Investigating the combustion mechanisms of bulk meteals through micoranalysis of post-test 3.2mm diameter metallic rods burned in oxygen-enriched atmospheres

De Wit, J. R.

Unknown Date

No description available.

299902 Combustion and Fuel Engineering

671401 Scientific instrumentation

Robust control of an articulating flexible structure using MIMO QFT

Kerr, M.

Unknown Date

No description available.

230119 Systems Theory and Control

671401 Scientific instrumentation

Optimal placement of distributed actuators on a multi-link flexible manipulator

Maxwell, Nigel

Unknown Date

No description available.

230119 Systems Theory and Control

671401 Scientific instrumentation

Optimal placement of distributed actuators on a multi-link flexible manipulator

Maxwell, Nigel

Unknown Date

No description available.

230119 Systems Theory and Control

671401 Scientific instrumentation

Robust control of an articulating flexible structure using MIMO QFT

Kerr, Murray Lawrence

Unknown Date

Quantitative Feedback Theory (QFT) is a control system design methodology founded on the premise that feedback is necessary only because of system uncertainty. Articulating flexible structures, such as flexible manipulators, present a difficult closed-loop control problem. In such servo systems, the coupling of the rigid and flexible modes and the non-minimum phase dynamics severely limit system stability and performance. The difficulties in controlling these structures is exacerbated by the denumerably infinite number of flexible modes and associated difficulties in developing accurate dynamic models for controller design. As such, the control of articulating flexible structures presents a non-trivial testbed for the design of QFT based robust control systems. This dissertation examines the multi-input multi-output (MIMO) QFT based control of an articulating flexible structure and presents an enhancement of the theoretical basis for the MIMO QFT design methodologies. The control problem under consideration is the active vibration control of an articulating single-link flexible manipulator. This is facilitated by an actuation scheme comprised of a combination of spatially discrete actuation, in the form of a DC motor to perform articulation, and spatially distributed actuation, in the form of a piezoelectric transducer for active vibration control. In the process of developing and experimentally validating the QFT based control system, shortcomings in the theoretical basis for the MIMO QFT design methodologies are addressed. Robust stability theorems are developed for the two main MIMO QFT design methodologies, namely the sequential and non-sequential MIMO QFT design methodologies. The theorems complement and extend the existing theoretical basis for the MIMO QFT design methodologies. The dissertation results expose salient features of the MIMO QFT design methodologies and provide connections to other multivariable design methodologies.

230119 Systems Theory and Control

671401 Scientific instrumentation

QFT

Control

Multivariable Control

Robust Control

Flexible Manipulator

Piezoelectric

Robust control of an articulating flexible structure using MIMO QFT

Kerr, Murray Lawrence

Unknown Date

Quantitative Feedback Theory (QFT) is a control system design methodology founded on the premise that feedback is necessary only because of system uncertainty. Articulating flexible structures, such as flexible manipulators, present a difficult closed-loop control problem. In such servo systems, the coupling of the rigid and flexible modes and the non-minimum phase dynamics severely limit system stability and performance. The difficulties in controlling these structures is exacerbated by the denumerably infinite number of flexible modes and associated difficulties in developing accurate dynamic models for controller design. As such, the control of articulating flexible structures presents a non-trivial testbed for the design of QFT based robust control systems. This dissertation examines the multi-input multi-output (MIMO) QFT based control of an articulating flexible structure and presents an enhancement of the theoretical basis for the MIMO QFT design methodologies. The control problem under consideration is the active vibration control of an articulating single-link flexible manipulator. This is facilitated by an actuation scheme comprised of a combination of spatially discrete actuation, in the form of a DC motor to perform articulation, and spatially distributed actuation, in the form of a piezoelectric transducer for active vibration control. In the process of developing and experimentally validating the QFT based control system, shortcomings in the theoretical basis for the MIMO QFT design methodologies are addressed. Robust stability theorems are developed for the two main MIMO QFT design methodologies, namely the sequential and non-sequential MIMO QFT design methodologies. The theorems complement and extend the existing theoretical basis for the MIMO QFT design methodologies. The dissertation results expose salient features of the MIMO QFT design methodologies and provide connections to other multivariable design methodologies.

230119 Systems Theory and Control

671401 Scientific instrumentation

QFT

Control

Multivariable Control

Robust Control

Flexible Manipulator

Piezoelectric