StorNext Storage Manager Requirements

Note

StorNext SM only runs on SGI IRIX, Red Hat Linux, and Sun Solaris operating

systems.

 

 

 

 

 

System/Component

Requirement

 

 

Browser settings

Reload the StorNext GUI pages. Perform these steps to enable the page

 

 

reload.

 

 

• In Netscape, click: Edit > Preferences > Advanced > Cache.

 

 

Select Every Time and click OK.

 

 

• In Internet Explorer, click:

 

 

Tools > Internet Options > General > Settings > General.

 

 

Under Settings, select Every visit to the page and click OK.

 

 

 

Server Memory

 

A minimum of 512 MB of RAM is required.

 

 

Server Hard Disk

Depending on file system activity, SNMS binaries, documentation,

 

 

configuration, and log files require up to 30 GB of local hard disk space. An

 

 

additional 500 MB of hard disk space is required per 1M managed files.

 

 

Client Hard Disk

StorNext FS requires 200 MB of hard disk space for binaries,

 

 

documentation, configuration, and log files.

 

 

 

Operating System Level Requirements

These tables list the required operating system levels required to successfully operate SNMS and StorNext FS 2.4.1.

StorNext Management Suite Requirements

Server Platform

Operating System Levels

 

 

Solaris

Solaris 8, level 108528-09 or later

 

Solaris 9

 

 

IRIX

6.5.19f, 22f and 6.5.19m, 22m and 23m

 

 

Red Hat Linux

Uniprocessor or Multiprocessor, Red Hat Enterprise Linux Advanced

 

Server 3.0, Update 2, kernel levels 2.4.21-15.0.x.EL and

 

2.4.21-15.0.x.ELsmp.

 

To build a loadable kernel module, both the kernel and kernel source RPM

 

packages must be installed. To build and install the StorNext FS modules,

 

install all tools necessary to build a kernel module (including compilers) on

 

all Linux clients and server systems. To install these tools, obtain and install

 

a patch (available from Red Hat).

 

 

September 2004, ADIC

7

Page 7
Image 7
Quantum 2.4.1 manual Operating System Level Requirements, StorNext Storage Manager Requirements

2.4.1 specifications

Quantum 2.4.1 is an exciting update in the realm of quantum computing frameworks, designed to enhance the capabilities and accessibility of quantum programming for developers and researchers. This version builds on its predecessors by introducing several significant features and improvements that streamline the quantum development process.

One of the standout features of Quantum 2.4.1 is its enhanced simulation capabilities. The new simulation backend allows developers to run quantum algorithms on classical hardware with greater efficiency, making it easier to prototype and test quantum circuits. This feature is particularly beneficial for researchers who wish to experiment with quantum algorithms without requiring access to expensive quantum hardware.

Additionally, Quantum 2.4.1 introduces an upgraded library of quantum algorithms, which now includes implementations for various state-of-the-art algorithms such as Grover's Algorithm and the Quantum Fourier Transform. This extensive library not only provides ready-to-use components for developers but also serves as a valuable educational resource for those new to quantum computing.

The user interface has also seen significant improvements. Quantum 2.4.1 offers a more intuitive graphical user interface (GUI) that simplifies the process of building and testing quantum circuits. The drag-and-drop functionality allows users to visually assemble circuits, making quantum programming more accessible to beginners.

Moreover, Quantum 2.4.1’s support for hybrid algorithms has been expanded. Hybrid algorithms combine classical and quantum computing techniques to solve complex problems more efficiently. This version enhances integration with classical programming languages, making it easier for developers to build applications that leverage both classical and quantum resources.

Security is another area of focus in the 2.4.1 release. Enhanced protocols for quantum communication and error-correction techniques provide improved data integrity and security for quantum operations. This is crucial as the interest in quantum communication technology grows, driven by the need for secure communication channels in a digital landscape increasingly vulnerable to cyber threats.

Furthermore, the framework is built upon a modular architecture, allowing developers to easily extend and customize components. This flexibility encourages innovation and further experimentation within the quantum computing community.

In summary, Quantum 2.4.1 represents a significant leap forward in quantum programming, with its robust simulation capabilities, expanded algorithm library, improved user interface, hybrid computing support, enhanced security measures, and modular design. These characteristics make it a valuable tool for advancing research and application development in the burgeoning field of quantum computing. As the landscape evolves, Quantum 2.4.1 is well-positioned to support the next wave of breakthroughs in this transformative technology.