IBM manufactured magnetic disk storage devices from 1956 to 2003, when it sold its hard disk drive business to Hitachi. [1] [2] Both the hard disk drive (HDD) and floppy disk drive (FDD) were invented by IBM and as such IBM's employees were responsible for many of the innovations in these products and their technologies. [3] The basic mechanical arrangement of hard disk drives has not changed since the IBM 1301. Disk drive performance and characteristics are measured by the same standards now as they were in the 1950s. Few products in history have enjoyed such spectacular declines in cost and physical size along with equally dramatic improvements in capacity and performance.
IBM manufactured 8-inch floppy disk drives from 1969 until the mid-1980s, but did not become a significant manufacturer of smaller-sized, 5.25- or 3.5-inch floppy disk drives (the dimension refers to the diameter of the floppy disk, not the size of the drive). [4] IBM always offered its magnetic disk drives for sale but did not offer them with original equipment manufacturer (OEM) terms until 1981. [5] By 1996, IBM had stopped making hard disk drives unique to its systems and was offering all its HDDs as an OEM. [6] [7]
IBM uses many terms to describe its various magnetic disk drives, such as direct-access storage device (DASD), [lower-alpha 1] disk file and diskette file. Here, the current industry standard terms, hard disk drive (HDD) and floppy disk drive (FDD), are used.
The IBM 350 disk storage unit, the first disk drive, was announced by IBM as a component of the IBM 305 RAMAC computer system on September 14, 1956. [8] [9] [10] [11] Simultaneously a very similar product, the IBM 355, was announced for the IBM 650 RAMAC computer system. RAMAC stood for "Random Access Method of Accounting and Control". The first engineering prototype 350 disk storage shipped to Zellerbach Paper Company, San Francisco, in June 1956, [12] with production shipment beginning in November 1957 with the shipment of a unit to United Airlines in Denver, Colorado. [13]
Its design was motivated by the need for real time accounting in business. [14] The 350 stores 5 million 6-bit characters (3.75 MB). [15] It has fifty-two 24- inch (610 mm ) diameter disks of which 100 recording surfaces are used, omitting the top surface of the top disk and the bottom surface of the bottom disk. Each surface has 100 tracks. The disks spin at 1200 rpm. Data transfer rate is 8,800 characters per second. An access mechanism moves a pair of heads up and down to select a disk pair (one down surface and one up surface) and in and out to select a recording track of a surface pair. Several improved models were added in the 1950s. The IBM RAMAC 305 system with 350 disk storage leased for $3,200 per month. The 350 was officially withdrawn in 1969.
U.S. patent 3,503,060 from the RAMAC program is generally considered to be the fundamental patent for disk drives. [16] This first-ever disk drive was initially cancelled by the IBM Board of Directors because of its threat to the IBM punch card business but the IBM San Jose laboratory continued development until the project was approved by IBM's president. [17]
The 350's cabinet is 60 inches (150 cm) long, 68 inches (170 cm) high and 29 inches (74 cm) wide.
The RAMAC unit weighs about one ton, has to be moved around with forklifts, and was frequently transported via large cargo airplanes. [18] According to Currie Munce, research vice president for Hitachi Global Storage Technologies (which acquired IBM's storage business), the storage capacity of the drive could have been increased beyond five million characters, but IBM's marketing department at that time was against a larger capacity drive, because they didn't know how to sell a product with more storage. Nonetheless, double capacity versions of the 350 were announced [8] in January 1959 and shipped later the same year.
In 1984, the RAMAC 350 Disk File was designated an International Historic Landmark by The American Society of Mechanical Engineers. [19] In 2002 at the Magnetic Disk Heritage Center, a team [20] led by Al Hoagland began restoration of an IBM 350 RAMAC in collaboration with Santa Clara University. [21] In 2005, the RAMAC restoration project relocated to the Computer History Museum, Mountain View, California and is now demonstrated to the public in the museum's Revolution exhibition. [22]
The IBM 353, used on the IBM 7030, was similar to the IBM 1301, but with a faster transfer rate. It has a capacity of 2,097,152 (221) 64-bit words or 134,217,728 (227) bits and transferred 125,000 words per second. [23] A prototype unit shipped in late 1960 was the first disk drive to use one head per surface flying on a layer of compressed air as in the older head design of the IBM 350 disk storage (RAMAC). Production 353s used self-flying heads essentially the same as those of the 1301.
The IBM 355 was announced on September 14, 1956, as an addition to the popular IBM 650. [24] It used the mechanism of the IBM 350 with up to three access arms [lower-alpha 2] and stored 6 million decimal digits and 600,000 signs. [24] It transferred a full track to and from the magnetic core memory of the 653, an IBM 650 option that included just sixty signed 10-digit words, enough for a single track of disk or a tape record, along with two unrelated features.
The IBM 1405 Disk Storage Unit was announced in 1961 and was designed for use with the IBM 1400 series, medium scale business computers. [25] The 1405 Model 1 has a storage capacity of 10 million alphanumeric characters (60,000,000 bits) on 25 disks. Model 2 has a storage capacity of 20 million alphanumeric characters (120,000,000 bits) on 50 disks. In both models the disks are stacked vertically on a shaft rotating at 1200 rpm.
