研究兴趣
1.水下无线光通信系统与网络
2.声-光-射频融合的空天地海一体化通信网络
3.水下目标检测
4.水下捕获对准跟踪
5.水下定位、导航
6.水下无线光能量传输
7.数字信号处理
8.图像处理
9.机器学习
科研项目
1.上海市领军人才(海外)青年人才项目,负责人
研究成果
SCI期刊文章:
[1] Zhou, H., Kong, M.*, Yuan, H., Pan, Y., Wang, X., Chen, R., Lu, W., Wang, R. and Yang, Q., 2024. Real-time underwater object detection technology for complex underwater environments based on deep learning”, Ecological Informatics.
[2] Yuan, H., Kong, M.*, Wang, M., Cui, W., Pan, Y., Zhou, H. and Yang, Q., 2024. Effect of turbulence-induced sediment resuspension and sedimentation on underwater wireless optical communication. Optics Express.
[3] Kong, M., Guo, Y., Alkhazragi, O., Sait, M., Kang, C. H., Ng, T. K., and Ooi, B. S., 2022. Real-time optical-wireless video surveillance system for high visual-fidelity underwater monitoring. IEEE Photonics Journal.
[4] Guo, Y., Kong, M. (共同一作), Alkhazragi, O., Sait, M. A., Kang, C. H., Ashry, I., Yang, Q., Ng, T.K. and Ooi, B. S., 2022. Current Trend in Optical Internet of Underwater Things. IEEE Photonics Journal.
[5] Kong, M., Guo, Y., Sait, M., Alkhazragi, O., Kang, C. H., Ng, T. K., & Ooi, B. S., 2021. Toward automatic subsea operations using real-time underwater optical wireless sensor networks. IEEE Photonics Journal, 14(1), 1-8.
[6](Invited) Kong, M., C.H., Kang, Sun, X., Guo, Y., Sait, M., Holguin-Lerma, J.A., Ng, T.K. and Ooi, B.S., 2020. Survey of energy-autonomous solar cell receivers for satellite–air–ground–ocean optical wireless communication. Progress in Quantum Electronics,pp.100300.
[7] Kong, M., Lin, J., Guo, Y., Sun, X., Sait, M., Alkhazragi, O., C.H., Kang, Holguin-Lerma, J.A., Kheireddine, M., Ouhssain, M., Jones B.H., Ng, T.K. and Ooi, B.S., 2020. AquaE-lite hybrid-solar-cell receiver-modality for energy-autonomous terrestrial and underwater Internet-of-Things. IEEE Photonics Journal, 12(4), pp.1-13.
[8] Holguin-Lerma, J.A., Kong, M. (共同一作), Alkhazragi, O., Sun, X., Ng, T.K. and Ooi, B.S., 2020. 480-nm distributed-feedback InGaN laser diode for 10.5-Gbit/s visible-light communication. Optics Letters, 45(3), pp.742-745.
[9] Kong, M., Lin, J., Kang, C.H., Shen, C., Guo, Y., Sun, X., Sait, M., Weng, Y., Zhang, H., Ng, T.K. and Ooi, B.S., 2019. Toward self-powered and reliable visible light communication using amorphous silicon thin-film solar cells. Optics Express, 27(24), pp.34542-34551.
[10] Kong, M., Chen, Y., Sarwar, R., Sun, B., Xu, Z., Han, J., Chen, J., Qin, H. and Xu, J., 2018. Underwater wireless optical communication using an arrayed transmitter/receiver and optical superimposition-based PAM-4 signal. Optics Express, 26(3), pp.3087-3097.
[11] Kong, M., Sun, B., Sarwar, R., Shen, J., Chen, Y., Qu, F., Han, J., Chen, J., Qin, H. and Xu, J., 2018. Underwater wireless optical communication using a lens-free solar panel receiver. Optics Communications, 426, pp.94-98.
