references.bib

---
---

@inproceedings{AA_C1,
  title={Aerodynamic performance of morphed camber rotor airfoils},
  author={Abdelmoula, Amine and Rauleder, J{\"u}rgen},
  booktitle={AIAA Scitech 2019 Forum},
  location={San Diego, CA},
  month={January},
  year={2019},
  doi={10.2514/6.2019-1101}
}

@article{Add1,
  title={Generalized flight dynamic model of quadrotor using hybrid blade element momentum theory},
  author={Shastry, Abhishek Kumar and Kothari, Mangal and Abhishek, Abhishek},
  journal={Journal of Aircraft},
  volume={55},
  number={5},
  pages={2162--2168},
  year={2018}
}

@inproceedings{Add17,
  title={Limitations in Helicopter Design},
  author={Bennett, JAJ},
  booktitle={3rd Annual Forum of the American Helicopter Society},
  location = {Philadelphia, PA},
  month={March},
  year={1947}
}

@article{Add40,
  title={Development of the autogiro: A technical perspective},
  author={Leishman, J Gordon},
  journal={Journal of aircraft},
  volume={41},
  number={4},
  pages={765--781},
  year={2004}
}

@inproceedings{Add42,
  title={Aerodynamics of the Helicopter World Speed Record},
  author={J Perry, F},
  booktitle={43rd Annual Forum of the American Helicopter Society},
  location = {St. Louis, MO},
  month={May},
  year={1987}
}

@article{Add42_1,
  title={High Speed Rotor Aerodynamics},
  author={B Amer, Kenneth},
  journal={Journal of the American Helicopter Society},
  volume={34},
  number={1},
  pages={63--63},
  year={1989}
}

@article{Add42_2,
  title={The Contribution of Planform Area to the Performance of the BERP Rotor},
  author={J Perry, F},
  journal={Journal of the American Helicopter Society},
  volume={34},
  number={1},
  pages={64--65},
  year={1989}
}

@INPROCEEDINGS{Add43,
  author={Gill, Rajan and D'Andrea, Raffaello},
  booktitle={2017 IEEE Conference on Control Technology and Applications (CCTA)}, 
  title={Propeller thrust and drag in forward flight}, 
  year={2017},
  pages={73-79},
  doi={10.1109/CCTA.2017.8062443}
}

@inproceedings{Add43_1,
  title={A hybrid blade element momentum model for flight simulation of rotary wing unmanned aerial vehicles},
  author={Davoudi, Behdad and Duraisamy, Karthikeyan},
  booktitle={AIAA Aviation 2019 Forum},
  month={June},
  year={2019},
  location={Dallas,TX}
}

@article{Add44,
  title={Dynamic stall experiments on the NACA 23012 aerofoil},
  author={Leishman, JG},
  journal={Experiments in Fluids},
  volume={9},
  number={1},
  pages={49--58},
  year={1990},
  publisher={Springer}
}

@article{Add45,
  title={Assessment of current rotor design comparison practices based on high-fidelity CFD methods},
  author={Fitzgibbon, Thomas and Woodgate, Mark and Barakos, George},
  journal={The Aeronautical Journal},
  volume={124},
  number={1275},
  pages={731--766},
  month={May},
  year={2020},
  publisher={Cambridge University Press}
}


@article{Add48, 
  title={Revitalising advanced rotorcraft research – and the compound helicopter},
  author={Ormiston, R. A.}, 
  volume={120}, 
  number={1223}, 
  journal={The Aeronautical Journal}, 
  publisher={Cambridge University Press}, 
  year={2016}, 
  pages={83–129},
  DOI={10.1017/aer.2015.5},
}

@article{Add54,
  title={An investigation of the flow of air around an aerofoil of infinite span},
  author={Bryant, LW and Williams, DH},
  journal={Philosophical Transactions of the Royal Society of London},
  volume={225},
  number={626-635},
  pages={199--245},
  year={1926},
  publisher={The Royal Society London}
}

@article{Add54_1,
  title={An investigation of the air-flow pattern in the wake of an aerofoil of finite span},
  author={Fage, Arthur and Simmons, Leonard Frederick George},
  journal={Philosophical Transactions of the Royal Society of London. Series A, Containing Papers of a Mathematical or Physical Character},
  volume={225},
  number={626-635},
  pages={303--330},
  year={1926},
  publisher={The Royal Society London}
}

