Manchester computers

Last updated

Replica of the Manchester Baby at the Museum of Science and Industry in Manchester SSEM Manchester museum.jpg
Replica of the Manchester Baby at the Museum of Science and Industry in Manchester

The Manchester computers were an innovative series of stored-program electronic computers developed during the 30-year period between 1947 and 1977 by a small team at the University of Manchester, under the leadership of Tom Kilburn. [1] They included the world's first stored-program computer, the world's first transistorised computer, and what was the world's fastest computer at the time of its inauguration in 1962. [2] [3] [4] [5]

Contents

The project began with two aims: to prove the practicality of the Williams tube, an early form of computer memory based on standard cathode-ray tubes (CRTs); and to construct a machine that could be used to investigate how computers might be able to assist in the solution of mathematical problems. [6] The first of the series, the Manchester Baby, ran its first program on 21 June 1948. [2] As the world's first stored-program computer, the Baby, and the Manchester Mark 1 developed from it, quickly attracted the attention of the United Kingdom government, who contracted the electrical engineering firm of Ferranti to produce a commercial version. The resulting machine, the Ferranti Mark 1, was the world's first commercially available general-purpose computer. [7]

The collaboration with Ferranti eventually led to an industrial partnership with the computer company ICL, who made use of many of the ideas developed at the university, particularly in the design of their 2900 series of computers during the 1970s. [8] [9] [10]

Manchester Baby

The Manchester Baby was designed as a test-bed for the Williams tube, an early form of computer memory, rather than as a practical computer. Work on the machine began in 1947, and on 21 June 1948 the computer successfully ran its first program, consisting of 17 instructions written to find the highest proper factor of 218 (262,144) by trying every integer from 218 − 1 downwards. The program ran for 52 minutes before producing the correct answer of 217 (131,072). [11]

The Baby was 17 feet (5.2 m) in length, 7 feet 4 inches (2.24 m) tall, and weighed almost 1  long ton. It contained 550  thermionic valves  – 300  diodes and 250  pentodes  – and had a power consumption of 3.5 kilowatts. [12] Its successful operation was reported in a letter to the journal Nature published in September 1948, [13] establishing it as the world's first stored-program computer. [14] It quickly evolved into a more practical machine, the Manchester Mark 1.

Manchester Mark 1

Development of the Manchester Mark 1 began in August 1948, with the initial aim of providing the university with a more realistic computing facility. [15] In October 1948 UK Government Chief Scientist Ben Lockspeiser was given a demonstration of the prototype, and was so impressed that he immediately initiated a government contract with the local firm of Ferranti to make a commercial version of the machine, the Ferranti Mark 1. [7]

Two versions of the Manchester Mark 1 were produced, the first of which, the Intermediary Version, was operational by April 1949. [15] The Final Specification machine, which was fully working by October 1949, [16] contained 4,050 valves and had a power consumption of 25 kilowatts. [17] Perhaps the Manchester Mark 1's most significant innovation was its incorporation of index registers, commonplace on modern computers. [18]

In June 2022 an IEEE Milestone was dedicated to the "Manchester University "Baby" Computer and its Derivatives, 1948-1951". [19]

Meg and Mercury

As a result of experience gained from the Mark 1, the developers concluded that computers would be used more in scientific roles than pure maths. They therefore embarked on the design of a new machine which would include a floating-point unit; work began in 1951. The resulting machine, which ran its first program in May 1954, was known as Meg, or the megacycle machine. It was smaller and simpler than the Mark 1, as well as quicker at solving maths problems. Ferranti produced a commercial version marketed as the Ferranti Mercury, in which the Williams tubes were replaced by the more reliable core memory. [20]

Transistor Computer

Work on building a smaller and cheaper computer began in 1952, in parallel with Meg's ongoing development. Two of Kilburn's team, Richard Grimsdale and D. C. Webb, were assigned to the task of designing and building a machine using the newly developed transistors instead of valves, which became known as the Manchester TC. [21] Initially the only devices available were germanium point-contact transistors; these were less reliable than the valves they replaced but consumed far less power. [22]

