Abstract: In a method for marking discrepancies of a captured image of an object, an image is captured and compared to a standard image. A discrepant image showing any discrepancies of the captured image is generated, and is separated into an R grayscale image, a G grayscale image, and a B grayscale image. An R channel matrix group, a G channel matrix group, and a B channel matrix group are created. R channel negative matrixes, G channel negative matrixes, and B channel negative matrixes are determined from the RGB channel matrix groups. RGB pixel groups are calculated based on the R channel negative matrixes, the G channel negative matrixes, and the B channel negative matrixes. A target pixel group to be marked is determined by calculating an intersection of the RGB pixel groups. The discrepancies of the digital image are marked out according to the target pixel group.

Abstract: Provided is an image coding apparatus including a decoding unit 102 decoding first coded data to generate a decoded picture and decoding information containing motion vectors and including a coding unit 104 coding, in a second coding scheme, the decoded picture generated by the decoding unit 102, to generate second coded data including a coded picture and coding information containing motion vectors. The image coding apparatus also includes a basic motion information generating unit 105 generating basic motion information from either the decoding information or the coding information, wherein the coding unit 104 determines a search range for estimating motion vectors of the decoded picture, according to the basic motion information generated by the basic motion information generating unit 105, estimates motion vectors of the decoded picture in the determined search range, and generates the second coded data including the coded picture and coding information containing the estimated motion vectors.

Abstract: Disclosed herein is a signal transmitting device including a multiplexing section configured to generate a B/R ch by alternately multiplexing image signals read from B pixels and R pixels among image signals read and input in units of a predetermined number of samples in each of the first line and the second line from said image pickup element in an active region corresponding to a C ch in HD-SDI together with start code of one of SAV and EAV, and generate a G ch by multiplexing, in order, image signals read from G pixels in an active region corresponding to a Y ch in HD-SDI together with said start code; and an 8B/10B encoder configured to output serial digital data converted by 8B/10B-encoding the active regions on the B/R ch and the G ch having data structures corresponding to said HD-SDI and an auxiliary data region including SAV, EAV, LN, and CRCC.

Abstract: An improved loss recovery method for coding streaming media classifies each data unit in the media stream as an independent data unit (I unit), a remotely predicted unit (R unit) or a predicted data unit (P unit). Each of these units is organized into independent segments having an I unit, multiple P units and R units interspersed among the P units. The beginning of each segment is the start of a random access point, while each R unit provides a loss recovery point that can be placed independently of the I unit. This approach separates the random access point from the loss recovery points provided by the R units, and makes the stream more impervious to data losses without substantially impacting coding efficiency. The most important data units are transmitted with the most reliability to ensure that the majority of the data received by the client is usable. The I units are the least sensitive to transmission losses because they are coded using only their own data.

Abstract: Provided is an image coding apparatus including a decoding unit 102 decoding first coded data to generate a decoded picture and decoding information containing motion vectors and including a coding unit 104 coding, in a second coding scheme, the decoded picture generated by the decoding unit 102, to generate second coded data including a coded picture and coding information containing motion vectors. The image coding apparatus also includes a basic motion information generating unit 105 generating basic motion information from the decoding information or the coding information selected based on a coding condition indicating a picture type of a current decoded picture to be coded. The coding unit 104 also determines a search range for estimating motion vectors of the current decoded picture, according to the basic motion information, and estimates motion vectors of the current decoded picture in the determined search range.

Abstract: Techniques are described that can be used to identify blocking artifacts in both vertical and horizontal directions. For blocking artifacts in a vertical direction, a horizontal gradient is determined for a pixel. Gradient smoothing is performed for pixels in the row of the pixel. A ratio of the horizontal gradient over the gradient smoothing is determined. Any pixel with a ratio above a threshold and in a segment with a length that exceeds a threshold length as potentially having block artifacts. Each column with pixels that potentially have block artifacts is inspected to determine whether a number of block artifacts in the column are a local maximum and whether there is a sufficient number of blocking artifacts in the column. Columns that satisfy both conditions are considered to include blocking artifacts.

Abstract: A disparity vector estimation method and an apparatus are provided for encoding and decoding a multi-view picture using the disparity vector estimation method. The method of estimating a disparity vector of a multi-view picture includes determining a disparity vector between two frames having a different viewpoint from a current viewpoint, and calculating a disparity vector of a current viewpoint frame using the determined disparity vector and a certain translation parameter.

Abstract: A cross-section processing and observation method includes: forming a first cross section in a sample by etching processing using a focused ion beam; obtaining image information of the first cross section by irradiating the focused ion beam to the first cross section; forming a second cross section by performing etching processing on the first cross section; obtaining image information of the second cross section by irradiating the focused ion beam to an irradiation region including the second cross section; displaying image information of a part of a display region of the irradiation region from the image information of the second cross section; displaying the image information of the first cross section by superimposing it on the image information being displayed; and moving the display region within the irradiation region. Observation images in which display regions are aligned can be obtained while reducing damage to the sample.

Abstract: A wide field microscopic image acquisition apparatus and method are disclosed. The apparatus is configured to acquire images of a specimen on a microscope slide and includes first and second illuminators each having unique illumination characteristics. The apparatus includes a microscope imaging system with an imaging device, an objective lens and a stage configured to digitally acquire a plurality of images of the specimen using the first and second illuminators. A controller is configured to automatically control the microscope imaging system and acquire the plurality of images of the specimen using the first and second illuminators. The first and second illuminators can be bright field, dark field or fluorescent illuminators.