@inproceedings{Add56,
  title={Hydrodynamical images},
  author={Milne-Thomson, LM},
  booktitle={Mathematical Proceedings of the Cambridge Philosophical Society},
  volume={36},
  number={2},
  pages={246--247},
  year={1940},
  organization={Cambridge University Press}
}

@article{Add57_2,
  title={The aerodynamics of insect flight},
  author={Sane, Sanjay P},
  journal={Journal of experimental biology},
  volume={206},
  number={23},
  pages={4191--4208},
  year={2003}
}

@article{A9_1,
  title={A Computational Fluid Dynamics--Based Viscous Vortex Particle Method for Coaxial Rotor Interaction Calculations in Hover},
  author={Singh, Puneet and Friedmann, Peretz P},
  journal={Journal of the American Helicopter Society},
  volume={63},
  number={4},
  pages={1--13},
  year={2018}
}

@techreport{A21,
  title={General theory of aerodynamic instability and the mechanism of flutter},
  author={Theodorsen, Theodore},
  number = {NACA Report No. 496},
  institution={Langley Memorial Aeronautical Lab},
  year={1940}
}

@techreport{A21_7,
  title={Airfoil in sinusoidal motion in a pulsating stream},
  author={Greenberg, J Mayo},
  number = {NACA TN 1326},
  institution={Langley Memorial Aeronautical Lab},
  year={1947}
}

@article{A21_8,
  title={{\"U}ber die Entstehung des dynamischen Auftriebes von Tragfl{\"u}geln},
  author={Wagner, Herbert},
  journal={Zeitschrift f{\"u}r Angewandte Mathematik und Mechanik},
  volume={5},
  pages={17--35},
  year={1925},
}

@article{A23,
  title={Concepts of aero-and hydromechanics},
  author={Platzer, MF and Jones, KD},
  journal={Flow Phenomena in Nature},
  volume={3},
  pages={5--19},
  year={2006},
  publisher={WIT Press}
}

@article{A23_1,
  title={Steady and unsteady aerodynamics},
  author={Platzer, MF and Jones, KD},
  journal={Flow Phenomena in Nature},
  volume={4},
  pages={531--541},
  year={2006},
  publisher={WIT Press}
}

@inproceedings{A23_2,
  title={On the dynamics of unsteady lift and circulation and the circulatory-non-circulatory classification},
  author={Taha, Haitham E and Rezaei, Amir S},
  booktitle={AIAA Scitech 2019 Forum},
  location={San Diego, CA},
  month = {January},
  year={2019}
}

@article{A29_R51,
  title={Viscous extension of potential-flow unsteady aerodynamics: the lift frequency response problem},
  author={Taha, Haithem and Rezaei, Amir S},
  journal={Journal of Fluid Mechanics},
  volume={868},
  pages={141--175},
  year={2019},
  publisher={Cambridge University Press}
}

@book{B0,
  title={Rotorcraft Aeromechanics},
  author={Wayne Johnson},
  year={2013},
  publisher={Cambridge University Press},
  address = {New York, NY}
}

@book{B3,
  title={Principles of helicopter aerodynamics},
  author={Leishman, Gordon J},
  year={2006},
  publisher={Cambridge university press},
  address = {New York, NY}
}

@techreport{B28,
  title={Rotary-Wing Aerodynamics Volume {I}},
  author={Stepniewski, W. Z.},
  number = {NASA Contractor Report 3082},
  institution={Boeing Vertol Company},
  year={1979}
}

@techreport{B28_1,
  title={Rotary-Wing Aerodynamics Volume {II}},
  author={Keys, C. N.},
  number = {{NASA} Contractor Report 3083},
  institution={Boeing Vertol Company},
  year={1979}
}

@book{B29,
  title={Aerodynamics of the Helicopter},
  author={Gessow, Alfred},
  year={1985},
  publisher={Frederik Ungar Publishing Co.},
  address = {New York, NY}
}

@incollection{B30,
  title={Airplane propellers},
  author={Glauert, Hermann},
  booktitle={Aerodynamic theory},
  pages={169--360},
  year={1935},
  publisher={Springer}
}

@book{B30_1,
  title={The elements of aerofoil and airscrew theory},
  author={Glauert, Hermann},
  year={1936},
  publisher={Cambridge University Press}
}


