A mirror for camera system includes a substrate, a mirror layer, a fluorescent layer and an excitation window layer. The substrate is provided at a position opposed to an objective lens of an infrared camera, and transmits visible light and infrared light. The mirror layer is provided on a main surface of the substrate, which is the side opposed to the infrared camera, and reflects visible light and transmits infrared light. The fluorescent layer is provided in at least a part of the surface of the mirror layer, and emits at least infrared light as a result of receiving predetermined excitation light. The excitation window layer is provided so as to cover the fluorescent layer, and transmits the excitation light and reflects, at least, the infrared light.

A system and method are provided for a wireless device for use with a first video conference device, a second video conference device, WAN and an item. The video conference devices are configured to establish a video conference over a secure communication channel over the WAN. The first video conference device is additionally configured to transmit a video conference invitation in response to a video conference request from the wireless device, the video conference invitation including credentials to establish a communication channel with the first video conference device. The second video conference device is additionally configured to transmit a magnification control signal. The wireless device is configured to: image the item in a first magnification; transmit first image data of the item based on the first magnification; change the magnification; image the item in a second magnification; and transmit second image data of the item based on the second magnification.

A system and method are provided for a wireless device for use with a first video conference device, a second video conference device, WAN and an item. The video conference devices are configured to establish a video conference over a secure communication channel over the WAN. The first video conference device is additionally configured to transmit a video conference invitation in response to a video conference request from the wireless device, the video conference invitation including credentials to establish a communication channel with the first video conference device. The second video conference device is additionally configured to transmit a magnification control signal. The wireless device is configured to: image the item in a first magnification; transmit first image data of the item based on the first magnification; change the magnification; image the item in a second magnification; and transmit second image data of the item based on the second magnification.

A camera system for collecting image data in a clinical environment includes a camera configured to acquire color (RGB), near-infrared, and depth image data and a plurality of LED modules held proximate to the camera such that the LED modules are configured to illuminate a subject while image data is collected by the camera. The camera system also includes a microcontroller in electrical communication with the camera and the plurality of LED modules. The microcontroller is configured to actuate the plurality of LED modules and the camera such that the camera acquires the image data. A computing device is in electrical communication with the camera and the microcontroller.

A detection device includes: a detector that detects an object from a first viewpoint; an information calculator that calculates first model information including shape information on the object from the first viewpoint by using detection results of the detector; a light source calculator that calculates light source information on the light source by using a first taken image obtained by imaging a space including a light source that irradiates the object with illumination light and including the object; and a position calculator that calculates a positional relation between the first viewpoint and the object by using the light source information as information used to integrate the first model information and second model information including shape information obtained by detecting the object from a second viewpoint different from the first viewpoint.

An imaging system includes a light source, an image sensor and a processing unit. The image sensor alternatively captures a first bright image, a first dark image, a second bright image and a second dark image, wherein the first bright image is captured with a first exposure time corresponding to activation of the light source within a first time interval, the first dark image is captured with the first exposure time corresponding to deactivation of the light source within the first time interval, the second bright image is captured with a second exposure time corresponding to activation of the light source within a second time interval, and the second dark image is captured with the second exposure time corresponding to deactivation of the light source within the second time interval, wherein the second exposure time is longer than the first exposure time. The processing unit adjusts the second exposure time according to an object image size in the second dark image, and controls the image sensor to stop capturing the first bright and dark images with the first exposure time when no object image is contained in the second dark image.

An ingestible device comprising a capsule, a camera, an antenna, and a propulsion component id disclosed. The camera can capture images of various in vivo environments as the ingestible device traverses the gastrointestinal tract, and these images can be wirelessly transmitted to an electronic device located outside of the living body. The images may be transmitted to the electronic device for review by an operator responsible for controlling the ingestible device.

A vehicle detecting device includes: a camera that includes an image sensor and a first filter, the image sensor including a plurality of imaging elements including a first imaging element group and a second imaging element group, the first filter keeping an amount of light entering the first imaging element group lower than an amount of light entering the second imaging element group; an image generating unit that generates a first image based on information obtained from the first imaging element group and a second image based on information obtained from the second imaging element group; and a detecting unit that detects a front vehicle based on the first image and the second image.

Embodiments of present invention provide a method for checking integrity of a device selection process. The method includes placing multiple devices in a device tray that has multiple cells arranged in a matrix of M-rows and N-columns; separating the multiple devices into a first group and a second group; causing a machine to memorize locations of at least the first group; removing the second group from the device tray; after the removing, causing the machine to capture an image of devices remaining in the device tray and identify locations of the remaining devices based upon the image; comparing locations so identified with locations of the first group of devices memorized by the machine; and taking a corrective action when a discrepancy is found between the locations identified and locations memorized. An apparatus for performing the above method is also provided.

A system for obtaining a measurement representative of a thickness of a layer on a substrate includes a support to hold a substrate, an optical assembly to capture two color images with light impinging the substrate at different angles of incidence, and a controller. The controller is configured to store a function that provides a value representative of a thickness as a function of position along a predetermined path in a coordinate space of at least four dimensions. For a pixel in the two color images, the controller determines a coordinate in the coordinate space from the color data, determines a position of a point on the predetermined path that is closest to the coordinate, and calculates a value representative of a thickness from the function and the position of the point on the predetermined path.