References

There are 305 references listed here on the topic of Modeling, Designing, controlling Micro Air Vehicles.

References

[1]  Manoj K.Bhardwaj, "A CFD CSD Interaction Methodology for Aircraft Wings", Doctorate Dissertation Virginia Polytechnic Institute (1997)

[2]  Vladislav Gavrilets, "Avionics Systems Development for small Unmanned Aircraft", Master's Thesis, Massachusetts Institute of Technology (1998)

[3] Michael A. Scott and Raymond C. Montgomery, "Subsonic Maneuvering Effectiveness of High Performance Aircraft", NASA Hampton, VA (1998)

[4] Geoffrey Louis Barrows," Mixed Mode VLSI Optic Flow Sensors for Micro Air Vehicles", Doctorate Dissertation, University of Maryland (1999)

[5]  Ilan Kroo and Peter Kunz, "Development of Mesicopter: A Miniature Autonomous Rotorcraft", Stanford University (2000)

[6]  Ilan Kroo and Fritz Prinz, "The Mesicopter: A Miniature Rotorcraft Concept Phase II Interim Report", Stanford University (2000)

[7] Gabriel Torres and Thomas J. Mueller, "Micro Aerial Vehicle Development: Design, Components, Fabrication, and Fight-testing", University of Notre Dame (2000)

[8] S. A. Combs and T. L. Daniel Shape, "Flapping and Flexion: Wing and Fin Design for Forward Flight", University of Washington (2001)

[9] Joel M. Grasmeyer and Matthew T. Keennon, "Development of the Black Widow Micro Air Vehicle", AeroVironment Inc. Simi Valley, CA 93063 (2001)

[10] Gabriel Torres and Thomas J. Mueller, "Micro Aerial Vehicle Development: Design, Components, Fabrication, and Flight Testing", University of Notre Dame (2001)

[11]  Helen Garcia, Mujahid Abdulrahim and Rick Lind, "Roll Control for A Micro Air Vehicle Using Active Wing Morphing", University of Florida (2002)

[12]  S. A. Combs and T. L. Daniel, "Into thin air: contributions of aerodynamic and intertial-elastic forces to wing bending in the hawkmoth Manuca sexta", University of Washington (2003)

[13]  Steven Ho, Hany Nassef, Nick Pornsinsirirak, Yu-Chong Tai and Chih-Ming Ho, "Unsteady Aerodynamics and Flow Control for Flapping Wing Flyers", University of California, Department of Mechanical Engineering, California Institute of Technology, Department of Electrical Engineering (2003)

[14] Mohd. Shariff Ammoo and Md. Nizam Dahalan, "Micro Air Vehicle: Technology Review and Design Study", University of Malaysia (2004)

[15] Francis Barnhart, Michael Cuipa, Daniel Stefanik and Zachary Swick, "Micro-Aerial Vehicle Design with Low Reynolds Number Airfoils", Brigham Yound University (2004)

[16] Daniel Dell, Alex Macleod and Yaron Mordfin, "Micro Air Vehicle Component Comparison and Proposed Military Reconnaissance Design Implementation", Army Research Office (2004)

[17] Jason Joseph Jackowski, "Nonlinear Simulation of A Micro Air Vehicle", Master's Thesis, University of Florida (2004)

[18] Soutis, "Proposal for A WUN Grand Challenge in MAV Design", University of Sheffield, Division of Aerospace Engineering (2004)

[19] James M. Abatti, "Small Power: The Role of Micro and Small UAV's in The Future", Air War College, Air University, Center for Strategy and Technology (2005)

[20] M. Meenakshi and M. Seetharama Baht, "Real Time Fixed Order Lateral H2 Controller for Micro Air Vehicle", A.I.T. Department of Instrumentation Technology, and I.I.Sc. Department of Aerospace Engineering (2005)

[21] Eric Parsons, "Investigation and Characterization of A Cycloidal Rotor for Application to A Micro-Air Vehicle", Master's Thesis, University of Maryland (2005)

[22] Iain K. Peddle, "Autonomous Flight of A Model Aircraft", Master's Thesis, University of Stellenbosch (2005)

[23] Evan R. Ulrich, Sean Humbert and Darryll J. Pines, "Pitch and Heave Control of Robotic Samara Micro Air Vehicles", University of Maryland, (2010), DOI: 10.2514.1.47197

[24]  Kevin P. Bollino, "High-Fidelity Real-Time Trajectory Optimization for Reusable Launch Vehicles", Doctorate Dissertation, Naval PostGraduate School (2006)

[25] Andrew Conn, Stuart Burgess, Rick Hyde and Chung Seng Ling, "From Natural Flyers to the Mechanical Realization of a Flapping Wing  Micro Air Vehicle", Queen's Building, University of Bristol, Department of Mechanical Engineering (2006)

[26] Xinyan Deng, Luca Schenato and S. Shankar Sastry, "Flapping Flight for Biomimetic Robotic Insects: Part 2 -Flight Control Design", IEEE (2006)

[27] J. Hall, D. Lawerence and K. Mohseni, "Lateral Control of A Tailless Micro Aerial Vehicle", University of Colorado,  Department of Aerospace Engineering (2006)

[28] Beerinder Singh, "Dynamics and Aeroelasticity of Hover Capable Flapping Wings: Experiments and Analysis", Doctorate Dissertation, University of Maryland (2006)

[29] Christel-Loic Tisse, Thomas Fauvel and Hugh Durrant-Whyte, "A Micro Aerial Vehicle Motion Capture System", The University of Sydney (2006)

[30] Zaeem A. Khan, Sunil K. Agrawal, "Control of Longitudinal Flight Dynamics of a Flapping-Wing Micro Air Vehicle Using Time-Averaged Model and Differential Flatness Based Controller", University of Delaware, Department of Mechanical Engineering (2007)

[31] B. Goksel, I. Rechenberg and R. Bannasch, "Electrokinetic Flow Control and Propulsion for MAV's", Technical University of Berlin, Institute of Bionics and Evolution Technology (2003)

[32]  "Modular, scaleable family of systems supporting soldiers in both urban and open terrain", Honeywell (2004)

[33] B. Mettler, M. Rhinehart, B. Evans and M. Asp, "Exploration of MAV Aerodynamics and Model Identification via Direct Trajectory Sampling", Powerpoint, University of Minnesota, Department of Aerospace Engineering, (2008)

[34] Pat Trizila, Chang-kwon Kang, Miguel Visbal and Wei Shyy, "A Surrogate Model Approach in 2D versus 3D Flapping Wing Aerodynamic Analysis", University of Michigan, Department of Aerospace Engineering, AFRL RBAC, Computational Sciences Branch, (2008)

[35] Defense Advanced Research Projects Agency, "DARPA Nano Air Vehicle Program Fact Sheet", Arlington, Virginia (2008)

[36] Satish K. Chimakurthi, "A Computational Aeroelasticity Framework for Analyzing Flapping Wings", Doctorate Dissertation, University of Michigan, (2009)

[37] Erik Schechter, "Micro Air Vehicle Revolution", The Journal of Net-Centric Warfare (2009)

[38] Lung-Jieh Yang, "Flapping Wings with Micro Sensors and Flexible Framework to Modify the Aerodynamic Forces of a Micro Aerial Vehicle (MAV)", Tamkang University (2009)

[39] [39] Sanjay K. Boddhu, "Evolution and Analysis of Neuromorphic Flapping-Wing Controllers", Doctorate Dissertation, Wright State University, (2005)

[40] Mircea Boscoianu, Ionică Circiu and Henri Coanda, "An Analysis of the Efficiency of the Functional Matching between a flying Wing MAV Airframe and Different Types of Micro Propellers", Air Force Academy (2011)

[41] Chang-kwon Kang, Hikaru Aono, Carlos S. Cesnik and Wei Shyy, "A Scaling Parameter for the Thrust Generation of Flapping Flexible Wings", University of Michigan, Department of Aerospace Engineering and Hong Kong University of Science and Technology, Department of Mechanical Engineering, (2011)

[42] Christopher T. Orlowski, "Flapping Wing Micro Air Vehicles: An Analysis of the Importance of the Mass of the Wings to Flight Dynamics, Stability, and Control", Doctorate Dissertation, University of Michigan (2011)

[43] Kui Ou and Anthony Jameson, "Towards Computational Flapping Wing Aerodynamics of Realistic Configurations using Spectral Difference Method", Stanford University, Aeronautics and Astronautics Department (2011)

[44] Luca Petricca, Per Ohlckers and Christopher Grinde, "Micro- and Nano-Air Vehicles: State of the Art", Vestfold University College, Department of Micro and Nano Systems Technology (IMST) (2011)

[45] Michael J. Thompson, "A Computational Study of Transient Couette Flow Over an Embedded Cavity Surface", Poster, Arizona State University, Department of Mechanical Engineering (2011)

[46] Stanley S. Baek, Kevin Y. Ma and Ronald S. Fearing, "Efficient Resonant Drive of Flapping-Wing Robots", University of California (2008)

[47] Stuart Burgess, "Development of an Insect-Inspired Micro Air Vehicle", Poster, University of Bristol, department of Mechanical Engineering

[48] Alioto V., Buttitta J., Epps A., Nguyen D-B,  Yahaghi A., Mourtos N.J., "Design of a Micro-Scale Deployable Unmanned Aerial Vehicle", San Jose State University (2010)

[49] Michael J. Thompson, "A Computational Study of Transient Couette Flow", Arizona State University, Department of Mechanical Engineering 2011

