Your search keyword '"optical injection"' showing total 15 results

1. Effects of Gain Saturation on Orbital Instability of Chaotic Laser Diode with External Pseudorandom Signal.

Author

Ebisawa, Satoshi

Subjects

SEMICONDUCTOR lasers, CHAOTIC communication, RANDOM numbers, LINEAR statistical models, STANDARD deviations

Abstract

In a laser diode (LD) system with optical injection, the effects of gain saturation of the LD on the orbital instability of the system are analyzed numerically. For the optical injection LD system without signal application, it is shown that the effect of optical injection is suppressed in the system with gain saturation and small optical injection, and that a higher amount of optical injection is necessary to obtain similar dynamics. Next, in the optical injection LD system with a pseudo-random signal applied to the LD drive current, it is confirmed that when the dynamics are a periodic window between chaotic and chaotic regions, chaotic dynamics are actualized as the standard deviation of the applied signal becomes larger. Furthermore, it is suggested that this phenomenon can be explained by linear stability analysis, and it is shown by introducing randomly varying tentative gain coefficients that gain fluctuations that lead to an expansion of the chaotic region. Hence, the results of this study provide research on the effects of gain saturation on chaotic oscillation in LDs with pseudo-random signals applied and contribute to the generation of more complex chaotic signals, chaotic secure communication, and random number generation. [ABSTRACT FROM AUTHOR]

Published

2024

2. A Numerical Study of Microwave Frequency Comb Generation in a Semiconductor Laser Subject to Modulated Optical Injection and Optoelectronic Feedback.

Author

Xue, Chenpeng, Chen, Wei, Zhu, Beibei, Zhang, Zuxing, and Hong, Yanhua

Subjects

FREQUENCY combs, SEMICONDUCTOR lasers, MICROWAVE generation, MICROWAVE photonics, MICROWAVES

Abstract

This study presents a comprehensive numerical investigation on the generation of a microwave frequency comb (MFC) using a semiconductor laser subjected to periodic-modulated optical injection. To enhance performance, optoelectronic feedback is incorporated through a dual-drive Mach–Zehnder modulator. The results show that the first optoelectronic feedback loop, with a delay time inversely proportional to the modulation frequency, can optimize MFC generation through a mode-locking effect and the second optoelectronic feedback loop with a multiple delay time of the first one can further enhance the performance of the MFC. The comb linewidth appears to decrease with the increase in the second-loop delay time in the power function. These results are consistent with experimental observations reported in the literature. We also explore the impact of the feedback index on comb contrast, the statistical characteristics of the central 128 lines within the MFC, and side peak suppression. The simulation results demonstrate the presence of an optimal feedback index. The study also reveals that linewidth reduction, through increasing the feedback index and delay time, comes at the cost of declining side peak suppression. These findings collectively contribute to a deeper understanding of the factors influencing MFC generation and pave the way for the design and optimization of high-performance MFC systems for various applications. [ABSTRACT FROM AUTHOR]

Published

2024

3. Nonlinear Dynamics of Silicon-Based Epitaxial Quantum Dot Lasers under Optical Injection.

Author

Fang, Ruilin, Xia, Guang-Qiong, Zheng, Yan-Fei, Wang, Qing-Qing, and Wu, Zheng-Mao

Subjects

LATTICE constants, QUANTUM dots, THERMAL expansion, LASERS

Abstract

For silicon-based epitaxial quantum dot lasers (QDLs), the mismatches of the lattice constants and the thermal expansion coefficients lead to the generation of threaded dislocations (TDs), which act as the non-radiative recombination centers through the Shockley–Read–Hall (SRH) recombination. Based on a three-level model including the SRH recombination, the nonlinear properties of the silicon-based epitaxial QDLs under optical injection have been investigated theoretically. The simulated results show that, through adjusting the injection parameters including injection strength and frequency detuning, the silicon-based epitaxial QDLs can display rich nonlinear dynamical states such as period one (P1), period two (P2), multi-period (MP), chaos (C), and injection locking (IL). Relatively speaking, for a negative frequency detuning, the evolution of the dynamical state with the injection strength is more abundant, and an evolution path P1-P2-MP-C-MP-IL has been observed. Via mapping the dynamical state in the parameter space of injection strength and frequency detuning under different SRH recombination lifetime, the effects of SRH recombination lifetime on the nonlinear dynamical state of silicon-based epitaxial QDLs have been analyzed. [ABSTRACT FROM AUTHOR]

Published

2024

4. Dynamics of the Frequency Shifts in Semiconductor Lasers under the Injection of a Frequency Comb.

Author

Al-Hosiny, Najm M.

