Watson on the farm: using cloud-based artificial intelligence to identify early indicators of water stress

Watson on the farm: using cloud-based artificial intelligence to identify early indicators of water stress

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As demand for freshwater increases while supply remains stagnant, the critical need for sustainable water use in agriculture has led the EPA Strategic Plan to call for new technologies that can optimize water allocation in real-time. This work assesses the use of cloud-based artificial intelligence to detect early indicators of water stress across six container-grown ornamental shrub species. Near-infrared images were previously collected with modified Canon and MAPIR Survey II cameras deployed via a small unmanned aircraft system (sUAS) at an altitude of 30 meters. Cropped images of plants in no, low-, and high-water stress conditions were split into four-fold cross-validation sets and used to train models through IBM Watson’s Visual Recognition service. Despite constraints such as small sample size (36 plants, 150 images) and low image resolution (150 pixels by 150 pixels per plant), Watson generated models were able to detect indicators of stress after 48 hours of water deprivation with a significant to marginally significant degree of separation in four out of five species tested (p < 0.10). Two models were also able to detect indicators of water stress after only 24 hours, with models trained on images of as few as eight water-stressed Buddleia plants achieving an average area under the curve (AUC) of 0.9884 across four folds. Ease of pre-processing, minimal amount of training data required, and outsourced computation make cloud-based artificial intelligence services such as IBM Watson Visual Recognition an attractive tool for agriculture analytics. Cloud-based artificial intelligence can be combined with technologies such as sUAS and spectral imaging to help crop producers identify deficient irrigation strategies and intervene before crop value is diminished. When brought to scale, frameworks such as these can drive responsive irrigation systems that monitor crop status in real-time and maximize sustainable water use.

