Deep Learning for Agriculture

Maria Pantoja; Franz J. Kurfess; Irene Humer

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Conference: 2020 ASEE Virtual Annual Conference Content Access
Location: Virtual On line
Publication Date: June 22, 2020
Start Date: June 22, 2020
End Date: June 26, 2021
Conference Session: Biological and Agricultural Engineering Division Technical Session 1
Tagged Division: Biological and Agricultural Engineering
Page Count: 13
DOI: 10.18260/1-2--34371
Permanent URL: https://strategy.asee.org/34371
Download Count: 591

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Paper Authors

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Maria Pantoja California Polytechnic State University, San Luis Obispo

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Maria Pantoja
Computer Engineering
Computer Science & Software Engineering
Office: 14-211
Phone Number: 805-756-1330
Email: mpanto01@calpoly.edu
Homepage:
https://cpe.calpoly.edu/faculty/mpanto01/
Biography
B.S., Universidad Politecnica de Valencia, Spain
Ph.D., Santa Clara University

Research Interests
High Performance Computing
Neural-Electronics
Parallel Computing

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Franz J. Kurfess California Polytechnic State University, San Luis Obispo orcid.org/0000-0003-1418-7198

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Franz J. Kurfess is a professor in the Computer Science and Software Engineering Department, California Polytechnic State University, San Luis Obispo, where he teaches mostly courses in Artificial Intelligence, Human-Computer Interaction, and User-Centered Design. Before joining Cal Poly, he was with Concordia University in Montreal, Canada, the New Jersey Institute of Technology, the University of Ulm, Germany, the International Computer Science Institute in Berkeley, CA, and the Technical University in Munich, where he obtained his M.S. and Ph.D. in Computer Science.

His main areas of research are Artificial Intelligence and Human-Computer Interaction, with particular interest in the intersection of the two fields.

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Irene Humer California Polytechnic State University, San Luis Obispo orcid.org/0000-0003-2647-4813

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Ph. D. Electrical Engineering and Information Technology, Vienna University of Technology
M. S. Physics, University of Vienna
M. S. Education Physics and Mathematics, University of Vienna

Research Interests: Computer Science Education, Physics Simulation, Applied Computing

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Abstract

The global population is estimated to reach 8 billion by 2023. To feed such an immense population in a sustainable way, while also enabling farmers to make a living, requires the modernization of production methods in agriculture. In recent years there has been a lot of excitement in academic research and industry about the application of modern computer technology to farming, making farming one of the favorites for investors. According to Forbes Magazine, the agricultural technology gold rush began in 2013, with Monsanto’s purchase of the agricultural data company, The Climate Corporation, for $930 million. The total investment in 2017 topped $1.5 billion, setting a new record. All economic indicators point to a huge increase in technology and in particular software used in the agriculture fields. The need for advanced technology in agriculture is clear. The technology is being developed and ready, but what is still lacking is the number of professionals that have both skills - agriculture and technological knowledge - in particular in advanced computing methods like computer vision and deep learning. The main goal of this paper is to report on our approach to close the gap between domain experts in agriculture and computer scientists by developing a practical, hands-on activity in the form of a workshop or tutorial specifically targeted at agricultural engineers and practitioners interested in applying computer vision techniques to solve agricultural problems. The tutorial consists of specific examples like detecting and counting bees, segmentation of fruit trees and automatic fruit classification. The examples for the tutorials are chosen because of their simplicity of implementation and because they are also easily expandable into more complex projects. For example, the segmentation tutorial can be used to estimate pruning weight which is useful to determine the baseline vigor levels of the fruit trees. It is one of the best ways to quantify areas of the orchards that are not uniform in terms of expected yield, which will enable the use of precision agriculture. The benefits of precision agriculture are multifold leading to reductions in cost and increases in production by targeting specific areas. We explain and develop the tutorials for agricultural engineers assuming no previous knowledge in computer programming or computer vision.

Citation
Format

Pantoja, M., & Kurfess, F. J., & Humer, I. (2020, June), Deep Learning for Agriculture Paper presented at 2020 ASEE Virtual Annual Conference Content Access, Virtual On line . 10.18260/1-2--34371

TY - CPAPER
AB - The global population is estimated to reach 8 billion by 2023. To feed such an
immense population in a sustainable way, while also enabling farmers to make a living, requires
the modernization of production methods in agriculture. In recent years there has been a lot of
excitement in academic research and industry about the application of modern computer
technology to farming, making farming one of the favorites for investors. According to Forbes
Magazine, the agricultural technology gold rush began in 2013, with Monsanto’s purchase of the
agricultural data company, The Climate Corporation, for $930 million. The total investment
in 2017 topped $1.5 billion, setting a new record. All economic indicators point to a huge
increase in technology and in particular software used in the agriculture fields.
The need for advanced technology in agriculture is clear. The technology is being developed and
ready, but what is still lacking is the number of professionals that have both skills - agriculture
and technological knowledge - in particular in advanced computing methods like computer
vision and deep learning.
The main goal of this paper is to report on our approach to close the gap between domain experts
in agriculture and computer scientists by developing a practical, hands-on activity in the form of
a workshop or tutorial specifically targeted at agricultural engineers and practitioners interested
in applying computer vision techniques to solve agricultural problems. The tutorial consists of
specific examples like detecting and counting bees, segmentation of fruit trees and automatic
fruit classification. The examples for the tutorials are chosen because of their simplicity of
implementation and because they are also easily expandable into more complex projects. For
example, the segmentation tutorial can be used to estimate pruning weight which is useful to
determine the baseline vigor levels of the fruit trees. It is one of the best ways to quantify areas
of the orchards that are not uniform in terms of expected yield, which will enable the use of
precision agriculture. The benefits of precision agriculture are multifold leading to reductions in
cost and increases in production by targeting specific areas. We explain and develop the tutorials
for agricultural engineers assuming no previous knowledge in computer programming or
computer vision.
AU - Maria Pantoja
AU - Franz J. Kurfess
AU - Irene Humer
CY - Virtual On line
DA - 2020/06/22
PB - ASEE Conferences
TI - Deep Learning for Agriculture
UR - https://strategy.asee.org/34371
DO - 10.18260/1-2--34371
ER -