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| - | ==== Communication Theory Laboratory (LTHC) ==== | + | ==== What is IPG About? ==== |
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| + | The **information processing group** is concerned with fundamental issues in the area of communications, in particular coding and information theory. Information theory establishes the limits of communications -- what is achievable and what is not. Coding theory tries to devise low complexity schemes that approach these limits. | ||
| - | The communications theory lab is concerned with fundamental issues in the area of communications, in particular coding and information theory. Information theory establishes the limits of communications -- what is achievable and what is not. Coding theory tries to devise low complexity schemes that approach these limits. | + | To say it the [[http://www.youtube.com/watch?v=uprjmoSMJ-o|Monty Python ]]way: Our chief weapon is probability ... probability and abstract algebra ... abstract algebra and probability.... Our **two** weapons are abstract algrebra and probability ... and optimization .... Our **three** weapons are abstract algebra, probability, and optimization ... and an almost fanatical devotion to methods of statistical physics ... |
| - | \\ | + | Our **four** ... no ... **Amongst** our weapons .... Amongst our weaponry ... are such elements as abstract algebra, probability ... |
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| - | The last ten years have seen dramatic changes and great improvements in the area of coding theory. Rather than relying on algebraic code constructions it is now recognized that suitably confined ``random structures'' combined with low complexity iterative decoding algorithms can achieve astonishing performance at unprecedentedly low complexity. This new approach to coding is usually referred to as ``iterative decoding.'' This paradigm shift poses many new challenging problems but also represents an enormous opportunity. We decided to take full advantage of this opportunity, and to make the analysis and design of these iterative coding systems the present focus of LTHC. In particular, we are interested in a sound understanding of the basic principles underlying such coding systems. The pool of applications which derive significant benefit from any improvement in this area is vast and contains many of the most prevalent communication systems today, e.g., wireless systems, optical links operating at rates as high as 40gbits/s and magnetic or holographic storage systems. | + | \\ |
| - | | + | //Return to// [[en:home|Home page]] |