Abstract: A vehicle front camera module integrated with a rearview mirror includes a windshield bracket module fixed to a central upper end of a windshield of a vehicle, a camera module fixed to the windshield bracket module and at which a pair of lenses for taking forward images of the vehicle are disposed to be laterally spaced apart from each other, and a rearview mirror coupled to the windshield bracket module through a supporter which is coupled to the windshield bracket module in front of the pair of lenses and extending downward so as not to interfere with respective angles of view of the pair of lenses. This arrangement enables the camera module to have a compact design with improved visibility for a safe driving experience.

Abstract: A multi view image display apparatus and a control method thereof are provided. The display apparatus includes an image inputter configured to receive an image, a display configured to display a multi view image that is generated based on the received image, and a processor configured to render views having different viewpoints based on a depth of the received image, expand a normal viewing area based on a cyclic mapping, adjust pixel values of the views so that a view jumping amount of a view jumping area occurring on a reverse viewing area due to the expansion of the normal viewing area is equal to a value, and generate the multi view image based on the adjusted pixel values.

Abstract: A method of an electronic device and an electronic device are provided. The method includes acquiring at least one captured image; determining a place corresponding to the at least one captured image by comparing the at least one captured image to at least one designated image; and performing at least one function in response to the determined place. The electronic device includes a memory configured to store a captured image; and at least one processor configured to acquire at least one captured image, determine a place corresponding to the captured image by comparing the captured image to at least one designated image, and perform at least one function in response to the determined place.

Abstract: An image processing apparatus comprises an image obtaining unit configured to obtain an omnidirectional image, a traveling direction obtaining unit configured to obtain information on a traveling direction of an image capturing apparatus when the omnidirectional image was shot, and a processing unit configured to perform processing of panoramic expansion on the omnidirectional image obtained by the image obtaining unit, based on the information on the traveling direction obtained with the traveling direction obtaining unit, such that an image portion corresponding to the traveling direction is positioned at a horizontal center in a panoramically expanded image, wherein the processing unit performs processing of panoramic expansion in accordance with change in the traveling direction in a case where the traveling direction changes while shooting the omnidirectional image that is a moving image.

Abstract: A method for performing a visual inspection of a gas turbine engine may generally include inserting a plurality of optical probes through a plurality of access ports of the gas turbine engine. The access ports may be spaced apart axially along a longitudinal axis of the gas turbine engine such that the optical probes provide internal views of the gas turbine engine from a plurality of different axial locations along the gas turbine engine. The method may also include coupling the optical probes to a computing device, rotating the gas turbine engine about the longitudinal axis as the optical probes are used to simultaneously obtain images of an interior of the gas turbine engine at the different axial locations and receiving, with the computing device, image data associated with the images obtained by each of the optical probes at the different axial locations.

Abstract: The disclosure provides an approach for predicting trajectories for real-time capture of video and object tracking, while adhering to smoothness constraints so that predictions are not excessively jittery. In one embodiment, a temporally consistent search and learn (TC-SEARN) algorithm is applied to train a regressor for camera planning. A automatic broadcasting application first receives video input captured by a human-operated camera and another video input captured by a stationary camera with a wide field of view. The automatic broadcasting application extracts feature vectors and pan-tilt-zoom states from the stationary camera input and human-operated camera input, respectively. The automatic broadcasting application further applies the TC-SEARN algorithm to learn a sequential regressor for predicting camera trajectories, based on the extracted feature vectors and pan-tilt-zoom states.

Abstract: A vision system for a vehicle is provided including a camera for capturing images within a field of view; a display device movably mounted relative to the vehicle for displaying a portion of the field of view of the camera; a movement sensor for sensing movement of the display device; and a processing circuit in communication with the movement sensor, the display device, and the camera for selecting the portion of the field of view to be displayed on the display device in response to movement of the display device as sensed by the movement sensor.

Abstract: A three-dimensional shape measuring apparatus includes a light source, an optical sensor, and an imaging unit that images a sensor signal. The three-dimensional shape measuring apparatus includes: a storing unit that stores control information indicating a state of the three-dimensional shape measuring apparatus at a point in time of imaging, the control information being obtained in synchronization with the imaging of the sensor signal performed by the imaging unit; and an output control unit that controls a transfer timing of the control information stored in the storing unit in accordance with a transfer timing of image data obtained by the imaging unit so as to output the control information to an image transfer path in association with the image data.

Abstract: Devices and methods for providing seamless preview images for multi-camera devices having two or more asymmetric cameras. A multi-camera device may include two asymmetric cameras disposed to image a target scene. The multi-camera device further includes a processor coupled to a memory component and a display, the processor configured to retrieve an image generated by a first camera from the memory component, retrieve an image generated by a second camera from the memory component, receive input corresponding to a preview zoom level, retrieve spatial transform information and photometric transform information from memory, modify at least one image received from the first and second cameras by the spatial transform and the photometric transform, and provide on the display a preview image comprising at least a portion of the at least one modified image and a portion of either the first image or the second image based on the preview zoom level.

Abstract: A camera device of one embodiment is provided with an image capturing unit configured to capture image of a room interior; a receiving unit configured to receive an image capturing instruction for capturing image of the room interior by way of a home appliance; and a camera-side controller being configured to standby in a low-power mode consuming relatively less electric power compared to a normal-operation mode and being configured to capture image of the room interior through the image capturing unit by returning to the normal-operation mode when the receiving unit receives the image capturing instruction.

