Abstract: A smart fabric may include a smart material such as an Electroactive Polymer (EAP). An adaptive garment formed from the smart fabric may change textile density based on user needs, sensor states, context, and other inputs. In various embodiments, the EAP enables the adaptive garment to change textile density based on a sport or activity, based on calendar or scheduled events, or based on user preferences. In various embodiments, these smart fabrics may be implemented in sporting garments, uniforms, multiple-day clothing (e.g., for travel or military usage), furniture fabric, curtains, or other implementations.

Abstract: A mechanism is described for dynamically facilitating virtual wearables according to one embodiment. A method of embodiments, as described herein, includes detecting a wearable area. The wearable area may represent a human body part of a primary user. The method may further include scanning the wearable area to facilitate suitability of the wearable area for projection of a virtual wearable, and projecting the virtual wearable on the wearable area using a primary wearable device of the primary user such that the projecting is performed via a projector of the primary wearable device.

Abstract: An embodiment of a semiconductor package apparatus may include technology to analyze an electronic image to determine indirect information including one or more of shadow information and reflection information, and provide the indirect information to a vehicle guidance system. Other embodiments are disclosed and claimed.

Abstract: Apparatus, systems, and/or methods may involve reporting a road hazard. Road hazard data may be collected for an object on a road, which may include automatically generated data from a device associated with the object causing a hazard. The road hazard data may be provided to a service, an application, a device, a client, and so on. For example, the road hazard data may be merged with a map and provided to a map services client, a navigation client, and so on. An alert may be generated based on the road hazard data to warn of the hazard caused by the object. The alert may include a visual and/or audio representation of the hazard data. The alert may be used to automatically and/or manually avoid the hazard.

Abstract: Technologies are described for delivering an active agent using an ingestible pill device, securing medication package content, and monitoring the medication package content. Examples of the technology include using an ingestible pill device to deliver an active agent, where release of the active agent can be based on patient authentication, analyzing sensor data to determine a condition for releasing the active agent, analyzing image data to identify a release point, etc. Examples of the technology also include using a monitoring device to secure a medication package using a cover and locking device, monitoring the medication package to detect access to the medication package, and tracking access to the medication package to determine medication adherence.

Abstract: A mechanism is described for facilitating dynamic detection and intelligent use of segmentation on flexible display screens according to one embodiment. A method of embodiments, as described herein, includes detecting, via one or more touch sensors, alterations in current in and around one or more areas of a flexible display screen, where the alterations represent pressure being applied to cause at least one of bending, rolling, and curving of the flexible display screen at the one or more areas. The method may further include dividing the flexible display screen into a plurality of zones corresponding to the one or more areas, where the marking/dividing logic is further to mark a plurality of portions of the plurality of zones to serve as a plurality of segments. The method may further include facilitating displaying of contents via the plurality of segments of the flexible display screen.

Abstract: Embodiments include apparatuses, methods, and systems for computer assisted or autonomous driving (CA/AD). An apparatus may include a trailer data collection unit and an automation level determination unit coupled with the trailer data collection unit. The trailer data collection unit may collect, from a trailer coupled with a CA/AD towing vehicle, trailer configuration data, including sensor configuration data for sensors disposed on the trailer. The automation level determination unit may determine a combined level of driving automation for the CA/AD towing vehicle and the trailer, based at least in part on the trailer configuration data, wherein the CA/AD towing vehicle alone has an initial level of driving automation. An apparatus for CA/AD may include a sensor configuration unit, a trailer configuration unit, and a communication interface coupled with the sensor configuration unit and the trailer configuration unit. Other embodiments may also be described and claimed.

Abstract: Various systems and methods for capturing media moments are described herein. An autonomous camera system for capturing media moments includes a configuration module to receive configuration parameters; a flight control module to autonomously maneuver the autonomous camera system over a crowd of people; a search module to search for a subject in the crowd of people based on the configuration parameters; and a control module to perform an action when the subject is found in the crowd of people.

Abstract: An example includes a computing device including a controller configured to communicably couple the computing device to a peripheral computing device. The controller includes an encryption unit configured to encrypt input data received from the peripheral computing device before sending the input data to an application running on the computing device, and a decryption unit configured to decrypt output data received from the application before sending the output data to the peripheral computing device. The computing device also includes a memory device including a data structure that directs the flow of the data between the peripheral computing device and the application. The data structure includes an encryption enable field and an encryption key field for controlling the encryption and decryption units of the controller.

Abstract: Various systems and methods for optimizing use of environmental and operational sensors are provided. A system for improving sensor efficiency includes object recognition circuitry (108) implementable in a vehicle (102) to detect an object ahead of the vehicle (102), the object recognition circuitry (108) to use an object detection operation to detect the object from sensor data of a sensor array, and the object recognition circuitry (108) configured to use at least one object tracking operation to track the object between successive object detection operations; and a processor (106) subsystem to: calculate a relative velocity of the object with respect to the vehicle (102); and configure the object recognition circuitry (108) to adjust intervals between successive object detection operations based on the relative velocity of the object.

