A computing system is provided. The computing system includes a server having one or more processors configured to receive from a user computing device run-time telemetry data, the run-time telemetry data being recorded during execution of a target program of a plurality of programs by the user computing device and being indicative of communication between the user computing device and a user input device. The one or more processors are further configured to determine a performance metric based on the run-time telemetry data, determine an updated driver parameter for the target program based on the determined performance metric, send the updated driver parameter to the user computing device, and apply the updated driver parameter for use during a subsequent execution of the target program.

A method for managing a resource system includes obtaining, by a hardware resource manager, a firmware update lockdown request for a lockdown for a firmware device of the resource system, in response to the firmware update lockdown request: identifying a firmware protocol corresponding to the firmware device, generating a firmware lockdown command corresponding to the firmware device based on the firmware protocol, and initiating updating of a lockdown policy based on the firmware lockdown command.

An Information Handling System (IHS) includes multiple hardware devices, and a baseboard Management Controller (BMC) in communication with the plurality of hardware devices. The BMC includes executable instructions for monitoring a parameter of one or more of the hardware devices of the IHS when a custom BMC firmware stack is executed on the BMC. The instructions that monitor the parameter are separate and distinct from the instructions of the custom BMC firmware stack. When the parameter exceeds a specified threshold, the instructions are further executed to control the BMC to perform one or more operations to remediate the excessive parameter.

A computing device saves storage space by foregoing writing the payloads for batches of feature files to local storage and then automatically downloading payloads for individual batches of feature files as associated features are called upon. In various embodiments, an operating system (OS) that includes both frequently used and infrequently used features is executing on the computing device. Batches of feature files for the frequently used features of the OS may be hydrated on the computing device whereas batches of feature files for the infrequently used features of the OS may be left dehydrated on the computing device. When an infrequently used feature is requested, the computing device automatically downloads a corresponding batch of feature files. Then, the computing device may fulfill the request by implementing the infrequently used feature. Thus, predetermined batches of feature files remain immediately accessible at the computing device without consuming storage space unless called upon.

An object of the present disclosure is to suppress an increase in the time required for setting a peripheral device including driver installation. An embodiment of the present invention is a method including: a step for causing a display unit to display information of each of detected peripheral devices as a search result from a searching step; a step for causing a storage unit to store information of a peripheral device selected by a user from among the detected peripheral devices; an installation step for installing a driver that is compatible with the selected peripheral device; and a determination step for determining a port that is capable of communicating with the selected peripheral device, based on the information stored in the storage unit, wherein an installation process by the installation step and a communication-capable port determination process by the determination step are executed concurrently.

A method for controlling functional elements and a device for use in bioprocess engineering or medical technology is disclosed. The method includes providing a first functional element, which has a memory, in which items of element information having specifications about the type and the function of the functional element are stored, and providing a second functional element. The method includes connecting the first and the second functional element to a control unit, reading the items of element information out of the first functional element and carrying out a check of the read-out items of element information from the second functional element or using items of information which are stored in the control unit. The first functional element is controlled by the control unit in dependence on the check or in dependence on the items of element information.

An attractive service is provided by freely mutually connecting existing IoT devices in a silo state for each private cloud via the Internet. An IoT connection system includes an IoT hub that is realized over a cloud and a local IoT router that is connected to the IoT hub. The IoT hub includes at least one of a first driver configured to connect the IoT hub to a private cloud to which a first device is able to be connected and a second driver configured to connect a second device to the IoT hub. The IoT router includes a third driver configured to connect a third device to the IoT router. The IoT router is an information processing terminal that is able to communicate with a predetermined base station. The third device is connected to the IoT hub using a tethering function of the IoT router in a specific situation.

The present invention is directed to a computing device capable of accepting, identifying, and processing signals from a plurality of different sensor types without sensor-specific code. The present invention features a small electronic device consisting of one or more sensors with a computing device that can be reconfigured for different purposes at any time, without the need for changing programming code.

A bus repeater includes first and second bus ports, a first termination resistor network coupled to the first bus port, a second termination resistor network coupled to the second bus port, and a power state change detection circuit coupled to the second bus port. The power state change detection circuit is configured to detect a power state change initiated by a device coupled to the first bus port. The detection of the power state change includes a determination that a voltage on the second bus port exceeds a threshold. Responsive to detection of the power state change, the power state change detection circuit is configured cause a change in a configuration of at least one of the first or second termination resistor networks.

A peripheral device includes one or more processors and a memory storing program instructions that when executed implement virtualization offloading components of a virtualized computing service, including a storage manager. The offloading components establish network connectivity with a control plane of the service. Based on detecting that a hardware server, in a separate enclosure, has been linked to the peripheral device, the hardware server is presented as a virtualization host of the service. The offloading components initiate compute instance configuration operations at the server in response to commands issued to the control plane, including at least one configuration operation initiated by the storage manager to enable access to a logical storage device from a compute instance.