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You searched for +publisher:"University of Colorado" +contributor:("John A. Evans"). Showing records 1 – 17 of 17 total matches.

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University of Colorado

1. Pope, David. Implementing a Loosely Coupled Fluid Structure Interaction Finite Element Model in PHASTA.

Degree: MS, Aerospace Engineering Sciences, 2015, University of Colorado

  Fluid Structure Interaction problems are an important multi-physics phenomenon in the design of aerospace vehicles and other engineering applications. A variety of computational fluid… (more)

Subjects/Keywords: ALE; Structural Equations; Aerodynamics and Fluid Mechanics

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APA (6th Edition):

Pope, D. (2015). Implementing a Loosely Coupled Fluid Structure Interaction Finite Element Model in PHASTA. (Masters Thesis). University of Colorado. Retrieved from http://scholar.colorado.edu/asen_gradetds/109

Chicago Manual of Style (16th Edition):

Pope, David. “Implementing a Loosely Coupled Fluid Structure Interaction Finite Element Model in PHASTA.” 2015. Masters Thesis, University of Colorado. Accessed October 19, 2019. http://scholar.colorado.edu/asen_gradetds/109.

MLA Handbook (7th Edition):

Pope, David. “Implementing a Loosely Coupled Fluid Structure Interaction Finite Element Model in PHASTA.” 2015. Web. 19 Oct 2019.

Vancouver:

Pope D. Implementing a Loosely Coupled Fluid Structure Interaction Finite Element Model in PHASTA. [Internet] [Masters thesis]. University of Colorado; 2015. [cited 2019 Oct 19]. Available from: http://scholar.colorado.edu/asen_gradetds/109.

Council of Science Editors:

Pope D. Implementing a Loosely Coupled Fluid Structure Interaction Finite Element Model in PHASTA. [Masters Thesis]. University of Colorado; 2015. Available from: http://scholar.colorado.edu/asen_gradetds/109


University of Colorado

2. Rothstein-Dowden, Ansel. Isogeometric Analysis of Subsonic Aerodynamic Flows with Application to Shape Optimization.

Degree: MS, 2018, University of Colorado

  The preliminary design phase of any engineering project is characterized by computationally efficient low-fidelity predictive modeling to inform early-stage design choices. It is essential… (more)

Subjects/Keywords: aerodynamics; isogeometric; optimization; fidelity; design-analysis; Aerodynamics and Fluid Mechanics; Aerospace Engineering

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APA (6th Edition):

Rothstein-Dowden, A. (2018). Isogeometric Analysis of Subsonic Aerodynamic Flows with Application to Shape Optimization. (Masters Thesis). University of Colorado. Retrieved from https://scholar.colorado.edu/asen_gradetds/201

Chicago Manual of Style (16th Edition):

Rothstein-Dowden, Ansel. “Isogeometric Analysis of Subsonic Aerodynamic Flows with Application to Shape Optimization.” 2018. Masters Thesis, University of Colorado. Accessed October 19, 2019. https://scholar.colorado.edu/asen_gradetds/201.

MLA Handbook (7th Edition):

Rothstein-Dowden, Ansel. “Isogeometric Analysis of Subsonic Aerodynamic Flows with Application to Shape Optimization.” 2018. Web. 19 Oct 2019.

Vancouver:

Rothstein-Dowden A. Isogeometric Analysis of Subsonic Aerodynamic Flows with Application to Shape Optimization. [Internet] [Masters thesis]. University of Colorado; 2018. [cited 2019 Oct 19]. Available from: https://scholar.colorado.edu/asen_gradetds/201.

Council of Science Editors:

Rothstein-Dowden A. Isogeometric Analysis of Subsonic Aerodynamic Flows with Application to Shape Optimization. [Masters Thesis]. University of Colorado; 2018. Available from: https://scholar.colorado.edu/asen_gradetds/201


University of Colorado

3. O'Neill, Nathanial James. Standard and Inception-Based Encoder-Decoder Neural Networks for Predicting the Solution Convergence of Design Optimization Algorithms.

