论文信息 - Theoretical security analysis of two-way fiber time transfer technique based on picosecond resolution simulation model

Theoretical security analysis of two-way fiber time transfer technique based on picosecond resolution simulation model

We build a new two-way fiber time transfer technique (TWFTT) simulation model, and simulate controllable asymmetric attack of delay and attenuation. Both asymmetric attacks can make the clock in the remote module slower by attacking the 1pps signal from local to remote side. Otherwise, the clock will be faster. In this paper, the asymmetric delay attack can linearly control the synchronization error from 0 to 300 ps. The asymmetric attenuation attack can adjust the synchronization error from 0 ~ 302.7 ps with the controllable attenuation from 0 to 2.8 dB. Moreover, we find that the time interval counter change greatly when the system is attacked. The research has a significant meaning in defense of such asymmetric attacks.

Bingjie Xu | Yang Li | Wei Huang | Chenlin Zhang

[1] M. Lukin,et al. Gravitational wave detection with optical lattice atomic clocks , 2016, 1606.01859.

[2] Anne Amy-Klein,et al. High-resolution optical frequency dissemination on a telecommunication network , 2009, 2009 IEEE International Frequency Control Symposium Joint with the 22nd European Frequency and Time forum.

[3] J. Moyne,et al. Smart clocks have a hand in the smart grid , 2011, 2011 IEEE Power and Energy Society General Meeting.

[4] M. Schioppo,et al. Atomic clock performance beyond the geodetic limit , 2018, 1807.11282.

[5] Bo Liu,et al. Simultaneously precise frequency transfer and time synchronization using feed-forward compensation technique via 120 km fiber link , 2015, Scientific reports.

[6] A. Ludlow,et al. Atomic clock performance enabling geodesy below the centimetre level , 2018, Nature.

[7] Wang Hai-yan. Research and Application of Power Grid Time Synchronization System , 2012 .

[8] Tao Wu,et al. Attack monitoring and localization in All-Optical Networks , 2006, Cluster Computing.