Abstract
The area-time complexity of sorting is analyzed under an updated model of VLSI computation. The new model has fewer restrictions on chip I/O than previous models. Also, the definitions of area and time performance have been adjusted to permit fair comparisons between pipelined and non-pipelined designs.
Using the new model, this paper briefly describes eleven different designs for VLSI sorters. These circuits demonstrate the existence of an area*time2 tradeoff for the sorting problem. The smallest circuit is only large enough to store a few elements at a time; it is, of course, rather slow at sorting N elements. The largest design solves a sorting problem in only 0(lg N) clock cycles. The area*time2 performance figure for all but three of the designs is close to the limiting value, Ω(N2).
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© 1981 Carnegie-Mellon University
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Thompson, C.D. (1981). The VLSI Complexity of Sorting. In: Kung, H.T., Sproull, B., Steele, G. (eds) VLSI Systems and Computations. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-68402-9_13
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DOI: https://doi.org/10.1007/978-3-642-68402-9_13
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