1. NAS / SAN NAS – Network Attached Storage (Filer)
SAN – Storage Area Network
What differentiates the two?

2. NAS What is a NAS? What components make up a NAS?
Network attached storage (NAS) is an adding of disk drives and PC servers to existing networks to increase storage space.
NAS appliances expand storage capacity independently of the PC server and provide a simple, cost-effective solution to adding network storage.
What components make up a NAS?
Appliance, disk storage, network connection

3. NAS What is a NAS appliance?
NAS appliances were developed as an alternative to the general-purpose server solely for file storage.
They are single-purpose appliances dedicated to serving files that provide a flexible and inexpensive alternative for adding storage to the workgroup.

4. NAS
NAS appliance hardware has been streamlined by eliminating unnecessary components, which results in significant cost savings over general-purpose servers.
For example, unlike a PC server, a NAS appliance has no need for a keyboard, mouse, monitor, or I/O ports.

5. NAS
NAS appliances run a highly efficient operating system, typically with built-in support for multiple networking protocols, which has been optimized for serving files on the network.
Unlike traditional servers whose operating systems charge a "per seat" licensing fee for each user connected to the server, there are no licensing fees with NAS appliances.

6. NAS How does it communicate?
An appliance communicates using Network File System (NFS) for UNIX/Linux environments, Common Internet File System (CIFS) for Microsoft Windows environments, FTP, http, and other networking protocols.

7. NAS Applications for NAS File sharing and online storage. Backups
Duplication of images for frequently used software configurations for distribution.
Increase online storage at particular locations for remote offices.

8. NAS Required/Desirable Features Compatibility with Existing Networks
Easy Installation
Intuitive Web Administration
Network Security
Cross-Platform File Sharing
(Cont.)

9. NAS
Legacy cross-platform environment
                                                                                                                                                                     

10. NAS
With NAS
                                                                                                                                   

11. NAS Required/Desirable Features (Cont)
Compatibility with Established Backup Policy
Improved Performance under Load
High Reliability
Portable Storage

12. NAS
Benefits
With a NAS appliance, users anywhere on the network—from corporate headquarters to remote offices—are assured of timely, reliable access to their data.
NAS provides IT managers have a cost-effective file server that is easily integrated into an existing workgroup.

13. NAS / SAN Similarities: Both provide optimal consolidation.
centralized data storage.
efficient file access.

14. NAS / SAN Similarities: Both allow you to:
share storage among a number of hosts
support multiple different operating systems at the same time
separate storage from the application server.

15. NAS / SAN Similarities: Both can provide high data availability
ensure integrity with redundant components and redundant array of independent disks (RAID).

16. NAS / SAN
Differences:
NAS and SAN represent two different storage technologies and they attach to your network in very different places.

17. NAS
NAS is a defined product that sits between your application server and your file system

18. SAN
SAN is a defined architecture that sits between a file system and an underlying physical storage It is its own network, connecting all storage and all servers.

19. NAS NAS is network-centric.
NAS provides security and performs all file and storage services through standard network protocols, using TCP/IP for data transfer, Ethernet and Gigabit Ethernet for media access, and CIFS, http, and NFS for remote file service.

20. SAN
A SAN is data-centric - a network dedicated to storage of data. Unlike NAS, a SAN is separate from the traditional LAN or messaging network. Therefore, a SAN is able to avoid standard network traffic, which often inhibits performance.
SANs employ gateways, switches, and routers to facilitate data movement between heterogeneous server and storage environments.

21. NAS / SAN NAS is file oriented SAN is SCSI block oriented
NAS is simple to install (Plug and Play)
SAN is complex

22. SAN
What is a SAN? A SAN consists of a dedicated network that interconnects servers and their applications to storage resources with the use a switch or hub. (Hubs seldom seen any more.)
Storage resources usually consists of disks and tapes.
The dedicated network is usually fibre channel or iSCSI

23. SAN
An adapter card on the server is connected by fiber optic or copper cabling to a SAN switch.
Disk arrays and tape devices are also connected to the switch, which brings all servers and storage devices into a peer-to-peer network.

24. SAN

25. NAS

26. NAS

27. NAS

28. NAS

29. SAN

30. SAN

31. SAN
How can SAN accommodate a mixed computing environment (UNIX, WINDOWS, NOVELL)?
Through a technique called zoning.

32. SAN

33. SAN
A method of subdividing a storage area network into disjoint zones, or subsets of nodes on the network. Storage area network nodes outside a zone are invisible to nodes within the zone. Moreover, with switched SANs, traffic within each zone may be physically isolated from traffic outside the zone.

34. SAN What type of network access does SAN employ? Fibre channel iSCSI
Infiniband
CIM (Common Information Model)
Bluefin (based on CIM)

35. Fibre Channel What is fibre channel?
Fibre channel is a high performance serial link supporting its own, as well as higher level protocols such as the FDDI, SCSI, HIPPI and IPI
It is neither a fiber or a channel.
Fibre Channel is the general name of an integrated set of standards developed by the American National Standards Institute (ANSI).

36. Fibre Channel What is a channel?
There are two basic types of data communication between processors and between processors and peripherials: channels and networks.
A channel provides a direct or switched point-to-point connection between the communicating devices.
A channel is typically hardware-intensive and transports data at the high speed with low overhead. .

37. Fibre Channel
A network is an aggregation of distributed nodes (like workstations, file servers or peripherials) with it's own protocol that supports interaction among these nodes.

38. Fibre Channel
A network is an aggregation of distributed nodes (like workstations, file servers or peripherials) with it's own protocol that supports interaction among these nodes.
Networks can handle a more extensive range of tasks than channels as they operate in an environment of unanticipated connections, while channels operate amongst only a few devices with predefined addresses.

