Abstract: A method for visualizing the surroundings of a vehicle, including the following steps: determining and storing an instantaneous distance between the vehicle and present obstacles in the surroundings of the vehicle with the aid of at least one sensor; determining and storing a present position of the vehicle; calculating an at least two-dimensional model of the surroundings from the stored data; calculating a virtual view of the model of the surroundings from a selected virtual observer position; recording a video depiction of at least a portion of the surroundings with the aid of at least one video camera and integrating the video depiction into the virtual view; and outputting the virtual view together with the integrated video depiction to a driver of the vehicle.

Abstract: In an example, a method of coding video data includes coding, by a video coder, at least a portion of a picture of an independently decodable non-base layer of a multi-layer bitstream. The method also includes coding, by the video coder, data indicating a picture order count (POC) value reset for a POC least significant bits (LSB) value of the picture only when the picture has a POC LSB value for the picture is equal to zero.

Abstract: A method and apparatus for video coding including an IntraBC (Intra-block copy) mode for a picture according to the present invention is disclosed. Embodiments of the present invention take advantage of pattern symmetry in screen contents as well as natural video to improve the performance of IntraBC coding. Accordingly, at least a reference block is reformed to generate a reformed predictor and IntraBC coding is applied to a block using the reformed predictor. Reforming the reference block may correspond to applying a reforming operation selected from a reforming group to the reference block, where the reforming group consists of horizontal flipping, vertical flipping, horizontal and vertical flipping, clockwise rotation, counter-clockwise rotation and transposition.

Abstract: A roof mounted module for a vehicle includes an imager housing in secure engagement with a roof of the vehicle. The imager housing defines a lateral aperture and a vertical aperture. An imager is disposed in the imager housing and is in communication with the lateral aperture. An antenna housing is removably coupled to the imager housing and is in communication with the vehicle via a data connection that extends through the vertical aperture.

Abstract: Systems and methods for capturing a digital image of a slide using an imaging line sensor and a focusing line sensor. In an embodiment, a beam-splitter is optically coupled to an objective lens and configured to receive one or more images of a portion of a sample through the objective lens. The beam-splitter simultaneously provides a first portion of the one or more images to the focusing sensor and a second portion of the one or more images to the imaging sensor. A processor controls the stage and/or objective lens such that each portion of the one or more images is received by the focusing sensor prior to it being received by the imaging sensor. In this manner, a focus of the objective lens can be controlled using data received from the focusing sensor prior to capturing an image of a portion of the sample using the imaging sensor.

Abstract: In a moving picture encoding apparatus, a primary candidate reference motion vector-setting unit sets N primary candidate reference motion vectors. A degree of reliability calculation unit calculates the reliability of each primary candidate reference motion vector, which represents effectiveness in predicting a motion vector of a block to be decoded, using coded or decoded image information. A reference motion vector determination unit selects M (M<N) secondary candidate reference motion vectors in accordance with degree of reliability from among the N primary candidate reference motion vectors. A motion vector prediction unit creates a predictive motion vector of a block to be coded using M secondary candidate reference motion vectors with high reliability.

Abstract: A method of decoding video data including receiving an encoded video bitstream that includes a plurality of pictures and storing the plurality of pictures in one or more sub-DPBs. The method further including receiving a respective set of sub-DPB parameters for each respective operation point of the encoded video bitstream. applying the respective set of sub-DPB parameters to all layers of an output layer set for each respective operation point, and performing a sub-DPB management process on the one or more sub-DPBs in accordance with the received respective single sets of sub-DPB parameters.

Abstract: A method and related apparatus for decoding an image sequence from a bitstream, wherein an identifier indicating if all output pictures are decodable with a predefined set of reference pictures is decoded; an indication of required reference pictures for a given output picture is decoded; the indicated at least one reference picture for the given output picture is decoded; and the at least one output picture is decoded.

Abstract: A system utilizing a high throughput coding mode for CABAC in HEVC is described. The system may include an electronic device configured to obtain a block of data to be encoded using an arithmetic based encoder; to generate a sequence of syntax elements using the obtained block; to compare an Absolute-3 value of the sequence or a parameter associated with the Absolute-3 value to a preset value; and to convert the Absolute-3 value to a codeword using a first code or a second code that is different than the first code, according to a result of the comparison.

Abstract: A system utilizing a high throughput coding mode for CABAC in HEVC is described. The system may include an electronic device configured to obtain a block of data to be encoded using an arithmetic based encoder; to generate a sequence of syntax elements using the obtained block; to compare an Absolute-3 value of the sequence or a parameter associated with the Absolute-3 value to a preset value; and to convert the Absolute-3 value to a codeword using a first code or a second code that is different than the first code, according to a result of the comparison.

