[1] Qin P, Wang S J. Progress in High-precision Distance Measurement based on Optical Frequency Combs(Invited)[J]. Electro-Optic Technology Application, 36, 42-48(2021).

[2] Niu J Y. Research on High Precision Absolute Ranging Method of Optical Frequency Comb[D](2021).

[3] Liu Y, Gao H, Chen Y et al. Full-duplex WDM-RoF System based on OFC with Dual Frequency Microwave Signal Generation and Wavelength Reuse[J]. Optical Fiber Technology, 58, 102252(2020).

[4] Fan Y M, Li P L. Digitally Controlled Microwave Frequency Comb based on Mach-Zehnder Modulator and Pulse Signals[J]. Optical Engineering, 59, 046110(2020).

[5] Ma L S, Bi Z, Bartels A et al. Optical Frequency Synthesis and Comparison with Uncertainty at the 10(-19) Level[J]. Science, 303, 1843-1845(2004).

[6] Buscaino B, Zhang M, Loncar M et al. Design of Efficient Resonator-enhanced Electro-optic Frequency Comb Generators[J]. Journal of Lightwave Technology, 38, 1400-1413(2020).

[7] Zhang T T, Wu S B. Optical Frequency Comb Generation based on Dual-parallel Mach–Zehnder Modulator and Intensity Modulator with RF Frequency Multiplication Circuit[J]. Photonic Network Communications, 36, 256-262(2018).

[8] Yang Y, Ma J, Xin X et al. Optical Frequency Comb Generation Using Two Cascaded Polarization Modulators[J]. Photonic Network Communications, 32, 126-32(2016).

[9] Lu Y, Xing Y, Dong Y. Equal-amplitude Optical Comb Generation Using Multi-frequency Phase Modulation in Optical Fibers[J]. Chinese Optics Letters, 8, 316-319(2010).

[10] Sakamoto T, Kawanishi T, Izutsu M. Asymptotic Formalism for Ultraflat Optical Frequency Comb Generation Using a Mach-Zehnder Modulator[J]. Optics Letters, 32, 1515-1517(2007).

[11] Zhai X M. Generation Scheme and Performance Analysis of Optical Frequency Comb based on External Modulator[D](2018).

[12] Feng S C, Fan Y Y, Chen X Y et al. Design of Multicarrier Optical Source Using Cascaded Electro-absorption Modulator and Phase Modulator[J]. Chinese Journal of Lasers, 43, 194-202(2016).

[13] Han Y S, Lu M T, Zheng J W et al. Design of Flat Multi-carrier Light Source with Adjustable Frequency Spacing[J]. Acta Photonica Sinica, 47, 122-129(2018).

[14] Lin G B. Research on Optical Frequency Comb Generation and Application in WDM System[D](2014).

[15] Mishra A K, Schmogrow R, Tomkos I et al. Flexible RF-based Comb Generator[J]. IEEE Photonics Technology Letters, 25, 701-704(2013).

[16] Zhang A L, He J L. A Dynamic Optical Arbitrary Waveform Generator based on Cross Phase Modulation[J]. Optoelectronics Letters, 12, 101-105(2016).

[17] Shen J, Wu S, Li D. Ultra-flat Optical Frequency Comb Generation based on Phase Modulation with Simple Digital Driving Signal[J]. Optik, 198, 163254(2019).

[18] Xie H L, Jia K X, Chen J W et al. Tunable Optical Frequency Comb based on Coupled Radio Frequency Signal and Single Mach-Zehnder Modulator[J]. Chinese Journal of Lasers, 47, 374-381(2020).

[19] Dong F. Application and Generation of Nyquist Pulses based on Optical Frequency Comb[D](2021).

[20] Shang L, Wen A, Lin G et al. A Flat and Broadband Optical Frequency Comb with Tunable Bandwidth and Frequency Spacing[J]. Optics Communications, 331, 262-266(2014).

[21] Pendiuk G F I, Neves P T, Pohl A A P. Use of a Differential Evolution Algorithm for Determining Input Driving Signals in Optical Frequency Combs[J]. OSA Continuum, 3, 2232-2242(2020).

[22] Pinto T, De Moura U C, Da Ros F et al. Optimization of Frequency Combs Spectral-flatness Using Evolutionary Algorithm[J]. Optics Express, 29, 23447-23460(2021).

[23] Xu D, Luo Y, Luo J et al. Efficient Design of a Dielectric Metasurface with Transfer Learning and Genetic Algorithm[J]. Optical Materials Express, 11, 1852-1862(2021).

[24] Fan C, Yang B, Liu Y et al. Using Deep Learning to Automatically Generate Design Starting Points for Free-form Imaging Optical Systems[J]. Applied Optics, 61, 6241-6248(2022).

[25] Zhang F, Yu H, Fang J et al. Efficient Generation and Tight Focusing of Radially Polarized Beam from Linearly Polarized Beam with All-dielectric Metasurface[J]. Optics Express, 24, 6656-6664(2016).

[26] Luo J, Li X, Zhang X Y et al. Deep-learning-enabled Inverse Engineering of Multi-wavelength Invisibility-to-superscattering Switching with Phase-change Materials[J]. Optics Express, 29, 10527-10537(2021).