[12] Kong, M., Lv, W., Ali, T., Sarwar, R., Yu, C., Qiu, Y., Qu, F., Xu, Z., Han, J. and Xu, J., 2017. 10-m 9.51-Gb/s RGB laser diodes-based WDM underwater wireless optical communication. Optics Express, 25(17), pp.20829-20834.
[13] Kong, M., Wang, J., Chen, Y., Ali, T., Sarwar, R., Qiu, Y., Wang, S., Han, J. and Xu, J., 2017. Security weaknesses of underwater wireless optical communication. Optics Express, 25(18), pp.21509-21518.
[14] Alkhazragi, O., Dong, M., Chen, L., Kong, M., Melinte, G., Liang, D., Ng, T. K., Zhang, J., Bagci, H., and Ooi, B. S. 2023. Chaotic-cavity surface-emitting lasers for optical wireless communication and low-speckle illumination. APL Photonics, 8(8).
[17] Guo, Y., Kong, M., Sait, M., Marie, S., Alkhazragi, O., Ng, T. K., and Ooi, B. S., 2022. Compact scintillating-fiber/450-nm-laser transceiver for full-duplex underwater wireless optical communication system under turbulence. Optics Express, 30(1), 53-69.
[31] Kang, C.H., Alkhazragi, O., Sinatra, L., Alshaibani, S., Wang, Y., Li, K.H., Kong, M., Lutfullin, M., Bakr, O.M., Ng, T.K. and Ooi, B.S., 2022. All-inorganic halide-perovskite polymer-fiber-photodetector for high-speed optical wireless communication. Optics Express, 30(6), pp.9823-9840.
[28] Sait, M., Guo, Y., Alkhazragi, O., Kong, M., Ng, T. K., & Ooi, B. S., 2021. The impact of vertical salinity gradient on non-line-of-sight underwater optical wireless communication. IEEE Photonics Journal, 13(6), 1-9.
[29] Tankimanova, A., Kang, C.H., Alkhazragi, O., Tang, H., Kong, M., Sinatra, L., Lutfullin, M., Li, D., Ding, S., Xu, B. and Bakr, O., 2021. Colloidal PbS quantum dots for visible-to-near-infrared optical-internet-of-things. IEEE Photonics Journal.
[14] (Invited) Ooi, B.S., Kong, M. and Ng, T.K., 2020. Underwater wireless optical communications: Opportunity, challenges and future prospects commentary on Recent progress in and perspectives of underwater wireless optical communication. Progress in Quantum Electronics, 73, pp.100275.
[18] Guo, Y., Kong, M., Alkhazragi, O., Sun, X., Sait, M., Ng, T.K. and Ooi, B.S., 2020. Diffused-line-of-sight communication for mobile and fixed underwater nodes. IEEEPhotonics Journal.
[19] Sun, X., Kong, M., Telegenov, K, Ouhssain, M., Sait, M., Guo, Y., Alkhazragi, O., Jones, B.H., Shamma, J.S., Ng, T.K. and Ooi, B.S., 2020. Field demonstrations of wide-beam optical communication through water–air interface.IEEE Access, 8, pp.160480-160489.
[20] Sun, X., Kong, M., Alkhazragi, O., Shen, C., Ooi, E.N., Zhang, X., Buttner, U., Ng, T.K. and Ooi, B.S., 2020. Non-line-of-sight methodology for high-speed wireless optical communication in highly turbid water. Optics Communications, pp.125264.
[24] Alkhazragi, O., Kang, C.H., Kong, M., Liu, G., Lee, C., Li, K.H., Zhang, H., Wagstaff, J.M., Alhawaj, F., Ng, T.K. and Speck, J.S., 2020. 7.4-Gbit/s visible-light communication utilizing wavelength-selective semipolar micro-photodetector. IEEE Photonics Technology Letters, 32(13), pp.767-770.