Abstract: In a vehicular visibility support apparatus, a camera positioned on a front portion that is either the left side or the right side of a vehicle provides an image of a view laterally behind the vehicle including a part of a face of the side of the vehicle as a camera image. An input portion accepts input manipulation to generate an input signal. A control portion trims a desired region in the camera image based on the input signal and provides a trimmed image. The control portion trims the camera image based on: a vertical reference line including a part of the face on the side of the vehicle in a trimmed image before the input manipulation is accepted by the input portion, and a horizontal reference line orthogonal to the vertical reference line; and a direction of movement for change to the desired region inputted to the input portion.

Abstract: Various aspects of the present disclosure are directed toward methods, systems, and apparatus that include an optical detection node to pass light through the optical pathway to the optical detection node where the light is detectable. At least one focusing element is provided to pass the light along the optical pathway, and at least one optical mask is used to provide spatially-varying modulation on the light passing along the optical pathway. The light passing along the optical pathway is redirected and modified to create a spiral point spread function at the optical detection node for estimating a distance to an object that is characterized at least in part by the light passing along the optical pathway.

Abstract: Disclosed is a vehicle, which senses a speed of the vehicle using a speed sensor unit and also senses a vehicle-to-vehicle distance between the vehicle and a first vehicle immediately ahead of the vehicle using a distance sensor unit and then determines a state of the vehicle based on the speed of the vehicle and the vehicle-to-vehicle distance. In this case, when the vehicle is in a first state, the vehicle displays a first image captured by a first camera unit on a first display unit. In addition, when the vehicle is in a second state, the vehicle displays a second image captured by a second camera unit on the first display unit. Here, the second camera unit is a camera unit stalled in a second vehicle, and the second vehicle being any one of one or more vehicles ahead of the vehicle.

Abstract: A display apparatus may be provided that includes a display module, a housing, at least one speaker module within the housing, and at least one reflector disposed adjacent to the at least one speaker module. The at least one reflector may have an inclined acoustic reflection surface exposed to a front side of the display module when the sounds are emitted from the at least one speaker module. The at least one speaker module may be disposed in parallel to a horizontal or vertical direction of the housing.

Abstract: There is disclosed a method, apparatus and computer program product for prediction mode selection for coding a block of a depth map. An ordered list of coding modes is obtained, wherein the ordered list of coding modes comprises a plurality of coding modes. And whether a depth modeling mode and/or a region boundary chain mode is to be added into the ordered list of coding modes in accordance with a decision condition is determined.

Abstract: A method and a device are described for modifying a video frame for encoding or decoding wherein values of pixels of the video frame are represented an increased bit depth. The described method comprises using processing means for executing the step of offsetting the pixel values of increased bit depth with offsets, the offsets depending on a spatial neighbourhood of the pixel to-be-offset. Such local adaptive offsetting of pixel values de-emphasizes high frequencies in the transform domain artificially emphasized by the bit depth increase.

Abstract: A method for processing components of an image for coding a sample of the image, the image being composed of a first type of component and a second type of component, wherein samples of the second type of component are predictable from samples of the first type of component using a prediction model, computing one parameter value for use in representing, in the prediction model, the link between the first type of component and the second type of component; detecting, whether or not, one type of error exists in one such computed parameter value of the prediction model and in the case where a first type of error is detected; adapting the computed parameter value to correct for the error detected; and predicting a sample of the second type from a sample of the first type using the prediction model and the adapted parameter value.

Abstract: Certain embodiments of the invention may include systems, methods, and apparatus for in vehicle fiducial mark tracking and interpretation According to an example embodiment of the invention, a method is provided for executing computer executable instructions by one or more processors. The method includes receiving the one or more images from at least one camera attached to a vehicle; selecting, from the one or more received images, a region of interest associated with an object in the vehicle; identifying fiducial marks within the selected region of interest by comparing the identified fiducial marks with one or more stored fiducial representations; determining, based at least in part on the comparison, spatial information associated with the object or an occupant of the vehicle; and sending information based at least in part on the determined spatial information.

Abstract: In various embodiments, video streams are decoded using decoders that support a different decoding profile. First processing circuitry is configured to receive a video stream encoded using a first encoding profile, transcode the video stream from the first encoding profile to a second encoding profile, and store the transcoded video stream in an output buffer. Second processing circuitry is configured to receive the transcoded video stream from the output buffer and decode the transcoded video stream according to the second encoding profile. The second processing circuitry may be unable to decode the video stream encoded using the first encoding profile.

Abstract: A user measures a length of a target using a mobile terminal and measure a length, irrespective of time and place. The mobile terminal and the target are photographed together in front of the mirror, and a size of the target is estimated using a ratio of the pictured size versus the actual size of the mobile terminal. The actual size of the target is calculated by adjusting the estimated length with an error associated with a difference between a distance from the mirror to the mobile terminal and a distance from the mirror to the target, and thus, a length is more accurately measured. In addition, the error associated with the distance is corrected based on the photographed picture and data stored in a database and thus, a separate distance measurement sensor for correcting the distance is not required and the cost may be reduced.