Each side of each disk has 200 tracks divided into five sectors. Sectors 0–4 are on the top surface and 5–9 are on the bottom surface. Each sector holds either 178 or 200 characters. One to three forked-shaped access arms each contains two read/write heads, one for the top of the disk and the other for the bottom of the same disk. The access arms are mounted on a carriage alongside the disk array. During a seek operation an access arm moved, under electronic control, vertically to seek a disk 0–49 and then horizontally to seek a track 0–199. Ten sectors are available at each track. It takes about 10 ms to read or write a sector.
The access time ranges from 100ms to a maximum access time for model 2 of 800ms and 700ms for model 1. The 1405 model 2 disk storage unit has 100,000 sectors containing either 200 characters in move mode or 178 characters in load mode, which adds a word mark bit to each character. The Model 1 contains 50,000 sectors. [26]
The IBM 7300 Disk Storage Unit was designed for use with the IBM 7070; IBM announced a model 2 in 1959, but when IBM announced the 1301 on June 5, 1961, 7070 and 7074 customers found it to be more attractive than the 7300. The 7300 uses the same technology as the IBM 350, IBM 355 and IBM 1405
The IBM 1301 Disk Storage Unit was announced on June 2, 1961 [27] [28] with two models. It was designed for use with the IBM 7000 series mainframe computers and the IBM 1410. The 1301 stores 28 million characters (168,000,000 bits) per module (25 million characters with the 1410). Each module has 25 large disks and 40 [lower-alpha 3] user recording surfaces, with 250 tracks per surface. The 1301 Model 1 has one module, the Model 2 has two modules, stacked vertically. The disks spin at 1800 rpm. Data is transferred at 90,000 characters per second.
A major advance over the IBM 350 and IBM 1405 is the use of a separate arm and head for each recording surface, with all the arms moving in and out together like a big comb. This eliminates the time needed for the arm to pull the head out of one disk and move up or down to a new disk. Seeking the desired track is also faster since, with the new design, the head will usually be somewhere in the middle of the disk, not starting on the outer edge. Maximum access time is reduced to 180 milliseconds.
The 1301 is the first disk drive to use heads that are aerodynamically designed to fly over the surface of the disk on a thin layer of air. [3] This allows them to be much closer to the recording surface, which greatly improves performance.
The 1301 connects to the computer via the IBM 7631 File Control. Different models of the 7631 allow the 1301 to be used with a 1410 or 7000 series computer, or shared between two such computers. [29]
The IBM 1301 Model 1 leased for $2,100 per month or could be purchased for $115,500. Prices for the Model 2 were $3,500 per month or $185,000 to purchase. The IBM 7631 controller cost an additional $1,185 per month or $56,000 to purchase. All models were withdrawn in 1970. [27]
The IBM 1302 Disk Storage Unit was introduced in September 1963. [30] Improved recording quadrupled its capacity over that of the 1301, to 117 million 6-bit characters per module. Average access time is 165 ms and data can be transferred at 180 K characters/second, more than double the speed of the 1301. There are two access mechanisms per module, one for the inner 250 cylinders and the other for the outer 250 cylinders. [31] As with the 1301, there is a Model 2 which doubles the capacity by stacking two modules. The IBM 1302 Model 1 leased for $5,600 per month or could be purchased for $252,000. Prices for the Model 2 were $7,900 per month or $355,500 to purchase. The IBM 7631 controller cost an additional $1,185 per month or $56,000 to purchase. The 1302 was withdrawn in February 1965.
The IBM 1311 Disk Storage Drive was announced on October 11, 1962, and was designed for use with several medium-scale business and scientific computers. [32] The 1311 is about the size and shape of a top-loading washing machine and stores 2 million characters (12,000,000 bits) (or, in so-called "Load Mode" on an IBM 1401, a sector can hold 90 7-bit characters, or 12,600,000 bits total [33] ) on a removable IBM 1316 disk pack. [34] Seven models of the 1311 were introduced during the 1960s. They were withdrawn during the early 1970s.
Each IBM 1316 Disk Pack is 4 inches (100 mm) high, weighs 10 pounds (4.5 kg) and contains six 14-inch (360 mm) diameter disks, yielding 10 recording surfaces (the outer surfaces are not used). The 10 individual read/write heads are mounted on a common actuator within the disk drive which moves in and out hydraulically and is mechanically detented at the desired track before reading or writing occurs. The disks spin at 1500 rpm. Each recording surface has 100 tracks with 20 sectors per track. Each sector stores 100 characters. The disk pack is covered with a clear plastic shell and a bottom cover when not in use. A lifting handle in the top center of the cover is rotated to release the bottom cover. Then the top of the 1311 drive is opened and the plastic shell lowered into the disk-drive opening (assuming it is empty). The handle is turned again to lock the disks in place and release the plastic shell, which is then removed and the drive cover closed. The process is reversed to remove a disk pack. The same methods are used for many later disk packs.
There are seven models of the 1311 disk drive. The first drive attached to a system is a "master drive" which contains the controller and can control a number of Model 2 "slave drives." [34]
The optional special features are:
The master drives, Models 1, 3, 4, and 5, which contain extra power supplies and the control logic, are about a foot wider than the Model 2 slave drive.
The IBM 2302 is the System/360 version of the 1302, with track formatting in accordance with S/360 DASD architecture rather than 7000 series architecture.
