Design and Development of a Neural Network-Based End-Effector for Disease Detection in Plants with 7-DOF Robot Integration

Harol Toro; Hector Moncada; Kristhian Dierik Gonzales; Cristian Moreno; Claudia L. Garzón-Castro; Jose Luis Ordoñez-Avila

doi:10.3390/pr13123934

Design and Development of a Neural Network-Based End-Effector for Disease Detection in Plants with 7-DOF Robot Integration

Harol Toro (First Author)
, Hector Moncada (Second Author)
, Kristhian Dierik Gonzales (Third Author)
, Cristian Moreno (Fourth Autor)
, Claudia L. Garzón-Castro (Correspondent Author)
, Jose Luis Ordoñez-Avila (Correspondent Author)

Universidad Tecnológica Centroamericana

Research output: Contribution to journal › Article › peer-review

Abstract

This study presents the design and development of an intelligent end-effector integrated
into a custom 7-degree-of-freedom (DOF) robotic arm for monitoring the health status of
tomato plants during their growth stages. The robotic system combines five rotational and
two prismatic joints, enabling both horizontal reach and vertical adaptability to inspect
plants of varying heights without repositioning the robot’s base. The integrated vision
module employs a YOLOv5 neural network trained with 7864 images of tomato leaves,
including both healthy and diseased samples. Image preprocessing included normalization
and data augmentation to enhance robustness under natural lighting conditions. The
optimized model achieved a detection accuracy of 90.2% and a mean average precision
(mAP) of 92.3%, demonstrating high reliability in real-time disease classification. The
end-effector, fabricated using additive manufacturing, incorporates a Raspberry Pi 4 for
onboard processing, allowing autonomous operation in agricultural environments. The
experimental results validate the feasibility of combining a custom 7-DOF robotic structure
with a deep learning-based detector for continuous plant monitoring. This research
contributes to the field of agricultural robotics by providing a flexible and precise platform
capable of early disease detection in dynamic cultivation conditions, promoting sustainable
and data-driven crop management.

Original language	English
Article number	3934
Pages (from-to)	1-26
Number of pages	26
Journal	Processes
Volume	13
Issue number	12
DOIs	https://doi.org/10.3390/pr13123934
State	Published - 5 Dec 2025

Strategic Focuses

Sociedad Digital y Competitividad (SocietalIA)

Article Classification

Full research article

Indexación Internacional (Artículo)

ISI Y SCOPUS

Scopus-Q Quartil

Q2

ISI- Q Quartil

Q3

Categoría Publindex

A2

Access to Document

10.3390/pr13123934

https://www.mdpi.com/2227-9717/13/12/3934

Robótica versátil: tecnología aplicada para el bienestar comunitario
Garzon Castro, C. L. (PI), Vitta Charris, M. A. (undergradstudent), Lemus Rey, J. D. (undergradstudent), Rojas Reyes, V. (undergradstudent) & Bello Portillo, D. S. (undergradstudent)
13/11/25 → 13/11/28
Project: Proyectos de Unidad Académica

Cite this

@article{3d70a1d8a20241fe88fe65c6497f3049,

title = "Design and Development of a Neural Network-Based End-Effector for Disease Detection in Plants with 7-DOF Robot Integration",

abstract = "This study presents the design and development of an intelligent end-effector integrated into a custom 7-degree-of-freedom (DOF) robotic arm for monitoring the health status of tomato plants during their growth stages. The robotic system combines five rotational and two prismatic joints, enabling both horizontal reach and vertical adaptability to inspect plants of varying heights without repositioning the robot{\textquoteright}s base. The integrated vision module employs a YOLOv5 neural network trained with 7864 images of tomato leaves, including both healthy and diseased samples. Image preprocessing included normalization and data augmentation to enhance robustness under natural lighting conditions. The optimized model achieved a detection accuracy of 90.2\% and a mean average precision (mAP) of 92.3\%, demonstrating high reliability in real-time disease classification. The end-effector, fabricated using additive manufacturing, incorporates a Raspberry Pi 4 for onboard processing, allowing autonomous operation in agricultural environments. The experimental results validate the feasibility of combining a custom 7-DOF robotic structure with a deep learning-based detector for continuous plant monitoring. This research contributes to the field of agricultural robotics by providing a flexible and precise platform capable of early disease detection in dynamic cultivation conditions, promoting sustainable and data-driven crop management.",

