胡亮 编委

学术贡献

• 1、[1 ]Qiu, Z., Zhou, Z., Hu, L. *,, Liu, J., Wu, G., Chen, J., Zhang, X., Dong, R., Liu, T. and Zhang, S., 2025.Temperature-induced noise-insensitive laser repeater station for optical frequency transfer. IEEE Transactions on Instrumentation and Measurement , 74, pp.1-11.
• 2、[2] Qiu, Z., Zhou, Z., Zhong, H., Zhao, L., Zhang, H., Hu, L. *,, Wu, G. and Chen, J., 2025. On-chip bidirectional optical frequency shifter for optical frequency transfer. Optics Letters, 50(4), pp.1132-1135.
• 3、[3] Xie, K., Yang, Y., Wang, L., Hu, L., Chen, J. and Wu, G., 2025. Reconfigurable Fiber-Optic Time Transfer Network Architecture Based on SD-TTU. IEEE Internet of Things Journal.
• 4、[4] Xie, K., Zhang, X., Hu, L., Chen, J. and Wu, G., 2024. Fiber-optic time transfer based on bidirectional FDM and cross-correlation processing. IEEE Transactions on Instrumentation and Measurement.
• 5、[5] Ren, J., Hu, L., Chen, J. and Wu, G., 2024. Fiber-optic radio frequency transfer with enhanced frequency stability using fiber Brillouin amplifiers. Optics Express, 32(23), pp.41567-41580.
• 6、[6] Qiu, Z., Li, R., Chen, W., Zhou, Z., Liu, J., Hu, L. *,, Wu, G. and Chen, J., 2024. Nearly-continuous kilometerscale free-space optical frequency comparison in the presence of Doppler shift. IEEE Transactions on Instrumentation and Measurement., 73, pp.1-8.
• 7、[7] Xie, K., Hu, L., Chen, J. and Wu, G., 2024. Integrated optical frequency transfer and optical physical layer key distribution with enhanced link reciprocity detection. Science China Information Sciences, 67(7),p.179303.
• 8、[8] Qiu, Z., Li, R., Hu, L. *,, Wu, G. and Chen, J., 2024. Optically synchronized unidirectional optical amplifierbased coherent optical fiber links. Optics Letters, 49(10), pp.2761-2764.
• 9、[9] Xie, K., Zuo, F., Hu, L., Chen, J. and Wu, G., 2024. Detecting and locating nonreciprocal links based on the correlation of routes in time transfer networks. IEEE Transactions on Instrumentation and Measurement, 73, pp.1-8.
• 10、[10] Xie, K., Zuo, F., Hu, L., Chen, J. and Wu, G., 2024. Joint time and frequency transfer through one International Telecommunication Union 100 GHz wavelength division multiplexing channel with commercial devices. Optics Letters, 49(4), pp.875-878.
• 11、[11] 陈建平, 刘涛，Rahman B. M. A., 胡亮*,, 2024. 高精度光纤时间频率传递及集成化技术 (特邀). Acta Optica Sinica (Online), 1(2), pp.0204001-0204001.
• 12、[12] Li, Q., Hu, L. *, Zhang, J., Chen, J. and Wu, G., 2023. Photonic millimeter-wave transfer with balanced dualheterodyne phase noise detection and cancellation. Optics Express, 31(17), pp.28078-28088.
• 13、[13] Wang, L., Jiao, W., Hu, L., Chen, J. and Wu, G., 2023. Residual timing jitter in the free-space optical twoway time and frequency transfer caused by atmospheric turbulence. Optics & Laser Technology, 163, p.109365.
• 14、[14] Shen, J., Qiu, Z., Xue, R., Hu, L. *, Liu, J., Wu, G., Zhang, X., Deng, X., Dong, R., Liu, T. and Zhang, S., 2023. Multiple-branch optical frequency transfer without the frequency allocation constraints. Journal of Lightwave Technology, 41(17), pp.5529-5537.
• 15、[15] Zhang, X., Hu, L., Deng, X., Zang, Q., Jiao, D., Gao, J., Wang, D., Zhou, Q., Liu, J., Xu, G. and Liu, T., 2023. Passively stable dissemination of ultrastable optical frequency via a noisy field fiber network. Optics & Laser Technology, 157, p.108738.
