Abstract: A method for coding video frames for forming a scalable, compressed video sequence comprising video frames coded according to at least a first and a second frame format. The video frames of the first frame format are independent video frames, and the video frames of the second frame format are predicted from at least one of the other video frames. The video sequence has a first sub-sequence determined therein, at least part of the first sub-sequence being formed by coding at least video frames of the first frame format; and with at least a second sub-sequence, at least part of which is formed by coding video frames of the second frame format, and at least one video frame of the second sub-sequence having been predicted from at least one video frame of the first sub-sequence. Frame identifier data of the second sub-sequence is determined into the video sequence.

Abstract: The present invention relates to a method and apparatus for producing a fully scalable compressed representation of video sequences, so that they may be transmitted over networks, such as the Internet, for example. Because the signal is scalable, users receiving the signal can obtain the signal at the appropriate resolution and quality that their system will handle or that they desire. The invention implements a “motion compensated temporal wavelet transform” in order to enable compression of the video in a scalable fashion while still taking advantage of inter-frame redundancy in a manner which is sensitive to scene and camera motion. The motion compensated temporal wavelet transform is implemented by decomposing the video sequence into a set of temporal frequency bands and then applying a sequence of motion compensated lifting operations to alternately update an odd frame sub-sequence based upon an even sub-sequence and vice versa in a manner which is sensitive to motion.

Abstract: A system for recording video comprising a plurality of cameras aligned in a substantially horizontal plane and adapted to capture images in substantially a three-hundred-sixty degree viewing angle; and a first additional camera adapted to capture images at the same time as the plurality of cameras adapted to capture images in the substantially three-hundred-sixty degree view, wherein the first additional camera is adapted to capture images in a direction above or below the horizontal plane. A system for displaying video comprising a side viewing area that provides substantially a three-hundred-sixty degree viewing area and forms at least part of a viewing pod; and at least one of atop viewing area and a bottom viewing area that forms a least a part of the viewing pod.

Abstract: An improved method and block transform for image or video encoding and decoding, wherein transformation and inverse transformation matrixes are defined such that computational complexity is significantly reduced when encoding and decoding. For example, in the two-dimensional inverse transformation of de-quantized transform coefficients into output pixel information during decoding, only four additions plus one shift operation are needed, per co-efficient transformation, all in sixteen-bit arithmetic. Transformations provide correct results because quantization during encoding and de-quantization (sixteen bit) during decoding, via the use of one of three tables selected based on each coefficient's position, have parameter values that already compensate for factors of other transformation multiplications, except for those of a power of two, (e.g., two or one-half), which are performed by a shift operation during the transformation and inverse transformation processes.

Abstract: A system and method for managing communication in an integrated services network ensures that media information is displayed on at least one of two terminals during a call without using any transmission bandwidth. This is achieved by having at least one of the terminals pre-store the media information in a memory and then controlling the terminal to recall and display this information when certain events occur during the call. The media information may include animated information, images, and short-time video scripts. This information and broader band media such as streaming video may be displayed on the same terminal. The display of media information may also be controlled based on the past knowledge and experience callers have about one another and/or their communications equipment.

Abstract: A receiving apparatus includes a receiving unit that receives an image signal, identification information on a transmitting apparatus, and color adjusting information that are radio transmitted from the transmitting apparatus; a lock controller that locks the color adjusting information when the receiving unit receives at least one of consecutively repeated identical color adjusting information and consecutively repeated identical identification information during a predetermined period or when the receiving unit most often receives at least one of the identical color adjusting information or the identical identification information during the predetermined period; and an image processing unit that performs image processing on the received image signal based on the locked color adjusting information.

Abstract: A method for synchronized recording of audio and video signals is disclosed. The video signals are grouped into a plurality of video frames. The method includes incrementing a counter value of an audio counter when at least an audio frame associated with the audio signals is encoded, and recording the current counter value of the audio counter when a video frame is received.

Abstract: The present invention provides a system and method for obtaining in vivo images. The system contains an imaging system and a transmitter for transmitting signals from a camera to a receiving system located outside a patient.

Abstract: A variable-bit-rate (VBR)-encoding of a plurality of clips from a plurality of video content items is performed to produce a VBR-encoded aggregated video content item. The VBR-encoding of each of the clips is based on an encoding complexity of at least one other one of the clips. This can be performed by combining the clips into aggregated video content and two-pass VBR-encoding the aggregated video content. A video quality test may be performed using the VBR-encoded aggregated video content item.