[25] Sun, X., Kang, C.H., Kong, M., Alkhazragi, O., Guo, Y., Ouhssain, M., Weng, Y., Jones, B.H., Ng, T.K. and Ooi, B.S., 2020. A review on practical considerations and solutions in underwater wireless optical communication. Journal of Lightwave Technology, 38(2), pp.421-431.
[21] Sun, X., Kong, M., Shen, C., Kang, C.H., Ng, T.K. and Ooi, B.S., 2019. On the realization of across wavy water-air-interface diffuse-line-of-sight communication based on an ultraviolet emitter. Optics Express, 27(14), pp.19635-19649.
[30] Kang, C.H., Dursun, I., Liu, G., Sinatra, L., Sun, X., Kong, M., Pan, J., Maity, P., Ooi, E.N., Ng, T.K. and Mohammed, O.F., 2019. High-speed colour-converting photodetector with all-inorganic CsPbBr 3 perovskite nanocrystals for ultraviolet light communication. Light: Science & Applications, 8(1), pp.1-12.
[33] Sait, M., Sun, X., Alkhazragi, O., Alfaraj, N., Kong, M., Ng, T.K. and Ooi, B.S., 2019. The effect of turbulence on NLOS underwater wireless optical communication channels. Chinese Optics Letters, 17(10), p.100013.
[32] Shen, J., Wang, J., Chen, X., Zhang, C., Kong, M., Tong, Z. and Xu, J., 2018. Towards power-efficient long-reach underwater wireless optical communication using a multi-pixel photon counter. Optics Express, 26(18), pp.23565-23571.
[15] Xu, J., Kong, M., Lin, A., Song, Y., Han, J., Xu, Z., Wu, B., Gao, S. and Deng, N., 2017. Directly modulated green-light diode-pumped solid-state laser for underwater wireless optical communication. Optics Letters, 42(9), pp.1664-1667.
[22] Chen, Y., Kong, M., Ali, T., Wang, J., Sarwar, R., Han, J., Guo, C., Sun, B., Deng, N. and Xu, J., 2017. 26 m/5.5 Gbps air-water optical wireless communication based on an OFDM-modulated 520-nm laser diode. Optics Express, 25(13), pp.14760-14765.
[23] Xu, J., Sun, B., Kong, M., Lin, A., Sarwar, R., Han, J., Zhang, W. and Deng, N., 2017. Underwater wireless optical communication using a blue-light leaky feeder. Optics Communications, 397, pp.51-54.
[26] Xu, J., Sun, B., Lyu, W., Kong, M., Sarwar, R., Han, J., Zhang, W. and Deng, N., 2017. Underwater fiber–wireless communication with a passive front end. Optics Communications, 402, pp.260-264.
[16] Xu, J., Kong, M., Lin, A., Song, Y., Yu, X., Qu, F., Han, J. and Deng, N., 2016. OFDM-based broadband underwater wireless optical communication system using a compact blue LED. Optics Communications, 369, pp.100-105.
[27] Xu, J., Lin, A., Yu, X., Kong, M., Song, Y., Qu, F., Han, J., Jia, W. and Deng, N., 2016. High-speed underwater wireless optical communication using a compact OFDM-modulated green laser diode. IEEE Photonics Technology Letters, 28(20), pp.2133-2136.
[34] Xu, J., Song, Y., Yu, X., Lin, A., Kong, M., Han, J. and Deng, N., 2016. Underwater wireless transmission of high-speed QAM-OFDM signals using a compact red-light laser. Optics Express, 24(8), pp.8097-8109.
[35] Xu, J., Lin, A., Yu, X., Song, Y., Kong, M., Qu, F., Han, J., Jia, W. and Deng, N., 2016. Underwater laser communication using an OFDM-modulated 520-nm laser diode. IEEE Photonics Technology Letters, 28(20), pp.2133-2136.