It uses a non-removable module of 25 platters, of which 46 surfaces are used for recording. The 2302 Model 3 contains one module and the Model 4 two. There are two independent access mechanisms per module, one for the innermost 250 cylinders, and one for the outermost 250, tracks available to each access mechanism are called an access group. The access mechanism provides one read/write head per track. Average rotational delay is 17 milliseconds (msec), and maximum is 34 msec. Maximum seek time per access group is 180 msec. The track size is 4985 bytes; with formatting information and alternate tracks, module capacity is stated as 112 MB. The 2302 attaches to IBM mainframes via a IBM 2841 Storage Control Unit. [36]
The IBM 2305 fixed head storage (a fixed-head disk drive sometimes incorrectly called a drum) and associated IBM 2835 Storage Control [37] were announced in 1970, [38] initially to connect to the 360/85 and 360/195 using the IBM 2880 Block Multiplexor Channel.
The 2305 Drive was in much demand when the System 370 offered Virtual Storage, and these 2305s were often used for paging devices. They were used in this way on 3155, 3165, 3158, 3168, 3033, 4341, and 3081 (with special feature microcode.) The 2305 was also used for high activity small data sets such as catalogs and job queues.
The 2305-1 has a capacity of 5.4 MB and runs at 3.0 MB/second when attached using the 2-byte channel interface. Average access time is 2.5 ms. The larger 2305-2 has a capacity of 11.2 MB and runs at 1.5 MB/second with an average access time of 5 ms. [38]
The 2305 provides large-scale IBM computers with fast, continuous access to small-sized quantities of information. Its capacity and high data rate make it ideal for some systems residence functions, work files, job queues, indices and data sets that are used repeatedly. [38] Its fast response time makes it attractive as a paging device in a heavily loaded systems, where there are 1.5 or more transactions per second. [39]
The IBM 2311 Disk Storage Drive was introduced with the 2841 Control Unit in 1964 for use throughout the IBM System/360; the combination was also available on the IBM 1130 and the IBM 1800. The drive also directly attaches to the IBM System/360 Model 20 and the IBM System/360 Model 25. All drives used the IBM 1316 Disk Pack introduced with the IBM 1311.
The 2311 Model 1 attaches to most IBM mainframes through a 2841 Control Unit; it attaches to the System/360 Model 25 thru a Disk Attachment Control which provides the function of the control unit. Disk packs are written in these attachments in IBM's count key data variable record length format.
The 2311 models 11 or 12 are used when attached to an integrated control of the System/360 Model 20 and the disk packs are written with a fixed sector format. The disk packs are not interchangeable between those written on the Model 1 and those written on the Models 11 or 12.
The 2311 mechanism is largely identical to the 1311, but recording improvements allow higher data density. The 2311 stores 7.25 megabytes on a single removable IBM 1316 disk pack (the same type used on the IBM 1311) consisting of six platters that rotate as a single unit. The 2311 has ten individual read/write (R/W) heads mounted on a common actuator which moves in and out hydraulically and is mechanically detented at the desired track before reading or writing occurred. Each recording surface has 200 tracks plus three optional tracks which can be used as alternatives in case faulty tracks are discovered. Average seek time is 85 ms. Data transfer rate is 156 kB/s.
Because the 2311 was to be used with a wide variety of computers within the 360 product line, its electrical interconnection was standardized. This created an opportunity for other manufacturers to sell plug compatible disk drives for use with IBM computers and an entire industry was born.
The IBM 2314 Disk Access Storage Facility Model 1 was introduced on April 22, 1965, one year after the System/360 introduction. [40] It was used with the System/360 and the System/370 lines. With the Two Channel Switch feature it could interface with two 360/370 channels. The 2314 Disk access mechanism was similar to the 2311, but further recording improvements allowed higher data density. The 2314 stored 29,176,000 characters (200×20×7294 bytes per track) on a single removable IBM 2316 disk pack which was similar in design to the 1316 but was taller as a result of increasing the number of disks from six to eleven. The 2316 disk pack containing the eleven 14-inch (360 mm) diameter disks yielded 20 recording surfaces. The drive access consisted of 20 individual R/W heads mounted on a common actuator which was moved in and out hydraulically and mechanically detented at the desired track before reading or writing occurred. Each recording surface has 200 tracks. Access time was initially the same as the 2311, but later models were faster as a result of improvements made in the hydraulic actuator. Data transfer rate was doubled to 310 kB/s.
The original Model 1 consists nine disk drives bundled together with one price; separately shipped was a storage control unit, a single drive module, and two four drive modules for a total of nine drives. The drives are mounted in individual drawers that are unlatched and pulled out to access the disk pack. Because of their appearance they acquired the nickname of "Pizza Ovens". Only eight drives of the nine are available to the computer at any one time. The ninth drive is there for a spare for the user and can also be worked on "offline" by a Field Engineer while the other drives are in use by the customer. Each drive's system address is determined in part by a user-swappable plug, one such plug denoting a spare drive not system accessible. This permits physically changing the address of a drive by changing the plug.
A 2844 Control Unit can be added to the 2314 Control Unit which allows two S/360 Channels simultaneous access to two separate disk drives in the Storage Facility.
Other 2314 models came later:
In 1969 IBM unbundled the facility into separate models allowing up to nine drives (eight on line) attached to a 2314 Storage Control:
IBM introduced the IBM 3310 Direct Access Storage Device on January 30, 1979, for IBM 4331 midrange computers. [41] Each drive had a capacity of 64.5 MB. The 3310 was a fixed-block architecture device, used on DOS/VSE and VM, the only S/370 operating systems that supported FBA devices.
