1. 胡亮; 吴龟灵; 陈建平; 被动相位补偿光学频率传递链路的中继装置和方法,2020-8-7, 中国,CN202010786516.9.
2. 胡亮; 吴龟灵; 陈建平; 一种用于光学频率传递的前馈相位补偿中继站装置与方法,2020-12-24, 中国,CN202011547745.1.
3. 胡亮; 吴龟灵; 陈建平; 基于电光调制双光梳的时间频率同步装置与同步方法,2020-7-22, 中国,CN202010708628. 2.
4. 胡亮; 吴龟灵; 陈建平; 基于用户端被动相位补偿的光学频率传递装置与传递方法,2020-2-18, 中国,CN202010098975.8.
5. 胡亮; 田雪阳; 吴龟灵; 陈建平; 基于多次反射的分布式光学频率传递装置与传递方法,2020-2-24, 中国,CN202010111641.X.
6. 胡亮; 吴龟灵; 陈建平; 基于环形光纤链路的光学频率传递装置与传递方法,2020-2-25, 中国,CN202010114992.6.
7. 胡亮; 吴龟灵; 陈建平; 基于被动相位补偿的光学频率传递装置与传递方法,2019-12-17, 中国,CN201911298790. 5.
8. 胡亮; 吴龟灵; 陈建平; 基于被动相位补偿的分布式光学频率传递装置与传递方法,2019-12-18, 中国,CN201911306753.4.
9. 胡亮; 吴龟灵; 陆梁军; 周林杰; 刘娇; 金敏慧; 陈建平; 通用型硅基集成光学频率传递芯片,2022-4-11, 中国,CN202210388319.0.
10. 胡亮; 吴龟灵; 刘娇; 金敏慧; 陈建平; 一种光学频率与时间同时传递系统与传递方法,2022-4-8, 中国,CN202210382730.7.
11. Liang Hu; Guiling Wu; Jianping Chen; Optical frequency transfer device based on passive phase compensation and transfer method,2022-8-18,美国,US 17/733,972.
12. 胡亮; 吴龟灵; 刘娇; 金敏慧; 陈建平; 基于时间内插的光纤时间传递系统与传递方法,2022-4-8, 中国,CN202210382791.3.
13. 胡亮; 仇子昂; 李蓉; 吴龟灵; 陈建平; 一种无带外噪声的中继设备及其光学频率传递系统与方法,2022-12-16, 中国,CN202211627535.2.
14. 胡亮; 仇子昂; 李蓉; 吴龟灵; 陈建平; 一种无带外噪声的交替式光学频率传递再生中继系统与方法,2022-12-26, 中国,CN202211626792.4.
15. 胡亮; 王龙; 吴龟灵; 刘娇; 陈建平; 级联光纤微波频率传递系统和传递方法,2021-11-1, 中国,CN202111283493.0.
16. 胡亮; 吴龟灵; 陈建平; 级联的光学频率传递装置和传递方法,2021-6-24, 中国,CN202110701941.8.
17. 胡亮; 王龙; 吴龟灵; 刘娇; 陈建平; 基于延时控制的光学频率传递装置与传递方法,2021-10-29, 中国,CN202111270550.1.
1. X. Zhang, L. Hu, X. Deng, Q. Zang, D. Jiao, J. Gao, D. Wang, Q. Zhou, J. Liu, G. Xu, and T. Liu, Passively stable dissemination of ultrastable optical frequency via a noisy field fiber network. Optics & Laser Technology, 157, p.108738, 2023.
2. L. Hu, R. Xue, X. Cao, J. Liu, K. Wu, G. Wu, and J. Chen, Free-space point-to-multiplepoint optical frequency transfer with lens assisted integrated beam steering. IEEE Transactions on Instrumentation and Measurement, 71, pp.1-10, 2022.
3. X. Zhang, X. Deng, Q. Zang, D. Jiao, J. Gao, D. Wang, Q. Zhou, J. Liu, G. Xu, R. Dong, and T. Liu, Coherent Optical Frequency Transfer via a 490 km Noisy Fiber Link. Chinese Physics Letters, 39(4), p.044201, 2022.
