Semiconductor & Computer Engineering
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{{title|Relay Computer}} | {{title|Relay Computer}} | ||
[[File:Harvard Mark I.jpg|thumb|right|250px|The {{ibm|Harvard Mark I}}, a [[relay logic|relay-based]] computer, one of the earliest, made by [[IBM]] in 1944.]] | [[File:Harvard Mark I.jpg|thumb|right|250px|The {{ibm|Harvard Mark I}}, a [[relay logic|relay-based]] computer, one of the earliest, made by [[IBM]] in 1944.]] | ||
| − | A '''relay computer''' is a computer system built primarily using [[relay]]s and [[relay logic]]. Relay computers were a short-lived technology during the late 1930s to early 1950s. By the late 1950s technology has shifted almost exclusively to [[vacuum tube]]s. | + | A '''relay computer''' is a computer system built primarily using electromechanical [[relay]]s and [[relay logic]]. Relay computers were a short-lived technology during the late 1930s to early 1950s. By the late 1950s technology has shifted almost exclusively to [[vacuum tube]]s. |
== Overview == | == Overview == | ||
Revision as of 20:44, 17 December 2015
A relay computer is a computer system built primarily using electromechanical relays and relay logic. Relay computers were a short-lived technology during the late 1930s to early 1950s. By the late 1950s technology has shifted almost exclusively to vacuum tubes.
Overview
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This section requires expansion; you can help adding the missing info. |
The idea of using relays to realize logic circuits was not new even in the 1920s. However it was not until the late 1930s that actual full-scale computers and calculators were developed. However, it was not until the end of World War II that a large number of systems were built.
The choice of using relays instead of vacuum tube boiled down to cost and availability. Standard telephone relays were already in wide use and were considerably cheaper than any other alternative, albeit slow and power hungry. Since most of the early relay computers were developed by independent individuals such as George Stibitz and Konrad Zuse and without a large budget, using relays made the most sense.
Relay Systems
This list is incomplete; you can help by expanding it.
| System | Developer | Company/Institution | Relay Count | Year Complete | Notes |
|---|---|---|---|---|---|
| Model K | George Stibitz | Bell Labs | 1937 | ||
| Model I | George Stibitz | Bell Labs | 400 | 1939 | |
| Z2 | Konrad Zuse | 600 | 1939 | ||
| Z3 | Konrad Zuse | 2,000 | 1941 | ||
| Model II | Bell Labs | 440 | 1943 | ||
| Z4 | Konrad Zuse | Zuse Apparatebau | 2,500 | 1944 | |
| Model III | Bell Labs | 1,400 | 1944 | ||
| Harvard Mark I | Howard Aiken | IBM | 3,500 | 1944 | |
| Model IV | Bell Labs | 1400 | 1945 | ||
| Model V | Bell Labs | 9,000 | 1946 | ||
| Harvard Mark II | Howard Aiken | IBM | 1947 | ||
| SSEC | IBM | 21,400 | 1948 | vacuum tubes & relays hybrid | |
| Baby Atlas | CSAW | 1949 | Used for the debugging of the Atlas computer | ||
| Model VI | Bell Labs | 1950 | |||
| BARK | Matematikmaskinnämnden | 8,000 | 1950 | ||
| Mark I | Electrotechnical Laboratory | 1952 | |||
| Z5 | Konrad Zuse | Zuse KG | 2,500 | 1953 | |
| FACOM 100 | Fujitsu | 1954 | |||
| Z11 | Konrad Zuse | Zuse KG | 1,665 | 1955 | |
| Mark II | Electrotechnical Laboratory | 22,253 | 1955 |
See also
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