• 16、[16] 张晋铂, 胡亮*, 李奇, 陈建平，吴龟灵, 2023. 相位自校准的光纤微波频率绝对相位传递. Acta Optica Sinica,52(9), pp.0906001-0906001.
• 17、[17] 付鑫宇, 胡亮*, 周子杰, 陈建平 and 吴龟灵, 2023. 基于单光子探测的高精度长距离光纤双向时间比对. Acta Optica Sinica, 43(13), pp.1306004-1306004.
• 18、[18] Hu, L., Xue, R., Cao, X., Liu, J., Wu, K., Wu, G. and Chen, J., 2022. Free-space point-to-multiplepoint optical frequency transfer with lens assisted integrated beam steering. IEEE Transactions on Instrumentation and Measurement, 71, pp.1-10.
• 19、[19] 印蓉, 胡亮*, 吴龟灵，陈建平, 2022. 基于高 Q 值光纤环形谐振腔的布里渊激光器. Acta Optica Sinica, 42(19), pp.1914002-1914002.
• 20、[20] Wang, L., Xue, R., Jiao, W., Hu, L. *, Chen, J. and Wu, G., 2022. Enhanced phase noise reduction in localized two-way optical frequency comparison. Journal of Lightwave Technology, 40(13), pp.4161-4168.
• 21、[21] Wang, L., Liu, Y., Jiao, W., Hu, L., Chen, J. and Wu, G., 2022. Fast and on-line link optimization for the longdistance two-way fiber-optic time and frequency transfer. Optics Express, 30(14), pp.25522-25535.
• 22、[22] Li, Q., Hu, L. *, Zhang, J., Chen, J. and Wu, G., 2022. Multiple-access relay stations for long-haul fiber-optic radio frequency transfer. Optics Express, 30(11), pp.18402-18414.
• 23、[23] Zhang, X., Hu, L., Deng, X., Zang, Q., Liu, J., Jiao, D., Gao, J., Dong, R., Liu, T., Wu, G. and Chen, J., 2022. Allpassive cascaded optical frequency transfer. IEEE Photonics Technology Letters, 34(8), pp.413-416.
• 24、[24] Zuo, F., Li, Q., Xie, K., Hu, L., Chen, J. and Wu, G., 2022. Fiber-optic joint time and frequency transmission with enhanced time precision. Optics Letters, 47(4), pp.1005-1008.
• 25、[25] Zuo, F., Xie, K., Hu, L., Chen, J. and Wu, G., 2021. 13 134-km fiber-optic time synchronization. Journal of Lightwave Technology, 39(20), pp.6373-6380.
• 26、[26] Xue, R., Hu, L. *, Shen, J., Chen, J. and Wu, G., 2021. Branching optical frequency transfer with enhanced post automatic phase noise cancellation. Journal of Lightwave Technology, 39(14), pp.4638-4645.
• 27、[27] Li, Q., Hu, L. *, Zhang, J., Chen, J. and Wu, G., 2021. Fiber radio frequency transfer using bidirectional frequency division multiplexing dissemination. IEEE Photonics Technology Letters, 33(13), pp.660-663.
• 28、[28] Hu, L. *, Xue, R., Wu, G. and Chen, J., 2021. Performance of digital servos in an optical frequency transfer network. Review of Scientific Instruments, 92(5).
• 29、[29] Hu, L. *, Xue, R., Tian, X., Wu, G. and Chen, J., 2021. All-passive multiple-place optical phase noise cancellation. Optics Letters, 46(6), pp.1381-1384.
• 30、[30] Li, Q., Hu, L. *, Chen, J. and Wu, G., 2021. Studying the double Rayleigh backscattering noise effect on fiber-optic radio frequency transfer. IEEE Photonics Journal, 13(2), pp.1-10.
• 31、[31] Zuo, F., Chen, Z., Hu, L., Chen, J., Jin, Y. and Wu, G., 2020. Multiple-node time synchronization over hybrid star and bus fiber network without requiring link calibration. Journal of Lightwave Technology, 39(7), pp.2015-2022.
