Abstract: An embodiment of the invention includes determining a first security status for first information and a second security status for second information, the second security status being more secure than the first security status; establishing a first communication path between the system and a first local computing node via a first wireless path; conveying the first information to the first local computing node via the first wireless path based on the first security status; and withholding the second information from the first local computing node based on the second security status; wherein the first and second information are stored on at least one of the system and a remotely located computing node. Other embodiments are described herein.

Abstract: A system and method for generating and using a wearable device profile are disclosed. A particular embodiment includes: a retention mechanism including an attachment mechanism configured to attach the retention mechanism to a body part of a user; a memory device for storage of information indicative of the location of the body part in a wearable device profile; and a data interface for communicating the wearable device profile to another electronic device.

Abstract: A method is described to facilitate behavioral nudging. The method includes receiving sensory data from one or more wearable devices, determining a context for a user wearing the one or more wearable devices based on the sensory data, determining a mechanism to nudge the user to reinforce user behavior based on stored preferences and policies and transmitting a nudging stimulus to at least one of the wearable devices via the determined mechanism to provide a notification to the user.

Abstract: Various systems and methods for a conversation agent are described herein. A system for a conversation agent includes a context module to determine a context of a conversation involving a first participant and a second participant; a conversation history module to access a conversation history of the first participant and a conversation history of the second participant; a conversation topic module to identify a conversation topic using the context of the conversation, the conversation history of the first participant, and the conversation history of the second participant; and a presentation module to present the conversation topic to the first participant.

Abstract: An apparatus may include a memory to store a recorded video. The apparatus may further include an interface to receive at least one set of sensor information based on sensor data that is recorded concurrently with the recorded video and a video clip creation module to identify a sensor event from the at least one set of sensor information and to generate a video clip based upon the sensor event, the video clip comprising video content from the recorded video that is synchronized to the sensor event.

Abstract: Systems, apparatuses and methods may provide for classifying a physical proximity event with respect to a wearable device based on one or more of a haptic input or a scent input. Additionally, the classified physical proximity event may be correlated with an augmented reality (AR) effect, wherein the AR effect may be initiated via the wearable device. In one example, the AR effect cancels a negative perceptual impact of the physical proximity event.

Abstract: Technologies for virtual camera scene generation include a computing device and one or more physical objects. The computing device determines a physical position of each of the physical objects by using a position sensor to detect a position sensor target of each physical object. The computing device determines a virtual object position based on the physical position of each of the physical objects. The computing device renders a virtual camera scene based on the virtual object positions. The computing device may identify one or more three-dimensional models corresponding to the physical objects and render each of the three-dimensional models in the virtual camera scene. The computing device may determine a predefined behavior associated with a virtual object based on the physical position or identity of the physical objects, or based upon user input received from a physical object. Other embodiments are described and claimed.

Abstract: Systems and methods may provide for determining a usage configuration of a wearable device and setting an activation state of an air conduction speaker of the wearable device based at least in part on the usage configuration. Additionally, an activation state of a tissue conduction speaker of the wearable device may be set based at least in part on the usage configuration. In one example, the usage configuration is determined based on a set of status signals that indicate one or more of a physical position, a physical activity, a current activation state, an interpersonal proximity state or a manual user request associated with one or more of the air conduction speaker or the tissue conduction speaker.

Abstract: The enhancement of user-to-user communication with augmented reality is described. In one example, a method includes receiving virtual object data at a local device from a remote user, generating a virtual object using the received virtual object data, receiving an image at the local device from a remote image store, augmenting the received image at the local device by adding the generated virtual object to the received image, and displaying the augmented received image on the local device.

Abstract: Systems and techniques for computer vision and sensor assisted contamination tracking are described herein. It may be identified that a food item has moved to a monitored area using computer vision. Sensor readings may be obtained from a sensor array. A contamination of the food item may be determined using the sensor readings. The contamination of the food item may be associated with a contamination area in the monitored area using the computer vision. A notification may be output for display in the contamination area indicating the contamination.

Abstract: Techniques for repair and/or recovery of computer program(s) installed on a programmable device using a distributed ledger that is based on cryptography and blockchain technology are described. One or more self-reliance logic/modules can commit, to a distributed ledger that resides on interconnected devices, records of watchdog communications between the devices. One or more of interconnected devices may include a respective self-reliance logic/module. The logic/modules can use the records of the distributed ledger to check that computer program(s) on the interconnected devices are operating as expected. When a self-reliance logic/module fails to respond to a watchdog communication, the distributed ledger can be updated to include this failure. A self-reliance logic/module can determine, based on the distributed ledger and/or the failure, that an installed computer program is faulty. Furthermore, a self-reliance logic/module can initiate one or more software recovery services based on the determination.

