research-article

Designing and Developing a Weed Detection Model for California Thistle

Authors:

Hossein Chegini,

Fernando Beltran,

Aniket MahantiAuthors Info & Claims

ACM Transactions on Internet Technology, Volume 23, Issue 3

Article No.: 48, Pages 1 - 29

https://doi.org/10.1145/3544491

Published: 21 August 2023 Publication History

Abstract

With a great percentage of farms in New Zealand as pastures, they are mainly important in contributing to the milk and meat industries. Pasture quality is highly affected by weeds. Weeds grow fast and invade pastures by seed pollination. They consume the nutrients, water, and other minerals, and once they are bitter, cattle do not eat them. Therefore, dairy farmers have to allocate a significant portion of their budget and time to monitor and clean weeds. Unfortunately, most weed management tasks are manual with no consistent technology. Thus, the motivation behind this article was to design an object detection model for weed monitoring and control in pastures. The model was designed and tested on California thistle, a dominant and widespread weed on New Zealand pastures. Our study is one of the major model designs for identifying weeds in an in-pasture environment, one of the most complicated environments for any object detection model. A synthetic methodology was used to create three types of datasets: plant-based, leaf-based, and mixed. The trained model based on the leaf-based dataset is one of the major contributions of our work and has not been conducted by any other weed detection models. After models had been trained, tuning experimentation was undertaken to improve the model’s performance. This involved studying the model’s hyperparameters in various ranges and then recording their values at the optimum points. The improved model showed a 93% mAP accuracy in the detection of training images and over 95% accuracy for testing images. The experimentation showed that the leaf-based model was slightly better than other models. The model can automate highly any weed management system. The use of this model will save farmers time and money and help them reduce the errors of manual work.

References

[1]

Ankush Gupta, Abhishek Dutta, and Andrew Zisserman. 2016. VGG annotation. Retrieved June 6, 2014, from http://www.robots.ox.ac.uk/vgg/software/via(2016).

[2]

G. W. Bourdôt, S. V. Fowler, G. R. Edwards, D. J. Kriticos, J. M. Kean, A. Rahman, and A. J. Parsons. 2007. Pastoral weeds in New Zealand: Status and potential solutions. New Zealand Journal of Agricultural Research 50, 2 (June2007), 139–161.

[3]

Hossein Chegini and Aniket Mahanti. 2019. A framework of automation on context-aware internet of things (IoT) systems. In Proceedings of the 12th IEEE/ACM International Conference on Utility and Cloud Computing Companion (UCC ’19 Companion). ACM Press, New York, NY.

Digital Library

[4]

Hossein Chegini, Aniket Mahanti, and Fernando Beltran. 2021. Smart and Sustainable Agriculture (1st ed.). Springer Nature, Cham, Switzerland.

[5]

Hossein Chegini, Aniket Mahanti, Ranesh Naha, and Parimala Thulasiraman. 2021. Process automation in an IoT-fog-cloud ecosystem: A survey and taxonomy. IoT 2 (2021).

[6]

Fenil Dankhara, Kartik Patel, and Nishant Doshi. 2019. Analysis of robust weed detection techniques based on the Internet of Things (IoT). Procedia Computer Science 160 (2019), 696–701.

Digital Library

[7]

Bruno de Lima Fruet, Aldo Merotto, and André da Rosa Ulguim. 2019. Survey of rice weed management and public and private consultant characteristics in Southern Brazil. Weed Technology 34, 3 (Nov.2019), 351–356.

[8]

R. Elakkiya, Deepak Kumar Jain, Ketan Kotecha, Sharnil Pandya, Sai Siddhartha Reddy, Rajalakshmi E, Vijayakumar Varadarajan, Aniket Mahanti, and Subramaniyaswamy V. 2021. Hybrid deep neural network for handling data imbalance in precursor MicroRNA. Front. Public Health 9 (Dec.2021), 821410.

[9]

R. Elakkiya, V. Subramaniyaswamy, V. Vijayakumar, and Aniket Mahanti. 2022. Cervical cancer diagnostics healthcare system using hybrid object detection adversarial networks. IEEE J. Biomed. Health Inform. 26, 4 (April2022), 1464–1471.