Abstract: Various systems and methods for providing a road condition heads up display system are provided herein. A road condition heads up display system, includes: a video display to present imagery captured by a camera system, the imagery including terrain around an autonomous vehicle, the terrain including a driving surface on which the autonomous vehicle operates; a vehicle control system coupled to the camera system and the video processor, the vehicle control system to: operate the autonomous vehicle in an autonomous mode; recognize a non-navigable portion of the terrain around the autonomous vehicle; present an augmented reality user interface on the video display, the augmented reality user interface used by an occupant of the autonomous vehicle to indicate a waypoint; and operate the autonomous vehicle in a non-autonomous mode according to the user input.

Abstract: With a device comprising a directional antenna, obtain an interaction profile for an augmentable object and augment a sensory experience of the augmentable object according to the interaction profile.

Abstract: A mechanism is described for facilitating dynamic detection and intelligent use of segmentation on flexible display screens according to one embodiment. A method of embodiments, as described herein, includes detecting, via one or more touch sensors, alterations in current in and around one or more areas of a flexible display screen, where the alterations represent pressure being applied to cause at least one of bending, rolling, and curving of the flexible display screen at the one or more areas. The method may further include dividing the flexible display screen into a plurality of zones corresponding to the one or more areas, where the marking/dividing logic is further to mark a plurality of portions of the plurality of zones to serve as a plurality of segments. The method may further include facilitating displaying of contents via the plurality of segments of the flexible display screen.

Abstract: Systems, apparatuses and methods may leverage technology that recognizes a set of one or more hands in one more frames of a video signal during a first gesture control interaction between the set of one or more hands and an electronic device. Moreover, one or more additional body parts may be detected in the frame(s), wherein the additional body part(s) are excluded from the gesture control interaction. In one example, detecting the additional body part(s) includes determining that the additional body part(s) correspond to a different individual than a target individual associated with the set of hand(s).

Abstract: Technologies for managing assets of a data center include a unmanned aerial vehicle (UAV) communicatively coupled to a remote computing device. The UAV is configured to navigate throughout a data center and capture data center mapping information during the navigation usable to generate a three-dimensional (3D) model of the data center. The UAV is further configured to transmit the captured data center mapping information to a remote computing device. Accordingly, the UAV can receive instructions from a remote computing device that define a type of task to be performed by the UAV in the data center and perform such a task (e.g., a data center map update task, an asset inventory task, a maintenance task, a visual inspection task, etc.) based on the received task instructions. Other embodiments are described and claimed herein.

Abstract: Technologies for seamless data streaming include a control server and one or more client computing devices. A client computing device receives user presence data indicative of whether a user is nearby from one or more sensors. The client computing device may receive user interest data indicative of the user's interest level in the current data stream from one or more sensors. The control server identifies available client computing devices based on the user presence data, selects a target client computing device, and causes the data stream to transition from the current client computing device to the target client computing device. The target client computing device may be selected based on proximity of the user or the user's interest level in the data stream. The volume or balance of the data stream may be adjusted to provide a smooth transition between client computing devices. Other embodiments are described and claimed.

Abstract: Technologies for managing power consumption include a power management device that determines a context associated with a user of computing devices located within a building and in communication with the power management device. The power management device compares the context associated with the user to a power management policy. The power management policy includes power management rules that define power consumption levels for the computing devices based on the context associated with the user. The power management device communicates with the computing devices to adjust the power consumption levels in response to the context associated with the user satisfying a power management rule.

Abstract: A smart fabric may include a smart material such as an Electroactive Polymer (EAP). An adaptive garment formed from the smart fabric may change textile density based on user needs, sensor states, context, and other inputs. In various embodiments, the EAP enables the adaptive garment to change textile density based on a sport or activity, based on calendar or scheduled events, or based on user preferences. In various embodiments, these smart fabrics may be implemented in sporting garments, uniforms, multiple-day clothing (e.g., for travel or military usage), furniture fabric, curtains, or other implementations.

Abstract: Technologies for seamless data streaming include a control server and one or more client computing devices. A client computing device receives user presence data indicative of whether a user is nearby from one or more sensors. The client computing device may receive user interest data indicative of the user's interest level in the current data stream from one or more sensors. The control server identifies available client computing devices based on the user presence data, selects a target client computing device, and causes the data stream to transition from the current client computing device to the target client computing device. The target client computing device may be selected based on proximity of the user or the user's interest level in the data stream. The volume or balance of the data stream may be adjusted to provide a smooth transition between client computing devices. Other embodiments are described and claimed.

Abstract: Technologies for sensor action verification include a local computing device to receive a request for the local computing device to perform a sensor action from a remote computing device. The local computing device verifies the received request to confirm that the remote computing device is authorized to request the local computing device to perform the sensor action and performs, by a sensor controller of the local computing device, the requested sensor action in response to verification of the received request. The sensor controller manages operation of one or more sensors of the local computing device. The local computing device transmits a response message to the remote computing device indicating whether the requested sensor action has been performed by the sensor controller of the local computing device.