Reinforcement learning in high-diameter, continuous environments

Provost, Jefferson, 1968-

28 August 2008

Many important real-world robotic tasks have high diameter, that is, their solution requires a large number of primitive actions by the robot. For example, they may require navigating to distant locations using primitive motor control commands. In addition, modern robots are endowed with rich, high-dimensional sensory systems, providing measurements of a continuous environment. Reinforcement learning (RL) has shown promise as a method for automatic learning of robot behavior, but current methods work best on lowdiameter, low-dimensional tasks. Because of this problem, the success of RL on real-world tasks still depends on human analysis of the robot, environment, and task to provide a useful set of perceptual features and an appropriate decomposition of the task into subtasks. This thesis presents Self-Organizing Distinctive-state Abstraction (SODA) as a solution to this problem. Using SODA a robot with little prior knowledge of its sensorimotor system, environment, and task can automatically reduce the effective diameter of its tasks. First it uses a self-organizing feature map to learn higher level perceptual features while exploring using primitive, local actions. Then, using the learned features as input, it learns a set of high-level actions that carry the robot between perceptually distinctive states in the environment. Experiments in two robot navigation environments demonstrate that SODA learns useful features and high-level actions, that using these new actions dramatically speeds up learning for high-diameter navigation tasks, and that the method scales to large (buildingsized) robot environments. These experiments demonstrate SODAs effectiveness as a generic learning agent for mobile robot navigation, pointing the way toward developmental robots that learn to understand themselves and their environments through experience in the world, reducing the need for human engineering for each new robotic application. / text

Robots--Control systems

Machine learning

Controller design for cable-driven teleoperator system with a massive slave

Wai, Check-chiu., 衛卓超.

January 2003

published_or_final_version / abstract / toc / Industrial and Manufacturing Systems Engineering / Master / Master of Philosophy

Robots - Control systems.

Remote control.

The design and evaluation of a flight simulator apparatus

Kaith, Irving, 1928-

January 1960

No description available.

Flight simulators.

Airplanes -- Control systems.

INTEGRATION OF ANALYTICAL AND CONVENTIONAL DESIGN TECHNIQUES FOR OPTIMUM CONTROL SYSTEMS

Streets, Rubert Burley

January 1963

No description available.

Feedback control systems.

Electronic control.

DESIGN OF NONLINEAR CONTROL SYSTEMS VIA STATE VARIABLE FEEDBACK

Herring, John Wesley, 1927-

January 1967

No description available.

Systems engineering.

Feedback control systems.

THE DESIGN OF LINEAR MULTIVARIABLE CONTROL SYSTEMS USING MODERN CONTROL THEORY

Slivinsky, Charles Robert, 1941-

January 1969

No description available.

Feedback control systems.

Systems engineering.

MULTIPLE INPUT-OUTPUT FEEDBACK SYNTHESIS INCORPORATING CROSS-COUPLING

Ferg, David Alvin, 1943-

January 1971

No description available.

Practical applications of state variable feedback

Brannen, Daniel Eugene, 1943-

January 1969

No description available.

Feedback control systems.

Automatic control.

State variable feedback design of a control system for a coupled- core reactor

Remshaw, Richard Patrick, 1943-

January 1968

No description available.

Nuclear reactors.

Feedback control systems.

Deadbeat control of linear sampled-data control systems using multiple feedback paths

Gibbons, James Henry, 1933-

January 1965

No description available.

Control theory.

Feedback control systems.