Degree: MS, Aerospace Engineering Sciences, 2019, University of Colorado

  The goal of this work is to investigate the ways in which the capabilities of machine learning algorithms, specifically those of neural networks, can… (more)

Subjects/Keywords: convolutional neural network; design optimization; encoder decoder; inception; neural network; topology optimization; Aerospace Engineering; Computer Sciences; Mechanical Engineering

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APA (6th Edition):

O'Neill, N. J. (2019). Standard and Inception-Based Encoder-Decoder Neural Networks for Predicting the Solution Convergence of Design Optimization Algorithms. (Masters Thesis). University of Colorado. Retrieved from https://scholar.colorado.edu/asen_gradetds/247

Chicago Manual of Style (16th Edition):

O'Neill, Nathanial James. “Standard and Inception-Based Encoder-Decoder Neural Networks for Predicting the Solution Convergence of Design Optimization Algorithms.” 2019. Masters Thesis, University of Colorado. Accessed October 19, 2019. https://scholar.colorado.edu/asen_gradetds/247.

MLA Handbook (7th Edition):

O'Neill, Nathanial James. “Standard and Inception-Based Encoder-Decoder Neural Networks for Predicting the Solution Convergence of Design Optimization Algorithms.” 2019. Web. 19 Oct 2019.

Vancouver:

O'Neill NJ. Standard and Inception-Based Encoder-Decoder Neural Networks for Predicting the Solution Convergence of Design Optimization Algorithms. [Internet] [Masters thesis]. University of Colorado; 2019. [cited 2019 Oct 19]. Available from: https://scholar.colorado.edu/asen_gradetds/247.

Council of Science Editors:

O'Neill NJ. Standard and Inception-Based Encoder-Decoder Neural Networks for Predicting the Solution Convergence of Design Optimization Algorithms. [Masters Thesis]. University of Colorado; 2019. Available from: https://scholar.colorado.edu/asen_gradetds/247


University of Colorado

4. Coley, Christopher Joel. Residual-Based Large Eddy Simulation of Turbulent Flows Using Divergence-Conforming Discretizations.

Degree: PhD, 2017, University of Colorado

  In this dissertation, a class of methods which combines divergence-conforming discretizations with residual-based subgrid modeling for large eddy simulation of turbulent flows is introduced.… (more)

Subjects/Keywords: Divergence-conforming; Large eddy simulation; Residual-based large eddy simulation; Structure-preserving; Turbulence modeling; Variational multiscale method; Aerospace Engineering

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APA (6th Edition):

Coley, C. J. (2017). Residual-Based Large Eddy Simulation of Turbulent Flows Using Divergence-Conforming Discretizations. (Doctoral Dissertation). University of Colorado. Retrieved from https://scholar.colorado.edu/asen_gradetds/172

Chicago Manual of Style (16th Edition):

Coley, Christopher Joel. “Residual-Based Large Eddy Simulation of Turbulent Flows Using Divergence-Conforming Discretizations.” 2017. Doctoral Dissertation, University of Colorado. Accessed October 19, 2019. https://scholar.colorado.edu/asen_gradetds/172.

MLA Handbook (7th Edition):

Coley, Christopher Joel. “Residual-Based Large Eddy Simulation of Turbulent Flows Using Divergence-Conforming Discretizations.” 2017. Web. 19 Oct 2019.

Vancouver:

Coley CJ. Residual-Based Large Eddy Simulation of Turbulent Flows Using Divergence-Conforming Discretizations. [Internet] [Doctoral dissertation]. University of Colorado; 2017. [cited 2019 Oct 19]. Available from: https://scholar.colorado.edu/asen_gradetds/172.

Council of Science Editors:

Coley CJ. Residual-Based Large Eddy Simulation of Turbulent Flows Using Divergence-Conforming Discretizations. [Doctoral Dissertation]. University of Colorado; 2017. Available from: https://scholar.colorado.edu/asen_gradetds/172


University of Colorado

5. Engvall, Luke H. Geometrically Exact and Analysis Suitable Mesh Generation Using Rational Bernstein–Bezier Elements.

Degree: PhD, 2018, University of Colorado

  This dissertation presents two novel contributions to the fields of isogeometric analysis and <i>p</i>-version finite elements. First, we present a framework for geometrically exact… (more)

