Computer Science

Computer Science ›› 2024, Vol. 51 ›› Issue (6A): 230400101-7.doi: 10.11896/jsjkx.230400101

• Image Processing & Multimedia Technolog • Previous Articles     Next Articles

Direction-aware Pyramidal Aggregation Network for Road Centerline Extraction

ZHANG Xiaoqing1, WANG Qingwang1, QU Xin1, SHEN Shiquan2, WU Changyi3, LIU Ju4   

  1. 1 School of Information Engineering and Automation,Kunming University of Technology,Kunming 650504,China
    2 School of Traffic Engineering,Kunming University of Technology,Kunming 650504,China
    3 Zhaotong City Construction Quality Supervision Station,Zhaotong,Yunnan 657099,China
    4 Process Manufacturing Development IV,Yonyou Network Technology Co,Chengdu 610095,China
  • Published:2024-06-06
  • About author:ZHANG Xiaoqing,born in 1997,postgraduate.Her main research interests include computer vision and deep lear-ning.
    WANG Qingwang,born in 1990,Ph.D,professor.His main research interests include the collaborative interpretation of multi-source remote sensing data and deep learning.
  • Supported by:
    Young Scientists Fund of the National Natural Science Foundation of China(62201237) and Yunnan Fundamental Research Projects(202101BE070001-008).

PDF (PC)

252

Abstract: As an abstract class,road centerlines have no explicit features,which in turn causes the model fail to extract road centerlines accurately.To address this problem,this paper models road centerline extraction as a semantic segmentation task,and proposes a direction-aware pyramidal aggregation network(DAPANet) based on the spatial linear structure of road centerlines.Firstly,for the spatial distribution characteristics and structural features of road centerlines,this paper designs the direction-aware module(DAM) to extract the features of road centerlines using four direction-aware layers on each of the four layers of the final output of the backbone network(ResNet18).Then,it further designs the pyramid aggregation module(PAM) to fuse the structural features extracted from the four layers to obtain a more robust road centerline feature.Experiments are conducted on real data collected under the UAV platform,and the experimental results show that the proposed DAPANet achieves 84.7% of mIoU and 98.6% of Precision,in which the IoU of road centerline reaches 77.28%,outperforming other advanced comparative methods and proving the effectiveness of the proposed method.

Key words: Direction-awareness, Pyramid aggregation, Semantic segmentation, Road centerline extraction

CLC Number: 