[50] Benjamin H. Cameron, "Flapping Wing PIV and Force Measurements", Doctorate Dissertation, University of Virginia (2007)

[51] Soumitra Pinak Banerjee, "Aeroelastic Analysis of Membrane Wings", Master's Thesis, Virginia Polytechnic Institute (2007)

[52] Jason L. Pereira, "Hover and Wind-Tunnel Testing of Shrouded Rotors for Improved Micro Air Vehicle Design", Doctorate Dissertation, University of Maryland, Department of Aerospace Engineering (2008)

[53] [53]Christian Dobler, "Development of Flight Hardware for a Next Generation Autonomous Micro Air Vehicle", Master's Thesis, Swiss Federal Institute of technology Zurich(2010)

[54] W. Shyy, H. Aono, S.K. Chimakurthi, P. Trizila, C.-K. Kang, C.E.S. Cesnik, H. Liu, "Recent Progress in Flapping Wing Aerodynamics and Aeroelasticity", University of Michigan, Department of Aerospace Engineering and Chiba University, Graduate School of Engineering, (2010) doi:10.1016.j.paerosci.2010.01.001

[55] Hou In (Edmond) Leong, "Development of a 6DOF Nonlinear Simulation Model Enhanced with Fine Tuning Procedures", Master's Thesis, University of Kansas, Department of Aerospace Engineering (2008)

[56] Antoine Beyeler, "Vision-Based Control of Near-Obstacle Flight", Master's Thesis, Ecole Polytechnique Federale Lausanne (EPFL) (2009)

[57] Daisuke Ishihara, T. Horie and Mitsunori Denda, "A two-dimensional computational study on the fluid–structure interaction cause of wing pitch changes in dipteran flapping flight", Japan University, Kyushu Institute of Technology, Rutgers University (2008)

[58] Kailash Kotwani, S. K. Sane, Hermendra Arya and K. Sudhakar, "Experimental Characterization of Propulsion System for Mini Aerial Vehicle", Indian Institute of Technology, Department of Aerospace Engineering (2004)

[59] Liang Zhao, Qingfeng Huang, Xinyan Deng and Sanjay P. Sane, "Aerodynamic effects of flexibility in flapping wings", University of Delaware, Department of Mechanical Engineering, Tata Institute of Fundamental Research,  2National Centre for Biological Sciences (2009)

[60] Evan R. Ulrich, J. Sean Humbert, and Darryll J. Pines, "Pitch and Heave Control of Robotic Samara Micro Air Vehicles", University of Maryland (2010)

[61] Ranjan Ganguli, "Nonlinear Aeroelasticity of Rotating and Flapping Wings- A Review", Indian Institute of Science, Department of Aerospace Engineering, (2010)

[62] S.H. Lin, F.Y. Hsiao, C.L. Chen and J.F. Shen, "Altitude Control of Flapping-wing MAV Using Vision-Based Navigation", Tamkeng University, Department of Aerospace Engineering and Taipei National University of the Arts (2010)

[63] Dario Martin Schafroth, "Aerodynamics, Modeling and Control of an Autonomous Micro Helicopter", Doctorate Dissertation, Swiss Federal Institute of Technology Zurich (2010)

[64] Katie Byl, "A Passive Dynamic AppraochFor Flapping-Wing Micro-Aerial Vehicle Control", University of California, Department of Electrical and Computer Engineering (2010)

[65] C. P. Ellington, "The Novel Aerodynamics of Insect Flight: Applications to Micro-Air Vehicles", University of Cambridge, Department of Zoology (1999)

[66] Peter Ifju, Roberto Albertani, Bret Stanford, Paul Hubner, Kyu-Ho Lee, Dan Claxton, Baron Johnson, "Experimental Characterization of a Flexible Wing Micro Air Vehicle", University of Florida (2005)

[67] Navabalachandran Jayabaln, Low Jun Horng, G. Leng, "Reverse Engineering and Aerodynamic Analysis of a Flying Wing UAV", National University of Singapore, Department of Mechanical Engineering

[68] Michael Karpelson, John P. Whitney, Gu-Yeon Wei, Robert J. Wood, "Energetics of Flapping-Wing Robotic Insects: Towards Autonomous Hovering Flight", Harvard University (2011)

[69] J. K. Shang, S. A. Combs, B. M. Finio and R. J. Wood, "Artificial insect wings of diverse morphology for flapping-wing MAV's", Harvard University, School of Engineering and Applied Sciences, Department of Organismic and Evolutionary Biology (2009)

[70] Roland Siegwart, "Miniature Ultrasound Sensor Array for MAV's", Swiss Federal Institute of Technology Zurich

[71] E. H. G. Tigis, G.C.H.E. de Croon, J. W. Wind, B. Remes, C. De Wagter, H-E de Bree, R. Ruijsink, "Hear and Avoid for Micro Air Vehicle", HAN University, Microflown Technologies, Delft University of Technology, Department of Aerospace Engineering (2011)

[72] Syaril Azrad, Farid Kendoul and Kenzo Nonami, "Visual Servoing of Quadrotor Micro-Air Vehicle Using Color Based Tracking Algorithm", Chiba University, Graduate School of Engineering and Department of electronics and Mechanical Engineering (2010)

[73] Paul Pounds, Robert Mahony and Peter Corke, "Modelling and Control of a Quad-Rotor Robot", Australian National University, Department of Engineering (2007)

[74] Oswald Berthold, Mathias Müller and Verena Hafner," A quadrotor platform for bio-inspired navigation experiments", Humboldt-Universität zu Berlin, Department of Computer Science (2010)

[75] Ryuta Ozawa and Francois Chaumette, "Dynamic Visual Servoing with Image Moments for a Quadrotor Using a Virtual Spring Approach", Ritsumeikan University, Department of Robotics,INRIA Rennes-Bretagne Atlantique

[76] Ken Wahren, "Saturn the UK Ministry of Defence Grand Challenge winner", Per Ada Magazine (2010)

[77] K. Alexis, G. Nikolakopoulos, Y. Koveos and A. Tzes, "Switching Model Predictive Control for a Quadrotor Helicopter under Severe Environmental Flight Conditions", University of Patras, Electrical and Computer Engineering Department, (2011)

[78] Ilan Zohar, Amit Ailon, and Hugo Guterman, "An automatic stabilization system for quadrotors with applications to vertical take-off and landing", Ben-Gurion University, Department of Electrical and Computer Engineering (2009)

[79] Paul Pounds, Robert Mahony and Peter Corke, "System Identification and Control of an Aerobot Drive System", Australian National University, Department of Engineering, (2007)

[80] Seong Hwang and Seung Jo Kim, "Aerodynamic Performance Enhancement of Cycloidal Rotor According to Blade Pivot Point Movement and Preset Angle Adjustment", Seoul National University, School of Mechanical and Aerospace Engineering, KSAS International Journal Vol. 9 No. 2, (2008) 

[81] Joshua Allen Stults, "Computational Aeroelastic Analysis of Micro Air Vehicle with Experimentally Determined Modes", Air Force Institute of Technology, Department of Aeronautical and Astronautical Engineering, Master's Thesis, (2005)

[82] Muhamad Azfar Bin Ramli, "AM21: Aerodynamics and Propulsion of an Indoor UAV", Bachelor's Degree,  National University of Singapore, Department of Mechanical Engineering, (2007)

[83] Markus Achtelik, Abraham Bachrach, Ruijie He, Samuel Prentice and Nicholas Roy, "Autonomous Navigation and Exploration of a Quadrotor Helicopter in GPS-denied Indoor Environments", Massachusetts Institute of Technology and Technische Universitat Munchen, (2009)

[84] Abraham Bachrach, Albert S. Huang, Daniel Maturana, Peter Henry, Michael Krainin, Dieter Fox, and Nicholas Roy, "Visual Navigation for Micro Air Vehicles", Massachusetts Institute of Technology, Computer Science and Artificial Intelligence Laboratory, University of Washington, Department of Computer Science and Engineering and Pontificia Universidad Catolica de Chile, Department of Computer Science, (2011)

[85] Randal W. Beard, "Quadrotor Dynamics and Control", Brigham Young University, (2008)

[86] Patrick Bouffard, Anil Aswani, and Claire Tomlin, "Learning-Based Model Predictive Control on a Quadrotor: Onboard Implementation and Experimental Results", University of California, Department of Electrical Engineering and Computer Sciences, (2012)

[87] Jinhui Zhang, Peng Shi, Hongjiu Yang, "Non-fragile robust stabilization and H¥ control for uncertain stochastic nonlinear time-delay systems, Beijing Institute of Technology, Department of Automatic Control, University of Glamorgan, Faculty of Advanced Technology, Victoria University, School of Science and Engineering, University of South Australia, School of Mathematics and Statistics, doi:10.1016.j.chaos.2009.04.049, (2009)

[88] Scott D. Hanford, Lyle N. Long, and Joseph F. Horn, "A Small Semi-Autonomous Rotary-Wing Unmanned Air Vehicle (UAV)", Pennsylvania State University, Aerospace Engineering, American Institute of Aeronautics and Astronautics, Paper No. 2005-7077, (2005) 

[89] Shengyuan Xu, James Lam, Jianliang Wang and Guang-Hong Yang, "Non-fragile positive real control for uncertain linear neutral delay systems", University of Hong Kong, Department of Mechanical Engineering, Nanyang Technological University, School of Electrical and Electronic Engineering and National University of Singapore, Temasek Laboratories, doi:10.1016.j.sysconle.2003.11.001, (2003) 

