Generating Highly Dark–Bright Solitons by Gaussian Beam Propagation in a PANDA Ring Resonator

Optical Soliton Communication Using Ultra-Short Pulses

Ahmad

2015

The first observation of soliton was done by Scott Russel and the first experimental observation of soliton was occurred by using microscope objectives. In 1970s, Hasegawa primed to realize that the NLS equation was appropriate for the calculation of pulse propagation in optical fibers. Microring resonators (MRRs) shaped from nanoscale photonic waveguides. Ring resonators are not used only in optical networks, but they have recently been presented to be used as sensors, filters and biosensors. Chaotic controls have been used in a great number of optical, engineering and biological designed systems. In applications, the stored ultra-short optical signal can be used to generate optical quantum memory. The ability of ultrashort optical soliton signal to synchronize in a communication system is valid. Multi soliton generation becomes an interesting subject when it is used to enlarge the capacity of communication channels.

Section: Ring Resonatorsmentioning

confidence: 99%

Optical Soliton Signals Propagation in Fiber Waveguides

Optical Soliton Communication Using Ultra-Short Pulses

Ahmad

2015

“…31 For the soliton pulse in the micro-ring device, a balance should be achieved between the dispersion length (L D ) and the nonlinear length (L NL = 1/ NL ), thus L D = L NL , where and NL are coupling loss of the field amplitude and nonlinear phase shift, respectively. [32][33][34][35] The nonlinear refractive index of the nonlinear medium can be expressed by 36…”

Section: Operating Principlementioning

confidence: 99%

Femtosecond Optical Quantum Memory Generation Using Optical Bright Soliton

Jnl of Comp & Theo Nano

Ali²

2014

Self Cite

Optical system of microring resonator is presented to form the femtosecond (fs) memory time of optical soliton signals. Localised soliton pulses can be stored within the microring device using suitable parameters of the system. The optical quantum memory is a solution for storing large amounts of data which is very inexpensive and more importantly, it helps to transport the data between optical communication devices. The integrated optical system of a series of microring resonators and two add or drop systems are presented. This system is used to generate chaotic signals using an input bright soliton pulse. The large output gain is obtained by the self-phase modulation which is required to balance the dispersion effects of the medium. The ultra-short single and multi-spatial and temporal soliton pulses are obtained by using the add/drop filter systems. The results show that the single and multi-soliton pulses can be localised within the microring waveguide while the optical quantum memory time of 83 fs could be generated.

“…One new feature of this specific type of ring resonator, which introduces a system of nanoscale-sensing transducers based on the add/drop ring resonator was presented by Amiri et al [10,11]. They have shown that the multisoliton can be generated and controlled within a modified add/drop ring resonator [12,13].…”

Section: Introductionmentioning

confidence: 99%

Full Width at Half Maximum (FWHM) Analysis of Solitonic Pulse Applicable in Optical Network Communication

Ahmad

Al-Khafaji

2015

AJNC

Abstract:In this paper, we propose a system of microring resonator (MRR). This system uses a laser diode input which can be incorporated with an optical add/drop filter system. When light from the laser diode feedbacks to the fiber ring resonator, the pulses in the form of soliton can be generated by using appropriate fiber ring resonator parameters and also the input power. The filtering process occurs during the propagation of the pulse within the ring resonators. The full width at half maximum (FWHM) or bandwidth characterization of the pulse can be performed using the proposed system. Results obtained have established particular possibilities from the application such as optical network communication. The obtained results show the effects of coupling coefficients and ring radius on the bandwidth of the soliton pulse, where the graph of the FWHM versus the variable parameters such as the radius and coupling coefficient are presented.