Computer Science

Computer Science ›› 2026, Vol. 53 ›› Issue (6A): 250600169-8.doi: 10.11896/jsjkx.250600169

• Image Processing & Multimedia Technology • Previous Articles     Next Articles

Asynchronous Dynamic Image Stitching Method Based on Parameter-adaptive Grey WolfOptimization Algorithm

SHAN Chengcheng1, LI Weiting1, MEI Chun1, ZHAO Hui2, QIAN Weixing2, ZENG Qinghua3   

  1. 1 SPIC Jiangsu Offshore Wind Power Co.,Ltd.,Yancheng,Jiangsu 224000,China
    2 School of Electrical and Automation Engineering,Nanjing Normal University,Nanjing 210023,China
    3 College of Automation Engineering,Nanjing University of Aeronautics and Astronautics,Nanjing 211106,China
  • Online:2026-06-16 Published:2026-06-12
  • About author:SHAN Chengcheng,born in 1996,engineer,registered safety engineer.His main research interests include offshore wind power industry engineering construction,production and operation maintenance,and transportation vessel management.
  • Supported by:
    National Natural Science Foundation of China(62373194).

PDF (PC)

18

Abstract: To address the inefficiency and dynamic object distortion issues in asynchronous image stitching under dynamic scenes,this paper proposes a parameter-adaptive image stitching method based on the Grey Wolf Optimizer (GWO) algorithm.This method integrates the swarm intelligence search mechanism of GWO into the RANSAC framework,mapping keypoint subsets as “wolf pack individuals” and utilizing the guided search mechanism of α,β,δ wolves to make keypoint selection “optimization-oriented”,ensuring the integrity and continuity of dynamic objects in asynchronous states.Additionally,to improve the robustness and processing efficiency of the algorithm in different scenarios,a two-stage parameter adaptation mechanism is introduced,including low-resolution pre-computation and dynamic termination conditions,achieving automated adjustment of core parameters such as error tolerance and iteration count.Experiments on the StabStitch-D dataset show that under the same iterative conditions,GWO-RANSAC improves the inlier matching rate by 4.91% compared to traditional RANSAC,PSNR value increases by 11.4% (from 32.5dB to 36.2dB) and SSIM value increases by 5.1% (from 0.881 to 0.926),while effectively reducing black borders and misalignment phenomena in stitched images,and ensuring the integrity and continuity of dynamic objects even in complex scenarios.Theoretical analysis shows that this method has significant advantages in resource-constrained environments and dynamic asynchronous scenarios,forming effective complementarity with deep learning methods.

Key words: Dynamic image stitching, Heuristic methods, RANSAC, Grey wolf optimizer, Parameter-adaptive

CLC Number: 

