핵심 개념
A real-time algorithmic framework to perform on-the-go detection of trees and key geometric characteristics (width and height) with wheeled mobile robots in the field, using a fusion of 2D domain-specific data (NDVI) and 3D LiDAR point clouds.
초록
The paper presents an algorithmic framework to perform real-time and on-the-go detection of trees and key geometric characteristics (width and height) with wheeled mobile robots in fruit tree groves. The method is based on the fusion of 2D domain-specific data (normalized difference vegetation index (NDVI) acquired via a red-green-near-infrared (RGN) camera) and 3D LiDAR point clouds, via a customized tree landmark association and parameter estimation algorithm.
The key highlights of the approach are:
- A multi-modal and entropy-based landmark correspondences approach, integrated into an underlying Kalman filter system, to recognize the surrounding trees and jointly estimate their spatial and vegetation-based characteristics.
- Real-time fusion of LiDAR and camera data to obtain accurate tree geometric traits and geo-reference the information on a global map.
- Robot-assisted proximal RGN sensing from the ground enabling integration of domain-specific vegetation data for active landmark detection outdoors.
The proposed system is evaluated extensively in both realistic simulated and real-world field survey experiments. The results demonstrate the efficacy of the algorithm in accurately detecting trees and estimating their width and height, even in challenging field conditions with high wind and varying ambient light.
통계
The robot is equipped with a 3D LiDAR sensor (Velodyne VLP-16) and an RGN camera (MAPIR Survey3N).
The 3D LiDAR sensor provides up to 300,000 points per second at a publication rate of 10Hz.
The RGN camera provides 30 fps of 720p RGN feed.
인용구
"Real-time tree crop monitoring is important in agriculture because it allows growers to make informed decisions about management practices, address potential issues promptly, and ultimately optimize crop yields and profitability."
"Unmanned Aerial Vehicles (UAVs), in particular, have been deployed in farms to acquire information from above and map field characteristics, yet the accuracy of these approaches is highly connected to the resolution of the used sensors and flight altitude."
"To this end, several works have proposed using trained detectors for trunk (or other tree parts) to improve robustness, however, the performance of these approaches highly depends on additional computational resources, precise training, and the generalizability of the method to be robust in different environments and physical conditions of the trees."