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L Shaped via based Mushroom type High Impedance Structure

Vol. 6, Issue 04, PP. 143-147, April 2019

Published online L Shaped via based Mushroom type High Impedance Structure

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Abstract

High-impedance Electromagnetic Band-Gap structures (EBG) surfaces have the capability to forbid flow of EM waves in a given band which and therefore surface waves in case of planar antennas like mictostrip antenna can be minimized with this characteristics of EBG plane. Shape, size, symmetry, and material used in their construction defines their operating band. In this research, a novel compact EBG structure also called high impedance structure (HIS) is proposed. The design is achieved through incorporation of ‘L’ shaped via to conventional mushroom type EBG/HIS instead of straight vias. The design includes distribution of square patches over substrate material below which there exists a ground plane. Vias passing through the substrate connecting square patches and the ground plane are also part of its design It has been observed that operating frequency of L shaped via based EBG is much lower than that of conventional mushroom type EBG/HIS having straight vias. Alternatively, we can say that size reduction has been achieved through incorporation of L shaped via to the EBG/HIS resulting in 62.5 % of size reduction. All the designs and simulations are carried out in CST microwave studio.

Author

Touseef Ahmad:Universitivy of Engineering and Technology Peshawar Pakistan
Shahid Bashir: Universitivy of Engineering and Technology Peshawar Pakistan

Cite

Touseef Ahmad and Shahid Bashir, L Shaped via based Mushroom type High Impedance Structure, International Journal of Engineering Works, Vol. 6 Issue 04 PP. 143-147 April 2019,

References

[1] A.Sihvola,―Electromagnetic emergence in metamaterials‖, Advances in Electromagnetics of Complex Media and Metamaterials, vol. 89, pp. 1-17, 2003.

[2] J. Zehentner and J. Machac, ―Volumetric single negative metamaterials‖, Proceedings of Metamaterials Congress, pp. 22–24, 2007

[3] N. Engheta,―Metamaterials with negative permittivity and permeability: background, salient features, and new trends‖, IEEE MTT-S International Microwave Symposium Digest, pp. 187-190, 2003.

[4] N. Engheta,―Design, fabrication, and testing of double negative metamaterials‖, IEEE Transactions on Antennas and Propagation, vol. 51, issue. 7, pp. 1516-1529, 2003.

[5] W. R. Ziolkowski and N. Engheta, ―Metamaterials: Physics and Engineering Explorations‖, John Wiley & Sons, Inc., 18 September 2006.

[6] D. Sievenpiper, ―High Impedance Electromagnetic Surfaces‖, Ph.D. dissertation, Electrical Engineering Department, University of California, Los Angeles, 1999.

[7] D. Sievenpiper, L. Zhang, R. F. J. Broas, N. G. Alexopolous, E. Yablonovitch,, "High-Impedance Electromagnetic Surfaces with a Forbidden Frequency Band," IEEE Transactions on Microwave Theory and Techniques, vol. 47, no. 11, pp. 2059-2074, 1999.

[8] Y. J. Lee, J. Yeo, R. Mittra, W. S. Park, "Application of Electromagnetic Bandgap (EBG) Superstrates With Controllable Defects for a Class of Patch Antennas as Spatial Angular Filters," IEEE Transactions on Antennas and Propagation, vol. 53, no. 1, pp. 224-235, 2005.

[9] S. G. Mao, M. Y. Chen, "Propagation Characteristics of Finite-Width Conductor-Backed Coplanar Waveguides with Periodic Electromagnetic Bandgap Cells," IEEE Transactions on Microwave Theory and Techniques, vol. 50, no. 11, pp. 2691-2703, 2002.

[10] F. Yang, Y. Rahmat-Samii, "Reflection Phase Characterizations of the EBG Ground Plane for Low Profile Wire Antenna Applications," IEEE Transactions on Antennas and Propagation, vol. 51, no. 10, pp. 677-682, 2003.

[11] F. Yang, Y. Rahmat-Samii, "A low-profile circularly polarized curl antenna over an electromagnetic bandgap (EBG) surface," Microwave and Optical Technology Letters, vol. 31, no. 4, pp. 264-267, 2001.

[12] Z. Li, Y. Rahmat-Samii, "PBG, PMC and PEC ground planes: A case study of dipole antennas," in IEEE Antennas and Propagation Society International Symposium, 2000.

13] T. H. Liu, W. X. Zhang, M. Zhang, K. F. Tsang, "Low profile spiral antenna with PBG substrate," Electronics Letters, vol. 36, p. 779–780, 2000.