Subjects/Keywords: curvilinear mesh generation; higher-order finite elements; isogeometric analysis; mesh generation; discretization; Engineering; Mechanical Engineering

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APA (6th Edition):

Engvall, L. H. (2018). Geometrically Exact and Analysis Suitable Mesh Generation Using Rational Bernstein–Bezier Elements. (Doctoral Dissertation). University of Colorado. Retrieved from https://scholar.colorado.edu/mcen_gradetds/170

Chicago Manual of Style (16th Edition):

Engvall, Luke H. “Geometrically Exact and Analysis Suitable Mesh Generation Using Rational Bernstein–Bezier Elements.” 2018. Doctoral Dissertation, University of Colorado. Accessed October 19, 2019. https://scholar.colorado.edu/mcen_gradetds/170.

MLA Handbook (7th Edition):

Engvall, Luke H. “Geometrically Exact and Analysis Suitable Mesh Generation Using Rational Bernstein–Bezier Elements.” 2018. Web. 19 Oct 2019.

Vancouver:

Engvall LH. Geometrically Exact and Analysis Suitable Mesh Generation Using Rational Bernstein–Bezier Elements. [Internet] [Doctoral dissertation]. University of Colorado; 2018. [cited 2019 Oct 19]. Available from: https://scholar.colorado.edu/mcen_gradetds/170.

Council of Science Editors:

Engvall LH. Geometrically Exact and Analysis Suitable Mesh Generation Using Rational Bernstein–Bezier Elements. [Doctoral Dissertation]. University of Colorado; 2018. Available from: https://scholar.colorado.edu/mcen_gradetds/170


University of Colorado

6. Benzaken, Joseph David. Propagation and Control of Geometric Variation in Engineering Structural Design and Analysis.

Degree: PhD, 2018, University of Colorado

 In this dissertation, we present a methodology for understanding the propagation and control of geometric variation in engineering design and analysis. This work is comprised… (more)

Subjects/Keywords: design space exploration; manifold optimization; parametric partial differential equations; thin shell structures; tolerance allocation protocols; uncertainty quantification; Aerospace Engineering; Applied Mathematics

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APA (6th Edition):

Benzaken, J. D. (2018). Propagation and Control of Geometric Variation in Engineering Structural Design and Analysis. (Doctoral Dissertation). University of Colorado. Retrieved from https://scholar.colorado.edu/appm_gradetds/108

Chicago Manual of Style (16th Edition):

Benzaken, Joseph David. “Propagation and Control of Geometric Variation in Engineering Structural Design and Analysis.” 2018. Doctoral Dissertation, University of Colorado. Accessed October 19, 2019. https://scholar.colorado.edu/appm_gradetds/108.

MLA Handbook (7th Edition):

Benzaken, Joseph David. “Propagation and Control of Geometric Variation in Engineering Structural Design and Analysis.” 2018. Web. 19 Oct 2019.

Vancouver:

Benzaken JD. Propagation and Control of Geometric Variation in Engineering Structural Design and Analysis. [Internet] [Doctoral dissertation]. University of Colorado; 2018. [cited 2019 Oct 19]. Available from: https://scholar.colorado.edu/appm_gradetds/108.

Council of Science Editors:

Benzaken JD. Propagation and Control of Geometric Variation in Engineering Structural Design and Analysis. [Doctoral Dissertation]. University of Colorado; 2018. Available from: https://scholar.colorado.edu/appm_gradetds/108


University of Colorado

7. Coley, Christopher Joel. Residual-Based Large Eddy Simulation of Turbulent Flows Using Divergence-Conforming Discretizations.

Degree: PhD, 2017, University of Colorado

  In this dissertation, a class of methods which combines divergence-conforming discretizations with residual-based subgrid modeling for large eddy simulation of turbulent flows is introduced.… (more)

Subjects/Keywords: divergence-conforming; large eddy simulation; residual-based large eddy simulation; structure-preserving; turbulence modeling; variational multiscale method; Aerospace Engineering; Applied Mathematics

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APA (6th Edition):

Coley, C. J. (2017). Residual-Based Large Eddy Simulation of Turbulent Flows Using Divergence-Conforming Discretizations. (Doctoral Dissertation). University of Colorado. Retrieved from https://scholar.colorado.edu/asen_gradetds/220

Chicago Manual of Style (16th Edition):

Coley, Christopher Joel. “Residual-Based Large Eddy Simulation of Turbulent Flows Using Divergence-Conforming Discretizations.” 2017. Doctoral Dissertation, University of Colorado. Accessed October 19, 2019. https://scholar.colorado.edu/asen_gradetds/220.

