Plated-wire memory

In this article we are going to address the issue of Plated-wire memory, an issue of utmost importance today. Plated-wire memory has generated great interest in various fields, from science to culture, through politics and society in general. Along these lines, we will explore the different aspects of Plated-wire memory, as well as its impact on our daily lives. We hope to shed light on this very relevant issue and offer the reader a clear and complete perspective on Plated-wire memory.

Computer memory and data storage types
General Memory cell Memory coherence Cache coherence Memory hierarchy Memory access pattern Memory map Secondary storage MOS memory floating-gate Continuous availability Areal density (computer storage) Block (data storage) Object storage Direct-attached storage Network-attached storage Storage area network Block-level storage Single-instance storage Data Structured data Unstructured data Big data Metadata Data compression Data corruption Data cleansing Data degradation Data integrity Data security Data validation Data validation and reconciliation Data recovery Storage Data cluster Directory Shared resource File sharing File system Clustered file system Distributed file system Distributed file system for cloud Distributed data store Distributed database Database Data bank Data storage Data store Data deduplication Data structure Data redundancy Replication (computing) Memory refresh Storage record Information repository Knowledge base Computer file Object file File deletion File copying Backup Core dump Hex dump Data communication Information transfer Temporary file Copy protection Digital rights management Volume (computing) Boot sector Master boot record Volume boot record Disk array Disk image Disk mirroring Disk aggregation Disk partitioning Memory segmentation Locality of reference Logical disk Storage virtualization Virtual memory Memory-mapped file Software entropy Software rot In-memory database In-memory processing Persistence (computer science) Persistent data structure RAID Non-RAID drive architectures Memory paging Bank switching Grid computing Cloud computing Cloud storage Fog computing Edge computing Dew computing Amdahl's law Moore's law Kryder's law
Volatile
RAM Hardware cache CPU cache Scratchpad memory DRAM eDRAM SDRAM SGRAM DDR GDDR LPDDR QDRSRAM EDO DRAM XDR DRAM RDRAM HBM SRAM 1T-SRAM ReRAM QRAM Content-addressable memory (CAM) Computational RAM VRAM Dual-ported RAM Video RAM (dual-ported DRAM)
Historical Williams–Kilburn tube (1946–1947) Delay-line memory (1947) Mellon optical memory (1951) Selectron tube (1952) Dekatron T-RAM (2009) Z-RAM (2002–2010)
Non-volatile
ROM Diode matrix MROM PROM EPROM EEPROM ROM cartridge Solid-state storage (SSS) Flash memory is used in: Solid-state drive (SSD) Solid-state hybrid drive (SSHD) USB flash drive IBM FlashSystem Flash Core Module Memory card Memory Stick CompactFlash PC Card MultiMediaCard SD card SIM card SmartMedia Universal Flash Storage SxS MicroP2 XQD card Programmable metallization cell
NVRAM Memistor Memristor PCM (3D XPoint) MRAM Electrochemical RAM (ECRAM) Nano-RAM CBRAM
Early-stage NVRAM FeRAM ReRAM FeFET memory
Analog recording Phonograph cylinder Phonograph record Quadruplex videotape Vision Electronic Recording Apparatus Magnetic recording Magnetic storage Magnetic tape Magnetic-tape data storage Tape drive Tape library Digital Data Storage (DDS) Videotape Videocassette Cassette tape Linear Tape-Open Betamax 8 mm video format DV MiniDV MicroMV U-matic VHS S-VHS VHS-C D-VHS Hard disk drive
Optical 3D optical data storage Optical disc LaserDisc Compact Disc Digital Audio (CDDA) CD CD Video CD-R CD-RW Video CD Super Video CD Mini CD Nintendo optical discs CD-ROM Hyper CD-ROM DVD DVD+R DVD-Video DVD card DVD-RAM MiniDVD HD DVD Blu-ray Ultra HD Blu-ray Holographic Versatile Disc WORM
In development CBRAM Racetrack memory NRAM Millipede memory ECRAM Patterned media Holographic data storage Electronic quantum holography 5D optical data storage DNA digital data storage Universal memory Time crystal Quantum memory UltraRAM
Historical Paper data storage (1725) Punched card (1725) Punched tape (1725) Plugboard Drum memory (1932) Magnetic-core memory (1949) Plated-wire memory (1957) Core rope memory (1960s) Thin-film memory (1962) Disk pack (1962) Twistor memory (~1968) Bubble memory (~1970) Floppy disk (1971)
v t e

Plated-wire memory is a variation of magnetic-core memory developed by Bell Laboratories in 1957.^[1] Its primary advantage was that it could be assembled by machine, which potentially led to lower prices than magnetic core, which was almost always assembled by hand.

Instead of threading individual ferrite cores on wires, plated-wire memory used a grid of wires coated with a thin layer of iron–nickel alloy (permalloy).^[2] The magnetic field normally stored in the ferrite core was instead stored on the wire itself. Operation was generally similar to core memory, with the wire itself acting as the data line, and the magnetic domains providing the individual bit locations defined by address (word) lines running on either side of (and perpendicular to) the data wire.

Early versions operated in a destructive read mode,^{[citation needed]} requiring a write after read to restore data. Non-destructive read mode was possible, but this required much greater uniformity of the magnetic coating.

Improvements in semiconductor RAM chips provided the higher storage densities and higher speeds needed for large-scale application such as mainframe computers, replacing previous types of memory, including both core and plated-wire memory.

Plated-wire memory has been used in a number of applications, typically in aerospace. It was used in the UNIVAC 1110 and UNIVAC 9000 series computers, the Viking program that sent landers to Mars, the Voyager space probes,^[3] a prototype guidance computer for the Minuteman-III, the Space Shuttle Main Engine controllers,^[4] the KH-9 Hexagon reconnaissance satellite,^[5] and in the Hubble Space Telescope.

References

^ U. F. Gianola (1958). "Nondestructive Memory Employing a Domain Oriented Steel Wire". J. Appl. Phys. 29 (5): 849–853. Bibcode:1958JAP....29..849G. doi:10.1063/1.1723297.
^ J. Mathias; G. Fedde (December 1969). "Plated-wire technology: A critical review". IEEE Transactions on Magnetics. 5 (4): 728–751. Bibcode:1969ITM.....5..728M. doi:10.1109/TMAG.1969.1066652.
^ Raymond L. Heacock (1980). "The Voyager Spacecraft". Proceedings of the Institution of Mechanical Engineers. 194 (1): 211–224. doi:10.1243/PIME_PROC_1980_194_026_02.
^ Tomayko, James. "Chapter Four: Computers in the Space Shuttle Avionics System". Computers in Spaceflight: The NASA Experience. NASA. Archived from the original on 13 September 2011. Retrieved 8 August 2011.
^ "The HEXAGON story". National Reconnaissance Office. 1988.

External links

technikum29.de - Description of Plated-wire memory