  • TP389
[1]WU H B,QIU W M,WANG J,et al.Intelligent multi-track inspection robot inspection system for urban rail vehicles[J].Locomotive Electric Drive,2022(1):45-52.
[2]ZHU J Y,LI P,LI X,et al.Intelligent inspection robot positioning system for urban rail vehicles[J].Railway Transport and Economy,2023,45(1):130-136.
[3]ZHAO X T,HU K,LU X P,et al.A method for fine detection of geological hazards in mines by low altitude aerial photography with unmanned aerial vehicles[J].Survey and Mapping Science,2014,39(6):49-52.
[4]PAN L,GUO T T.Intelligent inspection application of naturalgas long-distance pipeline by drones[J].Chemical Management,2023,653(2):124-126.
[5]ZHU C,ZHU J,BU T,et al.Monitoring and Identification of Road Construction Safety Factors via UAV[J].Sensors,2022,22(22):8797.
[6]SHERSTJUK V,ZHARIKOVA M,SOKOL I.Forest fire monitoring system based on UAV team,remote sensing,and image processing[C]//Procedings of IEEE Conference on Data Stream Mining and Processing(DSMP).2018:590-594.
[7]MIAO Z,WANG B,SHI W,et al.A semi-automatic method for road centerline extraction from VHR images[J].IEEE Geoscience and Remote Sensing Letters,2014,11(11):1856-1860.
[8]CHENG G,WANG Y,XU S,et al.Automatic road detectionand centerline extraction via cascaded end-to-end convolutional neural network[J].IEEE Transactions on Geoscience and Remote Sensing,2017,55(6):3322-3337.
[9]SHAO Z,ZHOU Z,HUANG X,et al.MRENet:Simultaneousextraction of road surface and road centerline in complex urban scenes from very high-resolution images[J].Remote Sensing,2021,13(2):239.
[10]YU C,WANG J,PENG C,et al.Bisenet:Bilateral segmentation network for real-time semantic segmentation[C]//European Conference on Computer Vision(ECCV).2018:325-341.
[11]ZHAO H,QI X,SHEN X,et al.Icnet for real-time semantic segmentation on high-resolution images[C]//European Conference on Computer Vision(ECCV).2018:405-420.
[12]WANG Y,ZHOU Q,LIU J,et al.Lednet:A lightweight encoder-decoder network for real-time semantic segmentation[C]//International Conference on Image Processing(ICIP).IEEE,2019:1860-1864.
[13]SHI W,MIAO Z,DEBAYLE J.An integrated method for urban main-road centerline extraction from optical remotely sensed imagery[J].IEEE Transactions on Geoscience and Remote Sensing,2013,52(6):3359-3372.
[14]DAI J,MA R,GONG L,et al.A model-driven-to-sample-driven method for rural road extraction[J].Remote Sensing,2021,13(8):1417.
[15]LIU R,MIAO Q,SONG J,et al.Multiscale road centerlines extraction from high-resolution aerial imagery[J].Neurocomputing,2019,329:384-396.
[16]LIAN R,HUANG L.DeepWindow:Sliding window based ondeep learning for road extraction from remote sensing images[J].IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing,2020,13:1905-1916.
[17]DONG G,YAN Y,SHEN C,et al.Real-time high-performance semantic image segmentation of urban street scenes[J].IEEE Transactions on Intelligent Transportation Systems,2020,22(6):3258-3274.
[18]LI S,YAN Q,SHI W,et al.HoloParser:Holistic Visual Parsing for Real-time Semantic Segmentation in Autonomous Driving[J].IEEE Transactions on Instrumentation and Measurement,2023,72:1-15.
[19]ZOU W,HUA G,ZHUANG Y,et al.Real-time Passable Area Segmentation with Consumer RGB-D Cameras for the Visually Impaired[J].IEEE Transactions on Instrumentation and Measurement,2023,72:1-11.
[20]YU C,GAO C,WANG J,et al.Bisenet v2:Bilateral networkwith guided aggregation for real-time semantic segmentation[J].International Journal of Computer Vision,2021,129:3051-3068.
[21]FAB M,LAI S,HUANG J,et al.Rethinkingbisenet for real-time semantic segmentation[C]//Conference on Computer Vision and Pattern Recognition(CVPR).2021:9716-9725.
[22]PAN H,HONG Y,SUN W,et al.Deep dual-resolution net-works for real-time and accurate semantic segmentation of traffic scenes[J].IEEE Transactions on Intelligent Transportation Systems,2023,24(3):3348-3460.
[23]XU J,XIONG Z,BHATTACHARYYA S P.Pidnet:A real-time semantic segmentation network inspired from pid controller[J].arXiv:2206.02066,2022.
