When an observer moves through the environment, self-motion creates large-field patterns of visual motion known as optic flow. Cortical processing of optic flow is important for perception of self-motion, as demonstrated in animal models. In most navigation behaviors, such as driving a vehicle, optic-flow processing is part of an active sensing loop in which self-motion produces optic flow which is, in turn, used to change direction at the next instant of time. While this is a natural mode of optic flow processing, almost all previous studies of neural processing of optic flow involve passive self-motion without an active control component. Indeed, the patterns of optic flow that are experienced when steering a vehicle along a curved path are quite different than those typically used to study cortical neurons. Thus, what we know about cortical processing of optic flow is generally not applicable to control of steering. Furthermore, to effectively steer, control theory indicates that optic flow signals should be combined with efference copy of motor commands and working memory signals, but essentially nothing is known about these critical interactions. We propose a tightly integrated program of research, involving behavior, neurophysiology and theory, that will provide the first systematic study of the neural mechanisms of visually guided steering control. In Aim #1, we train monkeys to steer through a virtual environment to align their heading with the remembered direction of a briefly flashed target. We develop optimal stochastic control theory for our task, and we fit the model to behavioral data to extract estimates of key latent variables that govern steering control. In Aim #2, we record from populations of neurons in areas MSTd and 7a during performance of the steering task. Using both model-free and model-based analyses, we test specific hypotheses about how and where the critical variables for steering control are represented in the brain. Our strong preliminary data suggest that we will make important advances in understanding cortical processing of optic flow in a more natural active-sensing context. The proposed research is directly relevant to the research priorities of the Strabismus, Amblyopia, and Visual Processing program at the National Eye Institute.