Abstract
The rapid development of new technologies and the changing landscape of the online world (e.g., Internet of Things (IoT), Internet of All, cloud-based solutions) provide a unique opportunity for developing automated and robotic systems for urban farming, agriculture, and forestry. Technological advances in machine vision, global positioning systems, laser technologies, actuators, and mechatronics have enabled the development and implementation of robotic systems and intelligent technologies for precision agriculture. Herein, we present and review robotic applications on plant pathology and management, and emerging agricultural technologies for intra-urban agriculture. Greenhouse advanced management systems and technologies have been greatly developed in the last years, integrating IoT and WSN (Wireless Sensor Network). Machine learning, machine vision, and AI (Artificial Intelligence) have been utilized and applied in agriculture for automated and robotic farming. Intelligence technologies, using machine vision/learning, have been developed not only for planting, irrigation, weeding (to some extent), pruning, and harvesting, but also for plant disease detection and identification. However, plant disease detection still represents an intriguing challenge, for both abiotic and biotic stress. Many recognition methods and technologies for identifying plant disease symptoms have been successfully developed; still, the majority of them require a controlled environment for data acquisition to avoid false positives. Machine learning methods (e.g., deep and transfer learning) present promising results for improving image processing and plant symptom identification. Nevertheless, diagnostic specificity is a challenge for microorganism control and should drive the development of mechatronics and robotic solutions for disease management.
Highlights
Research in agricultural robots has been growing in the last years, thanks to potential applications and industry efforts in robot development [1]
Hardware and software of platforms (UAVs, UGVs, or sensors installed on vehicles/structures) and manipulators, even if originally intended for agronomic tasks such as monitoring or harvesting, are developing fast
It is desirable that robot development will be strictly associated with the development of diagnostic systems, because many of the most advanced techniques of image analysis for plant pathogen recognitions are often developed and tested independently from robotic application/integration
Summary
Research in agricultural robots has been growing in the last years, thanks to potential applications and industry efforts in robot development [1]. Their role was investigated for many agricultural tasks, mainly focused in increasing automation of conventional agricultural machines and covering processes such as ground preparation, seeding, fertilization, and harvesting. Robotic plant protection has been investigated, but may represent the most complex challenge for researchers and developers because questions relative to pathogen diagnosis have to be considered along with common robot-related issues. Research in automatic recognition of diseases has been rapidly growing, with potential applications for developing robots able to recognize single plants, locate and identify diseases, and start routines for disease management. This paper aims to provide details of that new generation of robots that could support plant pathologists
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