[90] Roland Brockers, Patrick Bouffard, Jeremy Ma, Larry Matthies, Claire Tomlin, "Autonomous landing and ingress of micro-air-vehicles in urban environments based on monocular vision", California Institute of Technology, Jet Propulsion Laboratory, University of California, Electrical Engineering and Computer Sciences, (2010)

[91] C. Hancer, K. T. Oner, E. Sirimoglu, E. Cetinsoy, M. Unel, "Robust Position Control of a Tilt-Wing Quadrotor", Sabanci University, (2010)

[92] Kostas Alexis, George Nikolakopoulos, Anthony Tzes, "Switching model predictive attitude control for a quadrotor helicopter subject to atmospheric disturbances", University of Patras, Electrical  and Computer Engineering Department, Lulea University of Technology, Electrical and Space Engineering Department, doi:10.1016.j.conengprac.2011.06.010, (2011)

[93] Jonathan Andersh, Bernie Mettler, "System integration of a miniature rotorcraft for aerial tele-operation research", University of Minnesota, Department of Computer Science and Department of Aerospace Engineering and Mechanics, doi:10.1016.j.mechatronics.2010.12.008, (2010)

[94] C. Nicol, C.J.B. Macnab, A. Ramirez-Serrano , "Robust adaptive control of a quadrotor helicopter", University of Calgary, Department of Electrical and Computer Engineering and Department of Mechanical and Manufacturing Engineering, doi:10.1016.j.mechatronics.2011.02.007, (2011)

[95] Aydın Eresen, Nevrez Imamoglu and Mehmet Önder Efe, "Autonomous quadrotor flight with vision-based obstacle avoidance in virtual environment", Middle East Technical University, Electrical and Electronics Engineering Department, Nanyang Technological University, School of Computer Engineering, University of Turkish Aeronautical Association, Department of Pilotage, doi:10.1016.j.eswa.2011.07.087, (2011)

[96] Rita Cunha, Carlos Silvestre, João Hespanha and A. Pedro Aguiar, "Vision-based control for rigid body stabilization", Institute for Systems and Robotics, Department of Electrical Engineering and Computer Science, University of California, Department of Electrical and Computer Engineering, doi:10.1016.j.automatica.2011.01.062, (2011)

[97] P. Pounds, R. Mahony and P. Corke, "Modelling and control of a large quadrotor robot", Yale University, Australian National University, School of Engineering, Systemsdoi:10.1016.j.conengprac.2010.02.008, (2010)

[98] Gabriel M. Hoffmann Homiao Huang, Steven L. Waslander and Claire J. Tomlin, "Precision flight control for a multi-vehicle quadrotor helicopter testbed", Stanford University, Aeronautics and Astronautics, University of Waterloo, Department  of Mechanical and Mechatronics Engineering, University of California Berkeley, Electrical Engineering and Computer Sciences, doi:10.1016.j.conengprac.2011.04.005, (2011)

[99] Sergio Salazar-Cruz, Rogelio Lozano and Juan Escareno, "Stabilization and nonlinear control for a novel trirotor mini-aircraft", Instituto de Investiaciones Electricasdoi:10.1016.j.conengprac.2009.02.013, (2009)

[100] Jonathan Andersh and Bernie Mettler, "System integration of a miniature rotorcraft for aerial tele-operation research", University of Minnesota, Department of Computer Science and Department of Aerospace Engineering and Mechanics, doi:10.1016.j.mechatronics.2010.12.008, (2011)

[101] K.M. Zemalache, H. Maaref, "Controlling a drone: Comparison between a based model method and a fuzzy inference system", Universite´ d’Evry Val d’Essonne, doi:10.1016.j.asoc.2008.08.007, (2008)

[102] Jitendra K. Tugnait, Yi Zhou, "On closed-loop system identification using polyspectral analysis given noisy input-output time-domain data", Auburn University, Department of Electrical . Computer Engineering, PII: S 0 0 0 5 - 1 0 9 8 ( 0 0 ) 0 0 1 0 4 - 7, (2000)

[103] Spencer G. Fowers, "Stabilization and Control of a Quad-Rotor Micro-UAV Using Vision Sensors", Brigham Young University, Department of Electrical and Computer Engineering, Master's Thesis,  (2008)

[104] Dario Martin Schafroth, "Aerodynamics, Modeling and Control of an Autonomous Micro Helicopter", ETH ZÜRICH, Doctorate dissertation, (2010)

[105] Hikaru Aono, Satish Kumar Chimakurthi,, Carlos E. S. Cesnik3*, Hao Liu, and Wei Shyy, "Computational Modeling of Spanwise Flexibility Effects on Flapping Wing Aerodynamics", University of Michigan, Department of Aerospace Engineering and Chiba University, Department of Engineering,  (2009)

[106] Jian Tang, Satish Chimakurthi, Rafael Palacios, Carlos E.S. Cesnik, and Wei Shyy, "Computational Fluid-Structure Interaction of a Deformable Flapping Wing for Micro Air Vehicle Applications", University of Michigan, Department of Aerospace Engineering and Imperial College, Department of Aeronautics, (2008)  

[107] David Lentink, Stefan R. Jongerius, and Nancy L. Bradshaw, "The Scalable Design of Flapping Micro-Air Vehicles Inspired by Insect Flight", Wageningen University, Experimental Zoology Group, DOI 10.1007.978-3-540-89393-6_14, (2009) 

[108] [108] Chinnapat Thipyopas, "Survey of Micro Air Vehicles in an International Even . Utilization in Thailand", Kasetsart University, Department of Aerospace Engineering, (2010)

[109] Hao Liu, Toshiyuki Nakata, Na Gao, Masateru Maeda, Hikaru Aono and Wei Shyy, "Micro air vehicle-motivated computational biomechanics in bio-flights: aerodynamics, flight dynamics and maneuvering stability", Chiba University, Graduate School of Engineering, University of Michigan, Department of Aerospace Engineering and The Hong Kong University, Department of Mechanical Engineering, (2010), DOI 10.1007.s10409-010-0389-5

[110] Hikaru Aono, Chang-kwon Kang, Carlos E. S. Cesnik, and Wei Shyy, "A Numerical Framework for Isotropic and Anisotropic Flexible Flapping Wing Aerodynamics and Aeroelasticity", University of Michigan, Department of Aerospace Engineering, (2010)

[111] Osgar John Ohanian III, "Ducted Fan Aerodynamics and Modeling, with Applications of Steady and Synthetic Jet Flow Control", Virginia Polytechnic Institute, Doctorate Dissertation, (2011)

[112] S. Tobing, J. Young and J.C.S. Lai, "Effects of Aerolasticity on Flapping Wing Proppulsion", University of New South Wales At Australian Defence Force Academy, (2010)

[113] Radhakant Padhi, "Partially Integrated Guidance and Control of UAVs for Reactive Collision

Avoidance", Indian Institute of Science, Department of Aerospace Engineering, (2011)

[114] C. A. Patel, S. K. Rao, and Dr. B. J. Driessen, "A Testbed for Mini Quadrotor Unmanned Aerial Vehicle with Protective Shroud", Wichita State University, Department of Mechanical Engineering, (2006)

[115] Slawomir Grzonka, Giorgio Grisetti and Wolfram Burgard, "Towards a Navigation System for Autonomous Indoor Flying", University of Freiburg, Department of Computer Science, (2009)

[116] Aaron M. Harrington, "Optimal Propulsion System Design for a Micro Quad Rotor", University of Maryland, Department of Aerospace Engineering, Master's Thesis, (2011)

[117] Albert S. Huang, Stefanie Tellex, Abraham Bachrach, Thomas Kollar, Deb Roy, Nicholas Roy, "Natural Language Command of an Autonomous Micro-Air Vehicle", Massachusetts Institute of Technology, (2010)

[118] Rudolph Molero, Sebastian Scherer, Lyle Chamberlain, and Sanjiv Singh, "Navigation and Control for Micro Aerial Vehicles in GPS-Denied Environments", Carnegie Mellon University, (2011)

[119] Michael David Schmidt, "Simulation and Control of a Quadrotor Unmanned Aerial

Vehicle", University of Kentucky, Master's Thesis, (2011)

[120] Anil Aswani, Patrick Bouffard and Claire Tomlin, "Extensions of Learning-Based Model Predictive Control for Real-Time Application to a Quadrotor Helicopter", University of California, Department of Electrical Engineering and Computer

Sciences, (2011)

[121] Patrick Adigbli, Ch. Grand, J-B. Mouret and S. Doncieux, "Nonlinear Attitude and Position Control of a Micro Quadrotor using Sliding Mode and Backstepping Techniques", Technical University of München and Institute of Intelligent Systems and Robotics, Powerpoint, (2007)

[122] Carlo Canetta, Jonathan Chin, Sevan Mehrabian, Ludguier Montejo and Hendrik Thompson, "Quad-rotor Unmanned Aerial Vehicle", Columbia University, (2007)

[123] Albert S. Huang, Abraham Bachrach, Peter Henry, Michael Krainin, Daniel Maturana, Dieter Fox and Nicholas Roy, "Visual Odometry and Mapping for Autonomous Flight Using an RGB-D Camera" Massachusetts Institute of Technology, Computer Science and Artificial Intelligence Laboratory, University of Washington, Department of Computer Science and Engineering and Pontificia Universidad Catolica de Chile, Department of Computer Science,  (2009)