MLA Handbook (7th Edition):

Coley, Christopher Joel. “Residual-Based Large Eddy Simulation of Turbulent Flows Using Divergence-Conforming Discretizations.” 2017. Web. 19 Oct 2019.

Vancouver:

Coley CJ. Residual-Based Large Eddy Simulation of Turbulent Flows Using Divergence-Conforming Discretizations. [Internet] [Doctoral dissertation]. University of Colorado; 2017. [cited 2019 Oct 19]. Available from: https://scholar.colorado.edu/asen_gradetds/220.

Council of Science Editors:

Coley CJ. Residual-Based Large Eddy Simulation of Turbulent Flows Using Divergence-Conforming Discretizations. [Doctoral Dissertation]. University of Colorado; 2017. Available from: https://scholar.colorado.edu/asen_gradetds/220


University of Colorado

8. Shahabi, Farhad. Finite Strain Micromorphic Elasticity, Elastoplasticity, and Dynamics for Multiscale Finite Element Analysis.

Degree: PhD, 2017, University of Colorado

 This study stands as an attempt to consider the micro-structure of materials in a continuum framework by the aid of micromorphic continuum theory in the… (more)

Subjects/Keywords: Dynamics; Elastoplasticity; Finite Element Analysis; Large Deformation; Micromorphic Continuum; Micropolar Continuum; Engineering Mechanics; Mechanical Engineering

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APA (6th Edition):

Shahabi, F. (2017). Finite Strain Micromorphic Elasticity, Elastoplasticity, and Dynamics for Multiscale Finite Element Analysis. (Doctoral Dissertation). University of Colorado. Retrieved from https://scholar.colorado.edu/cven_gradetds/96

Chicago Manual of Style (16th Edition):

Shahabi, Farhad. “Finite Strain Micromorphic Elasticity, Elastoplasticity, and Dynamics for Multiscale Finite Element Analysis.” 2017. Doctoral Dissertation, University of Colorado. Accessed October 19, 2019. https://scholar.colorado.edu/cven_gradetds/96.

MLA Handbook (7th Edition):

Shahabi, Farhad. “Finite Strain Micromorphic Elasticity, Elastoplasticity, and Dynamics for Multiscale Finite Element Analysis.” 2017. Web. 19 Oct 2019.

Vancouver:

Shahabi F. Finite Strain Micromorphic Elasticity, Elastoplasticity, and Dynamics for Multiscale Finite Element Analysis. [Internet] [Doctoral dissertation]. University of Colorado; 2017. [cited 2019 Oct 19]. Available from: https://scholar.colorado.edu/cven_gradetds/96.

Council of Science Editors:

Shahabi F. Finite Strain Micromorphic Elasticity, Elastoplasticity, and Dynamics for Multiscale Finite Element Analysis. [Doctoral Dissertation]. University of Colorado; 2017. Available from: https://scholar.colorado.edu/cven_gradetds/96


University of Colorado

9. Brown-Dymkoski, Eric James. Adaptive Wavelet-Based Turbulence Modeling for Compressible Flows in Complex Geometry.

Degree: PhD, Mechanical Engineering, 2016, University of Colorado

  Turbulent flows, noted for their chaotic dynamic and multiscale nature, are notoriously difficult and expensive to simulate accurately for problems of engineering interest. Adaptive… (more)

Subjects/Keywords: Fluid Dynamics; Numerical Methods; Turbulence; adaptive wavelet collocation method; turbulent stress stability; heat flux stability; kinetic energy field; Fluid Dynamics; Mechanical Engineering

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APA (6th Edition):

Brown-Dymkoski, E. J. (2016). Adaptive Wavelet-Based Turbulence Modeling for Compressible Flows in Complex Geometry. (Doctoral Dissertation). University of Colorado. Retrieved from http://scholar.colorado.edu/mcen_gradetds/133

Chicago Manual of Style (16th Edition):

Brown-Dymkoski, Eric James. “Adaptive Wavelet-Based Turbulence Modeling for Compressible Flows in Complex Geometry.” 2016. Doctoral Dissertation, University of Colorado. Accessed October 19, 2019. http://scholar.colorado.edu/mcen_gradetds/133.

