Abstract: Systems and methods to generate maps or models of structures are disclosed. Features of the structure to be mapped may be determined for the purposes of generating the map or model based at least in part on images associated with the structure, sensor measurements associated with the structure, and phase data of communications signals that interact with the structure. The mapping or modeling processes may be performed at a mapping server that receives images, sensor data, and/or communications signal phase information from one or more user devices, such as mobile devices. The mapping servers may perform a simultaneous localization and mapping (SLAM) process and may enhance the generated maps using sensor and/or communications phase data to map one or more hidden features of the structure.

Abstract: Some demonstrative embodiments include apparatuses, devices, systems and methods of communicating a wakeup packet. For example, an apparatus may be configured to cause a first wireless device to generate a wakeup packet configured to wake up a receiver of a second wireless device; and to transmit the wakeup packet over a wakeup Resource Unit (RU) allocation of an Orthogonal Frequency Division Multiple Access (OFDMA) structure.

Abstract: Apparatuses, systems and methods associated with adaptive communication topology within a wireless mesh network of devices are disclosed herein. In embodiments, a computer device, may include wireless circuitry to communicate with a leader of a network and a controller coupled to the wireless circuitry. The controller may identify one or more values located within a message received via the network, wherein the one or more values are generated by the leader, and determine in which of one or more operation modes the computer device is to operate based, at least partially, on the one or more values. Other embodiments may be described and/or claimed.

Abstract: Generally discussed herein are systems, devices, and methods for managing content of an information centric network (ICN). A component of an ICN can include a memory including an extended content store that includes content from at least one other component of the ICN, and first attributes of the content, the first attributes including a content popularity value that indicates a number of requests for the content, and processing circuitry to increment the content popularity value in response to a transmission of a first content packet that includes the content, the first content packet transmitted in response to receiving an interest packet.

Abstract: System and techniques for network coding in an information centric network (ICN) are described herein. A request for a first portion of first named data may be received. A response to the request for the first portion of the first named data may be obtained. The first portion may be combined with a second portion for second named data to create a set of network coded responses. Names for members of the set of network coded responses may be created based on a first name for the first portion and a second name for the second portion. A response to the request may be made with the set of network coded responses using the names for members of the set of network coded responses.

Abstract: Generally discussed herein are systems, devices, and methods for routing interests and/or content in an information centric network. A router can include a memory and routing circuitry coupled to the memory, the routing circuitry configured to receive a packet, receive one or more attributes including at least one of (1) a network attribute, (2) a platform attribute, and (3) a content attribute, determine which neighbor node is to receive the packet next based on the received one or more attributes, and forward the packet to the determined neighbor node.

Abstract: Hybrid rendering is described for a wearable display that is attached to a tethered computer. In one example a process include determining a position and orientation of a wearable computing device, determining a rate of motion of the wearable computing device, comparing the rate of motion to a threshold, if the rate of motion is above the threshold, then rendering a view of a scene at the wearable computing device using the position and orientation information, and displaying the rendered view of the scene.

Abstract: A wearable display enhances rendering when attached to a tethered computer. In one example a process includes determining a position and an orientation of a wearable computing device, sending the determined position and orientation to a tethered computer, receiving a frame at the wearable computing device from the tethered computer, the frame being one of a sequence of frames of a video sequence corresponding to a view of a scene in response to the determined position and orientation, displaying the received frame on a display of the wearable computing device, generating a frame at the wearable computing device using the received frame, displaying the generated frame after the received frame, receiving a second frame at the wearable computing device from the tethered computer, the frame being a second one of a sequence of frames of a video sequence corresponding to a view of the scene, and displaying the second received frame.

Abstract: Hybrid rendering is described for a wearable display that is attached to a tethered computer. In one example a process include determining a position and orientation of a wearable computing device, determining a rate of motion of the wearable computing device, comparing the rate of motion to a threshold, if the rate of motion is above the threshold, then rendering a view of a scene at the wearable computing device using the position and orientation information, and displaying the rendered view of the scene.

Abstract: Provided are a method and apparatus for an error tolerance aware data retention scheme in a storage device for multi-scale error tolerant data. A mapping of retention priorities to sectors of the storage units maps higher retention priorities to sectors having a higher retention capability. A data stream and retention metadata for the data stream indicate retention priorities for segments of the data stream. Segments of the data stream having less error tolerance are mapped to higher retention priorities than segments of the data stream having greater error tolerance. The mapping of retention priorities is used to determine a sector having a retention priority matching a retention priority of a segment of the data stream indicated in the retention metadata. The segment of the data stream is stored in the determined sector.