[124] A. Barrientos, and J. Colorado, "Miniature Quad-rotor Dynamics Modeling & Guidance for Vision-based Target Tracking Control Tasks", University of Madrid, Robotics and Cybernetics

research group, (2009)

[125] Matko Orsag and Stjepan Bogdan, "Influence of Forward and Descent Flight on Quadrotor Dynamics", University of Zagreb, Department of Control and Computer Engineering, (2011)

[126] G. Angeletti, J. R. Pereira Valente, L. Iocchi and D. Nardi, "Autonomous Indoor Hovering with a Quadrotor", Sapienza University of Rome, Via Ariosto 25, 00185 Rome, Italy, (2008)

[127] Paul Martin, William Etter and Rahul Mangharam, "Demo Abstract: R.A.V.E.N. – Remote Autonomous Vehicle 0Explorer Network", University of Pennsylvania, Department of Electrical & System Engineering, ACM 978-1-4503-0512-9/11/04, (2011)

[128] Daniel Mellinger and Vijay Kumar, "Minimum Snap Trajectory Generation and Control for Quadrotors", University of

Pennsylvania, (2010)

[129] Abraham Bachrach, Ruijie He, and Nicholas Roy, "Autonomous Flight in Unstructured and Unknown Indoor Environments", Massachusetts Institute of Technology, (2008)

[130] Oswald Berthold and Michael Schulz, "Altitude control for a quadrotor with Linux", Humboldt-Universität zu Berlin, Powerpoint, (2007)

[131] Cooper Bills, Joyce Chen and Ashutosh Saxena, "Autonomous MAV Flight in Indoor Environments using Single Image Perspective Cues", Cornell University, Department of Computer Science, (2010)

[132] James F. Roberts, Timothy S. Stirling, Jean-Christophe Zufferey and Dario Floreano, "Quadrotor Using Minimal Sensing For Autonomous Indoor Flight”, Ecole Polytechnique Fédérale de Lausanne (EPFL), Lausanne, 1015, Switzerland, (2007)

[133] Jeff Cooper, Jitu Das, Priya Deo, Daniel Jacobs, Mike Ornstein, Harrison Rose and Alex Zirbel, "Aerial Point-Cloud Generation using the Microsoft Kinect on an Autonomous Quadrotor"

[134] N.K. Gupta, R. Goely and N. Ananthkrishnanz, "Role of Modeling and Simulation in Design and Development of Mini/Micro Air Vehicles: Case of an Autonomous Quadrotor", Massachusetts Institute of Technology, Department of Aeronautics and Astronautics, Korea Advanced Institute of Science and Technology, Division of Aerospace Engineering, (2009)

[135] Debadatta Sahoo, Amit Kumar and K. Sujatha, "A Survey on Remotely Operated Quadrotor Aerial Vehicle using the Camera Perspective", M.G.R. University, Dept. of EEE, (2010)

[136] Jacob Oursland, "The Design and Implementation of a Quadrotor Flight Controller Using the QUEST Algorithm," South Dakota School of Mines and Technology, Department of Mathematics and Computer Science, Rapid City, SD 57701,  (2010)

[137] Dinuka Abeywardena, Sarath Kodagoda, Rohan Munasinghe and Gamini Dissanayake, "A Virtual Odometer for a Quadrotor Micro Aerial Vehicle", University of Technology, Sydney and University of Moratuwa, Sri Lanka, (2010)

[138] Jeremy C. Goldin, "Perching Using a Quadrotor with Onboard Sensing", Utah State University, Master's Thesis, (2011)

[139] Ulf Pilz, Andrey P. Popov and Herbert Werner, "Robust Controller Design for Formation Flight of Quad-Rotor Helicopters", Hamburg University of Technology, Institute of Control Systems, 21073 Hamburg, Germany, (2008)

[140] Lorenz Meier, Petri Tanskanen, Lionel Heng, Gim Hee Lee, Friedrich Fraundorfer and Marc Pollefeys, "PIXHAWK: A Micro Aerial Vehicle Design for Autonomous Flight using Onboard Computer Vision", ETH Zurich, (2011)

[141] John Stowers, "Optical Flow for Attitude Estimation of a Quadrotor Helicopter", University of Canterbury, Department of Electrical Engineering, Power point, (2009)

[142] Julian Binder, Chris Burchhardt, James Church, Jeff Cooper, Priyanka Deo, Graham Harvey, Dan Jacobs, Sean James, Peter McHale, Nicolas Mellis, Doci Mou, Tom Mullins, Kaven Peng, Harrison Rose, Matthew Sebek, George Nick Stanley, Thomas Wucherpfennig, Alex Zirbel, "Vision-Based Object Following with an Autonomous Quadrotor", (2011)

[143] Noah Adams, "Air Force Eyes Micromachine Bugs That Can Spy", Ed Lopez, "Picatinny Engineers Develop Versatile Warheads", Gary Jones, "Two Recent Federal Court Rulings", Louise Lerne, "Argonne Designs Self-Assembled Micro-Robots", FLC NewsLink, (2011)

[144] Larry A. Young, M.R. Derby, J.L. Johnson, J. Navarrete, J. Klem, J. Andrews, R. Demblewski, R. Torres, "Engineering Studies into Vertical Lift Planetary Aerial Vehicles", Ames Research Center, Aerospace Computing, Inc, San Jose State University, Massachusetts Institute of Technology, College of San Mateo, New Mexico State University, (2002)

[145] Peter Ulbrich, Rüdiger Kapitza, Christian Harkort, Reiner Schmid, Wolfgang Schröder Preikschat, "I4Copter: An Adaptable and Modular Quadrotor Platform", Friedrich-Alexander University Erlangen-Nuremberg and Siemens Corporate Technology, Munich, (2011)

[146] Bo Cheng and Xinyan Deng, "Translational and Rotational Damping of Flapping Flight and Its Dynamics and Stability at Hovering", Purdue University, School of Mechanical Engineering, (2011)

[147] Min Xu, Mingjun Wei, Tao Yang, Young S. Lee, Thomas D. Burton, "Nonlinear Structural Response in Flexible Flapping Wings with Different Density Ratio", New Mexico State University, Department of Mechanical and Aerospace Engineering, Las Cruces, NM 88003, (2011)

[148] T. B. Gatski and C. E. Groscht, "Embedded Cavity Drag in Steady Laminar Flow" NASA Langley Research Center, Hampton, Virginia and Old Dominion University, Norfolk, Virginia, AIAA JOURNAL, (1985)

[149] Monte Verità, "Flying Insects and Robots", Ascona, Switzerland, International Symposium, (2007)

[150] National Aerospace laboratories, Aerial delivery Research and development Establishment, " 1st US-Asian Demonstration and assessment of Micro-Aerial Vehicle (MAV) and Unmanned Ground Vehicle (UGV)", (2008)

[151] Research and Technology Organization, North Atlantic Treaty Organization, "Unsteady Aerodynamics for Micro Air Vehicles", (2010)

[152] Samir Bouabdallah, Pierpaolmurrieri, Roland Siegwart, "Towards Autonomous Indoor Micro VTOL", Autonomous Systems Lab, EPFL, CH-1015, Lausanne, Switzerland, and Centro E. Piaggio, University of Pisa, 56126 Pisa, Italy, (2005)

[153] Henri Eisenbeiss, "The Potential of Unmanned Aerial Vehicles for Mapping", Zurich, PhD thesis(2009)

[154] Nelson dos Santos Fernandes , "Design and construction of a multi-rotor with various degrees of freedom",  Technical University of Lisboa, (2011)

[155] Pradeep Gopalakrishnan , "Unsteady Aerodynamic and Aeroelastic Analysis of Flapping Flight",  Virginia Polytechnic Institute, (2008)

[156] Paul Pounds, Robert Mahony , "Small-scale Aeroelastic Rotor Simulation, Design, and Fabrication",  Australian National University, (2005)

[157] Paul Pounds, Robert Mahony, Joel Gresham , "Towards Dynamically-Favourable Quad-Rotor Aerial Robots",  Australian National University, (2004)

[158] Harold Youngren, Steve Jameson, Brian Satterfield , "Design of the SAMARAI Monowing Rotorcraft Nano Air Vehicle",  Lockheed Martin Advanced Technology Laboratories, (2009)

[159] Sahjendra N. Singh, Aditya Simha, Rajat Mittal, "Biorobotic AUV Maneuvering by Pectoral Fins: Inverse Control Design Based on CFD Parameterization", Department of Electrical and Computer Engineering, University of Nevada, Las Vegas IEEE Journal, (2004)

[160] Mugdha S. Naik, Sahjendra N. Singh, Rajat Mittal, "Biologically-Inspired Adaptive Pectoral-Like Fin Control System For CFD Parameterized AUV, Department of Electrical and Computer Engineering, University of Nevada, Department of Mechanical and Aerospace Engineering, The Washington University, (2007)

[161] Ehsan Aram, Rajat Mittal and Louis Cattafesta, "Toward Simple Boundary Condition Representations of Zero-Net Mass-Flux Actuators in Grazing Flow", Department of Mechanical and Aerospace Engineering, The George Washington University and Interdisciplinary Microsystems Group, Department of Mechanical and Aerospace Engineering, AIAA 2009-4018, (2009)

[162] Reni Raju, Ehsan Aram, Rajat Mittal and Louis Cattafesta, "Simple Models of Zero-Net Mass-Flux Jets for Flow Control Simulations", Department of Mechanical Engineering, Johns Hopkins University and Department of Mechanical and Aerospace Engineering, University of Florida, (2009)

