Ramesh, K., Gopalarathnam, A., Ol, M., Granlund, K., Edwards, J.: Augmentation of inviscid airfoil theory to predict and model 2D unsteady vortex dominated flows. Ramesh, K., Gopalarathnam, A., Granlund, K., Ol, M., Edwards, J.: Discrete-vortex method with novel shedding criterion for unsteady aerofoil flows with intermittent leading-edge vortex shedding. thesis, North Carolina State University (2013) Ramesh, K.: Theory and low-order modelling of unsteady airfoil flows. Phillips, N., Knowles, K., Bomphrey, R.: Petiolate wings: effects on the leading-edge vortex in flapping flight. Maxworthy, T.: Experiments on the Weis-Fogh mechanism of lift generation by insects in hovering flight. Lentink, D., Dickson, W., van Leeuwen, J., Dickinson, M.H.: Leading-edge vortices elevate lift of autorotating plant seeds. Lentink, D., Dickinson, M.H.: Rotational accelerations stabilize leading edge vortices on revolving fly wings. Kurtulus, D., Scarano, F., David, L.: Unsteady aerodynamic forces estimation on a square cylinder by TR-PIV. Kruyt, J.W., van Heijst, G.F., Altshuler, D.L., Lentink, D.: Power reduction and the radial limit of stall delay in revolving wings of different aspect ratio.
Jones, A., Babinsky, H.: Unsteady lift generation on rotating wings at low Reynolds numbers. Jeong, J., Hussain, F.: On the identification of a vortex. Jardin, T., David, L., Farcy, A.: Characterization of vortical structures and loads based on time-resolved piv for asymmetric hovering flapping flight. Jardin, T., David, L.: Coriolis effects enhance lift on revolving wings. Jardin, T., David, L.: Spanwise gradients in flow speed help stabilize leading-edge vortices on revolving wings. Jardin, T.: Coriolis effect and the attachment of the leading edge vortex. Gursul, I., Lin, H., Ho, C.M.: Effects of time scales on lift of airfoils in an unsteady stream. Gursul, I., Ho, C.M.: High aerodynamic loads on an airfoil submerged in an unsteady stream. 51, 75–104 (2019)Įllington, C.P., den Berg, C.V., Willmott, A.P., Thomas, A.L.: Leading-edge vortices in insect flight. 858, 917–948 (2019)Įldredge, J., Jones, A.: Leading-edge vortices: mechanics and modeling. 197(25–28), 2131–2146 (2008)ĭarakananda, D., Eldredge, J.: A versatile taxonomy of low-dimensional vortex models for unsteady aerodynamics. 49, 2018–2033 (2011)Ĭolonius, T., Taira, K.: A fast immersed boundary method using a nullspace approach and multi-domain far-field boundary conditions. 51, 968–980 (2013)Ĭleaver, D.J., Wang, Z., Gursul, I., Visbal, M.R.: Lift enhancement by means of small-amplitude airfoil oscillations at low reynolds numbers. 763, 237–253 (2015)Ĭleaver, D.J., Wang, Z., Gursul, I.: Investigation of high-lift mechanisms for a flat-plate airfoil undergoing small-amplitude plunging oscillations.
thesis, California Institute of Technology (2016)Ĭhoi, J., Colonius, T., Williams, D.: Surging and plunging oscillations of an airfoil at low Reynolds number. 51, 2953–2964 (2013)Ĭhoi, J.: Unsteady aerodynamics and optimal control of an airfoil at low Reynolds number. 207, 1063–1072 (2004)Ĭalderon, D.E., Wang, Z., Gursul, I.: Lift-enhancing vortex flows generated by plunging rectangular wings with small amplitude. 220, 169–186 (2006)īirch, J.M., Dickson, W.B., Dickinson, M.H.: Force production and flow structure of the leading edge vortex on flapping wings at high and low Reynolds numbers. 13, 71–80 (2009)Īnsari, S., Zbikowski, R., Knowles, K.: Non-linear unsteady aerodynamic model for insect-like flapping wings in the hover. Andro, J.Y., Jacquin, L.: Frequency effects on the aerodynamic mechanisms of a heaving airfoil in a forward flight configuration.