[14] S. Bashir, M. Hosseini, R. M. Edwards, M. I. Khattak, L. Ma, "Bicep Mounted Low Profile Wearable Antenna Based on A Non-Uniform EBG Ground Plane – Flexible 60 EBG Inverted-L (FEBGIL)," in Loughborough antennas and propagation conference, Loughborough, 2008.

[15] N. Chahat, M. Zhadobov, R. Sauleau, K. Mahdjoubi, "Improvement of the On-Body Performance of a Dual-Band Textile Antenna Using an EBG structure," in Loughborough antennas and propagation conference, Loughborough, 2010.

[16] J. H. S. D. Sievenpiper, "Textured Surface Having High Electromagnetic Impedance in Multiple Frequency Bands". United States Patent US 6,483,481 B1, 19 November 2002.

[17] R. Li, G. DeJean, M. M. Tentzeris, J. Papapolymerou, J. Laskar, "Radiation-Pattern Improvement of Patch Antennas on a Large-Size Substrate Using a Compact Soft-Surface Structure and Its Realization on LTCC Multilayer Technology," IEEE Transactions on antennas and propagation, vol. 53, no. 1, pp. 200-208, 2005.

18] R. Diaz, V. Sanchez, E. Caswell, A. Miller, "Magnetic Loading of Artificial Magnetic Conductors for Bandwidth Enhancement," 2003.

[19] Aminian, F. Yang, Y. Rahmat-Samii, "In-phase Reflection and EM Wave Suppression Characteristics of Electromagnetic Band Gap Ground Planes,” IEEE Antennas and Propagation Society International Symposium," 2003.

[20] Aminian, Y. Rahmat-Samii, "Bandwidth Determination for Soft and Hard Ground Planes: A Unified Approach in Visible and Surface Wave Regions," in IEEE Antennas and Propagation Society International Symposium, 2004.

[21] F. Bilotti, L. Vegni, "Radiating Features of Capacitive and Inductive Surfaces," Microwave and Optical Technology Letters, vol. 39, no. 2, pp. 117-121, 2003.

[22] Stylianos D. Assimonis, Traianos V. Yioultsis, and Christos S. Antonopoulos, "Design and Optimization of Uniplanar EBG Structures for Low Profile Antenna Applications and Mutual Coupling Reduction," IEEE Transaction on antennas and propagation, vol. 60, no. 10, Oct. 2012, pp. 4944-4949.

[23] S. Zhang, B. Kiong Lau, Y. Tan, Z. Ying, and S. He, "Mutual Coupling Reduction of two PIFAs with a TShape Slot Impedance Transformer for MIMO Mobile Terminals," IEEE Transaction on antennas and propagation, vol. 60, no. 3, March 2012, pp. 1521-153l.

[24] A. M. Abdelreheem, and M. A. Abdalla, "A Novel Bilateral UC-EBG Structure," IEEE Antenna and Propagation Society International Symposium pp. 1780-81, July 2014, pp. 1780-1781.

[25] Eva Rajo-Iglesias, Member, IEEE, Luis Inclán-Sánchez, José-Luis Vázquez-Roy, Member, IEEE, and Enrique García-Muñoz, “Size Reduction of Mushroom-Type EBG Surfaces by Using Edge-Located Vias” IEEE MICROWAVE AND WIRELESS COMPONENTS LETTERS, VOL. 17, NO. 9, SEPTEMBER 2007.

[26] Wenquan Cao Bangning Zhang Tongbin Yu Daosheng Guo Aijun Liu “Helical-Via-Type Mushroom EBG Structure for Size Reduction” IEEE Antenna and Propagation Society International Symposium pp. 1780-81, June 2015, pp. 1347-1349

[27] D. Sievenpiper, ―High-Impedance Electromagnetic Surfaces with a Forbidden Frequency Band‖, IEEE Transactions on Microwave Theory and Techniques, vol. 47, pp. 2059-2073, November 1999.

[28] D. Sievenpiper, L. Zhang and E. Yablonovitch, ―High-Impedance Electromagnetic Ground Planes‖, IEEE MlT-S Digest, vol. 4, pp. 1529-1532, 1999.

[29] D. Sievenpiper, R. Broas and E. Yablonovitch, ―Antennas on high-impedance ground planes‖, IEEE MTT-S, International Microwave Symposium Digest, vol. 3, pp. 1245-1248, 1999.

