In this thesis, we apply machine learning techniques and statistical analysis towards the learning and validation of human control strategy (HCS) models. This work has potential impact in a number of applications ranging from space telerobotics and real-time training to the Intelligent Vehicle Highway System (IVHS) and human-machine interfacing. We specifically focus on the following two important questions: (1) how to efficiently and effectively model human control strategies from real-time human control data and (2) how to validate the performance of the learned HCS models in the feedback control loop. To these ends, we propose two discrete-time modeling frameworks, one for continuous and another for discontinuous human control strategies. For the continuous case, we propose and develop an efficient neural-network learning architecture that combines flexible cascade neural networks with extended Kalman filtering. This learning architecture demonstrates convergence to better local minima in many fewer epochs than alternative, competing neural network learning regimes. For the discontinuous case, we propose and develop a statistical framework that models control actions by individual statistical models. A stochastic selection criterion, based on the posterior probabilities for each model, then selects a particular control action at each time step.

Next, we propose and develop a stochastic similarity measure - based on Hidden Markov Model (HMM) analysis - that compares dynamic, stochastic control trajectories. We derive important properties for this similarity measure, and then, by quantifying the similarity between model-generated control trajectories and corresponding human control data, apply this measure towards validating the learned models of human control strategy. The degree of similarity (or dissimilarity) between a model and its training data indicates how appropriate a specific modeling approach is within a specific context. Throughout, the learning and validation methods proposed herein are tested on human control data, collected through a dynamic, graphic driving simulator that we have developed for this purpose. In addition, we analyze actual driving data collected through the Navlab project at Carnegie Mellon University.