George Stibitz

George Stibitz
Born (1904-04-30)April 30, 1904
York, Pennsylvania
Died January 31, 1995(1995-01-31) (aged 90)
Hanover, New Hampshire
Alma mater Cornell University
Union College
Denison University
Notable awards Harry H. Goode Memorial Award (1965)
IEEE Emanuel R. Piore Award (1977)

George Robert Stibitz (April 30, 1904[1] – January 31, 1995) is internationally recognized as one of the fathers of the modern first digital computer. He was a Bell Labs researcher known for his work in the 1930s and 1940s on the realization of Boolean logic digital circuits using electromechanical relays as the switching element.

Stibitz was born in York, Pennsylvania. He received his bachelor's degree from Denison University in Granville, Ohio, his master's degree from Union College in 1927, and his Ph.D. in mathematical physics in 1930 from Cornell University.

Computer

This bronze plaque is located in the entryway of McNutt Hall at Dartmouth College reads, "In this building on September 9, 1940, George Robert Stibitz, then a mathematician with bell telephone laboratories, first demonstrated the remote operation of an electrical digital computer. Stibitz, who conceived the electrical digital computer in 1937 at Bell Labs, described his invention of the "complex number calculator" at a meeting of the Mathematical Association of America held here. Members of the audience transmitted problems to the computer at Bell Labs in New York City, and in seconds received solutions transmitted from the computer to a teletypewriter in this hall."
The site of the first long-distance communication of man and computer: McNutt Hall at Dartmouth College, September 9, 1940. The bronze commemorative plaque is mounted on the left wall in the entryway of the hall.

In November 1937, George Stibitz, then working at Bell Labs, completed a relay-based calculator he later dubbed the "Model K" (for "kitchen table", on which he had assembled it), which calculated using binary addition.[2] Replicas of the "Model K" now reside in the Computer History Museum, the Smithsonian Institution, the William Howard Doane Library at Denison University and the American Computer Museum in Bozeman, Montana where the George R. Stibitz Computer and Communications Pioneer Awards are granted.

Bell Labs subsequently authorized a full research program in late 1938 with Stibitz at the helm. Their Complex Number Computer, completed in November 1939, was able to do calculations on complex numbers.[3] In a demonstration to the American Mathematical Society conference at Dartmouth College in September 1940, Stibitz used a teletype to send commands to the Complex Number Computer in New York over telegraph lines.[4] It was the first computing machine ever used remotely.[5] (See the commemorative plaque and the hall where this event took place in the photos below.)

Wartime activities and subsequent Bell Labs computers

After the United States entered World War II in December, 1941, Bell Labs became active in developing fire-control devices for the U.S. military. The Labs' most famous invention was the M-9 Gun Director, an ingenious analog device that directed anti-aircraft fire with uncanny accuracy.[6] Stibitz moved to the National Defense Research Committee, an advisory body for the government, but he kept close ties with Bell Labs. For the next several years, with his guidance, the Labs developed relay computers of ever-increasing sophistication. The first of them was used to test the M-9 Gun Director. Later models had more sophisticated capabilities. They had specialized names, but later on, Bell Labs renamed them "Model II," Model III, etc, and the Complex Number Computer was renamed the "Model I." All used telephone relays for logic, and paper tape for sequencing and control. The last of this series, the Model V, was completed in 1946 and was a fully programmable, general-purpose computer, although its relay technology made it slower than the all-electronic computers then under development.[7]

Origin of the term "digital"

In April, 1942, Stibitz attended a meeting of a division of the Office of Scientific Research and Development (OSRD), charged with evaluating various proposals for fire-control devices to be used against Axis forces during World War II. Stibitz noted that the proposals fell into two broad categories: "analog" and "pulse." In a memo written after the meeting, he suggested that the term "digital" be used in place of "pulse," as he felt the latter term was insufficiently descriptive of the nature of the processes involved. The word "digit" at the time had two common meanings: the ten fingers of one's hands, and the numbers 0 through 9. The adjective "digital" was also in use, although it was not as common. For example, among physicians, a "digital" examination referred to the use of a doctor's finger to palpate part of the body. Stibitz's memorandum was the first known use of the term "digital" to refer to calculating machinery.[8]

Awards

Stibitz held 38 patents, in addition to those he earned at Bell Labs. He became a member of the faculty at Dartmouth College in 1964 to build bridges between the fields of computing and medicine, and retired from research in 1983.

Computer art

In his later years, George "turned to non-verbal uses of the computer". Specifically, he used a Commodore-Amiga to create computer art. In a 1990 letter, written to the department chair of the Mathematics and Computer Science department of Denison University he said:

I have turned to non-verbal uses of the computer, and have made a display of computer "art". The quotes are obligatory, for the result of my efforts is not to create important art but to show that this activity is fun, much as the creation of computers was fifty years ago.

The Mathematics and Computer Science department at Denison University has enlarged and displayed some of his artwork.

Publications

See also

Notes

  1. Henry S. Tropp, "Stibitz, George Robert," in Anthony Ralston and Edwin D. Reilly, eds., Encyclopedia of Computer Science, Third Edition (New York: van Nostrand Rheinhold, 1993), pp. 1284–1286. Some accounts give April 20 as his birth date, but the Tropp citation is the most authoritative.
  2. Ritchie, David (1986). The Computer Pioneers. New York: Simon and Schuster. p. 35. ISBN 067152397X.
  3. Ritchie 1986, p. 38.
  4. Ritchie 1986, p. 39.
  5. Dalakov, Georgi. "Relay computers of George Stibitz". History of Computers: Hardware, Software, Internet. Retrieved 30 March 2015.
  6. Eames, office of Charles and Ray, A Computer Perspective: Background to the Computer Age (Cambridge, MA: Harvard University Press 1973, 1990), p. 128
  7. Paul E. Ceruzzi, Reckoners: The Prehistory of the Digital Computer, from Relays to the Stored Program Concept, 1935-1945 (Westport, CT: Greenwood Press 1983), chapter 4
  8. Bernard O. Williams, "Computing with Electricity, 1935-1945," PhD Dissertation, University of Kansas, 1984 (University Microfilms International, 1987), p. 310

References

"The second American project [Aiken's being the first] was underway at Bell Laboratories. Here the engineer G. Stibitz had first only thought of designing relay machines to perform decimal arithmetic with complex numbers, but after the outbreak of war had incorporated the facility to carry out a fixed sequence of arithmetical operations. His 'Model III' [sic] was under way in the New York building at the time of Alan Turing's stay there, but it had not drawn his attention." (p. 299)
Stibitz's work with binary addition has a peculiar (i.e. apparently simultaneous) overlap with some experimenting Alan Turing did in 1937 while a PhD student at Princeton. The following is according to a Dr. Malcolm McPhail "who became involved in a sideline that Alan took up" (p. 137); Turing built his own relays and "actually designed an electric multiplier and built the first three or four stages to see if it could be made to work" (p. 138). It is unknown whether Stibitz and/or McPhail had any influence on this work of Turing's; McPhail's implication is that Turing's "[alarm]about a possible war with Germany" (p. 138) caused him to become interested in cryptanalysis, and this interest led to discussions with McPhail, and these discussions led to the relay-multiplier experiments (the pertinent part of McPhail's letter to Hodges is quoted in Hodges p. 138).

External links

Patents

Other

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