A system for package management includes an interface and a processor. The interface is to receive an indication to install a package. The processor is to determine a configured package using a set local configuration properties and using the package and to launch, using a metascheduler, a set of subschedulers to install a plurality of applications of the configured package.

A method for transmitting data from a management entity in a communication system further comprising at least one data concentrator device to which smart electricity meters are attached via a first powerline communication network, each data concentrator device being connected to the management entity via a second communication network. Said smart electricity meter receives, coming from the management entity, via the first powerline communication network, a message indicating that a transfer of data is pending with the management entity. Said smart electricity meter comprising a wireless communication interface adapted to communicate via a third wireless local communication network with a residential gateway connected to the management entity via a fourth communication network, said smart electricity meter obtains said data from the management entity via the third wireless local communication network.

A user device has a plurality of modules which support an application such as gaming application. The user device has a stream processing module which is able to stream process events which are generated, for example when the application is run. The events which are generated by the modules are passed to an event module which distributes the events to other of the modules.

A data product system and method for generating and providing a data product using data supplied by a multitude of vehicles. The data product system includes in-vehicle data selection computer instructions and a remote data product system storing backend computer instructions. When the in-vehicle data selection computer instructions are executed at a vehicle, the vehicle: obtains data used to derive or otherwise obtain one or more data items specified by a selected data model and processes and transmits the data item(s) as a second data stream to a remote data repository. When the backend computer instructions are executed at the remote data product system, the remote data product system selects a data model as the selected data model, causes the selected data model to be delivered to the vehicle, generates a second data product based on the data item(s), and provides the second data product to a third party.

Technologies for secure I/O data transfer includes a compute device, which includes a processor to execute a trusted application, an input/output (I/O) device, and an I/O subsystem. The I/O subsystem is configured to establish a secured channel between the I/O subsystem and a trusted application running on the compute device, and receive, in response to an establishment of the secured channel, I/O data from the I/O device via an unsecured channel. The I/O subsystem is further configured to encrypt, in response to a receipt of the I/O data, the I/O data using a security key associated with the trusted application that is to process the I/O data and transmit the encrypted I/O data to the trusted application via the secured channel, wherein the secured channel has a data transfer rate that is higher than a data transfer rate of the unsecured channel between the I/O device and the I/O subsystem.

A system for returning synthetic database query results. The system may include a memory unit for storing instructions, and a processor configured to execute the instructions to perform operations comprising: receiving a query input by a user at a user interface; determining, based on natural language processing, a type of the query input; determining, based on the received query input and a database language interpreter, an output data format; returning, based on a generation model and the output data format, a result of the query input; providing, to a plurality of training models and based on the determined query type, the query input and the result; and training the training models, based on the query input and the result.

A system includes a server computer programmed upon determining that a first portion of software data for updating an operational feature of a first computer is stored in the first computer and a second portion of the software data is stored in a second computer, to encode the first portion and the second portion to generate encoded data, and to send the encoded data via wireless data transfer to the first and second computers. The first computer is programmed to decode the second portion from the received encoded data, to update the operational feature of the first computer based on the stored first portion and the decoded second portion, and to operate the first computer based on the updated operational feature.

The present disclosure relates to a communication method and system for converging a 5th-Generation (5G) communication system for supporting higher data rates beyond a 4th-Generation (4G) system with a technology for Internet of Things (IoT). The present disclosure may be applied to intelligent services based on the 5G communication technology and the IoT-related technology, such as smart home, smart building, smart city, smart car, connected car, health care, digital education, smart retail, security and safety services. Disclosed is a method of operating a MEC system, comprising the step of instantiating a first application in the MEC system, which comprises the step of a first entity transmitting an application instantiation request to a second entity, wherein the application instantiation request comprises pre-emption information concerning the first application, such that the pre-emption information may be used to pre-empt the first application in the future, if required.

A communication system for transport means is provided, by which wireless communication is performed between the outside and the wireless communication environment in the transport means. Optical wireless communication is performed between a terminal device 2 and a light source device 3. A body ECU 4 connected to the light source device 3 by wired connection is further connected, by the wired connection, to a DCM 7 performing wireless communication with the outside. The light source device 3 and the body ECU 4 communicate with each other by power line communication. Accordingly, the light source device 3 sends and receives information between the outside via the body ECU 4 and the DCM 7. Thus, a vehicle communication system 1 that realizes wireless communication between the outside and the in-vehicle wireless communication environment (in-vehicle wireless communication environment configured including the terminal device 2 and the light source device 3) is built.

A software updating method for transmitting update data for software installed in vehicle controllers via wireless communication from an operation managing server to a plurality of vehicles on which the vehicle controllers are respectively mounted, for causing each of the vehicle controllers to update the software, in which the operation managing server is configured to group the plurality of vehicles into a plurality of groups, and vary timings of causing the vehicle controllers to update the software on a group-by-group basis.