@book{B32_1,
  title={Helicopter Aerodynamics Volume II},
  author={Prouty, Ray},
  year={2009},
  publisher={Eagle Eye Solutions LLC},
  address = {Lebanon, OH}
}

@book{B37,
  title={Fundamentals of Aerodynamics},
  author={Anderson, John},
  year={2017},
  publisher={McGraw Hill},
  address = {New York, NY}
}

@book{BA1,
  title={Aerodynamics for Engineering Students},
  author={Houghton, Edward Lewis and Carpenter, Peter William and Collicott, Steven H and Valentine, Daniel T},
  year={2013},
  publisher={Elsevier}
}

@book{BA2,
  title={An Introduction to Fluid Dynamics},
  author={Batchelor, GK},
  year={2000},
  publisher={Cambridge University Press}
}

@book{BA3,
  title={Understanding Aerodynamics: arguing from the real physics},
  author={McLean, Doug},
  year={2013},
  publisher={John Wiley \& Sons}
}

@book{BA5,
  title={Theoretical and Computational Aerodynamics},
  author={Sengupta, Tapan K},
  year={2014},
  publisher={John Wiley \& Sons}
}

@book{BA9,
  title={Fluid Mechanics},
  author={White, Frank M},
  year={2011},
  publisher={McGraw Hill}
}

@book{BA13,
  title={The enigma of the aerofoil: Rival theories in aerodynamics, 1909-1930},
  author={Bloor, David},
  year={2019},
  publisher={University of Chicago Press}
}

@book{BA14,
  title={Applied hydro-and aeromechanics: based on lectures of L. Prandtl},
  author={Tietjens, Oskar Karl Gustav and (translator) Hartog, J P Den},
  year={1934},
  publisher={McGraw-Hill Book Company}
}

@book{BAE0,
  title={Aeroelasticity},
  author={Bisplinghoff, Raymond L and Ashley, Holt and Halfman, Robert L},
  year={1996},
  publisher={Dover Publications},
  address = {Mineola, New York}
}

@book{BD10,
  title={Nonlinear composite beam theory},
  author={Hodges, Dewey H},
  year={2006},
  publisher={American Institute of Aeronautics and Astronautics},
  address = {Reston, Virginia}
}

@book{BDI1,
  title={The Fluid Dynamic Basis for Actuator Disc and Rotor Theories},
  author={Kuik, Gijs van},
  year={2018},
  publisher={IOS Press},
  address={Amsterdam, The Netherlands}
}

@book{BDI2,
  title={Wing Theory},
  author={Robinson, A. and Laurmann, J. A.},
  year={2013},
  publisher={Cambridge University Press}
}

@inproceedings{P32,
  title={Airfoil Design and Rotorcraft Performance},
  author={Bousman, William G},
  year={2002},
  booktitle={58th Annual Forum of the American Helicopter Society, Montr{\`e}al, Canada}
}

@techreport{P32_R6,
  title={Aerodynamic Characteristics of Three Helicopter Rotor Airfoil Sections at Reynolds Numbers From Model Scale to Full Scale at Mach Numbers From 0.35 to 0.90},
  author={Noonan, Kevin W and Bingham, Gene J},
  number = {TP 1701},
  year={1980},
  institution={NASA Langley Research Center}
}

@inproceedings{P58_1,
  title={SMART rotor development and wind-tunnel test},
  author={Straub, Friedrich and Anand, VR and Birchette, Terry and Lau, Benton H},
  booktitle={35th European Rotorcraft Forum},
  location  = {Hamburg, VA},
  month={September},
  year={2009}
}

@inproceedings{P67,
  title={What Are The Lift and Propulsive Force Limits At High Speed For The Conventional Rotor?},
  author={McHugh, Frank J},
  booktitle={34th Annual Forum of the American Helicopter Society},
  location  = {Washington D.C.},
  month = {May},
  year={1978}
}

@techreport{P113,
  title={Effect of a Rapid Blade-Pitch Increase on Thrust and Induced-Velocity Response of a Full-Scale Helicopter Rotor},
  author={Carpenter, Paul J and Fridovich, Bernard},
  number = {NACA TN 3044},
  institution={Langley Aeronautical Lab},
  year={1953}
}


@inproceedings{P152,
  title={The ABC Rotor – A Historical Perspective},
  author={Burgess, Robert K.},
  booktitle={60th Annual Forum of the American Helicopter Society},
  location  = {Baltimore, MD},
  month={June},
  year={2004}
}

