Content deleted Content added
Reinstate the "data segment" title, even though rev3.1 now uses "Signal Segment" |
|||
(44 intermediate revisions by 33 users not shown) | |||
Line 1:
{{Short description|Computer bus interface for storage devices}}
{{For|others|SATA (disambiguation)}}
{{Use American English|date=February 2024}}
{{Lead too short|date=January 2022}}
{{Infobox computer hardware bus
| name = SATA
| fullname = [[File:Serial-ATA-Logo.svg|120px]]
| image =
Line 36 ⟶ 35:
Serial ATA industry compatibility specifications originate from the [[Serial ATA International Organization]] (SATA-IO). The SATA-IO group collaboratively creates, reviews, ratifies, and publishes the interoperability specifications, the test cases and [[plugfest]]s. As with many other industry compatibility standards, the SATA content ownership is transferred to other industry bodies: primarily INCITS T13<ref name="INCITS_T13" /> and an INCITS [[T10 subcommittee]] ([[SCSI]]), a subgroup of T10 responsible for [[Serial Attached SCSI]] (SAS). The remainder of this article strives to use the SATA-IO terminology and specifications.
Before SATA's introduction in 2000, PATA was simply known as ATA. The "AT Attachment" (ATA) name originated after the 1984 release of the [[IBM Personal Computer/AT|IBM Personal Computer AT]], more commonly known as the IBM AT.<ref>{{cite web|url=https://ecse.rpi.edu/courses/S15/ECSE-4780/Labs/IDE/IDE_SPEC.PDF|title=Lamars, Lawrence J., ''Information technology - AT Attachment Interface for Disk Drives'', Computer and Business Equipment Manufacturers Association, 1994, xi (introduction)|access-date=2016-08-02|url-status=live|archive-url=https://web.archive.org/web/20160617193535/https://ecse.rpi.edu/courses/S15/ECSE-4780/Labs/IDE/IDE_SPEC.PDF|archive-date=2016-06-17}}</ref> The IBM AT's controller interface became a de facto industry interface for the inclusion of hard disks. "AT" was IBM's abbreviation for "Advanced Technology"; thus, many companies and organizations indicate SATA is an abbreviation of "Serial Advanced Technology Attachment". However, the ATA specifications simply use the name "AT Attachment", to avoid possible trademark issues with IBM.<ref>{{cite book |url=https://books.google.com/books?id=Hyl8SA1eHzIC&q=AT+&pg=PA105|title= Govindarajalu, B., ''IBM PC And Clones: Hardware, Troubleshooting And Maintenance''|publisher=Tata McGraw-Hill Publishing Company
SATA host adapters and devices communicate via a high-speed [[serial communications|serial]] cable over two pairs of conductors. In contrast, parallel ATA (the [[retronym|redesignation]] for the legacy ATA specifications) uses a 16-bit wide data bus with many additional support and control signals, all operating at a much lower frequency. To ensure backward compatibility with legacy ATA software and applications, SATA uses the same basic ATA and [[ATA Packet Interface|ATAPI]] command sets as legacy ATA devices.
The world's first SATA hard disk drive is the Seagate Barracuda SATA V, which was released in Jan 2003.<ref>{{cite web|url=https://www.seagate.com/support/disc/manuals/sata/cuda5_sata_pm.pdf
SATA has replaced parallel ATA in consumer desktop and laptop [[computer]]s; SATA's market share in the desktop PC market was 99% in 2008.<ref name="rev30">{{cite web|url=http://www.serialata.org/documents/SATA-Rev-30-Presentation.pdf|title=Serial ATA: Meeting Storage Needs Today and Tomorrow|website=serialata.org|access-date=2011-10-30|url-status=dead|archive-url=https://web.archive.org/web/20120417133358/http://www.serialata.org/documents/SATA-Rev-30-Presentation.pdf|archive-date=2012-04-17}}</ref> PATA has mostly been replaced by SATA for any use; with PATA in declining use in industrial and embedded applications that use [[CompactFlash]] (CF) storage, which was designed around the legacy PATA standard. A 2008 standard, [[CFast]], to replace CompactFlash is based on SATA.<ref>{{cite web|url=https://www.engadget.com/2008/02/25/cfast-compactflash-cards-now-said-to-be-coming-in-18-to-24-mont/|author=Donald Melanson|publisher=[[Engadget]]|title=CFast CompactFlash cards now said to be coming in "18 to 24 months"|date=2008-02-25|access-date=2009-03-19|url-status=live|archive-url=https://web.archive.org/web/20090303144033/http://www.engadget.com/2008/02/25/cfast-compactflash-cards-now-said-to-be-coming-in-18-to-24-mont|archive-date=2009-03-03}}</ref><ref>{{cite web|url=http://www.dpreview.com/news/2009/1/9/preteccfaststoragecards|publisher=[[DPReview]]|title=Pretec release CFast card with SATA interface|date=8 January 2009|access-date=19 March 2009|url-status=live|archive-url=https://web.archive.org/web/20121025074641/http://www.dpreview.com/news/2009/1/9/preteccfaststoragecards|archive-date=25 October 2012}}</ref>
Line 57 ⟶ 56:
[[Advanced Host Controller Interface]] (AHCI) is an open host controller interface published and used by Intel, which has become a [[de facto]] standard. It allows the use of advanced features of SATA such as [[hotplug]] and [[native command queuing]] (NCQ). If AHCI is not enabled by the motherboard and chipset, SATA controllers typically operate in "IDE{{Efn|Integrated Drive Electronics}} emulation" mode, which does not allow access to device features not supported by the ATA (also called IDE) standard.
