Book contents
- Frontmatter
- Contents
- Acknowledgements
- Preface
- Notation
- Introduction
- 0 Duality and Fourier analysis
- 1 Background philosophy
- 2 Operator norm inequalities
- 3 Dual norm inequalities
- 4 Exercises: Including the Large Sieve
- 5 The method of the stable dual (1): Deriving the approximate functional equations
- 6 The method of the stable dual (2): Solving the approximate functional equations
- 7 Exercises: Almost linear, Almost exponential
- 8 Additive functions of class ℒα. A first application of the method
- 9 Multiplicative functions of the class ℒα: First Approach
- 10 Multiplicative functions of the class ℒα: Second Approach
- 11 Multiplicative functions of the class ℒα: Third Approach
- 12 Exercises: Why the form?
- 13 Theorems of Wirsing and Halász
- 14 Again Wirsing's Theorem
- 15 Exercises: The prime number theorem
- 16 Finitely distributed additive functions
- 17 Multiplicative functions of the class ℒα. Mean value zero
- 18 Exercises: Including logarithmic weights
- 19 Encounters with Ramanujan's function τ(n)
- 20 The operator T on L2
- 21 The operator T on Lα and other spaces
- 22 Exercises: The operator D and differentiation. The operator T and the convergence of measures
- 23 Pause: Towards the discrete derivative
- 24 Exercises: Multiplicative functions on arithmetic progressions. Wiener phenomenon
- 25 Fractional power Large Sieves. Operators involving primes
- 26 Exercises: Probability seen from number theory
- 27 Additive functions on arithmetic progressions: Small moduli
- 28 Additive functions on arithmetic progressions: Large moduli
- 29 Exercises: Maximal inequalities
- 30 Shift operators and orthogonal duals
- 31 Differences of additive functions. Local inequalities
- 32 Linear forms in shifted additive functions
- 33 Exercises: Stability. Correlations of multiplicative functions
- 34 Further readings
- 35 Rückblick (after the manner of Johannes Brahms)
- References
- Author index
- Subject index
0 - Duality and Fourier analysis
Published online by Cambridge University Press: 05 November 2011
- Frontmatter
- Contents
- Acknowledgements
- Preface
- Notation
- Introduction
- 0 Duality and Fourier analysis
- 1 Background philosophy
- 2 Operator norm inequalities
- 3 Dual norm inequalities
- 4 Exercises: Including the Large Sieve
- 5 The method of the stable dual (1): Deriving the approximate functional equations
- 6 The method of the stable dual (2): Solving the approximate functional equations
- 7 Exercises: Almost linear, Almost exponential
- 8 Additive functions of class ℒα. A first application of the method
- 9 Multiplicative functions of the class ℒα: First Approach
- 10 Multiplicative functions of the class ℒα: Second Approach
- 11 Multiplicative functions of the class ℒα: Third Approach
- 12 Exercises: Why the form?
- 13 Theorems of Wirsing and Halász
- 14 Again Wirsing's Theorem
- 15 Exercises: The prime number theorem
- 16 Finitely distributed additive functions
- 17 Multiplicative functions of the class ℒα. Mean value zero
- 18 Exercises: Including logarithmic weights
- 19 Encounters with Ramanujan's function τ(n)
- 20 The operator T on L2
- 21 The operator T on Lα and other spaces
- 22 Exercises: The operator D and differentiation. The operator T and the convergence of measures
- 23 Pause: Towards the discrete derivative
- 24 Exercises: Multiplicative functions on arithmetic progressions. Wiener phenomenon
- 25 Fractional power Large Sieves. Operators involving primes
- 26 Exercises: Probability seen from number theory
- 27 Additive functions on arithmetic progressions: Small moduli
- 28 Additive functions on arithmetic progressions: Large moduli
- 29 Exercises: Maximal inequalities
- 30 Shift operators and orthogonal duals
- 31 Differences of additive functions. Local inequalities
- 32 Linear forms in shifted additive functions
- 33 Exercises: Stability. Correlations of multiplicative functions
- 34 Further readings
- 35 Rückblick (after the manner of Johannes Brahms)
- References
- Author index
- Subject index
Summary
The notion of duality and its action in analytic number theory informs this entire work. Emphasis is given to the interplay between the arithmetic and analytic meaning of inequalities. The following remarks place ideas employed in the present work within a broader framework.
1. Conies. By duality the notion of a point conic gives rise to the notion of a line conic. The members of the line conic comprise the tangents to the point conic. Slightly surrealistically we may regard a conic to be a geometric object, defined from the inside by a point locus, and from the outside by a line envelope.
2. Dual spaces. Let V be a finite dimensional vector space over a field F. The dual of V is the vector space of linear maps of V into F. The space V and its dual, V′, are isomorphic.
To every linear map T: V → W between spaces, there corresponds a dual map T′: W′ → V′. In standard notation, the action f(x) of a function f upon x is written 〈x, f〉. The dual map T′ is defined by (Tx, y′) = 〈x, T′y′〉 where x, y′ denote typical elements of V, W′ respectively.
Let V = Fn, W = Fm. We may identify W′ with the set of maps W → F given by k ↦ kty′, where y′ is a vector in W, t denotes transposition.
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- Duality in Analytic Number Theory , pp. 1 - 15Publisher: Cambridge University PressPrint publication year: 1997