[10]

Mark Everingham, Luc Van Gool, Christopher K. I. Williams, John Winn, and Andrew Zisserman. 2009. The Pascal visual object classes (VOC) challenge. International Journal of Computer Vision 88, 2 (Sept.2009), 303–338.

Digital Library

[11]

George B. Frisvold, Joshua Albright, David E. Ervin, Micheal D. K. Owen, Jason K. Norsworthy, Katherine E. Dentzman, Terrance M. Hurley, Raymond A. Jussaume, Jeffrey L. Gunsolus, and Wesley Everman. 2020. Do farmers manage weeds on owned and rented land differently? Evidence from US corn and soybean farms. Pest Management Science 76, 6 (Feb.2020), 2030–2039.

[12]

Jiuxiang Gu, Zhenhua Wang, Jason Kuen, Lianyang Ma, Amir Shahroudy, Bing Shuai, Ting Liu, Xingxing Wang, Gang Wang, Jianfei Cai, and Tsuhan Chen. 2018. Recent advances in convolutional neural networks. Pattern Recognition 77 (May2018), 354–377.

Digital Library

[13]

P. J. Hardin, M. W. Jackson, V. J. Anderson, and R. Johnson. 2007. Detecting Squarrose Knapweed (Centaurea virgataLam. Ssp.squarrosaGugl.) Using a remotely piloted vehicle: A Utah case study. GIScience & Remote Sensing 44, 3 (Sept.2007), 203–219.

[14]

Martin Harries, Ken C. Flower, Craig A. Scanlan, Michael T. Rose, and Michael Renton. 2020. Interactions between crop sequences, weed populations and herbicide use in Western Australian broadacre farms: Findings of a six-year survey. Crop and Pasture Science 71, 5 (2020), 491.

[15]

Saima Hashim, Asad Jan, Shah Fahad, Hafiz Haider Ali, Muhammad Naeem Mushtaq, Karim Bux Laghari, Khawar Jabran, and Bhagirath Singh Chauhan. 2019. Weed management and herbicide resistant weeds: A case study from wheat growing areas of Pakistan. Pakistan Journal of Botany 51, 5 (April2019).

[16]

Kaiming He, Georgia Gkioxari, Piotr Dollar, and Ross Girshick. 2017. Mask R-CNN. In 2017 IEEE International Conference on Computer Vision (ICCV’17). IEEE.

[17]

Emmanuel Oyamedan Imoloame, Ibrahim Folorunsho Ayanda, and Olayinka Jelili Yusuf. 2021. Integrated weed management practices and sustainable food production among farmers in Kwara State, Nigeria. Open Agriculture 6, 1 (Jan.2021), 124–134.

[18]

Deepak Kumar Jain, Aniket Mahanti, Pourya Shamsolmoali, and Ramachandran Manikandan. 2020. Deep neural learning techniques with long short-term memory for gesture recognition. Neural Comput. Appl. 32, 20 (Oct.2020), 16073–16089.

Digital Library

[19]

Xiaojun Jin, Jun Che, and Yong Chen. 2021. Weed identification using deep learning and image processing in vegetable plantation. IEEE Access 9 (2021), 10940–10950.

[20]

Yashaswini Jogi, Preethi N. Rao, Raksha, Sharadhi Shetty, and Shreekari. 2020. CNN based Synchronal recognition of weeds in farm crops. In 2020 4th International Conference on Electronics, Communication and Aerospace Technology (ICECA’20). IEEE.

[21]

Shweta Kulkarni and S. A. Angadi. 2019. IOT based weed detection using image processing and CNN. International Journal of Engineering Applied Sciences and Technology 4, 3 (July2019), 606–609.

[22]

Vi Nguyen Thanh Le, Giang Truong, and Kamal Alameh. 2021. Detecting weeds from crops under complex field environments based on Faster RCNN. In 2020 IEEE 8th International Conference on Communications and Electronics (ICCE’21). IEEE.

