Reversible Systolic Arrays, Part II: m-ary Equipollent SIMD Circuits and their Quantum Realizations

This paper introduces new type of m-ary systolic arrays called m-ary reversible systolic arrays which extends the new concept of two-valued reversible systolic arrays that was introduced in the first part of my article. The m-ary quantum systolic architectures’ computations of the new type of systolic arrays are also introduced. The new m-ary systolic arrays maintain the high level of regularity while exhibiting the new fundamental m-ary equipollent (bijectivity; reversibility) and m-ary quantum superposition properties. Since basic PEs used in the construction of arithmetic systolic arrays are the add-multiply cells, the results introduced in this paper are general and apply to a very wide range of m-ary Galois add-multiply-based systolic arrays. The new reversibility and superposition properties will be essential in performing super-fast arithmetic-intensive computations that are fundamental in several minimal-power consuming future applications such as in m-ary multi-dimensional quantum signal processing (QSP).