An information handling system includes a host processing system, first and second data storage devices having respective first and second data storage capacities, and a license manager. The license manager implements a first license, receives a second license, and implements the second license without rebooting the information handling system. The first license defines a first configuration where the first data storage device is visible and the first data storage capacity is available to the host processing system, and the second data storage device is not visible and the second data storage capacity is not available to the host processing system. The second license defines a second configuration where both data storage devices are and both data storage capacities are available to the host processing system.

In the maintenance of rack system, a computing device may implement a plurality of smart plugs and a communication bus in a system. A smart plug may be plugged into a server node for communication between a management node and a designated server node. The communication bus may be coupled to the smart plugs for transmitting I2C packets. A server node may be associated with a corresponding smart plug that includes a unique address on the communication bus. The smart plug may be configured to receive a message via the communication bus. The smart plug is configured to determine whether the request is addressed to a unique address associated with the smart plug. Upon determining that the message is addressed to the unique address, the smart plug may reformat the request compatible with server node port using the local address. Reformatting request may depend on types of server node ports.

A signal transmission module with a USB Type-C socket connector, comprising a circuit substrate, a USB Type-C female electrical connector, a central processing unit, at least one multi-media output device and a power control unit, which are electrically connected to each other, wherein, the central processing unit computes and processes a first signal supplied by the USB Type-C socket connector and generates a second signal, which is transmitted to the multi-media output device, and the power control unit is to regulate an initial electric power, generate an regulated electric power, and transmit it to the circuit substrate, the USB Type-C female electrical connector, the central processing unit and the multi-media output device.

Embodiments of a method and apparatus are described for operating a mobile computing device in different modes using different operating systems. An apparatus may comprise, for example, a memory operative to store multiple operating systems, a processor operative to execute the multiple operating systems, an operating system management module operative to select a first operating system when the mobile computing device is in a first mode or a second operating system when the mobile computing device is in a second mode and the mobile computing device is coupled to one or more external devices. Other embodiments are described and claimed.

A method is provided for indicating to a user that a sink device is incorrectly connected to a High Definition Multimedia Interface (HDMI) In port. In accordance with the method, a proxy voltage is applied from an HDMI In port over an HDMI cable. The proxy voltage is sufficient to cause a hot plug event to occur. A hot plug event condition is detected at the HDMI In port from a device that is connected to the HDMI In port via the HDMI cable. Extended Display Identification Data (EDID) is read from the device at the HDMI In port over the HDMI cable. In response to receipt of the EDID, a determination is made that the device is a sink device and an error message is generated in response to the determination.

An apparatus comprises a positive data input/output terminal configured to be connected with a positive data line of a USB device, wherein the positive data input/output port is weakly pulled up to a first voltage potential through a pull-up resistor, a negative data input/output terminal configured to be connected with a negative data line of the USB device, wherein the negative data input/output terminal is connected to a second voltage potential, a window comparator having an input detecting a voltage across the two data input/output terminals and a wake-up signal generator connected to an output of the window comparator, wherein the wake-up signal generator is configured to generate a signal for adjusting a switching frequency of a power converter after the USB device is connected to the power converter.

A dynamic reconfiguration to include on-line addition, deletion, and replacement of individual modules of to support dynamic partitioning of a system, interconnect (link) reconfiguration, memory RAS to allow migration and mirroring without OS intervention, dynamic memory reinterleaving, CPU and socket migration, and support for global shared memory across partitions is described. To facilitate the on-line addition or deletion, the firmware is able to quiesce and de-quiesce the domain of interest so that many system resources, such as routing tables and address decoders, can be updated in what essentially appears to be an atomic operation to the software layer above the firmware.

In some embodiments, systems, devices, and methods are provided that allow a host device to communicate video information, network information, and USB information over USB via a USB host controller. The video information and the network information are encapsulated within USB and communicated by the USB host controller. In some embodiments, the USB information communicated by the USB host controller is further communicated over a non-USB extension medium by an upstream facing port device and one or more downstream facing port devices.

Techniques for supporting USB and video communication over an extension medium are provided. In some embodiments, an upstream facing port device (UFP device) is coupled to legacy connectors of a host device, and a downstream facing port device (DFP device) is coupled to a USB Type-C receptacle of the sink device that may provide both USB and DisplayPort information. The UFP device and DFP device communicate to properly configure the USB Type-C connection for use in the extension environment. In some embodiments, a source device is coupled to the UFP device via a USB Type-C connection, and legacy video and USB devices are coupled to the DFP device. The UFP device and DFP device again communicate to cause the source device to properly configure the USB Type-C connection for use in the extension environment.

The invention provides a hot plug method and device for a byte-addressable persistent memory, which includes hot-add and hot-remove; wherein the hot-add includes physical add and logical add, and the hot-remove includes logical remove and physical remove; the physical add is used for converting the memory from an uncharged raw media into a manageable block of an operating system; the logical add is used for converting the memory from the manageable block of the operating system into a memory device which capable of mapping a virtual address; the logical remove is used for converting the memory device which capable of mapping the virtual address into the manageable block of the operating system; and the physical remove is used for converting the memory from the manageable block of the operating system into the uncharged raw media. The method and device provided in the invention are suitable for scheduling and deployment the byte addressable persistent memory resource on any computer architecture and have a sound market outlook and application value.