| eBook ISBN: | 978-1-4704-4913-1 |
| Product Code: | MEMO/256/1225.E |
| List Price: | $78.00 |
| MAA Member Price: | $70.20 |
| AMS Member Price: | $46.80 |
| eBook ISBN: | 978-1-4704-4913-1 |
| Product Code: | MEMO/256/1225.E |
| List Price: | $78.00 |
| MAA Member Price: | $70.20 |
| AMS Member Price: | $46.80 |
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Book DetailsMemoirs of the American Mathematical SocietyVolume: 256; 2018; 142 ppMSC: Primary 49; 53; 58
The curvature discussed in this paper is a far reaching generalization of the Riemannian sectional curvature. The authors give a unified definition of curvature which applies to a wide class of geometric structures whose geodesics arise from optimal control problems, including Riemannian, sub-Riemannian, Finsler and sub-Finsler spaces. Special attention is paid to the sub-Riemannian (or Carnot–Carathéodory) metric spaces. The authors' construction of curvature is direct and naive, and similar to the original approach of Riemann. In particular, they extract geometric invariants from the asymptotics of the cost of optimal control problems. Surprisingly, it works in a very general setting and, in particular, for all sub-Riemannian spaces.
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Table of Contents
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Chapters
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1. Introduction
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1. Statements of the results
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2. General setting
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3. Flag and growth vector of an admissible curve
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4. Geodesic cost and its asymptotics
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5. Sub-Riemannian geometry
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2. Technical tools and proofs
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6. Jacobi curves
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7. Asymptotics of the Jacobi curve: Equiregular case
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8. Sub-Laplacian and Jacobi curves
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3. Appendix
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A. Smoothness of value function (Theorem $$)
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B. Convergence of approximating Hamiltonian systems (Proposition )
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C. Invariance of geodesic growth vector by dilations (Lemma $$)
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D. Regularity of $C(t,s)$ for the Heisenberg group (Proposition $$)
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E. Basics on curves in Grassmannians (Lemma $$ and $$)
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F. Normal conditions for the canonical frame
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G. Coordinate representation of flat, rank 1 Jacobi curves (Proposition $$)
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H. A binomial identity (Lemma $$)
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I. A geometrical interpretation of $\dot {c}_t$
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Additional Material
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The curvature discussed in this paper is a far reaching generalization of the Riemannian sectional curvature. The authors give a unified definition of curvature which applies to a wide class of geometric structures whose geodesics arise from optimal control problems, including Riemannian, sub-Riemannian, Finsler and sub-Finsler spaces. Special attention is paid to the sub-Riemannian (or Carnot–Carathéodory) metric spaces. The authors' construction of curvature is direct and naive, and similar to the original approach of Riemann. In particular, they extract geometric invariants from the asymptotics of the cost of optimal control problems. Surprisingly, it works in a very general setting and, in particular, for all sub-Riemannian spaces.
-
Chapters
-
1. Introduction
-
1. Statements of the results
-
2. General setting
-
3. Flag and growth vector of an admissible curve
-
4. Geodesic cost and its asymptotics
-
5. Sub-Riemannian geometry
-
2. Technical tools and proofs
-
6. Jacobi curves
-
7. Asymptotics of the Jacobi curve: Equiregular case
-
8. Sub-Laplacian and Jacobi curves
-
3. Appendix
-
A. Smoothness of value function (Theorem $$)
-
B. Convergence of approximating Hamiltonian systems (Proposition )
-
C. Invariance of geodesic growth vector by dilations (Lemma $$)
-
D. Regularity of $C(t,s)$ for the Heisenberg group (Proposition $$)
-
E. Basics on curves in Grassmannians (Lemma $$ and $$)
-
F. Normal conditions for the canonical frame
-
G. Coordinate representation of flat, rank 1 Jacobi curves (Proposition $$)
-
H. A binomial identity (Lemma $$)
-
I. A geometrical interpretation of $\dot {c}_t$
