Additive Number Theory [electronic resource] : The Classical Bases /

Additive Number Theory [electronic resource] : The Classical Bases /

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[Hilbert's] style has not the terseness of many of our modem authors in mathematics, which is based on the assumption that printer's labor and paper are costly but the reader's effort and time are not. H. Weyl [143] The purpose of this book is to describe the classical problems in additive number theory and to introduce the circle method and the sieve method, which are the basic analytical and combinatorial tools used to attack these problems. This book is intended for students who want to lel?Ill additive number theory, not for experts who already know it. For this reason, proofs include many "unnecessary" and "obvious" steps; this is by design. The archetypical theorem in additive number theory is due to Lagrange: Every nonnegative integer is the sum of four squares. In general, the set A of nonnegative integers is called an additive basis of order h if every nonnegative integer can be written as the sum of h not necessarily distinct elements of A. Lagrange 's theorem is the statement that the squares are a basis of order four. The set A is called a basis offinite order if A is a basis of order h for some positive integer h. Additive number theory is in large part the study of bases of finite order. The classical bases are the squares, cubes, and higher powers; the polygonal numbers; and the prime numbers. The classical questions associated with these bases are Waring's problem and the Goldbach conjecture.

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Main Authors: Nathanson, Melvyn B. author., SpringerLink (Online service)
Format: Texto biblioteca
Language:eng
Published: New York, NY : Springer New York : Imprint: Springer, 1996
Subjects:Mathematics., Mathematical analysis., Analysis (Mathematics)., Number theory., Number Theory., Analysis.,
Online Access:http://dx.doi.org/10.1007/978-1-4757-3845-2
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spelling KOHA-OAI-TEST:1990522018-07-30T23:25:28ZAdditive Number Theory [electronic resource] : The Classical Bases / Nathanson, Melvyn B. author. SpringerLink (Online service) textNew York, NY : Springer New York : Imprint: Springer,1996.eng[Hilbert's] style has not the terseness of many of our modem authors in mathematics, which is based on the assumption that printer's labor and paper are costly but the reader's effort and time are not. H. Weyl [143] The purpose of this book is to describe the classical problems in additive number theory and to introduce the circle method and the sieve method, which are the basic analytical and combinatorial tools used to attack these problems. This book is intended for students who want to lel?Ill additive number theory, not for experts who already know it. For this reason, proofs include many "unnecessary" and "obvious" steps; this is by design. The archetypical theorem in additive number theory is due to Lagrange: Every nonnegative integer is the sum of four squares. In general, the set A of nonnegative integers is called an additive basis of order h if every nonnegative integer can be written as the sum of h not necessarily distinct elements of A. Lagrange 's theorem is the statement that the squares are a basis of order four. The set A is called a basis offinite order if A is a basis of order h for some positive integer h. Additive number theory is in large part the study of bases of finite order. The classical bases are the squares, cubes, and higher powers; the polygonal numbers; and the prime numbers. The classical questions associated with these bases are Waring's problem and the Goldbach conjecture.I Waring’s problem -- 1 Sums of polygons -- 2 Waring’s problem for cubes -- 3 The Hilbert—Waring theorem -- 4 Weyl’s inequality -- 5 The Hardy—Littlewood asymptotic formula -- II The Goldbach conjecture -- 6 Elementary estimates for primes -- 7 The Shnirel’man—Goldbach theorem -- 8 Sums of three primes -- 9 The linear sieve -- 10 Chen’s theorem -- III Appendix -- Arithmetic functions -- A.1 The ring of arithmetic functions -- A.2 Sums and integrals -- A.3 Multiplicative functions -- A.4 The divisor function -- A.6 The Möbius function -- A.7 Ramanujan sums -- A.8 Infinite products -- A.9 Notes -- A.10 Exercises.