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Mobile Networks and Applications

Erschienen in:

10.12.2019

Efficient Traffic Sign Recognition Using Cross-Connected Convolution Neural Networks Under Compressive Sensing Domain

verfasst von: Jiping Xiong, Lingfeng Ye, Dingde Jiang, Tong Ye, Fei Wang, LingYun Zhu

Erschienen in: Mobile Networks and Applications | Ausgabe 2/2021

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Abstract

Convolutional neural networks (CNN) is widely used for traffic sign recognition. Meanwhile, the compressive sensing technology is developing and applied to the field of image reconstruction in the compressive sensing domain. Therefore, we first propose a traffic sign recognition algorithm based on compressive sensing domain and convolution neural networks for traffic sign recognition. The algorithm converts the image into a compressed sensing domain through the measurement matrix without reconstruction, and can extract the discriminant nonlinear features directly from the compressed sensing domain. In order to improve the accuracy of traffic sign recognition, we further propose a cross-connected convolution neural networks (CCNN). Cross-connected convolution neural networks is a 9 layers framework with an input layer, six hidden layers (i.e., three convolution layers alternating with three pooling layers), a fully-connected layer and an output layer, where the second pooling layer is allowed to connect directly to the fully-connected layer across two layers. Experimental results on well-known dataset show that the algorithm improves the accuracy of traffic sign recognition. The recognition of our algorithm is even possible at low compressive sensing measurement rates.

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Chhabra R, Verma S, Rama Krishna C (2017) A survey on driver behavior detection techniques for intelligent transportation systems. 7th international conference on cloud computing, data science & engineering-confluence, 2017

Jiang D, Huo L, Lv Z, Song H, Qin W (2018) A joint multi-criteria utility-based network selection app-roach for vehicle-to-infrastructure networking. IEEE Trans Intell Transp Syst pp(99):1–15

Jiang D, Xu Z, Wang W, Wang Y, Han Y (2015) A collaborative multi-hop routing algorithm for maximum achievable rate. J Netw Comput Appl 57(2015):182–191

Jiang D, Wang Y, Yao C, Han Y (2015) An effecti-ve dynamic spectrum access algorithm for multi-hop cognitive wireless networks. Comput Netw 84(19):1–16

Jiang D, Huo L, Lv Z et al (2018) A joint multi-criteria utility-based network selection approach for vehicle-to-infrastructure networking. IEEE Trans Intell Transp Syst 19(10):3305–3319

Jiang D, Wang Y, Lv Z et al (2019) Big data analysis-based network behavior insight of cellular networks for industry 4.0 applications. IEEE Trans Ind Inf. Online available: https://doi.org/10.1109/TII.2019.2930226

Xing Y, Lv C, Chen L, Wang H, Wang H, Cao D et al (2018) Advances in vision-based lane detection: algorithms, integration, assessment, and perspectives on ACP-based parallel vision. IEEE/CAA J Automat Sin 5(3):645–661

Jiang D, Xu Z, Li W, Chen Z (2015) Network codi-ng based energy-efficient multicast routing algorithm for multi-hop wireless networks. J Syst Softw 104(2015):152–165

Jiang D, Li W, Lv H (2017) An energy-efficient cooperative multicast routing in multi-hop wireless net-works for smart medical applications. Neurocomputin-g 220(2017):160–169

10.

Jiang D, Wang Y, Han Y et al (2017) Maximum connectivity-based channel allocation algorithm in cognitive wireless networks for medical applications. Neurocomputing 220(2017):41–51

11.

Jiang D, Xu Z, Li W et al (2016) An energy-efficient multicast algorithm with maximum network throughput in multi-hop wireless networks. J Commun Netw 18(5):713–724

12.

Jiang D, Zhang P, Lv Z et al (2016) Energy-efficient multi-constraint routing algorithm with load balancing for smart city applications. IEEE Internet Things J 3(6):1437–1447

13.

Wang F, Jiang D, Wen H et al (2019) Adaboost-based security level classification of mobile intelligent terminals. J Supercomput:1–19. Online available: https://doi.org/10.1007/s11227-019-02954-y

14.

