[1] Xian Feng, Francesco Poletti, Angela Camerlingo, et al. Optical fiber technology. Dispersion controlled highly nonlinear fibers for all-optical processing at telecoms wavelengths. Optical Fiber Technology, 16, 378-391(2010).

[2] T X Huang, Xiaoke Yi, Robert Minasian. Single passband microwave photonic filter using continuous-time impulse response. Optics Express, 19, 6231-6242(2011).

[3] Sanghoon Chin, Luc Thévenaz, Juan Sancho, et al. Broadband true time delay for microwave signal processing, using slow light based on stimulated Brillouin scattering in optical fibers. Optics Express, 18, 22599-22613(2010).

[4] Z Cao, R Lu, Q Wang, et al. Cyclic additional optical true time delay for microwave beam steering with spectral filtering. Optics Letters, 39, 3402-3405(2014).

[5] K Thyagarajan, B P Pal. Modeling dispersion in optical fibers: Applications to dispersion tailoring and dispersion compensation. Journal of Optical, Reports Fiber Communications, 4, 173-213(2007).

[6] Byung Min Jung, Jianping Yao. A two-dimensional optical true time-delay beamformer consisting of a fiber Bragg grating prism and switch-based fiber-optic delay lines. IEEE Photonics Technology Letters, 21, 627-629(2009).

[7] Lingjun Jiang, Zhaoran Huang. Integrated cascaded bragg gratings for on-chip optical delay lines. IEEE Photonics Technology Letters, 30, 499-502(2018).

[8] Valeria Maselli, Jason R Grenier, Stephen Ho, et al. Femtosecond laser written optofluidic sensor: Bragg grating waveguide evanescent probing of microfluidic channel. Optics Express, 17, 11719-11729(2009).

[9] Zhenmin Du, Chao Xiang, Tingzhao Fu, et al. Silicon nitride chirped spiral Bragg grating with large group delay. APL Photonics, 5, 101302(2020).

[10] Mark Kuznetsov, H Haus. Radiation loss in dielectric waveguide structures by the volume current method. IEEE Journal of Quantum Electronics, 19, 1505-1514(1983).

[11] R Baets, P E Lagasse. Loss calculation and design of arbitrarily curved integrated-optic waveguides. JOSA, 73, 177-182(1983).

[12] C J Chung, X Xu, G Wang, et al. On-chip optical true time delay lines featuring one-dimensional fishbone photonic crystal waveguide. Applied Physics Letters, 112, 071104(2018).

[13] I Giuntoni, D Stolarek, D I Kroushkov, et al. Continuously tunable delay line based on SOI tapered Bragg gratings. Optics Express, 20, 11241(2012).

[14] N Ishikura, R Hosoi, R Hayakawa, et al. Photonic crystal tunable slow light device integrated with multi-heaters. Applied Physics Letters, 100, 65(2012).

[15] H Lee, T Chen, J Li, et al. Ultra-low-loss optical delay line on a silicon chip. Nature Communications, 3, 1-7(2012).

[16] R L Moreira, J W Garcia, Barton J S Bauters, et al. Integrated ultra-low-loss 4-bit tunable delay for broadband phased array antenna applications. Photonics Technology Letters, IEEE, 25, 1165-1168(2013).

[17] F Morichetti, A Melloni, A Breda, et al. A reconfigurable architecture for continuously variable optical slow-wave delay lines. Optics Express, 15, 17273(2007).

[18] M S Rasras, C K Madsen, M A Cappuzzo. Integrated resonance-enhanced variable optical delay lines. IEEE Photonics Technology Letters, 17, 834-836(2005).

[19] W Shi, V Veerasubramanian, D Patel, et al. Tunable nanophotonic delay lines using linearly chirped contradirectional couplers with uniform Bragg gratings. Optics Letters, 39, 701-703(2014).

[20] J Xie, L Zhou, Z Zhi, et al. Continuously tunable reflective-type optical delay lines using microring resonators. Optics Express, 22, 817-823(2014).