In terminal management method, a server sends operation information for performing a management operation on a target terminal to a gateway. The operation information carries a return format of an execution result of an operation command for performing the management operation on the target terminal. After receiving an operation command execution result sent by the target terminal, of the operation command and if there is an indication of a return format for the operation command execution result, the gateway processes the operation command execution result according to the indicated return format of the operation command execution result to obtain an operation command execution result conforming to the return format. The operation command execution result conforming to the return format is sent to the server.

A robot for data logging is described as a module of a portable data transfer system for use in physically transferring very big amounts of data in secure, fast and cheap way. The data logger logs and optionally analyzes sensory and operation data by statistically correlating and combining data, events, and control data from a variety of system modules, user actions, and sensors used to track system transit, handling, operation, and events. The data logger allows forensic analysis and comparison against a mission description to identify system location, transit path, mishandling, tampering, security breaches and problems arising from environmental conditions, design problems, etc. As a result, persons or events causing problems can be identified, retrained, and rectified, and system debugging can solve problems with error in hardware and software. Furthermore, decision and actions can be taken by the robot or by remote control to protect stored data from unauthorized access from third parties, such actions can include destruction of operating keys repository, electrical destruction of storage modules, system shutdown etc.

A method for visually guided storage array installation is disclosed. The method includes receiving an installation plan for a storage array and determining a component of the storage array that is specified in the installation plan. One or more visual indicators that are associated with the component of the storage array are displayed to indicate a status corresponding to executing a portion of the installation plan.

Example methods and systems for logical network visualization. One example may comprise a computer system obtaining and processing topology information identifying a set of logical network elements. To visualize the set of logical network elements, the computer system may configure logical network topology graph is configured to include a multi-level group node that is formed using (a) a parent group node and (b) a child group node. The parent group node may be configured in a folded state to visualize multiple first elements and associated with parent group node information. The child group node may be configured in a folded state to visualize multiple second elements and associated with child group node information. The computer system may interact with a user device to cause display of the parent group node and the child group node along with the respective parent group node information and child group node information.

Systems, methods, and computer-readable storage devices for reducing the amount of management ports (and associated cabling) for a top-of-rack server environment. Whereas other server management configurations have cabling connecting each node in multiple multi-node chassis in a server rack to a top-of-rack, systems configured as described herein designate a single node as a point of communication for the multi-node chassis. The designated node forwards communications for all nodes in the chassis to a chassis management controller, which acts as a distribution point for all communications within the multi-node chassis, with the benefit of only a single connection being required between the multi-node chassis and the top of rack switch.

Systems and methods include receiving visual representations of components in network elements in a network; responsive to training a machine learning model to evaluate the visual representations, analyzing the visual representations using the machine learning model to determine a status of the components; and providing the status of the components to an inventory application for any of updating the inventory application and reconciling existing data in the inventory application.

Presented herein is an exemplified system and method that facilitate network-aware orchestration of similar sets of virtualized multicast-traffic receivers and/or sources (e.g., Virtual Machines) under a common network fabric element (e.g., same leaf switch and/or spine switch in a data center network fabric), e.g., to reduce network switch work load and/or number of network fabric elements involved with transmission of multicast traffic. The orchestration of scattered- and like-sets of multicast-traffic receivers and/or sources under a common network fabric element (e.g., a single and same leaf switch and/or spine switch) facilitates improvements of the operation of orchestration management technologies and virtualization overlay technologies by, e.g., improving network efficiency for multicast packet switching, reducing control plane traffic (e.g., IGMP queries), and reducing delay- and packet-transfer errors.

A smart hybrid acceleration method includes receiving a handshake request from a client terminal, and determining whether the handshake request contains a self-defined resource extension field. If not, a target domain name with which the client terminal is to connect is acquired from the handshake request, and whether to use a hardware acceleration or a software acceleration is determined according to a level of the target domain name. If so, a resource level of a resource accessed by the client terminal is determined according to content in the self-defined resource extension field, and whether to use the hardware acceleration or the software acceleration is determined according to the resource level.

Systems and methods for negotiating control of a shared audio or visual resource are disclosed. A request for control of a shared audio or visual resource is received at an arbiter. The arbiter maintains existing state information for ownership of the shared audio or visual resource and ownership transition conditions of the shared audio or visual resource. The request is received from one of a process executing on an embedded system and a process executing on a mobile computing device. New state information regarding ownership of the shared audio or visual resource is determined based at least in part on the request for control and the ownership transition conditions. The new state information indicates which of the processes controls output of the shared audio or visual resource.

A control node of a multi-tenant stream management service receives a request to initialize a data stream to be comprised of a plurality of data records. The control node determines, based on a partitioning policy, parameters to be used to configure subsystems for ingestion, storage and retrieval of the records. The control node identifies resources to be used for a node of retrieval subsystem The retrieval node is configured to implement programmatic record retrieval interfaces, including respective interfaces to implement non-sequential and sequential access patterns. The control node configures the retrieval node using the selected resources.