Two versions of the machine were produced. The first was the world's first transistorised computer, [23] a prototype, and became operational on 16 November 1953. [3] [24] "The 48-bit machine used 92 point-contact transistors and 550 diodes". [25] The second version was completed in April 1955. The 1955 version used 250 junction transistors, [25] 1,300 solid-state diodes, and had a power consumption of 150 watts. The machine[ clarification needed ] did however make use of valves to generate its 125 kHz clock waveforms and in the circuitry to read and write on its magnetic drum memory, so it was not the first completely transistorised computer, a distinction that went to the Harwell CADET of 1955. [26]

Problems with the reliability of early batches of transistors meant that the machine's[ clarification needed ] mean time between failures was about 90 minutes, which improved once the more reliable junction transistors became available. [27] The Transistor Computer's design was adopted by the local engineering firm of Metropolitan-Vickers in their Metrovick 950, in which all the circuitry was modified to make use of junction transistors. Six Metrovick 950s were built, the first completed in 1956. They were successfully deployed within various departments of the company and were in use for about five years. [23]

Muse and Atlas

Development of MUSE – a name derived from "microsecond engine" – began at the university in 1956. The aim was to build a computer that could operate at processing speeds approaching one microsecond per instruction, one million instructions per second. [28] Mu (or μ) is a prefix in the SI and other systems of units denoting a factor of 10−6 (one millionth).

At the end of 1958 Ferranti agreed to collaborate with Manchester University on the project, and the computer was shortly afterwards renamed Atlas, with the joint venture under the control of Tom Kilburn. The first Atlas was officially commissioned on 7 December 1962, and was considered at that time to be the most powerful computer in the world, equivalent to four IBM 7094s. [29] It was said that whenever Atlas went offline half of the UK's computer capacity was lost. [30] Its fastest instructions took 1.59 microseconds to execute, and the machine's use of virtual storage and paging allowed each concurrent user to have up to one million words of storage space available. Atlas pioneered many hardware and software concepts still in common use today including the Atlas Supervisor, "considered by many to be the first recognisable modern operating system". [31]

Two other machines were built: one for a joint British Petroleum/University of London consortium, and the other for the Atlas Computer Laboratory at Chilton near Oxford. A derivative system was built by Ferranti for Cambridge University, called the Titan or Atlas 2, which had a different memory organisation, and ran a time-sharing operating system developed by Cambridge Computer Laboratory. [30]

The University of Manchester's Atlas was decommissioned in 1971, [32] but the last was in service until 1974. [33] Parts of the Chilton Atlas are preserved by the National Museums of Scotland in Edinburgh.

In June 2022 an IEEE Milestone was dedicated to the "Atlas Computer and the Invention of Virtual Memory 1957–1962". [34]

MU5

The Manchester MU5 was the successor to Atlas. An outline proposal for a successor to Atlas was presented at the 1968 IFIP Conference in Edinburgh, [35] although work on the project and talks with ICT (of which Ferranti had become part) aimed at obtaining their assistance and support had begun in 1966. The new machine, later to become known as MU5, was intended to be at the top end of a range of machines and to be 20 times faster than Atlas.

In 1968 the Science Research Council (SRC) awarded Manchester University a five-year grant of £630,466 (equivalent to £12 million in 2023) [lower-alpha 1] to develop the machine and ICT, later to become ICL, made its production facilities available to the University. In that year a group of 20 people was involved in the design: 11 Department of Computer Science staff, 5 seconded ICT staff and 4 SRC supported staff. The peak level of staffing was in 1971, when the numbers, including research students, rose to 60. [36]