Subjects

FREQUENCY combs, SEMICONDUCTOR lasers, BANDWIDTHS

Abstract

We have numerically investigated the dynamics of frequency shifts in semiconductor lasers under the injection of a frequency comb. We have studied the effect of comb spacing on the locking bandwidth. Frequency comb spacing was found to play an important role in the boundaries of the locking bandwidth as well as in the frequency shift of the SL peak. [ABSTRACT FROM AUTHOR]

Published

2022

5. Processing-Speed Enhancement in a Delay-Laser-Based Reservoir Computer by Optical Injection.

Author

Li, Ziyue, Li, Song-Sui, Zou, Xihua, Pan, Wei, and Yan, Lianshan

Subjects

SEMICONDUCTOR lasers, SPEED limits, ERROR rates, SPEED, COMPUTERS, ORDER picking systems

Abstract

A delay-laser-based reservoir computer (RC) usually has its processing speed limited by the transient response of laser dynamics. Here, we study a simple all-optical approach to enhancing the processing speed by introducing optical injection to the reservoir layer of conventional RC that consists of a semiconductor laser with a delay loop. Using optical injection, the laser's transient response effectively accelerates due to the speeded carrier-photon resonance. In the chaotic time-series prediction task, the proposed RC achieves good performance in a flexible range of injection detuning frequency under sufficient injection rate. Using proper injection parameters, the prediction error is significantly reduced and stabilized when using high processing speed. For achieving a prediction error below 0.006, the optical injection enhances the processing speed by an order of magnitude of about 5 GSample/s. Moreover, the proposed RC extends the advantage to the handwritten digit recognition task by achieving better word error rate. [ABSTRACT FROM AUTHOR]

Published

2022

6. Period-One Laser Dynamics for Photonic Microwave Signal Generation and Applications.

Author

Zhou, Pei, Li, Nianqiang, and Pan, Shilong

Subjects

MICROWAVE generation, MICROWAVE photonics, SIGNAL generators, SIGNAL processing, FREQUENCIES of oscillating systems, LASERS

Abstract

Due to the advantages of rich dynamics, small size, and easy integration, semiconductor lasers have many applications in microwave photonics. With a proper perturbation to invoke period-one (P1) nonlinear laser dynamics, a widely tunable microwave signal can be generated. In this paper, we concentrate on the realization and application of photonic microwave signal generation based on the P1 oscillation state of semiconductor lasers. Recent developments in P1 dynamics-based tunable microwave signal generation techniques are reviewed with an emphasis on the optical injection system, which has a large frequency tuning range that is far beyond the intrinsic relaxation oscillation frequency. In order to improve the spectral purity and stability of the generated microwave signal, two typical approaches are introduced, i.e., microwave modulation stabilization, and delayed feedback stabilization. Various applications of the P1 dynamics-based microwave signal generator in diverse signal generation and photonic microwave signal processing are described. Development trends of the P1 dynamics-based photonic microwave signal generator are also discussed. [ABSTRACT FROM AUTHOR]

Published

2022

7. Microwave Photonic Signal Generation in an Optically Injected Discrete Mode Semiconductor Laser.

Author

Chang, Da, Zhong, Zhuqiang, Valle, Angel, Jin, Wei, Jiang, Shan, Tang, Jianming, and Hong, Yanhua

