Let M be an s ×t matrix and let M T be the transpose of M . Let x and y be t - and s -dimensional indeterminate column vectors, respectively. We show that any linear algorithm A that computes M x has associated with it a natural dual linear algorithm denoted A T that computes M T y . Furthermore, if M has no zero rows or columns then the number of additions used by A T exceeds the number of additions used by A by exactly s -t . In addition, a strong correspondence is established between linear algorithms that compute the product M x and bilinear algorithms that compute the bilinear form y T M x
Given two boolean matrices A and B, we define the boolean product A AND B as that matrix whose (i, j...
Matrix multiplication is commonly used in scientific computation. Given matrices A = (aij ) of size ...
Strassen\u27s 1969 algorithm for fast matrix multiplication is based on the possibility to multiply ...
In the previous lectures, we have seen that matrices play an important role in solving system of lin...
AbstractIn this paper we will show that Strassen's algorithm for the computation of the product of 2...
Let x be a column vector of indeterminates. We show that the complexity of computing the linear form...
AbstractWe wish to answer the following question: p matrices Bi, of the same dimension, being given,...
43 pagesWe consider putting certain tensors into forms with approximately minimum L2 norm. These ten...
AbstractWe present several bilinear algorithms for the acceleration of multiplication of n X n matri...
In this work, we present an approach to alleviate the potential benefit of adder graph algorithms by...
Abstract. Any associative bilinear multiplication on the set of n-by-n ma-trices over some field of ...
AbstractFast algorithms for computing the product with a vector are presented for a number of classe...
AbstractAlthough general theories are beginning to emerge in the area of automata based complexity t...
In this book the authors introduce a new product on matrices called the natural product. ... Thus by...
International audienceWe present a non-commutative algorithm for the multiplication of a 2x2-block-m...
Given two boolean matrices A and B, we define the boolean product A AND B as that matrix whose (i, j...
Matrix multiplication is commonly used in scientific computation. Given matrices A = (aij ) of size ...
Strassen\u27s 1969 algorithm for fast matrix multiplication is based on the possibility to multiply ...
In the previous lectures, we have seen that matrices play an important role in solving system of lin...
AbstractIn this paper we will show that Strassen's algorithm for the computation of the product of 2...
Let x be a column vector of indeterminates. We show that the complexity of computing the linear form...
AbstractWe wish to answer the following question: p matrices Bi, of the same dimension, being given,...
43 pagesWe consider putting certain tensors into forms with approximately minimum L2 norm. These ten...
AbstractWe present several bilinear algorithms for the acceleration of multiplication of n X n matri...
In this work, we present an approach to alleviate the potential benefit of adder graph algorithms by...
Abstract. Any associative bilinear multiplication on the set of n-by-n ma-trices over some field of ...
AbstractFast algorithms for computing the product with a vector are presented for a number of classe...
AbstractAlthough general theories are beginning to emerge in the area of automata based complexity t...
In this book the authors introduce a new product on matrices called the natural product. ... Thus by...
International audienceWe present a non-commutative algorithm for the multiplication of a 2x2-block-m...
Given two boolean matrices A and B, we define the boolean product A AND B as that matrix whose (i, j...
Matrix multiplication is commonly used in scientific computation. Given matrices A = (aij ) of size ...
Strassen\u27s 1969 algorithm for fast matrix multiplication is based on the possibility to multiply ...