Abstract: Various systems and methods for implementing intelligent traffic management for vehicle platoons are described herein. A road controller system includes A road controller system comprising: a data store to store an active traffic policy; a processor subsystem to: determine a speed or platoon size of a vehicle platoon traveling on an area controlled by the road controller system; and determine a change to the speed or platoon size of the vehicle platoon, the change based on the active traffic policy; and a transceiver to transmit a control message to the vehicle platoon to implement the change to the speed or platoon size of the vehicle platoon.

Abstract: Methods, apparatus, systems and articles of manufacture are disclosed Systems, apparatus, and methods to propagate a robot swarm using virtual partitions are disclosed. An example apparatus includes a transceiver to broadcast the availability of the apparatus to host one or more bots from a swarm of bots and to receive a copy request from a bot in the swarm of bots. The example apparatus also includes an evaluator to evaluate instructions from the bot and determine if the apparatus is equipped to propagate the bot. In addition, the example apparatus includes a virtual partition to provide an interface for executing a copy of the bot.

Abstract: Systems, apparatus, and computer-readable media for managing data storage for generating virtual bindings are provided. In embodiments, a user may perform one or more gestures and/or voice commands to create virtual bindings with physical objects, where the created virtual bindings may take on attributes and create/perform actions based on attributes of the physical objects. A projection device may recognize the physical objects and cause the bindings and/or projected virtual objects to perform various actions in response to different user gestures and/or voice commands. Additionally, the system may instruct some physical objects (e.g., robots, electromechanical devices, etc.) in response to user gestures/voice commands to cause those physical devices to perform various actions. Other embodiments are described and/or claimed.

Abstract: Apparatus, systems, or methods for mixed reality with chemical sense response are disclosed herein. In embodiments, an apparatus for a mixed reality computing with chemical sense response may include monitor logic and distribution logic. The monitor logic may collect data about a user's response to a first set of stimulations to represent an actual chemical sense response by the user with respect to the first set of stimulations. Based on the collected data, a variance between the actual chemical sense response by the user with respect to the first set of stimulations, and a desired chemical sense response for the user with respect to the first set of stimulations may be determined. The distribution logic, including circuitry, may deliver to the user a second set of stimulations. Other embodiments may also be described and claimed.

Abstract: Technologies for virtual attribute assignment include a compute device. The compute device is configured to receive an attribute assignment command from a user and analyze the attribute assignment command to determine a user-selected virtual object, a user-referenced attribute of the user-selected virtual object, a user-selected real object, and a user-referenced attribute of the user-selected real object. Based on the attribute assignment command, the compute device is further configured to determine a state of the user-referenced attribute of the user-selected real object and update a state of the user-referenced attribute of the user-selected virtual object based on the state of the user-referenced attribute of the user-selected real object.

Abstract: The present disclosure is directed to systems, apparatuses, and processes that provide mixed reality and/or augmented reality interactive environments. Disclosed embodiments include mechanisms to determine a location of a physical object within a mixed reality environment, determine a location of a viewer within the mixed reality environment, and project a display onto the physical object or on a portion of an area within the mixed reality environment proximate to the physical object to obscure the physical object from the viewer, based upon at least the location of the physical object with respect to the location of the viewer. Other embodiments may be disclosed and/or claimed.

Abstract: A mechanism is described for facilitating embedding of human labeler influences in machine learning interfaces in computing environments, according to one embodiment. A method of embodiments, as described herein, includes detecting sensor data via one or more sensors of a computing device, and accessing human labeler data at one or more databases coupled to the computing device. The method may further include evaluating relevance between the sensor data and the human labeler data, where the relevance identifies meaning of the sensor data based on human behavior corresponding to the human labeler data, and associating, based on the relevance, human labeler data with the sensor data to classify the sensor data as labeled data.

Abstract: Navigation in a virtual environment (VE) is facilitated by the creation and traversal of a 3D navigation path. A computing platform renders perspective-view imagery (PVI) of portions of the VE for display on a display device. User interactive input (UII) is read, and interaction with the VE is effected via the UII. A 3D navigation path is formed in the VE based on the UII interactive with the PVI. Thereafter, virtual movement is effected along the 3D navigation path while the viewing direction of the PVI is varied based on the UII.

Abstract: Systems, apparatuses, and methods may provide for technology to conduct contemporaneous crowd-sourced voting via interaction between a client and a client interface.

Abstract: Technologies for controlling degradation of a sensor mote including detecting a trigger event and initiating degradation of at least a portion of the sensor mote in response to the trigger event. The trigger event may be embodied as any type of event detectable by the sensor mote such as a trigger signal, particular sensed data, expiration of a reference time period, completion of a task, and so forth. The sensor mote may imitate the degradation by, for example, controlling a valve to release a chemical stored in the sensor mote or allow a substance into the sensor mote.

