Costate equation

The costate equation is related to the state equation used in optimal control.^[1]^[2] It is also referred to as auxiliary, adjoint, influence, or multiplier equation. It is stated as a vector of first order differential equations

{\dot {\lambda }}^{\mathsf {T}}(t)=-{\frac {\partial H}{\partial x}}

where the right-hand side is the vector of partial derivatives of the negative of the Hamiltonian with respect to the state variables.

Interpretation

The costate variables $\lambda (t)$ can be interpreted as Lagrange multipliers associated with the state equations. The state equations represent constraints of the minimization problem, and the costate variables represent the marginal cost of violating those constraints; in economic terms the costate variables are the shadow prices.

Solution

The state equation is subject to an initial condition and are solved forwards in time. The costate equation must satisfy a terminal condition and are solved backwards in time, from the final time towards the beginning. For more details see Pontryagin's maximum principle.^[3]

References

↑ Kamien, Morton I.; Schwartz, Nancy L. (1991). Dynamic Optimization (Second ed.). London: North-Holland. pp. 126–27. ISBN 0-444-01609-0.
↑ Luenberger, David G. (1969). Optimization by Vector Space Methods. New York: John Wiley & Sons. p. 263.
↑ Ross, I. M. A Primer on Pontryagin's Principle in Optimal Control, Collegiate Publishers, 2009. ISBN 978-0-9843571-0-9.

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Costate equation

Interpretation

Solution

See also

References