MLA Handbook (7th Edition):

Brown-Dymkoski, Eric James. “Adaptive Wavelet-Based Turbulence Modeling for Compressible Flows in Complex Geometry.” 2016. Web. 19 Oct 2019.

Vancouver:

Brown-Dymkoski EJ. Adaptive Wavelet-Based Turbulence Modeling for Compressible Flows in Complex Geometry. [Internet] [Doctoral dissertation]. University of Colorado; 2016. [cited 2019 Oct 19]. Available from: http://scholar.colorado.edu/mcen_gradetds/133.

Council of Science Editors:

Brown-Dymkoski EJ. Adaptive Wavelet-Based Turbulence Modeling for Compressible Flows in Complex Geometry. [Doctoral Dissertation]. University of Colorado; 2016. Available from: http://scholar.colorado.edu/mcen_gradetds/133


University of Colorado

10. Shervani-Tabar, Navid. Stabilized Conservative Level Set Method with Adaptive Wavelet-Based Mesh Refinement.

Degree: MS, 2017, University of Colorado

 This study investigates one of the well-known shortcomings of the conservative level set method, namely the ill-defined normal vector. A stabilized formulation is proposed which… (more)

Subjects/Keywords: adaptive mesh refinement; Adaptive Wavelet Collocation Method; computational fluid dynamics; level set method; reinitialization; stabilized conservative level set; Mathematics; Mechanical Engineering

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APA (6th Edition):

Shervani-Tabar, N. (2017). Stabilized Conservative Level Set Method with Adaptive Wavelet-Based Mesh Refinement. (Masters Thesis). University of Colorado. Retrieved from http://scholar.colorado.edu/mcen_gradetds/137

Chicago Manual of Style (16th Edition):

Shervani-Tabar, Navid. “Stabilized Conservative Level Set Method with Adaptive Wavelet-Based Mesh Refinement.” 2017. Masters Thesis, University of Colorado. Accessed October 19, 2019. http://scholar.colorado.edu/mcen_gradetds/137.

MLA Handbook (7th Edition):

Shervani-Tabar, Navid. “Stabilized Conservative Level Set Method with Adaptive Wavelet-Based Mesh Refinement.” 2017. Web. 19 Oct 2019.

Vancouver:

Shervani-Tabar N. Stabilized Conservative Level Set Method with Adaptive Wavelet-Based Mesh Refinement. [Internet] [Masters thesis]. University of Colorado; 2017. [cited 2019 Oct 19]. Available from: http://scholar.colorado.edu/mcen_gradetds/137.

Council of Science Editors:

Shervani-Tabar N. Stabilized Conservative Level Set Method with Adaptive Wavelet-Based Mesh Refinement. [Masters Thesis]. University of Colorado; 2017. Available from: http://scholar.colorado.edu/mcen_gradetds/137


University of Colorado

11. Khajehtourian, Romik. Nonlinear Dispersive Elastic Waves in Solids: Exact, Approximate, and Numerical Solutions.

Degree: PhD, 2017, University of Colorado

  Wave motion lies at the heart of many disciplines in the physical sciences and engineering. For example, problems and applications involving light, sound, heat,… (more)

Subjects/Keywords: dispersive elastic waves; elastic metamaterial; finite strain; nonlinear dispersion relation; nonlinear waves; phononic crystal; Aerospace Engineering; Engineering Mechanics; Mathematics

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APA (6th Edition):

Khajehtourian, R. (2017). Nonlinear Dispersive Elastic Waves in Solids: Exact, Approximate, and Numerical Solutions. (Doctoral Dissertation). University of Colorado. Retrieved from https://scholar.colorado.edu/asen_gradetds/171

Chicago Manual of Style (16th Edition):

Khajehtourian, Romik. “Nonlinear Dispersive Elastic Waves in Solids: Exact, Approximate, and Numerical Solutions.” 2017. Doctoral Dissertation, University of Colorado. Accessed October 19, 2019. https://scholar.colorado.edu/asen_gradetds/171.