Subjects

MICROWAVE photonics, OPTICAL feedback, MICROWAVES, SEMICONDUCTOR lasers

Abstract

In this paper, microwave photonic signal generation based on the period-one dynamic of optically injected discrete mode (DM) semiconductor lasers has been experimentally demonstrated and numerically simulated. The results show that the frequency of the generated microwave increases linearly with the frequency detuning or optical injection ratio. In addition, a single optical feedback loop is sufficient to reduce the microwave linewidth without significantly deteriorating side mode suppression. The simulation results using a model considering the nonlinear dependencies of the carrier recombination agree well with the experimental results, which indicates that the nonlinear carrier recombination effect is important in determining the nonlinear dynamics of optically injected DM lasers. [ABSTRACT FROM AUTHOR]

Published

2022

8. Characterization and direct modulation of a multi-section PIC suited for short reach optical communication systems

Author

Prajwal D. Lakshmijayasimha, Prince M. Anandarajah, M. Deseada Gutierrez Pascual, Aleksandra Kaszubowska-Anandarajah, Pascal Landais, Mohab N. Hammad, and Gaurav Jain

Subjects

lcsh:Applied optics. Photonics, Relative intensity noise, Optical communication, Optical power, 02 engineering and technology, 01 natural sciences, law.invention, 010309 optics, Laser linewidth, Optics, law, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Radiology, Nuclear Medicine and imaging, linewidth, optical injection, Instrumentation, Physics, business.industry, Photonic integrated circuit, direct modulation, lcsh:TA1501-1820, 020206 networking & telecommunications, bit error rate (BER), Laser, Atomic and Molecular Physics, and Optics, Injection locking, photonic integration, relative intensity noise (RIN), Bit error rate, frequency response, business

Abstract

A multi-section active photonic integrated circuit (PIC) is characterized in detail to gauge its suitability as a transmitter for short reach applications. The PIC is 1.5 mm long and consists of two lasers integrated in a master-slave configuration, which enables optical injection locking (OIL) of the slave laser. The beneficial impact of the injection is characterized by static and dynamic measurements. The results show a reduction of the optical linewidth from 8 MHz to 2 MHz, a relative intensity noise (RIN) value as low as &minus, 154.3 dB/Hz and a 45% improvement of the slave laser modulation bandwidth from 9.5 GHz to 14 GHz. This frequency response enhancement allows the direct modulation of the slave gain section at a data rate of 10.7 Gb/s and an error-free transmission over 25 km of standard single-mode fiber (SSMF). Transmission performance of the injected case shows a 2 dB improvement in the minimum optical power required to achieve a bit error rate of 3.8&times, 10&minus, 3 (hard decision forward error correction limit). These results demonstrate that the multi-section PIC can serve as an attractive cost-efficient transmitter in a wide variety of low-cost short-reach data communication applications.

Published

2020

9. Two Polarization Comb Dynamics in VCSELs Subject to Optical Injection.

Author

Doumbia, Yaya, Wolfersberger, Delphine, Panajotov, Krassimir, and Sciamanna, Marc

Subjects

LINEAR dichroism, OPTICAL communications, OPTICAL frequency conversion, OPTICAL spectroscopy, ELECTRIC lines

Abstract

Optical frequency comb technologies have received intense attention due to their numerous promising applications ranging from optical communications to optical comb spectroscopy. In this study, we experimentally demonstrate a new approach of broadband comb generation based on the polarization mode competition in single-mode VCSELs. More specifically, we analyze nonlinear dynamics and polarization properties in VCSELs when subject of optical injection from a frequency comb. When varying injection parameters (injection strength and detuning frequency) and comb properties (comb spacing), we unveil several bifurcation sequences enabling the excitation of free-running depressed polarization mode. Interestingly, for some injection parameters, the polarization mode competition induces a single or a two polarization comb with controllable properties (repetition rate and power per line). We also show that the performance of the two polarization combs depends crucially on the injection current and on the injected comb spacing. We explain our experimental findings by utilizing the spin-flip VCSEL model (SFM) supplemented with terms for parallel optical injection of frequency comb. We provide a comparison between parallel and orthogonal optical injection in the VCSEL when varying injection parameters and SFM parameters. We show that orthogonal comb dynamics can be observed in a wide range of parameters, as for example dichroism linear dichroism ( γ a = − 0.1 ns − 1 to γ a = − 0.8 ns − 1 ), injection current ( μ = 2.29 to μ = 5.29 ) and spin-flip relaxation rate ( γ s = 50 ns − 1 to γ s = 2300 ns − 1 ). [ABSTRACT FROM AUTHOR]

