Magnetic tape data storage
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Magnetic tape has been used for data storage for over 50 years. In this time, many advances in tape formulation, packaging, and data density have been made. The primary difference between tape data storage and disk data storage is that tape is a sequential access medium while disk is a random access medium.
There are two primary means to classify magnetic tape technologies. The first is the width of the tape medium. The most common width of tape for high capacity data storage has long been one half inch. Many other sizes exist and most were developed to either have smaller packaging or higher capacity.
The second classification is the recording method. More specifically, the difference is whether data is written linearly or by helical scan. The linear method arranges data in long parallel tracks that span the length of the tape. The helical scan method writes short curved tracks from one edge of the tape to the other.
Originally, linear recording meant the tape head spanned the whole width of the tape, writing or reading all tracks together as the tape passed over it. A variation on that technology is called Linear Serpentine recording. The linear serpentine method only records a fraction of the tracks on tape at a time. After making a pass over the whole length of the tape, the head shifts slightly and makes another pass in the reverse direction. This procedure is repeated until all tracks have been read or written. By using the linear serpentine method, the tape medium can have many more tracks than there are read/write heads. In contrast, the helical scan method only needs one pass to read or write to the entire tape.
As of 2006, magnetic tape is most commonly packaged in cartridges and cassettes and primarily serves as a high capacity archival medium useful for backups. The highest capacity tape cartridge is currently the DLT-S4. It can store 800 GB of data without using compression. Its capacity is larger than the largest hard disk (750 GB) currently on the market while its form factor is smaller.
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[edit] Open reels
Initially, magnetic tape for data storage was wound on large (10.5 in) reels. This defacto standard for large computer systems persisted though the late 1980s. Tape cartridges and cassettes were available as early as the mid 1970s and were frequently used with small computer systems. With the introduction of the IBM 3480 catridge in 1984, large computer systems started to move away from open reel tapes and towards cartridges.
[edit] UNIVAC
Magnetic tape was first used to record computer data in 1951 on the Eckert-Mauchly UNIVAC I. The UNISERVO drive recording medium was a thin metal strip of ½″ wide(12.7 mm) nickel-plated phosphor bronze. Recording density was 128 characters per inch (198 micrometre/character) on eight tracks at a linear speed of 100 in/s (2.54 m/s), yielding a data rate of 12,800 characters per second. Of the eight tracks, six were data, one was a parity track, and one was a clock, or timing track. Making allowance for the empty space between tape blocks, the actual transfer rate was around 7,200 characters per second.
[edit] IBM formats
IBM computers from the 1950s used ferrous-oxide coated tape similar to that used in audio recording. IBM's technology soon became the de facto industry standard. Magnetic tape dimensions was .5" (12.7 mm) wide and wound on removable reels of up to 10.5 inches (267 mm) in diameter. Different tape lengths were available with 1200', 2400' on mil and one half thickness being somewhat standard. Later during the 80's, longer tape lengths such as 3600' became available, but only with a much thinner Mylar plastic(TM) Most tape drives could support a maximum reel size of 10.5"
Early IBM tape drives were mechanically sophisticated floor-standing drives that used vacuum columns to buffer long u-shaped loops of tape. Between active control of powerful reel motors and vacuum control of these u-shaped tape loops, extremely rapid start and stop of the tape at the tape-to-head interface could be achieved. (1.5ms from stopped tape to full speed of up to 112.5 IPS) When active, the two tape reels thus fed tape into or pulled tape out of the vacuum columns, intermittently spinning in rapid, unsynchronized bursts resulting in visually-striking action. Stock shots of such vacuum-column tape drives in motion were widely used to represent "the computer" in movies and television.
Early half-inch tape had 7 parallel tracks of data along the length of the tape allowing six-bit characters plus parity written across the tape. This was known as 7-track tape. With the introduction of the IBM System 360, 9-track tapes became common to support 8-bit characters or "bytes." 7-track tapes used a .75 IRG (inter-record-gap) 9-track 800 NRZI and 1600 PE (Phase Encoding) tapes utilized a .60" IRG placed between data records to allow the tape to stop. 6250 GCR tapes used a very tight .3" IRG. Both 7 and 9 track tapes had reflective stickers placed near (10', 14') each end to signal beginning of tape (BOT) and end of tape (EOT) to the hardware. Effective recording density increased over time. Common 7-track densities started at 200, then 556, and finally 800 cpi. Nine-track tapes commonly had densities of 800, 1600, and 6250 cpi, giving approximately 20Mb, 40Mb and 140Mb respectively on a standard 2400' tape. Signaling EOT (end of tape) with space remaining to write trailer blocks allowed support for multivolume labelled tapes.
Standards
- ANSI INCITS 40-1993 (R2003) Unrecorded Magnetic Tape for Information Interchange (9-Track, 800 CPI, NRZI; 1600 CPI, PE; and 6250 CPI, GCR)
- ISO/IEC 1863:1990 9-track, 12.7 mm (½ in) wide magnetic tape for information interchange using NRZ1 at 32 ftpmm (800 ftpi) - 32 cpmm (800 cpi)
- ISO/IEC 3788:1990 9-track, 12.7 mm (½ in) wide magnetic tape for information interchange using phase encoding at 126 ftpmm (3 200 ftpi), 63 cpmm (1600 cpi)
- ANSI INCITS 54-1986 (R2002) Recorded Magnetic Tape for Information Interchange (6250 CPI, Group Coded Recording)
- ANSI INCITS 27-1987 (R2003) Magnetic Tape Labels and File Structure for Information Interchange
Since then, a multitude of tape formats have been used.
