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(electronics) A cathode-ray storage tube in which information is stored as a pattern of electric charges produced, maintained, read, and erased by suitably controlled scanning of the screen by the electron beam.
An electrostatic memory in the very first computers that used a cathode ray tube (CRT) for storage. Officially known as the Williams-Kilburn tube, it was developed at the University of Manchester in England by Professor F.C. (Freddie) Williams and graduate student Tom Kilburn. First deployed in the Baby computer in 1948, they were also used in the Whirlwind and IBM 701. Never the most reliable of devices, Williams tubes were superseded by delay line and magnetic core memories. See Whirlwind, IBM 701 and core storage.
Writing and Reading
Data were written on the screen by gating an electron beam on and off, creating a grid of dim and bright spots (0s and 1s). The visibility of the spots was not read by a person, rather the secondary electrons emitted at each spot built up a charge and turned the spots into capacitors (made up of the inside phosphor coating, the glass in the middle and a signal plate on the outside). Data were read by sweeping the beam across the grid using a lower intensity. Synchronized with the timing of the sweep, if the spot was bright, its greater charge caused the beam to reach the signal plate, and a 1 was output. If it was dim, a 0 was output. See Baby.
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| Williams tubes used in the Whirlwind computer in 1950 held a whopping 256 bits each, equivalent to 32 bytes of storage. The bits were "painted" on the surface of the tube, and their electrostatic charges determined their content. (Image courtesy of The MITRE Corporation Archives.) |
The Williams tube or (more accurately) the Williams-Kilburn tube (after Freddie Williams and co-worker Tom Kilburn), developed about 1946 or 1947, was a cathode ray tube used to electronically store binary data.
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When a dot is drawn on a cathode ray tube, the visible spot lasts for a time (called "persistence") that depends on the type of phosphor used in the tube. The operation of the Williams tube is due to a completely unrelated effect (in fact some Williams tubes were made with no phosphor), caused by secondary emission, such that the area of this dot becomes slightly positively charged and the area immediately around this dot becomes slightly negatively charged (creating a charge well). Also a positively charged dot is erased (filling the charge well) by drawing a second dot immediately adjacent to the one to be erased (most systems did this by drawing a short dash starting at the dot position, the extension of the dash erased the charge initially stored at the starting point). By later drawing a dot at that spot and measuring the charge, by means of a metal plate placed over the outside of the front of the tube, you have a simple form of memory that lasts for a time depending on the electrical resistance of the inside surface of the face of the tube. Reading a memory location destroyed its contents (creating a charge well), so any read had to be followed by a write (most systems did this by drawing a short dash starting at the dot position if the positive charge created needed to be erased). Also, because the charge gradually leaked off, it was necessary to scan the tube periodically and rewrite every dot (similar to the memory refresh cycles of DRAM in modern systems).
Williams tubes stored roughly 500 to 1,000 bits of data.
Developed at the University of Manchester in England, it provided the medium on which the first ever electronically stored-memory program was written in the Manchester Mark I computer. Tom Kilburn wrote a 17-line program to calculate the highest factor of a number. Tradition at Manchester University has it that this was the only program Tom Kilburn ever wrote.
The Williams tube tended to become unreliable with age, and most working installations had to be "tuned" by hand. By contrast, mercury delay line memory was slower and also needed hand tuning, but it did not age as badly and enjoyed some success in early digital electronic computing despite its speed, weight, cost, thermal and toxicity problems. However, the Manchester Mark I was successfully commercialised as the Ferranti Mark I and some early computers in the USA also used the Williams tube, including the IAS machine, originally designed for Selectron tube memory, and the UNIVAC 1103, IBM 701 and IBM 702. It was also used in the Soviet computer, Strela-1.
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