2013.09–2018.06：浙江大学，海洋学院，船舶与海洋工程专业（硕士）和海洋信息科学与工程专业（博士），硕博连读

2009.09–2013.06：浙江师范大学，数理与信息工程学院，材料物理专业，本科

2022.02-至今：同济大学，海洋与地球科学学院，研究员

2018.10–2021.10：阿卜杜拉国王科技大学，光电实验室，博士后

研究兴趣

水下无线光通信系统与网络

声-光-射频融合的空天地海一体化通信网络

水下目标探测

无线光能量传输

数字信号处理

图像处理

机器学习

科研项目

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] 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.

[2] 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.

[3] 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.

[4] (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.

[5] 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.

[6] 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.

[7] 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.

[8] 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.

[9] 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.

[10] 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.

[11] 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.

[12] (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.

[13] 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.

[14] 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.

[15] 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.

[16] 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.

[17] 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.

[18] 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.

[19] 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.

[20] 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.

[21] 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.

[22] 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.

[23] 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.

[24] 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.

[25] 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.

[26] 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.

[27] 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.

[28] 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.

[29] 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.

[30] 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.

[31] 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] 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.

[33] 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.

国际会议文章:

[1] (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.

[2] 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.

[3] (Invited) Kong, M., Holguin-Lerma, J.A., C.H., Kang, Alatawi, A.A., Ng, T.K. and Ooi, B.S., 2021, September. Superluminescent diodes and lasers-based visible light communication and lighting: opportunities and challenges. Congress of the International Commission for Optics (ICO) and Conference of International Society on Optics Within Life Sciences (OWLS).

[4] (Invited) Kong, M., Holguin-Lerma, J.A., Alatawi, A.A., C.H., Kang, Ng, T.K. and Ooi, B.S., 2021, June. Laser and superluminescent diodes for lighting and visible light communications. 12th International Conference on Optics-photonics Design & Fabrication (ODF'20).

[5] 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. In Optical Fiber Communication Conference (pp. T3C-3). Optical Society of America. （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”）

[6] 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) (pp. 1-3). IEEE.

[7] 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 (Vol. 679, No. 1, p. 012031). IOP Publishing.

[8] 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).

[9] Kang, C.H., Alkhazragi, O., Sinatra, L., Kong, M., Maity, P., Ng, T.K., Mohammed, O.F., Bakr, O.M. and Ooi, B.S, 2021, March. Enhanced color-conversion photodetection method based on metal halide perovskite nanocrystals for diffuse ultraviolet-C solar-blind communication. SPIE Photonics West 2021.

[10] 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.

[11] (Invited) Stegenburgs, E., Bertoncini, A., Hulguin-Lerma, J.A., Kong, M., Trichili, A., Alkhazragi, O., Sun, X., Alias, M.S., Ng, T.K., Alouini, M., Liberale, C. and Ooi, B.S., 2020, December. Single-frequency visible laser and vertical cavity surface emitting OAM laser for optical wireless communication. Optics & Photonics Taiwan International Conference (OPTIC).

[12] 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.

[13] 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.

[14] 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.

[15] Sarwar, R., Sun, B., Kong, M. （通讯作者）, 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) (pp. 1-3). IEEE.

[16] Xu, J., Zhang, C., Kong, M. （通讯作者）, Sun, B., Wang, J. and Cong, B., 2017, 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.

[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，公开号：CN107302401A。

[3] Kong, M., Ooi, B.S. and Ng, T.K., Fully energy-autonomous optical wireless communication system using switchable hybrid photoreceiver, US 63/023,454, May 12, 2020, PENDING, UNITED STATES.

[4] Kong, M., Ooi, B.S. and Ng, T.K., Underwater wireless sensor network and method based on optical wireless communication technology, US 63/023,458, May 12, 2020, PENDING, UNITED STATES.

[5] Kong, M., Ooi, B.S and Ng, T.K., Real-time digital video transmission system and method based on industrial Ethernet and optical wireless communication technology for coal mine monitoring, US 63/027,244, May 19, 2020, PENDING, UNITED STATES.

[6] Ooi, B.S, Ng, T.K., Kang, C., Kong, M., Guo, Y, Omnidirectional data and energy harvesting in underwater wireless optical communication, US 63/173,152, April 9, 2021, PENDING, UNITED STATES.

教学情况

《水下通信技术》(主讲，研究生课程)

《海洋调查方法与技术》(部分承担，研究生课程)

《海洋技术导论》(部分承担，本科生课程)

学术期刊任职

2022.11至今：担任Sensors期刊的Guest Editor

2022.03至今：担任Frontiers in Communications and Networks期刊的Guest Editor

2020.05至今：担任Optical Communications and Networks期刊的Review Editor

2018.01至今：多次担任Photonics Research, Scientific Reports, Optics Letters, Optics Express, Sensors, IEEE Journal of Oceanic Engineering, IEEE Photonics Journal, IEEE Photonics Technology Letters, Applied Optics, Marine Technology Society Journal等期刊的审稿人

学术组织任职

IEEE、OSA、SPIE 会员

2022年：Outstanding reviewer of Journal of Oceanic Engineering

2021年：Outstanding reviewer of Journal of Oceanic Engineering