Centera Viewer Software
Product: Centera Description: EMC Centera Viewer Resolution: EMC Centera Viewer is a tool used to monitor an EMC Centera. It provides status on all aspects of the system and its components. EMC Centera Viewer provides: • Usage information about the nodes. • The ability to shutdown the entire cluster. • The ability to set the eth2 linkspeed of the nodes with the external node role. • A set of diagnostic/monitoring tools.
• A consolidated log file for node online/offline events, hardware failures, replication activity, and ConnectEMC messages. • An historical chart for bandwidth consumption and read and write rates. • An historical chart for storage consumption. • An historical chart for the number of outstanding replications. • A CLI interface. Refer to EMC Centera Viewer Online Help for detailed information on using EMC Centera Viewer. To enable discovery and data collection for EMC Centera, install a supported version of Centera CLI software on the ViPR SRM Collector host.
SolutionPack for EMC Centera. Back to Top Technical. Identify the ViPR SRM Collector host where you will install the EMC Centera Viewer CLI software.
• Identify the ViPR SRM Collector host where you will install the EMC Centera Viewer CLI software. • Install a supported version of the EMC Centera Viewer CLI on the Collector host. The EMC Centera Viewer CLI is currently supported on Microsoft Windows Server 2008 R2. EMC ViPR SRM Support Matrix provides the specific version of Centera CLI software required and supported Collector host operating systems. • Identify the username (with monitor role enabled) and password. • Record this information.
You need it to install the SolutionPack. As you install the SolutionPack for EMC Centera, the installation program will prompt you to provide the location of the CenteraViewer.jar file. JCASScript The JCASScript utility, written in Java, provides a command-line interface to the EMC® Centera® Access API. JCASScript allows you to test or profile API behavior without having to write individual programs in Java or C. You can download OS Platform specific versions of this tool below: JCenteraVerify JCenteraVerify is a Java-based utility that tests the ability to make an API connection to an EMC® Centera® cluster, and allows C-Clip reads, writes, and deletes to be made on the cluster. You can use JCenteraVerify to do the following: • Test the connection to a cluster • Display cluster information • Display information about the cluster capabilities • Write test files to, retrieve from and delete test files from a cluster • Test the replication configuration (if set up) You can download OS Platform specific versions of this tool below: Centera Ping CenteraPing is a utility that allows you to quickly check the health status of an EMC® Centera® cluster.
This tool is an executable that runs from a command line and can be integrated easily into your system. To examine a specific cluster, you must obtain the IP address of a node with the access role belonging to that cluster. You can download OS Platform specific versions of this tool below: Centera Command Line Tools The command line tools have been removed, please use JCASScript. Centera Tools 4.1 the Centera Tools 4.1 for Windows the Centera Tools 4.1 for Solaris. If you think this website has helped you link to us in your blog or forum BinaryDB In 1992, Andersen et al.
Demonstrated the implantation of the first transcatheter aortic valve in a porcine model []. The prosthesis comprised a porcine aortic valve sutured on to a handmade stainless steel wire frame. The valve‐stent assembly was crimped onto a balloon catheter and delivered via the abdominal aortic route to replace the native aortic valve. Even though good hemodynamic results were achieved, the device was not applicable clinically due to the large delivery system (41Fr) that prohibited implantation in humans. Driver Stik Ps3 Untuk Pc on this page.
A decade later, Cribier et al. Performed the first percutaneous aortic valve implantation in a 57‐year‐old inoperable patient with symptomatic severe aortic stenosis []. The balloon‐expandable valve prosthesis was delivered with a 24Fr introducer sheath.
An antegrade transseptal route was adopted whereby the valve crossed the atrial septum though the right femoral vein and descended down into the mitral valve to the left ventricle before gaining access to the aortic annulus. This complex approach, albeit feasible, proved to be technically challenging and difficult to reproduce. Soon after, Paniagua et al. Vista Home Basic Trke Dil Paketi. Attempted the first retrograde transfemoral implantation of an aortic valve []. This technique was further enhanced and refined by Webb et al. In 2006 through modification of the delivery system, and it remained as the predominant access route for transcatheter aortic valve implantation (TAVI) as of today [].
Nevertheless, the femoral approach is not feasible in patients with narrow femoral arteries or severe peripheral arterial diseases. Consequently, the antegrade transapical route was developed []. During the transapical procedure, a mini thoracotomy is performed and the valve prosthesis is delivered through the left ventricular apex across the native aortic valve. These advancements significantly expanded the treatable patient population and set the scene for the current TAVI technology. Currently, the TAVI market is dominated by two distinct devices: the balloon‐expandable Edwards SAPIEN transcatheter heart valve (Edwards Lifesciences, Irvine, CA, USA) and the self‐expanding Medtronic CoreValve (Medtronic, Minneapolis, MN, USA). Both devices received CE Mark approval in Europe in 2007.