4. Q. Li, L. Hu, J. Zhang, J. Chen, and G. Wu, Multiple-access relay stations for long-haul fiber-optic radio frequency transfer. Optics Express, 30(11), pp.18402-18414, 2022.
5. X. Zhang, L. Hu, X. Deng, Q. Zang, J. Liu, D. Jiao, J. Gao, R. Dong, T. Liu, G. Wu, and J. Chen, All-Passive Cascaded Optical Frequency Transfer. IEEE Photonics Technology Letters, 34(8), pp.413-416, 2022.
6. F. Zuo, Q. Li, K. Xie, L. Hu, J. Chen, and G. Wu, Fiber-optic joint time and frequency transmission with enhanced time precision. Optics Letters, 47(4), pp.1005-1008, 2022.
7. L. Wang, R. Xue, W. Jiao, L. Hu, J. Chen, and G. Wu, Enhanced phase noise reduction in localized two-way optical frequency comparison. Journal of Lightwave Technology, 40(13), pp.4161-4168, 2022.
8. F. Zuo, K. Xie, L. Hu, J. Chen, and G. Wu, 13134-km fiber-optic time synchronization. Journal of Lightwave Technology, 39(20), pp.6373-6380, 2021.
9. F. Zuo, Z. Chen, L. Hu, J. Chen, Y. Jin, and G. Wu, Multiple-node time synchronization over hybrid star and bus fiber network without requiring link calibration. Journal of Lightwave Technology, 39(7), pp.2015-2022, 2021.
10. Q. Li, L. Hu, J. Chen, and G. Wu, Studying the double Rayleigh backscattering noise effect on fiber-optic radio frequency transfer. IEEE Photonics Journal, 13(2), pp.1-10, 2021.
11. L. Hu, R. Xue, X. Tian, G. Wu, and J. Chen, All-passive multiple-place optical phase noise cancellation. Optics Letters, 46(6), pp.1381-1384, 2021.
12. R. Xue, L. Hu, J. Shen, J. Chen, and G. Wu, Branching optical frequency transfer with enhanced post automatic phase noise cancellation. Journal of Lightwave Technology, 39(14), pp.4638-4645, 2021.
13. Q. Li, L. Hu, J. Zhang, J. Chen, and G. Wu, Fiber radio frequency transfer using bidirectional frequency division multiplexing dissemination. IEEE Photonics Technology Letters, 33(13), pp.660-663, 2021.
14. L. Hu, R. Xue, G. Wu, and J. Chen, Performance of digital servos in an optical frequency transfer network. Review of Scientific Instruments, 92(5), p.053709, 2021.
15. L. Hu, X. Tian, G. Wu, and J. Chen, Passive optical phase noise cancellation. Optics Letters, 45(15), pp.4308-4311, 2020.
16. L. Hu, X. Tian, L. Wang, G. Wu, and J. Chen, Passive optical phase stabilization on a ring fiber network. Journal of Lightwave Technology, 38(21), pp.5916-5924, 2020.
17. L. Hu, X. Tian, G. Wu, M. Kong, J. Shen, and J. Chen, Multi-node optical frequency dissemination with post automatic phase correction. Journal of Lightwave Technology, 38(14), pp.3644-3651, 2020.
18. X. Tian, L. Hu, G. Wu, and J. Chen, 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, 2020.
19. L. Hu, E. Wang, L. Salvi, J. N. Tinsley, G. M. Tino, and N. Poli, Sr atom interferometry with the optical clock transition as a gravimeter and a gravity gradiometer. Classical and quantum gravity, 37(1), p.014001, 2019.
20. R. P. del Aguila, T. Mazzoni, L. Hu, L. Salvi, G. M. Tino, and N. Poli, Bragg gravity-gradiometer using the 1S0–3P1 intercombination transition of 88Sr. New Journal of Physics, 20(4), p.043002, 2018.
21. L. Hu, N. Poli, L. Salvi, and G. M. Tino, Atom interferometry with the Sr optical clock transition, Physical Review Letters 119(26), p.263601, 2017(Editors’ Suggestion).