Apple Xsan Volume license D3370ZM/A 사용자 설명서
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D3370ZM/A
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Technology Overview
Xsan
Xsan
Xsan for High-Performance Computing
Recent gains in processing power have enabled scientists and researchers to build
world-class computational clusters using inexpensive servers, such as Apple’s Xserve
G5 running Mac OS X Server, for a fraction of the cost of comparable supercomputer
solutions. Also known as high-performance computing, these techniques are used
for scientific analysis, in render farms, and for other specialized, processor-intensive
applications.
world-class computational clusters using inexpensive servers, such as Apple’s Xserve
G5 running Mac OS X Server, for a fraction of the cost of comparable supercomputer
solutions. Also known as high-performance computing, these techniques are used
for scientific analysis, in render farms, and for other specialized, processor-intensive
applications.
A computational cluster runs an application against a single large data set. Typically
data sets are moved into the cluster and results are gathered from the cluster using
common network file system techniques. This can lead to data management challenges,
as it’s imperative that each computer uses the correct data set. In addition, in the case
of very large data sets or very large clusters, the network file server can become a
bottleneck. As in data center environments, Xsan can remove these limitations, provid-
ing dramatically faster and more scalable data sharing across small and large clusters.
data sets are moved into the cluster and results are gathered from the cluster using
common network file system techniques. This can lead to data management challenges,
as it’s imperative that each computer uses the correct data set. In addition, in the case
of very large data sets or very large clusters, the network file server can become a
bottleneck. As in data center environments, Xsan can remove these limitations, provid-
ing dramatically faster and more scalable data sharing across small and large clusters.
Deploying small clusters over Fibre Channel
With a small cluster, comprising fewer than 60 nodes, every node can share access to
an Xsan volume using a high-speed Fibre Channel network. Each node can read from
the same data set and each node can return its results to the same folder in the file
system, eliminating data replication and simplifying data management.
With a small cluster, comprising fewer than 60 nodes, every node can share access to
an Xsan volume using a high-speed Fibre Channel network. Each node can read from
the same data set and each node can return its results to the same folder in the file
system, eliminating data replication and simplifying data management.
Sharing data over a SAN also provides significant performance improvements over
traditional file servers. Multiple systems have simultaneous access to exactly the same
data. Data is never transferred over the LAN, preventing Ethernet bottlenecks and
avoiding idle computing cycles while nodes wait for data to process.
traditional file servers. Multiple systems have simultaneous access to exactly the same
data. Data is never transferred over the LAN, preventing Ethernet bottlenecks and
avoiding idle computing cycles while nodes wait for data to process.
Deploying larger clusters with Fibre Channel and Ethernet
With a larger cluster comprising hundreds of nodes, the configuration shifts to a
hierarchical structure. Head nodes are used to manage a group of cluster nodes. For
example, a 200-node cluster may have 10 head nodes each managing 20 client nodes.
The head nodes, all running Xsan, connect directly to the SAN using a Fibre Channel
network and share the SAN volume with their client nodes using a network file system
protocol, such as NFS over Gigabit Ethernet. Because the file sharing on each network
segment is limited to 20 nodes, network performance across the cluster is improved
and data management is simplified.
With a larger cluster comprising hundreds of nodes, the configuration shifts to a
hierarchical structure. Head nodes are used to manage a group of cluster nodes. For
example, a 200-node cluster may have 10 head nodes each managing 20 client nodes.
The head nodes, all running Xsan, connect directly to the SAN using a Fibre Channel
network and share the SAN volume with their client nodes using a network file system
protocol, such as NFS over Gigabit Ethernet. Because the file sharing on each network
segment is limited to 20 nodes, network performance across the cluster is improved
and data management is simplified.
This method for accessing and distributing data is faster and uses less network band-
width across the cluster than do typical NAS solutions. At the end of the run, nodes
return the processed data to the head nodes, which in turn write directly to the
shared SAN volume.
width across the cluster than do typical NAS solutions. At the end of the run, nodes
return the processed data to the head nodes, which in turn write directly to the
shared SAN volume.
Xserve G5 cluster node
Using affordable Xserve G5 cluster nodes,
scientists and engineers have built power-
ful computational clusters, including some
of the fastest supercomputers in the world.
Using affordable Xserve G5 cluster nodes,
scientists and engineers have built power-
ful computational clusters, including some
of the fastest supercomputers in the world.
Ethernet
Fibre Channel switch
SAN volume
Head nodes
Cluster nodes
Metadata controller
Large Computational Cluster