Abstract: In aspects of object contextual control based on UWB radios, a system includes ultra-wideband (UWB) radios associated with respective devices in an environment. The system can include camera devices that capture motions in the environment. Alternatively or in addition, the system can include a mobile wireless device moved in the environment to generate motions detected by sensors of the mobile wireless device. A motion controller can determine a motion indication to interact with a device in the environment based on a location of the device as determined by a position of the UWB radio associated with the device. The motion controller can then initiate a control communication to the device to control the device based on the motion indication to interact with the device.

Abstract: In aspects of UWB accessory for a wireless device, an attachable ultra-wideband (UWB) accessory includes a UWB radio to communicate with UWB radios in an environment. The attachable UWB accessory has one or more wireless interfaces to wirelessly communicate with radio devices of a wireless device to which the UWB accessory is attached. The attachable UWB accessory can also include a micro-controller that receives UWB ranging data from the UWB radios, and may determine a location of the wireless device in the environment based on the UWB ranging data. The attachable UWB accessory may utilize Bluetooth low energy (BLE) for UWB out-of-band communications. A wireless device can be implemented with the attachable UWB accessory, and the wireless device has a BLE interface to interface with the UWB accessory.

Abstract: In aspects of UWB automation experiences controller, a system includes ultra-wideband (UWB) radios associated with respective devices in an environment. An automation controller receives UWB ranging data from the UWB radios, and can monitor locations of the respective devices in the environment based on the UWB ranging data received from the UWB radios. The automation controller can determine a location change of a device in the environment, and update an automation experience in the environment based on the location change of the device in the environment. A computing device can implement the automation controller to monitor interactions with the respective devices, and monitor the locations of the respective devices in the environment. The automation controller can update an automation experience in the environment based on an interaction and the locations of the respective devices in the environment.

Abstract: In aspects of environment dead zone determination based on UWB ranging, a system includes ultra-wideband (UWB) radios associated with respective devices in an environment. An automation controller receives UWB ranging data from the UWB radios, and can monitor locations of the respective devices in the environment. The automation controller can detect a loss of coverage by a device connected in the environment, and determine a coverage dead zone within the environment at the location of the loss of coverage by the device based on the UWB ranging data. A computing device can implement the automation controller that receives the UWB ranging data from the UWB radios, and monitors the locations of the respective devices in the environment. The automation controller can detect the loss of coverage by the device, and determine the coverage dead zone within the environment at the location of the loss of coverage by the device.

Abstract: In aspects of object contextual control based on UWB radios, a system includes ultra-wideband (UWB) radios associated with respective devices in an environment. The system can include camera devices that capture motions in the environment. Alternatively or in addition, the system can include a mobile wireless device moved in the environment to generate motions detected by sensors of the mobile wireless device. A motion controller can determine a motion indication to interact with a device in the environment based on a location of the device as determined by a position of the UWB radio associated with the device. The motion controller can then initiate a control communication to the device to control the device based on the motion indication to interact with the device.

Abstract: In aspects of object and environment dimensioning based on UWB radios, a system includes objects in an environment that are tagged objects and non-tagged objects. The system includes ultra-wideband (UWB) radios associated with respective tagged objects in the environment. A mapping module is implemented to determine a location of each of the tagged objects in the environment based on a position of the UWB radio associated with a tagged object, and determine a location of each of the non-tagged objects in the environment based on the positions of the UWB radios. The mapping module can also determine dimensions of the environment and the objects based on the location and a relative position of each tagged object and non-tagged object in the environment. In implementations, one or more of the UWB radios are UWB tags located for association with the respective tagged objects.

Abstract: In aspects of digital media playback based on UWB radios, a system includes ultra-wideband (UWB) radios associated with respective media devices in an environment. A media playback manager receives location information for each of the media devices in the environment based on a position of the UWB radio associated with a respective media device. The media playback manager determines a location of each of the media devices relative to a position of a person in the environment. The media playback manager can then initiate communication of the digital media to a media device for digital media playback of the digital media, where the digital media is communicated to the media device based on the determined position of the person relative to the location of the media device in the environment.

Abstract: In aspects of object tracking based on UWB tags, a system includes ultra-wideband (UWB) tags located for association with respective objects in an environment, where each UWB tag is identified with a digital label indicative of the association with one or more of the objects. A tracking service is implemented to receive initial location data for the objects from each of the UWB tags that are associated with the objects, and generate an object identity database in which each of the objects are identified by their respective initial location data. The tracking service can monitor for movement of an object that is identified by the initial location data based on subsequent positioning data associated with the object. The movement of an object is monitored for an unauthorized relocation of the object, for a cluster of multiple objects moving together, and/or for an abnormal proximity of multiple objects in the environment.

Abstract: In aspects of environment mapping based on UWB tags, a system includes ultra-wideband (UWB) tags located for association with respective objects in an environment, where each UWB tag is identified with a digital label indicative of the association with one or more of the objects. A mapping module is implemented to determine a location of each of the UWB tags in the environment, and determine relative positions of each of the UWB tags with respect to each other. The mapping module can generate a location association map of the objects in the environment based on the location and the relative position of each of the UWB tags associated with the respective objects. In an environment within a building, the mapping module can generate the location association map as a floor plan of the building, including the objects location in the building.

