UNH InterOperability Lab

1. UNH InterOperability Lab Serial Advanced Technology Attachment (SATA)Use Cases

2. Presentation Topics • SATA Uses in the Enterprise • SATA Uses in Personal Computing • Device Form Factors • ODD, HDD, and SSD Devices • Port Multipliers

3. SATA Uses in the Enterprise • Scalability and Cost • Cabling and Connections • Performance and SATA / SAS Compatibility

4. Scalability and Cost • SATA is highly viable for servers and storage networks • One SATA controller can aggregate multiple ports • Multiple SATA drives can be linked using backplanes and external enclosures

5. Scalability and Cost • SATA was designed to provide excellent speed and storage at a low cost • Cost and scalability provides potential for greater storage capacity at a lower cost than networked or server storage

6. Cabling and Connections • Point-to-point connectivity • Thin and relatively small (compared to PATA) cables allow for simple routing and better airflow within systems • SATA was designed to eliminate master and slave setups as well as drive jumpers

7. Cabling and Connections • Hot-swapping is supported (drives can be added or removed while system is running) • Connectors allow for simple external RAID through backplanes

8. SATA Cables • Up to 1 meter in length, 7 conductors (3 grounds and 2 pairs of data lines)

9. Performance and SATA/SAS Compatibility • First Generation SATA (1.5 Gbit/s) • Second Generation SATA (3.0 Gbit/s) • Third Generation SATA (6.0 Gbit/s) • Native Command Queuing (NCQ) • Interoperability with SAS Initiators and Expanders

10. First Generation SATA (1.5 Gbit/s) • Communication rate of 1.5 Gbit/s for data transfer • At the application level, only one transaction can be handled at a given time

11. First Generation SATA (1.5 Gbit/s) • Throughput capabilities similar to PATA/133 specification • All optical drives operate at 1.5 Gbit/s transfer rate as well as many hard disk drives and hosts

12. Second Generation SATA (3.0 Gbit/s) • Designed to compensate for first generation shortcomings • Native Command Queuing (NCQ) support added for both 1.5 and 3.0 Gbit/s devices • Backwards compatibility with 1.5 controllers and 3.0 Gbit/s devices

13. Second Generation SATA (3.0 Gbit/s) • Second Generation SATA devices can drop to 1.5 Gbit/s transfer rate when communicating with First Generation devices • 3.0 Gbit/s transfer rate supported by many hosts and hard disk drives

14. Third Generation SATA (6.0 Gbit/s) • With introduction of Solid State Disk (SSD) drives, which operate at the 250 MB/s limit net read speed, enhancements were required • Isochronous data transfers in the NCQ streaming command were added • All DRAM cache reads operate at faster rates with Third Generation

15. Third Generation SATA (6.0 Gbit/s) • New NCQ host processing and management • Power management improved • Former SATA cables and connectors still meet specification

16. Native Command Queuing (NCQ) • When drive receives multiple commands from an application, NCQ optimizes how the commands will be completed • Drive must intelligently and internally assess the destination of the logic block addresses and then order the commands to optimize the workload

17. Native Command Queuing (NCQ) • This is due to the fact that the mechanical movement needed to position the read / write head is relevant • This improves performance and minimizes the mechanical positioning for the drive

18. Native Command Queuing (NCQ) • Commands are ordered in the queue to minimize mechanical movement

19. Interoperability with SAS Initiators and Expanders • SATA protocol was designed to interoperate with SAS • SATA drives can be used in many SAS enclosures • SATA targets are designed to connect to SAS initiators and expanders • However, SATA initiators cannot connect to SAS targets and expanders

20. SATA Uses in Personal Computing • Better performance than and backwards compatibility with PATA (Parallel Advanced Technology Attachment) • Enhanced reliability • Flexible system integration

21. SATA v. PATA Performance and Compatibility • Simplified operation with hot-swapping • SATA cables have only 7 conductors (two pairs of differential signaling lines, one for transmission, one for receiving and three grounds) improving accessibility

22. SATA v. PATA Performance and Compatibility • SATA devices can be set up to behave like PATA devices through “legacy mode” settings • Devices look as if they are on a PATA controller • Through eSATA connectivity internal SATA devices can connect to end systems externally

23. Enhanced Reliability • Packet integrity is verified by Cyclic Redundancy Checking (CRC) • CRC authenticates all data, validates that no corruption exists • SATA also uses CRC to communicate what data should be read or written and to watch drive optimization • Available latching connectors

24. Flexible System Integration • SATA is scalable, allowing for growth and augmentations to the platform • SATA supports all ATA and ATAPI devices (CD, DVD, CDRW, tape devices, Zip, etc.) • USB and IEEE1394 support for eSATA