39. Fibre Channel
Fibre Channel attempts to combine the best of these two methods of communication into a new I/O interface that meets the needs of channel users and also network users.
It allows for an active intelligent interconnection scheme, called a Fabric, to connect devices.

40. Fibre Channel
In Fibre Channel terms the switch connecting the devices is called Fabric.
The link is the two unidirectional fibres transmitting to opposite directions with their associated transmitter and receiver.
Each fibre is attached to a transmitter of a port at one end and a receiver of another port at the other end.

41. Fibre Channel
When a Fabric is present in the configuration, the fibre may attach to a node port (N_Port) and to a port of the Fabric (F_Port).

42. Fibre Channel
FC is structured as a set of hierarchical functions.

43. Fibre Channel
The lowest level (FC-0) defines the physical link in the system, including the fibre, connectors, optical and electrical parameters for a variety of data rates.
(133 Mbit/s, 266 Mbit/s, 530 Mbit/s, and 1 Gbits/s) and on three types of both electrical and optical media.
The system bit error rate (BER) at the supported media and speeds is less than 10exp-12 [1].

44. Fibre Channel
FC-1 defines the transmission protocol including serial encoding and decoding rules, special characters and error control. The information transmitted over a fibre is encoded 8 bits at a time into a 10 bit Transmission Character.

45. Fibre Channel
The Signaling Protocol (FC-2) level serves as the transport mechanism of Fibre Channel. The framing rules of the data to be transferred between ports, the different mechanisms for controlling the three service classes and the means of managing the sequence of a data transfer are defined by FC-2. To aid in the transport of data across the link, the following building blocks are defined by the standard:
Ordered Set
Frame
Sequence
Exchange
Protocol

46. Fibre Channel
The Frame Header is used to control link applications, control device protocol transfers, and detect missing or out of order Frames. An optional header may contain further link control information.

47. Fibre Channel
A maximum 2112 byte long field (payload) contains the information to be transferred from a source N_Port to a destination N_Port.

48. Fibre Channel
To ensure efficient transmission of different types of traffic, FC defines three classes of service.
Class 1 is a service which provides dedicated connections, in effect providing the equivalent of a dedicated physical connection. Once established, a Class 1 connection is retained and guaranteed by the Fabric. This service guarantees the maximum bandwidth between two N_Ports, so this is the best for sustained, high throughput transactions. In Class 1, Frames are delivered to the destination Port in the same order as they are transmitted. Figure 5 shows the flow control management of a Class 1 connection.

49. Fibre Channel

50. Fibre Channel
Class 2 is a Frame-switched, connectionless service that allows bandwidth to be shared by multiplexing Frames from multiple sources onto the same channel or channels. The Fabric may not guarantee the order of the delivery and Frames may be delivered out of order.
If delivery cannot be made due to congestion, a Busy frame is returned and the sender tries again.

51. Fibre Channel

52. Fibre Channel
Class 3 service is identical to Class 2, except that the Frame delivery is not confirmed. (Flow control is managed only on buffer level) This type of transfer, known as datagram provides the quickest transmission by not sending confirmation.

53. Fibre Channel

54. Fibre Channel
The FC-3 level of the FC standard is intended to provide the common services required for advanced features such as:
Striping -To multiply bandwidth using multiple N_ports in parallel to transmit a single information unit across multiple links.
Hunt groups - The ability for more than one Port to respond to the same alias address. This improves efficiency by decreasing the chance of reaching a busy N_Port.
Multicast - Multicast delivers a single transmission to multiple destination ports. This includes sending to all N_Ports on a Fabric (broadcast) or to only a subset of the N_Ports on a Fabric.

55. Fibre Channel
FC-4, the highest level in the FC structure defines the application interfaces that can execute over Fibre Channel. It specifies the mapping rules of upper layer protocols using the FC levels below

56. Three IP SAN Transports
The three IP storage networking transports are significantly different, but they all provide a common function: transporting block-level storage over an IP network. All three transports enable end users to
Leverage existing storage devices (SCSI and Fibre Channel) and networking infrastructures (Gigabit Ethernet);
Maximize storage resources to be available to more applications;
Extend the geographical limitations of DAS and SAN access;
Use existing storage applications (backup, disaster recovery, and mirroring) without modification; and
Manage IP-based storage networks with existing tools and IT expertise.

57. iSCSI
The Internet Small Computer Systems Interface (iSCSI) protocol defines the rules and processes to transmit and receive block storage applications over TCP/IP networks by encapsulating SCSI commands into TCP and transporting them over the network via IP.

58. FCIP
Fibre Channel over TCP/IP (FCIP) provides a mechanism to "tunnel" Fibre Channel over IP-based networks. This enables the interconnection of Fibre Channel SANs, with TCP/IP used as the underlying wide-area transport to provide congestion control and in-order delivery of data.

59. iFCP
The Internet Fibre Channel Protocol (iFCP) supports Fibre Channel Layer 4 FCP over TCP/IP. It is a gateway-to-gateway protocol where TCP/IP switching and routing components complement and enhance, or replace, the Fibre Channel fabric.

60. iFCP
The Internet Fibre Channel Protocol (iFCP) supports Fibre Channel Layer 4 FCP over TCP/IP. It is a gateway-to-gateway protocol where TCP/IP switching and routing components complement and enhance, or replace, the Fibre Channel fabric.

61. iSCSI
iSCSI (Internet Small Computer System Interface) is a TCP/IP-based protocol for establishing and managing connections between IP-based storage devices, hosts and clients. SNIA - IP Storage Forum:
iSCSI describes: 
Transport protocol for SCSI which operates on top of TCP 
New mechanism for encapsulating SCSI commands on an IP network
Protocol for a new generation of data storage systems that natively use TCP/IP

62. NAS / SAN

63. SAN