Abstract: In aspects of quantum-based security for hardware devices, a computing device includes a processor for application processing in a trusted execution environment, and includes a quantum random number generator to generate quantum random numbers sourced by multiple hardware devices in the computing device. The computing device also includes an embedded secure element that manages connection security of the multiple hardware devices, and is a single root of trust as a secure controller of the quantum random number generator. The computing device also includes a secure switch controlled by the embedded secure element, the secure switch being switchable to connect at least one of the multiple hardware devices to obtain a quantum random number from the quantum random number generator. The secure switch may be a virtualized secure switch implemented in the embedded secure element.

Abstract: A computing device supports the use of multiple different authenticators for a user to unlock his or her computing device and access his or her user account. An authenticator refers to something that the user knows or has that can be compared to known authentication data in order to authenticate the user. In one or more embodiments, the behavior of the computing device varies for different authenticators by displaying user-selectable content in different visibility modes based on which authenticator is used to authenticate the user. In one content visibility mode content is fully visible on the computing device display screen, whereas in another content visibility mode content visibility on the computing device display screen is reduced. Additionally or alternatively, the behavior of the computing device varies for different authenticators by using different authenticators for different contexts of the computing device.

Abstract: Techniques for authentication for key access are described. In the described techniques, interaction between a client device and an assistant device is utilized to authenticate the client device for access to protected functionality and/or content. For instance, proximity between the client device and the assistant device, and physical authentication of a user with the assistant device, are leveraged for authenticating the client device for access to the protected functionality and/or content.

Abstract: Content visibility on a computing device is controlled based at least in part on the current location of the computing device. When the current location is a safe location for making user-selectable content visible on a display screen of the computing device and the computing device is unlocked, the computing device operates in a full content visibility mode. In the full content visibility mode all user-selectable content on the computing device is accessible to a user of the computing device. When the current location is not a safe location for making user-selectable content visible on the display screen, the computing device operates in a reduced content visibility mode. In the reduced content visibility mode content visibility on the display screen is reduced, such as by limiting which applications (e.g., application icons or widgets) are displayed or otherwise accessible to the user.

Abstract: In aspects of quantum-based security for hardware devices, a computing device includes a processor for application processing in a trusted execution environment, and includes a quantum random number generator to generate quantum random numbers sourced by multiple hardware devices in the computing device. The computing device also includes an embedded secure element that manages connection security of the multiple hardware devices, and is a single root of trust as a secure controller of the quantum random number generator. The computing device also includes a secure switch controlled by the embedded secure element, the secure switch being switchable to connect at least one of the multiple hardware devices to obtain a quantum random number from the quantum random number generator. The secure switch may be a virtualized secure switch implemented in the embedded secure element.

Abstract: In aspects of quantum-based security for hardware devices, a computing device includes a processor for application processing in a trusted execution environment, and includes a quantum random number generator to generate quantum random numbers sourced by multiple hardware devices in the computing device. The computing device also includes an embedded secure element that manages connection security of the multiple hardware devices, and is a single root of trust as a secure controller of the quantum random number generator. The computing device also includes a secure switch controlled by the embedded secure element, the secure switch being switchable to connect at least one of the multiple hardware devices to obtain a quantum random number from the quantum random number generator. The secure switch may be a virtualized secure switch implemented in the embedded secure element.

Abstract: Techniques for subtask assignment for an artificial intelligence (AI) task are described, and may be implemented to leverage a local set of devices to distribute portions of an AI task between the devices. Generally, the described techniques enable AI task allocation based on a variety of factors, such as device capabilities, device availability, task complexity, and so forth.

Abstract: A wearable device enables access to VPN endpoint devices for secure data communication and privacy for a computing device. The wearable device stores VPN configuration information for a user, which includes the user's VPN credentials for each of one or more remote VPN endpoint devices. When the wearable device is in close proximity to a computing device and is being worn by a user that is authenticated to at least one of the wearable device and the computing device, the wearable device communicates the configuration information to the computing device. The computing device can then use this VPN configuration information to establish a VPN connection to a VPN endpoint device.

Abstract: Content visibility on a computing device is controlled based at least in part on the proximity of a wearable device to the computing device. When the wearable device is in close proximity to the computing device and the computing device is unlocked, the computing device operates in a full content visibility mode. In the full content visibility mode all user-selectable content on the computing device is displayed. When the wearable device is not in close proximity to the computing device and the computing device is unlocked, the computing device operates in a reduced content visibility mode. In the reduced content visibility mode content visibility on the computing device screen is reduced, such as by limiting which applications (e.g., application icons or widgets) are displayed.

Abstract: A wearable device enables access to VPN endpoint devices for secure data communication and privacy for a computing device. The wearable device stores VPN configuration information for a user, which includes the user's VPN credentials for each of one or more remote VPN endpoint devices. When the wearable device is in close proximity to a computing device and is being worn by a user that is authenticated to at least one of the wearable device and the computing device, the wearable device communicates the configuration information to the computing device. The computing device can then use this VPN configuration information to establish a VPN connection to a VPN endpoint device.

Abstract: An electronic device includes a user interface device and a wireless transceiver that scans for a wearable device within a threshold distance of the electronic device. The wearable device has an access key. A memory of the electronic device contains: (i) an access data structure; (ii) protected content; and (iii) an access application. A controller of the electronic device is communicatively coupled to the user interface device, the wireless receiver, and the memory. The controller executes the access application to enable the electronic device to determine whether the access key of a detected wearable device maps to a record in the access data structure identifying privileges associated with the protected content of the electronic device. Privileged interaction is enabled, via the user interface device, with the protected content in response to determining that the access key maps to the record having the privileges.