[30] D. Sievenpiper, ―High Impedance Electromagnetic Surfaces, Ph.D. dissertation, Electrical Engineering Department, University of California, Los Angeles, 1999.

[31] F. Yang, Y. Rahmat-Samii, ―Electromagnetic Band Gap Structures in Antenna Engineering‖, The Cambridge RF and Microwave Engineering Series, October 2008.

[32] B. Jecko, T. Monediere, L. Leger, “High Gain EBG Resonator Antenna”, 18th International Conference on Applied Electromagnetics and Communications, ICECom 2005, pp. 1-3, 12-14 Oct. 2005

[33] D. Sievenpiper, L. Zhang and E. Yablonovitch, “High-Impedance Electromagnetic Ground Planes”, IEEE MlT-S Digest, vol. 4, pp. 1529-1532, 1999.

[34] Qian Y., Coccioli R., Sievenpiper D., Radisic V., Yablonovitch E., and Itoh T., “A Microstrip Patch Antenna using novel photonic bandgap structures”, Microwave J., vol 42, pp. 66-76, Jan 1999.

[35] Z. Duan, D. Linton, W. Scanlon, and G. Conway, “Using EBG to Improve Antenna Efficiency in Proximity to the Human Body”, Institution of Engineering and Technology Seminar on Wideband, Multiband Antennas and Arrays for Defence or Civil Applications, pp. 173-180, London, 13-13 March 2008.

[36] X. L. Bao, G. Ruvio, M. J. Ammann, and M. John, “A novel GPS patch antenna on fractal Hi-Impedance surface Substrate”, IEEE Antenna and Wireless Propagation Letters, vol. 5, 2006.

[37] R. Baggen, M. Martínez-Vázquez and J. Leiss, “Low Profile GALILEO Antenna using EBG Technology”, IEEE Transactions on Antennas and Propagation, vol. 56, no. 3, pp. 667-674, March 2008.

[38] F. Yang, Y. Rahmat-Samii, “Polarization-Dependent Electromagnetic Band Gap (PDEBG) structures: designs and applications”, Microwave and Optical Technology Letters, vol. 41, issue. 6, pp. 439–444, June 20, 2004.

[39] Y. Fu and N. Yuan, “Surface-wave bandgap of Polarisation dependent Electromagnetic bandgap Structures”, Microwave and Optical Technology Letters, vol. 49, issue 4, pp. 946–949, 26 February 2007.

[40] D. Yan, Q. Gao, C. Wang, C. Zhu, N. Yuan, “A novel polarisation convert surface based on artificial magnetic conductor”, Asia-Pacific Microwave Conference Proceedings, APMC 2005, vol. 3, pp. 4-7, December 2005.

[41] P. J. Ferrer, B. Kelem and C. Craeye, “Design of broadband transpolarizing surfaces”, Microwave and Optical Technology Letters, vol. 48, no. 12, pp. 2606-2611, December 2006.

Productive Lithology Discrimination in Structurally Complex Area by Means of AVO/AVA Synthetics and Petrophysical Well Log Analysis, A Case Study from Khipro Block, Southern Indus Basin, Pakistan

Vol. 6, Issue 04, PP. 132-142, April 2019

Published online Productive Lithology Discrimination in Structurally Complex Area by Means of AVO/AVA Synthetics and Petrophysical Well Log Analysis, A Case Study from Khipro Block, Southern Indus Basin, Pakistan

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Abstract

In this study, AVO/AVA Synthetics and petrophysical well log analysis was carried out to discriminate between the reservoir and non-productive lithology for two wells Naimat Basal 01 & Siraj South-01. Synthetic AVO/AVA traces of Naimat Basal 01 & Siraj South-01 were generated. The behavior of the theoretical and NMO corrected synthetics for Naimat Basal 01 has a weak response, while Siraj South-01 indicated a clear sharp anomaly. AVA synthetic created for well Naimat Basal-01 and Siraj South-01 using Zoeppritz equation clearly indicated amplitude variations. On the basis of AVO/AVA anomalies petrophysical well log analysis was carried out for Naimat Basal-01 from 2600-3550 m depth. The two zones interval 3395m- 3411m and 3480m-3497m were studies in detail which confirmed the results obtained from AVO/AVA synthetics and 3395-3411m and 3480-3497m may be good reservoir zone for the hydrocarbon accumulation.

