Prossotowicz M, Heimes A, Flamm D, Jansen F, Otto H, Budnicki A, Killi A, Morgner U (2020) Coherent beam combining with micro-lens arrays. Opt Lett 45:6728–6731

Harish AV, Nilsson J (2015) Optimization of phase modulation with arbitrary waveform generators for optical spectral control and suppression of stimulated Brillouin scattering. Opt Express 23:6988–6999

Ng AY, Coates A, Diel M, Ganapathi V, Schulte J, Tse B, Berger E, Liang E (2006) Autonomous inverted helicopter flight via reinforcement learning. In Experimental robotics IX. Springer, Berlin, Heidelberg, pp 363–372

Stiles E (2009) New developments in IPG fiber laser technology. In: Proceedings of the 5th international workshop on fiber lasers

Zhou P, Xiao H, Leng J, Xu J, Chen Z, Zhang H, Liu Z (2017b) High-power fiber lasers based on tandem pumping. J Opt Soc Am B 34:A29–A36

Bruesselbach H, Wang S, Minden M, Jones DC, Mangir M (2005b) Power-scalable phase-compensating fiber-array transceiver for laser communications through the atmosphere. J Opt Soc Am B 22:347–353

Song J, Li Y, Che D, Guo J, Wang T (2020) Coherent beam combining based on the SPGD algorithm with a momentum term. Optik 202:163650

Kono Y, Takeoka M, Uto K, Uchida A, Kannari F (2000) A coherent all-solid-state laser array using the Talbot effect in a three-mirror cavity. IEEE J Quantum Electron 36:607–614

Poulton CV, Byrd MJ, Russo P, Timurdogan E, Khandaker M, Vermeulen D, Watts MR (2019) Long-range LiDAR and free-space data communication with high-performance optical phased arrays. IEEE J Sel Top Quantum Electron 25:1–8

Augst SJ, Fan TY, Sanchez A (2004) Coherent beam combining and phase noise measurements of ytterbium fiber amplifiers. Opt Lett 29:474–476

Thielen PA, Ho JG, Burchman DA, Goodno GD, Rothenberg JE, Wickham MG, Flores A, Lu CA, Pulford B, Robin C, Sanchez AD, Hult D, Rowland KB (2012) Two-dimensional diffractive coherent combining of 15 fiber amplifiers into a 600 W beam. Opt Lett 37:3741–3743

Li X, Xiao H, Dong X, Ma Y, Xu X (2011) Coherent beam combining of two slab laser amplifiers and second-harmonic phase locking based on a multi-dithering technique. Chin Phys Lett 28:094210

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Optical filters play a crucial yet often overlooked role in semiconductor manufacturing, where nanoscale precision can make or break a product.

Ma Y, Wang X, Leng J, Xiao H, Dong X, Zhu J, Du W, Zhou P, Xu X, Si L, Liu Z, Zhao Y (2011a) Coherent beam combination of 1.08 kW fiber amplifier array using single frequency dithering technique. Opt Lett 36:951–953

Billaud A, Gomez F, Allioux D, Laurenchet N, Jian P, Pinel O, Labroille G (2020) Optimal coherent beam combining based on Multi-Plane Light Conversion for high throughput optical feeder links (conference presentation). In: Proceedings of SPIE 11272,free-space laser communications XXXII

White JO, Young JT, Wei C, Hu J, Menyuk CR (2019) Seeding fiber amplifiers with piecewise parabolic phase modulation for high SBS thresholds and compact spectra. Opt Express 27:2962–2974

Zhou P, Liu Z, Wang X, Ma Y, Ma H, Xu X, Guo S (2009) Coherent beam combining of fiber amplifiers using stochastic parallel gradient descent algorithm and its application. IEEE J Sel Top Quantum Electron 15:248–256

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Ayyaswamy P, Linslal CL, Dixit A, Venkitesh D, Srinivasan B (2021) Data-driven modeling of phase noise sources in coherent beam combining. In: Laser applications conference, OSA laser congress

Tünnermann H, Pöld JH, Neumann J, Kracht D, Willke B, Weßels P (2011) Beam quality and noise properties of coherently combined ytterbium doped single frequency fiber amplifiers. Opt Express 19:19600–19606

Qiu Y, Xie Y, Wang W, Liu W, Kuang L, Bai X, Hu M, Ho J (2019) Ultra-high-power and high-efficiency 905 nm pulsed laser for LiDAR. In: 2019 IEEE 4th optoelectronics global conference (OGC), pp 32–35