The most significant novel features of the MU5 processor were its instruction set and the use of associative memory to speed up operand and instruction accesses. The instruction set was designed to permit the generation of efficient object code by compilers, to allow for a pipeline organisation of the processor and to provide information to the hardware on the nature of operands, so as to allow them to be optimally buffered. Thus named variables were buffered separately from array elements, which were themselves accessed by means of named descriptors. Each descriptor included an array length which could be used in string processing instructions or to enable array bound checking to be carried out by hardware. The instruction pre-fetching mechanism used an associative jump trace to predict the outcome of impending branches. [37]

The MU5 operating system MUSS [38] [39] was designed to be highly adaptable and was ported to a variety of processors at Manchester and elsewhere. In the completed MU5 system, three processors (MU5 itself, an ICL 1905E and a PDP-11), as well as a number of memories and other devices, were interconnected by a high-speed Exchange. [40] [41] All three processors ran a version of MUSS. MUSS also encompassed compilers for various languages and runtime packages to support the compiled code. It was structured as a small kernel that implemented an arbitrary set of virtual machines analogous to a corresponding set of processors. The MUSS code appeared in the common segments that formed part of each virtual machine's virtual address space.

MU5 was fully operational by October 1974, coinciding with ICL's announcement that it was working on the development of a new range of computers, the 2900 series. ICL's 2980 in particular, first delivered in June 1975, owed a great deal to the design of MU5. [42] MU5 remained in operation at the University until 1982. [43] A fuller article about MU5 can be found on the Engineering and Technology History Wiki. [44]

MU6

Once MU5 was fully operational, a new project was initiated to produce its successor, MU6. MU6 was intended to be a range of processors: MU6P, [45] an advanced microprocessor architecture intended for use as a personal computer, MU6-G, [46] a high performance machine for general or scientific applications and MU6V, [47] a parallel vector processing system. A prototype model of MU6V, based on 68000 microprocessors with vector orders emulated as "extracodes" was constructed and tested but not further developed beyond this. MU6-G was built with a grant from SRC and successfully ran as a service machine in the Department between 1982 and 1987, [4] using the MUSS operating system developed as part of the MU5 project.

SpiNNaker

SpiNNaker: Spiking Neural Network Architecture is a massively parallel, manycore supercomputer architecture designed by Steve Furber in the University of Manchester's Advanced Processor Technologies Research Group (APT). [48] Built in 2019, it is composed of 57,600 ARM9 processors (specifically ARM968), each with 18 cores and 128 MB of mobile DDR SDRAM, totalling 1,036,800 cores and over 7 TB of RAM. [49] The computing platform is based on spiking neural networks, useful in simulating the human brain (see Human Brain Project). [50] [51] [52] [53] [54] [55] [56] [57] [58]

Summary

Chronology of developments
YearUniversity PrototypeYearCommercial Computer
1948 Manchester Baby, which evolved into the Manchester Mark 1 1951 Ferranti Mark 1
1953Transistor computer1956 Metrovick 950
1954Manchester Mark II a.k.a. "Meg"1957 Ferranti Mercury
1959Muse1962 Ferranti Atlas, Titan
1974MU51974 ICL 2900 Series

Related Research Articles

<span class="mw-page-title-main">History of computing hardware</span>

The history of computing hardware covers the developments from early simple devices to aid calculation to modern day computers.

<span class="mw-page-title-main">Williams tube</span> Early form of computer memory

The Williams tube, or the Williams–Kilburn tube named after inventors Freddie Williams and Tom Kilburn, is an early form of computer memory. It was the first random-access digital storage device, and was used successfully in several early computers.

A stored-program computer is a computer that stores program instructions in electronically or optically accessible memory. This contrasts with systems that stored the program instructions with plugboards or similar mechanisms.

<span class="mw-page-title-main">Steve Furber</span> British computer scientist

Stephen Byram Furber is a British computer scientist, mathematician and hardware engineer, and Emeritus ICL Professor of Computer Engineering in the Department of Computer Science at the University of Manchester, UK. After completing his education at the University of Cambridge, he spent the 1980s at Acorn Computers, where he was a principal designer of the BBC Micro and the ARM 32-bit RISC microprocessor. As of 2023, over 250 billion ARM chips have been manufactured, powering much of the world's mobile computing and embedded systems, everything from sensors to smartphones to servers.