Abstract: Various systems and methods for virtual reality transitions are described herein.

Abstract: In some embodiments, the disclosed subject matter involves a system for mapping projection of content to surfaces in an environment. Groups of users in the environment are identified and surfaces in the environment are selected/assigned for projection and/or touch input based on user preferences, ranking of surfaces for projectability or touchability, content to be displayed, proximity of user groups to one another and surfaces, and user feedback and control. Other embodiments are described and claimed.

Abstract: Various systems and methods for presenting mixed reality presentations are described herein. A head-mounted display system for presenting mixed reality presentations including a processor subsystem to implement and interface with: a context engine to determine a user context of a user of a head-mounted display (HMD); a picture-in-picture (PIP) coordinator engine to determine a picture-in-picture (PIP) content for display in a PIP view of the HMD; and a graphics driver to simultaneously display an alternate reality content in a main view of the HMD and the PIP content in the PIP view of the HMD.

Abstract: Systems, apparatuses and methods may provide for visually or audibly indicating to users what areas are being covered or monitored by cameras, microphones, motion sensors, capacitive surfaces, or other sensors. Indicators such as projectors, audio output devices, ambient lighting, haptic feedback devices, and augmented reality may indicate the coverage areas based on a query from a user.

Abstract: Methods, apparatus, and systems to create, output, and use animation programs comprising keyframes, objects, object states, and programming elements. Objects, object states, and programming elements may be created through image analysis of image input. Animation programs may be output as videos, as non-linear interactive experiences, and/or may be used to control electronic actuators in articulated armatures.

Abstract: One or more sensors gather data, one or more processors analyze the data, and one or more indicators notify a user if the data represent an event that requires a response. One or more of the sensors and/or the indicators is a wearable device for wireless communication. Optionally, other components may be vehicle-mounted or deployed on-site. The components form an ad-hoc network enabling users to keep track of each other in challenging environments where traditional communication may be impossible, unreliable, or inadvisable. The sensors, processors, and indicators may be linked and activated manually or they may be linked and activated automatically when they come within a threshold proximity or when a user does a triggering action, such as exiting a vehicle. The processors distinguish extremely urgent events requiring an immediate response from less-urgent events that can wait longer for response, routing and timing the responses accordingly.

Abstract: Sensor management systems for computer assisted or autonomous driving vehicles are disclosed herein. A computer assisted or autonomous driving vehicle may be provided with a plurality of sensors and a sensor management system configured to predictively maintain effectiveness of the plurality of sensors, based at least in part on predicted cleaning needs of the sensors, predicted obstruction or destruction events of the sensors, or predicted environmental or operating conditions. In embodiments, the sensor management system may be coupled to a navigation system of the vehicle, and may, in response to a predicted sensor obstruction or destruction event, change a navigation parameter of the vehicle to avoid the event. Alternatively, if the predicted event is determined to be within an acceptable risk tolerance threshold, the sensor management system may follow an original navigational route but implement event avoidance actions. Other embodiments may be disclosed or claimed.

Abstract: Methods, apparatus, systems and articles of manufacture for measuring and adjusting physical resistance for athletic activities and fitness equipment are disclosed. An example system includes a user-wearable sensor to measure a first level of physical effort during a first athletic activity using fitness equipment and to generate sensor data indicative of the measured first level of physical effort. The example system also includes a controller to receive the sensor data to perform a comparison of the sensor data and data from second athletic activity indicative of a second level of physical effort, and automatically generate a control signal to adjust a setting of the fitness equipment based on the comparison.

Abstract: A mechanism is described for facilitating powering of unpowered objects for tracking, augmented reality, and other experiences according to one embodiment. A method of embodiments, as described herein, includes scanning, by a scanner of a computing device, an object, where the object includes an unpowered object, and where the scanner is further to detect a smart tag at the object. The method may further include providing power, by the computing device, to the object, where the power is provided via the smart tag at the object, where providing power includes initiating an output from the object to enable performing of location tracking of the object, where the output is received by the computing device. The method may further include rendering an augmented reality (AR) experience involving the object, where the AR experience is based on the output.