arxiv_cv 98% Match Research Paper Agricultural Scientists,Robotics Engineers,Computer Vision Researchers,Agronomists 2 weeks ago

Iterative Motion Compensation for Canonical 3D Reconstruction from UAV Plant Images Captured in Windy Conditions

computer-vision › 3d-vision

📄 Abstract

Abstract: 3D phenotyping of plants plays a crucial role for understanding plant growth, yield prediction, and disease control. We present a pipeline capable of generating high-quality 3D reconstructions of individual agricultural plants. To acquire data, a small commercially available UAV captures images of a selected plant. Apart from placing ArUco markers, the entire image acquisition process is fully autonomous, controlled by a self-developed Android application running on the drone's controller. The reconstruction task is particularly challenging due to environmental wind and downwash of the UAV. Our proposed pipeline supports the integration of arbitrary state-of-the-art 3D reconstruction methods. To mitigate errors caused by leaf motion during image capture, we use an iterative method that gradually adjusts the input images through deformation. Motion is estimated using optical flow between the original input images and intermediate 3D reconstructions rendered from the corresponding viewpoints. This alignment gradually reduces scene motion, resulting in a canonical representation. After a few iterations, our pipeline improves the reconstruction of state-of-the-art methods and enables the extraction of high-resolution 3D meshes. We will publicly release the source code of our reconstruction pipeline. Additionally, we provide a dataset consisting of multiple plants from various crops, captured across different points in time.

Authors (4)

Andre Rochow

Jonas Marcic

Svetlana Seliunina

Sven Behnke

Submitted

October 17, 2025

arXiv Category

cs.CV

arXiv PDF

Key Contributions

This paper presents a pipeline for high-quality 3D plant reconstruction using UAV imagery, featuring an iterative motion compensation method to address challenges from wind and UAV downwash. By estimating motion via optical flow between images and intermediate reconstructions, it corrects for leaf movement, enabling more accurate 3D models.

Business Value

Enables precise, automated 3D plant modeling for improved crop monitoring, yield prediction, and disease detection, leading to more efficient agricultural practices.

Paper Metadata

Innovation Type

Algorithmic Improvement

Deployment Feasibility

High. Leverages commercially available UAVs and established 3D reconstruction techniques, with the novel component being the motion compensation algorithm.

Limitations Addressed

Errors caused by leaf motion due to wind and UAV downwash,Challenges in 3D reconstruction from dynamic scenes,Need for autonomous data acquisition

Performance Gains

Generates high-quality 3D reconstructions of individual agricultural plants.

Technical Tags

3D reconstructionUAVplant phenotypingmotion compensationoptical flowiterative refinementArUco markersautonomous image acquisition

Research Topics

3D Computer VisionRoboticsAgricultural TechnologyRemote SensingImage Processing

Methods & Architectures

Iterative motion compensationImage deformationOptical flow estimation3D reconstruction pipelineAutonomous UAV image acquisition

Applications & Tasks

Agriculture Botany Environmental Science 3D ReconstructionMotion EstimationData Acquisition Canonical 3D reconstruction of plantsMitigating motion artifacts in UAV imagery

Related Fields

Precision AgricultureRoboticsComputer VisionAgronomy

Keywords

3D reconstructionUAVplant phenotypingmotion compensationoptical flowiterativeagricultureautonomouswindy conditionsArUco markers

Academic Context

#3D Computer Vision#Robotics#Agricultural Technology#Remote Sensing#Image Processing

Commercial Potential

Potential Products

Automated plant phenotyping systems3D crop modeling softwarePrecision agriculture platforms

Target Industries

AgricultureBiotechnologyEnvironmental MonitoringResearch Institutions

Use Case Examples

Tracking plant growth and development in 3DIdentifying disease symptoms on plant structuresEstimating crop yield based on plant volume

Competitive Edge

Offers a specialized solution for 3D plant reconstruction under challenging environmental conditions (wind), improving accuracy over standard methods.

Market Opportunity

Growing market for precision agriculture technologies and automated crop management.

Revenue Models

Software licensingservice contracts for data acquisition and analysis.

Resource Requirements

Compute Needs

Moderate to High, for processing image sequences and performing iterative 3D reconstruction.

Data Requirements

Image sequences of plants captured by UAVs, ideally with ground truth for validation.

Deployment Constraints

Requires stable UAV flight, accurate camera calibration, and sufficient image overlap. Environmental conditions (wind) can still pose challenges.

Scalability

Scalability depends on the efficiency of the iterative reconstruction process and the ability to handle large datasets.

Regulatory Considerations

Drone operation regulationsdata usage policies in agriculture.

Production Readiness

Maturity Level

Research

Time to Market

2-4 years for integration into commercial agricultural monitoring systems.

Patent Potential

Moderate, for the iterative motion compensation technique and the overall pipeline.

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