<span class="mw-page-title-main">Department of Computer Science, University of Manchester</span>

The Department of Computer Science at the University of Manchester is the longest established department of Computer Science in the United Kingdom and one of the largest. It is located in the Kilburn Building on the Oxford Road and currently has over 800 students taking a wide range of undergraduate and postgraduate courses and 60 full-time academic staff.

<span class="mw-page-title-main">Manchester Baby</span> First electronic stored-program computer, 1948

The Manchester Baby, also called the Small-Scale Experimental Machine (SSEM), was the first electronic stored-program computer. It was built at the University of Manchester by Frederic C. Williams, Tom Kilburn, and Geoff Tootill, and ran its first program on 21 June 1948.

<span class="mw-page-title-main">Ferranti Mark 1</span> First commercial electronic computer

The Ferranti Mark 1, also known as the Manchester Electronic Computer in its sales literature, and thus sometimes called the Manchester Ferranti, was produced by British electrical engineering firm Ferranti Ltd. It was the world's first commercially available electronic general-purpose stored program digital computer.

<span class="mw-page-title-main">Tom Kilburn</span> British electrical engineer

Tom Kilburn was an English mathematician and computer scientist. Over his 30-year career, he was involved in the development of five computers of great historical significance. With Freddie Williams he worked on the Williams–Kilburn tube and the world's first electronic stored-program computer, the Manchester Baby, while working at the University of Manchester. His work propelled Manchester and Britain into the forefront of the emerging field of computer science.

<span class="mw-page-title-main">Titan (1963 computer)</span>

Titan was the prototype of the Atlas 2 computer developed by Ferranti and the University of Cambridge Mathematical Laboratory in Cambridge, England. It was designed starting in 1963, and in operation from 1964 to 1973.

<span class="mw-page-title-main">International Computers and Tabulators</span>

International Computers and Tabulators or ICT was a British computer manufacturer, formed in 1959 by a merger of the British Tabulating Machine Company (BTM) and Powers-Samas. In 1963 it acquired the business computer divisions of Ferranti. It exported computers to many countries and in 1968 became part of International Computers Limited (ICL).

The FP-6000 was a second-generation mainframe computer developed and built by Ferranti-Packard, the Canadian division of Ferranti, in the early 1960s. It is particularly notable for supporting multitasking, being one of the first commercial machines to do so. Only six FP-6000s were sold before the computer division of Ferranti-Packard was sold off by Ferranti's UK headquarters in 1963, the FP-6000 becoming the basis for the mid-range machines of the ICT 1900, which sold into the thousands in Europe.

<span class="mw-page-title-main">Spiking neural network</span> Artificial neural network that mimics neurons

Spiking neural networks (SNNs) are artificial neural networks (ANN) that more closely mimic natural neural networks. These models leverage timing of discrete spikes as the main information carrier.

The Orion was a mid-range mainframe computer introduced by Ferranti in 1959 and installed for the first time in 1961. Ferranti positioned Orion to be their primary offering during the early 1960s, complementing their high-end Atlas and smaller systems like the Sirius and Argus. The Orion was based on a new type of logic circuit known as "Neuron" and included built-in multitasking support, one of the earliest commercial machines to do so.

<span class="mw-page-title-main">Atlas (computer)</span> Supercomputer of the 1960s

The Atlas was one of the world's first supercomputers, in use from 1962 to 1972. Atlas's capacity promoted the saying that when it went offline, half of the United Kingdom's computer capacity was lost. It is notable for being the first machine with virtual memory using paging techniques; this approach quickly spread, and is now ubiquitous.

<span class="mw-page-title-main">Harwell CADET</span> First fully transistorised computer in Europe

The Harwell CADET was the first fully transistorised computer in Europe, and may have been the first fully transistorised computer in the world.