Hmida R, Abdelali AB, Mtibaa A (2018) Hard-ware implementation and validation of a traffic road sign detection and identification system. J Real-Time Image Proc 15(1):13–30

15.

Huo L, Jiang D, Zhu X et al (2019) An SDN-based fine-grained measurement and modeling approach to vehicular communication network traffic. Int J Commun Syst:1–12. Online available: https://doi.org/10.1002/dac.4092

16.

Wang F, Jiang D, Qi S (2019) An adaptive routing algorithm for integrated information networks. China Commun 7(1):196–207

17.

Huo L, Jiang D (2019) Stackelberg game-based energy-efficient resource allocation for 5G cellular networks. Telecommun Syst 23(4):1–11

18.

Haloi M (2015) A novel pLSA based traffic signs classification system. Available at https://arxiv.org/

19.

Jiang D, Huo L, Song H (2018) Rethinking behaviors and activities of base stations in mobile cellular networks based on big data analysis. IEEE Trans Netw Sci Eng 1(1):1–12MathSciNet

20.

Zhao ZH, Yang SP, Ma ZQ (2010) The study of license character recognition based on the convolution neural network LeNet-5. J Syst Simul 22(3):638–641

21.

Shu Y, Huang Y, Li B (2018) Design of deep learning accelerated algorithm for online recognition of industrial products defects. Neural Comput Applic:1–14

22.

Jiang D, Huo L, Li Y (2018) Fine-granularity inference and estimations to network traffic for SDN. PLoS One 13(5):1–23

23.

Mrinal H (2016) Traffic sign classification using deep inception based convolutional networks. Available at https://arxiv.org/

24.

Yi Y, Hengliang L, Huarong X, Wu F (2016) Towards real-time traffic sign detection and classification. IEEE Trans Intell Transp Syst 17:2022–2031

25.

Zhu J, Song Y, Jiang D et al (2018) A new deep-Q-learning-based transmission scheduling mechanism for the cognitive Internet of Things. IEEE Internet Things J 5(4):2375–2385 uestc

26.

Yuan Y, Xiong Z, Wang Q (2019) VSSA-NET: vertical spatial sequence attention network for traffic sign detection. IEEE Trans Image Process 28(7):3423–3434MathSciNetMATH

27.

Zhong SH, Liu Y, Ren FF, Zhang JH, Ren TW (2013) Video saliency detection via dynamic consistent spatio-temporal attention modelling. In: Proceedings of the 2013 AAAI conference on articial intelligence. AAAI, Bellevue, pp 1063–1069

28.

Jiang D, Nie L, Lv Z et al (2016) Spatio-temporal Kronecker compressive sensing for traffic matrix recovery. IEEE Access 4:3046–3053

29.

Huo L, Jiang D, Lv Z (2018) Soft frequency reuse-based optimization algorithm for energy efficiency of multi-cell networks. Comput Electr Eng 66(2):316–331

30.

Tang W, Zhang K, Jiang D (2018) Physarum-inspired routing protocol for energy harvesting wireless sensor networks. Telecommun Syst 67(4):745–762

31.

Mei-Bin Q, Sheng-Shun T, Yun-Xia W, Hao L, Jian-Guo J (2016) Multi-feature subspace and kernel learning for person reidentication. Acta Automat Sin 42(2):299–308

32.

LeCun Y, Bengio Y, Hinton GE (2015) Deep learning. Nature 521(7553):436–444

33.

Cheng G, Li Z, Han J, Yao X, Guo L (2018) Exploring hierarchical convolutional features for hyperspectral image classification. IEEE Trans Geosci Remote Sens 56(11):6712–6722

34.

Sun M, Zhou Z, Hu Q et al (2019) SG-FCN: a motion and memory-based deep learning model for video saliency detection. IEEE Trans Cybern 49(8):2900–2911

35.

Ulyanov D, Vedaldi A, Lempitsky V (2018) Deep image prior. In: Proceedings of the IEEE conference on computer vision and pattern recognition, pp 9446–9454

36.

