[1] Peng H T, Wang J, Ma C et al. Arbitrary waveform generation of enhanced high-order harmonics based on injection locking[J]. Acta Optica Sinica, 40, 0419001(2020).

[2] Rashidinejad A, Weiner A M. Photonic radio-frequency arbitrary waveform generation with maximal time-bandwidth product capability[J]. Journal of Lightwave Technology, 32, 3383-3393(2014).

[3] Zhang F Z, Ge X Z, Pan S L. Triangular pulse generation using a dual-parallel Mach-Zehnder modulator driven by a single-frequency radio frequency signal[J]. Optics Letters, 38, 4491-4493(2013).

[4] Gao B D, Zhang F Z, Pan S L. Experimental demonstration of arbitrary waveform generation by a 4-bit photonic digital-to-analog converter[J]. Optics Communications, 383, 191-196(2017).

[5] Liao J X, Wen H, Zheng X P et al. A time-domain photonic arbitrary waveform generator[J]. Optics Express, 20, 12631-12639(2012).

[6] Ding J F, Zhang F F, Zhu W W et al. Optical digital to analog converter based on microring switches[J]. IEEE Photonics Technology Letters, 26, 2066-2069(2014).

[7] Yang Z H, Jiang M Z, Liu Y C et al. Tunable-bandwidth terahertz polarization converter based on a vanadium dioxide hybrid metasurface[J]. Chinese Journal of Lasers, 48, 1714001(2021).

[8] Li J Y. Telecom-wavelength-transparent Ge-Sb-Se-Te nonvolatile optical phase change materials and devices[D](2018).

[9] Pernice W H P, Bhaskaran H. Photonic non-volatile memories using phase change materials[J]. Applied Physics Letters, 101, 171101(2012).

[10] Lü Y S, Wang C G, Yuan W et al. Reconfigurable mode multiplexer waveguide switch based on phase change material[J]. Acta Optica Sinica, 41, 1723001(2021).

[11] Delaney M, Zeimpekis I, Lawson D et al. A new family of ultralow loss reversible phase-change materials for photonic integrated circuits: Sb2S3 and Sb2Se3[J]. Advanced Functional Materials, 30, 2002447(2020).

[12] Yan S[M]. Fundamentals of digital electronic technology, 507-510(2006).

[13] Bogaerts W, de Heyn P, van Vaerenbergh T et al. Silicon microring resonators[J]. Laser & Photonics Reviews, 6, 47-73(2012).

[14] Guo P X, Hou W G, Guo L et al. Potential threats and possible countermeasures for photonic network-on-chip[J]. IEEE Communications Magazine, 58, 48-53(2020).

[15] Hou W G, Guo P X, Guo L et al. O-star: an optical switching architecture featuring mode and wavelength-division multiplexing for on-chip many-core systems[J]. Journal of Lightwave Technology, 40, 24-36(2022).

[16] Ríos C, Stegmaier M, Hosseini P et al. Integrated all-photonic non-volatile multi-level memory[J]. Nature Photonics, 9, 725-732(2015).

[17] Ali N, Panepucci R R, Xie Y W et al. Electrically controlled 1 × 2 tunable switch using a phase change material embedded silicon microring[J]. Applied Optics, 60, 3559-3568(2021).

[18] Chakraborty I, Saha G, Roy K. Photonic in-memory computing primitive for spiking neural networks using phase-change materials[J]. Physical Review Applied, 11, 014063(2019).

[19] IEEE. IEEE standard for terminology and test methods of digital-to-analog converter devices[EB/OL]. https://ieeexplore.ieee.org/document/6152113

[20] Liu X, Chen H M, Hu Y C. An integrated device for photonic-crystal electro-optic modulation and coarse wavelength-division multiplexing[J]. Chinese Journal of Lasers, 48, 0306002(2021).

[21] Zhang Q, Yu H, Fu Z L et al. Improving the linearity of silicon ring modulators by manipulating the photon dynamics[J]. IEEE Photonics Journal, 12, 19523371(2020).

[22] Nikolova D, Calhoun D M, Liu Y et al. Modular architecture for fully non-blocking silicon photonic switch fabric[J]. Microsystems & Nanoengineering, 3, 16071(2017).

[23] Huang H, Heilmeyer J, Grözing M et al. An 8-bit 100-GS/s distributed DAC in 28-nm CMOS for optical communications[J]. IEEE Transactions on Microwave Theory and Techniques, 63, 1211-1218(2015).

[24] Okada T, Kobayashi R, Rui W et al. Photonic digital-to-analog conversion using a blue frequency chirp in a semiconductor optical amplifier[J]. Optics Letters, 45, 1483-1486(2020).

[25] Yang S N, Hu M, Chi H et al. Photonic digital-to-analog conversion based on wavelength multiplexing[J]. Optics Communications, 401, 1-5(2017).

[26] Zhang T H, Qiu Q, Su J et al. Optical assisted digital-to-analog conversion using dispersion-based wavelength multiplexing[J]. Optics Communications, 432, 44-48(2019).