Multiwavelength generation using an add-drop microring resonator integrated with an InGaAsP/InP sampled grating distributed feedback
A system of an add-drop microring resonator integrated with a sampled grating distributed feedback (SG-DFB) is investigated via modeling and simulation with the time-domain traveling wave (TDTW) method. The proposed microring resonator comprises a SiO2 waveguide integrated with an InGaAsP/InP SG-DFB...
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2016
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my.um.eprints.181992018-10-11T03:21:05Z http://eprints.um.edu.my/18199/ Multiwavelength generation using an add-drop microring resonator integrated with an InGaAsP/InP sampled grating distributed feedback Alavi, S.E. Amiri, I.S. Soltanian, M.R.K. Penny, R. Supa'at, A.S.M. Ahmad, Harith Q Science (General) QC Physics TK Electrical engineering. Electronics Nuclear engineering A system of an add-drop microring resonator integrated with a sampled grating distributed feedback (SG-DFB) is investigated via modeling and simulation with the time-domain traveling wave (TDTW) method. The proposed microring resonator comprises a SiO2 waveguide integrated with an InGaAsP/InP SG-DFB, and the SiO2 waveguide consists of a silicon core having a refractive index of 3.48 and Kerr coefficient of 4.5 × 10-18 m2/W. The SG-DFB consists of a series of grating bursts that are constructed using a periodic apodization function with a burst spacing in the grating of 45 μm, a burst length of 5 μm, and 10 bursts across the total length of the SG-DBR. Transmission results of the through and drop port of the microring resonator show the significant capacity enhancement of the generated center wavelengths. The Q-factor of the microring resonator system, defined as the center wavelength (λ0) divided by 3 dB FWHM, without and with integration with the SG-DFB is calculated as 1.93 × 105 and 2.87 × 105, respectively. Analysis of the dispersion of the system reveals that increasing the wavelength results in a decrease of the dispersion. The higher capacity and efficiency are the advantages of integrating the microring resonator and the InGaAsP/InP SG-DFB. Optical Society of America 2016 Article PeerReviewed Alavi, S.E. and Amiri, I.S. and Soltanian, M.R.K. and Penny, R. and Supa'at, A.S.M. and Ahmad, Harith (2016) Multiwavelength generation using an add-drop microring resonator integrated with an InGaAsP/InP sampled grating distributed feedback. Chinese Optics Letters, 14 (2). 021301. ISSN 1671-7694 https://doi.org/10.3788/COL201614.021301 doi:10.3788/COL201614.021301 |
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Q Science (General) QC Physics TK Electrical engineering. Electronics Nuclear engineering Alavi, S.E. Amiri, I.S. Soltanian, M.R.K. Penny, R. Supa'at, A.S.M. Ahmad, Harith Multiwavelength generation using an add-drop microring resonator integrated with an InGaAsP/InP sampled grating distributed feedback |
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A system of an add-drop microring resonator integrated with a sampled grating distributed feedback (SG-DFB) is investigated via modeling and simulation with the time-domain traveling wave (TDTW) method. The proposed microring resonator comprises a SiO2 waveguide integrated with an InGaAsP/InP SG-DFB, and the SiO2 waveguide consists of a silicon core having a refractive index of 3.48 and Kerr coefficient of 4.5 × 10-18 m2/W. The SG-DFB consists of a series of grating bursts that are constructed using a periodic apodization function with a burst spacing in the grating of 45 μm, a burst length of 5 μm, and 10 bursts across the total length of the SG-DBR. Transmission results of the through and drop port of the microring resonator show the significant capacity enhancement of the generated center wavelengths. The Q-factor of the microring resonator system, defined as the center wavelength (λ0) divided by 3 dB FWHM, without and with integration with the SG-DFB is calculated as 1.93 × 105 and 2.87 × 105, respectively. Analysis of the dispersion of the system reveals that increasing the wavelength results in a decrease of the dispersion. The higher capacity and efficiency are the advantages of integrating the microring resonator and the InGaAsP/InP SG-DFB. |
| format |
Article |
| author |
Alavi, S.E. Amiri, I.S. Soltanian, M.R.K. Penny, R. Supa'at, A.S.M. Ahmad, Harith |
| author_facet |
Alavi, S.E. Amiri, I.S. Soltanian, M.R.K. Penny, R. Supa'at, A.S.M. Ahmad, Harith |
| author_sort |
Alavi, S.E. |
| title |
Multiwavelength generation using an add-drop microring resonator integrated with an InGaAsP/InP sampled grating distributed feedback |
| title_short |
Multiwavelength generation using an add-drop microring resonator integrated with an InGaAsP/InP sampled grating distributed feedback |
| title_full |
Multiwavelength generation using an add-drop microring resonator integrated with an InGaAsP/InP sampled grating distributed feedback |
| title_fullStr |
Multiwavelength generation using an add-drop microring resonator integrated with an InGaAsP/InP sampled grating distributed feedback |
| title_full_unstemmed |
Multiwavelength generation using an add-drop microring resonator integrated with an InGaAsP/InP sampled grating distributed feedback |
| title_sort |
multiwavelength generation using an add-drop microring resonator integrated with an ingaasp/inp sampled grating distributed feedback |
| publisher |
Optical Society of America |
| publishDate |
2016 |
| url |
http://eprints.um.edu.my/18199/ https://doi.org/10.3788/COL201614.021301 |
| _version_ |
1643690638076542976 |
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13.209306 |