Real-Time Intensity Domain Characterization of Fibre Lasers Using Spatio-Temporal Dynamics

Sugavanam, Srikanth; Tarasov, Nikita; Churkin, Dmitry V.

doi:10.3390/app6030065

Cited by 11 publications

(7 citation statements)

References 86 publications

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“…Figure 6 demonstrates the principle of spatiotemporal dynamics of periodic pulses in bidirectional mode-locked fibre laser [ 29 ]. The temporal resolution is limited by the oscilloscope-detector combination according to the following expression [ 163 ]:

where

and

are the time-domain impulse response of photodetector and oscilloscope, correspondingly, which relate to the rise time

= 0.915

. The temporal resolution limits of the above method can be surpassed using nonlinear approaches.…”

Section: Ultrafast Lasersmentioning

confidence: 99%

Rotation Active Sensors Based on Ultrafast Fibre Lasers

Kudelin

Sugavanam

Chernysheva

2021

Sensors

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Gyroscopes merit an undeniable role in inertial navigation systems, geodesy and seismology. By employing the optical Sagnac effect, ring laser gyroscopes provide exceptionally accurate measurements of even ultraslow angular velocity with a resolution up to 10−11 rad/s. With the recent advancement of ultrafast fibre lasers and, particularly, enabling effective bidirectional generation, their applications have been expanded to the areas of dual-comb spectroscopy and gyroscopy. Exceptional compactness, maintenance-free operation and rather low cost make ultrafast fibre lasers attractive for sensing applications. Remarkably, laser gyroscope operation in the ultrashort pulse generation regime presents a promising approach for eliminating sensing limitations caused by the synchronisation of counter-propagating channels, the most critical of which is frequency lock-in. In this work, we overview the fundamentals of gyroscopic sensing and ultrafast fibre lasers to bridge the gap between tools development and their real-world applications. This article provides a historical outline, highlights the most recent advancements and discusses perspectives for the expanding field of ultrafast fibre laser gyroscopes. We acknowledge the bottlenecks and deficiencies of the presented ultrafast laser gyroscope concepts due to intrinsic physical effects or currently available measurement methodology. Finally, the current work outlines solutions for further ultrafast laser technology development to translate to future commercial gyroscopes.

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where

and

are the time-domain impulse response of photodetector and oscilloscope, correspondingly, which relate to the rise time

= 0.915

. The temporal resolution limits of the above method can be surpassed using nonlinear approaches.…”

Section: Ultrafast Lasersmentioning

confidence: 99%

Rotation Active Sensors Based on Ultrafast Fibre Lasers

Kudelin

Sugavanam

Chernysheva

2021

Sensors

Self Cite

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“…NFT-based signal processing requires full-field information, i.e., the knowledge of both the power (or intensity) and the phase. Note that while methods like spatio-temporal dynamics 29,30 and DFT 22 are often used for studying the dynamic behaviour of laser field, they do not capture phase information. The bottleneck lies in the intensity-based response of the square law detectors which average out all fast phase variation.…”

Section: Resultsmentioning

confidence: 99%

“…For instance, the dispersive Fourier transform (DFT) method for real-time spectral measurement 22 has been successfully used in fibre lasers for studying soliton explosions 26 , bound solitons 24,27 , and the complexities of mode-locking onset behaviour 28 . Further, measurements of spatio-temporal dynamics of intensity in fibre lasers 29,30 have revealed the existence of distinct spatio-temporal regimes of operation in ultralong fibre lasers 29,31 , proliferation of dark solitons in stretched pulse fibre lasers 29 , generation of spatio-temporal extreme events 32 and also interaction and collisions of solitons in multisoliton regimes 33 . The methodology of space-time duality 34 has been successfully exploited to realise time lenses for the study of integrable turbulence 35 , the direct observation of rogue waves 36 and in uncovering hidden universalities in soliton dynamics 37 .…”

Section: Introductionmentioning

confidence: 99%

Analysis of laser radiation using the Nonlinear Fourier transform

et al. 2019

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Modern high-power lasers exhibit a rich diversity of nonlinear dynamics, often featuring nontrivial co-existence of linear dispersive waves and coherent structures. While the classical Fourier method adequately describes extended dispersive waves, the analysis of time-localised and/or non-stationary signals call for more nuanced approaches. Yet, mathematical methods that can be used for simultaneous characterisation of localized and extended fields are not yet well developed. Here, we demonstrate how the Nonlinear Fourier transform (NFT) based on the Zakharov-Shabat spectral problem can be applied as a signal processing tool for representation and analysis of coherent structures embedded into dispersive radiation. We use full-field, real-time experimental measurements of mode-locked pulses to compute the nonlinear pulse spectra. For the classification of lasing regimes, we present the concept of eigenvalue probability distributions. We present two field normalisation approaches, and show the NFT can yield an effective model of the laser radiation under appropriate signal normalisation conditions.

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“…5 ps is the sampling period. Figure 4 shows a space-time representation of the single pulse within each round-trip, for 100 round-trips [24,25]. Each pixel in the figure is a representation of the acquired discrete signal amplitude for one sampling period of the oscilloscope and is scaled to the color according to the color-scale located on the right hand side of the figure.…”

Section: Fundamental Passive Mode-locking (Fml)mentioning

confidence: 99%

Mapping the dynamical regimes of a SESAM mode-locked VECSEL with a long cavity using time series analysis

et al. 2018

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The different dynamical regions of an optically-pumped SESAM mode-locked, long-cavity VECSEL system with a fundamental pulse repetition frequency of ~200 MHz are investigated. The output power, captured as 250 μs long time series using a sampling rate of 200 GSa/s, for each operating condition of the system, is analyzed to determine the dynamical state. A wavelength range of 985-995 nm and optical pump powers of 10 W-16.3 W is studied. The system produces high quality fundamental passive mode-locking (FML) over an extensive part of the parameter space, but the different dynamical regions outside of FML are the primary focus of this study. We report five types of output: CW emission, FML, mode-locking of a few modes, double pulsing, and, semi-stable 4 harmonic mode-locking. The high sampling rate of the oscilloscope, combined with the long duration of the time series analyzed, enables insight into how the structure and substructure of pulses vary systematically over thousands of round trips of the laser cavity. Higher average output power is obtained in regions characterized by semi-stable 4 harmonic mode-locking than observed for FML, raising whether such average powers might be achieved for FML. The observed dynamic transitions from fundamental mode-locking provide insights into instability challenges in developing a stable, widely tunable, low repetition rate, turn-key system; and to inform future modelling of the system.

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Real-Time Intensity Domain Characterization of Fibre Lasers Using Spatio-Temporal Dynamics

Cited by 11 publications

References 86 publications

Rotation Active Sensors Based on Ultrafast Fibre Lasers

Rotation Active Sensors Based on Ultrafast Fibre Lasers

Analysis of laser radiation using the Nonlinear Fourier transform

Mapping the dynamical regimes of a SESAM mode-locked VECSEL with a long cavity using time series analysis

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