TY - JOUR
T1 - PFPS
T2 - Polymerized Feature Panoptic Segmentation Based on Fully Convolutional Networks
AU - Ji, Shucheng
AU - Yuan, Xiaochen
AU - Bao, Junqi
AU - Liu, Tong
AU - Lian, Yang
AU - Huang, Guoheng
AU - Zhong, Guo
N1 - Publisher Copyright:
© 2017 IEEE.
PY - 2024
Y1 - 2024
N2 - Panoptic segmentation requires the prediction of a pixel-level mask with a category label in an image. In recent years, panoptic segmentation has been gaining more attention since it can help us understand objects and the environment in many fields, such as medical images, remote sensing images, and autonomous driving. However, existing panoptic segmentation methods are usually challenging for multi-scale object segmentation and boundary localization. In this paper, we propose a Polymerized Feature Panoptic Segmentation (PFPS) to enhance the network's feature representation ability by polymerizing the extracted stage features. Specifically, we propose a Generalization-Enhanced Stage Feature Generation Module (GSFGM) to extract and enhance the stage features. In the GSFGM, a novel Sampled and Concated Feature Generation (SCFG) is designed as an individual component, which polymerizes the convoluted backbone features to enhance multi-scale feature representation. Thereafter, we propose a Stage Feature Re-weight Module (SFRM) to ensure the network can learn efficient information from the massive channels. Moreover, we further propose a Unified Encoder Module (UEM) to provide spatial information and compress the high-dimensional features by coordinating convolution operations and channel attention. To demonstrate the superiority of the proposed PFPS, we conduct experiments on the COCO-2017 and the Cityscapes validation datasets. The experimental results indicate that the PFPS achieves a better performance in PQ of 43.0%, SQ of 80.4%, RQ of 51.9%, PQth of 48.6%, SQth of 82.6%, RQth of 58.1%, PQst of 34.6% on COCO-2017 validation dataset, while PQ of 61.7%, and PQst of 67.9% on Cityscapes validation dataset.
AB - Panoptic segmentation requires the prediction of a pixel-level mask with a category label in an image. In recent years, panoptic segmentation has been gaining more attention since it can help us understand objects and the environment in many fields, such as medical images, remote sensing images, and autonomous driving. However, existing panoptic segmentation methods are usually challenging for multi-scale object segmentation and boundary localization. In this paper, we propose a Polymerized Feature Panoptic Segmentation (PFPS) to enhance the network's feature representation ability by polymerizing the extracted stage features. Specifically, we propose a Generalization-Enhanced Stage Feature Generation Module (GSFGM) to extract and enhance the stage features. In the GSFGM, a novel Sampled and Concated Feature Generation (SCFG) is designed as an individual component, which polymerizes the convoluted backbone features to enhance multi-scale feature representation. Thereafter, we propose a Stage Feature Re-weight Module (SFRM) to ensure the network can learn efficient information from the massive channels. Moreover, we further propose a Unified Encoder Module (UEM) to provide spatial information and compress the high-dimensional features by coordinating convolution operations and channel attention. To demonstrate the superiority of the proposed PFPS, we conduct experiments on the COCO-2017 and the Cityscapes validation datasets. The experimental results indicate that the PFPS achieves a better performance in PQ of 43.0%, SQ of 80.4%, RQ of 51.9%, PQth of 48.6%, SQth of 82.6%, RQth of 58.1%, PQst of 34.6% on COCO-2017 validation dataset, while PQ of 61.7%, and PQst of 67.9% on Cityscapes validation dataset.
KW - deep learning
KW - deep neural networks
KW - fully convolutional networks
KW - Panoptic segmentation
KW - supervised learning
UR - http://www.scopus.com/inward/record.url?scp=85212938633&partnerID=8YFLogxK
U2 - 10.1109/TETCI.2024.3515004
DO - 10.1109/TETCI.2024.3515004
M3 - Article
AN - SCOPUS:85212938633
SN - 2471-285X
JO - IEEE Transactions on Emerging Topics in Computational Intelligence
JF - IEEE Transactions on Emerging Topics in Computational Intelligence
ER -