Abstract
Autonomous Mobile Robots (AMRs) are emerging as a potential solution for transitioning agriculture towards sustainability by optimizing resource utilization in applications such as water and fertilizer use. However, deploying AMRs requires a map of the environment for effective operation.
This study investigates UAVs equipped with RGB cameras to derive such a map that can be used by ground-level AMRs in vineyards. Our approach includes capturing detailed and frequent aerial imagery to reflect the vineyard's condition, identifying obstacles and separating vine growth from other vegetation through terrain model-based segmentation, and refining segmentation through vine-row reconstruction to enhance the accuracy and utility of the map for navigation. We compare our approach on three flights on a local vineyard with manually annotated ground truth data and show that our approach is a viable solution to derive an a priori map for autonomous ground vehicles in vineyards.
This study investigates UAVs equipped with RGB cameras to derive such a map that can be used by ground-level AMRs in vineyards. Our approach includes capturing detailed and frequent aerial imagery to reflect the vineyard's condition, identifying obstacles and separating vine growth from other vegetation through terrain model-based segmentation, and refining segmentation through vine-row reconstruction to enhance the accuracy and utility of the map for navigation. We compare our approach on three flights on a local vineyard with manually annotated ground truth data and show that our approach is a viable solution to derive an a priori map for autonomous ground vehicles in vineyards.
Original language | English |
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Title of host publication | Austrian Symposium on AI, Robotics, and Vision |
Volume | 1 |
Publication status | Accepted/In press - 2024 |
Research Field
- Assistive and Autonomous Systems
Keywords
- mobile robotics
- mapping
- Autonomous vehicles