[23]

Yann LeCun, Yoshua Bengio, and Geoffrey Hinton. 2015. Deep learning. Nature 521, 7553 (May2015), 436–444.

[24]

Tsung-Yi Lin, Michael Maire, Serge Belongie, James Hays, Pietro Perona, Deva Ramanan, Piotr Dollár, and C. Lawrence Zitnick. 2014. Microsoft COCO: Common objects in context. In Computer Vision (ECCV’14). Springer International Publishing, 740–755.

[25]

Li Liu, Wanli Ouyang, Xiaogang Wang, Paul Fieguth, Jie Chen, Xinwang Liu, and Matti Pietikäinen. 2019. Deep learning for generic object detection: A survey. International Journal of Computer Vision 128, 2 (Oct.2019), 261–318.

Digital Library

[26]

Wei Liu, Dragomir Anguelov, Dumitru Erhan, Christian Szegedy, Scott Reed, Cheng-Yang Fu, and Alexander C. Berg. 2016. SSD: Single shot MultiBox detector. In Computer Vision (ECCV’16). Springer International Publishing, 21–37.

[27]

Francisca López-Granados, Jorge Torres-Sánchez, Angélica Serrano-Pérez, Ana I. de Castro, Fco.-Javier Mesas-Carrascosa, and José-Manuel Peña. 2015. Early season weed mapping in sunflower using UAV technology: Variability of herbicide treatment maps against weed thresholds. Precision Agriculture 17, 2 (Aug.2015), 183–199.

[28]

Philipp Lottes, Jens Behley, Nived Chebrolu, Andres Milioto, and Cyrill Stachniss. 2018. Joint stem detection and crop-weed classification for plant-specific treatment in precision farming. In 2018 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS’18). IEEE.

Digital Library

[29]

Philipp Lottes, Jens Behley, Nived Chebrolu, Andres Milioto, and Cyrill Stachniss. 2019. Robust joint stem detection and crop-weed classification using image sequences for plant-specific treatment in precision farming. Journal of Field Robotics 37, 1 (Aug.2019), 20–34.

[30]

Sinno Jialin Pan and Qiang Yang. 2010. A survey on transfer learning. IEEE Transactions on Knowledge and Data Engineering 22, 10 (Oct.2010), 1345–1359.

Digital Library

[31]

T. Sarvini, Sneha T, Sukanya Gowthami G S, Sushmitha S, and Kumaraswamy R. 2019. Performance comparison of weed detection algorithms. In 2019 International Conference on Communication and Signal Processing (ICCSP’19). IEEE.

[32]

A. J. Irias Tejeda and R. Castro Castro. 2019. Algorithm of weed detection in crops by computational vision. In 2019 International Conference on Electronics, Communications and Computers (CONIELECOMP’19). IEEE.

[33]

Handsen Tibugari, Cornelius Chiduza, and Arnold Bray Mashingaidze. 2020. A survey of problem weeds of sorghum and their management in two sorghum-producing districts of Zimbabwe. Cogent Social Sciences 6, 1 (Jan.2020), 1738840.

[34]

André R. Ulguim, Bruno L. Fruet, Aldo Merotto, and Anelise L. Silva. 2021. Status of weed control in imidazolinone-herbicide resistant rice in Rio Grande do Sul. Advances in Weed Science 39 (2021).

[35]

Jialin Yu, Shaun M. Sharpe, Arnold W. Schumann, and Nathan S. Boyd. 2019. Deep learning for image-based weed detection in turfgrass. European Journal of Agronomy 104 (March2019), 78–84.

[36]

Wenhao Zhang, Mark F. Hansen, Timothy N. Volonakis, Melvyn Smith, Lyndon Smith, Jim Wilson, Graham Ralston, Laurence Broadbent, and Glynn Wright. 2018. Broad-leaf weed detection in pasture. In 2018 IEEE 3rd International Conference on Image, Vision and Computing (ICIVC’18). IEEE.