Panbiharwala Y, Harish AV, Feng Y, Venkitesh D, Nilsson J, Srinivasan B (2021) Stimulated Brillouin scattering mitigation using optimized phase modulation waveforms in high power narrow linewidth Yb-doped fiber amplifiers. Opt Express 29:17183–17200

Hansryd J, Dross F, Westlund M, Andrekson PA, Knudsen SN (2001) Increase of the SBS threshold in a short highly nonlinear fiber by applying a temperature distribution. J Light Technol 19:1691–1697

Wang D, Du Q, Zhou T, Li D, Wilcox R (2021) Stabilization of the 81-channel coherent beam combination using machine learning. Opt Express 29:5694–5709

Bai Y, Lei G, Chen H, Feng X, Li D, Bai J (2019) Incoherent space beam combining of fiber-transmitted semiconductor lasers for oil well laser perforation. IEEE Access 7:154457–154465

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Redmond SM, Ripin DJ, Yu CX, Augst SJ, Fan TY, Thielen PA, Rothenberg JE, Goodno GD (2012) Diffractive coherent combining of a 2.5 kW fiber laser array into a 1.9 kW Gaussian beam. Opt Lett 37:2832–2834

Honea E, Afzal RS, Savage-Leuchs M, Henrie J, Brar K, Kurz N, Jander D, Gitkind N, Hu D, Robin C, Jones AM, Kasinadhuni R, Humphreys R (2016) Advances in fiber laser spectral beam combining for power scaling. In: Proceedings ’components and packaging for laser systems II’, vol 9730

In the dynamic landscape of rapid product development, transforming ideas into prototypes swiftly is essential across diverse applications.

Jiang M, Su R, Zhang Z, Ma Y, Wang X, Zhou P (2017) Coherent beam combining of fiber lasers using a CDMA-based single-frequency dithering technique. Appl Opt 56:4255–4260

Jones DC, Turner AJ, Scott AM, Stone SM, Clark RG, Stace C, Stacey CD (2010) A multi-channel phase locked fibre bundle laser. In: Proceedings of SPIE 7580, fiber lasers VII: technology, systems, and applications, 75801V (17 February)

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Liu Z, Ma P, Su R, Tao R, Ma Y, Wang X, Zhou P (2017) High-power coherent beam polarization combination of fiber lasers: progress and prospect [Invited]. J Opt Soc Am B 34:A7–A14

Zhi D, Zhang Z, Ma Y, Wang X, Chen Z, Wu W, Zhou P, Si L (2017) Realization of large energy proportion in the central lobe by coherent beam combination based on conformal projection system. Sci Rep 7:2199

Augst SJ, Ranka JK, Fan TY, Sanchez A (2007) Beam combining of ytterbium fiber amplifiers (Invited). J Opt Soc Am B 24:1707–1715

Jauregui C, Eidam T, Limpert J, Tünnermann A (2011a) Impact of modal interference on the beam quality of high-power fiber amplifiers. Opt Express 19:3258–3271

Poulton CV, Yaacobi A, Cole DB, Byrd MJ, Raval M, Vermeulen D, Watts MR (2017) Coherent solid-state LIDAR with silicon photonic optical phased arrays. Opt Lett 42:4091–4094

Hou T, Chang Q, Chang H, Liu W, Ma P, Su R, Ma Y, Zhou P (2020) Structuring orbital angular momentum beams by coherent laser array systems with tip-tilt optimization. Results Phys 19:103602

Cao J, Zhao X, Liu W, Gu H (2017) Performance analysis of a coherent free space optical communication system based on experiment. Opt Express 25:15299–15312

Wang M, Liu L, Wang Z, Xi X, Xu X (2019) Mitigation of stimulated Raman scattering in kilowatt-level diode-pumped fiber amplifiers with chirped and tilted fiber Bragg gratings. High Power Laser Sci Eng 7

Fan X, Liu J, Liu J, Wu J (2010) Coherent combining of a seven-element hexagonal fiber array. Opt Laser Technol 42:274–279

Lombard L, Canat G, Durecu A, Bourdon P (2014) Coherent beam combining performance in harsh environment. In: Proceedings of SPIE 8961, fiber lasers XI: technology, systems, and applications, 896107 (12 March)

Dixit A, Sooraj MS, Linslal CL, Padmanabhan A, Venkitesh D, Srinivasan B (2021) Experimental validation of free-space coherent beam combining simulations for filled aperture configuration. In: Conference on lasers and electro-optics (CLEO 2021), OSA technical digest (Optical Society of America)

