We describe an algorithm for arbitrary-precision computation of the elementary functions (exp, log, sin, atan, etc.) which, after a cheap precomputation, gives roughly a factor-two speedup over previous state-of-the-art algorithms at precision from a few thousand bits up to millions of bits. Following an idea of Schönhage, we perform argument reduction using Diophantine combinations of logarithms of primes; our contribution is to use a large set of primes instead of a single pair, aided by a fast algorithm to solve the associated integer relation problem. We also list new, optimized Machin-like formulas for the necessary logarithm and arctangent precomputations
[[abstract]]This paper describes an algorithm which will generate all the prime implicants of a Bool...
AbstractLet p be a fixed small prime. We give an algorithm with preprocessing to compute the j-invar...
The notion of Prime Implicants plays an important role in many AI applications such as diagnostic an...
We describe an algorithm for arbitrary-precision computation of the elementary functions (exp, log, ...
We describe a new implementation of the elementary transcendental functions exp, sin, cos, log and a...
In many applications of real-number computation we need to evaluate elementary functions such as exp...
Prime numbers are considered the foundation-stone in the structure of integers. Since any positive i...
A new algorithm for computing the complex logarithm and exponential functions is proposed. This algo...
We introduce an algorithm that computes the prime numbers up to N using O(N=log logN) additions and ...
This textbook presents the concepts and tools necessary to understand, build, and implement algorith...
A commonly used argument reduction technique in el-ementary function computations begins with two po...
Abstract. Some methods being used to speed up floating-point computation in Maple are described. Spe...
Let M(t) denote the time required to multiply two t-digit numbers using base b arithmetic. Meth...
. We give algorithms for the computation of the d-th digit of certain transcendental numbers in var...
AbstractAn efficient algorithm is presented for reconstructing a rational number from its residue mo...
[[abstract]]This paper describes an algorithm which will generate all the prime implicants of a Bool...
AbstractLet p be a fixed small prime. We give an algorithm with preprocessing to compute the j-invar...
The notion of Prime Implicants plays an important role in many AI applications such as diagnostic an...
We describe an algorithm for arbitrary-precision computation of the elementary functions (exp, log, ...
We describe a new implementation of the elementary transcendental functions exp, sin, cos, log and a...
In many applications of real-number computation we need to evaluate elementary functions such as exp...
Prime numbers are considered the foundation-stone in the structure of integers. Since any positive i...
A new algorithm for computing the complex logarithm and exponential functions is proposed. This algo...
We introduce an algorithm that computes the prime numbers up to N using O(N=log logN) additions and ...
This textbook presents the concepts and tools necessary to understand, build, and implement algorith...
A commonly used argument reduction technique in el-ementary function computations begins with two po...
Abstract. Some methods being used to speed up floating-point computation in Maple are described. Spe...
Let M(t) denote the time required to multiply two t-digit numbers using base b arithmetic. Meth...
. We give algorithms for the computation of the d-th digit of certain transcendental numbers in var...
AbstractAn efficient algorithm is presented for reconstructing a rational number from its residue mo...
[[abstract]]This paper describes an algorithm which will generate all the prime implicants of a Bool...
AbstractLet p be a fixed small prime. We give an algorithm with preprocessing to compute the j-invar...
The notion of Prime Implicants plays an important role in many AI applications such as diagnostic an...