Wang T, Yao YT, Chen Y, Zhang MY, Tao F, Snoussi H (2018) Auto-sorting system toward smart factory based on deep learning for image segm-entation. IEEE Sensors J 18(20):8493–8501

37.

Suhas L, Kuldeep K, Pavan T (2016) Direct inference on compressive measurements using convolutional neural networks. Image Process (ICIP):1913–1917

38.

Sun ZJ, Xue L, Xu YM (2012) Review of deep learning research. Comput Appl Res 29(8):2807–2810

39.

Adcock B, Hansen AC, Poon C, Roman B (2017) Breaking the coherence barrier: a new theory for compressed sensing. In: Forum of mathematics, sigma, vol 5. Cambridge University Press, Cambridge

40.

Mehta BB, Coppo S, McGivney DF, Hamilton JI et al (2018) Magnetic resonance fingerprinting: a technical review. Magn Reson Med 81(1):25–46

41.

Donoho DL (2006) Compressed sensing. IEEE Trans Inf Theory 52(4):1289–1306MathSciNetMATH

42.

Ma J, Ma Y, Li C (2019) Infrared and visible image fusion methods and applications: a survey. Inf Fusion 45:153–178

43.

Jiang D, Wang W, Shi L et al (2018) A compressive sensing-based approach to end-to-end network traffic reconstruction. IEEE Trans Netw Sci Eng 5(3):1–12

44.

Udell M, Horn C, Zadeh R, Boyd S (2016) Generalized low rank models. Found Trends Mach Learn 9(1):1–118MATH

45.

Sankaranarayanan AC, Turaga PK, Baraniuk RG, Chellappa R (2010) Compressive acquisition of dynamic scenes. In: ECCV. Springer, pp 129–142

46.

Wang X, Li G, Varshney PK (2018) Detection of sparse signals in sensor networks via locally most powerful tests. IEEE Signal Process Lett 25(9):1418–1422

47.

Millikan B, Dutta A, Sun Q, Foroosh H (2017) Fast detection of compressively sensed ir targets using stochastically trained least squares and compressed quadratic correlation filters. IEEE Trans Aerosp Electron Syst 53(5):2449–2461

48.

Sermanet P, LeCun Y (2011) Traffic sign recognition with multi-scale convolutional networks. In: IEEE, Neural Networks (IJCNN), pp 2809–2813

49.

Stallkamp J, Schlipsing M, Salmen J, Igel C (2011) The German traffic sign recognition benchmark: a multi-class classification competition. In: IEEE, Neural Networks (IJCNN), pp 1453–1458

50.

Zaklouta F, Stanciulescu B, Hamdoun O (2011) Traffic sign classification using kd trees and random forests. In: IEEE, Neural Networks (IJCNN), pp 2151–2155

51.

Huang Z, Yu Y, Gu J, Liu H (2016) An effificient method for traffific sign recognition based on extre-me learning machine. IEEE Trans Cybern 99:1–14

52.

Ellahyani A, Ansari ME, Jaafari IE (2016) Traffific sign detection and recognition based on random forests. Appl Soft Comput. https://doi.org/10.1016/j.asoc.2015.12.041

53.

Gudigar A, Chokkadi S, Raghavendra U, Acharya UR (2017) Local texture patterns for traffific sign recognition using higher order spectra. Pattern Recogn Lett. https://doi.org/10.1016/j.patrec.2017.02.016

54.

Gudigar A, Chokkadi S, Raghavendra U, Acharya UR (2019) An efficient traffic sign recognition based on graph embedding features. Neural Comput & Applic 31(2):395–340

Titel: Efficient Traffic Sign Recognition Using Cross-Connected Convolution Neural Networks Under Compressive Sensing Domain
verfasst von: Jiping Xiong
Lingfeng Ye
Dingde Jiang
Tong Ye
Fei Wang
LingYun Zhu
Publikationsdatum: 10.12.2019
Verlag: Springer US
Erschienen in: Mobile Networks and Applications / Ausgabe 2/2021
Print ISSN: 1383-469X
Elektronische ISSN: 1572-8153
DOI: https://doi.org/10.1007/s11036-019-01409-1

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