May 06

EDSAC, the first ‘practical’ civilian computer, turns 64

Posted in: Today's Chili

EDSAC, the first 'practical' civilian computer, turns 64

On May 6th, 1949 EDSAC (or Electronic Delay Storage Automatic Calculator) ran its first programs, calculating a table of squares and generating a list of prime numbers. The massive vacuum-tube-powered machine was put into service at the University of Cambridge and almost immediately changed how research was done at the school. It was among the first general-purpose computers capable of storing programs in rewritable memory, which took the form of mercury delay lines. Maurice Wilkes, the designer of the EDSAC, certainly earned his place in computing history, but David Wheeler’s later contributions were equally important. Using the EDSAC he invented subroutines, an essential component of modern programming that allows developers to reuse bits of existing code to simplify the act of writing software. This milestone piece of machinery is little more than scraps at this point, but a team at the UK’s National Museum of Computing is working to build a working replica. The hope is to have the computer up and running by May of 2015. For some more insight into how the EDSAC changed the face of computing, check out the video after the break.

[Image credit: University of Cambridge]

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Source: Google

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Feb 03

University of Cambridge chip moves data in 3D through magnetic spin

Posted in: Today's Chili

University of Cambridge chip moves data in 3D

Chips that have 3D elements to them are very much real. Moving data in 3D hasn’t been truly viable until now, however, which makes an experimental chip from the University of Cambridge that much more special. By sandwiching a layer of ruthenium atoms between cobalt and platinum, researchers found that they can move data up and down an otherwise silicon-based design through spintronics; the magnetic field manipulation sends information across the ruthenium to its destination. The layering is precise enough to create a “staircase” that moves data one step at a time. There’s no word on if and when the technique might be applied to real-world circuitry, but the advantages in density are almost self-evident: the university suggests higher-capacity storage, while processors could also be stacked vertically instead of consuming an ever larger 2D footprint. As long as the 3D chip technology escapes the lab, computing power could take a big step forward. Or rather, upward.

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Source: University of Cambridge

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