The IBM 3330 Direct Access Storage Facility, code-named Merlin, was introduced in June 1970 for use with the IBM System/370 and the IBM System 360/195. The original announcement included the 3330 Model 1, with two drives, and the 3330 Model 2, with only one drive. The 3330 has removable disk packs, similar to its predecessors, and the packs hold 100 MB (404×19×13,030 bytes). Access time is 30 ms and data transfers at 806 kB/s. A major advance introduced with the 3330 is the use of error correction, which makes the drives more reliable and reduces costs because small imperfections in the disk surface can be tolerated. The circuitry can correct error bursts up to 11 bits long through use of fire codes.
The initial configuration consists of one storage control unit (3830 Model 1) bolted to a 3330, with optionally three more 3330's bolted together. This is known as a string, making a maximum of eight drives in a string.
In August 1972 IBM announced the 3830 Model 2 Storage Control and the 3333 Disk Storage and Control, separating the control unit from the string. The 3830 became a director type of storage control, controlling one or more strings. The now first unit of the string, the 3333 contains a controller and two drives and it can control up to three attached 3330's for a maximum of eight drives in the string as shown in the illustration. The 3830 Model 2 can connect two 3333's for a maximum of 16 drives per storage control and the 3333 optionally has a string switch that enables it to be connected to two different storage controls.
In 1973 IBM announced double density versions (-11 models) of the 3330 product line: the 3333–11, 3330-11 and the 3336–11; the 3336-11 Disk Packs hold up to 200 MB (808x19x13,030 bytes). It is not possible to mix single and double density drives within a string. It is possible to field upgrade existing 3330 Models to Model 11, but this is a major task, as the drives had to be converted, and all the existing data had to be copied to the new media.
The 3330 was withdrawn in 1983. [42]
The IBM 3340 and 3344 have similar characteristics. However, only a 3340 can serve as head of string; there are no A model 3344 drives, and a 3344 must be attached to a 3340 A model as head of string.
The IBM 3340 Direct Access Storage Facility, code-named Winchester, was introduced in March 1973 for use with IBM System/370. [43] Three models were announced, the 3340-A2 with two drives and a controller, the models B2 (two drives) and B1 (one drive). B-units can connect to the model A2 to a maximum of eight drives.
It uses removable data modules that included the head and arm assembly; an access door of the data module opens or closes during a mechanical load/unload process to connect the data module to the drive; unlike previous disk packs and cartridges there is no cover to remove during the insertion process. Access time is 25 millisecond and data transfers at 885 kB/s. Three versions of the removable IBM 3348 Data Module were sold, one with 35 megabyte capacity, another with 70 megabytes, the third also has 70 megabytes, of which 500 kilobytes were accessible with fixed heads for faster access. The 3340 also uses error correction. It was withdrawn in 1984.
The 3340 was developed in San Jose under the leadership of Ken Haughton. Early on the design was focused on two removable 30 megabyte modules. Because of this 30/30 configuration, the code name Winchester was selected after the famous Winchester .30-30 rifle; [44] subsequently the capacities were increased, but the code name stuck.
One significant aspect of this product, and the reason that disk drives in general became known as "Winchester technology", was that this head design was very low cost and did not require the heads to be unloaded from the media. Winchester technology allowed the head to land and take off from the disk media as the disk spun up and down. This resulted in very significant savings and a large reduction of complexity of the head and arm actuating mechanism. This head design rapidly became a standard design within the disk drive manufacturing community.
Up into the early 1990s the term Winchester or Winnie was used for hard disk drives in general long after the introduction of the 3340, but is no longer in common use in most parts of the world.
The IBM 3344 is similar to the 3340, except that it uses fixed media rather than removable 3348 data modules, each spindle has four logical drives each with the capacity of a 3348–70, there is no A (head of string) model and it is only available in dual drive models. The 3344-B2F is identical to the 3344-B2 except that both drives have fixed heads over some cylinders. Both 3344-B2 and 3344-B2F require a 3340-A2 or 3340-A2F as head of string. Inside, the 3344 is exactly the same as IBM 3350, the difference is only in the microcode in the control unit.
The IBM 3350 Direct Access Storage Facility, code-named Madrid, was introduced in 1975 for use with IBM System/370. [45] Its non-removable head-disk assemblies (HDAs) are sealed and included the head and arm assembly. The 3350 disk geometry is 555 cylinders, 30 heads, and 19,069 bytes per track, which give each HDA a storage capacity of 317,498,850 bytes. Sealed HDAs were standard practice on all IBM DASD hereafter.
Disk units are identified as Models A2, A2F, B2, B2F, C2, and C2F with each model containing two HDAs. Model A2 and A2F has one additional electronic board, allowing it to be connected to the control unit. They are referred to as controllers, and also sometimes head-of-string. The models are installed in strings of units with an A2 or A2F unit, and then up to three B2 units or up to two B2s and a C2. The A2 unit usually has a string switch, allowing it to be connected to two different storage control units. This allows two I/O operations simultaneously take place to two different HDAs in the string. The storage control unit can be a 3830 Model 2, or the ISC (Integrated Storage Control) found in the 3148, 3158 or 3168 cpu's. Also later control units (3880) are backwards compatible and can be used. The C2s unit also contains a controller, that can be connected to a storage control unit and serves as a secondary path to itself and the A2 and B2 units. The C2 controller is a spare, it can only be used when the controller in the A unit is broken, and subsequently powered off. It has also limited connections, usually the A unit has a string switch, but the C unit only can be connected to one storage control unit. The valid 3350 strings are: -A, -AB, -ABB, -ABBB, -AC-, -ABC-, or -ABBC- configurations.
