Evaluating Video-to-3D Foundation Models for Wire Harness Assembly Verification
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Författare
Typ
Examensarbete för masterexamen
Master's Thesis
Master's Thesis
Modellbyggare
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Sammanfattning
Automotive wire harness assembly is a heavily manual process, and a critical part of
this workflow is Quality Control (QC). Automating this visual verification is challenging:
traditional 2D computer vision struggles with spatial occlusions, and lacks
essential geometric depth, whereas 3D data can capture a more comprehensive representation
of the object. However, existing 3D machine learning methods depend
on rigid scanning hardware and extensive training data. To bypass these technical
bottlenecks and reduce the industry’s critical reliance on human labor, this thesis
evaluates emerging feed-forward "Video-to-3D" foundation models for automated assembly
verification.
Using a custom dataset of smartphone videos, four state-of-the-art (SOTA) architectures
(Pi3-X, VGGT, Depth Anything V3, and Map Anything) were evaluated for
geometric fidelity and automated component classification. Results identify Depth
Anything V3 demonstrated superior global spatial coherence and strong baseline
counting capabilities, though high false-positive rates across the models indicate
further refinement is needed. Pi3-x also proved to be a reliable architecture with
competitive classification performance. Although current models lack the geometric
precision for highly granular verification tasks, often exhibiting wire duplication
or loss of detailed structural definition, they show high promise on broader classification
tasks, such as distinguishing and counting clips versus terminal housings.
While fully autonomous inspection requires further refinement to mitigate high falsepositive
rates, this flexible 3D approach establishes a step toward modernizing visual
quality control of wire harnesses
Beskrivning
Ämne/nyckelord
Wire Harness Assembly, Assembly Verification, Video-to-3D, 3D Reconstruction, Foundation Models, Computer Vision, Quality Control