25. Device Form Factors • 2.5” Side and Bottom Mounting Device • 3.5” Side and Bottom Mounting Device • 5.25” Optical Device • 5.25” Non-optical Device • 9.5 mm Slim-line Drive • 12.7 mm Slim-line Drive • 1.8” SATA Drive

26. 2.5” Side and Bottom Mounting Device • Form Factor for SSD and HDD applications

27. 3.5” Side and Bottom Mounting Device • Form Factor for disk drives

28. 5.25” Optical Device • Form Factor for CD, DVD, CDRW, DVDRW, etc. drives

29. 9.5 mm Slim-line Drive • Form Factor for many laptop optical drives

30. 12.7 mm Slim-line Drive • Form Factor for many laptop optical drives

31. 1.8” SATA Drive • Form Factor for many drives designed for portable devices and notebook computers

32. Types of SATA Drives • Optical Disk Drives (ODD) • Hard Disk Drives (HDD) • Solid State Disk Drives (SSD)

33. Optical Disk Drives (ODD) • All SATA Optical Disk Drives operate at Generation 1 speed (1.5 Gbit/s) • Offered in 5.25”, 9.5 mm, and 12.7 mm form factors • Capabilities include CD, DVD, CDRW, DVDR, DVDRW

34. Hard Disk Drives (HDD) • SATA Hard Disk Drives can operate at all speeds: 1.5 Gbit/s, 3.0 Gbit/s, and 6.0 Gbit/s • Operating speeds of 4200 rpm, 5400 rpm, 7200 rpm, and 10,000 rpm • Seen in all form factors (enclosures available for 9.5 mm and 12.7 mm are available)

35. Solid State Disk Drives (SSD) • SSD drives have many advantages over HDD drives • Typically composed of DRAM or NAND memory • No moving parts: faster startup, reading, constant performance, silent, lower heat production and power consumption, more resistant to physical shock and climate

36. Solid State Disk Drives (SSD) • Some disadvantages compared to HDD drives • Considerably higher cost, lower relative capacities, limited write cycles, slower write speeds

37. Port Multipliers • What Port Multipliers Do • How Port Multipliers Operate • How Port Multipliers are Cost-effective

38. What Port Multipliers Do • From one SATA port, multiple drives or devices can communicate • Placed on the backplane of a SATA enclosure

39. What Port Multipliers Do • Transparent operation to the drives attached • All SATA drives are supported

40. How Port Multipliers Operate • One SATA port multiplier host connects to many SATA drives • Operation is similar to USB hubs but performance is in line with an aggregated switch

41. How Port Multipliers Operate • Host bus adapter communicates with all drives but each subsequent drive is unaware of the multiplexing • Drives act as if they are connected directly to the host

42. How Port Multipliers Operate • Bus to SATA Devices • Note that the available bandwidth on the 3Gbit/s link limits drive connectivity, maintaining efficiency and performance • Bus to SATA PM to Devices

43. How Port Multipliers are Cost-effective • Allow extended device scalability • Up to 15 SATA devices can link to the host with one cable • Efficient packaging

44. How Port Multipliers are Cost-effective • Greater performance than Firewire / USB external drives • Only one host adapter is required as one PCI slot is needed • No performance loss

45. Sources • http://www.serialata.org/technology/why_sata.asp • http://www.wisegeek.com/what-is-sata-or-serial-ata.htm • http://www.thaiinternetwork.com/backend/imagefile/0213_3.jpg • http://www.smartcomputing.com/editorial/article.asp?article=articles/archive/l0907/41l07/41l07.asp • http://www.blogcdn.com/www.engadget.com/media/2007/10/wd-scorpio-320gb.jpg • http://c1.neweggimages.com/productimage/22-136-317-03.jpg • http://computer-reviews.net/files/Toshiba%20Dual%20Layer%20DVD%20Writer.jpg • http://www.pcstats.com/articleimages/200708/LGGSAH62N_sata2.jpg • http://www.techfresh.net/wp-content/uploads/2008/09/toshiba-250gb-sata-disk.jpg • http://www.serialata.org/technology/port_multipliers.asp • http://freshisback.files.wordpress.com/2009/03/skyscraper.jpg • http://www.uriel-law.com/images/ComputerNetwork.jpg • http://www.tomsguide.com/us/intel-ss4000e-raid5-nas,review-714-4.html • http://img.tomshardware.com/us/2007/08/10/unified_serial_raid_controllers_for_pci_express/sata-sas.jpg • http://img.zdnet.com/techDirectory/_SATPAT.JPG • http://www.sataport.com/5-port-sata-multiplier-silicon-image2.jpg

47. UNH InterOperability Lab Serial Attached SCSI (SAS)Use Cases