[163] Haoxiang Luo, Rajat Mittal and Steven A. Bielamowicz,  "Analysis of flow-structure interaction in the larynx during phonation using an immersed-boundary method", Department of Mechanical Engineering, Vanderbilt University, Department of Mechanical and Aerospace Engineering, George Washington University and Division of Otolaryngology, George Washington University  Acoustical Society of America, DOI: 10.1121/1.3158942, (2009)

[164] H. Dong, M. Bozkurttas, R. Mittal, P. Madden and G. V. Lauder, "Computational modelling and analysis of the hydrodynamics of a highly deformable fish pectoral fin", Department of Mechanical and Aerospace Engineering, The George Washington University and The Museum of Comparative Zoology, Harvard University, doi:10.1017/S0022112009992941, (2010)

[165] Ehsan Aram, Rajat Mittal, John Griffin and Louis Cattafesta, "Towards Effective ZNMF Jet Based Control of a Canonical Separated Flow", Department of Mechanical Engineering, Johns Hopkins University and Florida Center for Advanced Aero-Propulsion (FCAAP) Interdisciplinary Microsystems Group, AIAA 2010-4705, (2010)

[166] Lingxiao Zheng, Rajat Mittal and Tyson L. Hedrick, "A Search for Optimal Wing Strokes in Flapping Flight: Can Engineers Improve Upon Nature? ", Department of Mechanical Engineering, Johns Hopkins University , Department of Biology, University of North-Carolina , AIAA 2010-4944, (2010)

[167] Rupesh B. Kotapati, Rajat Mittal, Olaf Marxen, Frank Ham, Donghyun You and Louis N. Cattafesta I I I, "Nonlinear dynamics and synthetic-jet-based control of a canonical separated flow", Department of Mechanical and Aerospace Engineering, The George Washington University, Centre for Turbulence Research, Stanford University, Department of Mechanical Engineering, Carnegie Mellon University and  Department of Mechanical and Aerospace Engineering, University of Florida, doi:10.1017/S002211201000042X, (2010)

[168] J. H. Seo and R. Mittal, "A New Immersed Boundary Method for Aeroacoustic Sound Prediction around Complex Geometries", Department of Mechanical Engineering, Johns Hopkins University, AIAA 2010-4434, (2010)

[169] Shawn Aram and Rajat Mittal, "Computational Study of the Effect of Slot Orientation on Synthetic Jet-Based Separation Control", Department of Mechanical Engineering, Johns Hopkins University, (2011)

[170] X. Zheng, R. Mittal and S. Bielamowicz, "A computational study of asymmetric glottal jet deflection during phonation", Department of Mechanical Engineering, Johns Hopkins University and Division of Otolaryngology, The George Washington University, (2010)

[171] Xudong Zheng, Steve Bielamowicz, Haoxinag Luo and Rajat Mittal, "A Computational Study of the Effect of False Vocal Folds on Glottal Flow and Vocal Fold Vibration During Phonation", Department of Mechanical and Aerospace Engineering, Division of Otolaryngology, The George Washington University and Department of Mechanical Engineering, Vanderbilt University, DOI: 10.1007/s10439-008-9630-9, (2009)

[172] B. R. Ravi, R. Mittal and  F.M. Najjar, "Study of Three-Dimensional Synthetic Jet Flow Fields Using Direct Numerical Simulation", Department of Mechanical & Aerospace Engineering, The George Washington University and Center for Simulation of Advanced Rockets, University of Illinois, AIAA 2004-0091 (2004)

[173] M. Bozkurttas, H. Dong., V. Seshadri, R. Mittal and F. Najjar, "Towards Numerical Simulation of Flapping Foils on Fixed Cartesian Grids", Department of Mechanical & Aerospace Engineering, The George Washington University andCenter for Simulation of Advanced Rockets, University of Illinois, AIAA 2005-0079, (2005)

[174] H. Dong, R. Mittal, M. Bozkurttas and F. Najjar, "Wake Structure and Performance of Finite Aspect-Ratio Flapping Foils", Department of Mechanical & Aerospace Engineering, The George Washington University and Center for Simulation of Advanced Rockets, University of Illinois, AIAA 2005-0081(2005)

[175] K. Mohseni, R. Mittal, F. E. Fish, "Special issue featuring selected papersfrom the Mini-Symposium on Biomimetic and Bio-Inspired Propulsion (Boulder, CO, USA, 26 June 2006)", Department of Aerospace Engineering, University of Colorado, Department of Mechanical and Aerospace Engineering, George Washington University and Department of Biology, West Chester University doi:10.1088/1748-3182/1/4/E01, (2006)

[176] Alfred von Loebbecke, Rajat Mittal, "Comparative Analysis of Thrust Production for Distinct Arm-Pull Styles in Competitive Swimming", Mechanical and Aerospace Engineering, The George Washington University and Mechanical Engineering, Johns Hopkins University, (2012)

[177] Louis N. Cattafesta III, Ye Tian and R. Mittal, "Adaptive Control of Post-Stall Separated Flow Application to Heavy Vehicles", Interdisciplinary Microsystems Group Department of Mechanical and Aerospace Engineering and Department of Mechanical and Aerospace Engineering The George Washington University, (2009)

[178] Abel Vargas and Rajat Mittal, "Aerodynamic Performance of Biological Airfoils",The George Washington University, AIAA-2004-2319, (2004)

[179] R. Mittal, F.M. Najjar, R. Byrganhalli, V. Seshadri and H. Singh, "Simulation of complex biological flows and flow control problems on Cartesian grids", The George Washington University, University of Illinois, Thomas Jefferson School of Science and Technology,( 2004)

[180] Alfred von Loebbecke, Rajat Mittal, Frank Fish and Russell Mark, "Propulsive Efficiency of the Underwater Dolphin Kick in Humans" Department of Mechanical and Aerospace Engineering, George Washington University, Department of Biology, West Chester University, DOI: 10.1115/1.3116150, (2009)

[181] Rajat Mittal and Parviz Moin, "Suitability of Upwind-Biased Finite Difference Schemes for large-Eddy Simulation of Turbulent Flows", Stanford University, AIAA (1997)

[182] R. Mittal, J. J. Wilson and F. M. Najjar, Symmetry Properties of the Transitional Sphere Wake, University of Florida and University of Illinois, AIAA0001-1452/02 (2001)

[183]Chelakara S. Subramanian,Tahani R. Amer, Donald M. Oglesby and Cecil G. Burkett Jr., "New Self-Referencing Pressure-Sensitive-Paint Measurement", Florida Institute of Technology and NASA Langley Research Center, AIAA 2000-2526, (2000)

[184] J. H. Seo and R. Mittal, "Computation of Aerodynamic Sound around Complex Stationary and Moving Bodies", Department of Mechanical Engineering, Johns Hopkins University, AIAA (2001)

[185]Rajat Mittal, "Planar Symmetry in the Unsteady Wake of a Sphere," University of Florida, AIAA (1998)

[186] R. Mittal, Y. Utturkar, and H.S. Udaykumar "Computational Modeling and Analysis of Biomimetic Flight Mechanisms", Department of Mechanical and Aerospace Engineering The George Washington University, Department of Mechanical Engineering University of Florida and Department of Mechanical Engineering, University of Iowa AIAA 2002-0865 (2002)

[187] T. Ye, R. Mittal, H. S. Udaykumar and W. Shyy, "A Cartesian Grid Method for Viscous Incompressible Flows with Complex Immersed Boundaries", Department of Mechanical Engineering, University of Florida and Department of Aerospace Engineering, Mechanics and Engineering Science, University of Florida AIAA–99–3312, (1999)

[189] R. Mittal, F.M. Najjar, "Vortex Dynamics in the Sphere Wake", Department of Mechanical Engineering, University of Florida and Center for Simulation of Advanced Rockets, University of Illinois, AIAA 99-3806 (1999)

[190] Y. Utturkar1, R. Mittal, P. Rampunggoon and L. Cattafesta, "Sensitivity of Synthetic Jets to the Design of the Jet Cavity", 1Department of Mechanical Engineering, University of Florida, Department of Mechanical and Aerospace Engineering, The George Washington University and 3Department of Aerospace Engineering, Mechanics and Engineering Sciences, University of Florida, AIAA 2002-0124, (2002)

[191] Yogen Utturkar, Ryan Holman, Rajat Mittal, Bruce Carroll, Mark Sheplak, and Louis Cattafesta, "A Jet Formation Criterion for Synthetic Jet Actuators", Department of Mechanical and Aerospace Engineering,University of Florida and Department of Mechanical and Aerospace Engineering, The George Washington University, AIAA-2003-0636, (2003)

[192] Donghyun You, Meng Wang, Rajat Mittal, and Parviz Moin, "Study of Rotor Tip-Clearance Flow Using Large-Eddy Simulation", Stanford University and The George Washington University, AIAA 2003-0838, (2003)

[193] Reza Ghias, Rajat Mittal, Thomas S. Lund, "A Non-Body Conformal Grid Method For Simulation of Compressible Flows With Complex Immersed Boundaries", Department of Mechanical and Aerospace Engineering, The George Washington University and Department of Aerospace Engineering Sciences, The University of Colorado, AIAA 2004-0080, (2004)

[194] Quentin Gallas, Ryan Holman, Reni Raju, Rajat Mittal, Mark Sheplak and Louis Cattafesta, "Low Dimensional Modeling of Zero-Net Mass-Flux Actuators, "University of Florida, The George Washington University, University of Florida, AIAA 2004-2413 (2004)