  • TP391.41
[1] ANAND V,GUPTA S,KOUNDAL D,et al.Fusion of U-net and CNN model for segmentation and classification of skin lesions from dermoscopy images [J].Expert Systems with Applications,2023,213:119230.
[2] WANG Y H,ZHOU X.Outlierrecognition and eliminationmethod base on zero-phase difference fitting model[J].Electronic Measurement Technology,2024,47(4):31-35.
[3] YU Y F,QIAN J B,YAN D Q,et al.Cross-CNN:An Animation Cross-Frame Sketch Colorization Algorithm Based on Hybrid Model with CNN and Transformer[J].Acta Electronica Sinica,2024,52(7):2491-2502.
[4] LIN Z K,HOU G J,WANG G D,et al.Image Deraining Based on Union Attention Mechanism and Multi-stage Feature Extraction[J].Computer Science,2025,52(11):206-212.
[5] NIE L,LIN C,LIAO K,et al.Deep rectangling for image stitching:A learning baseline [C]//Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition.2022:5740-5748.
[6] LIU Y,WANG X,SUN L,et al.Underwater image stitchingmethod based on optimal seam and multi-resolution fusion algorithms [C]//Proceedings of Eighth Symposium on Novel Photoelectronic Detection Technology and Applications.2022.2759-2769.
[7] RAHMAN M,LI X,YIN X.DL-RANSAC:An improvedRANSAC with modified sampling strategy based on the likelihood [C]//Proceedings of IEEE 4th International Conference on Image,Vision and Computing.2019:463-468.
[8] ZHAO S,ZHANG C T,FAN C L.Deep feature extraction-based sequential image stitching network for deep-sea environments[J].Electronic measurementtechnology,2025,48(3):180-187.
[9] JIN S,GE D Y,YAO X F.Image Mosaic Based on RANSACwith Matching Point Increasing[J].Science Technology and Engineering,2025,25(6):2435-2441.
[10] LIU J,BU F.Improved RANSAC features image-matchingmethod based on SURF [J].The Journal of Engineering,2019,2019(23):9118-9122.
[11] HAN C Y,SU S J,SHI W B,et al.Indoor Positioning in Dynamic Environment Based on PSO-OS-ELM[J].Journal of Data Acquisition and Processing,2022,37(6):1345-1352.
[12] KANG Y,WANG H N,TAO L,et al.Hybrid Improved FlowerPollination Algorithm and Gray Wolf Algorithm for Feature Selection[J].Computer Science,2022,49(S1):125-132.
[13] CAO G G,ZHU X Y,CHEN Y,et al.Medical Image Registration Based on Improved Brain Storm Optimization Algorithm[J].Journal of Data Acquisition and Processing,2020,35(4):730-738.
[14] POŁAP D,WOĆNIAK M.Polar bear optimization algorithm:Meta-heuristic with fast population movement and dynamic birth and death mechanism [J].Symmetry,2017,9(10):203.
[15] NARUEI I,KEYNIA F.Wild horse optimizer:A new meta-heuristic algorithm for solving engineering optimization problems [J].Engineering with Computers,2022,38(Suppl 4):3025-3056.
[16] WANG J X,HU R Z,GUAN Y,et al.Vibration prediction of hydropower unit based on RFOA-GRNN[J].Journal of Vibration and Shock,2021,40(21):120-126.
[17] CHEN J,LI H.UDis:Unsupervised discovery for image stitching[C]//CVPR.2021:5140-5149.
[18] SUN J,SHEN Z,WANG Y,et al.LoFTR:Detector-free local feature matching with transformers[C]//CVPR.2021:8922-8931.
[19] ROSINOL A,ABATE M,CHANG Y,et al.Kimera:an open-source library for real-time metric-semantic localization and mapping[C]//ICRA.2020:1689-1696.
[1] DU Likuan, LIU Chen, WANG Junlu, SONG Baoyan. Self-learning Star Chain Space Adaptive Allocation Method [J]. Computer Science, 2025, 52(3): 359-365.
[2] CHEN Haiyan. Efficient Clustering Routing Method for WSNs Based on Clone Reverse Learning Grey WolfOptimization Algorithm [J]. Computer Science, 2025, 52(12): 294-301.
[3] XU Xin, ZHU Hongbin, CHEN Jie, LI Qingwen, ZHANG Xiaorong, LYU Zhihui. Anti-money Laundering Detection Method for Asset Management Based on Temporal Graph Neural Networks [J]. Computer Science, 2025, 52(10): 60-69.
[4] YU Mingyang, LI Ting, XU Jing. Adaptive Grey Wolf Optimizer Based on IMQ Inertia Weight Strategy [J]. Computer Science, 2024, 51(7): 354-361.
[5] LI Zhiyuan, XU Binglei, ZHOU Yingyi. Blockchain Anonymous Transaction Tracking Method Based on Node Influence [J]. Computer Science, 2024, 51(7): 422-429.
[6] QIN Zhongpiao, ZHOU Yatong, LI Zhe. Bank Transaction Fraud Detection Method Based on Graph Neural Network [J]. Computer Science, 2024, 51(11A): 240200024-8.
[7] KANG Zhenwei, LI Jing, ZHU Jianming. Tripartite Evolutionary Game Analysis of Blockchain Applications in Patent Transactions [J]. Computer Science, 2024, 51(10): 432-441.
[8] DONG Hao, ZHAO Hengtai, WANG Ziyao, YUAN Ye, ZHANG Aoqian. Parallel Transaction Execution Models Under Permissioned Blockchains [J]. Computer Science, 2024, 51(1): 124-132.
[9] HONG Xuan, YUAN Mengling. Ring Confidential Transaction Protocol Based on Multivariate Public-key Cryptosystem [J]. Computer Science, 2023, 50(6A): 220100157-6.
[10] ZHANG Wenning, ZHOU Qinglei, JIAO Chongyang, XU Ting. Hybrid Algorithm of Grey Wolf Optimizer and Arithmetic Optimization Algorithm for Class Integration Test Order Generation [J]. Computer Science, 2023, 50(5): 72-81.
[11] SUN Min, XU Senwei, SHAN Tong. LN-ERCL Lightning Network Optimization Scheme [J]. Computer Science, 2023, 50(11A): 230200115-5.
[12] ZHANG Yuan, KANG Le, GONG Zhao-hui, ZHANG Zhi-hong. Related Transaction Behavior Detection in Futures Market Based on Bi-LSTM [J]. Computer Science, 2022, 49(7): 31-39.
[13] ZHOU Hang, JIANG He, ZHAO Yan, XIE Xiang-peng. Study on Optimal Scheduling of Power Blockchain System for Consensus Transaction ofEach Unit [J]. Computer Science, 2022, 49(6A): 771-776.
[14] HE Xi, HE Ke-tai, WANG Jin-shan, LIN Shen-wen, YANG Jing-lin, FENG Yu-chao. Analysis of Bitcoin Entity Transaction Patterns [J]. Computer Science, 2022, 49(6A): 502-507.
[15] FAN Xing-ze, YU Mei. Coverage Optimization of WSN Based on Improved Grey Wolf Optimizer [J]. Computer Science, 2022, 49(6A): 628-631.
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.