[1] Wang, X., Zhou, H., Le, X., Ding, J., Tao, H., Cheng, L., Chen, W., Wang, R., Yang, Q., Chen, C., Kong, M.*, 2024. Generative adversarial network with lightweight U-Net for underwater optical image enhancement. 12th International Conference on Intelligent Computing and Wireless Optical Communications (ICWOC).
[2] Cheng, L., Zhou, H., Le, X., Chen, W., Tao, H., Ding, J., Wang, X., Wang, R., Yang, Q., Chen, C., Kong, M.*, 2024. An improved underwater object detection algorithm based on YOLOv5 for blurry images. 12th International Conference on Intelligent Computing and Wireless Optical Communications (ICWOC).
[3] Zhou, H., Wang, X., Chen, R., Lu, W., Cheng, L., Su, Q., Wang, R., Yang, Q., Kong, M.*, 2023. Research on underwater target detection technology based on deep learning.3rd International Conference on Robotics, Automation and Intelligent Control, 178-182.
[4] (Invited) Kong, M., Yuan H., Yang Q., Ng, T.K. and Ooi, B.S., 2022. Optical wireless communication-based 2K real-time video surveillance system for future underwater visual monitoring. SPIE, 12706, 92-96.
[5] Kong, M., Guo, Y., Sait, M., Alkhazragi, O., Kang, C.H., Ng, T.K. and Ooi, B.S., 2022, March. Underwater optical wireless sensor network for real-time underwater environmental monitoring. SPIE, 12028, 82-86.
[6] Kong, M., Holguin-Lerma, J.A., Alkhazragi, O., Sun, X., Ng, T.K. and Ooi, B.S., 2020, March. 10-Gbit/s Sky-blue distributed feedback laser diode-based visible light communication. Optical Fiber Communications Conference and Exhibition (OFC). IEEE, 1-3.(EI Index, 该会议论文目前被Compound Semiconductor Magazine邀请写了一篇Feature,题目为 Lasers: Accelerating visible light communication “GaN-based single-mode lasers get ready to revolutionise communication”)
[7] Kong, M., Chen, Y., Sarwar, R., Sun, B., Cong, B. and Xu, J., 2017, August. Optical superimposition-based PAM-4 signal generation for visible light communication. In 2017 16th International Conference on Optical Communications and Networks (ICOCN). IEEE, 1-3.
[8] Kong, M., Tong, Z., Yu, X., Song, Y., Lin, A. and Xu, J., 2016. Airborne wireless optical communication system in low altitude using an unmanned aerial vehicle and LEDs. In Journal of Physics: Conference Series. IOP Publishing, 679(1), 012031.
[9] Sarwar, R., Sun, B., Kong, M.*, Ali, T., Yu, C., Cong, B. and Xu, J., 2017, August. Visible light communication using a solar-panel receiver. In 2017 16th International Conference on Optical Communications and Networks (ICOCN). IEEE, 1-3.
[10] Xu, J., Zhang, C., Kong, M.*, Sun, B., Wang, J. and Cong, B., 2017, August. On the characteristicsof a directly-modulated green-light diode pump solid state laser. In 2017 16th International Conference on Optical Communications and Networks (ICOCN). IEEE, 1-3.
[11] Kang, C. H., Alkhazragi, O., Sinatra, L., Alshaibani, S., Wang, Y., Li, K. H., Kong, M., Lutfullin, M., Bakr, O. M., Ng, T.K. and Ooi, B. S. (2022, March). Wide-field-of-view perovskite quantum-dots fibers array for easing pointing, acquisition and tracking in underwater wireless optical communication. In 2022 Optical Fiber Communications Conference and Exhibition (OFC) (pp. 1-3). IEEE.
[12] Guo, Y., Marie, S., Kong, M., Sait, M. and Ng, T.K., and Ooi, B.S., 2022, March. Underwater turbulence on scintillating-fiber based omnidirectional underwater wireless optical communication system. In Proc. of SPIE Vol (Vol. 12028, pp. 120280D-1).