[195] Rupesh B. Kotapati and Rajat Mittal, "Time-Accurate Three-Dimensional Simulations of Synthetic Jets in Quiescent Air, The George Washington University, AIAA 2005-0103 (2005)

[196] Rajat Mittal,  Rupesh B. Kotapati and Louis N. Cattafesta III, "Numerical Study of Resonant Interactions and Flow Control in a Canonical Separated Flow", Department of Mechanical and Aerospace Engineering, The George Washington University and Department of Mechanical and Aerospace Engineering, University of Florida, AIAA 2005-1261, (2005)

[197] I. Akhtar and R. Mittal, "A Biologically Inspired Computational Study of Flow Past Tandem Flapping Foils", Department of Mechanical and Aerospace Engineering, The George Washington University, AIAA 2005-4760 (2005)

[198] B. R. Ravi and R. Mittal,"Numerical Study of Large Aspect-Ratio Synthetic Jets, "Department of Mechanical and Aerospace Engineering, The George Washington University, AIAA 2006-0315, (2006)

[199] Rupesh B. Kotapati, Rajat Mittal and Louis N. Cattafesta III, "Numerical Experiments in Synthetic Jet Based Seperation Control", Department of Mechanical and Aerospace Engineering, The George Washington University and Department of Mechanical and Aerospace Engineering, University of Florida, AIAA 2660-0320 (2006)

[200] M. Bozkurttas, H. Dong., R. Mittal, P. Madden and G.V. Lauder, "Hydrodynamic Performance of Deformable Fish Fins and Flapping Foils", Department of Mechanical & Aerospace Engineering, The George Washington University and Museum of Comparative Zoology Harvard University, AIAA 2006-1392 (2006)

[201] Ye Tian, Louis N. Cattafesta III and Rajat Mittal, "Adaptive Control of Separated Flow", Department of Mechanical and Aerospace Engineering, University of Florida and Department of Mechanical and Aerospace Engineering, The George Washington University, AIAA 2006-1401 (2006)

[202] R. Mittal, H. Dong, M. Bozkurttas, A. Von Loebbecke and F. Najjar, "Analysis of Flying and Swimming in Nature Using an Immersed Boundary Method", Department of Mechanical & Aerospace Engineering, The George Washington University and Center for Simulation of Advanced Rockets, University of Illinois, AIAA 2006-2867 (2006)

[203] M. Bozkurttas, H. Dong, R. Mittal, James Tangorra, Ian Hunter, G.V. Lauder and P. Madden, "CFD based Analysis and Design of Biomimetic Flexible Propulsors for Autonomous Underwater Vehicles", Department of Mechanical & Aerospace Engineering, The George Washington University, AIAA-2007-4213 (2007)

[204] Srinivas Ramakrishnan, Rajat Mittal, George V. Lauder and  Meliha Bozkurttas, "Analysis of Maneuvering Fish Fin Hydrodynamics Using an Immersed Boundary Method", Department of Mechanical and Aerospace Engineering, George Washington University and The Museum of Comparative Zoology, Harvard University, AIAA 2008-3717, (2008)

[205] Xudong Zheng and Rajat Mittal, "A High Fidelity Computational Method for Flow-Tissue Interaction in Biological Flows", Department of Mechanical and Aerospace Engineering, The George Washington University, AIAA 2008-3954, (2008)

[206] Reni Raju, Ehsan Aram, Rajat Mittal and Louis Cattafesta, "Reduced-Order Models of Zero-Net Mass-Flux Jets for Large-Scale Flow Control Simulations", Department of Mechanical and Aerospace Engineering, The George Washington University and Interdisciplinary Microsystems Group, Department of Mechanical and Aerospace Engineering, University of Florida AIAA 2008-6404, (2008)

[207] Lingxiao Zheng, Xiaolin Wang, Afzal Khan, R. R. Vallance Rajat Mittal and Tyson L. Hedrick, "A Combined Experimental-Numerical Study of the Role of Wing Flexibility in Insect Flight", Department of Mechanical & Aerospace Engineering, George Washington University, Department of Biology, University of North-Carolina, AIAA 2009-382, (2009)

[208] Jonathan H. Tu, Clarence W. Rowley, Ehsan Aram and Rajat Mittal, " Koopman spectral analysis of separated flow over a finite-thickness flat plate with elliptical leading edge", Princeton University and Johns Hopkins University, AIAA 2011-38, (2011)

[209] Donghyun You,  Meng Wang, Rajat Mittal and Parviz Moin, "Large-Eddy Simulations of Longitudinal Vortices Embedded in a Turbulent Boundary Layer," Stanford University and George Washington University, DOI: 10.2514/1.22043, (2006)

[210] Reni Raju,  Rajat Mittal and Louis Cattafesta, "Dynamics of Airfoil Separation Control Using Zero-Net Mass-Flux Forcing", The George Washington University and University of Florida, DOI: 10.2514/1.37147, (2008)

[211] Reni Raju, Rajat Mittal, Quentin Gallas and Louis Cattafesta, "Scaling of Vorticity Flux and Entrance Length Effects in Zero-Net Mass-Flux Devices", Department of Mechanical and Aerospace Engineering,The George Washington University and Department of Mechanical and Aerospace Engineering, University of Florida, AIAA 2005-4751, (2005)

[212] Rupesh B. Kotapati, Rajat Mittal, Olaf Marxen, Frank Ham and Donghyun You, "Numerical Simulations of Synthetic Jet Based Separation Control in a Canonical Separated Flow", Department of Mechanical and Aerospace Engineering, The George Washington University and Center for Turbulence Research, Stanford University, AIAA 2007-1308, (2007)

[213] Reni Raju, Rajat Mittal and Louis N. Cattafesta III, "Towards Physics Based Strategies for Separation Control over an Airfoil using Synthetic Jets", The George Washington University and University of Florida, AIAA 2007-1421 (2007)

[214] Ryan Holman, Yogen Utturkar, Rajat Mittal, Barton L. Smith, Louis Cattafesta, "Formation Criterion for Synthetic Jets", University of Florida, George Washington University and Utah State University, AIAA, 0001-1452/05, (2005)

[215] R. Ghias, R. Mittal and H. Dong, "A sharp interface immersed boundary method for compressible viscous flows", Department of Mechanical and Aerospace Engineering, The George Washington University, doi:10.1016/j.jcp.2006.12.007 (2006)

[216] Isaac I. Kaminer, Oleg A. Yakimenko, Vladimir N. Dobrokhodov and Kevin D Jones, "Rapid Flight Test Prototyping System and the Fleet of UAVs and MAVs at the Naval Postgraduate School", Naval Postgraduate School, AIAA (2005)

[217] Soon-Jo Chung, Michael Dorothy and Jeremiah R. Stoner,  "Neurobiologically Inspired Control of Engineered Flapping Flight", Iowa State University, AIAA, (2009)

[218]Alfred Von Loebbecke, Rajat Mittal, Russell Mark and James Hahn, "A Computational Method for analysis of Underwater Dolphin Kick Hydrodynamics in Human Swimming", George Washington University, DOI: 10.1080/1470802629982, (2008)

[219] Rajat Mittal and S. Balachandar, " On the Inclusion of Three-Dimensional Effects in Simulations of Two-Dimensional Bluff-Body Wake Flows", Stanford University and University of Illinois, (1997)

[220] Frank E. Fish, George V. Lauder, Rajat Mittal, Alexandra H. Techet, Michael S. Triantafyllou, Jeffery A. Walker, and Paul W. Webb, "Conceptual Design for the Construction of a Biorobotic AUV Based on Biological Hydrodynamics", West Chester University, Harvard University, George Washington University, MIT, University of Southern Maine, University of Michigan, (2003)

[221] Abel Vargas, Rajat Mittal and Haibo Dong, "A computational study of the aerodynamic performance of a dragonfly wing section in gliding flight", The George Washington University, Bioinspiration and Biomimetics,doi:10.1088/1748-3182/3/2/026004, (2008)

[222] Rajneesh Bhardwaj and Rajat Mittal, "Benchmarking a Coupled Immersed-Boundary-Finite-Element Solver for Large-Scale Flow-Induced Deformation", Johns Hopkins University, AIAA, (2011)

[223] Rajat Mittal, "Computational Modeling in Biohydrodynamics: Trends, Challenges, and Recent Advances", The George Washington University, IEEE, D.O.I.10.1109/JOE.2004.833215, (2004)

[224] M. Bozkurttas, R. Mittal, H. Dong, G. V. Lauder and P. Madden, "Low-dimensional models and performance scaling of a highly deformable fish pectoral fin", The George Washington University and Harvard University,  doi:10.1017/S0022112009007046, (2009)

[225] Jung Hee Seo and Rajat Mittal, "A Coupled Flow-Acoustic Computational Study of Bruits from a Modeled Stenosed Artery", Johns Hopkins University, (2011)

[226] T. Ye, R. Mittal, H. S. Udaykumar and W. Shyy, "An Accurate Cartesian Grid Method for Viscous Incompressible Flows with Complex Immersed Boundaries", University of Florida, Journal of Computational Physics 156, 209–240 (1999)

[227] H. S. Udaykumar, R. Mittal and P. Rampunggoon, "Interface tracking finite volume method for complex solid–fluid interactions on fixed meshes", University of Iowa and University of Florida, DOI: 10.1002/cnm.468 (2002)