MLA Handbook (7th Edition):

Khajehtourian, Romik. “Nonlinear Dispersive Elastic Waves in Solids: Exact, Approximate, and Numerical Solutions.” 2017. Web. 19 Oct 2019.

Vancouver:

Khajehtourian R. Nonlinear Dispersive Elastic Waves in Solids: Exact, Approximate, and Numerical Solutions. [Internet] [Doctoral dissertation]. University of Colorado; 2017. [cited 2019 Oct 19]. Available from: https://scholar.colorado.edu/asen_gradetds/171.

Council of Science Editors:

Khajehtourian R. Nonlinear Dispersive Elastic Waves in Solids: Exact, Approximate, and Numerical Solutions. [Doctoral Dissertation]. University of Colorado; 2017. Available from: https://scholar.colorado.edu/asen_gradetds/171


University of Colorado

12. Krattiger, Dimitri. Fast Band-Structure Computation for Phononic and Electronic Waves in Crystals.

Degree: PhD, 2017, University of Colorado

  The band structure is a frequency/energy versus wave vector/momentum relationship that fundamentally describes the nature of wave motion in a periodic medium. It is… (more)

Subjects/Keywords: band structure; electronic structure; model reduction; phononics; structural dynamics; wave propagation; Acoustics, Dynamics, and Controls; Aerospace Engineering; Physics

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APA (6th Edition):

Krattiger, D. (2017). Fast Band-Structure Computation for Phononic and Electronic Waves in Crystals. (Doctoral Dissertation). University of Colorado. Retrieved from https://scholar.colorado.edu/asen_gradetds/173

Chicago Manual of Style (16th Edition):

Krattiger, Dimitri. “Fast Band-Structure Computation for Phononic and Electronic Waves in Crystals.” 2017. Doctoral Dissertation, University of Colorado. Accessed October 19, 2019. https://scholar.colorado.edu/asen_gradetds/173.

MLA Handbook (7th Edition):

Krattiger, Dimitri. “Fast Band-Structure Computation for Phononic and Electronic Waves in Crystals.” 2017. Web. 19 Oct 2019.

Vancouver:

Krattiger D. Fast Band-Structure Computation for Phononic and Electronic Waves in Crystals. [Internet] [Doctoral dissertation]. University of Colorado; 2017. [cited 2019 Oct 19]. Available from: https://scholar.colorado.edu/asen_gradetds/173.

Council of Science Editors:

Krattiger D. Fast Band-Structure Computation for Phononic and Electronic Waves in Crystals. [Doctoral Dissertation]. University of Colorado; 2017. Available from: https://scholar.colorado.edu/asen_gradetds/173


University of Colorado

13. Sharma, Ashesh. Advances in Design and Optimization Using Immersed Boundary Methods.

Degree: PhD, 2017, University of Colorado

  This thesis is concerned with topology optimization which provides engineers with a systematic approach to optimize the layout and geometry of a structure against… (more)

Subjects/Keywords: computational mechanics; level set method; shape sensitivities; stress stabilization; topology optimization; XFEM; computational physics; Applied Mathematics; Engineering; Other Physics

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APA (6th Edition):

Sharma, A. (2017). Advances in Design and Optimization Using Immersed Boundary Methods. (Doctoral Dissertation). University of Colorado. Retrieved from https://scholar.colorado.edu/asen_gradetds/190

Chicago Manual of Style (16th Edition):

Sharma, Ashesh. “Advances in Design and Optimization Using Immersed Boundary Methods.” 2017. Doctoral Dissertation, University of Colorado. Accessed October 19, 2019. https://scholar.colorado.edu/asen_gradetds/190.

MLA Handbook (7th Edition):

Sharma, Ashesh. “Advances in Design and Optimization Using Immersed Boundary Methods.” 2017. Web. 19 Oct 2019.

Vancouver:

Sharma A. Advances in Design and Optimization Using Immersed Boundary Methods. [Internet] [Doctoral dissertation]. University of Colorado; 2017. [cited 2019 Oct 19]. Available from: https://scholar.colorado.edu/asen_gradetds/190.