Windows device drivers that are labeled as SATA are often running in IDE emulation mode unless they explicitly state that they are AHCI mode, in [[RAID]] mode, or a mode provided by a proprietary driver and command set that allowed access to SATA's advanced features before AHCI became popular. Modern versions of [[Microsoft Windows]], [[macOS|Mac OS X]], [[FreeBSD]], [[Linux kernel|Linux]] with version 2.6.19 onward,<ref>{{cite web |url=http://linux-ata.org/driver-status.html#ahci|archive-url=https://web.archive.org/web/20070312010549/http://linux-ata.org/driver-status.html#ahci|archive-date=2007-03-12 |title=Serial ATA (SATA) Linux hardware/driver status report |website=linux-ata.org |access-date=2010-01-26}}</ref> as well as [[Solaris (operating system)|Solaris]] and [[OpenSolaris]], include support for AHCI, but earlier operating systems such as [[Windows XP]] do not. Even in those instances, a proprietary driver may have been created for a specific chipset, such as [[Intel]]'s.<ref>{{cite web|url=http://www.intel.com/support/chipsets/imst/sb/cs-020825.htm|title=Intel® Matrix Storage Technology - Unattended Installation Instructions Under Windows* XP|date=2 March 2007|publisher=[[Intel]]|url-status=
==Revisions==
SATA revisions are typically designated with a dash followed by [[Roman numerals]], e.g. "SATA-III",<ref>{{cite web|url=http://kb.sandisk.com/app/answers/detail/a_id/8142/~/difference-between-sata-i,-sata-ii-and-sata-iii|
==={{Anchor|1.0}}SATA revision 1.0 (1.5 Gbit/s, 150 MB/s, Serial ATA-150)===
Revision 1.0a<ref name="SATA1a" /> was released on January 7, 2003. First-generation SATA interfaces, now known as SATA 1.5 Gbit/s, communicate at a rate of 1.5 Gbit/s,{{Efn|{{BDprefix|p=D}}}} and do not support [[Native Command Queuing]] (NCQ). Taking [[8b/10b encoding]] overhead into account, they have an actual [[uncoded transfer rate]] of 1.2 Gbit/s (150 MB/s). The theoretical burst throughput of SATA 1.5
During the initial period after SATA 1.5 Gbit/s finalization, adapter and drive manufacturers used a "bridge chip" to convert existing PATA designs for use with the SATA interface. Bridged drives have a SATA connector, may include either or both kinds of power connectors, and, in general, perform identically to their native-SATA equivalents.<ref>{{cite web
Line 75 ⟶ 74:
|archive-url = https://web.archive.org/web/20150325001151/http://techreport.com/review/6390/western-digital-raptor-wd740gd-sata-hard-drive
|archive-date = 2015-03-25
}}</ref>
{{As of|2010|4}}, the fastest 10,000 rpm SATA [[hard disk drive]]s could transfer data at maximum (not average) rates of up to 157 MB/s,<ref name="Tom2010HardDrives">{{Cite news|title=VelociRaptor Returns: 6Gbit/s, 600GB, And 10,000 RPM |website=tomshardware.com |author=Patrick Schmid and Achim Roos |url=http://www.tomshardware.com/reviews/wd6000hlhx-velociraptor-600gb,2600-5.html |date=2010-04-06 |access-date=2010-06-26}}</ref> which is beyond the capabilities of the older PATA/133 specification and also exceeds the capabilities of SATA 1.5 Gbit/s.