<span class="mw-page-title-main">Manchester Mark 1</span> British stored-program computer, 1949

The Manchester Mark 1 was one of the earliest stored-program computers, developed at the Victoria University of Manchester, England from the Manchester Baby. Work began in August 1948, and the first version was operational by April 1949; a program written to search for Mersenne primes ran error-free for nine hours on the night of 16/17 June 1949.

Ferranti's Sirius was a minicomputer released in 1961. Designed to be used in smaller offices without a dedicated programming staff, the Sirius used decimal arithmetic instead of binary, supported Autocode to ease programming, was designed to fit behind a standard office desk, and ran on UK standard mains electricity with no need for cooling. It was also fairly slow, with instruction speeds around 4,000 operations per second, and had limited main memory based on delay lines, but as Ferranti pointed out, its price/performance ratio was difficult to beat.

<span class="mw-page-title-main">SpiNNaker</span>

SpiNNaker is a massively parallel, manycore supercomputer architecture designed by the Advanced Processor Technologies Research Group (APT) at the Department of Computer Science, University of Manchester. It is composed of 57,600 processing nodes, each with 18 ARM9 processors and 128 MB of mobile DDR SDRAM, totalling 1,036,800 cores and over 7 TB of RAM. The computing platform is based on spiking neural networks, useful in simulating the human brain.

The Ferranti F100-L was a 16-bit microprocessor family announced by Ferranti in 1976 which entered production in 1977. It was the first microprocessor designed in Europe, and among the first 16-bit single-chip CPUs. It was designed with military use in mind, able to work in a very wide temperature range and radiation hardened. To deliver these capabilities, the F100 was implemented using bipolar junction transistors, as opposed to the metal oxide semiconductor (MOS) process used by most other processors of the era. The family included a variety of support chips including a multiply/divide unit, various memory support chips, timers and serial bus controllers.

