Abstract: An image generating apparatus generates a vicinity image including a vehicle and a vicinity of the vehicle viewed from a virtual viewpoint, based on a captured image, and generates a combined image by superimposing a vehicle image of the vehicle on the vicinity image. Then the image generating apparatus generates the vehicle image in a frame style that shows a body frame of the vehicle by frame lines and changes a style form in the frame style in accordance with a predetermined condition.

Abstract: A time-of-flight camera, having a time-of-flight sensor, which has at least one receiving pixel and is configured as a photomixing detector, having an illumination means, and having a modulator, which is connected to the time-of-flight sensor and to the illumination means, wherein a control sensor is arranged in the region of the illumination means such that at least some of the radiation emitted by the illumination means can be received by the control sensor is provided.

Abstract: A method for disseminating information regarding a problem and administering medical interventions comprises providing a mobile device wirelessly connectable to a network, receiving and storing contact information corresponding to a designated list of information recipients, receiving, via the mobile device and via the wireless trigger transmitting to the mobile device, a signal from a user indicating the problem, receiving, via the mobile device, information regarding the problem, transmitting an indication of the problem to a rescue clearinghouse via the network, prompting a participant of the rescue clearinghouse, different from the user, to make a decision about a course of action regarding the problem, and at least one of transmitting the information regarding the problem to the information recipients from the designated list and transmitting the information regarding the problem to a government rescue organization, based at least in part on the decision.

Abstract: A vehicle imaging system includes an image capture device capturing an image exterior of a vehicle. The captured image includes at least a portion of a sky scene. A processor generates a virtual image of a virtual sky scene from the portion of the sky scene captured by the image capture device. The processor determines a brightness of the virtual sky scene from the virtual image. The processor dynamically adjusts a brightness of the captured image based the determined brightness of the virtual image. A rear view mirror display device displays the adjusted captured image.

Abstract: In one embodiment, a method comprising receiving at a single encoding engine an input video stream having one or more pictures of a first size; and generating by the single encoding engine, in parallel, plural encoded streams, a first of the encoded streams comprising one or more pictures of the first size and a second of the encoded streams comprising one or more pictures of a second size that is smaller than the first size, the encoding of the second stream based on sharing video coding information used in encoding the first encoded stream.

Abstract: The invention concerns a method and a system for purposes of registering the position of a vehicle (1) in a defined region (3), wherein a digital map of the defined region (3) is created, having a defined coordinates system, wherein the digital map includes stationary reference features (T1) with a unique identifying feature, before digital images are recorded of at least a sub-region of the defined region (3), preferably of the whole defined region (3), for purposes of registering and detecting further reference features (T1, T2, T3), wherein stationary and/or temporary reference features (T2, T3) without unique identifying features are also registered and detected, and are added to the digital map and/or an associated buffer store, so that the absolute position of the vehicle (1) in the defined region (3) can subsequently be determined, in that a digital image of a portion of the defined region (3) is recorded by the vehicle (1), and in the digital image reference features (T1, T2, T3) are detected and opti

Abstract: The present invention relates to transmission and reception of digital broadcast in a digital broadcast network supporting a configuration of multiple physical layer pipes (PLPs). In particular, signalling parameters relating to a complete PLP are transmitted within layer 1 signalling related to the PLP. The baseband frames mapped on the pipe are configured according to this layer 1 signalling in the same way at the transmitter as they are demapped on the receiver side. The baseband frames are transmitted and received without including these parameters, in particular, at least one of parameters indicating (i) an input stream format, (ii) a single or a multiple input stream, (iii) constant or adaptive coding and modulation, (iv) presence of input stream synchronization, (v) presence of null packet deletion, or (vi) input stream identifier.

Abstract: The invention provides systems and methods for imaging a sample. In various embodiments, the invention provides a system comprising an image sensor, a laser for emitting excitation light for an infrared or near-infrared fluorophore, a visible light source, a notch beam splitter, a notch filter, a synchronization module, an image processing unit, an image displaying unit, and light-conducting channels. In various embodiments, the present invention provides a system comprising an image sensor, a laser for emitting excitation light for an infrared or near-infrared fluorophore, a laser clean-up filter, a notch filter, a white light source, an image processing unit, an image displaying unit, and light-conducting channels. In accordance with the present invention, the image sensor can detect both visible light and infrared light.

Abstract: According to one embodiment, a motion vector detection apparatus includes following units. The layering unit generates layers with different resolutions for each of first and second images. The first extraction unit extracts a space candidate vector. The second extraction unit extracts a time candidate vector. The third extraction unit extracts a layer candidate vector. The determination unit determines a motion vector to be assigned to the target block, based on correlations between the target block and blocks, the blocks being located in a layer which corresponds to the second image and being specified by assigning, to the target block, the space, time, and layer candidate vectors.

Abstract: Disclosed is an operation method of an endoscope, the method comprising: a sheath insertion step of percutaneously inserting at least one sheath in a pericardial cavity of a heart; an insertion step of inserting a rigid scope in the sheath; a view field securing step for securing the view field for a surgical site within the pericardial cavity; a guide step for guiding the rigid scope to the surgical site; and an observation step of observing the surgical site with the rigid scope.

Abstract: A control unit shifts an imaging unit relatively with respect to a stage to take an image of a measuring object at a plurality of places by the imaging unit and thereby obtain a plurality of images, and generates a composite image of the measuring object having a range which is wider than an imaging range of the imaging unit by combining the plurality of images. The control unit shifts the imaging unit relatively with respect to the stage such that parts of images adjacent to one another obtained by the imaging unit overlap, and performs an image matching processing that performs image matching of an overlapped portion of the adjacent images. The control unit generates the composite image of the measuring object by joining the adjacent images at a position where the image matching is performed in the image matching processing.