Line 91 ⟶ 90:
===={{Anchor|2.6}}SATA revision 2.6====
Announced in February 2007, SATA revision 2.6 introduced the following features:<ref name="sata26">{{cite web |title=Serial ATA Revision 2.6 |url=http://read.pudn.com/downloads157/doc/project/697017/SerialATA_Revision_2_6_Gold.pdf |url-status=live |archive-url=https://web.archive.org/web/20141006104140/http://read.pudn.com/downloads157/doc/project/697017/SerialATA_Revision_2_6_Gold.pdf |archive-date=2014-10-06 |publisher=Serial ATA International Organization |page=115}}</ref>
* [[#Slimline connector|Slimline connector]].
* [[#Micro connector|Micro connector (initially for 1.8” HDD)]].
Line 113 ⟶ 112:
}}</ref> and ratified its physical layer specification on August 18, 2008.<ref>{{cite web|url=http://www.sata-io.org/technology/6Gbdetails.asp|publisher=[[SATA-IO]]|title=SATA Revision 3.0|date=27 May 2009|access-date=4 December 2009|url-status=live|archive-url=https://web.archive.org/web/20130202075739/http://www.sata-io.org/technology/6Gbdetails.asp|archive-date=2 February 2013}}</ref> The full 3.0 standard was released on May 27, 2009.<ref>{{cite press release |url=http://www.sata-io.org/documents/SATA-Revision-3.0-Press-Release-FINAL-052609.pdf |title=SATA-IO Releases SATA Revision 3.0 Specification |publisher=Serial ATA International Organization |date=May 27, 2009 |access-date=3 July 2009 |url-status=live |archive-url=https://web.archive.org/web/20090611174913/http://www.sata-io.org/documents/SATA-Revision-3.0-Press-Release-FINAL-052609.pdf |archive-date=11 June 2009 }}</ref>
Third-generation SATA interfaces run with a native transfer rate of 6.0 Gbit/s; taking [[8b/10b encoding]] into account, the maximum uncoded transfer rate is 4.8 Gbit/s (600 MB/s). The theoretical burst throughput of SATA 6.0 Gbit/s is double that of SATA revision 2.0. It is backward compatible with
The SATA 3.0 specification contains the following changes:
Line 156 ⟶ 155:
|archive-date = 2016-03-04
}}</ref>
* The [[SATA Express]] specification defines an interface that combines both SATA and [[PCI Express]] buses, making it possible for both types of storage devices to coexist. By employing PCI Express, a much higher theoretical throughput of 1969
* The [[M.2|SATA M.2]] standard is a small form factor implementation of the SATA Express interface, with the addition of an internal [[USB 3.0]] port; see the [[#M.2|M.2 (NGFF)]] section below for a more detailed summary.<ref>{{cite web |url=https://www.sata-io.org/sata-m2-card |title=SATA M.2 Card |publisher=SATA-IO |access-date=2014-01-16 |url-status=live |archive-url=https://web.archive.org/web/20131003103042/https://www.sata-io.org/sata-m2-card |archive-date=2013-10-03 }}</ref>
* ''microSSD'' introduces a [[ball grid array]] electrical interface for miniaturized, embedded SATA storage.<ref>[http://www.sata-io.org/technology/ussd.asp SATA
* ''USM Slim'' reduces thickness of Universal Storage Module (USM) from {{Convert|14.5|mm|in|abbr=off|sp=us}} to {{Convert|9|mm|in|abbr=off|sp=us}}.<ref>{{cite web |url=https://www.sata-io.org/system/files/member-downloads/SATA-IO%20USM%20SLIM%20PR_Final_0.pdf |title=SATA-IO Rolls Out USM Slim Specification for Thinner, Lighter External Storage |publisher=SATA-IO |access-date=2014-02-12 |url-status=live |archive-url=https://web.archive.org/web/20140222150433/https://www.sata-io.org/system/files/member-downloads/SATA-IO%20USM%20SLIM%20PR_Final_0.pdf |archive-date=2014-02-22 }}</ref>
* [[DevSleep]] enables lower power consumption for always-on devices while they are in low-power modes such as [[InstantGo]] (which used to be known as Connected Standby).<ref>{{cite web |url=https://www.sata-io.org/power-management |title=SATA Enables Life Unplugged |publisher=SATA-IO |access-date=2014-01-16 |url-status=live |archive-url=https://web.archive.org/web/20140207100518/https://www.sata-io.org/power-management |archive-date=2014-02-07 }}</ref>
* ''Hybrid Information'' provides higher performance for [[solid-state hybrid drive]]s.<ref>{{cite web
Line 193 ⟶ 192:
|archive-date = 2016-12-26
}}</ref>
* [[Shingled magnetic recording]] (SMR) host-control support
* ''Power Disable'' feature (see PWDIS pin) allows for remote power cycling of SATA drives and a Rebuild Assist function that speeds up the rebuild process to help ease maintenance in the data center.