Linslal CL, Sooraj MS, Panbiharwala Y, Padmanabhan A, Dixit A, Venkitesh D, Srinivasan B (2019) Investigation of line broadening scheme dependence on coherent beam combination efficiency. In Laser congress 2019 (ASSL, LAC, LS&C), OSA technical digest (Optical Society of America)

Shiner B (2013) The impact of fiber laser technology on the world wide material processing market. In: Proceedings of the CLEO, OSA, San Jose, CA, USA, p AF2J.1

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Sumida DS, Jones DC, Rockwell DA (1994) An 8.2 J phase-conjugate solid-state laser coherently combining eight parallel amplifiers. IEEE J Quantum Electron 30:2617–2627

State-of-the-art equipment ensures the quality of optical components by conducting in-house testing for imaging performance.

Experienced in serving the scientific, biomedical, and photonics communities we know how to design and deliver optical filters.

Mnih V, Kavukcuoglu K, Silver D, Graves A, Antonoglou I, Wierstra D, Riedmiller M (2013) Playing Atari with deep reinforcement learning. arXiv preprint arXiv:1312.5602

Carlson NW, Evans GA, Hammer JM, Lurie M, Palfrey SL, Dholakia A (1987) Phase-locked operation of a grating-surface-emitting diode laser array. Appl Phys Lett 50:1301–1303

Yu CX, Augst SJ, Redmond SM, Goldizen KC, Murphy DV, Sanchez A, Fan TY (2011) Coherent combining of a 4 kW, eight-element fiber amplifier array. Opt Lett 36:2686–2688

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Wang X, Ma Y, Zhou P, He B, Xiao H, Xue Y, Liu C, Li Z, Xu X, Zhou J, Liu Z, Zhao Y (2011) Coherent beam combining of 137W 2×2 fiber amplifier array. Opt Commun 284:2198–2201

Geng C, Luo W, Tan Y, Liu H, Mu J, Li X (2013) Experimental demonstration of using divergence cost-function in SPGD algorithm for coherent beam combining with tip/tilt control. Opt Express 21:25045–25055

Uberna R, Bratcher A, Alley TG, Sanchez AD, Flores AS, Pulford B (2010) Coherent combination of high power fiber amplifiers in a two-dimensional re-imaging waveguide. Opt Express 18:13547–13553

Linslal, C.L., Ayyaswamy, P., Maji, S. et al. Challenges in coherent beam combining of high power fiber amplifiers: a review. ISSS J Micro Smart Syst 11, 277–293 (2022). https://doi.org/10.1007/s41683-022-00099-4

Yu-Hao X, Bing H, Jun Z, Zhen L, Yuan-Yuan F, Yun-Feng Q, Chi L, Zhi-Jun Y, Hai-Bo Z, Qi-Hong L (2011) High power passive phase locking of four Yb-doped fiber amplifiers by an all-optical feedback loop. Chin Phys Lett 28:054212

Huo Y, Cheo PK, King GG (2004) Fundamental mode operation of a 19-core phase-locked Yb-doped fiber amplifier. Opt Express 12:6230–6239

Cheung EC, Ho JG, Goodno GD, Rice RR, Rothenberg J, Thielen P, Weber M, Wickham M (2008) Diffractive-optics-based beam combination of a phase-locked fiber laser array. Opt Lett 33:354–356

Shay TM, Baker JT, Sanchez AD, Robin CA, Vergien CL, Zeringue C, Gallant D, Lu CA, Pulford B, Bronder TJ, Lucero A (2009) High-power phase locking of a fiber amplifier array. In: Proceedings of SPIE 7195, fiber lasers VI: technology, systems, and applications, 71951M (19 February)

Anderson B, Flores A, Holten R, Dajani I (2015) Comparison of phase modulation schemes for coherently combined fiber amplifiers. Opt Express 23:27046–27060

Satellite imaging, remote sensing, or aircraft instrumentation, our optical filters ensure precision and clarity, vital for navigation, reconnaissance, and scientific exploration.

Ma P, Chang H, Ma Y, Su R, Qi Y, Wu J, Li C, Long J, Lai W, Chang Q, Hou T, Zhou P, Zhou J (2021) 7.1 kW coherent beam combining system based on a seven-channel fiber amplifier array. Opt Laser Technol 140:107016

High-performance optical filters specifically designed, our precision-engineered filters enable astronomers to achieve clearer views of celestial objects.

