Disclosed are a mobile device and method which include acquiring, by an image acquisition unit installed in a mobile device, an image of eyes of a patient while light provided by a light source reflects from an optical surface of the eyes of the patient; and obtaining, by a processor installed in the mobile device, ocular misalignment measurements, including a magnitude and a direction of ocular misalignment in the eyes of the patient, using the acquired image or set of images.

In a sound source display system, an omnidirectional camera captures an image of a monitoring area. A microphone array collects a voice in the monitoring area. A monitoring monitor displays the image of an imaging area captured by the omnidirectional camera. A sound pressure calculator in a directivity control device calculates a sound pressure indicating a source of a sound in the image of the imaging area using voice data of the voice collected by the microphone array. An output controller in the directivity control device compares the sound pressure and threshold values (first threshold value, second threshold value), and causes sound image information in which the sound pressure is converted into visual information according to the result of comparison, to be displayed on the monitoring monitor so as to be superimposed on the image of the imaging area.

An interactive container creation method, apparatus and system. The method includes creating a list, deploying the list to at least one device, calibrating and identifying touch areas, identifying at least one of an asset and a shape to be defined as a touch area, identifying the x,y axis of each point for a predetermined number of points for each of the at least one of asset or shape, and creating a touch area based of the identified x,y axis.

The invention relates to a portable textile treatment device (1) comprising a heatable sole plate (4) intended to be in contact with a textile (TXT) for treating the textile. The portable textile treatment device also comprises an image sensor (5) for taking an image of the textile to be treated, an illumination system (6) for illuminating a portion of the textile when said image is being taken. The portable device also comprises a control unit (8) configured for executing an algorithm stored in said portable textile treatment device, using the taken image as an input of said algorithm, to obtain a classification of the textile; and controlling, based on said classification, at least one operating parameter of the portable textile treatment device. The image sensor and the control unit are integrated within the portable textile treatment device. The image sensor comprises an active surface sensitive to light, the image sensor being oriented with respect to the surface of the heatable sole plate (4), with an absolute value of an orientation angle being in the range from 15 to 70 degrees; and/or the illumination system (6) comprises a light source oriented with respect to the surface of the heatable sole plate (4) being in contact with the textile, with an absolute value of an orientation angle being in the range from 15 to 70 degrees.

An optical detection system for a vehicle having a detection region for recording a section of the surroundings. The optical detection system has an image receiver chip having a maximum number of pixels. During the recording of an image of the surroundings a number of pixels is active in a pixel region to be evaluated of the image receiver chip. The maximum number of pixels of the image receiver chip is greater than the number of pixels of the pixel region to be evaluated. The optical detection system detects a region lying behind the vehicle and is designed such that, if the tailgate is moved, the detection region remains substantially unchanged as a result of a change to the pixel region to be evaluated on the image receiver chip. A method for retaining a detection region of an optical detection system is also disclosed.

Disclosed herein is a surround camera system for autonomous driving. The surround camera system includes: at least one forward surveillance camera configured to monitor a region in front of a vehicle; at least one backward surveillance camera configured to monitor a region behind the vehicle; one or more side surveillance cameras configured to monitor both sides alongside the vehicle; a monitoring means configured to display each of acquired images; and a video control unit configured to process the images acquired via the forward surveillance camera, the backward surveillance camera, and the side surveillance camera, to transmit the processed images to the monitoring means, to detect a target object from the acquired images, analyze the target object, and issue a warning to a driver, and to control the electronic control unit of the vehicle; wherein a 360-degree omnidirectional region around the vehicle is monitored.

Embodiments of this application disclose a method for photographing VR content by a computing device. The method includes: obtaining first position and first rotation of a VR display device; obtaining a photographing parameter including a distance between a virtual camera and a target object displayed in the display device; calculating second position of the camera according to the first position and the photographing parameter, and second rotation of the camera according to the first rotation; calculating a real-time direction of the camera according to the second position and the second rotation; and recording, according to the real-time direction of the camera, image information including the target object photographed by the camera. The embodiments of this application further provide a computing device for providing a universal photographing manner in VR applications, and the photographing manner is not limited to photographing functions of the VR applications.

A camera captures an image of a subject, and a light source illuminates with light a plane intersecting an optical axis of the camera at a prescribed angle. The processor generates guidance information related to a distance between the subject and the light source on the basis of a pixel value distribution of the image of the subject which is illuminated with the light, and outputs the generated guidance information.

An image processing apparatus that is capable of communicating with an image capturing apparatus, acquires a first image generated by performing an image capture process at a first zoom magnification, sets a division condition for dividing a detection range included in the first image, divides the detection range into a plurality of divided areas in accordance with the division condition, controls the image capturing apparatus to change an image capture direction on the basis of each position of the respective divided areas of the detection range and performs an image capture process at a second zoom magnification greater than the first zoom magnification so as to sequentially generate second images, acquires each of the second images, and performs a data reading process for each of the second images.

The image processing apparatus includes a calculator configured to calculate, using luminance values of one or more input images produced by photoelectric conversion of multiple polarized lights whose polarization angles are mutually different, an angle-dependent component at a specific polarization angle among angle-dependent components that are luminance components changing depending on the polarization angle. The apparatus further includes a producer configured to produce an output image using the angle-dependent component at the specific polarization angle.