* Transmitter Emphasis Specification increases interoperability and reliability between host and devices in electrically demanding environments.
Line 225 ⟶ 224:
===={{Anchor|3.5}}SATA revision 3.5====
Released in July 2020, SATA revision 3.5
|url = https://sata-io.org/sites/default/files/documents/SATA%20Spec%20Rev%203%205%20FINAL.pdf
|title = SATA-IO Increases Interoperability Features with Revision 3.5 Specification
Line 238 ⟶ 237:
* Defined Ordered NCQ Commands: allows the host to specify the processing relationships among queued commands and sets the order in which commands are processed in the queue.
* Command Duration Limit Features: reduces latency by allowing the host to define quality of service categories, giving the host more granularity in controlling command properties. The feature helps align SATA with the "Fast Fail" requirements established by the Open Compute Project (OCP) and specified in the INCITS T13 Technical Committee standard.
SATA revision '''3.5a''' was released in March 2021.
=={{Anchor|CONNECTORS}}Cables, connectors, and ports==
Line 253 ⟶ 254:
}}</ref>
Standard SATA connectors for both data and power have a conductor pitch of {{Convert|1.27|mm|in|abbr=in|sp=us}}. Low insertion force is required to mate a SATA connector. A smaller mini-SATA or mSATA connector is used by smaller devices such as 1.8-inch SATA drives, some DVD and Blu-ray drives, and mini SSDs.<ref>{{cite web |url=http://techreport.com/discussions.x/17624 |title=Get ready for mini-SATA |publisher=The Tech Report |date=2009-09-21 |access-date=2010-01-26 |url-status=live |archive-url=https://web.archive.org/web/20090925002619/http://www.techreport.com/discussions.x/17624 |archive-date=2009-09-25 }}</ref>
A special eSATA connector is specified for external devices, and an optionally implemented provision for clips to hold internal connectors firmly in place. SATA drives may be plugged into [[Serial Attached SCSI|SAS]] controllers and communicate on the same physical cable as native SAS disks, but SATA controllers cannot handle SAS disks.
Line 264 ⟶ 265:
{| class="wikitable" style="float:right; margin-left:1em; margin-right:0; margin-top:0;"
|+ Standard connector, data segment, host side signal naming
|-
! colspan="2"| Pin # !! Mating !! Function
Line 304 ⟶ 305:
|}
The SATA standard defines a data cable with seven conductors (three grounds and four active data lines in two pairs) and 8 mm wide wafer connectors on each end. SATA cables can have lengths up to {{convert|1|m|ft|sp=us}}, and connect one motherboard socket to one hard drive. PATA [[ribbon cable]]s, in comparison, connect one motherboard socket to one or two hard drives, carry either 40 or 80 wires, and are limited to {{convert|45|cm|in|sp=us}} in length by the PATA specification; however, cables up to {{convert|90|cm|in|sp=us}} are readily available. Thus, SATA connectors and cables are easier to fit in closed spaces and reduce obstructions to [[air cooling]]. Some cables even include a locking feature, whereby a small (usually metal) spring holds the plug in the socket.
SATA connectors may be straight, right-angled, or left-angled. Angled connectors allow lower-profile connections. Right-angled (also called 90-degree) connectors lead the cable immediately away from the drive, on the circuit-board side. Left-angled (also called 270-degree) connectors lead the cable across the drive towards its top.
Line 313 ⟶ 314:
File:SATA Data Cable.jpg|A seven-pin SATA data cable (left-angled version of the connector)
File:2.5-inch SATA drive on top of a 3.5-inch SATA drive, close-up of data and power connectors.jpg|SATA connectors on 2.5 and 3.5-inch hard drives, with data pins on the left and power pins on the right. The two different pin lengths ensure a specific mating order; the longer lengths are ground pins and make contact first. (The cable side has similar variations to achieve three levels of mating order.)
File:SATA3-TwinAxCable.jpg|SATA cable showing the two foil shielded differential pairs
</gallery>
{{Clear}}
===SATA Power connectors{{Anchor|SATA power}}===
====Standard power connector (15 pins)====
{| class="wikitable" style="float:right; margin-left:1em; margin-right:0; margin-top:0;"
|+ Standard connector, power segment
Line 383 ⟶ 384:
|}
[[File:SATA power cable.jpg|thumb|left|200px|A fifteen-pin SATA power connector (
SATA specifies a different [[DC connector|power connector]] than the four-pin [[Molex connector]] used on [[Parallel ATA]] (PATA) devices (and earlier small storage devices, going back to [[ST-506]] hard disk drives and even to floppy disk drives that predated the IBM PC). It is a wafer-type connector, like the SATA data connector, but much wider (fifteen pins versus seven) to avoid confusion between the two. Some early SATA drives included the four-pin Molex power connector together with the new fifteen-pin connector, but most SATA drives now have only the latter.
