Systolic array: Difference between revisions

In [[parallel computing|parallel]] [[computer architectures]], a '''systolic array''' is a homogeneous [[Graph (discrete mathematics)|network]] of tightly coupled [[data processing unit]]s (DPUs) called cells or [[Node (computer science)|node]]s. Each node or DPU independently computes a partial result as a function of the data received from its upstream neighbours, stores the result within itself and passes it downstream. Systolic arrays were first used in [[Colossus computer|Colossus]], which was an early computer used to break German [[Lorenz cipher|Lorenz]] ciphers during [[World War II]].<ref>{{YouTube |id=g2tMcMQqSbA |title=Colossus - The Greatest Secret in the History of Computing |time=41m45s}}</ref> Due to the classified nature of Colossus, they were independently invented or rediscovered by [[H. T. Kung]] and [[Charles Leiserson]] who described arrays for many dense linear algebra computations (matrix product, solving systems of [[linear equation]]s, [[LU decomposition]], etc.) for banded matrices. Early applications include computing [[greatest common divisor]]s of integers and polynomials.<ref>http://www.eecs.harvard.edu/~htk/publication/1984-ieeetoc-brent-kung.pdf</ref> They are sometimes classified as [[Multiple instruction, single datamultipledata|multiple-instruction single-data]] (MISD) architectures under [[Flynn's taxonomy]], but this classification is questionable because a strong argument can be made to distinguish systolic arrays from any of Flynn's four categories: [[Single instruction, single data|SISD]], [[Single instruction, multiple data|SIMD]], [[Multiple instruction, single data|MISD]], [[Multiple instruction, multiple data|MIMD]], as discussed later in this article.