An examination of major works for wind band: “National emblem march” by Edwin Eugene Bagley ed. by Frederick Fennell, “On an American spiritual” by David Holsinger, “Portraits” by Jim Colonna, “Serenade, Op. 22 (c)” by Derek Bourgeois.

Bistline, Michael E.

January 1900

Master of Music / Department of Music / Frank C. Tracz / The following report is an in depth research and analysis project based on the graduation requirement for a Masters in Music Degree from Kansas State University. The product of this project was a conducting recital performed by Michael E. Bistline with the Union High School Concert Band. This performance was held on May 5, 2009 in Matt Auditorium at Union High School. The repertoire included National Emblem March by E.E. Bagley/edited by Frederick Fennell, On An American Spiritual by David Holsinger, Portraits by Jim Colonna, and Serenade Op. 22 (c) by Derek Bourgeois. The theoretical, historical and technical analyses of this project was collected using the Unit of the Teacher Resource Guide, developed by Richard Miles and the Macro, Micro, Macro score analysis form developed by Dr. Frank Tracz. This report also includes documentation of the planning and evaluation of each rehearsal.

Education, Music (0522)

Modeling a Dynamic System Using Fractional Order Calculus

Jordan D.F. Petty (9216107)

06 August 2020

<p>Fractional calculus is the integration and differentiation to an arbitrary or fractional order. The techniques of fractional calculus are not commonly taught in engineering curricula since physical laws are expressed in integer order notation. Dr. Richard Magin (2006) notes how engineers occasionally encounter dynamic systems in which the integer order methods do not properly model the physical characteristics and lead to numerous mathematical operations. In the following study, the application of fractional order calculus to approximate the angular position of the disk oscillating in a Newtonian fluid was experimentally validated. The proposed experimental study was conducted to model the nonlinear response of an oscillating system using fractional order calculus. The integer and fractional order mathematical models solved the differential equation of motion specific to the experiment. The experimental results were compared to the integer order and the fractional order analytical solutions. The fractional order mathematical model in this study approximated the nonlinear response of the designed system by using the Bagley and Torvik fractional derivative. The analytical results of the experiment indicate that either the integer or fractional order methods can be used to approximate the angular position of the disk oscillating in the homogeneous solution. The following research was in collaboration with Dr. Richard Mark French, Dr. Garcia Bravo, and Rajarshi Choudhuri, and the experimental design was derived from the previous experiments conducted in 2018.</p>

Mechanical Engineering

Computational Fluid Dynamics

Fluidisation and Fluid Mechanics

Dynamical Systems in Applications

Theoretical and Applied Mechanics

Fluid Mechanics

Applied Mathematics

Fractional Calculus

Navier-Stokes equation

Bagley-Torvik equation

Engineering