Line 396 ⟶ 397:
|url-status=dead
}}</ref>
* 3.3 V is supplied along with the traditional 5 V and 12 V supplies. However, very few drives actually use it
* Pin 3 in SATA revision 3.3 has been redefined as PWDIS and is used to enter and exit the POWER DISABLE mode in line with SAS-3.<ref>{{cite web |last1=Chu |first1=Frank (HGST) |last2=Frank |first2=James (Seagate) |last3=Cox |first3=Alvin (Seagate) |title=SATA3.2 TPR056 Enable new Power Disable feature on standard SATA connector P3 |url=https://sata-io.org/sites/default/files/TPR056r13_SATA32_EnableNewPowerDisableFeatureOnStandardSATA.pdf |access-date=17 June 2023 |date=3 March 2014}}</ref> If Pin 3 is driven HIGH (2.1–3.6 V max), power to the drive circuitry is cut. Drives with this feature enabled do not power up in systems designed to SATA revision 3.1 or earlier, because Pin 3 driven HIGH prevents the drive from powering up.<ref name="power-disable" /> The workaround is to use a Molex adapter without 3.3 V or to put insulating tape over the PWDIS pin.
* To reduce resistance and increase current capability, each voltage is supplied by three pins in parallel, though one pin in each group is intended for precharging (see below). Each pin should be able to carry 1.5 A.
Line 402 ⟶ 403:
* Two ground pins and one pin for each supplied voltage support [[hot swapping|hot-plug]] precharging. Ground pins 4 and 12 in a hot-swap cable are the longest, so they make contact first when the connectors are mated. Drive power connector pins 3, 7, and 13 are longer than the others, so they make contact next. The drive uses them to charge its internal bypass capacitors through current-limiting resistances. Finally, the remaining power pins make contact, bypassing the resistances and providing a low-resistance source of each voltage. This two-step mating process avoids glitches to other loads and possible arcing or erosion of the SATA power-connector contacts.
* Pin 11 might be used (often by chassis or backplane hardware independent from SATA host controller and its data connection) for [[staggered spinup]], activity indication, emergency head parking, or other vendor defined functions in various combinations. It is an [[open-collector]] signal, which may be pulled down by the connector or the drive.
** Host signaling: If pulled down at the connector (as it is on most cable-style SATA power connectors), the drive spins up as soon as power is applied.
** Drive signaling: The pin is also pulled low by the drive to indicate drive activity. This may be used to give feedback to the user through an [[LED]]. Relevant definitions of pin operation have changed multiple times in published revisions of SATA standard, so the observed behavior may be dependent on device version, host version, firmware and software configuration.<ref>{{cite web |author1=Samsung Electronics |title=Device Activity Signal (DAS) Application Note |url=https://semiconductor.samsung.com/resources/others/Samsung_SSD_845DC_01_Device_Activity_Signal_DAS.pdf |access-date=27 April 2023 |date=26 May 2014}}</ref><ref>{{cite web |author1=SATA-IO |title=Serial ATA Revision 3.2 Technical Proposal #058: DAS/DSS/DHU Changes |url=https://sata-io.org/sites/default/files/TPR058v3_SATA32_DAS%2BDSS%2BDHU_Changes.pdf |access-date=27 April 2023 |date=2 June 2014}}</ref><ref>{{cite web |author1=SATA-IO |title=Serial ATA Revision 3.2 Error Correction #089: DAS/DSS support clarifications |url=https://sata-io.org/sites/default/files/ECN089v6_SATA32_DSS_DAS_SupportClarifications.pdf |access-date=27 April 2023 |date=11 August 2015}}</ref> There is also a specification for transmission of drive temperature and other status values with activity signal pulses routinely used to make LED blink.<ref>{{cite web |author1=SNIA SFF TWG |title=SFF-8609: Management Interface for Drive Conditions |url=https://members.snia.org/document/dl/27389 |access-date=27 April 2023 |date=7 July 2017}}</ref>
Line 408 ⟶ 409:
{{Clear}}
====Slimline power connector (6 pins)====
{| class="wikitable" style="float:right; margin-left:1em; margin-right:0; margin-top:0;"
|+ Slimline connector, power segment
Line 446 ⟶ 447:
|}
<gallery widths="200">▼
</gallery>The power connector is reduced to six pins so it supplies only +5 V (red wire), and not +12 V or +3.3 V.<ref name="sata26" /><ref>{{cite web |title=Press release: SATA-IO ADVANCES TECHNOLOGY WITH THE SATA REVISION 2.6 SPEC |url=https://sata-io.org/system/files/member-downloads/SATA-IOAdvancesTechnologyWithTheSATARevision2.6Spec.pdf |url-status=live |archive-url=https://web.archive.org/web/20170829210356/https://www.sata-io.org/system/files/member-downloads/SATA-IOAdvancesTechnologyWithTheSATARevision2.6Spec.pdf |archive-date=2017-08-29 |access-date=2017-11-10 |publisher=SATA}}</ref>
Pin 1 of the slimline power connector, denoting device presence, is shorter than the others to allow hot-swapping.
