[1] NGUYEN B L, NGO D T, DAO M N, et al. Scheduling and power control for connectivity enhancement in multi-hop I2V/V2V networks[J]. IEEE transactions on intelligent transportation systems, 2021:1-11.

[2] TUAN N M, PHUONG T V, DO T H, et al. An highly realistic optical camera communication simulation framework for internet of things applications[C]//21st ACIS International Winter Conference on Software Engineering, Artificial Intelligence, Networking and Parallel/Distributed Computing (SNPD-Winter), January 28-30, 2021, Ho Chi Minh City, Vietnam. New York: IEEE, 2021:240-242.

[3] MOHSAN S A H. Optical camera communications: practical constraints, applications, potential challenges, and future directions[J]. Journal of optical technology, 2021, 88(12):729-741.

[4] HUANG Z, HE J, YU K, et al. Efficient demodulation scheme based on adaptive clock extraction and mapping-sampling for a mobile OCC system[J]. Applied optics, 2021, 60(12):3308-3313.

[5] THOTA J, ABDULLAH N F, DOUFEXI A, et al. V2V for vehicular safety applications[J]. IEEE transactions on intelligent transportation systems, 2019, 21(6): 2571-2585.

[6] MORENO D, RUFO J, GUERRA V, et al. Optical multispectral camera communications using LED spectral emission variations[J]. IEEE photonics technology letters, 2021, 33(12):591-594.

[7] ISLAM A, HOSSAN M T, JANG Y M. Convolutional neural network scheme-based optical camera communication system for intelligent Internet of vehicles[J]. International journal of distributed sensor networks, 2018, 14(4):155014771877015.

[8] SHI J, HE J, JIANG Z, et al. Enabling user mobility for optical camera communication using mobile phone[J].Optics express, 2018, 26(17):21762-21767.

[9] HSU K L, CHOW C W, LIU Y, et al. Rolling-shutter-effect camera-based visible light communication using RGB channel separation and an artificial neural network[J]. Optics express, 2020, 28(26): 39956-39962.

[10] LIU Z, GUAN W, WEN S. Improved target signal source tracking and extraction method based on outdoor visible light communication using an improved particle filter algorithm based on Cam-Shift algorithm[J]. IEEE photonics journal, 2019, 11(6):1-20.

[11] PHAM T L, SHAHJALAL M D, BUI V, et al. Deep learning for optical vehicular communication[J]. IEEE access, 2020, 8:102691-102708.

[12] SUN X, SHI W, CHENG Q, et al. An LED detection and recognition method based on deep learning in vehicle optical camera communication[J]. IEEE access, 2021, 9:80897-80905.

[13] HAN K, WANG Y, TIAN Q, et al. Ghostnet:more fea tures from cheap operations[C]//33st IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR), June 13-19, 2020, Seattle, WA, USA. Piscataway :IEEE, 2020:1577-1586.

[14] LIU S, QI L, QIN H, et al. Path aggregation network for instance segmentation[C]//31st IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR), June 18-23, 2018, Salt Lake City, UT, USA. Piscataway :IEEE, 2018:8759-8768.

[15] WANG C Y, BOCHKOVSKIY A, LIAO H Y M. Scaled-YOLOv4: scaling cross stage partial network[C]//34st IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR), June 20-25, 2021, Nashville, TN, USA. Piscataway: IEEE, 2021: 13024-13033.

[16] ZHENG Z, WANG P, LIU W, et al. Distance-IoU loss: faster and better learning for bounding box regression[C]//34th AAAI Conference on Artificial Intelligence, February 7-12, 2020, New York, USA. Menlo Park:AAAI Press, 2020:12993-13000.

[17] BOCHKOVSKIY A, WANG C Y, LIAO H Y M. YOLOv4 :optimal speed and accuracy of object detection[EB/OL]. (2020-04-23) [2022-04-25]. https://arxiv.org/abs/2004.10934?sid=V22o3y.