Your search keyword '"Flippo, Daniel"' showing total 2 results

1. Aphid cluster recognition and detection in the wild using deep learning models.

Author

Zhang, Tianxiao, Li, Kaidong, Chen, Xiangyu, Zhong, Cuncong, Luo, Bo, Grijalva, Ivan, McCornack, Brian, Flippo, Daniel, Sharda, Ajay, and Wang, Guanghui

Subjects

MACHINE learning, DEEP learning, APHIDS, PEST control, SORGHUM, AGRICULTURAL productivity

Abstract

Aphid infestation poses a significant threat to crop production, rural communities, and global food security. While chemical pest control is crucial for maximizing yields, applying chemicals across entire fields is both environmentally unsustainable and costly. Hence, precise localization and management of aphids are essential for targeted pesticide application. The paper primarily focuses on using deep learning models for detecting aphid clusters. We propose a novel approach for estimating infection levels by detecting aphid clusters. To facilitate this research, we have captured a large-scale dataset from sorghum fields, manually selected 5447 images containing aphids, and annotated each individual aphid cluster within these images. To facilitate the use of machine learning models, we further process the images by cropping them into patches, resulting in a labeled dataset comprising 151,380 image patches. Then, we implemented and compared the performance of four state-of-the-art object detection models (VFNet, GFLV2, PAA, and ATSS) on the aphid dataset. Extensive experimental results show that all models yield stable similar performance in terms of average precision and recall. We then propose to merge close neighboring clusters and remove tiny clusters caused by cropping, and the performance is further boosted by around 17%. The study demonstrates the feasibility of automatically detecting and managing insects using machine learning models. The labeled dataset will be made openly available to the research community. [ABSTRACT FROM AUTHOR]

Published

2023

2. Turning Efficiency Prediction for Skid Steer Robots Using Single Wheel Testing.

Author

Flippo, Daniel, Heller, Richard, and Miller, David P.

Abstract

To date, most field robots use wheels as their means of locomotion (especially true of planetary exploration robots). In many cases these robots are required to travel significant distances, with limited power, and over rough terrain. All of which make wheels a major component contributing to their performance. It is through experimentation and iteration that effective wheel design, for a given rover in a given mission, can be achieved. To do this, the SWEET (Suspension andWheel Evaluation and Experimentation Testbed) simulates the rover environment using a single wheel methodology. The wheels currently being tested belong to the SR2 skid steer Mars rover designed and built at the University of Oklahoma. Simulating a skid steer turn with SWEET is achieved by varying the spinning rate of the platform under the wheel, which is rotating at a certain rate, and recording the forces incurred. These forces interact in such a way that the relevantmobility properties for a rover can be predicted. This experimentation method allows for cheap and timely iterative single wheel design. [ABSTRACT FROM AUTHOR]

Published

2010