• 32、[32] Hu, L. *, Tian, X., Wu, G. and Chen, J., 2020. Passive optical phase noise cancellation. Optics Letters, 45(15), pp.4308-4311.
• 33、[33] Hu, L. *, Tian, X., Wu, G., Kong, M., Shen, J. and Chen, J., 2020. Multi-node optical frequency dissemination with post automatic phase correction. Journal of Lightwave Technology, 38(14), pp.3644-3651.
• 34、[34] Xu, R., Zuo, F., Hu, L., Chen, J. and Wu, G., 2020. High-precision time transfer over a local ring fiber link. Optics Communications, 466, p.125636.
• 35、[35] Hu, L. *, Tian, X., Wang, L., Wu, G. and Chen, J., 2020. Passive optical phase stabilization on a ring fiber network. Journal of Lightwave Technology, 38(21), pp.5916-5924.
• 36、[36] Zuo, F., Chen, Z., Hu, L., Chen, J. and Wu, G., 2020. WDM-based fiber-optic time synchronization without requiring link calibration. IEEE Access, 8, pp.114656-114662.
• 37、[37] Liu, Y., Wu, G., Zhang, H., Zuo, F., Hu, L. and Chen, J., 2020. Multi-access fiber-optic time dissemination with bidirectional optical–electrical–optical nodes. Review of Scientific Instruments, 91(6).
• 38、[38] Tian, X., Hu, L. *, Wu, G. and Chen, J., 2020. Hybrid fiber-optic radio frequency and optical frequency dissemination with a single optical actuator and dual-optical phase stabilization. Journal of Lightwave Technology, 38(16), pp.4270-4278.
• 39、[39] Wang, S., Sun, Y., Hu, L., Chen, J. and Wu, G., 2020. High-speed and broadband digital receiver based on optical sampling pulse waveform matching. Optics Letters, 45(6), pp.1338-1341.
• 40、[40] Shi, P., Wu, G., Hu, L., Li, Q. and Chen, J., 2020. Stable RF transfer over a fiber-optic ring with DSBCS modulation and a DSB RF signal. Chinese Optics Letters, 18(2), p.020603.
• 41、[41] Hu, L., Wang, E., Salvi, L., Tinsley, J.N., Tino, G.M. and Poli, N., 2019. Sr atom interferometry with the optical clock transition as a gravimeter and a gravity gradiometer. Classical and Quantum Gravity, 37(1),p.014001.
• 42、[42] Cheng, H., Wu, G., Zuo, F., Hu, L. and Chen, J., 2019. Time transfer through the optical supervisory channel in wavelength division multiplexing systems. Optics Letters, 44(21), pp.5206-5209.
• 43、[43] del Aguila, R. P., Mazzoni, T., Hu, L., Salvi, L., Tino, G. M. and Poli, N., 2018. Bragg gravity-gradiometer using the 1S0–3P1 intercombination transition of 88Sr. New Journal of Physics, 20(4), p.043002.
• 44、[44] Rosi, G., Viceré, A., Cacciapuoti, L., D'Amico, G., Hu, L., Jain, M., Poli, N., Salvi, L., Sorrentino, F., Wang, E. and Tino, G. M., 2018. Detecting gravitational waves with atomic sensors. IL NUOVO CIMENTO C, 41, pp.130-138.
• 45、[45] Hu, L., Poli, N., Salvi, L. and Tino, G. M., 2017. Atom interferometry with the Sr optical clock transition. Physical Review Letters, 119(26), p.263601.
• 46、[46] Wu, G., Hu, L., Zhang, H. and Chen, J., 2014. High-precision two-way optic-fiber time transfer using an improved time code. Review of Scientific Instruments, 85(11).
• 47、[47] Wu, G., Hu, L., Zhang, H. and Chen, J., 2014. Distributed high-precision time transfer through passive optical networks. Optical Engineering, 53(9), pp.096113-096113.
• 48、[48] Shen, J., Wu, G., Hu, L., Zou, W. and Chen, J., 2014. Active phase drift cancellation for optic-fiber frequency transfer using a photonic radio-frequency phase shifter. Optics Letters, 39(8), pp.2346-2349.