References

  1. Lavington (1998), p. 49
  2. 1 2 Enticknap, Nicholas (Summer 1998), "Computing's Golden Jubilee", Resurrection (20), The Computer Conservation Society, ISSN   0958-7403, archived from the original on 9 January 2012, retrieved 19 April 2008
  3. 1 2 Grimsdale, Dick, "50th Birthday of Transistor Computer", curation.cs.manchester.ac.uk, retrieved 24 February 2018
  4. 1 2 "A Timeline of Manchester Computing", University of Manchester, archived from the original on 5 July 2008, retrieved 25 February 2009
  5. "timeline". 5 July 2008. Archived from the original on 5 July 2008.
  6. Lavington (1998), p. 7
  7. 1 2 Lavington (1998), p. 21
  8. Lavington, Simon (1980), Early British Computers, Manchester University Press, ISBN   978-0-7190-0803-0
  9. Lavington, Simon (1998), A History of Manchester Computers (2nd ed.), The British Computer Society, ISBN   978-1-902505-01-5
  10. Napper, R. B. E. (2000), "The Manchester Mark 1 Computers", in Rojas, Raúl; Hashagen, Ulf (eds.), The First Computers: History and Architectures, MIT Press, pp. 356–377, ISBN   978-0-262-68137-7
  11. Tootill, Geoff (Summer 1998), "The Original Original Program", Resurrection (20), The Computer Conservation Society, ISSN   0958-7403, archived from the original on 9 January 2012, retrieved 19 April 2008
  12. Manchester Museum of Science & Industry (2011), "The "Baby": The World's First Stored-Program Computer" (PDF), MOSI, archived from the original (PDF) on 15 February 2012, retrieved 3 April 2012
  13. Williams, F. C.; Kilburn, T. (25 September 1948), "Electronic Digital Computers", Nature, 162 (4117): 487, Bibcode:1948Natur.162..487W, doi: 10.1038/162487a0 , S2CID   4110351, archived from the original on 6 April 2009, retrieved 22 January 2009
  14. Napper (2000), p. 365
  15. 1 2 Lavington (1998), p. 17
  16. Napper, R. B. E., "The Manchester Mark 1", University of Manchester, archived from the original on 9 February 2014, retrieved 22 January 2009
  17. Lavington, S. H. (July 1977), "The Manchester Mark 1 and Atlas: a Historical Perspective" (PDF), University of Central Florida, retrieved 8 February 2009. (Reprint of the paper published in Communications of the ACM (January 1978) 21 (1)
  18. Lavington (1998), p. 18
  19. "Manchester University "Baby" Computer and its Derivatives, 1948-1951".
  20. Lavington (1998), p. 31
  21. "The "Manchester TC" transistor computer - CHM Revolution".
  22. Lavington (1998), pp. 34–35
  23. 1 2 Lavington (1998), p. 37
  24. Neumann, Albrecht J. (April 1955). "COMPUTERS, Overseas: 5. Manchester University - A SMALL EXPERIMENTAL TRANSISTOR DIGITAL COMPUTER". 7 (2): 16–17. Archived from the original on 10 May 2024.{{cite journal}}: Cite journal requires |journal= (help)
  25. 1 2 "1953: Transistorized Computers Emerge | The Silicon Engine | Computer History Museum". www.computerhistory.org. Retrieved 2 September 2019.
  26. Cooke-Yarborough, E. H. (June 1998), "Some early transistor applications in the UK", Engineering Science & Education Journal, 7 (3), IEE: 100–106, doi:10.1049/esej:19980301, ISSN   0963-7346, archived from the original on 5 July 2020, retrieved 7 June 2009(subscription required)
  27. Lavington (1998), pp. 36–37
  28. "The Atlas", University of Manchester, archived from the original on 28 July 2012, retrieved 21 September 2010
  29. Lavington (1998), p. 41
  30. 1 2 Lavington (1998), pp. 44–45
  31. Lavington (1980), pp. 50–52
  32. Lavington (1998), p. 43
  33. Lavington (1998), p. 44
  34. "Milestones:Atlas Computer and the Invention of Virtual Memory, 1957–1962".
  35. Kilburn, T.; Morris, D.; Rohl, J.S.; Sumner, F.H. (1969), "A System Design Proposal", Information Processing 68, vol. 2, North Holland, pp. 806–811
  36. Morris, Derrick; Ibbett, Roland N. (1979), The MU5 Computer System, Macmillan, p. 1
  37. Sumner, F.H. (1974), "MU5 - An Assessment of the Design", Information Processing 74, North Holland, pp. 133–136
  38. Frank, G.R.; Theaker, C.J. (1979), "The design of the MUSS operating system", Software: Practice and Experience, 9 (8): 599–620, doi:10.1002/spe.4380090802, S2CID   1962276
  39. Morris & Ibbett (1979), pp. 189–211
  40. Lavington, S.H.; Thomas, G.; Edwards, D.B.G. (1977), "The MU5 Multicomputer Communication System", IEEE Trans. Computers, vol. C-26, pp. 19–28
