Optimality Conditions and Regularity Properties in Infinite-Dimensional Optimal Control Problems

The results on Strong Metric sub-Regularity (SMsR) and Strong Metric Regularity (SMR) can be extended to broader classes of optimal control problems by adapting the definitions and conditions to accommodate additional complexities such as state constraints and more general cost functionals. Incorporating State Constraints: For optimal control problems with state constraints, the set of admissible states must be carefully defined. The regularity properties can be analyzed by considering the active constraints at the reference solution. The framework established in the paper can be modified to include a set-valued mapping that accounts for the state constraints, similar to how the normal cone is defined for control constraints. This would involve ensuring that the gradients of the state constraints are linearly independent, which is crucial for the application of the Mangasarian-Fromovitz constraint qualification (MFCQ). General Cost Functionals: When extending to more general cost functionals, one can consider cost functionals that are not merely quadratic or linear but may involve higher-order terms or non-convex components. The analysis would require establishing conditions under which the optimality mapping remains well-defined and exhibits the desired regularity properties. This could involve using techniques from variational analysis to derive sufficient conditions for SMsR and SMR that are tailored to the specific structure of the cost functional. Robustness of Results: The robustness of the established results can be leveraged by employing perturbation techniques. By showing that the SMsR and SMR properties hold under small perturbations of the control or state variables, one can generalize the findings to a wider class of problems. This approach is particularly useful in practical applications where exact conditions may not be met, but approximate conditions can still yield valid results.

The established regularity properties, specifically SMsR and SMR, have significant implications for the convergence analysis of numerical methods applied to optimal control problems. Stability of Solutions: The regularity properties imply that small perturbations in the input (such as disturbances in the control or state variables) lead to controlled changes in the output (the optimal solution). This stability is crucial for numerical methods, as it ensures that the numerical solutions will not diverge significantly from the true solutions when subjected to small errors or approximations. Convergence Rates: The SMsR and SMR properties provide estimates for the convergence rates of numerical algorithms. For instance, if a numerical method approximates the optimal control problem, the regularity conditions can be used to derive bounds on how quickly the numerical solution converges to the true solution as the discretization parameters are refined. This is particularly important in iterative methods where convergence speed is a key performance metric. Error Analysis: The established regularity properties facilitate a rigorous error analysis of numerical methods. By understanding how the optimality mapping behaves under perturbations, one can quantify the errors introduced by numerical approximations. This allows for the development of adaptive algorithms that can adjust their parameters based on the regularity properties of the problem, leading to more efficient and accurate solutions.

Yes, there are notable connections between the regularity properties studied in this paper and the concept of generalized derivatives, particularly coderivatives, which have been instrumental in characterizing metric regularity in various contexts. Generalized Derivatives: Coderivatives provide a framework for analyzing the sensitivity of set-valued mappings, which is closely related to the concepts of SMsR and SMR. The coderivative captures how the output of a set-valued mapping changes in response to perturbations in the input, similar to how the regularity properties describe the stability of solutions under disturbances. Characterization of Regularity: In finite-dimensional spaces, the regularity properties can often be characterized in terms of graphical derivatives and coderivatives. The results in the paper can be seen as an extension of these characterizations to infinite-dimensional spaces, where the complexity of the mappings necessitates a more nuanced approach. The use of coderivatives can help establish conditions under which the SMsR and SMR properties hold, thereby linking the two concepts. Applications in Optimization: The interplay between regularity properties and generalized derivatives is particularly relevant in optimization problems, where understanding the behavior of the optimality mapping is crucial. Coderivatives can be used to derive necessary and sufficient conditions for the regularity properties, thus providing a robust theoretical foundation for the analysis of optimal control problems. In summary, the connections between regularity properties and generalized derivatives enrich the understanding of stability and convergence in optimal control problems, offering a comprehensive framework for analyzing the behavior of solutions under various perturbations.