembly onto a surface. The switch assembly is electrically connected to a battery assembly. The display receives and shows images captured by the camera assembly.

In a vehicle-mounted camera system, an appropriate white balance correction processing according to a situation is executed to a long exposure time image and a short exposure time image shot in variously changing illumination environments. A vehicle-mounted camera system includes a vehicle-mounted camera that performs relatively long exposure time shooting and short exposure time shooting, a signal processing device (signal processing device) that executes a white balance correction processing for each of a long exposure time image and a short exposure time image, composes these images after the white balance correction processing, and generates a high dynamic range image, and a system control part (processing switch device) that obtains an illumination environment in which the vehicle is placed, and switches the white balance correction processing for the long exposure time image and the white balance correction processing for the short exposure time image according to the illumination environment.