Autonomous Navigation System of Greenhouse Mobile Robot Based on 3D Lidar and 2D Lidar SLAM

Jiang, Saike; Wang, Shilin; Yi, Zhongyi; Zhang, Meina; Lv, Xiaolan

doi:10.3389/fpls.2022.815218

Cited by 27 publications

(23 citation statements)

References 33 publications

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“…However, the information provided by OSM may be insufficient for complex planning tasks, and future work needs to incorporate additional semantic knowledge, such as traffic signs and building shapes, to enhance the practicality of the navigation framework. Jiang et al [10] proposed a precise autonomous navigation system for greenhouse robots combining 3D and 2D LiDAR with SLAM to streamline real-time localization and environmental mapping. The integration of various sensors facilitates a comprehensive navigation framework, thus utilizing Dijkstra for global path planning and DWA for agile local maneuvering.…”

Section: Lidarmentioning

confidence: 99%

“…The advent of robots represents a significant milestone in technological evolution. Robots are now increasingly prevalent across a broad spectrum of applications, from industrial processes [1][2][3][4][5] and medical surgeries [6][7][8][9] to various real-world scenarios [10][11][12][13][14]. The advancement of robotics technology is fundamentally propelled by the development and integration of sensor technologies, which equip robots with essential tools for effective environmental interaction.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Robotics Perception and Control: Key Technologies and Applications

Luo,

Zhou,

Zeng

et al. 2024

Micromachines

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The integration of advanced sensor technologies has significantly propelled the dynamic development of robotics, thus inaugurating a new era in automation and artificial intelligence. Given the rapid advancements in robotics technology, its core area—robot control technology—has attracted increasing attention. Notably, sensors and sensor fusion technologies, which are considered essential for enhancing robot control technologies, have been widely and successfully applied in the field of robotics. Therefore, the integration of sensors and sensor fusion techniques with robot control technologies, which enables adaptation to various tasks in new situations, is emerging as a promising approach. This review seeks to delineate how sensors and sensor fusion technologies are combined with robot control technologies. It presents nine types of sensors used in robot control, discusses representative control methods, and summarizes their applications across various domains. Finally, this survey discusses existing challenges and potential future directions.

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Section: Lidarmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Robotics Perception and Control: Key Technologies and Applications

Luo,

Zhou,

Zeng

et al. 2024

Micromachines

View full text Add to dashboard Cite

show abstract

“…are common 2D laser SLAM algorithms currently used for service robots for environmental map building. Considering that this research uses a Jetson nano with 2G video memory as the main controller, its arithmetic power level is limited, and by comparing the simulated environment, real environment, and central processing unit (CPU) utilization (Santos et al 2013;Jiang et al 2022;Hess et al 2016), this study chooses Cartographer SLAM algorithm. Cartographer, a graph optimization-based algorithm capable of generating resolution 5 r  cm raster maps, is a SLAM algorithm introduced by Google.…”

Section: Environment Map Buildingmentioning

confidence: 99%

Autonomous navigation system for exhibition hall service robots via laser SLAM

Cai

Zhu

et al. 2022

Preprint

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As an important tool for guiding and introducing visitors to the exhibition hall, the service robot needs to confront the complex environment existed and the constantly moving visitors. It is needed to have the ability to enable accurate positioning and navigation as well as dynamic obstacle avoidance. In recent years, simultaneous localization and mapping technology has been widely used to address localization and navigation issues in unknown indoor environments. Combining the service robot’s inertial measurement unit with other sensors to map the exhibition hall environment by the Cartographer SLAM algorithm, environmental information is collected by two-dimensional laser lidar. The path planning and dynamic obstacle are also achieved by the Cartographer simultaneous localization and mapping algorithm. The \({A^*}\) algorithm is selected for global path planning and the dynamic window approach algorithm for local path planning. The environment map construction, path planning and dynamic obstacle avoidance functions are verified by simulation and experiments in real environment. The average position deviation and standard deviation of the robot are less than 7cm and 3cm, respectively, when the robot is set to move at 0.5m/s. The average heading deviation is less than \({9^ \circ }\)and standard deviation is less than \({3^ \circ }\). The robot's positioning and navigation can well meet the working requirements of the pavilion service robot.

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“…However, 3D LiDAR point cloud data required extensive processing of computational costs and computational requirements [ 24 ]. Therefore, Saike et al processed 3D LiDAR data in 2D to achieve autonomous navigation operations in a greenhouse [ 25 ].…”

Section: Introductionmentioning

confidence: 99%

Navigation of an Autonomous Spraying Robot for Orchard Operations Using LiDAR for Tree Trunk Detection

Jiang

Ahamed

2023

Sensors

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Traditional Japanese orchards control the growth height of fruit trees for the convenience of farmers, which is unfavorable to the operation of medium- and large-sized machinery. A compact, safe, and stable spraying system could offer a solution for orchard automation. Due to the complex orchard environment, the dense tree canopy not only obstructs the GNSS signal but also has effects due to low light, which may impact the recognition of objects by ordinary RGB cameras. To overcome these disadvantages, this study selected LiDAR as a single sensor to achieve a prototype robot navigation system. In this study, density-based spatial clustering of applications with noise (DBSCAN) and K-means and random sample consensus (RANSAC) machine learning algorithms were used to plan the robot navigation path in a facilitated artificial-tree-based orchard system. Pure pursuit tracking and an incremental proportional–integral–derivative (PID) strategy were used to calculate the vehicle steering angle. In field tests on a concrete road, grass field, and a facilitated artificial-tree-based orchard, as indicated by the test data results for several formations of left turns and right turns separately, the position root mean square error (RMSE) of this vehicle was as follows: on the concrete road, the right turn was 12.0 cm and the left turn was 11.6 cm, on grass, the right turn was 12.6 cm and the left turn was 15.5 cm, and in the facilitated artificial-tree-based orchard, the right turn was 13.8 cm and the left turn was 11.4 cm. The vehicle was able to calculate the path in real time based on the position of the objects, operate safely, and complete the task of pesticide spraying.

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Autonomous Navigation System of Greenhouse Mobile Robot Based on 3D Lidar and 2D Lidar SLAM

Cited by 27 publications

References 33 publications

Robotics Perception and Control: Key Technologies and Applications

Robotics Perception and Control: Key Technologies and Applications

Autonomous navigation system for exhibition hall service robots via laser SLAM

Navigation of an Autonomous Spraying Robot for Orchard Operations Using LiDAR for Tree Trunk Detection

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