The present disclosure provides task delegation and cooperation for automated assistants. In one example, a method includes receiving, at a centralized support center that is in contact with a plurality of automated assistants including a first automated assistant and a second automated assistant, a request to perform a task on behalf of an individual, formulating, at the centralized support center, the task as a plurality of sub-tasks including a first sub-task and a second sub-task, delegating, at the centralized support center, the first sub-task to the first automated assistant, based on a determination at the centralized support center that the first automated assistant is capable of performing the first sub-task, and delegating, at the centralized support center, the second sub-task to the second automated assistant, based on a determination at the centralized support center that the second automated assistant is capable of performing the second sub-task.

A method and system for mapping media content is provided. The method includes detecting first media content being presented. The first media content is compared to second media content and similarities are determined. In response, are first electronic device is paired with a second electronic device and associated input content being inputted into a GUI is detected. A contextual analysis of the input content is executed and audio, video, and image data is compared to the input content. A correlation between the input content and a portion of the audio, video, and image data is determined and an associated portion is extracted from the audio, video, and image data. The portion is embedded and presented within a specified area of the GUI.

A wearable electronic device includes a first member and a second member. The second member includes a first, RF-attenuating, portion and a second, electrically conductive portion. A gap exists between the first member and at least the second portion of the second member. One or more transmitter/receivers, such as one or more BLUETOOTH, BLUETOOTH low energy, and/or IEEE 802.11 transceivers may be mounted in the first member. The one or more transmitter/receivers are conductively coupled to the second portion of the second member. RF signals generated by the one or more transceivers are emitted from the second portion of the second member.

In one embodiment, a server computing device receives a message indicating a current notification mode of a mobile computing device of a user. The received message comprises information from one or more sensors of the mobile computing device. The current notification mode is based at least in part on the information from the one or more sensors of the mobile computing device. The activity of the user is determined based at least in part on sensor information of the mobile computing device. The current notification mode of the mobile computing device is determined based on the user activity or the information from the one or more sensors of the mobile computing device. The server computing device determines whether to transmit a communication to the mobile computing device based on the current notification mode of the mobile computing device.

Aspects of this disclosure relate to pair of wireless communication devices wirelessly communicating with a network system in a coordinated manner. A secondary wireless communication device can wirelessly communicate part of a multiple-input multiple-output (MIMO) transmission associated with a primary wireless communication device (i) with the primary wireless communication device via the peer-to-peer link and (ii) with the network system via a cellular link. The secondary wireless communication device can enable the primary wireless communication device to communicate with the network system at a higher data rate and/or at a higher MIMO rank.

A registration is received from an application framework. The registration is for the application framework to be notified of an event managed by a service gateway. The event is based on a communication service provided by the service gateway. The service gateway detects the event. The service gateway sends a notification associated with the event to the application framework. The notification associated with the event comprises information associated with the event. For example, the notification may include a caller's name and address. An object is received from the application framework that is associated with the event. The object associated with the event further comprises extension information that is not used by the communication service/service gateway. A message is sent to a communication endpoint and/or an external application that comprises the object. The extension information is used to provide custom services that are not supported by the communication service/service gateway.

In order to perform message routing utilizing service-oriented communication without having inquiry of a routing database storing all message transmission paths between a plurality of controllers, a message routing system according to an embodiment includes: an adapter configured to perform a conversion between a CAN message for CAN (Controller Area Network) communication and a service message for service-oriented communication; and a gateway configured to receive an offer-service message and a service subscription message from the plurality of controllers through the adapter, and set a message transmission path between the plurality of controllers based on the offer-service message and the service subscription message.

Control systems and methods are provided for vehicles that include, in one embodiment, a plurality of sensors, and a processor. The plurality of sensors are dispersed across a body of the vehicle, and are configured to detect an electronic device in proximity to the vehicle; and collect sensor data with respect to the electronic device. The processor is configured to determine, using the sensor data, whether the electronic device is physically disposed inside the vehicle; and selectively connect the electronic device with a telematics unit of the vehicle, via the processor, based on whether the electronic device is physically disposed inside the vehicle.

A system and methods relate to, inter alia, aggregating electronic information generated at a first computing environment. The system and methods further relate to receiving a message for at least a portion of the electronic information from a second computing environment. The system and methods further relate to determining whether the aggregated electronic information is available. The system and methods further relate to transforming the electronic information from a first type to a second type in response to determining that the aggregated electronic information is available, the first type comprising an electronic information type of the electronic information generated at the first computing environment and the second type comprising another electronic information type consumable by the second computing environment. The system and methods further relate to transmitting at least a portion of the transformed electronic information to the second computing environment.

Aspects of this disclosure relate to pair of wireless communication devices wirelessly communicating with a network system in a coordinated manner. A secondary wireless communication device can wirelessly communicate part of a multiple-input multiple-output (MIMO) transmission associated with a primary wireless communication device (i) with the primary wireless communication device via the peer-to-peer link and (ii) with the network system via a cellular link. The secondary wireless communication device can enable the primary wireless communication device to communicate with the network system at a higher data rate and/or at a higher MIMO rank.