All-optical gain optoelectronic oscillator based on a dual-frequency integrated semiconductor laser: potential to break the bandwidth limitation in the traditional OEO configuration

Jin, Li; Pu, Tao; Zheng, Jilin; Zhang, Yunshan; Shi, Yuechun; Shao, Wei; Zhang, Xin; Meng, Xianshuai; Liu, Jie; Liang, Juan; Chen, Xiangfei

doi:10.1364/oe.415429

Opt. Express

2021

DOI: 10.1364/oe.415429

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All-optical gain optoelectronic oscillator based on a dual-frequency integrated semiconductor laser: potential to break the bandwidth limitation in the traditional OEO configuration

Li Jin

Tao Pu

Jilin Zheng

et al.

Abstract: A novel photonic method, to the best of our knowledge, to generate high-frequency micro/millimeter-wave signals based on the optoelectronic oscillator (OEO) with all-optical gain is proposed in this paper. The core device is the monolithically integrated dual-frequency semiconductor laser (MI-DFSL), in which the two DFB laser sections are simultaneously fabricated on one chip. Attributing to the combined impact of the photon-photon resonance effect and the sideband amplification injection locking effect, one w… Show more

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“…The device is dual semiconductor laser. The bandwidth was widened by introducing optical amplifier instead of electric one [18]. This means that laser electronic chips are now available.…”

mentioning

confidence: 99%

Electronic Chips Acting as Capacitors or Inductors when Laser Act as Information Transmitter

Yousef

Alsubaie

Saad

et al. 2022

EEJP

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To increase the speed of information flow and storage capacity in electronic devices laser can be used to carry information instead of electric current. Since the photon is faster than electrons, one expects information to be transmitted very fast through the internet when photons replace electrons. This requires searching for chips that act as capacitors, inductors or resistors. To do this Maxwell's equation for the electric field intensity beside the electron equation of motion were used. The electron is assumed to vibrate naturally inside a frictional medium in the presence of a local electric and magnetic fields. These equations have been used to find a useful expression for the absorption coefficient. The absorption coefficient was found to be dependent on the laser and natural frequencies beside the coefficient of friction in addition to the internal electric and magnetic fields. These parameters can be fine-tuned to make the chip act as a capacitor, inductor or resistor. The laser intensity decreases when the absorption coefficient inecreases. Thus, the absorption coefficient acts as an electic resistor. Therefore, if the absorption coefficient inecreases upon decreasing the frequency the chip acts as a capacitor. But when the absorption coefficient inecreases when the laser frequency inreases the chip acts as an inductor. In the case that the absorption coefficient inecreases with the concentration of the carriers it acts in this situation as a resistor. For magnetic materials with magnetic flux density that cancels the frictional force, when the laser frequency is equal nearly to the atom’s natural frequency the material acts as an inductor. But when the frictional force is low with the internal and external electric fields in phase, the material acts as a capacitor. However, it acts as a resistor for negligible natural frequency, when no electric dipoles exist and when the internal magnetic field force balance the frictional force.

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“…The device is dual semiconductor laser. The bandwidth was widened by introducing optical amplifier instead of electric one [18]. This means that laser electronic chips are now available.…”

mentioning

confidence: 99%

Electronic Chips Acting as Capacitors or Inductors when Laser Act as Information Transmitter

Yousef

Alsubaie

Saad

et al. 2022

EEJP

View full text Add to dashboard Cite

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Dual-loop fourier domain mode-locked optoelectronic oscillator based on three-section mutual-injection integrated semiconductor laser

Wu,

Li,

et al. 2024

Optics Communications

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High-purity linearly frequency-modulated signal generation based on the integrated semiconductor laser subject to the dynamical optoelectrical feedback

Li,

Pu,

Zhang

et al. 2023

Opt. Express

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A novel photonic method of linearly frequency-modulated (LFM) signal generation with high purity based on the monolithically integrated semiconductor laser (MISL) subject to the dynamical optoelectrical feedback is proposed and demonstrated in this paper. In this approach, the MISL is firstly operated in period-one state. By introducing the dynamical optoelectrical feedback to modulate the MISL, the generated LFM signals would be constantly optimized as long as the delay of the feedback loop is matched with the repetition period of the LFM signal. In this system, no additional high-speed external modulator, high-frequency electrical LFM oscillator are required, highly simplifying the framework and reducing the power consumption. In the current proof-of-concept experiment, one LFM signal with the bandwidth as large as 5.6 GHz is generated and the corresponding frequency comb contrast can be drastically improved by 51 dB. Furthermore, the effect of the delay mismatch is also discussed in this paper.

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All-optical gain optoelectronic oscillator based on a dual-frequency integrated semiconductor laser: potential to break the bandwidth limitation in the traditional OEO configuration

Cited by 3 publications

References 15 publications

Electronic Chips Acting as Capacitors or Inductors when Laser Act as Information Transmitter

Electronic Chips Acting as Capacitors or Inductors when Laser Act as Information Transmitter

Dual-loop fourier domain mode-locked optoelectronic oscillator based on three-section mutual-injection integrated semiconductor laser

High-purity linearly frequency-modulated signal generation based on the integrated semiconductor laser subject to the dynamical optoelectrical feedback

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