Ferranti Pegasus

Pegasus was an early British vacuum tube (valve) computer built by Ferranti, Ltd that pioneered design features to make life easier for both engineers and programmers.[1][2][3] Originally it was named the Ferranti Package Computer as its hardware design followed that of the Elliott 401 with modular plug-in packages.[4] Much of the development was the product of three men: W.S. (Bill) Elliott (Hardware); Christopher Strachey (Software) and Bernard Swann (Marketing and Customer Support).[5] It was Ferranti's most popular valve computer[6] with 38 being sold. The first Pegasus was delivered in 1956[7] and the last was delivered in 1959. Ferranti received funding for the development from the National Research Development Corporation (NRDC).[8]

A typical Pegasus computer installation, on view at the Science Museum, London.

At least two Pegasus machines survive, one in The Science Museum, London and one which was displayed in the Science and Industry Museum, Manchester but which has now been removed to the storage in the Science Museum archives at Wroughton. The Pegasus in The Science Museum, London ran its first program in December 1959 and was regularly demonstrated until 2009 when it developed a severe electrical fault.[9][10] In early 2014, the Science Museum decided to retire it permanently,[11] effectively ending the life of one of the world's oldest working computers. The Pegasus officially held the title of the world's oldest computer until 2012, when the restoration of the Harwell computer was completed at the National Museum of Computing.

Design

In those days it was common for it to be unclear whether a failure was due to the hardware or the program. As a consequence, Christopher Strachey of NRDC who was himself a brilliant programmer,[12] recommended the following design objectives:

  1. The necessity for optimum programming (favoured by Alan Turing) was to be minimised, "because it tended to become a time-wasting intellectual hobby of the programmers";
  2. The needs of the programmer were to be a governing factor in selecting the instruction set; and
  3. It was to be cheap and reliable.

The first objective was only partially met: because both program and the data on which it was to operate had to be in the 128 words of primary storage contained in 8-word nickel delay lines. The rest of the memory was held on a 7936-word magnetic drum[13] which rotated at 3750 rpm,[14] so it was often necessary to use ingenuity to reduce the number of transfers between the fast store and the drum.

The front panel of the Pegasus.

Pegasus had eight accumulators, seven of which could also be used as index registers, the first computer to allow this dual use. Accumulators 6 and 7 were known as p and q and were involved in multiply and divide and some double length shift instructions. Each word contained 39 bits plus one bit for parity checking. Two 19-bit instructions were packed into one word and the extra bit that could be used to indicate a breakpoint (optional stop), to assist in debugging. In line with Strachey's second objective, it had a relatively generous instruction set for a computer of its time, but there was no explicit hardware provision for handling either characters or floating point numbers.

The speed of arithmetic operations was about the same as the Elliott 402 computer, which could add in 204 microseconds and multiply in 3366 microseconds. The Pegasus basic instruction cycle time for add/subtract/move and logical instructions was 128 microseconds. Multiply, divide, justify and shift instructions took a variable time to complete. Transfers to and from the drum were synchronous. The layout of blocks on the drum was interleaved to allow some processing between transfers to/from consecutive blocks. The computer was advertised as weighing 2,560 lb (1.2 t).[15]

To what extent Strachey's third objective was reached, depends on how one views a price of £50,000 for Pegasus 1, which did not have magnetic tape drives, line printer or punched card input and output. The modular design with plug-in units of hardware did, however, make it very reliable by the standards of the day, and maintenance was "a doddle of a job".[10]

Applications

A printout from a Pegasus Computer

The initial version of Pegasus, Pegasus 1 was intended for scientific and engineering applications. Its input was via 5-hole paper tape with output on tape. The variant for business data processing was called Pegasus 2 and could equipped with punched cards, magnetic tape and line printer.[16]

In 1956 the first Pegasus was used to calculate the stresses and strains in the tail plane of the Saunders-Roe SR.53; the results were used to check the manufacturers figures; the programmer was Anne Robson. Because of the importance of a computer it was housed in the drawing room, complete with an Adam's ceiling, of Ferranti's London office in Portland Place.