Abstract: An image processing device includes a processor; and a memory which stores a plurality of instructions that cause the processor to execute, capturing an image including vehicle side information, dividing the image into a plurality of areas, and defining a first divided area image including a center of a side end of the image and a second divided area image not including the center of the side end of the image; smoothing the first divided area image using a first filter, or smoothing the second divided area image using a second filter having a greater coefficient than that of the first filter; extracting a plurality of feature points from the first divided area image or the second divided area image; calculating an optical flow from the plurality of feature points of the first divided area image or the second divided area image.

Abstract: A method of processing three-dimensional image data includes demodulating a first transmission signal into image data which is image data for a left-eye or image data for a right-eye, wherein the first transmission signal is received during an enable period of a frame; demodulating a second transmission signal into identification data, where the second transmission signal is received during a blanking period of the frame, and the identification data identifies the image data of a subsequent frame; identifying whether the image data of the subsequent frame is the image data for the left-eye or the image data for the right-eye based on the identification data; and processing the image data based on an identified result from the identifying whether the image data of the subsequent frame is the image data for the left-eye or the image data for the right-eye.

Abstract: An image signal processing device is provided which includes a receiving unit for receiving an image signal and setting information for each predetermined unit of the image signal including image type setting information to define whether the image signal represents a stereoscopic image and gamma correction setting information to define a gamma correction amount for the image signal, a gamma correcting unit for performing gamma correction for the image signal based on the gamma correction setting information included in the setting information received by the receiving unit, and a stereoscopic image processing unit for selectively performing a process to display the stereoscopic image for the image signal corrected by the gamma correcting unit based on the image type setting information included in the setting information received by the receiving unit.

Abstract: An input stereoscopic video signal has a first frame sequence (SL) in a left-eye channel and a second frame sequence (SR) in a right-eye channel, the second frame sequence (SR) having a zero or non-zero time offset ?1 with respect to the first frame sequence (SL). It is converted into an output stereoscopic video signal having a third frame sequence (S?L) in the left-eye channel and a fourth frame sequence (S?R) in the right-eye channel. The fourth frame sequence (S?R) has a zero or non-zero time offset ?2 with respect to the third left-eye frame sequence (S?L). The two time offsets ?1, ?2 may be different ?2??1), in which case the conversion comprises a time interpolation of the frames of at least one of the first and second frame sequences with interpolation parameters selected to apply a relative time shift of ?2??1 to the right-eye channel with respect to the left-eye channel.

Abstract: There is provided: a CPU that, in at least one case among a case in which fluctuation of a fixed interval in the acquired parallax amount is greater than a predetermined value, and a case in which the parallax amount reaches a predetermined allowed limit value, or a case in which an object of acquisition of the parallax amount can no longer be detected, judges that there is an abnormality in the parallax amount, and that, in a case that is none of these, judges that there is no abnormality in the parallax amount, and that, when it is judged that there is no abnormality in the parallax amount, carries out first parallax adjustment, and that, when it is judged that there is an abnormality in the parallax amount, switches to control of a second parallax adjustment and carries out parallax adjustment.

Abstract: A method of measuring a height of 3-dimensional shape measurement apparatus includes irradiating a first grid pattern light from a plurality of first lighting devices and a second grid pattern light from a plurality of second lighting devices which are alternatively arranged to the first lighting devices toward a target object wherein the first grid pattern light has a first equivalent wavelength and the second grid pattern light has a second equivalent wavelength that is different from the first equivalent wavelength, and obtaining a first pattern image corresponding to the first grid pattern light and a second pattern image corresponding to the second grid pattern light, generating combined pattern images by combining the first and second pattern images obtained from the first and second lighting devices adjacent to each other among the plurality of first and second lighting devices, calculating heights of the target object according to a combined equivalent wavelength of the combined pattern images, and de

Abstract: One or more display elements of an apparatus provide light representative of distant objects and near objects and at least one optical element of the apparatus is responsive to the light representative of the near objects, for providing video images of the near objects at one or more near focal lengths, and is responsive to the light representative of distant objects, for providing video images of the distant objects at one or more far focal length and positioned for viewing at an elevation above the video images of the near objects.

Abstract: A system is disclosed for measuring the crystallization of crystalline-amorphous mixtures. The system includes a sample holder. and a heating apparatus to melt a ink composition and to keep the melted ink composition at a first specified temperature for a first period of time. The system includes a cooling apparatus to receive the melted ink composition, to cool the melted ink composition and to maintain the cooled ink composition at a second specified temperature. The system includes a microscope and a video recording device to capture images of the cooled ink composition for a second period of time A video processing computer includes a memory, a processor and software instructions and the software instructions causes the computer to extract crystallization parameters about the cooled ink composition from the captured images. The crystallization parameters identify fast solidifying crystalline inks that have a short time duration from onset of crystallization until crystallization.

Abstract: In one embodiment, an element 106 transform, with a voltage, non-polarized light into plane polarized light with an arbitrary plane of polarization. A synchronizer 112 gives the plane of polarization control element 106 an instruction to rotate the plane of polarization, thereby getting the plane of polarization of the illumination rotated and casting that polarized light toward the object. At the same time, the synchronizer 112 sends a shooting start signal to an image sensor 110, thereby getting video. The synchronizer 112 performs these processing steps multiple times. A captured video signal is sent to an image processing processor 108, where LL, RR and CC images are separately generated as images of light rays that have passed through left and right polarizing areas and the central non-polarizing area and left and right parallax signals are generated and sent to a 3D display section 122.