A method for operating a transfer device for a differential bus system, including a first bus connection and a second bus connection for connecting to a transfer medium of the differential bus system. The method includes: ascertaining a first variable that characterizes a voltage associated with a first bus line of the bus system, ascertaining a second variable that characterizes a voltage associated with a second bus line of the bus system, ascertaining a third variable that characterizes a sum of the first variable and the second variable for a first bus state, ascertaining a fourth variable that characterizes a sum of the first variable and the second variable for a second bus state, the second bus state being different from the first bus state.

Provided is a system, comprising: a computing device, comprising: computational storage or computational memory, the computational storage or computational memory having a processor; a downstream data processor that is different from the processor of the computational storage or computational memory; and a bus connecting the processor to the computational storage or computational memory, wherein the computing device comprises a tangible, non-transitory, machine readable medium storing instructions that, when executed, effectuate operations comprising: receiving an input from a remote device conveyed to the computing device; determining, based on the input, how to configure a transformation of data stored in the computational storage or computational memory; and applying, with the processor, the configured transformation to the data stored in the computational storage or computational memory; and outputting the transformed data to the downstream data processor.

Provided is a system, comprising: a computing device, comprising: computational storage or computational memory, the computational storage or computational memory having a processor; a downstream data processor that is different from the processor of the computational storage or computational memory; and a bus connecting the processor to the computational storage or computational memory, wherein the computing device comprises a tangible, non-transitory, machine readable medium storing instructions that, when executed, effectuate operations comprising: receiving an input from a remote device conveyed to the computing device; determining, based on the input, how to configure a transformation of data stored in the computational storage or computational memory; and applying, with the processor, the configured transformation to the data stored in the computational storage or computational memory; and outputting the transformed data to the downstream data processor.

Managing application migration is provided. An API server on a controller node is invoked to update a configuration map of a reverse proxy on a worker node for the reverse proxy to route user service requests corresponding to unmigrated applications of a set of applications from a first computing platform to a second computing platform to maintain liveness of the unmigrated applications during migration. The API server is invoked to build an image for an application of the set of applications based on source code of the application obtained from the second computing platform. The API server is invoked to generate a pod on the worker node to perform a workload of the application using the image. The API server is invoked to update a service on the worker node to select the pod on the worker node performing the workload of the application.

A method used in an on-board network system, having electronic controllers that exchange messages and a fraud-detecting electronic controller. The method includes receiving an inquiry for a vehicle status indicating whether a vehicle in which the fraud-detecting electronic controller is installed is running from an external device, transmitting the vehicle status to the external device, and determining whether a message transmitted conforms to fraud detection rules. The method also includes receiving from the external device the delivery data, including updated fraud detection rules and network type information indicating a network type that the updated fraud detection rules are to be applied The method further includes determining whether the vehicle is running, and whether the network type information indicates a drive network that is connected to an electronic controller related to travel of the vehicle. When the network type information does not indicate the drive network, updating the fraud detection rules.

A system includes a plurality of systems-on-a-chip (SoCs), connected by a network. The plurality of SoCs and the network are configured to operate as a single logical computing system. The plurality of SoCs may be configured to exchange local power information indicative of network activity occurring on their respective portions of the network. A given one of the plurality of SoCs may be configured to determine that a local condition for placing the respective portion of the network corresponding to the given SoC into a reduced power mode has been satisfied. The given SoC may be further configured to place the respective portion of the network into the reduced power mode in response to determining that a global condition for the reduced power mode is satisfied. The global condition may be assessed based upon current local power information for remaining ones of the plurality of SoCs.

This application is directed to a stacked semiconductor device assembly including a plurality of identical stacked integrated circuit (IC) devices. Each IC device further includes a master interface, a channel master circuit, a slave interface, a channel slave circuit, a memory core, and a modal pad configured to receive a selection signal for the IC device to communicate data using one of its channel master circuit or its channel slave circuit. In some implementations, the IC devices include a first IC device and one or more second IC devices. In accordance with the selection signal, the first IC device is configured to communicate read/write data via the channel master circuit of the first IC device, and each of the one or more second IC devices is configured to communicate respective read/write data via the channel slave circuit of the respective second IC device.

A message-level policy implemented with for a message routing system may be used to mediate between a variety of message sources and message targets that receive and use messages. The message-level policy may allow fine grained message-by-message policy assessment that a message routing system policy may be able to provide. The message-level policy may furthermore interact with the message routing system policy to provide mechanisms to avoid accidental leakage of protected messages or spill-over to protected regions.

A message-level policy implemented with for a message routing system may be used to mediate between a variety of message sources and message targets that receive and use messages. The message-level policy may allow fine grained message-by-message policy assessment that a message routing system policy may be able to provide. The message-level policy may furthermore interact with the message routing system policy to provide mechanisms to avoid accidental leakage of protected messages or spill-over to protected regions.

A set of discrete input/output (I/O) channels for one or more field devices may be grouped, organized, and connected to a field module device, which may connect to an electronic marshalling apparatus in a marshalling cabinet via an I/O channel. The field module acts as an intermediary, decoding messages received via the I/O channel to identify commands for discrete output (DO) channels that are then forwarded appropriately. The field module may also receive variable values carried by signals on discrete input (DI) channels and encode the values to a message that may be transmitted to the marshalling apparatus and controller, thus making the variable values on the DI channels available to the controller. The field module may store a profile including information that facilitates various smart commissioning techniques, including autosensing of tags, automatic tag binding, and automatic configuration of a control element corresponding to the field module.