Cited By

Pai DKamath RBalachandra M(2024)Deep Learning Techniques for Weed Detection in Agricultural Environments: A Comprehensive ReviewIEEE Access10.1109/ACCESS.2024.341845412(113193-113214)Online publication date: 2024
https://doi.org/10.1109/ACCESS.2024.3418454
Kushal SShanmugam BSundaram JThennadil S(2024)Self-healing hybrid intrusion detection system: an ensemble machine learning approachDiscover Artificial Intelligence10.1007/s44163-024-00120-94:1Online publication date: 16-Apr-2024
https://doi.org/10.1007/s44163-024-00120-9
Belcher BBower EBurford BCelis MFahimipour AGuevara IKatija KKhokhar ZManjunath ANelson SOlivetti SOrenstein ESaleh MVaca BValladares SHein SHein A(2023)Demystifying image-based machine learning: a practical guide to automated analysis of field imagery using modern machine learning toolsFrontiers in Marine Science10.3389/fmars.2023.115737010Online publication date: 5-Jun-2023
https://doi.org/10.3389/fmars.2023.1157370
Show More Cited By

Index Terms

Designing and Developing a Weed Detection Model for California Thistle
1. Computing methodologies
  1. Modeling and simulation
    1. Model development and analysis

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Information & Contributors

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Published In

cover image ACM Transactions on Internet Technology

ACM Transactions on Internet Technology Volume 23, Issue 3

August 2023

303 pages

ISSN:1533-5399

EISSN:1557-6051

DOI:10.1145/3615983

Editor:
Ling Liu
Georgia Institute of Technology, USA

Issue’s Table of Contents

Permission to make digital or hard copies of all or part of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for components of this work owned by others than ACM must be honored. Abstracting with credit is permitted. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Request permissions from [email protected].

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Publication History

Published: 21 August 2023

Online AM: 18 July 2022

Accepted: 03 June 2022

Revised: 05 May 2022

Received: 30 April 2021

Published in TOIT Volume 23, Issue 3

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Cited By

Pai DKamath RBalachandra M(2024)Deep Learning Techniques for Weed Detection in Agricultural Environments: A Comprehensive ReviewIEEE Access10.1109/ACCESS.2024.341845412(113193-113214)Online publication date: 2024
https://doi.org/10.1109/ACCESS.2024.3418454
Kushal SShanmugam BSundaram JThennadil S(2024)Self-healing hybrid intrusion detection system: an ensemble machine learning approachDiscover Artificial Intelligence10.1007/s44163-024-00120-94:1Online publication date: 16-Apr-2024
https://doi.org/10.1007/s44163-024-00120-9
Belcher BBower EBurford BCelis MFahimipour AGuevara IKatija KKhokhar ZManjunath ANelson SOlivetti SOrenstein ESaleh MVaca BValladares SHein SHein A(2023)Demystifying image-based machine learning: a practical guide to automated analysis of field imagery using modern machine learning toolsFrontiers in Marine Science10.3389/fmars.2023.115737010Online publication date: 5-Jun-2023
https://doi.org/10.3389/fmars.2023.1157370
Yoshitoshi RSakanoue SWatanabe N(2023) Detecting reed canary grass ( Phalaris arundinacea L.) patches from UAV‐based digital surface model images—A case study in a timothy ( Phleum pretense L.) meadow field Grassland Science10.1111/grs.1241570:1(35-40)Online publication date: 23-Nov-2023
https://doi.org/10.1111/grs.12415
Chegini HNaha RMahanti AGong MPassi K(2023)An Agriprecision Decision Support System for Weed Management in PasturesIEEE Access10.1109/ACCESS.2023.330731111(92660-92675)Online publication date: 2023
https://doi.org/10.1109/ACCESS.2023.3307311
Rivera Guzmán EMañay Chochos EChiliquinga Malliquinga MBaldeón Egas PToasa Guachi R(2022)LoRa Network-Based System for Monitoring the Agricultural Sector in Andean Areas: Case Study EcuadorSensors10.3390/s2218674322:18(6743)Online publication date: 7-Sep-2022
https://doi.org/10.3390/s22186743

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