Abstract: In one example, a head mounted display system includes detecting a position of a head of a user of the head mounted display, predicting a position of the head of the user of the head mounted display at a time after a time that the position of the head of the user was detected, and rendering image data based on the predicted head position.

Abstract: Systems and methods may provide for receiving unfiltered feedback information from a network interface component of a wireless display pipeline and receiving display region-specific information from a region update component of the wireless display pipeline. Additionally, a coding policy associated with wireless display content may be adjusted based on the unfiltered feedback information and the display region-specific information.

Abstract: Some demonstrative embodiments include apparatuses, devices, systems and methods of communicating a wakeup packet. For example, an apparatus may include circuitry configured to cause a first wireless device to modulate a preamble of a wakeup packet according to an Orthogonal Frequency Division Multiplexing (OFDM) scheme; modulate a payload of the wakeup packet according to an On-Off keying (OOK) modulation scheme over a plurality of OFDM tones; and transmit the wakeup packet to a second wireless device.

Abstract: Techniques related to encoding image content for transmission and display via a remote device with improved latency and efficiency are discussed. Such techniques may include skipping one or more of frame capture, encode, packetization, and transmission for a frame based on a skip indicator. One or more selective updates may be captured for the skipped frame and integrated into an encode of a subsequent non-skipped frame, which may be packetized and transmitted for to the remote device for presentment to a user.

Abstract: Provided are a method and apparatus for an error tolerance aware data retention scheme in a storage device for multi-scale error tolerant data. A mapping of retention priorities to sectors of the storage units maps higher retention priorities to sectors having a higher retention capability. A data stream and retention metadata for the data stream indicate retention priorities for segments of the data stream. Segments of the data stream having less error tolerance are mapped to higher retention priorities than segments of the data stream having greater error tolerance. The mapping of retention priorities is used to determine a sector having a retention priority matching a retention priority of a segment of the data stream indicated in the retention metadata. The segment of the data stream is stored in the determined sector.

Abstract: A higher frame rate (a multiple of the original display frame rate at the host) is exploited at a display sink device to opportunistically insert new decoded frames for display at the higher refresh rate of the sink. In other words, delayed frames arriving at the sink may get a chance to be displayed during the higher refresh rate cycle, thus offering a better (“smoother”) viewing experience along with improved interactivity or “responsiveness.

Abstract: A tile concept allows independent encoding and decoding of regions of the video frames combined with changes in the way that the coded tiles are packetized and queued for transport. After the coded tile network abstraction layer (NAL) units are packetized into MPEG-TS frames, the more important tile data is put in the network abstraction layer at the head of the queue while the less important data is inserted later in the queue. Audio can also be accorded high priority. For a given link bandwidth/latency environment, the important data is transmitted first and the less important data can be discarded at the transmitter with less impact on the user perceived quality.

Abstract: Some demonstrative embodiments include apparatuses, devices, systems and methods of communicating a wakeup packet. For example, an apparatus may include circuitry configured to cause a first wireless device to modulate a preamble of a wakeup packet according to an Orthogonal Frequency Division Multiplexing (OFDM) scheme; modulate a payload of the wakeup packet according to an On-Off keying (OOK) modulation scheme over a plurality of OFDM tones; and transmit the wakeup packet to a second wireless device.

Abstract: A method and an information handling system configured to select a mobility anchor point for a mobile device in a distributed mobility anchor point network may comprise collecting information about movement behavior or data transfer behavior of the mobile device, or tunneling overhead of two or more base stations. A mobility anchor point associated with a first base station may be assigned to the mobile device if the mobile device is connected to the first base station for at least a predetermined amount of time, if the mobile device transfers at least a predetermined amount of data via the first base station, or device if a tunneling overhead of the first base station is less than a predetermined level. In some embodiments, a centralized mobility anchor may be assigned to the mobile device if the mobile device is highly mobile and there is no identified base station to which the mobile device is frequently connected.

Abstract: This disclosure pertains to Theremin-based positioning. In general, Theremin technology may operate based on changes in frequency that may be induced in a signal when a certain object (e.g., a user's hand) is proximate to a capacitive electrode. An example system may comprise at least four capacitive electrodes in an arrangement that reacts to proximate objects. A change in frequency sensed for any of the at least four capacitive electrodes may trigger a determination of distance from each of the capacitive electrodes to the object based on the frequency change, and a determination of object positioning data based on the distances. Embodiments may include, for example, the ability to verify the arrangement of the at least four capacitive electrodes, determine object position and/or orientation in a coordinate system referenced to the at least four capacitive electrodes, determine object motion, provide the positioning data to a requesting application, etc.