Prossotowicz M, Flamm D, Heimes A, Jansen F, Otto H, Budnicki A, Killi A, Morgner U (2021) Dynamic focus shaping with mixed-aperture coherent beam combining. Opt Lett 46:1660–1663

Vikram BS, Prakash R, Balaswamy V, Supradeepa VR (2021) Determination and analysis of line-shape induced enhancement of stimulated Brillouin scattering in noise broadened, narrow linewidth, high power fiber lasers. IEEE Photon J 13:1–12. https://doi.org/10.1109/JPHOT.2021.3067350

Manufacturing capabilities for high-performance optical filters involve precision techniques like thin-film coating and optical design.

Our filters optimize industrial processes like machine vision and quality control, fostering efficiency and innovation across diverse sectors.

Anderegg J, Brosnan SJ, Weber ME, Komine H, Wickham MG (2003) 8-W coherently phased 4-element fiber array. In; Proceedings of SPIE 4974, advances in fiber lasers (3 July)

Labroille G, Denolle B, Jian P, Genevaux P, Treps N, Morizur J (2014) Efficient and mode selective spatial mode multiplexer based on multi-plane light conversion. Opt Express 22:15599–15607

Hu Q, Zhao X, Tian X, Li H, Wang M, Wang Z, Xu X (2022) Raman suppression in 5 kW fiber amplifier using long period fiber grating fabricated by CO2 laser. Opt Laser Technol 145:107484

Fini JM, Mermelstein MD, Yan MF, Bise RT, Yablon AD, Wisk PW, Andrejco MJ (2006) Distributed suppression of stimulated Raman scattering in an Yb-doped filter-fiber amplifier. Opt Lett 31:2550–2552

Corcoran CJ, Rediker RH (1991) Operation of five individual diode lasers as a coherent ensemble by fiber coupling into an external cavity. Appl Phys Lett 59:759–761

Baumeister T, Brunton SL, Kutz JN (2018) Deep learning and model predictive control for self-tuning mode-locked lasers. J Opt Soc Am B 35:617–626

Tünnermann H, Shirakawa A (2018) Reinforcement learning for coherent beam combining. In: 2018 conference on lasers and electro-optics Pacific Rim (CLEO-PR), pp 1–2

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Expertise in optical filter technology, a deep understanding of applications in life sciences and clinical instrumentation.

Azarian A, Bourdon P, Lombard L, Jaouën Y, Vasseur O (2014) Orthogonal coding methods for increasing the number of multiplexed channels in coherent beam combining. Appl Opt 53:1493–1502

Coherent combining of light from multiple high power fiber amplifiers is a promising pathway to scaling the output power to hundreds of kiloWatts. In the last decade, substantial progress has been made in terms of scaling number of elements along with improvement in phase control techniques to achieve stable locking, resulting in tens of kiloWatts of output power. In this paper, we review the progress in coherent beam combining of fiber amplifiers in the master oscillator power amplifier configuration. We also discuss the challenges in power scaling as well as the current trends in the corresponding mitigation strategies. Specifically, the use of optimized phase modulation waveforms for mitigation of stimulated Brillouin scattering in high power amplifiers, scaling of the number of beam combining elements through deep-learning based phase control, and the use of micro-lens array for enhancing beam combination efficiency are discussed.

Chang H, Chang Q, Xi J, Hou T, Su R, Ma P, Wu J, Li C, Jiang M, Ma Y, Zhou P (2020) First experimental demonstration of coherent beam combining of more than 100 beams. Photon Res 8:1943–1948

Zhu J, Zhou P, Ma Y, Xu X, Liu Z (2011) Power scaling analysis of tandem-pumped Yb-doped fiber lasers and amplifiers. Opt Express 19:18645–18654

Jin Y, Hassan A, Jiang Y (2016) Freeform microlens array homogenizer for excimer laser beam shaping. Opt Express 24:24846–24858

Raman filters are ideal when you need higher transmission values, fast transitions, and superior blocking to keep out unwanted photons.

