Fuzzy Attitude Control of a Magnetically Actuated CubeSat

Walker, Alex R.

January 2013

No description available.

Aerospace Materials

Attitude Control

CubeSat

Magnetic

Fuzzy Logic

Genetic Algorithm

Genetic Fuzzy Controller for a Gas Turbine Fuel System

Vick, Andrew W.

January 2010

No description available.

Aerospace Materials

Genetic Algorithm

Fuzzy Logic

Gas Turbine

Fuel System

Fuzzy counter Ant Algorithm for Maze Problem

Ahuja, Mohit

20 April 2011

No description available.

Aerospace Materials

Fuzzy Logic

Ant

Maze

Khepera

Carrot or Stick

Fuzzy Logic Seismic Vibration Control of Buildings

Edalath, Sanooj Sadique

18 September 2012

No description available.

Civil Engineering

Fuzzy logic

Seismic

Controls

Structures

TMD

Base isolators

DESIGN OF A CONTROLLER TO CONTROL LIGHT LEVEL IN A COMMERCIAL OFFICE

JAVIDBAKHT, SAEID

03 December 2007

No description available.

Fluorescent lamp

electronic ballast

light sensor

simulation

fuzzy logic controller

The Harmonic Distortion Reduction of Phase-Angle Fired SCRs Feeding a Resistive Load using Fuzzy Logic

Clark, Matthew A.

15 April 2010

No description available.

Electrical Engineering

Fuzzy Logic

Control

Power

SCR

Harmonics

Substations

Guidance of a Small Spacecraft for Soft Landing on an Asteroid using Fuzzy Control

Hartmann, Jacob

15 October 2015

No description available.

Aerospace Materials

fuzzy logic control

asteroid

spacecraft guidance

Verification of Genetic Fuzzy Systems

Arnett, Timothy J.

06 June 2016

No description available.

Aerospace Materials

fuzzy logic

verification

model checking

genetic algorithm

Rule-Based Approaches for Controlling on Mode Dynamic Systems

Moon, Myung Soo

27 August 1997

This dissertation presents new fuzzy logic techniques for designing control systems for a wide class of complex systems. The methods are developed in detail for a crane system which contains one rigid-body and one oscillation mode. The crane problem is to transfer the rigid body a given distance such that the pendulation of the oscillation mode is regulated at the final time using a single control input. The investigations include in-depth studies of the time-optimal crane control problem as an integral part of the work. The main contributions of this study are: (1) Development of rule-based systems (both fuzzy and crisp) for the design of optimal controllers. This development involves control variable parametrization, rule derivation with parameter perturbation methods, and the design of rule based controllers, which can be combined with model-based feedback control methods. (2) A thorough investigation and analysis of the solutions for time-optimal control problems of oscillation mode systems, with particular emphasis on the use of phase-plane interpretation. (3) Development of fuzzy logic control system methodology using expert rules obtained through energy reducing considerations. In addition, dual mode control is a "spin-off" design method which, although no longer time optimal, can be viewed as a near-optimal control method which may be easier to implement. In both types of design optimization of the fuzzy logic controller can be used to improve performance. / Ph. D.

Rule-Based System

Fuzzy Logic

Time-Optimal Control

Crane Control

Design Optimization of Fuzzy Logic Systems

Dadone, Paolo

29 May 2001

Fuzzy logic systems are widely used for control, system identification, and pattern recognition problems. In order to maximize their performance, it is often necessary to undertake a design optimization process in which the adjustable parameters defining a particular fuzzy system are tuned to maximize a given performance criterion. Some data to approximate are commonly available and yield what is called the supervised learning problem. In this problem we typically wish to minimize the sum of the squares of errors in approximating the data. We first introduce fuzzy logic systems and the supervised learning problem that, in effect, is a nonlinear optimization problem that at times can be non-differentiable. We review the existing approaches and discuss their weaknesses and the issues involved. We then focus on one of these problems, i.e., non-differentiability of the objective function, and show how current approaches that do not account for non-differentiability can diverge. Moreover, we also show that non-differentiability may also have an adverse practical impact on algorithmic performances. We reformulate both the supervised learning problem and piecewise linear membership functions in order to obtain a polynomial or factorable optimization problem. We propose the application of a global nonconvex optimization approach, namely, a reformulation and linearization technique. The expanded problem dimensionality does not make this approach feasible at this time, even though this reformulation along with the proposed technique still bears a theoretical interest. Moreover, some future research directions are identified. We propose a novel approach to step-size selection in batch training. This approach uses a limited memory quadratic fit on past convergence data. Thus, it is similar to response surface methodologies, but it differs from them in the type of data that are used to fit the model, that is, already available data from the history of the algorithm are used instead of data obtained according to an experimental design. The step-size along the update direction (e.g., negative gradient or deflected negative gradient) is chosen according to a criterion of minimum distance from the vertex of the quadratic model. This approach rescales the complexity in the step-size selection from the order of the (large) number of training data, as in the case of exact line searches, to the order of the number of parameters (generally lower than the number of training data). The quadratic fit approach and a reduced variant are tested on some function approximation examples yielding distributions of the final mean square errors that are improved (i.e., skewed toward lower errors) with respect to the ones in the commonly used pattern-by-pattern approach. Moreover, the quadratic fit is also competitive and sometimes better than the batch training with optimal step-sizes, thus showing an improved performance of this approach. The quadratic fit approach is also tested in conjunction with gradient deflection strategies and memoryless variable metric methods, showing errors smaller by 1 to 7 orders of magnitude. Moreover, the convergence speed by using either the negative gradient direction or a deflected direction is higher than that of the pattern-by-pattern approach, although the computational cost of the algorithm per iteration is moderately higher than the one of the pattern-by-pattern method. Finally, some directions for future research are identified. / Ph. D.

Non-differentiable optimization

Supervised learning

Optimization

Fuzzy logic systems