[228] Donghyun You, Rajat Mittal, Meng Wang and Parviz Moin, "Progress in Large-Eddy Simulation of a Rotor Tip-Clearance Flow", Stanford University and The George Washington University, (2002)

[229] Michelle Kwok and Rajat Mittal, "Experimental Investigation of the Aerodynamics of a Modeled Dragonfly Wing Section", The George Washington University, AIAA (2005)

[230] X. Zheng, J.H. Seo, V. Vedula, T. Abraham and R.Mittal, "Computational Modeling and Analysis of Intracardiac Flows in Simple Models of the Left Ventricle", Johns Hopkins University, (2012)

[231] R. Mittal and S. Balachandar, "Direct Numerical Simulation of Flow Past Elliptic Cylinders", University of Illinois, Journal of Computational Physics 124, 351–367 (1996)

[232] Donghyun You, Rajat Mittal,  Meng Wang and Parviz Moin, "A Computational Methodology for Large-Eddy Simulation of Tip-Clearance Flows", Stanford University and The George Washington University, FEDSM2003-45395 (2003)

[233] Q. Xue, X. Zheng, S. Bielamowicz and R. Mittal, "Sensitivity of vocal fold vibratory modes to their three-layer structure: Implications for computational modeling of phonation", Johns Hopkins University and The George Washington University, Acoustical Society of America DOI: 10.1121/1.3605529, (2011)

[234] Ge Jin, Nakhoon baek, james k. Hahn, Steven Bielamowicz, Rajat Mittal and Raymond Walsh, John Wiley and Sons, "Image Guided Mediaization Laryngoplasty", Computer Animation and Vitrtual Worlds, 19: 1-10, DOI: 10.1002/cav, (2008)

[235] Raman S. Dusaj, Katherine C. Michelis, Megan Terek, Reza Sanai, Rajat Mittal, Jannet F. Lewis, Robert K. Zeman, Brian G. Choi, George Washington University and Johns Hopkins University, "Estimation of right atrial and ventricular hemodynamics by CT coronary angiography" ,Journal of Cardiovascular Computed Tomography, doi:10.1016/j.jcct.2010.10.005, (2011)

[236] Fady M. Najjar and Rajat Mittal, University of Illinois and The George Washington University, "Simulations of Complex Flows and Fluid-Structure Interaction Problems on Fixed Cartesian Grids", FEDSM2003-45577, ASME, (2003)

[237] Donghyun You, Meng Wang, Parviz Moin and Rajat Mittal, Stanford University and The George Washington University, " Vortex Dynamics and Mechanisms for Viscous Losses in the Tip-Clerance Flow", FEDSM2005-77175, ASME, (2005)

[238] Rajat Mittal, Xudong Zheng, Rajneesh Bhardwaj, Jung Hee Seo, Qian Xue and Steven Bielamowicz, Johns Hopkins University and George Washington University, " Toward a simulation-based tool for the treatment of vocal fold paralysis", doi: 10.3389/fphys.2011.00019, (2011)

[239] James L. Tangorra, George V. Lauder, Peter G. Madden, Rajat Mittal, Meliha Bozkurttas and Ian W. Hunter, Drexel University, Harvard University, George Washington University and Massachusetts Institute of Technology, "A Biorobotic Flapping Fin for Propulsion and Maneuvering", (2007)

[240] Ehsan Aram, Rajat Mittal and Louis Cattafesta,  Johns Hopkins University and University of Florida, "Simple Representations of Zero-Net Mass-Flux Jets in Grazing Flow for Flow-Control Simulations", International Journal of Flow Control, ISSN 1756-8250 (2010)

[241] Donghyun You, Meng Wang and Rajat Mittal, Stanford University, University of Notre Dame and George Washington University, "A methodology for high performance computation of fully inhomogeneous turbulent flows", International Journal for Numerical Methods in Fluids, 2007; 53:947–968, DOI: 10.1002/fld (2006)

[242] Rajat Mittal and Rupesh B. Kotapati, George Washington University, "Resonant Mode Interaction in A Canonical Seperated Flow", IUTAM Symposium, (2004)

[243] James Louis Tangorra, S. Naomi Davidson, Ian W. Hunter, Peter G. A. Madden, George V. Lauder, Haibo Dong, Meliha Bozkurttas, and Rajat Mittal, "The Development of a Biologically Inspired Propulsor for Unmanned Underwater Vehicles, IEEE Journal of Oceanic Engineering, (2007)

[244] Jung Hee Seo and Rajat Mittal, Johns Hopkins University, "A high-order immersed boundary method for acoustic wave scattering and low-Mach number flow-induced sound in complex geometries", Journal of Computational Physics,  doi:10.1016/j.jcp.2010.10.017, (2010)

[245] Jung Hee Seo and Rajat Mittal, Johns Hopkins University, "A sharp-interface immersed boundary method with improved mass conservation and reduced spurious pressure oscillations", Journal of Computational Physics, doi:10.1016/j.jcp.2011.06.003, (2011)

[246] H. S. Udaykumar, R. Mittal, P. Rampunggoon and A. Khanna, University of Iowa, George Washington University and University of Florida, "A Sharp Interface Cartesian Grid Method  for Simulating Flows with Complex Moving Boundaries Journal of Computational Physics, doi:10.1006/jcph.2001.6916, (2001)

[247] Donghyun You, Meng Wang, Parviz Moin, and Rajat Mittal, Stanford University, University of Notre Dame and George Washington University, "Vortex Dynamics and Low-Pressure Fluctuations in the Tip-Clearance Flow", Journal of Fluids Engineering,

[248] Donghyun You, Meng Wang, Rajat Mittal and Parviz Moin, Stanford University and George Washington University,  A Quasi-Generalized-Coordinate Approach for Numerical Simulation of Complex Flows", ASME, DOI: 10.1115/1.2354533, (2006)

[249] H. Dong, R. Mittal and F. M. Najjar, George Washington University and University of Illinois, "Wake topology and hydrodynamic performance of low-aspect-ratio flapping foils", doi:10.1017/S002211200600190, (2006)

[250] Mukund Narasimhan, Haibo Dong, Rajat Mittal and Sahjendra N. Singh, University of Nevada and George Washington University, "Optimal Yaw Regulation and Trajectory Control of Biorobotic AUV Using Mechanical Fins Based on CFD Parametrization1", Journal of Fluids Engineering, DOI: 10.1115/1.2201634, (2006)

[251] R. Mittal, S. P. Simmons and F. Najjar, George Washington University, University of Florida and University of Illinois, "Numerical study of pulsatile flow in a constricted channel", Journal of Fluid Mechanics, DOI: 10.1017/S002211200300449X, (2003)

[252] Dongyun You, Meng Wang, Parviz Moin and Rajat Mittal, Stanford University, University of Notre Dame and George Washington University, "Large-eddy simulation analysis of mechanisms for viscous losses in a turbomachinery tip-clearance flow", Journal of Fluid Mechanics, doi:10.1017/S0022112007006842, (2007)

[253]  Ge Jin, Sang-Joon Lee, James K. Hahn, Steven Bielamowicz, Rajat Mittal, and Raymond Walsh, George Washington University, "3D Surface Reconstruction and Registration for Image Guided Medialization Laryngoplasty", (2003)

[254] George V Lauder, Peter G A Madden, Rajat Mittal, Haibo Dong and Meliha Bozkurttas, Harvard University and George Washington University, "Locomotion with flexible propulsors: I. Experimental analysis of pectoral fin swimming in sunfish", doi:10.1088/1748-3182/1/4/S04, (2006)

[255] Reza Ghias, Rajat Mittal, Haibo Dong and Thomas S. Lund, George Washington University and University of Colorado, "Large-Eddy Simulation of the Tip Flow of a Rotor in Hover", AIAA-2004-2432, (2004)

[256] Alfred von Loebbecke, Rajat Mittal, Frank Fish and Russell Mark, George Washington University and West Chester University, "A comparison of the kinematics of the dolphin kick in humans and cetaceans", doi:10.1016/j.humov.2008.07.005, (2008)

[257] R. Mittal, S.Venkatasubramanian and F.M. Najjar, University of Florida and University of Illinois, "Large–Eddy Simulation of Flow Through a Low-Pressure Turbine Cascade", AIAA 2001–2560, (2001)

[258] T. E. Mengesha, R. R. Vallance and R. Mittal, George Washington University and Johns Hopkins University, "Stiffness of desiccating insect wings", doi:10.1088/1748-3182/6/1/014001, (2010)

[259] Donghyun You, Rajat Mittal, MengWang and Parviz Moin, Stanford University and George Washington University, "Computational Methodology for Large-Eddy Simulation of Tip- Clearance Flows", AIAA Journal, (2004)

[260] Rajat Mittal, Veeraraghavan Seshadri and Holavanahalli S. Udaykumar, The George Washington University and University of Iowa, "Flutter, Tumble and Vortex Induced Autorotation", Theoretical and Computational Fluid Dynamics, DOI10.1007/s00162-003-0101-5, (2004)

[261] Imran Akhtar, Rajat Mittal, George V. Lauder and Elliot Drucker, George Washington University, Virginia Tech and Harvard University, "Hydrodynamics of a biologically inspired tandem flapping foil configuration, Theoretical and Computational Fluid Dynamics, DOI 10.1007/s00162-007-0045-2, (2007)

[262] Rajat Mittal, Haibo Dong, Meliha Bozkurttas, George V. Lauder and Peter Madden, The George Washington University and Harvard University, "Locomotion with flexible propulsors: II. Computational modeling of pectoral fin swimming in sunfish", doi:10.1088/1748-3182/1/4/S05, (2006)