The "x2F", as in Model A2F, unit is a normal x2 unit, but its two HDAs also have a Fixed Head area over the first five cylinders, thereby reducing [lower-alpha 4] seek time to zero for these five cylinders. This fixed head area is intended to be allocated to the frequently accessed HASP or JES2 checkpoint area and thus greatly reduce head motion on the SPOOL device. The fixed head area can also be utilized for TSO swap data (MVT and SVS) and system swap data (MVS) wherein the swap data for SVS and MVS consist of blocks of pages that have been in memory when an address space is selected for swap-out; those pages need not be contiguous and in general do not include pages that have not been modified since their last page-in. This system architecture greatly improves context switches between TSO users or batch regions.
The IBM 3350 family was withdrawn in September 1994.
IBM introduced the IBM 3370 Direct Access Storage Device in January 1979 for IBM 4331, 4341, and System/38 midrange computers. [46] It has seven fixed 14-inch (360 mm) disks, and each unit has a capacity of 571 MB. It was the first HDD to use thin-film head technology; research on that technology started at Thomas J. Watson Research Center in the late 1960s. [46] The 3370 was a fixed-block architecture device, used on DOS/VSE and VM, the only S/370 operating systems that supported FBA devices.
The sister unit was called the IBM 3375 and used count key data architecture, which was required for OS/360 and successor operating systems.
The IBM 3380 Direct Access Storage Device was introduced in June 1980. [47] It uses film head technology and has a unit capacity of 2.52 gigabytes (two hard disk assemblies each with two independent actuators each accessing 630 MB within one 3380 unit) with a data transfer rate of 3 megabytes per second. Average access time was 16 ms. Purchase price at time of introduction ranged from $81,000 to $142,200. Due to tribology problems encountered between heads and media, the first units did not ship until October 1981. [47]
Similar to its predecessor (3350) the standard configuration is one A unit and up to three B units, but because each 3380 contains four devices each string now can contain up to 16 devices. Usually it is connected to a 3880 storage control units with two paths, allowing two simultaneous I/O operations, however, the operations must target different HDAs.
In February 1985, IBM announced a double density version – the Extended Capability Models of the 3380 (3380 E) having 5.04 gigabytes per 3380 unit, that is, two 1.26 gigabyte actuators on two hard disk assemblies.
A triple capacity version, the 3380 K was announced in August 1987 having 7.562 gigabytes per 3380 unit, that is, two 1.89 gigabyte actuators on two hard disk assemblies. The new Model K and Model J can optionally run in four-path mode. In this mode, the string has two A units located in the middle, and up to three B units connected on each side, giving a maximum of 32 devices in a string. This requires they are connected to a 3990 storage control unit, and allows four simultaneous I/O operation in the string.
There are twelve models of the IBM 3380 family: six A-units, five B-units and one C-unit. A-units (heads of string) contain additional logic to perform string controller functions and connect to IBM storage control units (3880 or 3990). The C-units connect directly to an IBM channel. B-units connects to A-units or C-units.
The last models were withdrawn by IBM in May 1996 representing a production run of 15 years; a run longer than most disk drives [48]
The IBM 3390 Direct Access Storage Device series was introduced November 1989, offering a maximum storage of up to 22 gigabytes in a string of multiple drives. [49] Cost of a storage system varied by configuration and capacity, between $90,000 and $795,000.
A 3390 string consists of an A unit placed in the middle, and optionally one or two B units bolted to its sides. The A unit can have four or eight devices, each B unit can have up to 12 devices. The 3390 is always running in four-path mode, connected to a 3990 storage control unit. Optionally the 3990 can have a second 3390 string attached, giving a maximum of 64 devices in the subsystem.
Packaged in Hard Disk Assemblies with two actuator-head units and one set of platters, a model 1 HDA provides 1.89 GB before formatting and a model 2 provides 3.78 GB/HDA. The Model 3 enhancement to the drive family, announced September 11, 1991, increased capacity 1.5 times to 5.67 GB/HDA and the Model 9, announced May 20, 1993, further increased capacity 3 times to 11.3 GB/HDA. [50] [51]
All the preceding DASD models are equipped with a large AC motor, driving the HDA with a belt; however, the 3390 HDA is directly driven by a DC motor that is included in the enclosure.
The 3390 Model 9 was the last Single Large Expensive Disk (sometimes called SLEDs) drive announced by IBM.
The IBM 9345 HDD first shipped in Nov 1990 as an RPQ on IBMs SCSE (SuperComputing Systems Extensions). Developed at IBM's San Jose, California laboratory under the code name Sawmill. It was an up to 1.5 GB full height 51⁄4-inch HDD using up to 8 130 mm disks. It was the first HDD to use MR (Magneto Resistive) heads. [52]
In October 1991 the 9345 DASD was announced as part of the IBM 9340 channel-attached, count key data (CKD) DASD subsystem family which attached to IBM mainframes including the ES/9000 processor family. [53] The 9345 DASD Model 1 had two 1.0 GB HDDs while the Model 2 had two 1.5 GB HDDs.
For most practical applications, the 9340/9345 was functionally equivalent to a 3990/3390, although without non-volatile RAM cache of the 3990 and with a somewhat shorter maximum block length than the 3390.
The OS's IOS component learned of this device's characteristics through a special initializer, IECCINIT, which also serviced other DASD device types, and for the same purpose. It was at initialization-time that the OS learned that the 9340 has no non-volatile cache and the 9345 has a shorter than expected track capacity. The initializer, therefore, assigned a different device type than the 3990/3390.
