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Insect Event Extraction in LIDAR Images using Image Analysis and Convolutional Neural Networks

Malmros, Ludvig LU (2018) In Master's Theses in Mathematical Sciences FMAM05 20181
Mathematics (Faculty of Engineering)
Abstract
Insect monitoring has earlier been a manual, tedious and time consuming task that is impossible to do in real time. Thus there exists a need for a real time automatic insect monitoring system for counting and classifying insect for use in scientific research and pesticide spraying control. One approach to automatize this is using LIDAR to detect insects. In this thesis it has been explored how to detect, segment and do merge classification on insect events showing up in large 2D time-range map frames created from a LIDAR optics setup as insects fly through a laser beam.
The suggested extraction method combines simple intensity thresholding techniques and well known edge detection techniques to do the first selection of insect event pixels. A... (More)
Insect monitoring has earlier been a manual, tedious and time consuming task that is impossible to do in real time. Thus there exists a need for a real time automatic insect monitoring system for counting and classifying insect for use in scientific research and pesticide spraying control. One approach to automatize this is using LIDAR to detect insects. In this thesis it has been explored how to detect, segment and do merge classification on insect events showing up in large 2D time-range map frames created from a LIDAR optics setup as insects fly through a laser beam.
The suggested extraction method combines simple intensity thresholding techniques and well known edge detection techniques to do the first selection of insect event pixels. A statistical dilation iteration stopping criteria based on background noise is suggested for region growing. Together they create a segmentation method that is used to segment insect events while avoiding accidental splitting and merging of events. Thereafter a trained convolutional neural network is suggested to classify all events that might have been merged, such that they could be discarded instead of being inputted to the species classification system.
Tests and observations indicate that the old segmentation method finds close to all the wanted insect events, but over-segments them drastically in some cases. By dividing the method into one event detection and one border finding part, the suggested extraction method are able to find the same amount of events without increasing the number of splits and merges. At the same time it is able to find event segmentation borders with a higher precision then previously possible.
Tests on the merge classification indicate surprisingly good results for the ability to classify event merges. Creating artificial merges to handle the imbalanced data set shows further improvement, while oversampling does not. Indicated is also that the size compression used does not seem to effect the classification negatively. (Less)
Please use this url to cite or link to this publication:
author
Malmros, Ludvig LU
supervisor
organization
course
FMAM05 20181
year
type
H2 - Master's Degree (Two Years)
subject
keywords
Image analysis, Machine Learning
publication/series
Master's Theses in Mathematical Sciences
report number
LUTFMA-3355-2018
ISSN
1404-6342
other publication id
2018:E37
language
English
id
8955090
date added to LUP
2018-09-19 14:29:59
date last changed
2018-09-19 14:29:59
@misc{8955090,
  abstract     = {{Insect monitoring has earlier been a manual, tedious and time consuming task that is impossible to do in real time. Thus there exists a need for a real time automatic insect monitoring system for counting and classifying insect for use in scientific research and pesticide spraying control. One approach to automatize this is using LIDAR to detect insects. In this thesis it has been explored how to detect, segment and do merge classification on insect events showing up in large 2D time-range map frames created from a LIDAR optics setup as insects fly through a laser beam.
The suggested extraction method combines simple intensity thresholding techniques and well known edge detection techniques to do the first selection of insect event pixels. A statistical dilation iteration stopping criteria based on background noise is suggested for region growing. Together they create a segmentation method that is used to segment insect events while avoiding accidental splitting and merging of events. Thereafter a trained convolutional neural network is suggested to classify all events that might have been merged, such that they could be discarded instead of being inputted to the species classification system.
Tests and observations indicate that the old segmentation method finds close to all the wanted insect events, but over-segments them drastically in some cases. By dividing the method into one event detection and one border finding part, the suggested extraction method are able to find the same amount of events without increasing the number of splits and merges. At the same time it is able to find event segmentation borders with a higher precision then previously possible.
Tests on the merge classification indicate surprisingly good results for the ability to classify event merges. Creating artificial merges to handle the imbalanced data set shows further improvement, while oversampling does not. Indicated is also that the size compression used does not seem to effect the classification negatively.}},
  author       = {{Malmros, Ludvig}},
  issn         = {{1404-6342}},
  language     = {{eng}},
  note         = {{Student Paper}},
  series       = {{Master's Theses in Mathematical Sciences}},
  title        = {{Insect Event Extraction in LIDAR Images using Image Analysis and Convolutional Neural Networks}},
  year         = {{2018}},
}