| Session |
Author(s) |
Title |
94 |
Fabian, ST*; Zhou, R; Lin, HT |
Dragon-drop: The passive mechanism and active control of the dragonfly’s aerial righting behaviour |
94 |
Palermo, N*; Hershman, M; Proenca, M; Theobald, J |
Drosophila melanogaster increase steering errors when relying on restricted-area optic flow fields |
94 |
Lingenfelter, B; van Breugel, F* |
Tradeoffs in spatial integration of optic flow for visual velocity estimation in flying insects |
94 |
Jordan, KA*; Yarger, AM; Fox, JL |
Halteres increase takeoff speed in calyptratae |
94 |
Mo, A*; Kamska, V; Contreras, FB; Daley, M; Badri-Spröwitz, A |
Developing a mechanical model for intraspinal mechanosensing in avians |
94 |
Johnsen, S*; Lohmann, KL; Warrant, EJ |
The wobbly compass needle: are the peculiarities of magnetic orientation behavior partially explained by low signal relative to noise? |
94 |
Kingston, ACN*; Chappell, DR; Speiser, DI |
A snapping shrimp has the fastest vision of any aquatic animal |
94 |
Uhrhan, MJ*; Fabian, JM; Siwanowicz, I; Lin, HT |
The sensory apparatus of dragonfly wings: sensor distribution and morphologies |
94 |
Weber, AI*; Daniel, TL; Brunton, BW |
Neural encoding and structural properties interact to determine optimal placement of sparse, spiking sensors on an insect wing |
94 |
Balebail, S*; Sisneros, JA |
Using finite element analysis to investigate the role of the swim bladder in directional hearing by the plainfin midshipman (Porichthys notatus) |
94 |
Natesan, D*; Dave, SD; Saxena, N; Sane, SP |
Flexibility of reflexes: How Johnston’s organs modulate the antennal set-point in flying hawkmoths |
94 |
Goyal, P*; Cribellier, A; Croon, G; Lankheet, M; Leeuwen, J; Pieters, R; Muijres, F |
Bumblebees land by adjusting the set-point of optical expansion rate in a stepwise manner |
