AbstractThe complexity of matrix multiplication has attracted a lot of attention in the last forty years. In this paper, instead of considering asymptotic aspects of this problem, we are interested in reducing the cost of multiplication for matrices of small size, say up to 30. Following the previous work of Probert & Fischer, Smith, and Mezzarobba, in a similar vein, we base our approach on the previous algorithms for small matrices, due to Strassen, Winograd, Pan, Laderman, and others and show how to exploit these standard algorithms in an improved way. We illustrate the use of our results by generating multiplication codes over various rings, such as integers, polynomials, differential operators and linear recurrence operators
The exponent of matrix multiplication is the smallest real number ω such that for all ε>0, O(n^(ω+ε)...
Can post-Schönhage–Strassen multiplication algorithms be competitive in practice for large input siz...
Since 1960 and the result of Karatsuba, we know that the complexity of the multiplication (of intege...
AbstractThe complexity of matrix multiplication has attracted a lot of attention in the last forty y...
Matrix multiplication (hereafter we use the acronym MM) is among the most fundamental operations of ...
The complexity of matrix multiplication (hereafter MM) has been intensively studied since 1969, when...
It is widely known that the lower bound for the algorithmic complexity of square matrix multiplicati...
The evaluation of the product of two matrices can be very computationally expensive. The multiplica...
AbstractThe main purpose of this paper is to present a fast matrix multiplication algorithm taken fr...
Matrix multiplication is a basic operation of linear algebra, and has numerous applications to the t...
Let M(n) denote the bit complexity of multiplying n-bit integers, let ω ∈ (2, 3] be an exponent for ...
International audienceBini–Capovani–Lotti–Romani approximate formula (or border rank) for matrix mul...
We show that lower bounds on the border rank of matrix multiplication can be used to non-trivially d...
Matrix multiplication is one of the most widely used operations in all computational fields of linea...
AbstractThe numbers of bit operations (bt) required for matrix multiplication (MM), matrix inversion...
The exponent of matrix multiplication is the smallest real number ω such that for all ε>0, O(n^(ω+ε)...
Can post-Schönhage–Strassen multiplication algorithms be competitive in practice for large input siz...
Since 1960 and the result of Karatsuba, we know that the complexity of the multiplication (of intege...
AbstractThe complexity of matrix multiplication has attracted a lot of attention in the last forty y...
Matrix multiplication (hereafter we use the acronym MM) is among the most fundamental operations of ...
The complexity of matrix multiplication (hereafter MM) has been intensively studied since 1969, when...
It is widely known that the lower bound for the algorithmic complexity of square matrix multiplicati...
The evaluation of the product of two matrices can be very computationally expensive. The multiplica...
AbstractThe main purpose of this paper is to present a fast matrix multiplication algorithm taken fr...
Matrix multiplication is a basic operation of linear algebra, and has numerous applications to the t...
Let M(n) denote the bit complexity of multiplying n-bit integers, let ω ∈ (2, 3] be an exponent for ...
International audienceBini–Capovani–Lotti–Romani approximate formula (or border rank) for matrix mul...
We show that lower bounds on the border rank of matrix multiplication can be used to non-trivially d...
Matrix multiplication is one of the most widely used operations in all computational fields of linea...
AbstractThe numbers of bit operations (bt) required for matrix multiplication (MM), matrix inversion...
The exponent of matrix multiplication is the smallest real number ω such that for all ε>0, O(n^(ω+ε)...
Can post-Schönhage–Strassen multiplication algorithms be competitive in practice for large input siz...
Since 1960 and the result of Karatsuba, we know that the complexity of the multiplication (of intege...