Published

2022

10. Mapping the Stability and Dynamics of Optically Injected Dual State Quantum Dot Lasers.

Author

Dillane, Michael, Lingnau, Benjamin, Viktorov, Evgeny A., and Kelleher, Bryan

Subjects

QUANTUM states, QUANTUM dots, EXCITED states, SQUARE waves, SEMICONDUCTOR lasers

Abstract

Optical injection is a key nonlinear laser configuration both for applications and fundamental studies. An important figure for understanding the optically injected laser system is the two parameter stability mapping of the dynamics found by examining the output of the injected laser under different combinations of the injection strength and detuning. We experimentally and theoretically generate this map for an optically injected quantum dot laser, biased to emit from the first excited state and optically injected near the ground state. Regions of different dynamical behaviours including phase-locking, excitability, and bursting regimes are identified. At the negatively detuned locking boundary, ground state dropouts and excited state pulses are observed near a hysteresis cycle for low injection strengths. Higher injection strengths reveal μ s duration square wave trains where the intensities of the ground state and excited state operate in antiphase. A narrow region of extremely slow oscillations with periods of several tens of milliseconds is observed at the positively detuned boundary. Two competing optothermal couplings are introduced and are shown to reproduce the experimental results extremely well. In fact, the dynamics of the system are dominated by these optothermal effects and their interplay is central to reproducing detailed features of the stability map. [ABSTRACT FROM AUTHOR]

Published

2022

11. Generation of Broadband Optical Frequency Comb Based on a Gain-Switching 1550 nm Vertical-Cavity Surface-Emitting Laser under Optical Injection.

Author

Ren, Huiping, Fan, Li, Liu, Na, Wu, Zhengmao, and Xia, Guangqiong

Subjects

SURFACE emitting lasers, OPTICAL frequency conversion, PHASE noise, VOLTAGE-controlled oscillators

Abstract

In this work, broadband optical frequency comb (OFC) generation by a gain-switching vertical-cavity surface-emitting laser (VCSEL) subject to optical injection is investigated experimentally. During implementing the experiment, a 1550 nm VCSEL under a large signal current modulation is driven into the gain-switching state with a broad noisy spectrum. By further introducing an optical injection, a high performance OFC can be produced. The experimental results demonstrate that the power and wavelength of the injection light seriously affect the performance of the produced OFC. Under proper optical injection parameters, two sub-combs originating from two orthogonal polarization components of the VCSEL can splice into a broadband total-OFC. By selecting optimized operation parameters, a high quality total-OFC can be acquired, with stable comb lines, high coherence, wide bandwidth of 70.0 GHz (56.0 GHz) within 10 dB (3 dB) amplitude variation and low single sideband phase noise at the fundamental frequency below −120.6 dBc/Hz @ 10 kHz. [ABSTRACT FROM AUTHOR]

Published

2020

12. Characterization and Direct Modulation of a Multi-Section PIC Suited for Short Reach Optical Communication Systems.

Author

Hammad, Mohab N., Kaszubowska-Anandarajah, Aleksandra, Pascual, M. Deseada Gutierrez, Landais, Pascal, Lakshmijayasimha, Prajwal D., Jain, Gaurav, and Anandarajah, Prince M.

Subjects

OPTICAL communications, DATA transmission systems, FORWARD error correction, SINGLE-mode optical fibers, ERROR rates, INTEGRATED circuits

Abstract

A multi-section active photonic integrated circuit (PIC) is characterized in detail to gauge its suitability as a transmitter for short reach applications. The PIC is 1.5 mm long and consists of two lasers integrated in a master-slave configuration, which enables optical injection locking (OIL) of the slave laser. The beneficial impact of the injection is characterized by static and dynamic measurements. The results show a reduction of the optical linewidth from 8 MHz to 2 MHz, a relative intensity noise (RIN) value as low as −154.3 dB/Hz and a 45% improvement of the slave laser modulation bandwidth from 9.5 GHz to 14 GHz. This frequency response enhancement allows the direct modulation of the slave gain section at a data rate of 10.7 Gb/s and an error-free transmission over 25 km of standard single-mode fiber (SSMF). Transmission performance of the injected case shows a 2 dB improvement in the minimum optical power required to achieve a bit error rate of 3.8 × 10 − 3 (hard decision forward error correction limit). These results demonstrate that the multi-section PIC can serve as an attractive cost-efficient transmitter in a wide variety of low-cost short-reach data communication applications. [ABSTRACT FROM AUTHOR]

