Your search keyword '"Amiri I"' showing total 9 results

1. Realizing unique bifurcation model in a cascaded microring feedback circuit

Author

Bahadoran, Mahdi, Jalil, M. A., Ali, J., Amiri, I. S., and Yupapin, P.

Published

2020

2. Nonlinear studies of graphene oxide and its application to moisture detection in transformer oil using D-shaped optical fibre.

Author

Zakaria, R., Mezher, M. H., Zahid, Ali Z. Ghazi, Rohizat, N. S., Patel, Shobhit K., and Amiri, I. S.

Subjects

GRAPHENE oxide, CONTINUOUS wave lasers, FIBERS, INSULATING oils, LASER beams

Abstract

This paper reports nonlinear optical response studies of thin layers using graphene oxide (GO) and their performance for detecting water content in transformer oil using three sets of approaches. The sensor performance is evaluated based on bare optical fibre, D-shape optical fibre integrated with GO and the effects of the covering device with polydimethylsiloxane (PDMS). The improvement of this study is to ensure the stability of the recorded signal. The nonlinear optical response of the prepared dispersion was explored using the Z-scan technique with an 800 nm continuous wave laser beam. Taking advantage of the graphene-induced evanescent field using D-shape optical fibre with PDMS covers on the device can give high sensitivity and good stability for water dissolved in the oil at 1550 nm. We measured fluctuations in transmitted light associated with varying water contents ranging from 16 to 38 ppm. [ABSTRACT FROM AUTHOR]

Published

2020

3. Network system engineering by controlling the chaotic signals using silicon micro ring resonator.

Author

Shahidinejad, A., Nikoukar, A., Amiri, I. S., Ranjbar, M., Shojaei, A. A., Ali, J., and Yupapin, P. P.

Abstract

We investigate nonlinear behaviors of light known as bifurcation and chaos within a nonlinear silicon microring resonator (SMRR). The research is used to controlling SMRR's behaviors such as chaos applicable in security coding systems. The variable parameters affect the bifurcation to be happened in smaller roundtrip among total round trip of 20000 or input power. Simulated Results show that rising of the nonlinear refractive indices, coupling coefficients and radius of the SMRR leads to descending in input power and round trips wherein the bifurcation occurs. As result, bifurcation or chaos behaviors are seen at lower input power of 44 W, where the nonlinear refractive index is n2=3.2×10−20 m2/W. Smallest round trips of 4770 and 5720 can be seen for the R=40 µm and k = 0.1 respectively. The controlled chaotic signals from the SMRR are passing through a polarizer beam splitter to generate quantum binary codes which are used in wireless network communication. [ABSTRACT FROM PUBLISHER]

Published

2012

4. Generation of discrete frequency and wavelength for secured computer networks system using integrated ring resonators.

Author

Amiri, I. S., Sarkhanlou, k., Nikoukar, A., Shahidinejad, A., Ali, J., and Yupapin, P. P.

Abstract

In this study, a system of discrete optical pulse generation via a series of microring resonator (MRR) is presented. Chaotic signals can be generated by an optical soliton or a Gaussian pulse within a MRR system. Large bandwidth signals of optical soliton are generated by input pulse propagating within the MRRs, which can be used to form continuous wavelength or frequency with large tunable channel capacity. Therefore, distinguished discrete wavelength or frequency pulses can be generated by using localized spatial pulses via a networks communication system. Selected discrete pulses are more suitable to generate high-secured quantum codes because of the large free spectral range (FSR). Quantum codes can be generated by using a polarization control unit and a beam splitter, incorporating to the MRRs. In this work, frequency band of 10.7 MHz and 16 MHz and wavelengths of 206.9 nm, 1448 nm, 2169 nm and 2489 nm are localized and obtained which can be used for quantum codes generation applicable for secured networks communication. [ABSTRACT FROM PUBLISHER]

Published

2012

5. MRR quantum dense coding for optical wireless communication system using decimal convertor.

Author

Nikoukar, A., Amiri, I. S., Shahidinejad, A., Shojaei, A. A., Ali, J., and Yupapin, P. P.

Abstract

In this study, simply two systems consist of series of microring resonators (MRRs) and a add/drop filter are used to generate a large bandwidth signal as localized multi wavelength, applicable for quantum dense coding (QDC) and continuous variable encoding generation using incorporated system. This technique uses the Kerr nonlinear type of light in the MRR to generate multi wavelength for desired application especially in internet security and quantum network cryptography. Quantum dense encoding can be perform by output signals of selected wavelengths which are incorporated to a polarization control system in which dark and bright optical soliton pulses with different time slot are generated. Generated dark and bright optical pulses can be converted into digital logic quantum codes using a decimal convertor system in which transmission of secured information are perform via a wireless network communication system. Results show that multi soliton wavelength, ranged from 1.55µm to 1.56µm with FWHM and FSR of 10 pm and 600 pm can be generated respectively. [ABSTRACT FROM PUBLISHER]

Published

2012

6. Optical Dark and Bright Soliton Generation and Amplification.

Author

Afroozeh, A., Amiri, I. S., Kouhnavard, M., Jalil, M. A., Ali, J., and Yupapin, P. P.