Abstract: An apparatus and method for displaying a three-dimensional image according to the position of a user, in which the distance between a display panel displaying a two-dimensional image and a three-dimensional optical panel converting a two-dimensional image into a three-dimensional image is controlled in accordance with the position of the user to provide an optimized three-dimensional image. The apparatus includes a three-dimensional optical device converting a displayed two-dimensional image into a three-dimensional image, a position measurement module measuring the position of the user who converges on the three-dimensional image, a crosstalk calculator calculating the level of crosstalk that can occur in the position of the user, and a driver adjusting a position of the three-dimensional optical device if the level of crosstalk exceeds a predetermined threshold value.

Abstract: A camera angle computing device includes an image acquiring unit that acquires an image containing a first jig disposed in an overlap region of an image capturing range of a camera and an image capturing range of an adjacent camera and a second jig disposed vertically below the camera; and an angle computing unit that computes an angle of the camera from coordinates of the first jig and the second jig contained in the image acquired by the image capturing unit.

Abstract: Provided is a method of controlling view of a stereoscopic image. The method includes changing the view angle and depth information of a 3D image displayed on a display according to position information for each user; and combining at least two of a spatial division technique spatially dividing light from the display, a time division technique temporally dividing light from the display and a polarization division technique dividing light from the display into lights having polarization characteristics to divide the 3D image for the each user by using the combined technique and producing a binocular disparity of for the each user.

Abstract: A video encoding method includes selecting a reference vector target frame and a reference frame from among already-encoded frames; encoding information for designating each frame; setting a reference vector for indicating an area in the reference vector target frame with respect to an encoding target area; encoding the reference vector; performing a corresponding area search by using image information of a reference vector target area, which belongs to the reference vector target frame and is indicated by the reference vector, and the reference frame; determining a reference area in the reference frame based on the search result; generating a predicted image by using image information of the reference frame, which corresponds to the reference area; and encoding differential information between image information of the encoding target area and the predicted image.

Abstract: An interactive stereo display system and a method for calculating a three-dimensional (3D) coordinate are provided. The interactive stereo display system includes a plurality of interactive devices, a stereo display panel, and a processing unit. When the stereo display panel is irradiated by a light radiated from a light source of each interactive device, an image of each light filtered by a color filter is captured by an in-cell type optical sensor array. After receiving the images, the processing unit determines overlapping circle objects in each image and identifies the circle object formed by each light source according to a light intensity value at the center of each circle objects. Accordingly, the 3D coordinate of each interactive device relative to the stereo display panel can be calculated according to the center and a radius of each circle object corresponding to each light source.

Abstract: According to one embodiment, a decoding device includes a storage section, a control section, a decoding processing section. The storage section stores control information showing a progress state of process stages for a decoding process as to a plurality of processing data included in coded data. The control section allocates process stages corresponding to executable processing data which is executable in parallel, to a processor on the basis of the control information, a dependence relation between the processing data in the decoding process, and a dependence relation between the process stages. The decoding processing section parallelly executes allocated process stages corresponding to the executable processing data.

Abstract: A decoder is disclosed. A video decoder extracts, when receiving a video stream, video output time information attached to each video frame. Thereafter, a difference value calculator calculates a difference value between an occurrence time of a synchronizing signal and the video output time information. Further, an audio output time corrector corrects, using the difference value, audio output time information attached to each audio frame. Then, a video source outputs video represented by a video frame in synchronization with a synchronizing signal. An audio source outputs, when a value of reference time information and a corrected value of the audio output time information are synchronized, audio represented by an audio frame with the synchronized audio output time information.

Abstract: Rate control mechanisms for video encoding aim to provide the best possible video quality while keeping given conditions on transmission rate and decoding delay. In order to achieve a constant video quality, the anchor and non-anchor frames of different frame types are encoded using a different number of bits. However, since video sequences generally contain widely varying picture content and previously coded frames are used to predict a given frame, a suitable assignment of frame target bit rates is hard to determine, especially for non-anchor frames. According to the invention, non-anchor frames are coded using a fixed quantization parameter. Since the quantization parameter used for the encoding of non-anchor frames is directly derived from the average quantization parameter of the previously encoded anchor frame, such approach ensures a constant video quality.

Abstract: Disclosed is a system for transmitting a digital video stream, which supports decoding of a scalable video coding (SVC) scheme, the system includes a transmission terminal and a reception terminal, wherein the transmission terminal includes an encoder for encoding a high-definition digital video stream and a division transmission unit for dividing the high-definition video stream having a predetermined time unit into a first divided high-definition video stream and a second divided high-definition video stream by reducing a frame rate and for transmitting the first and second divided high-definition video streams, and the reception terminal includes a transmission coupling unit for receiving the first and second divided high-definition video streams transmitted from the transmission terminal, coupling the received streams according to validity thereof, and transmitting the received streams as a reception high-definition digital video stream; and a decoder for decoding the reception high-definition digital vid

Abstract: What is disclosed is a novel system and method for determining the number of persons in an IR image obtained using an IR imaging system. The present method separates a human from the surrounding background via a set of particularly formed intensity ratios. Quantities derived from these ratios and threshold values are used to selectively classify whether a pixel in the IR image is from a human or from a non-human. Based upon the classification of the various pixels in the IR image, the number of persons is determined. Various embodiments are disclosed.

Abstract: A display apparatus includes a display panel and an optical member. The display panel includes a plurality of a pixel and displays a 2D image. The optical member includes a plurality of a lens, each having a plurality of a focal point and configured such that at least two pixels of the display panel correspond to one 3D pixel. The optical member divides the 2D image into left and right-eye images by using the lenses of the optical member.