Council of Science Editors:

Sharma A. Advances in Design and Optimization Using Immersed Boundary Methods. [Doctoral Dissertation]. University of Colorado; 2017. Available from: https://scholar.colorado.edu/asen_gradetds/190


University of Colorado

14. Krattiger, Dimitri. Fast Band-Structure Computation for Phononic and Electronic Waves in Crystals.

Degree: PhD, 2017, University of Colorado

  The band structure is a frequency/energy versus wave vector/momentum relationship that fundamentally describes the nature of wave motion in a periodic medium. It is… (more)

Subjects/Keywords: band structure; electronic structure; model reduction; phononics; structural dynamics; wave propagation; Acoustics, Dynamics, and Controls; Aerospace Engineering; Physics

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APA (6th Edition):

Krattiger, D. (2017). Fast Band-Structure Computation for Phononic and Electronic Waves in Crystals. (Doctoral Dissertation). University of Colorado. Retrieved from https://scholar.colorado.edu/asen_gradetds/216

Chicago Manual of Style (16th Edition):

Krattiger, Dimitri. “Fast Band-Structure Computation for Phononic and Electronic Waves in Crystals.” 2017. Doctoral Dissertation, University of Colorado. Accessed October 19, 2019. https://scholar.colorado.edu/asen_gradetds/216.

MLA Handbook (7th Edition):

Krattiger, Dimitri. “Fast Band-Structure Computation for Phononic and Electronic Waves in Crystals.” 2017. Web. 19 Oct 2019.

Vancouver:

Krattiger D. Fast Band-Structure Computation for Phononic and Electronic Waves in Crystals. [Internet] [Doctoral dissertation]. University of Colorado; 2017. [cited 2019 Oct 19]. Available from: https://scholar.colorado.edu/asen_gradetds/216.

Council of Science Editors:

Krattiger D. Fast Band-Structure Computation for Phononic and Electronic Waves in Crystals. [Doctoral Dissertation]. University of Colorado; 2017. Available from: https://scholar.colorado.edu/asen_gradetds/216


University of Colorado

15. Khajehtourian, Romik. Nonlinear Dispersive Elastic Waves in Solids: Exact, Approximate, and Numerical Solutions.

Degree: PhD, 2017, University of Colorado

  Wave motion lies at the heart of many disciplines in the physical sciences and engineering. For example, problems and applications involving light, sound, heat,… (more)

Subjects/Keywords: dispersive elastic waves; elastic metamaterial; finite strain; nonlinear dispersion relation; nonlinear waves; phononic crystal; Aerodynamics and Fluid Mechanics; Aerospace Engineering; Mathematics

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APA (6th Edition):

Khajehtourian, R. (2017). Nonlinear Dispersive Elastic Waves in Solids: Exact, Approximate, and Numerical Solutions. (Doctoral Dissertation). University of Colorado. Retrieved from https://scholar.colorado.edu/asen_gradetds/221

Chicago Manual of Style (16th Edition):

Khajehtourian, Romik. “Nonlinear Dispersive Elastic Waves in Solids: Exact, Approximate, and Numerical Solutions.” 2017. Doctoral Dissertation, University of Colorado. Accessed October 19, 2019. https://scholar.colorado.edu/asen_gradetds/221.

MLA Handbook (7th Edition):

Khajehtourian, Romik. “Nonlinear Dispersive Elastic Waves in Solids: Exact, Approximate, and Numerical Solutions.” 2017. Web. 19 Oct 2019.

Vancouver:

Khajehtourian R. Nonlinear Dispersive Elastic Waves in Solids: Exact, Approximate, and Numerical Solutions. [Internet] [Doctoral dissertation]. University of Colorado; 2017. [cited 2019 Oct 19]. Available from: https://scholar.colorado.edu/asen_gradetds/221.

Council of Science Editors:

Khajehtourian R. Nonlinear Dispersive Elastic Waves in Solids: Exact, Approximate, and Numerical Solutions. [Doctoral Dissertation]. University of Colorado; 2017. Available from: https://scholar.colorado.edu/asen_gradetds/221


University of Colorado

16. Shahabi, Farhad. Finite Strain Micromorphic Elasticity, Elastoplasticity, and Dynamics for Multiscale Finite Element Analysis.