Subjects

*ELECTRONIC amplifiers, *SOLITONS, *ELECTRIC resonators, *MULTIPLEXING, *WAVEGUIDES, *NONLINEAR optics, *SIGNAL processing

Abstract

We propose two designed systems consist of series of micro ring resonator (MRR) and an add/drop multiplexer in which the optical dark and bright soliton pulse propagating within the nonlinear waveguides can be amplified which can be used in long communication system. The dark or bright soliton is input into designed systems and travels within the waveguide. A continuous soliton pulse is sliced into smaller pulses by the nonlinear effect which is known as chaos. In this way large bandwidth of optical signals can be obtained. The power amplification occurs when the soliton propagates along the MRRs or add/drop systems. The add/drop multiplexer system can itself be used to amplify the optical soliton when the bright soliton is input at the drop part of the system. In this work we have studied the generation of amplified pulse of optical dark and bright soliton when they propagating inside single systems or when they interact and collide during propagation inside an add/drop device. It means that amplified soliton pulse also can be obtained when two types of soliton i.e., dark and bright soliton collide with each other in a same system. In such a way the amplified dark soliton or bright soliton can be used to perform the long distance link. [ABSTRACT FROM AUTHOR]

Published

2011

7. All-Optical OFDM Generation for IEEE802.11a Based on Soliton Carriers Using Microring Resonators.

Author

Alavi, S. E., Amiri, I. S., Idrus, S. M., Supa'at, A. S. M., Ali, J., and Yupapin, P. P.

Abstract

The optical carrier generation is the basic building block to implement all-optical orthogonal frequency-division multiplexing (OFDM) transmission. One method to optically generate single and multicarriers is to use the microring resonator (MRR). The MRRs can be used as filter devices, where generation of high-frequency (GHz) soliton signals as single and multicarriers can be performed using suitable system parameters. Here, the optical soliton in a nonlinear fiber MRR system is analyzed, using a modified add/drop system known as a Panda ring resonator connected to an add/drop system. In order to set up a transmission system, i.e., IEEE802.11a, first, 64 uniform optical carriers were generated and separated by a splitter and modulated; afterward, the spectra of the modulated optical subcarriers are overlapped, which results one optical OFDM channel band. The quadrature amplitude modulation (QAM) and 16-QAM are used for modulating the subcarriers. The generated OFDM signal is multiplexed with a single-carrier soliton and transmitted through the single-mode fiber (SMF). After photodetection, the radio frequency (RF) signal was propagated. On the receiver side, the RF signal was optically modulated and processed. The results show the generation of 64 multicarriers evenly spaced in the range from 54.09 to 55.01 GHz, where demodulation of these signals is performed, and the performance of the system is analyzed. [ABSTRACT FROM PUBLISHER]

Published

2014

8. IEEE 802.15.3c WPAN Standard Using Millimeter Optical Soliton Pulse Generated by a Panda Ring Resonator.

Author

Amiri, I. S., Alavi, S. E., Idrus, Sevia M., Nikoukar, A., and Ali, J.

Abstract

A system of microring resonators (MRRs) connected to an optical modified add/drop filter system known as a Panda ring resonator is presented. The optical soliton pulse of 60 GHz frequency band can be generated and used for Wireless Personal Area Network (WPAN) applications such as IEEE 802.15.3c. The system uses chaotic signals generated by a Gaussian laser pulse propagating within a nonlinear MRRs system. The chaotic signals can be generated via a series of microring resonators, where the filtering process is performed via the Panda ring resonator system wherein ultrashort single and multiple optical soliton pulses of 60 GHz are generated and seen at the through and drop ports, respectively. The IEEE 802.15.3c standard operates at the 60 GHz frequency band, and it is applicable for a short distance optical communication such as indoor systems, where the higher transmission data rate can be performed using a high frequency band of the output optical soliton pulses. The single and multi-soliton pulses could be generated and converted to logic codes, where the bandwidths of these pulses are 5 and 20 MHz, respectively. Thus, these types of signals can be used in optical indoor systems and transmission link using appropriate components such as transmitter, fiber optics, amplifier, and receiver. [ABSTRACT FROM PUBLISHER]

Published

2013

9. Mode-locked self-pumping and squeezing photons model in a nonlinear micro-ring resonator.

Author

Khunnam, W., Ali, J., Amiri, I. S., Suhailin, F. H., Singh, G., Yupapin, P., and Grattan, K. T. V.

Subjects

PHOTONS, GALLIUM arsenide, NONLINEAR optics, ELECTRIC resonators, DIRAC function

Abstract

Photon squeezing and self-pumping within a nonlinear microring GaAsInP/P resonator are modeled and simulated, based on practical, published device parameters. A slowly varying amplitude pulse is input to the system, with a pulse width of 20 ns, a wavelength of 1.55 µm and peak power of 100 mW. The nonlinear effect resulting from the photons within the nonlinear ring resonator can be increased by adding external nonlinear coupling where, in this case, two nonlinear side rings are provided. The Dirac approach is used to generate the squeezed photons within the system. Three different device structures have been investigated, which include an add-drop filter, and a modified add-drop filter with two inner and outer side ring coupling resonators, where the nonlinear four-wave mixing effect is introduced. By using the commercial Opti-wave and MATLAB programs (in which suitable parameters have been chosen), the balance between the creation and annihilation operators can form the squeezed photons, which can be seen at the edge and center rings. The results obtained have shown that the squeezed center photon optical path (between 0 and 1 nm can be obtained) can be useful for interferometry, photon sources, and security code and sensor applications. [ABSTRACT FROM AUTHOR]

Published

2018