Patent application number | Description | Published |
20110055406 | Maintaining session states within virtual machine environments - Sessions states within virtual machine (VM) environments are maintained. Each VM environment hosts a guest operating system (OS) and one or more application programs running. The guest OS and the application computer programs of each VM environment constitute a session. A connection broker maintains a state machine as to states of the sessions and permits transitions among the states in response to messages, commands, and internal decisions. Different types of agents may send the messages, and the commands. The states of the sessions may include a pending state and a number of other states. The pending state is an interim state that indicates a session is being transitioned from one of the other states to another of the other states. These other states may include an offline state, an online-down state, an online-up state, a suspended state, an active state, an idle state, a disconnected state, and a failed state. | 03-03-2011 |
20120072765 | JOB MIGRATION IN RESPONSE TO LOSS OR DEGRADATION OF A SEMI-REDUNDANT COMPONENT - A computer program product and method of managing the workload in a computer system having one or more semi-redundant hardware components are provided. The method comprises detecting loss or degradation of the level of performance of one or more of the semi-redundant hardware components, identifying hardware components that are affected by the loss or degradation of the one or more semi-redundant components, migrating a critical job from an affected hardware component to an unaffected hardware component, and performing less-critical jobs on an affected hardware component. Loss or degradation of the semi-redundant component reduces the capacity of affected hardware components in the computer system without entirely disabling the computer system. Jobs identified as being critical are run on hardware components having the most capacity and reliability, while allowing less-critical jobs to make use of the remaining capacity of affected hardware components. Optionally, the semi-redundant hardware component may be selected from a memory module, CPU core, Ethernet port, power supply, fan, disk drive, and an input output port. | 03-22-2012 |
20120151248 | REDUCED POWER FAILOVER SYSTEM AND METHOD - Embodiments include a power-efficient failover system and method. In one embodiment, a primary server operating in a normal operating state is configured to dynamically backup device states or transaction logs. A redundant server coupled to the primary server in a failover cluster is operated at a reduced power state. The redundant server dynamically receives the backup from the primary server and is elevated to a normal operating state in response to a failure of the primary server. By enforcing a reduced power state of the redundant server, a failover system provides a desired combination of high power efficiency with low latency. | 06-14-2012 |
20120151360 | CONTENT PRESENTATION IN REMOTE MONITORING SESSIONS FOR INFORMATION TECHNOLOGY SYSTEMS - Content presentation in remote sessions by reducing processing and communication bandwidth requirements for the remote sessions in an information technology environment. Content presentation includes maintaining a session window on an electronic display screen of a remote administration console for remotely monitoring a corresponding server system via a communication link, and monitoring a display status of the session window on the display screen. Based on the display status of the session window, a quantity of refresh information for the session window is selectively transmitted from a management server to the remote administration console over the communication link for display in the session window. The refresh information includes status information for the remotely monitored server system. | 06-14-2012 |
20120166957 | CONTENT PRESENTATION IN MANAGEMENT SESSIONS FOR INFORMATION TECHNOLOGY SYSTEMS - A content presentation system maintains a window on an electronic display screen of an administration console for remotely managing servers via a communication link. The window includes plural tabbed user interface elements, each user interface element corresponding to a session providing status information for a corresponding server. Problem servers are dynamically detected. A user interface element tab is added to the window for each detected problem server. User interaction with a user interface element based on user input, is monitored. Based on the user interaction with a user interface element for a problem server, a panel is displayed on the display screen wherein the panel includes status information for a corresponding problem server. | 06-28-2012 |
20120166958 | CONTENT PRESENTATION IN MONITORING SESSIONS FOR INFORMATION TECHNOLOGY SYSTEMS - A computing resource management system maintains a management user interface (UI) on an electronic display screen of an administration console for managing computing resources via a communication link. The management UI comprises plural user interface elements, each user interface element including a physical topography for a managed computing resource and a graphical user interface element corresponding to a session providing information for said managed computing resource. User interaction with a graphical user interface element is monitored. Based on the user interaction, a content element is displayed on the display screen wherein the content element includes information for said corresponding managed computing resource. | 06-28-2012 |
20120166991 | COMPUTING RESOURCE MANAGEMENT IN INFORMATION TECHNOLOGY SYSTEMS - A computing resource management system maintains plural sessions for managing plural computing resources using an administration console. The system further maintains a management user interface on an electronic display screen of the administration console. The management user interface includes plural tabbed user interface elements, wherein each user interface element corresponds to a session for managing a computing resource via a communication link. The system dynamically refreshes the status of each computing resource in a corresponding user interface element tab in the management user interface. User interaction with a user interface element based on user input is monitored, and based on the user interaction with a user interface element, display a panel is displayed on the display for the user managing the corresponding computing resource. | 06-28-2012 |
20120272094 | REDUCED POWER FAILOVER - Embodiments include a power-efficient failover method. The method includes operating a primary server at a normal operating state in which program code is executed, and dynamically generating a backup of the results of the executed program code while in the normal operating state. The method further includes operating a redundant server at a reduced power state in which less power is consumed than in the normal operating state of the primary server. The workload of the primary server may be assumed according to the backup in response to a failure of the primary server. The power state of the redundant server is managed, including maintaining the redundant server in the reduced power state prior to detecting a failure of the primary server and increasing the power state of the redundant server and assuming the workload of the primary server in response to the failure of the primary server. | 10-25-2012 |
20120290874 | JOB MIGRATION IN RESPONSE TO LOSS OR DEGRADATION OF A SEMI-REDUNDANT COMPONENT - A method of managing the workload in a computer system having one or more semi-redundant hardware components is provided. The method comprises detecting loss or degradation of the level of performance of one or more of the semi-redundant hardware components, identifying hardware components affected by the loss or degradation, migrating a critical job from an affected hardware component to an unaffected hardware component, and performing less-critical jobs on an affected hardware component. Loss or degradation of the semi-redundant component reduces the capacity of affected hardware components in the computer system without entirely disabling the computer system. Jobs identified as critical run on hardware components having the most capacity and reliability, while less-critical jobs use the remaining capacity of affected hardware components. Examples of semi-redundant hardware components include a memory module, CPU core, Ethernet port, power supply, fan, disk drive, and an input output port. | 11-15-2012 |