The IBM 2310 Removable Cartridge Drive was announced in 1964 with the IBM 1800, [60] and then in 1965 with the IBM 1130; it likely first shipped with the 1130 in late 1965. [61] It could store 512,000 16-bit words (1,024,000 bytes) on an IBM 2315 cartridge. A single 14-inch (360 mm) oxide-coated aluminum disk spun in a plastic shell with openings for the read/write arm and two heads.
The IBM 5444 was announced September 1969 as part of System/3. Developed at IBM's Hursley, England, laboratory under code name Dolphin [57] it used the 5440 disk cartridge. The cartridge in turn contained one 14-inch disk. There were three models: [62]
The 62GV first shipped in May 1974. Developed at IBM's Hursley, UK, laboratory under the code name Gulliver with an initial capacity of 5 MB. Subsequent models have 10 MB (62TM) and 14 MB capacities. It used a Swinging Arm actuator with one 14-inch disk. The simple design of the actuator, [63] invented at IBM's UK Hursley Labs, became IBM's most licensed electro-mechanical invention [64] of all time, the actuator and filtration system being adopted in the 1980s eventually for all HDDs, and still universal nearly 40 years and 10 Billion arms later. During its production life the IBM 62GV shipped 177,000 units making it the first HDD known to have shipped in excess of 100,000 units. [57]
This section lists IBM manufactured HDDs offered both as an OEM product and for attachment to IBMs small systems such as the System/3, System/32, /34 and /36 and the AS/400. HDDs are identified by their OEM model number and listed chronologically by date of first customer shipment.
The 0680 first shipped in 1979 on most IBM small systems [65] and the low end of the System/370 as the 3310 direct access storage. [41] The OEM version was announced as the 0680 in September 1981. [5] Developed at IBM's Hursley, UK, laboratory under the code name Piccolo with an initial capacity of up to 65MB, it used six 8-inch disks (210 mm) and had an improved rotary actuator. [66] [57]
A double capacity version, the 62SW, shipped in June 1984 but very few units were sold because its price per megabyte was the same as the 62GV. [57]
The 0676 first shipped in November 1982 as a 5247 Disk Storage Unit for the IBM System/23 Datamaster. [67] Developed at the IBM Rochester, Minnesota, laboratory as the 21ED it was an 8-inch HDD with an initial capacity of 15 or 30 MB in two or foue 210 mm disks. In 1983 it shipped as the HDD in the 5360 System Unit of the S/36. In 1984 its capacity was doubled by doubling the number of tracks per surface and it was incorporated into the 5362 System Unit of the System/36. [68]
The 0665 first shipped in October 1985 in the system unit for the PC AT (5170). [69] Developed under the code name "Pixie" at IBM Rochester, Minnesota, it was a 51⁄4-inch HDD with capacities of 20, 30 and 44 MB.
The 0667 first shipped in August 1986. [67] Developed at IBM Rochester, Minnesota, under the code name "Grant", it was a 70 MB ESDI full height 51⁄4-inch HDD with up to four 130 mm disks. [70] It was offered as a feature on certain models of the PC RT (6150, 6151, 6152) and in System/36 Model System Units (5363, 5364). [71]
The 0669 first shipped in 1987. [67] Developed at IBM Rochester, Minnesota, under the code name "Grant-Prime", it was a full-height 51⁄2-inch HDD with a capacity of up to 115 MB on up to four 130 mm disks. [72] It was the HDD internal to the System/36 5363 System Unit and Series 1 4956 System Unit. [72]
The 0671 first shipped in 1987. [67] Developed under the code name "Lee" at IBM Rochester, Minnesota, it was an up to 316 MB ESDI full height 51⁄4-inch HDD with up to eight 130 mm disks depending upon model. [72] This was IBM's first usage of a thin metal film as the disk's recording surface. [72] In 1988 it shipped as part of the 9404 System Unit of the IBM AS/400 system which contained two, or optionally three of these HDDs. [73]
The 0661 first shipped in 1989 as the model 371. [74] Developed initially under the code name "Lightning" at IBM Rochester Minnesota (and IBM Hursley, UK) as a 320 MB SCSI HDD with up to eight 95 mm disks (14 heads), it was followed in 1990 with a 400 MB version, code named "Turbo". During 1990 it was added as a standard drive on several major IBM systems, [74] e.g., IBM AS/400 System Unit Model CXX. [75]
The 0681 first shipped in April 1990. Developed at IBM's Hursley, UK, laboratory under the code name Redwing, it was the last HDD product developed at Hursley. [76] It was an up to 857 MB full-height 51⁄4-inch HDD using up to 12 130 mm disks. It was the first HDD to use PRML decoding of data. [3] It was the drive component of the 9333 Disk Drive Subsystem which first shipped in early 1992.
