Method, device, and storage medium for processing a driver on a terminal device side are provided. A method includes obtaining connection information between a peripheral device corresponding to the driver and a terminal device; determining, according to the connection information, driver installation options capable of successfully installing the driver; and displaying the driver installation options capable of successfully installing the driver.

A system includes a real-time partitioning separation kernel installed on a multi-core processor. Guest operating systems are hosted with in hardware virtualized machines in the cores. Another hardware virtualized machine performs a real-time USB-CAN interface communicatively coupled to distributed electronic control units which acquire data and command actuators. A plurality of hardware virtualized machines support processes of various criticality. A secure shared memory serves as the communication means between processes performing different levels of functionality at suitable latency ranges. a policy to distinguish, allocate, and distribute clock, memory, and input/output resources to meet focused latency ranges to the Observation, Decision, and Execution processes. Remaining resources have diffuse latency ranges made available to the Observation, Decision, and Execution processes in an as available but guarded minimum and maximum buffet. A latency policy ensures that each process receives its minimum tranche before queueing for up to the maximum at the resource buffet.

A computer-implemented method includes monitoring, by a power monitor on a computer device, for a peripheral device connection. The peripheral device connection connecting a peripheral device to an input/output port of the computer device. The input/output port is configured to provide power from a power supply of the computer device to the peripheral device. In response to the monitoring for the peripheral device connection identifying the peripheral device connection, the method includes determining, by the power monitor, a device type and a negotiated power of the peripheral device as connected. The power monitor determines whether the negotiated power of the peripheral device as connected matches expected power information. In response to determining the negotiated power of the peripheral device does not match the expected power information, the power monitor takes action on the computer device.

Techniques for input session between devices based on an input trigger are described and may be implemented to enable a first device (e.g., a mobile device) to serve as an input device for a second device. Generally, the described implementations enable multiple different input triggers to be utilized to trigger an input session between devices, such as for enabling proximity-based input (e.g., stylus input, touch input, etc.) to a first device to be provided as input to a second device.

A mobile terminal, an on-the-go (OTG) control and configuration method, and a storage medium, wherein the method includes: obtaining an accumulated number of changes of differences in voltages of at least one of a positive data line and a negative data line in an OTG data cable at intervals; according to the accumulated number of changes of the differences in the voltages of at least one of the positive data line and the negative data line in the OTG cable, querying a lookup table pre-stored in the mobile terminal for a current value corresponding to the number of changes; and according to the queried current value, controlling the mobile terminal to set the current value as a current limit for an OTG peripheral device.

Techniques are provided for generating host connectivity plans with load balancing and resiliency. One method comprises obtaining a number of storage system target ports needed for a given host; identifying available target ports in the storage system and an input-output (IO) target component associated with each available target port; and calculating the host connectivity plan until the host connectivity plan includes the obtained number of target ports by: (i) selecting at least one IO target component not already in the host connectivity plan that satisfies a resiliency policy and/or a load balancing policy; (ii) selecting at least one target port associated with the selected at least one IO target component and (iii) adding the selected at least one target port to the host connectivity plan. The resiliency policy may require connectivity without a single point of failure. The load balancing policy may specify that the IO target components serve a substantially equal IO load.

A device is configured to operate in an industrial automation environment. The device includes a processing unit, a memory, an industrial communication interface to communicate with an external device via an industrial communication protocol, and a serial peripheral interface to communicate with a peripheral board during operation of the device. The device is configured to receive configuration data related to an industrial automation function of the device via the serial peripheral interface and store the received configuration data in the memory, when the serial peripheral interface is coupled to an external memory device. When the serial peripheral interface is coupled to the peripheral board, the device is configured to operate to perform the industrial automation function, in accordance with the received configuration data.

A recording system has a listener processor for automatically capturing events involving computer applications during a dialogue involving the user of the computer. The system generates a visual transcript of events on a timeline. It automatically detects start of a dialogue and proceeds to detect events and determines if they are configured as transcript events, before detecting end of the dialogue. The system may associate dialogue events with audio clips, using meta tags.

A method of transparently inserting a virtual storage layer into a Fibre channel based storage area network (SAN) while maintaining continuous I/O operations is provided. A device is inserted between a host entity and a first storage device. The device identifies a plurality of first paths between the host entity and the first storage device, and defines a plurality of second paths by defining, for each first path among the plurality of first paths, a corresponding second path between the host entity and a second storage device. The device determines, for each of the plurality of first paths, a respective first state. The device establishes, for each of the second paths among the plurality of second paths, a second state based on the first state of the corresponding first path. The device redirects, to the second storage device, communications directed from the host entity to the first storage device, via the plurality of second paths.

Systems and methods are disclosed to implement an endpoint command invocation system (“ECIS”). In some embodiments, ECIS can quickly dispatch a command to a large number of endpoint components, where the endpoint components are online. ECIS can receive an invocation of a command, which can include the command recipients. In some embodiments, ECIS determines that some of the command recipients are online, while some of the command recipients are offline. ECIS determines connections to the online command recipients based on a connection map, which is updated whenever an endpoint component opens a connection to ask for a command. ECIS can deliver the command to the online command recipients using the connections. ECIS can also deliver the command to dispatch queues corresponding to the offline command recipients, where the dispatch queues store the command as a pending command that can be delivered to their respective command recipients whenever they come online.