Note: The '''data''' connector used is the same as the non-slimline version.
Low-cost adapters exist to convert from standard SATA to slimline SATA.
SATA 2.6 is the first revision that defined the '''slimline''' power connector targeted for smaller form-factors drives, such as laptop optical drives.
▲<gallery widths="200">
▲File:SATA Slimline Powercable.jpg|A six-pin slimline SATA power connector
▲File:SATA connector Slimline CD-ROM.jpg|The back of a SATA-based slimline optical drive
</gallery>▼
{{Clear}}
Line 508 ⟶ 513:
|align=center| 2nd
|}
<gallery widths="200">
2008 Intel Developer Forum Taipei Showcae Samsung muSATA 128GB SSD.jpg|[[Samsung]] 128 GB micro SATA [[solid-state drive]]
▲</gallery>
The micro SATA connector (sometimes called uSATA or μSATA<ref name="amazon-msata">{{cite web
Line 522 ⟶ 530:
===Additional pins{{Anchor|EXTRAPINS}}===
Some SATA drives, in particular mechanical ones, come with an extra 4 or more pin interface which isn't uniformly
{{Clear}}
Line 533 ⟶ 541:
[[File:Connector esata IMGP6050 wp.jpg|thumb|upright|eSATA ports]]
Standardized in 2004, eSATA (''e'' standing for external) provides a variant of SATA meant for external connectivity.
* Minimum transmit amplitude increased: Range is 500–600 mV instead of 400–600 mV.
* Minimum receive amplitude decreased: Range is 240–600 mV instead of 325–600 mV.
* Maximum cable length increased to {{convert|2|m|ft|sp=us}} from {{convert|1|m|ft|sp=us}}.
* The eSATA cable and connector is similar to the SATA 1.0a cable and connector, with these exceptions:
** The eSATA connector is mechanically different to prevent unshielded internal cables from being used externally. The eSATA connector discards the
** The eSATA insertion depth is deeper: 6.6 mm instead of 5 mm. The contact positions are also changed.
** The eSATA cable has an extra shield to reduce [[Electromagnetic interference|EMI]] to FCC and CE requirements. Internal cables do not need the extra shield to satisfy EMI requirements because they are inside a shielded case.
Line 553 ⟶ 561:
* For small form-factor devices (such as external 2.5-inch<!-- No unit conversion: this is a nominal size class and not a measurement. --> disks), a PC-hosted USB or FireWire link can usually supply sufficient power to operate the device. However, eSATA connectors cannot supply power, and require a power supply for the external device. The related [[eSATAp]] (but mechanically incompatible, sometimes called ''eSATA/USB'') connector adds power to an external SATA connection, so that an additional power supply is not needed.<ref>{{cite web|url=http://www.sata-io.org/documents/External%20SATA%20WP%2011-09.pdf|title=External Serial ATA|publisher=Silicon Image, Inc|access-date=8 August 2009|url-status=dead|archive-url=https://web.archive.org/web/20100613100125/http://sata-io.org/documents/External%20SATA%20WP%2011-09.pdf|archive-date=13 June 2010}}</ref>
{{As of
Desktop computers without a built-in eSATA interface can install an eSATA [[host bus adapter]] (HBA); if the motherboard supports SATA, an externally available eSATA connector can be added. Notebook computers with the now rare [[Cardbus]]<ref name="addonics_cardbus">{{cite web |url=http://www.addonics.com/products/adcb2sa-e.php |title=CardBus SATA adapter |website=addonics.com |access-date=2010-01-26 |url-status=live |archive-url=https://web.archive.org/web/20111104205549/http://www.addonics.com/products/adcb2sa-e.php |archive-date=2011-11-04 }}</ref> or [[ExpressCard]]<ref name="addonics_expresscard">{{cite web |url=http://www.addonics.com/products/adexc34-2e.php |title=ExpressCard SATA adapter |website=addonics.com |access-date=2010-01-26 |url-status=live |archive-url=https://web.archive.org/web/20111129201348/http://www.addonics.com/products/adexc34-2e.php |archive-date=2011-11-29 }}</ref> could add an eSATA HBA. With passive adapters, the maximum cable length is reduced to {{convert|1|m|ft|sp=us}} due to the absence of compliant eSATA signal-levels.