[13] Kang, C. H., Alkhazragi, O., Sinatra, L., Alshaibani, S., Li, K. H., Kong, M., Lutfullin M., Bakr O. M., Ng, T.K., and Ooi, B. S. 2021. All-inorganic halide-perovskite-polymer luminescent fibers for high-bitrate ultraviolet free-space optical communication. In 2021 IEEE Photonics Conference (IPC) (pp. 1-2). IEEE.
[14] Hu, F., Holguin-Lerma, J.A., Mao, Y., Shen, C., Sun, X., Kong, M., Ng, T.K., Ooi, B.S. and Chi, N., 2020, January. 3.8-Gbit/s visible light communication (VLC) based on 443-nm superluminescent diode and bit-loading discrete-multiple-tone (DMT) modulation scheme. In Broadband Access Communication Technologies XIV (Vol. 11307, p. 113070H). International Society for Optics and Photonics.
[15] Kang, C.H., Dursun, I., Liu, G., Sinatra, L., Sun, X., Kong, M., Pan, J., Maity, P., Ooi, E.N., Ng, T.K. and Mohammed, O.F., 2019, November. High-speed ultraviolet-C photodetector based on frequency down-converting CsPbBr 3 perovskite nanocrystals on silicon platform. In 2019 IEEE Photonics Conference (IPC) (pp. 1-2). IEEE.
[16] Yu, C., Kong, M., Sun, B. and Xu, J., 2017, October. Underwater wireless optical communication: A review. In 2017 IEEE/CIC International Conference on Communications in China (ICCC Workshops) (pp. 1-2). IEEE.
[17] Xu, J., Yu, X., Kong, M., Sun, B., Han, J. and Deng, N., 2016, November. Towards broadband long-reach underwater wireless optical communication. In 2016 Asia Communications and Photonics Conference (ACP)(pp. 1-3). IEEE.
[18] Lin, A., Tong, Z., Song, Y., Kong, M. and Xu, J., 2016. Underwater wireless optical communication system using blue LEDs. In Journal of Physics: Conference Series (Vol. 679, No. 1, p. 012032). IOP Publishing.
[19] Song, Y., Tong, Z., Cong, B., Yu, X., Kong, M. and Lin, A., 2016. A combined radio and underwater wireless optical communication system based on buoys. In Journal of Physics: Conference Series (Vol. 679, No. 1, p. 012030). IOP Publishing.
发明专利:
[1] 徐敬、孔美巍、林奥博、宋宇航、徐翔宇、韩军。基于直接调制DPSSL的无线光通信装置及其方法,授权公告号:CN 1063300329 B。
[2] 徐敬、孔美巍、吴景盈、吕伟超、余楚盈。一种基于波分复用技术的水下无线光通信装置及方法,授权公告号CN 107302401 B。
[3] Ooi, B.S, Ng, T.K., Kang, C., Kong, M., Guo, Y, Omnidirectional data and energy harvesting in underwater wireless optical communication, US 11,750,027 B2.
[4] Kong, M., Ooi, B.S. and Ng, T.K., Underwater wireless communication network, Pub. No.: US 2024/0007197 A1.
[5] Kong, M., Ooi, B.S. and Ng, T.K., Autonomous mining system based on real-time digital video communication that uses ethernet and optical technologies, Pub. No.: US 2023/0188212 A1.
[6] Kong, M., Ooi, B.S. and Ng, T.K., Energy autonomous optical wireless communication system, Pub. No.: US 2023/0163638 A1.
教学情况
《海洋光学基础与应用》(独立授课,本科生课程)
《水下通信技术》(独立授课,研究生课程)
《专业导论(理科类)》(部分承担,本科生课程)
《海上专业综合实践》(部分承担,本科生课程)
《计算机海洋应用实习》(部分承担,本科生课程)
《海洋技术导论》(部分承担,本科生课程)
《海洋调查方法与技术》(部分承担,研究生课程)