[edit] DEC format
LINCtape, and its derivative, DECtape, were variations on this "round tape." They were essentially a personal storage medium. The tape was ¾ inch wide and featured a fixed formatting track which, unlike standard tape, made it feasible to read and rewrite blocks repeatedly in place. LINCtapes and DECtapes had similar capacity and data transfer rate to the diskettes that displaced them, but their "seek times" were on the order of thirty seconds to a minute.
[edit] Cartridges and Cassettes
In the context of magnetic tape, the term cassette usually refers to an enclosure that holds two reels with a single span of magnetic tape. The term cartridge is more generic, but typically means a single reel of tape in a plastic enclosure. A tape drive that uses a single reel cartridge has a takeup reel in the drive while cassettes have the take up reel in the cassette. The type of packaging is a large determinant of the load and unload times as well as the length of tape that can be held.
A tape drive (or "transport" or "deck") uses precisely-controlled motors to wind the tape from one reel to the other, passing a read/write head as it does. In the 1980's compact audio cassettes were used with home computers of the 1980s, and digital audio tape was used for backup in workstations. Most modern magnetic tape systems use reels that are fixed inside a cartridge to protect the tape and facilitate handling. Modern cartridge formats include DAT/DDS, DLT and LTO with capacities in the tens to hundreds of gigabytes.
[edit] Technical details
[edit] Block layout
In a typical format, data is written to tape in blocks with inter-block gaps between them, and each block is written in a single operation with the tape running continuously during the write. However, since the rate at which data is written or read to the tape drive is not deterministic, a tape drive usually has to cope with a difference between the rate at which data goes on and off the tape and the rate at which data is supplied or demanded by its host.
Various methods have been used alone and in combination to cope with this difference. A large memory buffer can be used to queue the data. The tape drive can be stopped, backed up, and restarted. The host can assist this process by choosing appropriate block sizes to send to the tape drive. There is a complex tradeoff between block size, the size of the data buffer in the record/playback deck, the percentage of tape lost on inter-block gaps, and read/write throughput.
[edit] Access time
Tape has quite a long data latency for random accesses since the deck must wind an average of one-third the tape length to move from one arbitrary data block to another. Most tape systems attempt to alleviate the intrinsic long latency, either using indexing, where a separate lookup table is maintained which gives the physical tape location for a given data block number, or by marking blocks with a tape mark that can be detected while winding the tape at high speed.
[edit] Data compression
Most tape drives now include some kind of data compression. There are several algorithms which provide similar results: LZ (Most), IDRC (Exabyte), ALDC (IBM, QIC) and DLZ1 (DLT). The actual compression algorithms used are not the most effective known today, and better results can usually be obtained by turning off the compression built into the device and using a software compression program instead. Software compression also allows encryption to be performed after compression. (Once data has been encrypted, compression algorithms are no longer effective.) However, software compression can place high loads on processors. Future tape drive will likely incorporate hardware encryption after the compression.
[edit] Viability
Tape remains a viable alternative to disk due to its higher bit density and lower cost per bit. Tape has historically offered enough advantage in these two areas above disk storage to make it a viable product, particularly for backup. The rapid improvement in disk storage density and price, coupled with arguably less-vigorous innovation in tape storage, has reduced the market share of tape storage products.
[edit] Chronologial list of tape formats
- 1951 - UNISERVO
- 1952 - IBM 7 Track
- 1962 - LINCtape
- 1963 - DECtape
- 1964 - IBM 9 Track
- 1972 - QIC
- 1975 - KC Standard, Compact Cassette
- 1976 - DC100
- 1977 - Datassette
- 1979 - DECtapeII
- 1979 - Exatron Stringy Floppy
- 1983 - ZX Microdrive
- 1984 - Rotronics Wafadrive
- 1984 - IBM 3480
- 1984 - DLT
- 1986 - SLR
- 1987 - Exabyte Data8
- 1989 - DDS/DAT
- 1992 - Ampex DST
- 1994 - Mammoth
- 1995 - IBM 3590
- 1995 - Redwood SD-3
- 1995 - Travan
- 1996 - AIT
- 1997 - IBM 3570 MP
- 1998 - T9840
- 1999 - VXA
- 2000 - T9940
- 2000 - LTO Ultrium
- 2003 - SAIT
- 2006 - T10000
[edit] See also
| Magnetic tape data storage formats | ||
|---|---|---|
| Linear | Helical-Scan | |
| Three Quarter Inch (~19 mm) | ||
| Half Inch (12.65 mm) |
UNISERVO (1951) - IBM 7 Track (1952) - IBM 9 Track (1964) - IBM 3480 (1984) - DLT (1984) - IBM 3590 (1995) - T9840 (1998) - T9940 (2000) - LTO Ultrium (2000) - T10000 (2006) |
Redwood SD-3 (1995) - DTF (19xx) - SAIT (2003) |
| Eight Millimeter (8 mm) |
Travan (1995) - IBM 3570 MP (1997) | |
| Quarter Inch (6.35 mm) | ||
| Four Millimeter (3.8 mm) |
DDS/DAT (1989) | |
| One Eighth Inch (3.18 mm) |
KC Standard, Compact Cassette (1975) - Datassette (1977) | |
| Stringy (1.58 - 1.9 mm) |
Exatron Stringy Floppy (1979) - ZX Microdrive (1983) - Rotronics Wafadrive (1984) | |
[edit] References
[edit] ISO Standard lists
These are just lists, not the actual standards.