Published

2020

13. Orbital Instability of Chaotic Laser Diode with Optical Injection and Electronically Applied Chaotic Signal.

Author

Ebisawa, Satoshi and Komatsu, Shinichi

Subjects

OPTICAL feedback, LYAPUNOV exponents, SEMICONDUCTOR lasers, CHAOS synchronization

Abstract

We numerically studied the chaotic dynamics of a laser diode (LD) system with optical injection, where a chaotic signal, which is generated by an LD with optical feedback, is applied to the drive current of the master LD. To quantify the orbital instability of the slave LD, the Lyapunov exponent was calculated as a function of the optical injection ratio between the master and slave LDs and the optical feedback ratio of the applied signal. We found that the Lyapunov exponent was increased and the orbital instability was enhanced by applying a chaotic signal when the inherent system without the applied signal was in a "window". Next, we investigated the orbital instability of the slave LD in terms of statistical and dynamical quantities of the applied chaotic signal. The maximal value of the Lyapunov exponent for a certain range of the injection ratio was calculated and we showed that a chaotic pulsation is suitable for enhancing the orbital instability of the LD system. We then investigated chaos synchronization between the LDs. It is concluded that the orbital instability of an LD with optical injection can be enhanced by applying chaotic pulsation without chaos synchronization. [ABSTRACT FROM AUTHOR]

Published

2020

14. Nonlinear Dynamics of Exclusive Excited-State Emission Quantum Dot Lasers Under Optical Injection.

Author

Jiang, Zai-Fu, Wu, Zheng-Mao, Jayaprasath, Elumalai, Yang, Wen-Yan, Hu, Chun-Xia, and Xia, Guang-Qiong

Subjects

LASERS, QUANTUM dots, DYNAMICS

Abstract

We numerically investigate the nonlinear dynamic properties of an exclusive excited-state (ES) emission quantum dot (QD) laser under optical injection. The results show that, under suitable injection parameters, the ES-QD laser can exhibit rich nonlinear dynamical behaviors, such as injection locking (IL), period one (P1), period two (P2), multi-period (MP), and chaotic pulsation (CP). Through mapping these dynamic states in the parameter space of the frequency detuning and the injection coefficient, it can be found that the IL occupies a wide region and the dynamic evolution routes appear in multiple forms. Via permutation entropy (PE) calculation to quantify the complexity of the CP state, the parameter range for acquiring the chaos with high complexity can be determined. Moreover, the influence of the linewidth enhancement factor (LEF) on the dynamical state of the ES-QD laser is analyzed. With the increase of the LEF value, the chaotic area shrinks (expands) in the negative (positive) frequency detuning region, and the IL region gradually shifts towards the negative frequency detuning. [ABSTRACT FROM AUTHOR]

Published

2019

15. Exploiting the Nonlinear Dynamics of Optically Injected Semiconductor Lasers for Optical Sensing.

Author

Torre, Maria S. and Masoller, Cristina

Subjects

RATE equation model, ROGUE waves, SEMICONDUCTOR lasers

Abstract

Optically injected semiconductor lasers are known to display a rich variety of dynamic behaviours, including the emission of excitable pulses, and of rare giant pulses (often referred to as optical rogue waves). Here, we use a well-known rate equation model to explore the combined effect of excitability and extreme pulse emission, for the detection of variations in the strength of the injected field. We find parameter regions where the laser always responds to a perturbation by emitting an optical pulse whose amplitude is above a pre-defined detection threshold. We characterize the sensing capability of the laser in terms of the amplitude and the duration of the perturbation. [ABSTRACT FROM AUTHOR]

Published

2019