Joint prototype and coefficient prediction for 3D instance segmentation

Remco Donovan Royen; Leon Denis; Adrian Munteanu

doi:10.1049/ell2.13137

Joint prototype and coefficient prediction for 3D instance segmentation

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2 Citaten (Scopus)

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3D instance segmentation is crucial for applications demanding comprehensive 3D scene understanding. Here, a novel method is introduced that simultaneously learns coefficients and prototypes. Employing an overcomplete sampling strategy, the method produces an overcomplete set of instance predictions, from which the optimal ones are selected through a Non-Maximum Suppression (NMS) algorithm during inference. The obtained prototypes are visualizable and interpretable. The method demonstrates superior performance on S3DIS-blocks, consistently outperforming existing methods in mRec and mPrec. Moreover, it operates 32.9% faster than the state-of-the-art. Notably, with only 0.8% of the total inference time, the method exhibits an over 20-fold reduction in the variance of inference time compared to existing methods. These attributes render the method well-suited for practical applications requiring both rapid inference and high reliability.

Originele taal-2	English
Artikelnummer	e13137
Aantal pagina's	3
Tijdschrift	Electronics Letters
Volume	60
Nummer van het tijdschrift	5
DOI's	https://doi.org/10.1049/ell2.13137
Status	Published - mrt. 2024

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Funding infomation:
This work is funded by Fonds Wetenschappelijk Onderzoek (FWO) - 1S89420N and Innoviris within the research project SPECTRE.

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10.1049/ell2.13137Licentie: CC BY-ND

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title = "Joint prototype and coefficient prediction for 3D instance segmentation",

abstract = "3D instance segmentation is crucial for applications demanding comprehensive 3D scene understanding. Here, a novel method is introduced that simultaneously learns coefficients and prototypes. Employing an overcomplete sampling strategy, the method produces an overcomplete set of instance predictions, from which the optimal ones are selected through a Non-Maximum Suppression (NMS) algorithm during inference. The obtained prototypes are visualizable and interpretable. The method demonstrates superior performance on S3DIS-blocks, consistently outperforming existing methods in mRec and mPrec. Moreover, it operates 32.9\% faster than the state-of-the-art. Notably, with only 0.8\% of the total inference time, the method exhibits an over 20-fold reduction in the variance of inference time compared to existing methods. These attributes render the method well-suited for practical applications requiring both rapid inference and high reliability.",

author = "Royen, \{Remco Donovan\} and Leon Denis and Adrian Munteanu",

note = "Funding infomation: This work is funded by Fonds Wetenschappelijk Onderzoek (FWO) - 1S89420N and Innoviris within the research project SPECTRE.",

year = "2024",

month = mar,

doi = "10.1049/ell2.13137",

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journal = "Electronics Letters",

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AU - Royen, Remco Donovan

AU - Denis, Leon

AU - Munteanu, Adrian

N1 - Funding infomation: This work is funded by Fonds Wetenschappelijk Onderzoek (FWO) - 1S89420N and Innoviris within the research project SPECTRE.

PY - 2024/3

Y1 - 2024/3

N2 - 3D instance segmentation is crucial for applications demanding comprehensive 3D scene understanding. Here, a novel method is introduced that simultaneously learns coefficients and prototypes. Employing an overcomplete sampling strategy, the method produces an overcomplete set of instance predictions, from which the optimal ones are selected through a Non-Maximum Suppression (NMS) algorithm during inference. The obtained prototypes are visualizable and interpretable. The method demonstrates superior performance on S3DIS-blocks, consistently outperforming existing methods in mRec and mPrec. Moreover, it operates 32.9% faster than the state-of-the-art. Notably, with only 0.8% of the total inference time, the method exhibits an over 20-fold reduction in the variance of inference time compared to existing methods. These attributes render the method well-suited for practical applications requiring both rapid inference and high reliability.

AB - 3D instance segmentation is crucial for applications demanding comprehensive 3D scene understanding. Here, a novel method is introduced that simultaneously learns coefficients and prototypes. Employing an overcomplete sampling strategy, the method produces an overcomplete set of instance predictions, from which the optimal ones are selected through a Non-Maximum Suppression (NMS) algorithm during inference. The obtained prototypes are visualizable and interpretable. The method demonstrates superior performance on S3DIS-blocks, consistently outperforming existing methods in mRec and mPrec. Moreover, it operates 32.9% faster than the state-of-the-art. Notably, with only 0.8% of the total inference time, the method exhibits an over 20-fold reduction in the variance of inference time compared to existing methods. These attributes render the method well-suited for practical applications requiring both rapid inference and high reliability.

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VL - 60

JO - Electronics Letters

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ER -

Joint prototype and coefficient prediction for 3D instance segmentation

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