Waste object detection with subtype-aware fusion and efficient re-ranking (SAFE-R) for hazardous waste identification and recycling in waste streams
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BRAC University
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Abstract
Waste management is essential for a multitude of reasons, including protecting the
environment and the people who are employed for this job, especially in developing
countries like Bangladesh where primitive practices of waste-collection and landfilling
still persist. Improper classification and disposal of waste can lead to many issues
like air and water pollution. This study aims to address the challenges of waste management
by proposing an automated system that classifies waste into seven different
categories like sharpened objects, plastic, metal, glass, etc., using computer vision.
To that end, multiple modifications of the popular YOLOv8 model were tested to
ascertain the ideal balance between accuracy and latency for real-world implementation.
Therefore, after filtering the set of 2,444 images (24,715 annotated objects) and
trying various architectural variations, we discovered that the YOLOv8m detector
has the balance of being the fastest and most accurate (mAP50 = 0.591, mAP50-95
= 0.332, around 9 ms per image).Furthermore, our study aims to identify hazardous
objects like syringes amongst medical waste and nails amongst sharpened objects using
query-aware reranking. When identifying dangerous subclasses our pipeline, too,
showed significant improvement compared to an open-vocabulary baseline (OWLViT).
To illustrate, with an IoU of 0.5, syringe detection had an AP50 of 0.619
versus 0.064 with OWL-ViT and nails had 0.538 versus 0.214. These findings indicate
that we can successfully detect the presence of dangerous objects such as syringes
in real time, which makes waste collection not only quicker and more efficient
but also significantly safer to the people working on it. Implementation of proper
waste classification using our proposed pipeline can give the waste-collectors safety
and promote practices like composting and recycling. In this thesis, we propose to
introduce an automated system that will help classify and separate garbage into superclasses
and further distinguish subclasses by the combination of YOLOv8m and
CLIP algorithms which can aid garbage collectors in their task and foster better
recycling and landfill practices.
Description
Cataloged from PDF version of thesis.
Includes bibliographical references (pages 42-45).
This thesis is submitted in partial fulfillment of the requirements for the degree of Bachelor of Science in Computer Science and Engineering, 2025.
Includes bibliographical references (pages 42-45).
This thesis is submitted in partial fulfillment of the requirements for the degree of Bachelor of Science in Computer Science and Engineering, 2025.
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Thesis