Abstract: Examples include techniques for real object and hand representation in virtual reality content. In some examples, one or more hands of a user of a head-mounted display (HMD) may be tracked while receiving sensor data from an identified object including one or more embedded sensors. Virtual reality content visible to the user on the HMD may be modified based on the tracking of the one or more hands and based on the received sensor data.

Abstract: Technologies for motion-compensated virtual reality include a virtual reality compute device of a vehicle. The virtual reality compute device is configured to render a virtual reality content to an occupant of the vehicle and determine a motion of the vehicle based at least on sensor data generated by one or more vehicle motion sensors of the vehicle. Based on the determined motion of the vehicle, the virtual reality compute device modifies the rendered virtual reality media. In some embodiments, the virtual reality compute device may utilize other sensors associated with the vehicle and/or a user-worn virtual reality device to predict the motion of the vehicle in order to determine an expected motion of the vehicle that is expected to be sensed in the future.

Abstract: Various embodiments are directed to techniques for reducing electric power employed by devices of a game play monitoring system that collects data during game play in a sport. An apparatus may include an interaction detection component to monitor an interaction sensor of a playing piece to detect an interaction with a body, generate playing piece data recording an aspect of the interaction and determine whether the interaction maintains the playing piece within a close proximity to the body; and a communications component to use electric power from a power source to wirelessly transmit the playing piece data to a player device carried by the body via shorter range wireless communications or to an access point device via longer range wireless communications based on the determination, the shorter range wireless communications to consume electric power of the power source at a lesser rate. Other embodiments are described and claimed.

Abstract: Systems, apparatuses and methods for monitoring and adjusting audio/video/actuation (A/V/A) synchronization to ensure immersive mixed reality experiences. The method includes preparing the mixed reality content with timestamp metadata in the content stream to describe modality synchronization requirements. The mixed reality content is presented. Synchronization between components of the mixed reality content is monitored. The system determines whether the components of the mixed reality content are in synchronization. If they are not in synchronization, the system may take action to improve the perception of the A/V/A synchronization.

Abstract: Technologies for user notification suppression include a user notification controller that controls a presentation of notifications to a user. The user notification controller includes a user notification determiner that determines whether a user notification is to be presented to the user, a user activity analyzer that determines an activity of the user, and a notification suppressor. The notification suppressor determines whether the determined activity of the user is indicative of the user's knowledge of information included in the user notification prior to the presentation of the user notification to the user. In response to a determination that the determined activity of the user is indicative of the user's knowledge of the information included in the user notification, the notification suppressor suppresses the presentation of the user notification to the user.

Abstract: Technologies for time-delayed augmented reality (AR) presentations includes determining a location of a plurality of user AR systems located within the presentation site and determining a time delay of an AR sensory stimulus event of an AR presentation to be presented in the presentation site for each user AR system based on the location of the corresponding user AR system within the presentation site. The AR sensory stimulus event is presented to each user AR system based on the determined time delay associated with the corresponding user AR system. Each user AR system generates the AR sensory stimulus event based on a timing parameter that defines the time delay for the corresponding user AR system such that the generation of the AR sensory stimulus event is time-delayed based on the location of the user AR system within the presentation site.

Abstract: Technologies for generating a motion model for a virtual character includes a compute device that generates an online search query for motion videos of an animal that depict a corresponding animal in motion and selects a motion video from a search result of the online search query. The selected motion video is analyzed to generate a motion model for the virtual character based on the motion of the animal depicted in the selected motion video. The compute device presents the virtual character in motion on a display using the generated motion model for the motion of the virtual character.

Abstract: One embodiment provides an apparatus. The apparatus includes a user profile; and a content filter logic. The content filter logic is to determine whether a content of a received message directed to a target recipient is compatible with the user profile and a current emotional state of the target recipient and to select at least one action based, at least in part, on one or more of the content, the user profile and/or the current emotional state of the target recipient. The at least one action is selected from the group comprising place the received message on hold, provide the received message to the target recipient, modify the received message, delete the received message, store the received message to an original message log, provide an alert to the target recipient, forward the message to another recipient and/or ascertain, from a sender, an urgency of the received message.

Abstract: One embodiment provides an apparatus. The apparatus includes a group response logic. The group response logic is to determine a respective user emotional response to a relevant content provided to each user of a plurality of users. The respective emotional response is determined based, at least in part, on a respective user objective data captured for each user in response to exposure of each user to the relevant provided content. The relevant content is provided to at least some of the plurality of users across at least one of a plurality of points in time and/or a plurality of locations. The group response logic is further to aggregate a plurality of respective user emotional responses to yield a first aggregated emotional response.

Abstract: Tangible interfaces for partitioned energy consumption are generally described herein. An example tangible resource device to represent a limited resource may include sensor and communication modules to receive a consumption limit of the limited resource allocated to an associated user. The sensor and communication modules may further monitor consumption of the limited resource by the associated user. The example tangible resource device may further include a display to present information indicative of the consumption limit and consumption of the limited resource by the user, and an interface module to receive input from the user to control the limited resource.