Abstract: A determination is made as to when two computing devices are in the presence of each other, also referred to as the two computing devices being colocated. This determination is made based on wireless location signals received at the two computing devices as well as environment data sensed by the two computing devices. The computing devices determine whether they are in the presence of each other and enable multi-device engagement in response to determining that the two computing devices are in the presence of each other.

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: Apparatuses, methods, and systems are disclosed for transmitting a message in response to receiving a message. One apparatus (300) includes a receiver (312) that receives (602) a second message from a second remote unit (200). The second message is transmitted from the second remote unit in response to the second remote unit receiving a first message from a first remote unit. The apparatus (300) includes a transmitter (310) that transmits (604) a third message corresponding to the first message in response to receiving the second message.

Abstract: A system and method of adaptive video interface switching between a mobile electronic communications device and a wearable device entail determining during an ongoing video session via a first one of the devices that an audio or video input or output mechanism on the first device is compromised. It is determined that the audio and video input and output mechanisms on a second of the devices are uncompromised. The video session is then continued using at least one of the audio and video input and output mechanisms on the second device.

Abstract: A system and method of adaptive video interface switching between a mobile electronic communications device and a wearable device entail determining during an ongoing video session via a first one of the devices that an audio or video input or output mechanism on the first device is compromised. It is determined that the audio and video input and output mechanisms on a second of the devices are uncompromised. The video session is then continued using at least one of the audio and video input and output mechanisms on the second device.

Abstract: An electronic device includes an audio capture device receiving audio input. The electronic device includes one or more processors, operable with the audio capture device, and configured to execute a control operation in response to a device command preceded by a trigger phrase identified in the audio input when in a first mode of operation. The one or more processors transition from the first mode of operation to a second mode of operation in response to detecting a predefined operating condition of the electronic device. In the second mode of operation, the one or more processors execute the control operation without requiring the trigger phrase to precede the device command.

Abstract: Implementations for masking for mitigating visual contrast of a camera region of a display are described. Generally, the described techniques provide ways for mitigating visual differences between a camera region and other regions of a display. For instance, visual masks can be generated and displayed overlapping and/or peripherally to a camera region of a display to smooth a visual transition between the camera region and other regions of the display. The masks, for example, are displayed in regions of the display that surround the camera region. Further, color attributes of the masks can be configured to provide a gradual visual transition from color output at the camera region to color output at other regions of the display.

Abstract: Systems and methods for providing multiple paths through a mobile electronic device entail providing one of multiple levels of device access and cloud access based on an identity determination and authentication as to a potential user. In an embodiment, the device attempts to identify the user based on traditional touch/touchless authentication techniques. If this attempt is unsuccessful, the device then tries to identify the user by alternative means. If the user can be identified, the device attempts to authenticate the user for full access to the device and associated cloud data. If this is successful, the user is granted full access. If instead the identified user is not qualified for full access, the user is given pass-through access to their personal cloud storage. If, however, the device is unable to even identify the user, the user may be given pass-through access to the cloud generally.

Abstract: Apparatuses, methods, and systems are disclosed for reconfiguring a data connection using new parameters. One apparatus includes a processor and transceiver that communicates with a mobile communication network. The processor establishes a data connection with the mobile communication network using a first set of parameters and receives a second set of parameters from the mobile communication network with an indication of how at least one parameter in the first set corresponds to at least one new parameter in the second set. The processor further determines a third set of parameters from the first set of parameters and the second set of parameters and reconfigures the data connection using the third set of parameters.

Abstract: In aspects of shareable devices, a shareable device implements a device sharing module that can maintain an interactive session of a user on the shareable device. The shareable device can detect that the user has moved away from the shareable device during the interactive session, and obscure personalized content associated with the user who has moved away from the shareable device. The device sharing module is implemented to detect, without user input, a user condition indicative of an intent to end or share the interactive session. The device sharing module can determine a status of an executing application associated with the interactive session of the user. The device sharing module can then end or share the interactive session based on the detected user condition and the determined status of the application.

Abstract: An electronic device, method, and computer program product provide detecting entry of an image capturing device of the electronic device into an image capture mode. In response to detecting entry, a controller of the electronic device detects, via at least one of: (i) the image capturing device; and (ii) the microphone, a first external input that alerts a subject that an image of the subject is about to be captured by the image capturing device. In response to detecting the first external input, the controller enables the electronic device to monitor for detection by one of: (i) the image capturing device; and (ii) the microphone of a second external input. The second external input is associated with the subject being ready to have an image of the subject captured. In response to detecting the second external input, the controller activates recording of image data via the image capturing device.

Abstract: Techniques for optimal device position for wireless communication are described, and may be implemented via a mobile device to identify an orientation in which to place a mobile device to achieve optimum wireless signal. Generally, the described techniques enable the mobile device to be dynamically calibrated for wireless communication by identifying signal attributes at multiple different device positions, and enabling the mobile device to be placed at a position that exhibits optimum wireless signal. Further, calibration can take into account multiple different antennas on the mobile device, and wireless signal attributes detected at each individual antenna.