===={{Anchor|eSATAp}}eSATAp====
Line 568 ⟶ 576:
====Pre-standard implementations====
* Prior to the final eSATA 6 Gbit/s specification many add-on cards and some motherboards advertised eSATA 6 Gbit/s support because they had 6 Gbit/s SATA 3.0 controllers for internal-only solutions. Those implementations are non-standard, and eSATA 6 Gbit/s requirements were ratified in the July 18, 2011 SATA 3.1 specification.<ref>{{cite web |url=https://www.sata-io.org/sites/default/files/documents/SATA-Revision-3.0-FAQ-FINAL.pdf |title=Frequently Asked Questions About SATA 6 Gbit/s and the SATA Revision 3.0 Specification |date=May–June 2009 |access-date=2011-10-30 |url-status=live |archive-url=https://web.archive.org/web/20140222150446/https://www.sata-io.org/sites/default/files/documents/SATA-Revision-3.0-FAQ-FINAL.pdf |archive-date=2014-02-22 }}</ref> Some products might not be fully eSATA 6 Gbit/s compliant.
==={{Anchor|mSATA}}Mini-SATA (mSATA)===
{{See also|PCI Express#MSATA|l1=PCI Express § Mini-SATA (mSATA) variant}}
[[File:Intel 525 mSATA SSD.jpg|thumb|upright|An mSATA SSD]]
Mini-SATA (abbreviated as mSATA), which is distinct from the micro connector,<ref name="amazon-msata" /> was announced by the Serial ATA International Organization on September 21, 2009.<ref>{{cite news|title=mSATA Press Release|url=http://www.sata-io.org/documents/mSATA-press%20release-v9.pdf|access-date=11 March 2011|url-status=dead|archive-url=https://web.archive.org/web/20110726065816/http://www.sata-io.org/documents/mSATA-press%20release-v9.pdf|archive-date=26 July 2011}}</ref>
The physical dimensions of the mSATA connector are identical to those of the [[Mini-PCIe#PCI Express Mini Card|PCI Express Mini Card]] interface,<ref>{{cite web |title=Intel 310 SSD |url=http://download.intel.com/design/flash/nand/324042.pdf |archive-url=https://web.archive.org/web/20110112092850/http://download.intel.com/design/flash/nand/324042.pdf |publisher=[[Intel]] |access-date=11 March 2011 |archive-date=12 January 2011}}</ref> but the interfaces are electrically incompatible; the data signals (TX±/RX± SATA, PETn0 PETp0 PERn0 PERp0 PCI Express) need a connection to the SATA host controller instead of the [[PCI Express]] host controller.
Line 608 ⟶ 615:
|}
Slim 2.5-inch SATA devices, {{Convert|5|mm|in|abbr=in|sp=us}} in height, use the twenty-pin ''SFF-8784'' [[edge connector]] to save space.
|url = http://www.wdc.com/wdproducts/library/SpecSheet/ENG/2579-771981.pdf
|title = SFF-8784 Edge Connector Pin Definitions: Information Sheet
Line 624 ⟶ 631:
==={{Anchor|SATA-EXPRESS}}SATA Express===
[[File:SATA Express connectors on a computer motherboard.jpg|thumb|upright=1.3|Two SATA Express connectors (light gray) on a [[computer motherboard]]; to the right of them are common SATA connectors (dark gray).]]
{{Main|SATA Express}}
Line 635 ⟶ 642:
|archive-url = https://archive.today/20130809202201/https://www.sata-io.org/sata-revision-32
|archive-date = 2013-08-09
}}</ref> is an interface that supports either SATA or [[PCI Express]] storage devices.
|url = https://www.sata-io.org/sites/default/files/documents/MM_Nereus_Signage_Print_0719.pdf
|title = Connector Mating Matrix
Line 643 ⟶ 650:
|archive-url = https://web.archive.org/web/20131004231134/https://www.sata-io.org/sites/default/files/documents/MM_Nereus_Signage_Print_0719.pdf
|archive-date = 2013-10-04
}}</ref>
|url = https://www.sata-io.org/sata-express
|title = Enabling Higher Speed Storage Applications with SATA Express
Line 654 ⟶ 661:
}}</ref>
Instead of the otherwise usual approach of doubling the native speed of the SATA interface, PCI Express was selected for achieving data transfer speeds greater than 6 Gbit/s.
