July 17, 2012
MOUNTAIN VIEW, Calif., July 17 — Violin Memory, Inc., provider of one of the world's fastest and most scalable flash Memory Arrays, served as the storage platform required by Cisco to set the 2-socket server world record in cloud computing performance as measured by the VMware VMmark 2.1 benchmark. A record of this magnitude validates the sustained performance achieved by Violin Memory Arrays and their ability to provide the infrastructure necessary to support virtualized and cloud environments.
VMmark 2.1: The Industry's Virtualization Platform Benchmark
VMmark 2.1 is the industry's first multi-server datacenter virtualization benchmark, which assesses the performance of a group of virtualized real world applications. It includes a variety of common platform-level workloads such as live migration of virtual machines, cloning and deploying of virtual machines, and automatic virtual machine load balancing across the datacenter. To achieve the best results, end-to-end performance from server to storage is needed.
"Cloud computing is a key driver for the acceleration of solid-state adoption in data centers," said Joseph Unsworth, research vice president at Gartner. "Companies that can deliver high-performance and reliable solutions at aggressive price-points are best positioned to exploit this opportunity."
Violin Storage at the Speed of Memory
The VMmark 2.1 results emphasize that the Violin 6000 Series flash Memory Arrays have the best combined IOPS and latency to virtualize and consolidate demanding business critical applications and desktops.
"Cisco UCS has established the best VMmark scores for 2-socket servers, and storage performance was a key requirement," said Don Basile, CEO of Violin Memory. "With industry leading random IO performance, economics and sustained low latency, the Violin 6000 was the obvious storage infrastructure choice for this effort. Offering the best IOPS per terabyte, Violin enables storage consolidation just like Cisco UCS drives server consolidation."
The Violin 6000 Series flash Memory Arrays bring storage performance in balance with high speed compute and networking, offering a significant opportunity for infrastructure consolidation. A single system fits in a 3U of rack space and can deliver one million IOPS with 4 GB/sec of bandwidth -- enough performance to replace multiple racks of traditional disk arrays for savings of both CAPEX and OPEX. The arrays attach to the network for shared primary storage. Multiple arrays can be clustered together to achieve petabytes (PB) of capacity and high aggregate bandwidth.
About Violin Memory, Inc.
Violin Memory is pioneering the future of Flash memory in the enterprise data center with Memory Arrays that accelerate business critical applications and enable enterprises to virtualize and optimize their IT infrastructures. Specifically designed for sustained performance with high reliability, Violin's Memory Arrays scale to hundreds of terabytes and millions of IOPS with low, spike-free latency. Founded in 2005, Violin Memory is headquartered in Mountain View, California. For more information about Violin Memory products, visit www.vmem.com.
Source: Violin Memory, Inc.
10/30/2013 | Cray, DDN, Mellanox, NetApp, ScaleMP, Supermicro, Xyratex | Creating data is easy… the challenge is getting it to the right place to make use of it. This paper discusses fresh solutions that can directly increase I/O efficiency, and the applications of these solutions to current, and new technology infrastructures.
10/01/2013 | IBM | A new trend is developing in the HPC space that is also affecting enterprise computing productivity with the arrival of “ultra-dense” hyper-scale servers.
Ken Claffey, SVP and General Manager at Xyratex, presents ClusterStor at the Vendor Showdown at ISC13 in Leipzig, Germany.
Join HPCwire Editor Nicole Hemsoth and Dr. David Bader from Georgia Tech as they take center stage on opening night at Atlanta's first Big Data Kick Off Week, filmed in front of a live audience. Nicole and David look at the evolution of HPC, today's big data challenges, discuss real world solutions, and reveal their predictions. Exactly what does the future holds for HPC?