Anderegg J, Brosnan S, Cheung E, Epp P, Hammons D, Komine H, Weber M, Wickham M (2006) Coherently coupled high-power fiber arrays. In: Proceedings of SPIE 6102, fiber lasers III: technology, systems, and applications, 61020U (23 February)

Ma Y, Zhou P, Wang X, Ma H, Xu X, Si L, Liu Z, Zhao Y (2011b) Active phase locking of fiber amplifiers using sine-cosine single-frequency dithering technique. Appl Opt 50:3330–3336

McNaught SJ, Asman CP, Injeyan H, Jankevics A, Johnson AMF, Jones GC, Komine H, Machan J, Marmo J, McClellan M, Simpson R, Sollee J, Valley MM, Weber M, Weiss SB (2009) 100-kW coherently combined Nd:YAG MOPA laser array. In Frontiers in optics 2009/laser science XXV/fall

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Jabczyński JK, Gontar P (2021) Impact of atmospheric turbulence on coherent beam combining for laser weapon systems. Defence Technol 17:1160–1167

Klenke A, Müller M, Stark H, Tünnermann A, Limpert J (2018) Sequential phase locking scheme for a filled aperture intensity coherent combination of beam arrays. Opt Express 26:12072–12080

Song H, Yan D, Wu W, Shen B, Feng X, Liu Y, Li L, Chu Q, Li M, Wang J, Tao R (2021) SRS suppression in multi-kW fiber lasers with a multiplexed CTFBG. Opt Express 29:20535–20544

Leger JR, Scott ML, Veldkamp WB (1988) Coherent addition of AlGaAs lasers using microlenses and diffractive coupling. Appl Phys Lett 52:1771–1773

Hou T, An Y, Chang Q, Ma P, Li J, Zhi D, Huang L, Su R, Wu J, Ma Y, Zhou P (2019) Deep-learning-based phase control method for tiled aperture coherent beam combining systems. High Power Laser Sci Eng 7:e59

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Beyer E (2008) High power laser materials processing—new developments and trends. In: Pacific international conference on applications of lasers and optics 2008, pp 5–9

Flores A, Shay TM, Lu CA, Robin C, Pulford B, Sanchez AD, Hult DW, Rowland KB (2011) Coherent beam combining of fiber amplifiers in a kW regime. In CLEO:2011—laser applications to photonic applications, OSA technical digest (CD) (Optical Society of America)

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The authors would like to acknowledge funding support by DRDO Laser Science & Technology Centre (LASTEC) and Centre for High Energy Systems & Sciences (CHESS) through Contract for Acquisition of Research Services (CARS) projects, and MHRD/DRDO, Government of India through the Impacting Research Innovation and Technology scheme (IMPRINT/5375), as well as technical discussions with Drs. Anup Shah and Jagannath Nayak. The authors are thankful to Prof. Johan Nilsson and Dr. Yusuf Panbiharwala for the technical discussions.

Wang X, Wang X, Zhou P, Su R, Geng C, Li X, Xu X, Shu B (2012) 350-W coherent beam combining of fiber amplifiers with tilt-tip and phase-locking control. IEEE Photon Technol Lett 24:1781–1784

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Jauregui C, Limpert J, Tünnermann A (2011b) On the Raman threshold of passive large mode area fibers. In: Proceedings of SPIE 7914, fiber lasers VIII: technology, systems, and applications, 791408 (10 February)

Moyer RH, Valley M, Cimolino MC (1988) Beam combination through stimulated Brillouin scattering. J Opt Soc Am B 5:2473–2489

Tünnermann H, Shirakawa A (2019) Deep reinforcement learning for coherent beam combining applications. Opt Express 27:24223–24230

Present address: Joint Advanced Technology Centre, Indian Institute of Technology Delhi, New Delhi, Delhi, 110016, India

Dawson JW, Messerly MJ, Beach RJ, Shverdin MY, Stappaerts EA, Sridharan AK, Pax PH, Heebner JE, Siders CW, Barty CPJ (2008) Analysis of the scalability of diffraction-limited fiber lasers and amplifiers to high average power. Opt Express 16:13240–13266

Shekel E, Vidne Y, Urbach B (2020) 16 kW single mode CW laser with dynamic beam for material processing. In: Proceedings of SPIE 11260, fiber lasers XVII: technology and systems, p 1126021 (21 February)

Müller M, Aleshire C, Klenke A, Haddad E, Légaré F, Tünnermann A, Limpert J (2020) 10.4 kW coherently combined ultrafast fiber laser. Opt Lett 45:3083–3086

Kim J, Dupriez P, Codemard C, Nilsson J, Sahu JK (2006) Suppression of stimulated Raman scattering in a high power Yb-doped fiber amplifier using a W-type core with fundamental mode cut-off. Opt Express 14:5103–5113