|url = https://www.sata-io.org/sites/default/files/documents/SATA%20Express%20-%20CS%202013.pdf
|title = SATA Express: PCIe Client Storage
Line 683 ⟶ 690:
==={{Anchor|M.2}}M.2 (NGFF)===
[[File:M.2 and mSATA SSDs comparison.jpg|thumb|right|upright=1.3|Size comparison of mSATA (left) and M.2 (size 2242, right) SSDs]]
[[File:M.2 2242 SSD connected into USB 3.0 adapter.jpg|thumb|An [[M.2]] (2242) solid-state-drive ([[SSD]]) connected into [[USB]] 3.0 adapter and connected to computer
{{Main|M.2}}
[[M.2]], formerly known as the [[Next Generation Form Factor]] (NGFF), is a specification for computer [[expansion card]]s and associated connectors.
|url = https://www.sata-io.org/sata-m2-card
|title = SATA M.2 Card
Line 696 ⟶ 703:
}}</ref>
The M.2 standard is designed as a revision and improvement to the mSATA standard, so that larger [[printed circuit board]]s (PCBs) can be manufactured.
|url = http://wccftech.com/intel-ssd-530-series-arriving-august-2013-feature-ngff-m2-interface/
|title = Intel SSD 530 Series Arriving Next Week – Feature NGFF M.2 Interface
Line 716 ⟶ 723:
}}</ref>
Supported host controller interfaces and internally provided ports are a superset to those defined by the SATA Express interface.
{{Clear}}
Line 725 ⟶ 732:
{{Clear}}
==Topology==
Line 764 ⟶ 744:
===SATA and PATA===
[[File:PATA hard disk with SATA converter.png|thumb|PATA hard disk with SATA converter attached
At the hardware interface level, SATA and PATA ([[Parallel ATA|Parallel AT Attachment]]) devices are completely incompatible: they cannot be interconnected without an adapter.
Line 801 ⟶ 781:
SATA 3 Gbit/s theoretically offers a maximum bandwidth of 300 MB/s per device, which is only slightly lower than the rated speed for SCSI Ultra 320 with a maximum of 320 MB/s total for all devices on a bus.<ref>Ultra-640 is specified, but devices do not exist</ref> SCSI drives provide greater sustained throughput than multiple SATA drives connected via a simple (i.e., command-based) [[port multiplier]] because of disconnect-reconnect and aggregating performance.<ref>FIS-based switching is comparable to SCSI's tagged command queueing</ref> In general, SATA devices link compatibly to SAS enclosures and adapters, whereas SCSI devices cannot be directly connected to a SATA bus.
SCSI, SAS{{Citation needed|date=January 2024}}, and fibre-channel (FC) drives are more expensive than SATA, so they are used in [[server (computing)|server]]s and [[disk array]]s where the better performance justifies the additional cost. Inexpensive ATA and SATA drives evolved in the [[home computer|home-computer]] market, hence there is a view that they are less reliable. As those two worlds overlapped, the subject of reliability [[Hard disk drive#Integrity and failure|became somewhat controversial]]. Note that, in general, the failure rate of a disk drive is related to the quality of its heads, platters and supporting manufacturing processes, not to its interface.
Use of serial ATA in the business market increased from 22% in 2006 to 28% in 2008.<ref name="rev30" />
Line 816 ⟶ 796:
! [[Bit rate#Gross bit rate|Raw data rate]]
! data-sort-type="number" | [[Bit rate#Information rate|Data rate]]
!
! Power provided
! Devices per channel
Line 851 ⟶ 831:
| [[#1.0|SATA revision 1.0]]
|data-sort-value="1.5" | 1.5 Gbit/s
|data-sort-value="150" | 150 MB/s<ref>{{cite web|url=
|1
|-
Line 928 ⟶ 908:
|data-sort-value="{{#expr:480/1000}}" | 480 Mbit/s
|data-sort-value="58" | 58 MB/s<!-- 8 bits/byte, NRZI encoding with bit-stuffing -->
|5 m
|Yes|2.5 W, 5 V
|-
Line 960 ⟶ 940:
|data-sort-value="{{#expr:0.98*1024}}" | 0.98 GB/s
| {{plainlist|
*5 m (copper)<ref>{{cite web|url=http://download.intel.com/design/network/products/optical/cables/ornl.pdf |archive-url=https://
*<10 km (fiber)
}}
|