Abstract: Techniques for an auto adjustable pane view are described, including receiving a request to display a plurality of elements in a pane, the pane located in a display space, determining a number and a size of the a plurality of elements, and sizing the pane based on the number of the plurality of elements and the size of the plurality of elements, wherein the sizing is also based on minimizing unused space in the pane.

Abstract: Systems and methods for identifying, tracking, and using objects in a video or similar electronic content, including methods for tracking one or more moving objects in a video. This can involve tracking one or more feature points within a video scene and separating those feature points into multiple layers based on motion paths. Each such motion layer can be further divided into different clusters, for example, based on distances between points. These clusters can then be used as an estimate to define the boundaries of the objects in video. Objects can also be compared with one another in cases in which identified objects should be combined and considered a single object. For example, if two objects in the first two frames have significantly overlapping areas, they may be considered the same object. Objects in each frame can further be compared to determine the life of the objects across the frames.

Abstract: Synchronization between multiple data repositories is described which retrieves tree structures that represent the hierarchical organization of the data repositories that will be or are synchronized. One of tree structures is parsed for data nodes, while the other tree structures are parsed for each such data node to find matching data nodes having corresponding hierarchies. Moved nodes are identified when a matching node is found that does not have the same hierarchy in its tree structure. Similarly, deleted nodes are identified when a node is found with no match in a controlling tree structure. Data structure lists are compiled noting matching relationships and hierarchies and also noting moved and deleted nodes and their relationships with the rest of the formerly corresponding nodes. Using these data structure lists, a synchronization interface is generated for display to a user that visually compares the synchronization of the multiple data repositories.

Abstract: A system identifies a change in a position of an object from a first frame to a second frame from a plurality of frames. The video is comprised of a plurality of frames. In one embodiment, the plurality is at least three frames. The image stability measuring process identifies a change in direction of the change in the position of the object. The change in direction is determined by utilizing a plurality of adjacent frames located near the first frame and the second frame. The image stability measuring process determines an image stability value for a subset of the plurality of frames. The image stability value is calculated based on the change in direction. The image stability measuring process renders a portion of the video within an automatic editing script. The portion of the video is selected based on a preferred image stability value identified within the automatic editing script.

Abstract: Systems and methods for identifying, tracking, and using objects in a video or similar electronic content, including methods for tracking one or more moving objects in a video. This can involve tracking one or more feature points within a video scene and separating those feature points into multiple layers based on motion paths. Each such motion layer can be further divided into different clusters, for example, based on distances between points. These clusters can then be used as an estimate to define the boundaries of the objects in video. Objects can also be compared with one another in cases in which identified objects should be combined and considered a single object. For example, if two objects in the first two frames have significantly overlapping areas, they may be considered the same object. Objects in each frame can further be compared to determine the life of the objects across the frames.

Abstract: Plasmonics-active nanostructure substrates—developed on a wafer scale in a reliable and reproducible manner such that these plasmonics-active nanostructures have nano-scale gaps (that include but are not limited to sub-10 nm gaps or sub-5 nm gaps) that provide the highest EM field enhancement between neighboring plasmonics-active metallic or metal-coated nanostructures. The plasmonics-active nanostructure substrates relate to environmental sensing based on SERS, SPR, LSPR, and plasmon enhanced fluorescence based sensing as well as for developing plasmonics enhanced devices such as solar cells, photodetectors, and light sources. Controllable development of sub-2 nm gaps between plasmonics-active nanostructures can also be achieved. Also, the size of the nano-scale gap regions can be tuned actively (e.g., by the application of voltage or current) to develop tunable sub-5 nm gaps between plasmonic nanostructures in a controllable manner.

Abstract: Embodiments herein include a focus evaluator configured to categorize portions of image content into different groupings depending on a respective focus value derived for each portion of the image content. The focus evaluator compares relative sizes of the different groupings to identify one or more groupings representative of an overall focus quality associated with the image content. Based on the identified one or more groupings, the focus evaluator generates the overall focus value for the image content.

