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The covector mapping principle is a special case of Riesz' representation theorem, which is a fundamental theorem in functional analysis. The name was coined by by Ross and co-workers,^[1]^[2] ^[3]^[4]^[5]^[6] It provides conditions under which dualization can be commuted with discretization in the case of computational optimal control.

Description

An application of Pontryagin's minimum principle to Problem $B$ , a given optimal control problem generates a boundary value problem. According to Ross, this boundary value problem is a Pontryagin lift and is represented as Problem $B^{\lambda }$ .

File:CMP-OptimalControl.png

Illustration of the Covector Mapping Principle (adapted from Ross and Fahroo .^[7]

Now suppose one discretizes Problem $B^{\lambda }$ . This generates Problem $B^{\lambda N}$ where $N$ represents the number of discrete pooints. For convergence, it is necessary to prove that as

N\to \infty ,\quad {\text{Problem }}B^{\lambda N}\to {\text{Problem }}B^{\lambda }

In the 1960s Kalman and others ^[8] showed that solving Problem $B^{\lambda N}$ is extremely difficult. This difficulty, known as the curse of complexity,^[9] is complementary to the curse of dimensionality.

In a series of papers starting in the late 1990s, Ross and Fahroo showed that one could arrive at a solution to Problem $B^{\lambda }$ (and hence Problem $B$ ) more easily by discretizing first (Problem $B^{N}$ ) and dualizing afterwards (Problem $B^{N\lambda }$ ). The sequence of operations must be done carefully to ensure consistency and convergence. The covector mapping principle asserts that a covector mapping theorem can be discovered to map the solutions of Problem $B^{N\lambda }$ to Problem $B^{\lambda N}$ thus completing the circuit.

References

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↑ Ross, I. M., “A Historical Introduction to the Covector Mapping Principle,” Proceedings of the 2005 AAS/AIAA Astrodynamics Specialist Conference, August 7–11, 2005 Lake Tahoe, CA. AAS 05-332.
↑ Q. Gong, I. M. Ross, W. Kang, F. Fahroo, Connections between the covector mapping theorem and convergence of pseudospectral methods for optimal control, Computational Optimization and Applications, Vol. 41, pp. 307–335, 2008
↑ Ross, I. M. and Fahroo, F., “Legendre Pseudospectral Approximations of Optimal Control Problems,” Lecture Notes in Control and Information Sciences, Vol. 295, Springer-Verlag, New York, 2003, pp 327–342.
↑ Ross, I. M. and Fahroo, F., “Discrete Verification of Necessary Conditions for Switched Nonlinear Optimal Control Systems,” Proceedings of the American Control Conference, June 2004, Boston, MA
↑ Ross, I. M. and Fahroo, F., “A Pseudospectral Transformation of the Covectors of Optimal Control Systems,” Proceedings of the First IFAC Symposium on System Structure and Control, Prague, Czech Republic, 29–31 August 2001.
↑ W. Kang, I. M. Ross, Q. Gong, Pseudospectral optimal control and its convergence theorems, Analysis and Design of Nonlinear Control Systems, Springer, pp.109–124, 2008.
↑ I. M. Ross and F. Fahroo, A Perspective on Methods for Trajectory Optimization, Proceedings of the AIAA/AAS Astrodynamics Conference, Monterey, CA, August 2002. Invited Paper No. AIAA 2002-4727.
↑ Bryson, A.E. and Ho, Y.C. Applied optimal control. Hemisphere, Washington, DC, 1969.
↑ Ross, I. M. A Primer on Pontryagin's Principle in Optimal Control. Collegiate Publishers. Carmel, CA, 2009. ISBN 978-0-9843571-0-9.

[R1-1] Ross, I. M., “A Historical Introduction to the Covector Mapping Principle,” Proceedings of the 2005 AAS/AIAA Astrodynamics Specialist Conference, August 7–11, 2005 Lake Tahoe, CA. AAS 05-332.

[2] Q. Gong, I. M. Ross, W. Kang, F. Fahroo, Connections between the covector mapping theorem and convergence of pseudospectral methods for optimal control, Computational Optimization and Applications, Vol. 41, pp. 307–335, 2008

[R2-3] Ross, I. M. and Fahroo, F., “Legendre Pseudospectral Approximations of Optimal Control Problems,” Lecture Notes in Control and Information Sciences, Vol. 295, Springer-Verlag, New York, 2003, pp 327–342.

[R3-4] Ross, I. M. and Fahroo, F., “Discrete Verification of Necessary Conditions for Switched Nonlinear Optimal Control Systems,” Proceedings of the American Control Conference, June 2004, Boston, MA

[R4-5] Ross, I. M. and Fahroo, F., “A Pseudospectral Transformation of the Covectors of Optimal Control Systems,” Proceedings of the First IFAC Symposium on System Structure and Control, Prague, Czech Republic, 29–31 August 2001.