Abstract: Multiple feed, front-shielded, coplanar waveguide, direct-fed, cavity-backed slot antennas are described. Various implementations form an antenna unit capable of millimeter waveform and/or microwave waveform transmissions. An antenna comprises a conductive plate that includes an aperture. The aperture has a shape that extends along an axis that bisects the aperture into first and second bisected portions, the first bisected portion having a first geometry type, and the second portion having a second geometry type that is a bilateral symmetry shape type of the first geometry type. In implementations, the aperture is configured to radiate waveforms within a frequency range from about between 600 Megahertz (MHz) to 72 Gigahertz (GHz) by applying multiple signal feeds to the conductive plate.

Abstract: Implementations for heat structure for thermal mitigation are described. The described heat structures, for instance, provide a multi-layered structure that optimizes heat spreading and dissipation, as well as wireless performance of wireless devices. A heat structure, for instance, is installed internally in a wireless device adjacent various internal components to absorb heat generated by the components, and to dissipate the heat. According to various implementations, a heat structure is implemented as a thermally conductive layer surrounded by layers of electrically conductive material. Electrically conductive vias can be formed that traverse the thermally conductive layer and form an electrical connection between different electrically conductive layers to mitigate current flow in the thermally conductive layer.

Abstract: Front-shielded, coplanar waveguide, direct-fed, cavity-backed slot antennas are described. Various implementations form an antenna unit capable of millimeter waveform and/or microwave waveform transmissions. A bottom shielding structure of the antenna unit defines a cavity, where various implementations include one or more dampening structures within the cavity. Some implementations includes a slot antenna within the cavity defined by the bottom shielding structure, such as a coplanar waveguide (CPW) direct-fed slot antenna, to form a cavity-backed slot antenna. Some implementations connect a top shielding structure to the bottom shielding structure to encase the slot antenna. In one or more implementations, the top shielding structure includes aperture windows to allow waveforms within a frequency range from about between 600 Megahertz (MHz) to 72 Gigahertz (GHz). and radiated by the slot antenna to radiate outward from the antenna unit.

Abstract: Apparatuses, methods, and systems are disclosed for gap period (524, 528, 532, 536) configuration. One apparatus (200) includes a receiver (212) that receives (602) a configuration message. The configuration message includes information that configures one or more gap periods within a transmission period. The apparatus (212) also includes a transmitter (210) that transmits (604) data in the transmission period. The receiver (212) receives (606) a control indication message in the one or more gap periods.

Abstract: Front-shielded, coplanar waveguide, direct-fed, cavity-backed slot antennas are described. Various implementations form an antenna unit capable of millimeter waveform and/or microwave waveform transmissions. A bottom shielding structure of the antenna unit defines a cavity, where various implementations include one or more dampening structures within the cavity. Some implementations includes a slot antenna within the cavity defined by the bottom shielding structure, such as a coplanar waveguide (CPW) direct-fed slot antenna, to form a cavity-backed slot antenna. Some implementations connect a top shielding structure to the bottom shielding structure to encase the slot antenna. In one or more implementations, the top shielding structure includes aperture windows to allow waveforms within a frequency range from about between 600 Megahertz (MHz) to 72 Gigahertz (GHz) and radiated by the slot antenna to radiate outward from the antenna unit.

Abstract: An electronic device (e.g., smartphone) can be connected to an external display device, allowing the electronic device to display content on the external display device. The external display device can be a standalone display device or be part of another electronic device (e.g., a laptop or tablet). The electronic device supports multiple input styles including a gesture-based input style and a non-gesture-based input style. The electronic device adapts to the external display device by using the gesture-based input style if the external display device is touch enabled and using the non-gesture-based if the external display is not touch enabled. Additionally or alternatively, the external display device adapts to the input style being used by the electronic device by displaying an augmentation bar associated with the content and supporting the non-gesture-based input style when the external display device detects that the electronic device is using the gesture-based input style.

Abstract: Techniques for thermal based wireless configuration are described and may be implemented via a wireless device to adapt antennas and/or wireless beams of the wireless device based on a thermal condition. Generally, the described techniques enable the wireless device to compensate for thermal conditions that occur at different antennas, such as high temperatures that may degrade antenna and device performance.

Abstract: The present application provides a method and a user device for monitoring a use condition. The method includes determining a baseline level of performance for each of one or more elements of the device including a determined replacement threshold level. The method further includes running a diagnostic determining the current performance of at least some of the one or more elements for which a baseline level of performance has been determined, wherein the running of the diagnostic includes a diagnostic determination triggered by a detected non-standard use condition. The current performance of the at least some of the one or more elements is compared to the determined baseline level performance for the respective ones of the one or more elements of the user device. When the determined current performance of at least one of the one or more elements falls below the determined replacement threshold level, the user is notified of a need for service of the user device.