  41. Morris & Ibbett (1979), pp. 132–140.
  42. Buckle, John K. (1978), The ICL 2900 Series, The Macmillan Press
  43. Ibbett, Roland N. (1999), "The University of Manchester MU5 Computer Project", Annals of the History of Computing, 21, IEEE: 24–31, doi:10.1109/85.759366
  44. "The University of Manchester MU5 Computer System". ethw.org. 10 June 2022.
  45. Woods, J.V.; Wheen, A.J.T. (1983). "MU6P: an advanced microprocessor architecture". The Computer Journal. 26 (3): 208–217. doi:10.1093/comjnl/26.3.208.
  46. Edwards, D.B.G; Knowles, A.E.; Woods, J.V. (1980), "MU6-G: a new design to achieve mainframe performance from a mini-sized computer", 7th Annual International Symposium on Computer Architecture, pp. 161–167, doi:10.1145/800053.801921, S2CID   7224504
  47. Ibbett, R.N.; Capon, P.C.; Topham, N.P. (1985), "MU6V: a parallel vector processing system", 12th Annual International Symposium on Computer Architecture, IEEE, pp. 136–144, ISBN   9780818606342
  48. "Themes - Department of Computer Science - The University of Manchester". www.cs.manchester.ac.uk.
  49. "SpiNNaker Project - The SpiNNaker Chip". apt.cs.manchester.ac.uk. Retrieved 17 November 2018.
  50. SpiNNaker Home Page, University of Manchester, retrieved 11 June 2012
  51. Furber, S. B.; Galluppi, F.; Temple, S.; Plana, L. A. (2014). "The SpiNNaker Project". Proceedings of the IEEE. 102 (5): 652–665. doi: 10.1109/JPROC.2014.2304638 .
  52. Xin Jin; Furber, S. B.; Woods, J. V. (2008). "Efficient modelling of spiking neural networks on a scalable chip multiprocessor". 2008 IEEE International Joint Conference on Neural Networks (IEEE World Congress on Computational Intelligence). pp. 2812–2819. doi:10.1109/IJCNN.2008.4634194. ISBN   978-1-4244-1820-6. S2CID   2103654.
  53. A million ARM cores to host brain simulator News article on the project in the EE Times
  54. Temple, S.; Furber, S. (2007). "Neural systems engineering". Journal of the Royal Society Interface. 4 (13): 193–206. doi:10.1098/rsif.2006.0177. PMC   2359843 . PMID   17251143. A manifesto for the SpiNNaker project, surveying and reviewing the general level of understanding of brain function and approaches to building computer modelof the brain.
  55. Plana, L. A.; Furber, S. B.; Temple, S.; Khan, M.; Shi, Y.; Wu, J.; Yang, S. (2007). "A GALS Infrastructure for a Massively Parallel Multiprocessor". IEEE Design & Test of Computers. 24 (5): 454. doi:10.1109/MDT.2007.149. S2CID   16758888. A description of the Globally Asynchronous, Locally Synchronous (GALS) nature of SpiNNaker, with an overview of the asynchronous communications hardware designed to transmit neural 'spikes' between processors.
  56. Navaridas, J.; Luján, M.; Miguel-Alonso, J.; Plana, L. A.; Furber, S. (2009). "Understanding the interconnection network of SpiNNaker". Proceedings of the 23rd international conference on Conference on Supercomputing - ICS '09. p. 286. CiteSeerX   10.1.1.634.9481 . doi:10.1145/1542275.1542317. ISBN   9781605584980. S2CID   3710084. Modelling and analysis of the SpiNNaker interconnect in a million-core machine, showing the suitability of the packet-switched network for large-scale spiking neural network simulation.
  57. Rast, A.; Galluppi, F.; Davies, S.; Plana, L.; Patterson, C.; Sharp, T.; Lester, D.; Furber, S. (2011). "Concurrent heterogeneous neural model simulation on real-time neuromimetic hardware". Neural Networks. 24 (9): 961–978. doi:10.1016/j.neunet.2011.06.014. PMID   21778034. A demonstration of SpiNNaker's ability to simulate different neural models (simultaneously, if necessary) in contrast to other neuromorphic hardware.
  58. Sharp, T.; Galluppi, F.; Rast, A.; Furber, S. (2012). "Power-efficient simulation of detailed cortical microcircuits on SpiNNaker". Journal of Neuroscience Methods. 210 (1): 110–118. doi:10.1016/j.jneumeth.2012.03.001. PMID   22465805. S2CID   19083072. Four-chip, real-time simulation of a four-million-synapse cortical circuit, showing the extreme energy efficiency of the SpiNNaker architecture

Notes

  1. United Kingdom Gross Domestic Product deflator figures follow the MeasuringWorth "consistent series" supplied in Thomas, Ryland; Williamson, Samuel H. (2024). "What Was the U.K. GDP Then?". MeasuringWorth . Retrieved 15 July 2024.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.