A Pegasus 1 was installed at Cyber House, Sheffield by Stafford Beer for the use of United Steel. It was the first computer installed for management cybernetics.[17] The Pegasus at Southampton University was used for analysis of ground resonance data for the Saro P.531 helicopter that eventually entered production as the Westland Scout and Westland Wasp.[18]

In 1957 a Pegasus computer was used to calculate 7480 digits of pi, a record at the time. In 1959 Handley Page Ltd were advertising for experienced Pegasus programmers to join their aviation design team at Cricklewood, London [19]

The University of Leeds had a Pegasus computer, run by Sandy Douglas. This was used, among other things, for a project to process the University's matriculation records.[20]

Other people who worked on the Pegasus included Hugh McGregor Ross and Donald B. Gillies.

See also

References

  1. Ferranti Computers 1953-64 (PDF), Museum of Science & Industry, 2011, archived from the original (PDF) on 2 October 2014, retrieved 15 November 2014
  2. Merry, Ian (Autumn 1993), "The design of Pegasus", Resurrection: The Bulletin of the Computer Conservation Society (7), ISSN 0958-7403
  3. Pegasus – a vintage British computer, University of Essex
  4. Lavington 1980, p. 79.
  5. Ross 2012, p. 1.
  6. Burton, Chris (18 November 2003), "Ferranti Pegasus, Perseus and Sirius: Delivery Lists and Applications" (PDF), CCS-F3X1 (4), retrieved 15 November 2014
  7. "COMPUTERS, OVERSEAS: 3. PEGASUS, Ferranti Limited, England". Digital Computer Newsletter. 8 (3): 11. Jul 1956.
  8. Lavington 1980, p. 102.
  9. The Pegasus Incident and its Aftermath, retrieved February 23, 2018
  10. The Science Museum 2015.
  11. Computer Conservation Society Projects list, retrieved June 8, 2014
  12. Berners-Lee 1969.
  13. Felton 1962, p. 279.
  14. Weik 1957, p. 112.
  15. Weik 1957, p. 114.
  16. Felton 1962, p. 13.
  17. Cabezas, Guido. "Stafford's Curriculum Vitae". Guido Cabezas Fuentealba. Universidad del BioBio. Retrieved 18 August 2015.
  18. http://www.flightglobal.com/pdfarchive/view/1964/1964%20-%202166.html
  19. https://www.flightglobal.com/FlightPDFArchive/1959/1959%20-%203007.pdf
  20. P. F. Windley; L. R. Kay; A. Rowland-Jones (1960). "Data Processing in University Administration". The Computer Journal. 3 (1): 15–20. doi:10.1093/comjnl/3.1.15.

Bibliography

  • Berners-Lee, C. M. (22 May 1969), "Pegasus - A Pioneer in Reliability and Ease of Use", Computer Weekly: 12
  • Felton, G. E. (1962), The Pegasus Programming Manual (PDF), London: Ferranti Ltd.
  • Kershaw, Donald, "Experiences with Pegasus 1", Resurrection: The Bulletin of the Computer Conservation Society (14)
  • Lavington, Simon (June 1980), Early British Computers, Butterworth-Heinemann, ISBN 978-0932376084
  • Lavington, Simon (2000), The Pegasus Story: A history of a vintage British computer, London: Science Museum, ISBN 978-1900747400
  • Ross, Hugh McGregor; Colleagues (2012), Pegasus: The Early Seminal Computer, Sandy, Bedfordshire: Authors Online, ISBN 978-0-7552-1482-2
  • The Ferranti Pegasus Computer (YouTube). The Science Museum. 13 May 2015.
  • Weik, Martin H. (June 1957). "Ferranti Pegasus". ed-thelen.org. A Second Survey of Domestic Electronic Digital Computing Systems. pp. 112–114 (114).
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