| Session |
Author(s) |
Title |
74 |
Zhao, W*; Ayala, J; Schulz, A; Rong, H; McGowan, C; Hu, D |
Juvenile pandas use head motion to maintain balance during climbing |
74 |
Greenslit, NW; Erskine, OM*; Iijima, M; Blob, RW; Palecek, AM |
Acrobatic archosaurs: kinematic comparisons of climbing behaviors in turtles and alligators |
74 |
Pulliam, JN*; Salcedo, MK; Weiss, TM; Hernandez, AM; Socha, JJ |
Climbing strategies of cicadas across vertical ‘gaps’ of low friction |
74 |
Wölfer, J*; Michel, J; Aschenbach, T; Nyakatura, JA |
A small squirrel (Tamiops swinhoei) sheds light on the complex biomechanical adaptations to fast arboreal locomotion |
74 |
Graham, M*; Clemente, CJ; Socha, JJ |
Body size influences transition to dynamic gap crossing movements in australian tree snakes |
74 |
Erickson, E*; Diaz, K; Carruthers, A; Ozkan-Aydin, Y; Chong, B; Goldman, DI |
Centipede locomotion on bumpy terrain |
74 |
Fu, Q*; Astley, HC; Li, C |
Snakes traversing complex 3-D terrain |
74 |
Diaz, K*; Chong, B; Ding, JL; Lu, H; Goldman, DI |
C. elegans maneuvering strategies in heterogeneous environments |
74 |
Vega, CM*; Ashley-Ross, MA |
Tiger salamanders (Ambystoma tigrinum) increase foot contact surface area on challenging substrates during terrestrial locomotion |
74 |
Zheng, B*; Xuan, Q; LI, C |
Stochastic dynamics model statistically predicts beam obstacle traversal |
74 |
Xuan, Q*; Li, C |
An energy landscape based dynamic model to simulate locomotion in complex 3-D terrain |