A higher density, 1.07 GB, version was incorporated into the 9333 subsystem in May 1992. [77]
The 0663 first shipped in late 1991. Developed under the code name "Corsair", it was a 31⁄2-inch HDD with the height of a 51⁄2-inch half-height device (1.6-inch high) and up to 1 GB on up to 8 95 mm disks. [78] [79] It was offered as a feature on certain models of the PS/2 and RS/6000. [79] It was the first OEM disk drive to use MR Heads. [3]
The 0664 first shipped in November 1992. Developed under the code name "Allicat" at IBM Rochester, Minnesota, it was a full-height 51⁄2-inch HDD (3.25-inch high) that combined two 31⁄2-inch devices in one, with up to 2.013 GB capacity on up to 8 95 mm disks. [80] [81]
The 0662 first shipped in June 1993. Developed under the code name "Spitfire" at IBM Rochester, Minnesota, it was a full-height (1-inch high) 31⁄2-inch HDD with 1.05 GB on three disks or five disk surfaces. [81] [82] [83] It was the HDD internal to the 9336 Disk Unit and the 9337 Disk Array. [81]
Another important IBM innovation is the floppy disk drive. IBM first introduced the 8-inch FDD in 1971 as a read only program load device. In 1973 IBM shipped its first read/write floppy disk drive as a part of the 3740 Data Entry System. IBM established early standards in 8" FDDs but never sold such products separately so that the industry then developed separate from IBM.
IBM was at one point was the world's largest purchaser of OEM 51⁄4-inch FDDs; its selection of the two-sided, 48 tracks-per-inch model helped establish the model as the de facto industry standard. IBM made extensive preparations to manufacture such models and smaller form factors but cancelled all such efforts in 1985. [84] IBM's 1983 attempt to OEM its 4-inch DemiDisk failed. [85]
On October 17, 1994, IBM's Storage Systems division announced three new families of hard disk drives, the Travelstar 21⁄2-inch family for notebooks, the Deskstar 31⁄2-inch family for desktop applications and the Ultrastar 31⁄2-inch family for high performance computer system applications. [7]
The following table compares IBM's first HDD, the RAMAC 350, with the last three models it manufactured in each of its "Star" series of OEM HDDs. It illustrates HDD's spectacular decline in cost and size along with corresponding improvement in capacity and performance.
Parameter (units) | RAMAC 350 [8] | Ultrastar 146Z10 [86] [87] | Deskstar 180GXP [88] [89] | Travelstar 80GN [90] [91] | 46-year improvement (maximum) |
---|---|---|---|---|---|
Announced | Sep 1956 | Jul 2002 | Oct 2002 | Nov 2002 | |
Capacity (gigabytes) | 0.004 | 146 | 180 | 80 | 48,000 |
Dimensions (inches) | 60×68×29 | 4×1×5.75 | 4×1×5.75 | 2.75×0.38×3.95 | |
Dimensions (mm) | 1500×1700×700 | 102×25×146 | 102×25×146 | 70×9.5×100 | |
Volume (in³) | 118,320 | 23 | 23 | 4 | 29,161 |
Volume (litres) | 1,939 | 0.4 | 0.4 | 0.1 | |
Weight (lbs) | 2,140 | 1.7 | 1.4 | 0.2 | 1,244 |
Weight (kg) | 971 | 0.8 | 0.64 | 0.095 | |
Power (watts) | 8100 BTUs/hour (i.e., 2374 watts), [92] up to 5500 VA depending upon model [93] | 16 | 10.3 | 1.85 | 1,283 |
Power density (megabytes/watt) | 0.0016 | 9,125 | 17,476 | 43,243 | 27,375,856 |
List price (US$) | $34,500 [94] ($234,000 in 2002 dollars) [95] | 1200 | 360 | 420 | |
Price/megabyte (US$) | $9,200 ($68,000 in 2002 dollars) | 0.0082 | 0.0020 | 0.0053 | 4,600,000 (34,000,000 in 2002 dollars) |
Density (megabits/in²) | 0.002 | 26,263 | 46,300 | 70,000 | 35,000,000 |
Density (kilobits/mm²) | 0.003 | 40,708 | 71,765 | 108,500 | |
Volume density (gigabytes/in³) | 0.00000003 | 6 | 8 | 20 | 622,100,131 |
Volume density (megabytes/cm³) | 0.000002 | 388 | 478 | 1,203 | |
Latency (ms) | 25 | 3 | 4 | 7 | 8 |
Average seek time (ms) | 600 | 5.9 | 10.2 | 12 | 102 |
Data rate (megabytes/s) | 0.001 | 103 | 29.4 | 43.75 | 11,719 |
IBM in some of its operating systems classifies HDDs and FDDs as DASDs, direct access storage devices. Other technologies so classified include:
The IBM 7320 is a magnetic-drum storage unit announced in 1962.
The IBM 2301 is a magnetic-drum storage device introduced in the late 1960s
The IBM 2303 is a magnetic-drum storage device introduced in 1964.
The IBM 2321 Data Cell announced in 1964 is a device that uses short strips of magnetic tape to store data. It holds 10 40 MB removable cells, for a total capacity of 400 MB.
The IBM 3850 Mass Storage System , announced in 1974, is a library system of tape cartridges that staged data from the cartridges onto physical IBM 3330 or 3350 disk drives which then appeared to the system as virtual 3330 drives.
Disk storage is a data storage mechanism based on a rotating disk. The recording employs various electronic, magnetic, optical, or mechanical changes to the disk's surface layer. A disk drive is a device implementing such a storage mechanism. Notable types are hard disk drives (HDD), containing one or more non-removable rigid platters; the floppy disk drive (FDD) and its removable floppy disk; and various optical disc drives (ODD) and associated optical disc media.
A hard disk drive (HDD), hard disk, hard drive, or fixed disk is an electro-mechanical data storage device that stores and retrieves digital data using magnetic storage with one or more rigid rapidly rotating platters coated with magnetic material. The platters are paired with magnetic heads, usually arranged on a moving actuator arm, which read and write data to the platter surfaces. Data is accessed in a random-access manner, meaning that individual blocks of data can be stored and retrieved in any order. HDDs are a type of non-volatile storage, retaining stored data when powered off. Modern HDDs are typically in the form of a small rectangular box.