Abstract: Coaxial and twisted pair conductive yarn structures reduce signal crosstalk between adjacent lines in woven electrical networks. A coaxial conductive yarn structure includes an inner conductive yarn having a plurality of conductive strands twisted together. An outer conductive yarn is wrapped around the inner conductive yarn. An insulating layer separates the inner and outer yarns. A twisted pair conductive yarn structure includes first and second conductive yarns, each including a plurality of conductive strands being twisted together. The first and second conductive yarns are twisted together to form a helical structure. In a woven electrical network, at least one conductor of adjacent conductive yarn structures is connected to ground to reduce signal crosstalk. Coaxial and twisted pair yarn structures may also be formed simultaneously with weaving or knitting the threads that make up the structures into a fabric.

Abstract: In-line fiber optic structure devices for use as environmental sensors and methods of fabricating in-line fiber optic structures as environmental sensors are disclosed and provided. According to some embodiments, fiber optic sensor devices can utilize the interaction of surface plasmons or evanescent waves with a surrounding environment. Fiber optic sensors according to some embodiments of the present invention provide an optical fiber with a long environmental interaction length having improved structural integrity. Graded-index optical fiber elements can be used as lenses and a coreless optical fiber element can act as an environmental interaction or sensing area. Graded-index and coreless optical elements can be fused to provide a continuous fiber optic sensing system. Other various embodiments are also claimed and described.

Abstract: Coaxial and twisted pair conductive yarn structures reduce signal crosstalk between adjacent lines in woven electrical networks. A coaxial conductive yarn structure includes an inner conductive yarn having a plurality of conductive strands twisted together. An outer conductive yarn is wrapped around the inner conductive yarn. An insulating layer separates the inner and outer yarns. A twisted pair conductive yarn structure includes first and second conductive yarns, each including a plurality of conductive strands being twisted together. The first and second conductive yarns are twisted together to form a helical structure. In a woven electrical network, at least one conductor of adjacent conductive yarn structures is connected to ground to reduce signal crosstalk. Coaxial and twisted pair yarn structures may also be formed simultaneously with weaving or knitting the threads that make up the structures into a fabric.

Abstract: Methods and systems for selectively connecting and disconnecting conductors in a fabric are disclosed. First and second conductors are integrated into a fabric such that the conductors intersect at a crossover point. The conductors are bonded to each other at the crossover point to improve AC and DC characteristics. Disconnect areas may be provided near the crossover point to allow selective disconnection of the conductors from the crossover point.

Abstract: Methods and systems for selectively connecting and disconnecting conductors in a fabric are disclosed. First and second conductors are integrated into a fabric such that the conductors intersect at a crossover point. The conductors are bonded to each other at the crossover point to improve AC and DC characteristics. Disconnect areas may be provided near the crossover point to allow selective disconnection of the conductors from the crossover point.

Abstract: Methods and systems for selectively connecting and disconnecting conductors in a fabric are disclosed. First and second conductors are integrated into a fabric such that the conductors intersect at a crossover point. The conductors are bonded to each other at the crossover point to improve AC and DC characteristics. Disconnect areas may be provided near the crossover point to allow selective disconnection of the conductors from the crossover point.

Abstract: Coaxial and twisted pair conductive yarn structures reduce signal crosstalk between adjacent lines in woven electrical networks. A coaxial conductive yarn structure includes an inner conductive yarn having a plurality of conductive strands twisted together. An outer conductive yarn is wrapped around the inner conductive yarn. An insulating layer separates the inner and outer yarns. A twisted pair conductive yarn structure includes first and second conductive yarns, each including a plurality of conductive strands being twisted together. The first and second conductive yarns are twisted together to form a helical structure. In a woven electrical network, at least one conductor of adjacent conductive yarn structures is connected to ground to reduce signal crosstalk. Coaxial and twisted pair yarn structures may also be formed simultaneously with weaving or knitting the threads that make up the structures into a fabric.

Abstract: Methods and systems for selectively connecting and disconnecting conductors in a fabric are disclosed. First and second conductors are integrated into a fabric such that the conductors intersect at a crossover point. The conductors are bonded to each other at the crossover point to improve AC and DC characteristics. Disconnect areas may be provided near the crossover point to allow selective disconnection of the conductors from the crossover point.