Caltech Library System
About | Browse | Search | Caltech Student Instructions
|
About | Browse | Search | Caltech Student Instructions |
Type of Document Dissertation Author Reiser, Michael B. Author's Email Address mreiser AT gmail.com URN etd-01082007-033253 Persistent URL http://resolver.caltech.edu/CaltechETD:etd-01082007-033253 Title Visually mediated control of flight in Drosophila: not lost in translation Degree PhD Option Computation and Neural Systems Advisory Committee
Advisor Name Title Joel Wakeman Burdick Committee Chair Christof Koch Committee Member Michael Dickinson Committee Member Pietro Perona Committee Member Richard M. Murray Committee Member Keywords
- Drosophila
- flight control
- insect vision
- optic flow
Date of Defense 2006-12-15 Availability restricted Abstract Flying insects exhibit stunning behavioral repertoires that are largely mediated by the visual control of flight. For this reason, presenting a controlled visual environment to tethered insects has been and continues to be a powerful tool for studying the sensory control of complex behaviors. The work presented in this dissertation concerns several robust behavioral responses exhibited by Drosophila that shed light on some of the challenges of visual navigation. To address questions of visual flight control in Drosophila, a modular display system has been designed and has proven to be a robust experimental instrument. The display system has enabled the wide variety of experimental paradigms presented in the thesis.
Much is known about the responses of tethered Drosophila to rotational stimuli. However, the processing of the more complex patterns of motion that occur during translatory flight is largely unknown. Recent experimental results have demonstrated that Drosophila turn away from visual patterns of expansion. However, the avoidance of expansion is so vigorous, that flies robustly orient towards the focus of contraction of a translating flow field. Much of the effort documented in this thesis has sought to explain this paradox.
The paradox has been largely resolved by several significant findings. When undergoing flight directed towards a prominent object, Drosophila will tolerate a level of expansion that would otherwise induce avoidance. The expansion-avoidance behavior is also critically dependent on the speed of image motion; in response to reduced speeds of expansion, Drosophila exhibit a centering response in which they steer towards the focus of expansion by balancing the image motion seen by both eyes. Taken together, these behaviors contribute to a model of Drosophila's visual flight control as emerging from multiple behavioral modules that operate concurrently.
Simple computational models of Drosophila's visual system are used to demonstrate that the experimental results arrived at by doing psychophysics on tethered animals actually yield sensible navigation strategies. This final component of the thesis documents an effort to close the feedback loop around the experimenter, by using computational models of Drosophila behavior to constrain the design of future experiments.
Files
Filename Size Approximate Download Time (Hours:Minutes:Seconds)
28.8 Modem 56K Modem ISDN (64 Kb) ISDN (128 Kb) Higher-speed Access Reiser_thesis.pdf 45.86 Mb 03:32:17 01:49:10 01:35:32 00:47:46 00:04:04 indicates that a file or directory is accessible from the campus network only and must not be distributed to non-campus persons.