author = "Harol Toro and Hector Moncada and \{Dierik Gonzales\}, Kristhian and Cristian Moreno and Garz{\'o}n-Castro, \{Claudia L.\} and Ordo{\~n}ez-Avila, \{Jose Luis\}",

year = "2025",

month = dec,

day = "5",

doi = "10.3390/pr13123934",

language = "Ingl{\'e}s",

volume = "13",

pages = "1--26",

journal = "Processes",

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publisher = "Multidisciplinary Digital Publishing Institute (MDPI)",

number = "12",

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TY - JOUR

T1 - Design and Development of a Neural Network-Based End-Effector for Disease Detection in Plants with 7-DOF Robot Integration

AU - Toro, Harol

AU - Moncada, Hector

AU - Dierik Gonzales, Kristhian

AU - Garzón-Castro, Claudia L.

AU - Ordoñez-Avila, Jose Luis

A2 - Moreno, Cristian

PY - 2025/12/5

Y1 - 2025/12/5

N2 - This study presents the design and development of an intelligent end-effector integrated into a custom 7-degree-of-freedom (DOF) robotic arm for monitoring the health status of tomato plants during their growth stages. The robotic system combines five rotational and two prismatic joints, enabling both horizontal reach and vertical adaptability to inspect plants of varying heights without repositioning the robot’s base. The integrated vision module employs a YOLOv5 neural network trained with 7864 images of tomato leaves, including both healthy and diseased samples. Image preprocessing included normalization and data augmentation to enhance robustness under natural lighting conditions. The optimized model achieved a detection accuracy of 90.2% and a mean average precision (mAP) of 92.3%, demonstrating high reliability in real-time disease classification. The end-effector, fabricated using additive manufacturing, incorporates a Raspberry Pi 4 for onboard processing, allowing autonomous operation in agricultural environments. The experimental results validate the feasibility of combining a custom 7-DOF robotic structure with a deep learning-based detector for continuous plant monitoring. This research contributes to the field of agricultural robotics by providing a flexible and precise platform capable of early disease detection in dynamic cultivation conditions, promoting sustainable and data-driven crop management.

AB - This study presents the design and development of an intelligent end-effector integrated into a custom 7-degree-of-freedom (DOF) robotic arm for monitoring the health status of tomato plants during their growth stages. The robotic system combines five rotational and two prismatic joints, enabling both horizontal reach and vertical adaptability to inspect plants of varying heights without repositioning the robot’s base. The integrated vision module employs a YOLOv5 neural network trained with 7864 images of tomato leaves, including both healthy and diseased samples. Image preprocessing included normalization and data augmentation to enhance robustness under natural lighting conditions. The optimized model achieved a detection accuracy of 90.2% and a mean average precision (mAP) of 92.3%, demonstrating high reliability in real-time disease classification. The end-effector, fabricated using additive manufacturing, incorporates a Raspberry Pi 4 for onboard processing, allowing autonomous operation in agricultural environments. The experimental results validate the feasibility of combining a custom 7-DOF robotic structure with a deep learning-based detector for continuous plant monitoring. This research contributes to the field of agricultural robotics by providing a flexible and precise platform capable of early disease detection in dynamic cultivation conditions, promoting sustainable and data-driven crop management.

U2 - 10.3390/pr13123934

DO - 10.3390/pr13123934

M3 - Artículo

SN - 2227-9717

VL - 13

SP - 1

EP - 26

JO - Processes

JF - Processes

IS - 12

M1 - 3934

ER -

Design and Development of a Neural Network-Based End-Effector for Disease Detection in Plants with 7-DOF Robot Integration

Abstract

Strategic Focuses

Article Classification

Indexación Internacional (Artículo)

Scopus-Q Quartil

ISI- Q Quartil

Categoría Publindex

Access to Document

Projects

Robótica versátil: tecnología aplicada para el bienestar comunitario

Cite this