Abstract: Systems and methods are described relating to accepting an indication of an inertial impact associated with at least one mobile device; and presenting an indication of location of the at least one mobile device at least partially based on accepting the indication of the inertial impact associated with the at least one mobile device. Additionally, systems and methods are described relating to means for accepting an indication of an inertial impact associated with at least one mobile device; and means for presenting an indication of location of the at least one mobile device at least partially based on accepting the indication of the inertial impact associated with the at least one mobile device.

Abstract: Systems and methods are described relating to detecting an indication of a person within a specified proximity to at least one mobile device; and presenting an indication of location of the at least one mobile device at least partially based on the indication of the person within the specified proximity. Additionally, systems and methods are described relating to means for detecting an indication of a person within a specified proximity to at least one mobile device; and means for presenting an indication of location of the at least one mobile device at least partially based on the indication of the person within the specified proximity.

Abstract: Systems and methods are described relating to accepting a mobile device location query using digital signal processing and presenting an indication of location of the mobile device at least partially based on receiving the location query. Additionally, systems and methods are described relating to means for accepting a mobile device location query using digital signal processing and means for presenting an indication of location of the mobile device at least partially based on receiving the location query.

Abstract: Systems and methods are described relating to accepting an indication of an inertial impact associated with at least one mobile device; and presenting an indication of location of the at least one mobile device at least partially based on accepting the indication of the inertial impact associated with the at least one mobile device. Additionally, systems and methods are described relating to means for accepting an indication of an inertial impact associated with at least one mobile device; and means for presenting an indication of location of the at least one mobile device at least partially based on accepting the indication of the inertial impact associated with the at least one mobile device.

Abstract: Techniques for sensory enhancement and augmentation are described. Some embodiments provide an audible assistance facilitator system (“AAFS”) configured to provide audible assistance to a user via a hearing device. In one embodiment, the AAFS receives data that represents an utterance of a speaker received by a hearing device of the user, such as a hearing aid, smart phone, media device, or the like. The AAFS identifies the speaker based on the received data, such as by performing speaker recognition. The AAFS determines speaker-related information associated with the identified speaker, such as by determining an identifier (e.g., name or title) of the speaker, by locating an information item (e.g., an email message, document) associated with the speaker, or the like. The AAFS then informs the user of the speaker-related information, such as by causing an audio representation of the speaker-related information to be output via the hearing device.

Abstract: Techniques for ability enhancement are described. Some embodiments provide an ability enhancement facilitator system (“AEFS”) configured to enhance a user's ability to operate or function in a transportation-related context as a pedestrian or a vehicle operator. In one embodiment, the AEFS is configured perform vehicular threat detection based at least in part on analyzing image data. An example AEFS receives data that represents an image of a vehicle. The AEFS analyzes the received data to determine vehicular threat information, such as that the vehicle may collide with the user. The AEFS then informs the user of the determined vehicular threat information, such as by transmitting a warning to a wearable device configured to present the warning to the user.

Abstract: Techniques for ability enhancement are described. Some embodiments provide an ability enhancement facilitator system (“AEFS”) configured to enhance a user's ability to operate or function in a transportation-related context as a pedestrian or a vehicle operator. In one embodiment, the AEFS is configured perform vehicular threat detection based at least in part on analyzing audio signals. An example AEFS receives data that represents an audio signal emitted by a vehicle. The AEFS analyzes the audio signal to determine vehicular threat information, such as that the vehicle may collide with the user. The AEFS then informs the user of the determined vehicular threat information, such as by transmitting a warning to a wearable device configured to present the warning to the user.

Abstract: Techniques for ability enhancement are described. Some embodiments provide an ability enhancement facilitator system (“AEFS”) configured to enhance voice conferencing among multiple speakers. Some embodiments of the AEFS enhance voice conferencing by recording and presenting voice conference history information based on speaker-related information. The AEFS receives data that represents utterances of multiple speakers who are engaging in a voice conference with one another. The AEFS then determines speaker-related information, such as by identifying a current speaker, locating an information item (e.g., an email message, document) associated with the speaker, or the like. The AEFS records conference history information (e.g., a transcript) based on the determined speaker-related information.

Abstract: Techniques for ability enhancement are described. Some embodiments provide an ability enhancement facilitator system (“AEFS”) configured to automatically translate utterances from a first to a second language, based on speaker-related information determined from speaker utterances and/or other sources of information. In one embodiment, the AEFS receives data that represents an utterance of a speaker in a first language, the utterance obtained by a hearing device of the user, such as a hearing aid, smart phone, media player/device, or the like. The AEFS then determines speaker-related information associated with the identified speaker, such as by determining demographic information (e.g., gender, language, country/region of origin) and/or identifying information (e.g., name or title) of the speaker. The AEFS translates the utterance in the first language into a message in a second language, based on the determined speaker-related information.

Abstract: Techniques for ability enhancement are described. Some embodiments provide an ability enhancement facilitator system (“AEFS”) configured to determine and present speaker-related information based on speaker utterances. In one embodiment, the AEFS receives data that represents an utterance of a speaker received by a hearing device of the user, such as a hearing aid, smart phone, media player/device, or the like. The AEFS identifies the speaker based on the received data, such as by performing speaker recognition. The AEFS determines speaker-related information associated with the identified speaker, such as by determining an identifier (e.g., name or title) of the speaker, by locating an information item (e.g., an email message, document) associated with the speaker, or the like. The AEFS then informs the user of the speaker-related information, such as by presenting the speaker-related information on a display of the hearing device or some other device accessible to the user.