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Bibliographic Details
Main Authors: Freeman, Daniel, Gupta, Shaurya, Smith, D. Hudson, Maja, Joe Mari, Robbins, James, Owen, James S., Peña Barragán, José Manuel, Castro, Ana Isabel de
Other Authors: J. Frank Schmidt Family Charitable Foundation
Format: artículo biblioteca
Language:Spanish / Castilian
Published: Multidisciplinary Digital Publishing Institute 2019-11-13
Subjects:sUAS, Water stress, Ornamental, Container-grown, Artificial intelligence, Machine learning, Deep learning, Neural network, Visual recognition, Precision agriculture,
Online Access:http://hdl.handle.net/10261/195374
http://dx.doi.org/10.13039/501100004837
http://dx.doi.org/10.13039/501100003339
http://dx.doi.org/10.13039/100000199
http://dx.doi.org/10.13039/100005825
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spelling dig-ica-es-10261-1953742020-07-27T06:25:19Z Watson on the farm: using cloud-based artificial intelligence to identify early indicators of water stress Freeman, Daniel Gupta, Shaurya Smith, D. Hudson Maja, Joe Mari Robbins, James Owen, James S. Peña Barragán, José Manuel Castro, Ana Isabel de J. Frank Schmidt Family Charitable Foundation National Institute of Food and Agriculture (US) Department of Agriculture (US) Ministerio de Ciencia e Innovación (España) Consejo Superior de Investigaciones Científicas (España) sUAS Water stress Ornamental Container-grown Artificial intelligence Machine learning Deep learning Neural network Visual recognition Precision agriculture As demand for freshwater increases while supply remains stagnant, the critical need for sustainable water use in agriculture has led the EPA Strategic Plan to call for new technologies that can optimize water allocation in real-time. This work assesses the use of cloud-based artificial intelligence to detect early indicators of water stress across six container-grown ornamental shrub species. Near-infrared images were previously collected with modified Canon and MAPIR Survey II cameras deployed via a small unmanned aircraft system (sUAS) at an altitude of 30 meters. Cropped images of plants in no, low-, and high-water stress conditions were split into four-fold cross-validation sets and used to train models through IBM Watson’s Visual Recognition service. Despite constraints such as small sample size (36 plants, 150 images) and low image resolution (150 pixels by 150 pixels per plant), Watson generated models were able to detect indicators of stress after 48 hours of water deprivation with a significant to marginally significant degree of separation in four out of five species tested (p < 0.10). Two models were also able to detect indicators of water stress after only 24 hours, with models trained on images of as few as eight water-stressed Buddleia plants achieving an average area under the curve (AUC) of 0.9884 across four folds. Ease of pre-processing, minimal amount of training data required, and outsourced computation make cloud-based artificial intelligence services such as IBM Watson Visual Recognition an attractive tool for agriculture analytics. Cloud-based artificial intelligence can be combined with technologies such as sUAS and spectral imaging to help crop producers identify deficient irrigation strategies and intervene before crop value is diminished. When brought to scale, frameworks such as these can drive responsive irrigation systems that monitor crop status in real-time and maximize sustainable water use. This work was partially supported by a grant from the J. Frank Schmidt Family Charitable Foundation and is based on work supported by NIFA/USDA under project numbers SC-1700540, SC-1700543 and 2014-51181-22372 (USDA-SCRI Clean WateR3). Research of Drs. Peña and de Castro was financed by the “Salvador de Madariaga” for Visiting Researchers in Foreign Centers Program (Spanish MICINN funds) and the Intramural-CSIC Project (ref. 201940E074), respectively. Peer reviewed 2019-11-22T14:55:02Z 2019-11-22T14:55:02Z 2019-11-13 2019-11-22T14:55:02Z artículo http://purl.org/coar/resource_type/c_6501 Remote Sensing 11(22): 2645 (2019) http://hdl.handle.net/10261/195374 10.3390/rs11222645 2072-4292 http://dx.doi.org/10.13039/501100004837 http://dx.doi.org/10.13039/501100003339 http://dx.doi.org/10.13039/100000199 http://dx.doi.org/10.13039/100005825 es Publisher's version https://doi.org/10.3390/rs11222645 Sí open Multidisciplinary Digital Publishing Institute
institution ICA ES
collection DSpace
country España
countrycode ES
component Bibliográfico
access En linea
databasecode dig-ica-es
tag biblioteca
region Europa del Sur
libraryname Biblioteca del ICA España
language Spanish / Castilian
topic sUAS
Water stress
Ornamental
Container-grown
Artificial intelligence
Machine learning
Deep learning
Neural network
Visual recognition
Precision agriculture
sUAS
Water stress
Ornamental
Container-grown
Artificial intelligence
Machine learning
Deep learning
Neural network
Visual recognition
Precision agriculture
spellingShingle sUAS
Water stress
Ornamental
Container-grown
Artificial intelligence
Machine learning
Deep learning
Neural network
Visual recognition
Precision agriculture
sUAS
Water stress
Ornamental
Container-grown
Artificial intelligence
Machine learning
Deep learning
Neural network
Visual recognition
Precision agriculture
Freeman, Daniel
Gupta, Shaurya
Smith, D. Hudson
Maja, Joe Mari
Robbins, James
Owen, James S.
Peña Barragán, José Manuel
Castro, Ana Isabel de
Watson on the farm: using cloud-based artificial intelligence to identify early indicators of water stress
description As demand for freshwater increases while supply remains stagnant, the critical need for sustainable water use in agriculture has led the EPA Strategic Plan to call for new technologies that can optimize water allocation in real-time. This work assesses the use of cloud-based artificial intelligence to detect early indicators of water stress across six container-grown ornamental shrub species. Near-infrared images were previously collected with modified Canon and MAPIR Survey II cameras deployed via a small unmanned aircraft system (sUAS) at an altitude of 30 meters. Cropped images of plants in no, low-, and high-water stress conditions were split into four-fold cross-validation sets and used to train models through IBM Watson’s Visual Recognition service. Despite constraints such as small sample size (36 plants, 150 images) and low image resolution (150 pixels by 150 pixels per plant), Watson generated models were able to detect indicators of stress after 48 hours of water deprivation with a significant to marginally significant degree of separation in four out of five species tested (p < 0.10). Two models were also able to detect indicators of water stress after only 24 hours, with models trained on images of as few as eight water-stressed Buddleia plants achieving an average area under the curve (AUC) of 0.9884 across four folds. Ease of pre-processing, minimal amount of training data required, and outsourced computation make cloud-based artificial intelligence services such as IBM Watson Visual Recognition an attractive tool for agriculture analytics. Cloud-based artificial intelligence can be combined with technologies such as sUAS and spectral imaging to help crop producers identify deficient irrigation strategies and intervene before crop value is diminished. When brought to scale, frameworks such as these can drive responsive irrigation systems that monitor crop status in real-time and maximize sustainable water use.
author2 J. Frank Schmidt Family Charitable Foundation
author_facet J. Frank Schmidt Family Charitable Foundation
Freeman, Daniel
Gupta, Shaurya
Smith, D. Hudson
Maja, Joe Mari
Robbins, James
Owen, James S.
Peña Barragán, José Manuel
Castro, Ana Isabel de
format artículo
topic_facet sUAS
Water stress
Ornamental
Container-grown
Artificial intelligence
Machine learning
Deep learning
Neural network
Visual recognition
Precision agriculture
author Freeman, Daniel
Gupta, Shaurya
Smith, D. Hudson
Maja, Joe Mari
Robbins, James
Owen, James S.
Peña Barragán, José Manuel
Castro, Ana Isabel de
author_sort Freeman, Daniel
title Watson on the farm: using cloud-based artificial intelligence to identify early indicators of water stress
title_short Watson on the farm: using cloud-based artificial intelligence to identify early indicators of water stress
title_full Watson on the farm: using cloud-based artificial intelligence to identify early indicators of water stress
title_fullStr Watson on the farm: using cloud-based artificial intelligence to identify early indicators of water stress
title_full_unstemmed Watson on the farm: using cloud-based artificial intelligence to identify early indicators of water stress
title_sort watson on the farm: using cloud-based artificial intelligence to identify early indicators of water stress
publisher Multidisciplinary Digital Publishing Institute
publishDate 2019-11-13
url http://hdl.handle.net/10261/195374
http://dx.doi.org/10.13039/501100004837
http://dx.doi.org/10.13039/501100003339
http://dx.doi.org/10.13039/100000199
http://dx.doi.org/10.13039/100005825
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