[1] Agrawal G P[M]. Applications of nonlinear fiber optics(2020).

[2] Mamyshev P V, Mamysheva N A. Pulse-overlapped dispersion-managed data transmission and intrachannel four-wave mixing[J]. Optics Letters, 24, 1454-1456(1999).

[3] Johannisson P, Anderson D, Berntson A et al. Generation and dynamics of ghost pulses in strongly dispersion-managed fiber-optic communication systems[J]. Optics Letters, 26, 1227-1229(2001).

[4] Lefrançois M, Barnasson E, Charlet G et al. Numerical discrimination of intrachannel cross-phase modulation and intrachannel four-wave mixing and their respective effect on 40 Gbit/s transmissions[J]. Optics Letters, 31, 432-434(2006).

[5] Striegler A G, Schmauss B. Compensation of intrachannel effects in symmetric dispersion-managed transmission systems[J]. Journal of Lightwave Technology, 22, 1877-1882(2004).

[6] Ip E, Kahn J M. Compensation of dispersion and nonlinear impairments using digital backpropagation[J]. Journal of Lightwave Technology, 26, 3416-3425(2008).

[7] Júnior J H C, Sutili T, Rossi S M et al. Fast adaptive digital back-propagation algorithm for unrepeatered optical systems[C], T4I.2(2020).

[8] Minzioni P, Schiffini A. Unifying theory of compensation techniques for intrachannel nonlinear effects[J]. Optics Express, 13, 8460-8468(2005).

[9] Sackey I, da Ros F, Karl Fischer J et al. Kerr nonlinearity mitigation: mid-link spectral inversion versus digital backpropagation in 5×28-GBd PDM 16-QAM signal transmission[J]. Journal of Lightwave Technology, 33, 1821-1827(2015).

[10] Al-Khateeb M A Z, McCarthy M E, Sánchez C et al. Nonlinearity compensation using optical phase conjugation deployed in discretely amplified transmission systems[J]. Optics Express, 26, 23945-23959(2018).

[11] Yoshima S, Sun Y J, Liu Z X et al. Mitigation of nonlinear effects on WDM QAM signals enabled by optical phase conjugation with efficient bandwidth utilization[J]. Journal of Lightwave Technology, 35, 971-978(2017).

[12] Sackey I, da Ros F, Jazayerifar M et al. Kerr nonlinearity mitigation in 5×28-GBd PDM 16-QAM signal transmission over a dispersion-uncompensated link with backward-pumped distributed Raman amplification[J]. Optics Express, 22, 27381-27391(2014).

[13] Hu H, Jopson R M, Gnauck A H et al. Fiber nonlinearity mitigation of WDM-PDM QPSK/16-QAM signals using fiber-optic parametric amplifiers based multiple optical phase conjugations[J]. Optics Express, 25, 1618-1628(2017).

[14] Ellis A D, Tan M M, Iqbal M A et al. 4 Tb/s transmission reach enhancement using 10×400 Gb/s super-channels and polarization insensitive dual band optical phase conjugation[J]. Journal of Lightwave Technology, 34, 1717-1723(2016).

[15] Umeki T, Kazama T, Sano A et al. Simultaneous nonlinearity mitigation in 92×180-Gbit/s PDM-16QAM transmission over 3840 km using PPLN-based guard-band-less optical phase conjugation[J]. Optics Express, 24, 16945-16951(2016).

[16] Minzioni P, Cristiani I, Degiorgio V et al. Experimental demonstration of nonlinearity and dispersion compensation in an embedded link by optical phase conjugation[J]. IEEE Photonics Technology Letters, 18, 995-997(2006).

[17] Kim I, Vassilieva O, Akasaka Y et al. Enhanced spectral inversion for fiber nonlinearity mitigation[J]. IEEE Photonics Technology Letters, 30, 2040-2043(2018).

[18] Pechenkin V, Fair I J. On four-wave mixing suppression in dispersion-managed fiber-optic OFDM systems with an optical phase conjugation module[J]. Journal of Lightwave Technology, 29, 1678-1691(2011).

[19] Pelusi M D. WDM signal all-optical precompensation of kerr nonlinearity in dispersion-managed fibers[J]. IEEE Photonics Technology Letters, 25, 71-74(2013).

[20] Shao J, Kumar S. Optical backpropagation for fiber-optic communications using optical phase conjugation at the receiver[J]. Optics Letters, 37, 3012-3014(2012).

[21] Watanabe S, Shirasaki M. Exact compensation for both chromatic dispersion and Kerr effect in a transmission fiber using optical phase conjugation[J]. Journal of Lightwave Technology, 14, 243-248(1996).

[22] Liang X J, Kumar S, Shao J. Ideal optical backpropagation of scalar NLSE using dispersion-decreasing fibers for WDM transmission[J]. Optics Express, 21, 28668-28675(2013).

[23] Kaminski P M, da Ros F, Yankov M P et al. Symmetry enhancement through advanced dispersion mapping in OPC-aided transmission[J]. Journal of Lightwave Technology, 39, 2820-2829(2021).

[24] Cao W H. Large predispersion for reduction of intrachannel nonlinear impairments in strongly dispersion-managed transmissions[J]. Optical Fiber Technology, 29, 13-19(2016).

[25] da Ros F, Gajda A, da Silva E P et al. Optical phase conjugation in a silicon waveguide with lateral p-i-n diode for nonlinearity compensation[J]. Journal of Lightwave Technology, 37, 323-329(2019).

[26] Cao W H, Cai W W, Liu C L. Intra-channel nonlinear effects and their suppression in quasi-linear strongly dispersion-managed transmission[J]. Laser & Optoelectronics Progress, 51, 011901(2014).

[27] Cao W H, Wang Y, Liu S H. Dispersion and nonlinearity compensation in optical fiber communication systems by optical phase conjugation incorporated pulse prechirp[J]. Acta Optica Sinica, 32, 0906005(2012).

[28] McCarthy M E, Kahteeb M A Z A, Ferreira F M et al. PMD tolerant nonlinear compensation using in-line phase conjugation[J]. Optics Express, 24, 3385-3392(2016).

[29] Liu C W, Yu J J, Xiong L M et al. Generation and detection of six-fold frequency vector millimeter-wave signal with precoding[J]. Chinese Journal of Lasers, 48, 0906006(2021).

[30] Meng J Y, Zhang H B, Zhang M et al. Fiber nonlinear impairments compensation based on IPCA-DNN algorithm[J]. Acta Optica Sinica, 41, 2406002(2021).

[31] Jiang C P, Zhao F, Wei Y et al. Performance analysis of a multi-band vector millimetre-wave signal probability shaping[J]. Laser & Optoelectronics Progress, 58, 2106002(2021).