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Fu X, Brunton SL, Kutz JN (2014) Classification of birefringence in mode-locked fiber lasers using machine learning and sparse representation. Opt Express 22:8585–8597

Goodno GD, Asman CP, Anderegg J, Brosnan S, Cheung EC, Hammons D, Injeyan H, Komine H, Long WH, McClellan M, McNaught SJ, Redmond S, Simpson R, Sollee J, Weber M, Weiss SB, Wickham M (2007) Brightness-scaling potential of actively phase-locked solid-state laser arrays. IEEE J Sel Top Quantum Electron 13:460–472

Ma Y, Liu Z, Zhou P et al (2009) Coherent beam combination of three fiber amplifiers with multi-dithering technique. Chin Phys Lett 26:44204

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Richardson DJ, Nilsson J, Clarkson WA (2010) High power fiber lasers: current status and future perspectives [Invited]. J Opt Soc Am B 27:B63–B92

Vasilyev A, Petersen E, Satyan N, Rakuljic G, Yariv A, White JO (2013) Coherent Power Combining of Chirped-Seed Erbium-Doped Fiber Amplifiers. IEEE Photon Technol Lett 25:1616–1618

Goodno GD, McNaught SJ, Rothenberg JE, McComb TS, Thielen PA, Wickham MG, Weber ME (2010a) Active phase and polarization locking of a 1.4 kW fiber amplifier. Opt Lett 35:1542–1544

Goodno GD, Shih C, Rothenberg JE (2010b) Perturbative analysis of coherent combining efficiency with mismatched lasers. Opt Express 18:25403–25414

Montoya J, Hwang C, Martz D, Aleshire C, Fan TY, Ripin DJ (2017) Photonic lantern kW-class fiber amplifier. Opt Express 25:27543–27550

Shirakawa A, Saitou T, Sekiguchi T, Ueda K (2002) Coherent addition of fiber lasers by use of a fiber coupler. Opt Express 10:1167–1172

Filters play a crucial role in enhancing clarity, color accuracy, and contrast in machine vision applications where details matter.

Charles Lailabai Linslal, Padmanabhan Ayyaswamy, Satyajit Maji, Mundakkolly Sureshbabu Sooraj, Awakash Dixit, Deepa Venkitesh & Balaji Srinivasan

Liu Y, Lv Z, Dong Y, Li Q (2009) Research on stimulated Brillouin scattering suppression based on multi-frequency phase modulation. Chin Opt Lett 7:29–31

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Rothenberg JE, Thielen PA, Wickham M, Asman CP (2008) Suppression of stimulated Brillouin scattering in single-frequency multi-kilowatt fiber amplifiers. In: Proceedings of SPIE 6873, fiber lasers V: technology, systems, and applications, 68730O (22 February)

Ricklin JC, Davidson FM (2002) Atmospheric turbulence effects on a partially coherent Gaussian beam: implications for free-space laser communication. J Opt Soc Am A 19:1794–1802

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Loftus TH, Thomas AM, Norsen M, Minelly JD, Jones P, Honea E, Shakir SA, Hendow S, Culver W, Nelson B, Fitelson M (2008) Four-channel, high power, passively phase locked fiber array. In Advanced solid-state photonics, OSA technical digest series (CD) (Optical Society of America)

Flores A, Dajani I, Holten RH, Ehrenreich T, Anderson BT (2016) Multi-kilowatt diffractive coherent combining of pseudorandom-modulated fiber amplifiers. Opt Eng 55(9):096101

Shpakovych M, Maulion G, Kermene V, Boju A, Armand P, Desfarges-Berthelemot A, Barthélemy A (2021) Experimental phase control of a 100 laser beam array with quasi-reinforcement learning of a neural network in an error reduction loop. Opt Express 29:12307–12318

Tünnermann H, Shirakawa A (2020) Tiled aperture beam combining with reinforcement learning. In: 2020 conference on lasers and electro-optics (CLEO), pp 1–2

Bruesselbach H, Jones DC, Mangir MS, Minden M, Rogers JL (2005a) Self-organized coherence in fiber laser arrays. Opt Lett 30:1339–1341

Satyan N, Vasilyev A, Rakuljic G, White JO, Yariv A (2012) Phase-locking and coherent power combining of broadband linearly chirped optical waves. Opt Express 20:25213–25227

Zhou T, Sano T, Wilcox R (2017a) Coherent combination of ultrashort pulse beams using two diffractive optics. Opt Lett 42:4422–4425