[263] H. S. Udaykumar and L. Mao and R. Mittal, University of Iowa and George Washington University, "A Finite-Volume Sharp Interface scheme for Dendritic Growth Simulations: Comparison with Microscopic Sovability Theory", (2002)

[264] Wei Shyy and Rajat Mittal, University of Florida, "The Handbook of Fluid Dynamics, Ch. 31 solution Methods for the Incompressible navier-Stokes Equations", (1998)

[265] W. Shyy, M.-H. Chen, R. Mittal and H. S. Udaykumar, University of Florida, "On the Suppression of Numerical Oscillations Using a Non-Linear Filter", Journal of Computational physics, (1991)

[266] S. Balachandar, R. Mittal and F. M. Najjar, University of Illinois, "Properties of the Mean Recirculation Region in the Wakes of Two-Dimensional Bluff Bodies", Journal of Fluid Mechanics, (1997)

[267] H. -J. Kaltenbach, M. Fatica, R. Mittal, T. S. Lund and P. Moin, Stanford University, "Study of Flow in a Planar Asymmetric Diffuser Using Large-Eddy Simulation", Journal of Fluid Mechanics, (1999)

[268] R. Mittal, V. Seshadri, S.E. Sarma and H.S. Udaykumar, George Washington University, Massachusetts Institute of Technology and University of Iowa, "Computational Modeling of Fluidic Micro-Handling Processes, (2002)

[269] Meliha Bozkurttas, James Tangorra, George Lauder and Rajat Mittal, Drexel University, Harvard University and The George Washington University, "Understanding the Hydrodynamics of Swimming: From Fish Fins to Flexible Propulsors for Autonomous Underwater Vehicles", Advances in Science and Technology Vol. 58 (2008)

[270] Frank Bos, Bas van Oudheusden and Hester Bijl, Delft University of Technology, "Three-dimensional numerical simulations of flapping wings at low Reynolds numbers", PowerPoint, (2007)

[271] Elias E. Panagiotopoulos and Spyridon D. Kyparissis, Hellenic Military Academy and University of Patras, "CFD Transonic Store Separation Trajectory Predictions with Comparison to Wind Tunnel Investigations", International Journal of Engineering, (2009)

[272] Fluent Inc, "User Defined Functions", Fluent Software Training TRN-99-003, (2001)

[273] ANSYS FLUENT 12.0, "Tutorial Guide", (2009)

[274] Fluent Inc, "Chapter 11. Modeling Flows Using Sliding and Deforming Meshes", (2006)

[275] Nonthipat Thaweewat, Delft University of Technology, "Influence of wing kinematics on vortex dynamics and performance in insect forward flight", MS, (2007)

[276]Michael Ehlen, "Dynamic Mesh in Fluent Uberblick und Ausblick", CFD Conference (2004)

[277] ANSYS Inc., "CH. 9 Advanced Fluid Training", PowePoint, (2009)

[278] Gyung-Jin Park, Hanyang University,"Optimization of the Flapping Wing Systems for a Micro Air Vehicle", AOARD-09-4103, (2010)

[279] Evren Sakarya, Middle East Technical University, "Structural Design and Evaluation of an Adaptive Camber Wing", MS, (2010)

[280] Fluent Inc, "Tutorial: 3D Adiabatic Compression (Layering, Remeshing and Spring Smoothing)" , (2006)

[281] Fluent Inc, "Tutorial: Using a UDF to Control the Dynamic Mesh of a Flexible Oscillating Membrane", (2006)

[282] Fluent Inc, "Tutorial: Store Separation from a 3D Delta Wing", (2008)

[283] Frank Martijn, Delft University of Technology "Numerical simulations of flapping foil and wing aerodynamics", PhD Thesis, (2009)

[284] Andrew A. Johnson, Network Computing Services Inc, "Dynamic-Mesh CFD and its Application to Flapping-Wing Micro-Air Vehicles ", (2006)

[285] Yih-Ferng Peng, Rajat Mittal, Amalendu Sau, Robert R. Hwang, National Chi Nan University, George Washington University, Gyeongsang National University and Institute of Physics, "Nested Cartesian grid method in incompressible viscous fluid flow", Journal of Computational Physics 229, doi:10.1016/j.jcp.2010.05.041, (2010)

[286] Donghyun You, Meng Wang, Parviz Moin, Rajat Mittal, Stanford University, University of Notre Dame, and George Washington University, "Effects of tip-gap size on the tip-leakage flow in a turbomachinery cascade", Physics of Fluids 18, 105102, DOI: 10.1063/1.2354544, (2006)

[287] R. Mittal and S. Balachandar, University of Illinois, "Generation of Streamwise Vortical Structures in Bluff body Wakes", Physical Review letters, (1995)

[288] R. Mittal and S. Balachandar, University of Illinois, "Effect of three-dimensionality on the lift and drag of nominally two-dimensional cylinders", American Institute of Physics, (1995)

[289] R. Mittal, P. Rampunggoon, The George Washington University and University of Florida, "On the virtual aeroshaping effect of synthetic jets", Physics of Fluids, DOI: 10.1063/1.1453470, (2002)

[290] R. Mittal, University of Florida, "Response of the Sphere Wake to Freestream Fluctuations", Theoretical and Computational Fluid Dynamics, (2000)

[291] Reni Raju, Quentin Gallasa, Rajat Mittal and Louis Cattafesta, The George Washington University and University of Florida, "Scaling of pressure drop for oscillatory flow through a slot", DOI: 10.1063/1.2749814, (2007)

[292] Srinivas Ramakrishnan, Meliha Bozkurttas, Rajat Mittal and George V. Lauder, ANSYS, Inc, College of Engineering, Johns Hopkins University and Harvard University, "Thrust Production in Highly Flexible Pectoral Fins: A Computational Dissection",  (2007)

[293] Reza Ghias, Rajat Mittal, Haibo Dong and Thomas S. Lund, The George Washington University and  The University of Colorado, "Study of Tip-Vortex Formation Using Large-Eddy Simulation", AIAA-2005-1280, (2005)

[294] H. S. Udaykumar, R. Mittal and Wei Shyy, University of Florida, "Computation of Solid–Liquid Phase Fronts in the Sharp Interface Limit on Fixed Grids," Journal of Computational Physics 153, 535–574 (1999)

[295] Donghyun You, Rajat Mittal, Meng Wang and Parviz Moin, Stanford University and George Washington University, "Analysis of stability and accuracy of finite-difference schemes on a skewed mesh", Journal of Computational Physics 213, doi:10.1016/j.jcp.2005.08.007, (2006)

[296] Rajat Mittal,  University of Florida, "A Fourier–Chebyshev Spectral Collocation Method For Simulating Flow Past Spheres and Spheroids", International Journal For Numerical Methods in Fluids 30: 921–937, (1999)

[297] R. Mittal, S. P. Simmons, H. S. Udaykumar, University of Florida, University of Iowa, "Application of Large-Eddy Simulation to the Study of Pulsatile Flow in a Modeled Arterial Stenosis", Journal of Biomechanical Engineering, DOI: 10.1115/1.1385840, (2001)

[298] R. Mittal, P. Rampunggoon and H. S. Udaykumar, University of Florida, University of Iowa, "Interaction of a Synthetic Jet with a Flat Plate Boundary Layer", AIAA 2001–2773, (2001)

[299] James L. Tangorra, George V. Lauder, Ian W. Hunter, Rajat Mittal, Peter G. A. Madden and Meliha Bozkurttas, Drexel University, MIT, Johns Hopkins University and The George Washington University, "The effect of fin ray flexural rigidity on the propulsive forces generated by a biorobotic fish pectoral fin", The Journal of Experimental Biology 213, 4043-4054, doi:10.1242/jeb.048017, (2010)

[300] Donghyun You, Meng Wang, Parviz Moin and Rajat Mittal, Stanford University and George Washington University, Syudy of Tip-Clearance Flow in Turbomachines Using Large-Eddy Simulation", Computing in Science and Engineering, (2004)

[301] Rajat Mittal, The George Washington University, "Computational Modeling in Bio-Hydrodynamics: Trends, Challenges and Recent Advances", (2002)

[302] Rajat Mittal, Imran Akhtar, Meliha Bozkurttas and Fady. M. Najjar, The George Washington University and University of Illinois, "Towards a Conceptual Model of a Bio-Robotic AUV: Pectoral Fin Hydrodynamics", (2003)

[303] Veeraraghavan Seshadri, Rajat Mittal and H.S. Udaykumar, The George Washington University, University of Iowa, "Vortex Induced Auto-Rotation of a Hinged Plate: A Computational Study", F E DSM2003-45512, (2003)

[304] Srinivas Ramakrishnan, Lingxiao Zheng, Rajat Mittal, Fady Najjar, George V. Lauder and Tyson L. Hedrick, George Washington University, Harvard University and University of North Carolina, "Large Eddy Simulation of Flows with Complex Moving Boundaries: Application to Flying and Swimming in Animals", AIAA-2009-3976, (2009)

[305] X. Zheng, Q. Xue, R. Mittal, S. Beilamowicz, Johns Hopkins University and George Washington University, "A Coupled Sharp-Interface Immersed Boundary-Finite-Element Method for Flow-Structure Interaction With Application to Human Phonation, Journal of Biomechanical Engineering, ASME, DOI: 10.1115/1.4002587, (2010)