@inproceedings{P152_1,
  title={ADvancing Blade Concept (ABC) - High Speed Development},
  author={Ruddell, Andrew J. and Macrino, John A.},
  booktitle={36th Annual Forum of the American Helicopter Society},
  location  = {Washington, DC},
  month={May},
  year={1980}
}

@inproceedings{P152_2,
  title={An ABC status report},
  author={Linden, Arthur W. and Ruddell, Andrew J.},
  booktitle={37th Annual Forum of the American Helicopter Society},
  location  = {Washington, DC},
  month={May},
  year={1981}
}


@inproceedings{U12_2,
  title={Blade deflection measurements of a full-scale UH-60A rotor system},
  author={Olson, Lawrence E and Abrego, Anita I and Barrows, Danny A and Burner, Alpheus W},
  booktitle={American Helicopter Society Aeromechanics Specialists' Conference},
  location={San Francisco, CA},
  month={January},
  year={2010}
}

@techreport{T15,
  title={Rotor dynamic inflow derivatives and time constants from various inflow models},
  author={Pitt, Dale Marvin},
  institution = {USATSARCOM},
  number = {TR 81-2},
  month={December},
  year={1980}
}

@phdthesis{T16,
    title    = {A new appreciation of inflow modelling for autorotative rotors},
    school   = {University of Glasgow},
    author   = {Murakami, Yoh},
    month = {October},
    year     = {2008}
}

@phdthesis{T20,
    title    = {Development and Application of a Generalized Dynamic Wake Theory for Lifting Rotors},
    school   = {Georgia Institute of Technology},
    author   = {He, Chegjian},
    month    = {July},
    year     = {1989}
}

@phdthesis{T24,
    title    = {Dynamic Inflow-based Analysis of Pitch Changes to Hovering Rotor},
    school   = {Nanyang Technological University},
    author   = {Banerjee, Tridib},
    month    = {September},
    year     = {2020} 
}

@techreport{U2,
   title = {Predesign study for a modern 4-bladed rotor for {RSRA}},
   author={Davis, S Jon},
   institution={United Technologies Corporation},
   number={NASA CR 166155},
   month = {March},
   year = {1981}
}

@techreport{U19,
   title = {UH-60A Airloads Program Tutorial },
   author={Subsonic Rotary Wing Project },
   institution={NASA},
   month = {January},
   year = {2009}
}


@inproceedings{WJ10,
  title={ADVANCED VIBRATION REDUCTION BY IBC TECHNOLOGY},
  author={D. Roth},  
  booktitle={30th European Rotorcraft Forum}, 
  location={Marseilles, France},
  month={September},
  year={2004}
}

@misc{SikorskyWeb,
  title = {{S-69 (XH-59A)} Advancing Blade Concept Demonstrator},
  howpublished = {\url{https://www.sikorskyarchives.com/S-69%20(XH-59A).php}},
  note = {Accessed: 2022-05-29}
}


@inproceedings{holdgraf_evidence_2014,
	address = {Brisbane, Australia, Australia},
	title = {Evidence for {Predictive} {Coding} in {Human} {Auditory} {Cortex}},
	booktitle = {International {Conference} on {Cognitive} {Neuroscience}},
	publisher = {Frontiers in Neuroscience},
	author = {Holdgraf, Christopher Ramsay and de Heer, Wendy and Pasley, Brian N. and Knight, Robert T.},
	year = {2014}
}

@article{holdgraf_rapid_2016,
	title = {Rapid tuning shifts in human auditory cortex enhance speech intelligibility},
	volume = {7},
	issn = {2041-1723},
	url = {http://www.nature.com/doifinder/10.1038/ncomms13654},
	doi = {10.1038/ncomms13654},
	number = {May},
	journal = {Nature Communications},
	author = {Holdgraf, Christopher Ramsay and de Heer, Wendy and Pasley, Brian N. and Rieger, Jochem W. and Crone, Nathan and Lin, Jack J. and Knight, Robert T. and Theunissen, Frédéric E.},
	year = {2016},
	pages = {13654},
	file = {Holdgraf et al. - 2016 - Rapid tuning shifts in human auditory cortex enhance speech intelligibility.pdf:C\:\\Users\\chold\\Zotero\\storage\\MDQP3JWE\\Holdgraf et al. - 2016 - Rapid tuning shifts in human auditory cortex enhance speech intelligibility.pdf:application/pdf}
}