[24]ELHASSAN M A M,YANG C,HUANG C,et al.SPFNet:Subspace Pyramid Fusion Network for Semantic Segmentation[J].arXiv:2204.01278,2022.
[25]SHI M,SHEN J,YI Q,et al.LMFFNet:A well-balanced lightweight network for fast and accurate semantic segmentation[J].IEEE Transactions on Neural Networks and Learning Systems,2023,34(6):3205-3219.
[26]ELHASSAN M A M,YANG C,HUANG C,et al.SS-FPN:Scale-ware Strip Attention Guided Feature Pyramid Network for Real-time Semantic Segmentation[J].arXiv:2206.07298,2022.
[27]SUN T,DI Z,CHE P,et al.Leveraging crowdsourcedgps datafor road extraction from aerial imagery[C]//Conference on Computer Vision and Pattern Recognition(CVPR).2019:7509-7518.
[28]MEI J,LI R J,GAO W,et al.CoANet:Connectivity attentionnetwork for road extraction from satellite imagery[J].IEEE Transactions on Image Processing,2021,30:8540-8552.
[29]WANG J,CHEN K,XU R,et al.Carafe:Content-aware reassembly of features[C]//International Conference on Computer Vision(ICCV).2019:3007-3016.
[30]LIN T Y,GOYAL P,GIRSHICK R,et al.Focal loss for dense object detection[C]//International Conference on Computer Vision(ICCV).2017:2980-2988.
[1] HUANG Haixin, CAI Mingqi, WANG Yuyao. Review of Point Cloud Semantic Segmentation Based on Graph Convolutional Neural Networks [J]. Computer Science, 2024, 51(6A): 230400196-7.
[2] SUN Jifei, JIA Kebin. Classification and Detection Algorithm of Ground-based Cloud Images Based on Multi-scale Features [J]. Computer Science, 2024, 51(6A): 230400041-6.
[3] WANG Guogang, DONG Zhihao. Lightweight Image Semantic Segmentation Based on Attention Mechanism and Densely AdjacentPrediction [J]. Computer Science, 2024, 51(6A): 230300204-8.
[4] WU Yibo, HAO Yingguang, WANG Hongyu. Rice Defect Segmentation Based on Dual-stream Convolutional Neural Networks [J]. Computer Science, 2024, 51(6A): 230600107-8.
[5] XIAO Yahui, ZHANG Zili, HU Xinrong, PENG Tao, ZHANG Jun. Clothing Image Segmentation Method Based on Deeplabv3+ Fused with Attention Mechanism [J]. Computer Science, 2024, 51(6A): 230900153-7.
[6] HUANG Wenke, TENG Fei, WANG Zidan, FENG Li. Image Segmentation Based on Deep Learning:A Survey [J]. Computer Science, 2024, 51(2): 107-116.
[7] LUO Huilan, YE Ju. Study of Multi-task Learning with Joint Semantic Segmentation and Depth Estimation [J]. Computer Science, 2023, 50(6A): 220100111-10.
[8] SUN Kaiwei, LIU Hu, RAN Xue, GUO Hao. Few-shot Segmentation Based on Multi-scale Prototype Hierarchical Matching [J]. Computer Science, 2023, 50(6A): 220300275-7.
[9] GU Yuhang, HAO Jie, CHEN Bing. Semi-supervised Semantic Segmentation for High-resolution Remote Sensing Images Based on DataFusion [J]. Computer Science, 2023, 50(6A): 220500001-6.
[10] BAI Zhengyao, FAN Shenglan, LU Qianjie, ZHOU Xue. COVID-19 Instance Segmentation and Classification Network Based on CT Image Semantics [J]. Computer Science, 2023, 50(6A): 220600142-9.
[11] CHEN Qiaosong, ZHANG Yu, PU Liu, TAN Chongchong, DENG Xin, WANG Jin, SUN Kaiwei, OUYANG Weihua. Multi-path Semantic Segmentation Based on Edge Optimization and Global Modeling [J]. Computer Science, 2023, 50(6A): 220700137-7.
[12] LI Yang, HAN Ping. Human Parsing Model Combined with Regional Sampling and Inter-class Loss [J]. Computer Science, 2023, 50(4): 103-109.
[13] XU Huajie, XIAO Yifeng. Semi-supervised Semantic Segmentation Method Based on Multiple Teacher Network Model [J]. Computer Science, 2023, 50(12): 279-284.
[14] ZHANG Xinfeng, BIAN Haonan, ZHANG Bo, ZHANG Jiaming, LIANG Yuqing. Rail Light Band Detection Algorithm Based on Deep Learning [J]. Computer Science, 2023, 50(11A): 230200146-6.
[15] WANG Yan, XIA Chuangshuai, WANG Na, NAN Peiqi. Real-time Image Semantic Segmentation Algorithm Based on Hybrid Attention [J]. Computer Science, 2023, 50(11A): 230200010-6.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
渝ICP备16013121号-4
Add:18# Honghu West Rd., Yubei ,Chongqing,China    Post Code: 401121
Tel: 023-63500828/023-67039612/023-67039623
E-mail: jsjkx12@163.com
Powered by Beijing Magtech Co., Ltd.