A representation of a category of task offloaders is stored, in response to receiving a descriptor of the category, in a database of categories of offloaders which can be attached to servers of one or more classes. An indication of server configurations which include a task offloader of the category is provided via programmatic interfaces. A task is executed at a task offloader of a server with one of the server configurations.

A method for handling power faults in a primary electronic device is provided. The method includes setting a power-off duration to an initial value and powering on a hardware interface. In response to detecting a power fault at the hardware interface, the hardware interface is power-cycled by a plurality of power cycles having progressively increasing power-off durations until a limit is reached. A primary electronic device for carrying out the method is also provided. The primary electronic device includes a controller, a memory, and a hardware interface for coupling the telematics device to a secondary electronic device.

In a relay device, a transmitting/receiving unit of an ECU relay receives data. A first counter value is incremented if an amount of data received by the transmitting/receiving unit per unit time exceeds a first threshold. A second counter value is incremented if the amount of data received by the transmitting/receiving unit per unit time exceeds a second threshold. The second threshold is greater than the first threshold. A control unit of a bus relay repeatedly monitors the first counter value. If the first counter value is incremented, the control unit shortens a cycle with which the second counter value is monitored.

The invention relates to an IO-Link system comprising at least one IO-Link master (1), at least one IO-Link device (2) and at least one IO-Link-capable infrastructure component (30). The at least one IO-Link master (1) and the at least one IO-Link device (2) are connected via the at least one infrastructure component (30) and exchange data via a data channel (K1). The infrastructure component (30) has an apparatus (61, 62) for recording diagnostic data. A diagnostic channel (K2) is provided in the IO-Link system, via which diagnostic channel (K2) the diagnostic data can be sent and received between the at least one infrastructure component (30) and the at least one IO-Link master (1) separately from the data channel (K1).

An electronic device and an operating method thereof are provided. The electronic device includes a receiver, a memory, a processor configured to search the memory for fixed rate link (FRL) transmission bandwidth data for a source device in response to an electrical connection to the source device, perform FRL link training with a bandwidth value of the FRL transmission bandwidth data determined according to a FRL transmission bandwidth data search result, and process a content signal transmitted with a transmission bandwidth when the FRL link training is completed, and a reproducing device configured to perform a reproducing operation based on the processed content signal.

A data processing method includes: in the case where an operation state of an audio/video device in a target driving device is an out of operation state, generating an out of operation state notification message of the audio/video device; and sending the out of operation state notification message to a push client for stopping a data push between the push client and a push server using the out of operation state notification message.

Systems and techniques for automated transfer of peripheral device operations are described herein. In an example, a system may adapted so that, while a first device of a first type and a second device of the first type are simultaneously connected to a client device, the first device, rather than the second device, is used as an active device of the first type for at least one application, the first and second devices being peripheral devices. The system may be further adapted so that, while both the first and second devices remain connected to the client device, a switch from the first device to the second device by a user is determined, and, based on the switch from the first device to the second device, the second device, rather than the first device, is used as the active device of the first type for the at least one application.

A host performs benchmark I/O operations for a storage system by an application on the host formulating a performance test command, providing the performance test command to a channel subsystem layer of the host that actuates communication hardware that provides signals to the storage system, and performing a plurality of benchmark I/O operations at the channel subsystem layer in response to a single performance test command by actuating the communication hardware that provides signals to the storage system. The single performance test command may result in actuating the communication hardware to read and write data at a plurality of addresses of the storage system. The channel subsystem layer may perform the plurality of benchmark I/O operations without receiving any additional data or commands from any applications on the host. A dispatch program that runs on the channel subsystem layer may receive operational data and may actuate the communication hardware.

Disclosed are systems, methods, and non-transitory computer-readable media for determining attention based on user interactions. While content is being presented by a client device, an attention determination system causes presentation of a prompt object on a display of the client device. The prompt object starts from an entry point and traverses a path across the display. While the prompt object is traversing the path across the display, the attention determination system detects a user input at a point on the display that is within a threshold distance of a current position of the prompt object along the path. The attention determination system determines an attention level of a user of the client device based on the user input.

A serial communication link receiver-transmitter with autonomous transmission error detection is described, and a communication peripherals including the same. Transmit data at a transmitter and transmitted data output by the transmitter and received by the receiver are observed by an error detector configured to generate an error indication in response to difference between the transmit data and corresponding observed transmit data of a transmitted data frame. If a difference is detected a transmit error indicator is asserted.