@inproceedings{holdgraf_portable_2017,
	title = {Portable learning environments for hands-on computational instruction using container-and cloud-based technology to teach data science},
	volume = {Part F1287},
	isbn = {978-1-4503-5272-7},
	doi = {10.1145/3093338.3093370},
	abstract = {© 2017 ACM. There is an increasing interest in learning outside of the traditional classroom setting. This is especially true for topics covering computational tools and data science, as both are challenging to incorporate in the standard curriculum. These atypical learning environments offer new opportunities for teaching, particularly when it comes to combining conceptual knowledge with hands-on experience/expertise with methods and skills. Advances in cloud computing and containerized environments provide an attractive opportunity to improve the effciency and ease with which students can learn. This manuscript details recent advances towards using commonly-Available cloud computing services and advanced cyberinfrastructure support for improving the learning experience in bootcamp-style events. We cover the benets (and challenges) of using a server hosted remotely instead of relying on student laptops, discuss the technology that was used in order to make this possible, and give suggestions for how others could implement and improve upon this model for pedagogy and reproducibility.},
	booktitle = {{ACM} {International} {Conference} {Proceeding} {Series}},
	author = {Holdgraf, Christopher Ramsay and Culich, A. and Rokem, A. and Deniz, F. and Alegro, M. and Ushizima, D.},
	year = {2017},
	keywords = {Teaching, Bootcamps, Cloud computing, Data science, Docker, Pedagogy}
}

@article{holdgraf_encoding_2017,
	title = {Encoding and decoding models in cognitive electrophysiology},
	volume = {11},
	issn = {16625137},
	doi = {10.3389/fnsys.2017.00061},
	abstract = {© 2017 Holdgraf, Rieger, Micheli, Martin, Knight and Theunissen. Cognitive neuroscience has seen rapid growth in the size and complexity of data recorded from the human brain as well as in the computational tools available to analyze this data. This data explosion has resulted in an increased use of multivariate, model-based methods for asking neuroscience questions, allowing scientists to investigate multiple hypotheses with a single dataset, to use complex, time-varying stimuli, and to study the human brain under more naturalistic conditions. These tools come in the form of “Encoding” models, in which stimulus features are used to model brain activity, and “Decoding” models, in which neural features are used to generated a stimulus output. Here we review the current state of encoding and decoding models in cognitive electrophysiology and provide a practical guide toward conducting experiments and analyses in this emerging field. Our examples focus on using linear models in the study of human language and audition. We show how to calculate auditory receptive fields from natural sounds as well as how to decode neural recordings to predict speech. The paper aims to be a useful tutorial to these approaches, and a practical introduction to using machine learning and applied statistics to build models of neural activity. The data analytic approaches we discuss may also be applied to other sensory modalities, motor systems, and cognitive systems, and we cover some examples in these areas. In addition, a collection of Jupyter notebooks is publicly available as a complement to the material covered in this paper, providing code examples and tutorials for predictive modeling in python. The aimis to provide a practical understanding of predictivemodeling of human brain data and to propose best-practices in conducting these analyses.},
	journal = {Frontiers in Systems Neuroscience},
	author = {Holdgraf, Christopher Ramsay and Rieger, J.W. and Micheli, C. and Martin, S. and Knight, R.T. and Theunissen, F.E.},
	year = {2017},
	keywords = {Decoding models, Encoding models, Electrocorticography (ECoG), Electrophysiology/evoked potentials, Machine learning applied to neuroscience, Natural stimuli, Predictive modeling, Tutorials}
}

@book{ruby,
  title     = {The Ruby Programming Language},
  author    = {Flanagan, David and Matsumoto, Yukihiro},
  year      = {2008},
  publisher = {O'Reilly Media}
}


@inbook{understandingaerodynamics,
publisher = {John Wiley & Sons, Ltd},
isbn = {9781118454190},
booktitle = {Understanding Aerodynamics},
doi = {https://doi.org/10.1002/9781118454190.ch10},
url = {https://onlinelibrary.wiley.com/doi/abs/10.1002/9781118454190.ch10},
eprint = {https://onlinelibrary.wiley.com/doi/pdf/10.1002/9781118454190.ch10},
year = {2012}
}