Abstract: A predictive video coder performs gradient prediction based on previous blocks of image data. For a new block of image data, the prediction determines a horizontal gradient and a vertical gradient from a block diagonally above the new block (vertically above a previous horizontally adjacent block). Based on these gradients, the encoder predicts image information based on image information of either the horizontally adjacent block or a block vertically adjacent to the new block. The encoder determines a residual that is transmitted in an output bitstream. The decoder performs the identical gradient prediction and predicts image information without need for overhead information. The decoder computes the actual information based on the predicted information and the residual from the bitstream.

Abstract: In one embodiment, decoding of a video signal includes predicting at least a portion of a current image in a current layer based on at least a portion of a base image in a base layer and shift information for samples in the predicted current image.

Abstract: In one embodiment, decoding of a video signal includes predicting at least a portion of a current image in a current layer based on at least a residual coded portion of a base image in a base layer and shift information for samples in the predicted current image.

Abstract: Motion-compensated video coding that employs fine-granular computational complexity scalable motion estimation is described. The scalable motion estimation technique adapts to varying computational limitations of the device performing the video coding technique. The scalable motion estimation technique calculates a predicted priority for each macroblock in a frame and identifies a set of macroblocks based on the predicted priority. A pass is then performed on each macroblock within the set. The pass checks a set of candidate motion vectors for each macroblock in the set and determines a new starting point for the next pass of the macroblocks during processing of the same frame. The predicted priority for each macroblock within the set of macroblocks is re-calculated and the process repeats by identifying another set of macroblocks and performing a pass on them. These repeats until a computation limit associated with the device performing the passes has been reached.

Abstract: A video encoding apparatus includes selecting one combination, for each block of an input video signal, from a plurality of combinations. Each combination includes a predictive parameter and at least one reference picture number determined in advance for the reference picture. A prediction picture signal is generated in accordance with the reference picture number and predictive parameter of the selected combination. A predictive error signal is generated representing an error between the input video signal and the prediction picture signal. Encoding the predictive error signal, information of the motion vector, and index information indicating the selected combination is included.

Abstract: A video encoding apparatus includes selecting one combination, for each block of an input video signal, from a plurality of combinations. Each combination includes a predictive parameter and at least one reference picture number determined in advance for the reference picture. A prediction picture signal is generated in accordance with the reference picture number and predictive parameter of the selected combination. A predictive error signal is generated representing an error between the input video signal and the prediction picture signal. Encoding the predictive error signal, information of the motion vector, and index information indicating the selected combination is included.

Abstract: A video encoding method includes selecting one combination, for each block of an input video signal, from a plurality of combinations. Each combination includes a predictive parameter and at least one reference picture number determined in advance for the reference picture. A prediction picture signal is generated in accordance with the reference picture number and predictive parameter of the selected combination. A predictive error signal is generated representing an error between the input video signal and the prediction picture signal. Encoding the predictive error signal, information of the motion vector, and index information indicating the selected combination is included.

Abstract: A video encoding apparatus includes selecting one combination, for each block of an input video signal, from a plurality of combinations. Each combination includes a predictive parameter and at least one reference picture number determined in advance for the reference picture. A prediction picture signal is generated in accordance with the reference picture number and predictive parameter of the selected combination. A predictive error signal is generated representing an error between the input video signal and the prediction picture signal. Encoding the predictive error signal, information of the motion vector, and index information indicating the selected combination is included.

Abstract: The method comprising a wavelet-based spatial analysis step comprising filtering operations of the picture at the high resolution format and horizontal and/or vertical decimation operations of the filtered picture to supply subband signals, is wherein a decimation operation is carried out according to a factor different from an even value and corresponds to the quotient of the horizontal and vertical dimensions of the first and second format such that the low frequency picture thus obtained relative to the low frequency subband signals, corresponds to the second format.

Abstract: A video encoding method includes selecting one combination, for each block of an input video signal, from a plurality of combinations. Each combination includes a predictive parameter and at least one reference picture number determined in advance for the reference picture. A prediction picture signal is generated in accordance with the reference picture number and predictive parameter of the selected combination. A predictive error signal is generated representing an error between the input video signal and the prediction picture signal. Encoding the predictive error signal, information of the motion vector, and index information indicating the selected combination is included.

Abstract: A still-picture acquisition section in a computer selects a brightness-periodically-varying portion of image data of a living cell like a cardiac cell, as a sample, which makes a self-ordered periodic motion, monitors a change in brightness, generates a trigger signal at the timing at which the value of the brightness exceeds a specific threshold value, causes a camera body to repeatedly pick up the image of the living cell after a predetermined delay time, and then averages the picked-up images. This makes it possible to acquire as high-quality still pictures the instantaneous status of a living cell which varies with time in accordance with the application of external stimulation or the in-vivo order.