Abstract: An encoding, a decoding method, a system for encoding and decoding, an encoder, and a decoder are provided. The encoding method includes the following. In a palette mode, if colors of pixels of a coding unit block are all represented by one or more major colors of the coding unit block, a flag is set as a first state value, and if the color of at least one pixel of the coding unit block is not represented by the one or more major colors of the coding unit block, the flag is set as a second state value. The encoding method further includes establishing a palette table corresponding to the coding unit block according to a state value of the flag and the one or more major colors.

Abstract: An oral monitoring system is provided. The oral monitoring system includes one or more cameras configured for installation in a mouth for capturing images. A memory is configured for storing images. One or more processors are configured to process images captured by the one or more cameras, and a wireless transmitter is configured to transmit data corresponding to the captured images. A chemical sensor is further provided and the wireless transmitter is further configured to transmit data corresponding to substances detected by the chemical sensor.

Abstract: A control apparatus includes a projection unit configured to project a first pattern onto an object; and a selection unit configured to select a single first pattern from a plurality of first patterns. After the projection unit projects each of the plurality of first patterns having different resolutions onto the object, the projection unit projects a second pattern onto the object, the second pattern having the same resolution as that of the selected single first pattern.

Abstract: A monitoring apparatus includes a processor, wherein the monitoring apparatus images a monitoring area and outputs a moving image of the monitoring area, and the processor detects all persons appearing in the moving image, performs mask processing of changing inner portions of outlines of all persons into translucent mask images, and superposes the mask images on a background image, to generate a mask-processed moving image, and outputs the mask-processed moving image to a browsing apparatus through a network.

Abstract: The present invention relates to a method of visualizing a downhole environment using a downhole visualization system. The downhole visualization system comprises a downhole tool string comprising one or more sensors, a downhole data processing means for processing the sensor signals to provide sensor data, an uphole data processing means for uphole processing and visualization, and a data communication link operable to convey the sensor data from the downhole data processing means to the uphole data processing means, the sensors being capable of generating sensor signals indicative of one or more physical parameters in the downhole environment. The downhole visualization system further comprises a downhole data buffering means capable of receiving the sensor data from the downhole data processing means and temporarily storing the sensor data in the downhole data buffering means.

Abstract: Systems, methods, and apparatus for space surveillance are disclosed herein. In one or more embodiments, the disclosed method involves scanning, by at least one sensor on at least one satellite in super-geostationary earth orbit (super-GEO), a raster scan over a field of regard (FOR). In one or more embodiments, the scanning is at a variable rate, which is dependent upon a target dwell time for detecting a target of interest. In at least one embodiment, the target dwell time is a function of a characteristic brightness of the target.

Abstract: A method of generating 3D information including: varying the distance between the sample and an objective lens of the optical microscope at pre-determined steps; capturing an image at each pre-determined step; determining a characteristic value of each pixel in each captured image; determining, for each captured image, the greatest characteristic value across a first portion of pixels in the captured image; comparing the greatest characteristic value for each captured image to determine if a surface of the sample is present at each pre-determined step; determining a first captured image that is focused on an apex of a bump of the sample; determining a second captured image that is focused on a first surface of the sample based on the characteristic value of each pixel in each captured image; and determining a first distance between the apex of the bump and the first surface.

Abstract: Systems, methods, and computer-readable media for feedback on and improving the accuracy of super-resolution imaging. In some embodiments, a low resolution image of a specimen can be obtained using a low resolution objective of a microscopy inspection system. A super-resolution image of at least a portion of the specimen can be generated from the low resolution image of the specimen using a super-resolution image simulation. Subsequently, an accuracy assessment of the super-resolution image can be identified based on one or more degrees of equivalence between the super-resolution image and one or more actually scanned high resolution images of at least a portion of one or more related specimens identified using a simulated image classifier. Based on the accuracy assessment of the super-resolution image, it can be determined whether to further process the super-resolution image. The super-resolution image can be further processed if it is determined to further process the super-resolution image.

Abstract: The present invention provides an imaging device capable of greatly reducing the assignment number of light reception cells assigned to each microlens of an array lens and increasing the number of pixels of images having different characteristics that are captured simultaneously. One aspect of the present invention is an imaging device that includes an imaging optical system including a center optical system (wide-angle lens) and an annular optical system (telescopic lens) that share an optical axis, an image sensor, and an array lens arranged on the incidence side of the image sensor and including microlenses (pupil imaging lenses). The array lens causes annular pupil images corresponding to the annular optical system adjacent to each other among a center pupil image and annular pupil images formed on the image sensor by the respective microlenses to partially overlap each other on the image sensor.

Abstract: Method and apparatus of video coding using coding modes including Intra Block Copy (IntraBC) for a video coding system incorporating multi-stage pipeline processing is disclosed. In order to overcome data dependency issue due to the use of pipeline architecture, a first embodiment uses constrained previous reconstructed region for IntraBC estimation by excluding unavailable reconstructed previous reconstructed data due to the multi-stage pipeline processing. In the second embodiment, the unavailable reconstructed data is replaced by source pixel data.