Abstract: Techniques for ability enhancement are described. Some embodiments provide an ability enhancement facilitator system (“AEFS”) configured to enhance voice conferencing among multiple speakers. In one embodiment, the AEFS receives data that represents utterances of multiple speakers who are engaging in a voice conference with one another. The AEFS then determines speaker-related information, such as by identifying a current speaker, locating an information item (e.g., an email message, document) associated with the speaker, or the like. The AEFS then informs a user of the speaker-related information, such as by presenting the speaker-related information on a display of a conferencing device associated with the user.

Abstract: Techniques for ability enhancement are described. Some embodiments provide an ability enhancement facilitator system (“AEFS”) configured to enhance a user's ability to operate or function in a transportation-related context as a pedestrian or a vehicle operator. In one embodiment, the AEFS is configured to perform vehicular threat detection based on information received at a road-based device, such as a sensor or processor that is deployed at the side of a road. An example AEFS receives, at a road-based device, information about a first vehicle that is proximate to the road-based device. The AEFS analyzes the received information to determine threat information, such as that the vehicle may collide with the user. The AEFS then informs the user of the determined threat information, such as by transmitting a warning to a wearable device configured to present the warning to the user.

Abstract: Techniques for ability enhancement are described. In some embodiments, devices and systems located in a transportation network share threat information with one another, in order to enhance a user's ability to operate or function in a transportation-related context. In one embodiment, a process in a vehicle receives threat information from a remote device, the threat information based on information about objects or conditions proximate to the remote device. The process then determines that the threat information is relevant to the safe operation of the vehicle. Then, the process modifies operation of the vehicle based on the threat information, such as by presenting a message to the operator of the vehicle and/or controlling the vehicle itself.

Abstract: A method for modifying the viewpoint of a main image of a scene captured from a first viewpoint. The method uses one or more complementary images of the scene captured from viewpoints that are different from the first viewpoint. A warped main image is determined corresponding to a target viewpoint by warping the main image responsive to a corresponding range map, wherein the warped main image includes one or more holes corresponding to scene content that was occluded. Warped complementary images are similarly determined by warping the complementary images to the target viewpoint responsive to corresponding range maps. Pixel values to fill the one or more holes in the warped main image are determined using pixel values at corresponding pixel locations in the warped complementary images.

Abstract: A method for determining a range map for a particular video frame from a digital video comprising: determining a set of extrinsic parameters and one or more intrinsic parameters for each video frame. A set of candidate video frames are defined and an image similarity score for each candidate video frame providing an indication of the visual similarity. The image similarity scores are compared to a predefined threshold to determine a subset of the candidate video frames. A position difference score is determined for each video frame in the determined subset responsive to the extrinsic parameters, and the video frame having the largest position difference score is selected. The range map is determined responsive to disparity values representing a displacement between corresponding image pixels in the particular video frame and the selected video frame.

Abstract: An environment is described in which a processing system provides application-level usage information to users. In one scenario, for example, the processing system may provide personal usage information to a user who is operating a user device. The personal usage information itemizes the amount of data (and/or other resources) that has been consumed by each application run by the user device. In another scenario, the processing system may provide expected usage information associated with at least one candidate application provided by a marketplace system. The expected usage information describes an expected consumption of data (and/or other resources) by the candidate application upon running the candidate application by the user device. The processing system can tailor the expected usage information that it sends to a particular user based on user profile data. The user profile data describes a manner in which users operate applications.

Abstract: Vertically-stacked electronic devices having conductive carbon films are disclosed. The vertically-stacked devices exhibit non-linear current-versus-voltage response over a voltage sweep range in various embodiments. The vertically-stacked devices may be assembled into arrays where the vertically-stacked devices may be electrically addressed independently of one another. Uses of the vertically-stacked electronic devices and arrays as two-terminal memory devices, logic units, and sensors are disclosed. Crossbar arrays of vertically-stacked electronic devices having conductive carbon films and nanowire electrodes are disclosed.

Abstract: Various exemplary user interfaces, methods and computer program products describe enabling sharing of mobile communication devices. This process utilizes a shared mode for an owner of the mobile communication device to create a virtual environment for a borrower of the mobile communication device, which allows content information (e.g., certain applications and files) to be accessible and visual to the borrower. The process allows an owner of the mobile communication device to track and to manage data created or changed by the borrower. The owner may accept or reject the changes made in the content information. Furthermore, the process conceals non-shared resources to the borrower.

Abstract: A choke module (100) for connecting with a mother board includes a housing (1), a magnetic unit (2) and a number of terminals (3). The magnetic unit includes a paddle board (21) attached to the housing and having a number of conductive pads 9212) and conductive sections (211), a number of SMDs (Surface Mount Devices 22) surface mounted on the paddle board, and a number of magnetic components (23) each having a magnetic core (231) stacked on the corresponding SMD along a vertical direction and a plurality of wires (232) winding around the magnetic core and soldered on the conductive pads. The number terminals are electrically connected with the conductive sections and secured to the housing for connecting with the mother board.

Abstract: A method for managing TCP flows in a mobile device adapted to connect to two or more wireless network types includes enabling connection to a number of networks of different types at the mobile device and executing a plurality of Internet-enabled applications on the mobile device. Each such application forms an existing TCP connection over a first one of the wireless networks. The routing table is modified such that any additional TCP connection will be created on a second one of the wireless networks. The device determines that a termination condition has occurred and in response to determining that the termination condition has occurred, renders an interface on the mobile device to the first one of the wireless networks inoperative.