Degree: PhD, 2017, University of Colorado

  This study stands as an attempt to consider the micro-structure of materials in a continuum framework by the aid of micromorphic continuum theory in… (more)

Subjects/Keywords: dynamics; elastoplasticity; finite element analysis; large deformation; micromorphic continuum; micropolar continuum; Applied Mechanics; Mechanical Engineering

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APA · Chicago · MLA · Vancouver · CSE | Export to Zotero / EndNote / Reference Manager

APA (6th Edition):

Shahabi, F. (2017). Finite Strain Micromorphic Elasticity, Elastoplasticity, and Dynamics for Multiscale Finite Element Analysis. (Doctoral Dissertation). University of Colorado. Retrieved from https://scholar.colorado.edu/cven_gradetds/404

Chicago Manual of Style (16th Edition):

Shahabi, Farhad. “Finite Strain Micromorphic Elasticity, Elastoplasticity, and Dynamics for Multiscale Finite Element Analysis.” 2017. Doctoral Dissertation, University of Colorado. Accessed October 19, 2019. https://scholar.colorado.edu/cven_gradetds/404.

MLA Handbook (7th Edition):

Shahabi, Farhad. “Finite Strain Micromorphic Elasticity, Elastoplasticity, and Dynamics for Multiscale Finite Element Analysis.” 2017. Web. 19 Oct 2019.

Vancouver:

Shahabi F. Finite Strain Micromorphic Elasticity, Elastoplasticity, and Dynamics for Multiscale Finite Element Analysis. [Internet] [Doctoral dissertation]. University of Colorado; 2017. [cited 2019 Oct 19]. Available from: https://scholar.colorado.edu/cven_gradetds/404.

Council of Science Editors:

Shahabi F. Finite Strain Micromorphic Elasticity, Elastoplasticity, and Dynamics for Multiscale Finite Element Analysis. [Doctoral Dissertation]. University of Colorado; 2017. Available from: https://scholar.colorado.edu/cven_gradetds/404


University of Colorado

17. Wieland, Scott A. Direct Numerical Simulations of the Compressible Low Atwood Rayleigh-Taylor Instability.

Degree: PhD, 2019, University of Colorado

 Two fluids are considered Rayleigh-Taylor unstable when the more dense fluid is suspended above the less dense fluid in the presence of a gravitational like… (more)

Subjects/Keywords: computational fluid dynamics; fluid dynamics; fluid instabilities; numerical methods; rayleigh-taylor instability; wavelets; Computer Sciences; Mechanical Engineering; Physics

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APA · Chicago · MLA · Vancouver · CSE | Export to Zotero / EndNote / Reference Manager

APA (6th Edition):

Wieland, S. A. (2019). Direct Numerical Simulations of the Compressible Low Atwood Rayleigh-Taylor Instability. (Doctoral Dissertation). University of Colorado. Retrieved from https://scholar.colorado.edu/mcen_gradetds/194

Chicago Manual of Style (16th Edition):

Wieland, Scott A. “Direct Numerical Simulations of the Compressible Low Atwood Rayleigh-Taylor Instability.” 2019. Doctoral Dissertation, University of Colorado. Accessed October 19, 2019. https://scholar.colorado.edu/mcen_gradetds/194.

MLA Handbook (7th Edition):

Wieland, Scott A. “Direct Numerical Simulations of the Compressible Low Atwood Rayleigh-Taylor Instability.” 2019. Web. 19 Oct 2019.

Vancouver:

Wieland SA. Direct Numerical Simulations of the Compressible Low Atwood Rayleigh-Taylor Instability. [Internet] [Doctoral dissertation]. University of Colorado; 2019. [cited 2019 Oct 19]. Available from: https://scholar.colorado.edu/mcen_gradetds/194.

Council of Science Editors:

Wieland SA. Direct Numerical Simulations of the Compressible Low Atwood Rayleigh-Taylor Instability. [Doctoral Dissertation]. University of Colorado; 2019. Available from: https://scholar.colorado.edu/mcen_gradetds/194

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