English

BeetleFlow: An Integrative Deep Learning Pipeline for Beetle Image Processing

Computer Vision and Pattern Recognition 2026-03-30 v2

Abstract

In entomology and ecology research, biologists often need to collect a large number of insects, among which beetles are the most common species. A common practice for biologists to organize beetles is to place them on trays and take a picture of each tray. Given the images of thousands of such trays, it is important to have an automated pipeline to process the large-scale data for further research. Therefore, we develop a 3-stage pipeline to detect all the beetles on each tray, sort and crop the image of each beetle, and do morphological segmentation on the cropped beetles. For detection, we design an iterative process utilizing a transformer-based open-vocabulary object detector and a vision-language model. For segmentation, we manually labeled 670 beetle images and fine-tuned two variants of a transformer-based segmentation model to achieve fine-grained segmentation of beetles with relatively high accuracy. The pipeline integrates multiple deep learning methods and is specialized for beetle image processing, which can greatly improve the efficiency to process large-scale beetle data and accelerate biological research.

Keywords

Cite

@article{arxiv.2511.00255,
  title  = {BeetleFlow: An Integrative Deep Learning Pipeline for Beetle Image Processing},
  author = {Fangxun Liu and S M Rayeed and Samuel Stevens and Alyson East and Cheng Hsuan Chiang and Colin Lee and Daniel Yi and Junke Yang and Tejas Naik and Ziyi Wang and Connor Kilrain and Elijah H Buckwalter and Jiacheng Hou and Saul Ibaven Bueno and Shuheng Wang and Xinyue Ma and Yifan Liu and Zhiyuan Tao and Ziheng Zhang and Eric Sokol and Michael Belitz and Sydne Record and Charles V. Stewart and Wei-Lun Chao},
  journal= {arXiv preprint arXiv:2511.00255},
  year   = {2026}
}

Comments

4 pages, NeurIPS 2025 Workshop Imageomics

R2 v1 2026-07-01T07:16:32.317Z