[Hilbert's] style has not the terseness of many of our modem authors in mathematics, which is based on the assumption that printer's labor and paper are costly but the reader's effort and time are not. H. Weyl [143] The purpose of this book is to describe the classical problems in additive number theory and to introduce the circle method and the sieve method, which are the basic analytical and combinatorial tools used to attack these problems. This book is intended for students who want to lel?Ill additive number theory, not for experts who already know it. For this reason, proofs include many "unnecessary" and "obvious" steps; this is by design. The archetypical theorem in additive number theory is due to Lagrange: Every nonnegative integer is the sum of four squares. In general, the set A of nonnegative integers is called an additive basis of order h if every nonnegative integer can be written as the sum of h not necessarily distinct elements of A. Lagrange 's theorem is the statement that the squares are a basis of order four. The set A is called a basis offinite order if A is a basis of order h for some positive integer h. Additive number theory is in large part the study of bases of finite order. The classical bases are the squares, cubes, and higher powers; the polygonal numbers; and the prime numbers. The classical questions associated with these bases are Waring's problem and the Goldbach conjecture.Mathematics.Mathematical analysis.Analysis (Mathematics).Number theory.Mathematics.Number Theory.Analysis.Springer eBookshttp://dx.doi.org/10.1007/978-1-4757-3845-2URN:ISBN:9781475738452
institution COLPOS
collection Koha
country México
countrycode MX
component Bibliográfico
access En linea
En linea
databasecode cat-colpos
tag biblioteca
region America del Norte
libraryname Departamento de documentación y biblioteca de COLPOS
language eng
topic Mathematics.
Mathematical analysis.
Analysis (Mathematics).
Number theory.
Mathematics.
Number Theory.
Analysis.
Mathematics.
Mathematical analysis.
Analysis (Mathematics).
Number theory.
Mathematics.
Number Theory.
Analysis.
spellingShingle Mathematics.
Mathematical analysis.
Analysis (Mathematics).
Number theory.
Mathematics.
Number Theory.
Analysis.
Mathematics.
Mathematical analysis.
Analysis (Mathematics).
Number theory.
Mathematics.
Number Theory.
Analysis.
Nathanson, Melvyn B. author.
SpringerLink (Online service)
Additive Number Theory [electronic resource] : The Classical Bases /
description [Hilbert's] style has not the terseness of many of our modem authors in mathematics, which is based on the assumption that printer's labor and paper are costly but the reader's effort and time are not. H. Weyl [143] The purpose of this book is to describe the classical problems in additive number theory and to introduce the circle method and the sieve method, which are the basic analytical and combinatorial tools used to attack these problems. This book is intended for students who want to lel?Ill additive number theory, not for experts who already know it. For this reason, proofs include many "unnecessary" and "obvious" steps; this is by design. The archetypical theorem in additive number theory is due to Lagrange: Every nonnegative integer is the sum of four squares. In general, the set A of nonnegative integers is called an additive basis of order h if every nonnegative integer can be written as the sum of h not necessarily distinct elements of A. Lagrange 's theorem is the statement that the squares are a basis of order four. The set A is called a basis offinite order if A is a basis of order h for some positive integer h. Additive number theory is in large part the study of bases of finite order. The classical bases are the squares, cubes, and higher powers; the polygonal numbers; and the prime numbers. The classical questions associated with these bases are Waring's problem and the Goldbach conjecture.
format Texto
topic_facet Mathematics.
Mathematical analysis.
Analysis (Mathematics).
Number theory.
Mathematics.
Number Theory.
Analysis.
author Nathanson, Melvyn B. author.
SpringerLink (Online service)
author_facet Nathanson, Melvyn B. author.
SpringerLink (Online service)
author_sort Nathanson, Melvyn B. author.
title Additive Number Theory [electronic resource] : The Classical Bases /
title_short Additive Number Theory [electronic resource] : The Classical Bases /
title_full Additive Number Theory [electronic resource] : The Classical Bases /
title_fullStr Additive Number Theory [electronic resource] : The Classical Bases /
title_full_unstemmed Additive Number Theory [electronic resource] : The Classical Bases /
title_sort additive number theory [electronic resource] : the classical bases /
publisher New York, NY : Springer New York : Imprint: Springer,
publishDate 1996
url http://dx.doi.org/10.1007/978-1-4757-3845-2
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