SFX by Ex Libris Inc.

Title:	Adverse rotorcraft pilot couplings—Past, present and future challenges
Source:	Progress in Aerospace Sciences [0376-0421] Pavel, Marilena yr:2013

Basic

Sorry, no full text available...

Please use the document delivery service (see below)

Holding information

Holdings in library search engine ALBERT

Document delivery

Request document via Library/Bibliothek

Users interested in this article also expressed an interest in the following:
description	1.	Murugan, S. "Morphing wing flexible skins with curvilinear fiber composites." Composite structures 99 (2013): 69-75.
description	2.	Brocklehurst, A. "A review of helicopter rotor blade tip shapes." Progress in aerospace sciences 56 (2012): 35-74.
description	3.	Arabagi, V. "Design and manufacturing of a controllable miniature flapping wing robotic platform." The international journal of robotics research 31.6 (2012): 785-800.
description	4.	Lentink, D. "How swifts control their glide performance with morphing wings." Nature 446.7139 (2007): 1082-1085.
description	5.	Nakata, T. "A fluid-structure interaction model of insect flight with flexible wings." Journal of computational physics 231.4 (2012): 1822-1847.
description	6.	Couceiro, Micael S. "Modeling and control of biologically inspired flying robots." Robotica 30.1 (2012): 107-121.
description	7.	Barbarino, S. "Design of extendable chord sections for morphing helicopter rotor blades." Journal of intelligent material systems and structures 22.9 (2011): 891-905.
description	8.	Asheghian, L. "Shear Morphing Skins - Simulation and Testing of Optimized Design." Journal of intelligent material systems and structures 22.9 (2011): 945-960.
description	9.	Askue, V. "Rotor blade design." Air medical journal 23.3 (2004): 8-9.
description	10.	Sofla,, A.Y.N., A.Y.N. N. "Shape morphing of aircraft wing: Status and challenges." Materials in engineering 31.3 (2010): 1284-1292.
description	11.	Padfield, G. D. D. Helicopter flight dynamics : the theory and application of flying qualities and simulation modelling. Blackwell Publishing, 2007. 1-642.
description	12.	Kanda, K. "Simple fabrication of metal-based piezoelectric MEMS by direct deposition of Pb(Zr,Ti) O3 thin films on titanium substrates." Journal of microelectromechanical systems 18.3 (2009): 610-615.
description	13.	Paradies, R. "Active wing design with integrated flight control using piezoelectric macro fiber composites." Smart materials & structures 18.3 (2009): 35010-.
description	14.	LYNN, T.B. B. "DIRECT DRAG MEASUREMENTS IN A TURBULENT FLAT-PLATE BOUNDARY-LAYER WITH TURBULENCE MANIPULATORS." Experiments in fluids 19.6 (1995): 405-416.
description	15.	Ganguli, R. "Optimum design of a helicopter rotor for low vibration using aeroelastic analysis and response surface methods." Journal of Sound and Vibration 258.2 (2002): 327-43.
description	16.	Render, P. "Experimental investigation into the aerodynamics of battle damaged airfoils.(Author abstract)." Journal of aircraft 44.2 (2007): 539-.
description	17.	Deng, Xinyan Y. "Flapping flight for biomimetic robotic insects: Part II - Flight control design." IEEE Transactions on Robotics 22.4 (2006): 789-803.
description	18.	Tuzcu, I. "On the stability of flexible aircraft." Aerospace science and technology 12.5 (2008): 376-384.
description	19.	Watkinson, J. Art of the Helicopter. 2003.
description	20.	Henningsson, P. "Aerodynamics of gliding flight in common swifts." Journal of experimental biology 214.3 (2011): 382-393.