[6] W. Kang, I. M. Ross, Q. Gong, Pseudospectral optimal control and its convergence theorems, Analysis and Design of Nonlinear Control Systems, Springer, pp.109–124, 2008.

[7] I. M. Ross and F. Fahroo, A Perspective on Methods for Trajectory Optimization, Proceedings of the AIAA/AAS Astrodynamics Conference, Monterey, CA, August 2002. Invited Paper No. AIAA 2002-4727.

[8] Bryson, A.E. and Ho, Y.C. Applied optimal control. Hemisphere, Washington, DC, 1969.

[9] Ross, I. M. A Primer on Pontryagin's Principle in Optimal Control. Collegiate Publishers. Carmel, CA, 2009. ISBN 978-0-9843571-0-9.

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+The '''covector mapping principle''' is a special case of [[Riesz_representation_theorem|Riesz' representation theorem]], which is a fundamental theorem in functional analysis.
+The name was coined by  by [[I. Michael Ross|Ross]] and co-workers,<ref name = "R1">Ross, I. M., “A Historical Introduction to the Covector Mapping Principle,” Proceedings of the 2005 AAS/AIAA Astrodynamics Specialist Conference, August 7–11, 2005 Lake Tahoe, CA. AAS 05-332.</ref><ref>
+Q. Gong, I. M. Ross, W. Kang, F. Fahroo, Connections between the covector mapping theorem and convergence of pseudospectral methods for optimal control, Computational Optimization and Applications, Vol. 41, pp. 307–335, 2008</ref>
+<ref name ="R2">Ross, I. M. and Fahroo, F., “Legendre Pseudospectral Approximations of Optimal Control Problems,” Lecture Notes in Control and Information Sciences, Vol. 295, Springer-Verlag, New York, 2003, pp 327–342.</ref><ref name = "R3">Ross, I. M. and Fahroo, F., “Discrete Verification of Necessary Conditions for Switched Nonlinear Optimal Control Systems,” Proceedings of the American Control Conference, June 2004, Boston, MA</ref><ref name = "R4">Ross, I. M. and Fahroo, F., “A Pseudospectral Transformation of the Covectors of Optimal Control Systems,” Proceedings of the First IFAC Symposium on System Structure and Control, Prague, Czech Republic, 29–31 August 2001.</ref><ref>W. Kang, I. M. Ross, Q. Gong, Pseudospectral optimal control and its convergence theorems, Analysis and Design of Nonlinear Control Systems, Springer, pp.109–124, 2008.</ref>
+It provides conditions under which dualization can be commuted with [[discretization]] in the case of  computational [[optimal control]].
+==Description==
+An application of [[Pontryagin's minimum principle]] to Problem <math> B </math>, a given optimal control problem generates a [[boundary value problem]].  According to Ross, this boundary value problem is a Pontryagin lift and is represented as Problem <math>B^\lambda</math>. [[Image:CMP-OptimalControl.png|thumb|300px|center|Illustration of the Covector Mapping Principle (adapted from Ross and Fahroo
+.<ref>I. M. Ross and F. Fahroo, A Perspective on Methods for Trajectory Optimization,  ''Proceedings of the AIAA/AAS Astrodynamics Conference'', Monterey, CA, August 2002. Invited Paper No. AIAA 2002-4727.</ref>]] Now suppose one discretizes Problem <math>B^\lambda</math>.  This generates Problem<math>B^{\lambda N}</math> where <math>N</math> represents the number of discrete pooints. For convergence, it is necessary to prove that as
+:<math> N \to \infty, \quad \text{Problem } B^{\lambda N} \to \text{Problem } B^\lambda </math>
+In the 1960s Kalman and others <ref>Bryson, A.E. and Ho, Y.C. Applied optimal control. Hemisphere, Washington, DC, 1969.</ref> showed that solving Problem <math> B^{\lambda N}</math> is extremely difficult.  This difficulty, known as the curse of complexity,<ref>Ross, I. M. A Primer on Pontryagin's Principle in Optimal Control. Collegiate Publishers. Carmel, CA, 2009. ISBN 978-0-9843571-0-9.</ref>  is complementary to the curse of dimensionality.
+In a series of papers starting in the late 1990s, Ross and Fahroo showed that one could arrive at a solution to Problem <math> B^{\lambda}</math> (and hence Problem <math> B </math>) more easily by discretizing first (Problem <math> B^{N}</math>) and dualizing afterwards (Problem <math> B^{N \lambda}</math>).  The sequence of operations must be done carefully to ensure consistency and convergence.  The covector mapping principle asserts that a covector mapping theorem can be discovered to map the solutions of Problem <math> B^{N \lambda}</math> to Problem <math> B^{\lambda N}</math> thus completing the circuit.
+==See also==
+*[[Legendre pseudospectral method]]
+*[[Ross–Fahroo pseudospectral method]]s
+*[[Ross–Fahroo lemma]]
+==References==
+{{Reflist}}
+[[Category:Optimal control]]

Tate curve: Difference between revisions

Revision as of 21:17, 26 January 2014

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