The ST-506 and ST-412 were early hard disk drive products introduced by Seagate in 1980 and 1981 respectively, that later became construed as hard disk drive interfaces: the ST-506 disk interface and the ST-412 disk interface. Compared to the ST-506 precursor, the ST-412 implemented a refinement to the seek speed, and increased the drive capacity from 5 MB to 10 MB, but was otherwise highly similar.
The Jaz drive is a removable hard disk storage system sold by the Iomega company from 1995 to 2002.
Density is a measure of the quantity of information bits that can be stored on a given physical space of a computer storage medium. There are three types of density: length of track, area of the surface, or in a given volume.
The IBM 3850 Mass Storage System (MSS) was an online tape library used to hold large amounts of infrequently accessed data. It was one of the earliest examples of nearline storage.
The Microdrive is a type of miniature, 1-inch hard disk produced by IBM and Hitachi. These rotational media storage devices were designed to fit in CompactFlash (CF) Type II slots.
In 1953, IBM recognized the immediate application for what it termed a "Random Access File" having high capacity and rapid random access at a relatively low cost. After considering technologies such as wire matrices, rod arrays, drums, drum arrays, etc., the engineers at IBM's San Jose California laboratory invented the hard disk drive. The disk drive created a new level in the computer data hierarchy, then termed Random Access Storage but today known as secondary storage, less expensive and slower than main memory but faster and more expensive than tape drives.
In computer disk storage, a sector is a subdivision of a track on a magnetic disk or optical disc. For most disks, each sector stores a fixed amount of user-accessible data, traditionally 512 bytes for hard disk drives (HDDs), and 2048 bytes for CD-ROMs, DVD-ROMs and BD-ROMs. Newer HDDs and SSDs use 4096 byte (4 KiB) sectors, which are known as the Advanced Format (AF).
Count key data (CKD) is a direct-access storage device (DASD) data recording format introduced in 1964, by IBM with its IBM System/360 and still being emulated on IBM mainframes. It is a self-defining format with each data record represented by a Count Area that identifies the record and provides the number of bytes in an optional Key Area and an optional Data Area. This is in contrast to devices using fixed sector size or a separate format track.
This timeline of binary prefixes lists events in the history of the evolution, development, and use of units of measure that are germane to the definition of the binary prefixes by the International Electrotechnical Commission (IEC) in 1998, used primarily with units of information such as the bit and the byte.
Fixed-block architecture (FBA) is an IBM term for the hard disk drive (HDD) layout in which each addressable block on the disk has the same size, utilizing 4 byte block numbers and a new set of command codes. FBA as a term was created and used by IBM for its 3310 and 3370 HDDs beginning in 1979 to distinguish such drives as IBM transitioned away from their variable record size format used on IBM's mainframe hard disk drives beginning in 1964 with its System/360.
William A. Goddard was an American engineer and inventor. He earned a degree in physics from Occidental College. Before working in industry, Goddard was a high school science teacher in Los Angeles. He briefly worked in the aerospace industry for North American Aviation, Inc. before becoming an engineer at International Business Machines (IBM). His most acclaimed achievement is co-inventing along with John Lynott United States Patent 3,503,060, which is entitled “Direct Access Magnetic Disc Storage Device”. This invention claims cover modern-day hard disk drives.
Higher performance in hard disk drives comes from devices which have better performance characteristics. These performance characteristics can be grouped into two categories: access time and data transfer time .
Hard disk drives are accessed over one of a number of bus types, including parallel ATA, Serial ATA (SATA), SCSI, Serial Attached SCSI (SAS), and Fibre Channel. Bridge circuitry is sometimes used to connect hard disk drives to buses with which they cannot communicate natively, such as IEEE 1394, USB, SCSI, NVMe and Thunderbolt.
John Mason "Jack" Harker was an inventor, mechanical engineer, and product and program manager who pioneered development of disk storage systems. Starting as a member of the original team that developed the first disk storage system, he went on to develop IBM Direct Access Storage products for the next 35 years. Over that time, Harker was twice director of the IBM San Jose Storage Laboratories, an IBM Fellow, and an IEEE Fellow. He retired from IBM in 1987 and died in 2013.
Beginning with its 1964 System/360 announcement, IBM's mainframes initially accessed count key data (CKD) subsystems via a channel connected to separate Storage Control Units (SCUs) with attached Direct Access Storage Devices (DASD), typically a hard disk drive. This practice continued in IBM's larger mainframes thru IBM Z; however low end systems generally used lower cost integrated attachments where the function of the SCU was combined with that of the channel, typically called an Integrated File Adapter.
In addition to the drums used as main memory by IBM, e.g., IBM 305, IBM 650, IBM offered drum devices as secondary storage for the 700/7000 series and System/360 series of computers.
A track is a path on a recording medium. There are some variations in nomenclature; for some media a track is a logical path and for others it is based on the geometry of the medium. The term is not used for punched cards.
... the scheduled ship date of the first field test machine slipped. In June 1956, however, the 305-A RAMAC went out to the Zellerbach Paper Company in San Francisco.
stored 5 million 6-bit characters (the equivalent of 3.75 million 8-bit bytes)
Kenneth E. Haughton, who led the 3340 development effort, is reported to have said: 'If it's a 30–30, then it must be a Winchester.'