Experimental Implementation of a Photonic Neural Network with a 1550nm-VCSEL subject to Optical Injection and Delayed Optical Feedback

2018 ◽

pp. 96-101 ◽

Cited By ~ 2

Author(s):

Bruno Garbin ◽

Giovanna Tissoni ◽

Stephane Barland

Keyword(s):

Semiconductor Laser ◽

Semiconductor Lasers ◽

Optical Feedback ◽

Optical Injection ◽

Localized States ◽

External Perturbations ◽

Parameter Values ◽

And Diffusion ◽

Delayed Optical Feedback

Semiconductor lasers with optical injection may be brought to an “excitable” regime, in which they respond to external perturbations in a neuron-like way. When submitted to delayed optical feedback this system can host stable optical localized states. We characterize experimentally the excitable response of a semiconductor laser with optical injection to external perturbations for different parameter values and show that localized states may diffuse in presence of noise.

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Control of Timing Stability, and Suppression in Delayed Feedback Induced Frequency-Fluctuations by Means of Power Split Ratio and Delay Phase-Dependent Dual-Loop Optical Feedback

Applied Sciences ◽

10.3390/app11104529 ◽

2021 ◽

Vol 11 (10) ◽

pp. 4529

Author(s):

Haroon Asghar ◽

John G. McInerney

Keyword(s):

Coupling Strength ◽

Optical Feedback ◽

Fine Tuning ◽

Split Ratio ◽

Optical Delay ◽

Quantum Dash ◽

Power Split ◽

Frequency Fluctuations ◽

Mode Locked Lasers ◽

Delayed Optical Feedback

We experimentally demonstrated a power split ratio and optical delay phase dependent dual-loop optical feedback to investigate the suppression of frequency-fluctuations induced due to delayed optical feedback. The device under investigation is self-mode-locked (SML) two-section quantum-dash (QDash) laser operating at ∼21 GHz and emitting at ∼1.55 m. The effect of two selective combinations of power split ratios (Loop-I: −23.29 dB and Loop-II: −28.06 dB, and Loop-I and Loop-II: −22 dB) and two optical delay phase settings ((i) stronger cavity set to integer resonance and fine-tuning the weaker cavity, (ii) weaker cavity set to integer resonance and fine-tuning of stronger cavity) on the suppression of cavity side-bands have been studied. Measured experimental results demonstrate that delayed optical feedback induced frequency-fluctuations can be effectively suppressed on integer resonance as well as on full delay range tuning (0–84 ps) by adjusting coupling strength −22 dB through Loop-I and Loop-II, respectively. Our findings suggest that power split ratio and delays phase-dependent dual-loop optical feedback can be used to maximize the performance of semiconductor mode-locked lasers.

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Multi-target ranging using optical reservoir computing approach in the laterally coupled semiconductor lasers with self-feedback

Chinese Physics B ◽

10.1088/1674-1056/ac4021 ◽

2021 ◽

Author(s):

Dong-Zhou Zhong ◽

Zhe Xu ◽

Ya-Lan Hu ◽

Ke-Ke Zhao ◽

Jin-Bo Zhang ◽

...

Keyword(s):

Semiconductor Lasers ◽

Hilbert Transform ◽

Optical Feedback ◽

Optical Injection ◽

Reservoir Computing ◽

Probe Signal ◽

Laser Array ◽

Target Ranging ◽

Relative Errors ◽

Computing Approach

Abstract In this work, we utilize three parallel reservoir computers using semiconductor lasers with optical feedback and light injection to model radar probe signals with delays. Three radar probe signals are generated by driving lasers constructed by a three-element lase array with self-feedback. The response lasers are implemented also by a three-element lase array with both delay-time feedback and optical injection, which are utilized as nonlinear nodes to realize the reservoirs. We show that each delayed radar probe signal can well be predicted and to synchronize with its corresponding trained reservoir, even when there exist parameter mismatches between the response laser array and the driving laser array. Based on this, the three synchronous probe signals are utilized for ranging to three targets, respectively, using Hilbert transform. It is demonstrated that the relative errors for ranging can be very small and less than 0.6%. Our findings show that optical reservoir computing provides an effective way for applications of target ranging.

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The Role of Master Laser with Feedback in Time-Delay Signature Suppression of Semiconductor Laser Subject to Chaotic Optical Injection

International Journal of Bifurcation and Chaos ◽

10.1142/s0218127417501693 ◽

2017 ◽

Vol 27 (11) ◽

pp. 1750169 ◽

Cited By ~ 1

Author(s):

Liyue Zhang ◽

Wei Pan ◽

Penghua Mu ◽

Xiaofeng Li ◽

Shuiying Xiang ◽

...

Keyword(s):

Time Delay ◽

Semiconductor Laser ◽

Optical Feedback ◽

Bias Current ◽

Optical Injection ◽

Strength Parameter ◽

Master Laser ◽

Feedback Strength ◽

Chaotic Signals

The important role of parameters in master laser with optical feedback for the elimination of time-delay (TD) signature in semiconductor laser subject to chaotic optical injection is investigated systemically. The experimental results show that TD signature suppressed chaotic signals can be credibly generated by increasing the feedback strength of the master laser, which is quite different from the trends observed in semiconductor laser (SL) with optical feedback. Systematically numerical analysis is also carried out as a validation, and it is shown that with low bias current and strong feedback strength, parameter regions contributing to successful TD suppression are much wider. Furthermore, it is shown that the influence of frequency detuning in TD concealment will change with the increase of feedback strength. All the numerical results are in perfect accordance with experimental observation.

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