The detection threshold for odor plume tracking in the smooth dogfish, Mustelus canis.

Jennings, Ashley Robina

12 March 2016

The survival of Elasmobranch fishes (sharks, skates and rays) depends critically on their ability to sense odor cues. The outstanding question of detection thresholds to food odors in the shark is investigated in this study. The tracking behavior of Mustelus canis (the smooth dogfish) was analyzed using a binary choice flume designed specifically for testing odor preferences of aquatic animals. To determine threshold, odor was serially diluted until no tracking responses were observed. Sharks spent significantly more time in the odor side of the flume, regardless of their individual side bias, until the "squid juice" was diluted several orders of magnitude. For the whole flume the two greatest dilutions (10-4-10-5 at the odor source) did not cause significant choice and for the upstream flume half, all but the greatest dilution (10-5 at the odor source) caused significant odor side preference. To interpret these results fully we need to consider the structure of odor plumes and the function of the sharks' olfactory responses. Nonetheless, assuming that M. canis represent sharks in general, these findings demonstrate that their extraordinary sensitivity to food attractants may indicate aspects still unknown about life history of elasmobranch fishes including the ranges that benthic elasmobranchs are capable of traveling to feed.

Biology

Mustelus canis

Odor

Threshold

Plume tracking

Smooth dogfish

An investigation into insect chemical plume tracking using a mobile robot.

Harvey, David John.

January 2007

Insects are confronted with the problem of locating food, mates, prey and hosts for their young over long distances, which they often overcome using chemical plume tracking. Tracking a plume of chemical back to its source is made difficult due to the complexity of plume structure. Turbulence and shifts in the wind direction prevail over diffusion in the spreading of an airborne chemical from a point in most cases, producing intricate plumes consisting of filaments of high chemical concentration interspersed with regions of clean air. It has been proposed that insects achieve plume tracking in this environment through variations of anemotaxis, which involves travelling upwind when an attractive chemical is perceived. This study aimed to investigate anemotaxis through the use of a mobile robot to test the efficacy of algorithms which mimic the way insects achieve plume tracking and also to determine whether these algorithms are an effective means of plume tracking for a mobile robot under a range of conditions. To achieve the aims of this study, various plume-tracking algorithms were implemented on a mobile robot built to model a plume-tracking insect and their performance was compared under a range of wind conditions. The algorithms tested were based upon a range of plume-tracking hypotheses. The simplest algorithm was surge anemotaxis, where the robot surged upwind in the presence of an attractive chemical and performed crosswind casting (back and forth motion) in the absence of chemical. The other algorithms tested were the counterturner, where the robot zigzagged upwind, and two bounded search methods. To allow these algorithms to be appropriately implemented, a robot model was constructed that could move in two dimensions and sense the wind velocity and ion level at a point in space. An ion plume was used instead of a chemical plume in each test as it behaves in a similar manner to a chemical plume, but ion sensors have response and recovery times far more rapid than conventional chemical sensors, similar to insects. The plume-tracking robot was tested in three series of tests. Initially, the entire range of plume-tracking algorithms was tested in a wind tunnel with fixed wind direction for a range of wind speeds and release positions. The second series of tests compared the performance of the surge anemotaxis and bounded search algorithms, again in a wind tunnel, but with a wind shift of 20° during some of the tests. The algorithms were tested with and without a direct crosswind surge response to detected wind shifts. The third set of tests examined the performance of the simple and wind shift response algorithms outdoors using natural wind to produce the plume. All algorithms tested achieved successful plume tracking in some conditions. The surge anemotaxis and triangular bounded search algorithms were particularly successful. The tests also showed that the paths obtained from tests undertaken in natural outdoor wind conditions varied greatly from those undertaken in a wind tunnel. This indicates the need to test plume-tracking algorithms in natural environments. This is vital both in the investigation of insect plume-tracking behaviour, as insects navigate in these environments, and in the process of producing plume-tracking robots that are capable of operating effectively in these conditions. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1287973 / Thesis (Ph.D.) -- University of Adelaide, School of Mechanical Engineering, 2007

Robots Design and construction.

Sensing array for coherence analysis of modulated aquatic chemical plumes

Cantor, Ryan Segler

08 April 2009

An electrochemical sensor array can provide information about the spatial and temporal distribution of chemicals in liquid turbulent plumes. Planar laser induced fluorescence (PLIF) and amperometric sensor arrays were used to record signals from modulated chemical plumes released into a recirculating aquatic flume. Coherence analysis was applied to extract the frequency components contained in the sensor response. Effects due to release distance, modulation frequency, and array orientation were investigated. This study has demonstrated that frequency encoded information can be extracted from a turbulent chemical plume using an array of amperometric sensors with optimized three-dimensional geometry and tuning.

Chemical plume tracking

Electrochemical sensor array

Chemical detectors

Plumes (Fluid dynamics)

Eddies

Aquatic sciences

Coherence (Optics)