Author

Manaf Muhammad: Department of Earth Sciences, University of Sargodha, Sargodha, Pakistan
Haris Ahmad Khan:Department of Earth Sciences, Bahria University, Karachi, Pakistan
Shaukat Khan: Department of Earth Sciences, University of Sargodha, Sargodha, Pakistan
Faisal Rehman: Department of Earth Sciences, University of Sargodha, Sargodha, Pakistan

Cite

Manaf Muhammad Haris Ahmad Kha Shaukat Khan and Faisal Rehman, Productive Lithology Discrimination in Structurally Complex Area by Means of AVO/AVA Synthetics and Petrophysical well log Analysis A Case Study from Khipro Block Southern Indus Basin Pakistan, International Journal of Engineering Works, Vol. 6 Issue 04 PP. 132-142 April 2019

References

[1] Tsa, C.C., C.S., Liu, P., Schnurle. Application of AVO method to analyze the seismic characteristics of gas hydrate offshore Southwestern Taiwan. 2007.

[2] Hilterman, F., Is AVO the seismic signature of lithology? A case history of Ship Shoal‐South Addition. The Leading Edge (1990). 9(6). 15–22.

[3] Beucher-Darricau, H., B. Doligez, and J.M., Yarus. Modeling complex reservoirs with multiple conditional techniques: A practical approach to reservoir characterization, in T. C. Coburn, J. M. Yarus, and R. L. Chambers, eds., Stochastic modeling and geostatistics: Principles, methods, and case studies, volume II: AAPG Computer Applications in Geology 2006. 5: 289-299.

[4] Valizadeh Alvan, H., Uncertainty of Estimated Petrophysical Parameters of Ahvaz Oil Reservoir. J, Adv Sci Eng Res. 2011. 1:165-176.

[5] Ehinola, O. A., et al., Geology, geochemistry and biomarker evaluation of Lafia-Obi coal, Benue Trough, Nigeria. Fuel, (2002). 81(2) 219-233.

[6] Aigbedion, I., and S.E.. Iyayi. Formation evaluation of Oshioka field using Geophysical well logs." Middle-East J. Sci. Res. 2007. 2(3-4): 107-110.

[7] Searlc, M.P., Geology and Tectonics of the Karakoram Mountains. Chichester (John Wiley and Sons Ltd.), 1991. 358.

[8] [15] Powell, C.M., A speculative tectonic history of Pakistan and surroundings: Some constraints from the Indian Ocean.” In: Farah, A. & DeJong, K. A. (eds.) Geodynanmics of Pakistan. Geol. Surv. Quetta, Pak. 1979. 1-451.

[9] Khan, S.D., et al., Did the Kohistan-Ladakh island arc collide first with India?." Geological Society of America Bulletin, 2009. 121(3-4): 366-384.

[10] Valdiya, K.S., Emergence and evolution of Himalaya: reconstructing history in the light of recent studies. Progress in physical geography. 2002. 26(3): 360-399.

[11] Chaudhry, M.N., M. Ghazanfar, J.G. Ramsay, D.A. Spencer and M. Qayyumm. Northwest Himalaya – A Tectonic subdivision. 175-184, Feburary 1994 In; (Eds: Ahmed, R and Shiekh, A.M) Geology in South Asia-1: Proceeding of First South Asia Geological Congress. Islamabad, Pakistan:

[12] Burg, J.P., J.L., Bodinier, S.H., Chaudhry and H., Dawood. Infra-arc mantle-crust transition and intra-arc mantle diapirs in the Kohistan complex (Pakistani Himalaya): petro-structural evidence." TERRA NOVA-OXFORD 1998. 10: 74-80.

[13] Khan, M.A., S., Rehman, M., Fahad ullah and N., Ahsan. Geochemistry and tectonic environments of Babusar amphibolites in southeast Kohistan, Pakistan. Geol. Bull. Punjab Univ 2009. 44: 105-116.

[14] Khan, M.A., S., Rehman and N., Ahsan. Geology and geochemistry of Sumal amphibolites, Kamila amphibolite unit, southeast Kohistan, Pakistan. Int. J. Agric. Appl. Sci, 2012. 4(2): 99-111.

[15] Qadri I.B., Petroleum geology of Pakistan: Pakistan Petroleum Limited. Karachi, Pakistan. 1995.

[16] Zaigham, N.A., and K.A., Mallick. Prospect of hydrocarbon associated with fossil-rift structures of the southern Indus basin, Pakistan."AAPG bulletin. 2000. 84(11): 1833-1848.

[17] Faisal, M., F.,Rehman, S., Rehman and N., Ahsan. Better perceptive and enhanced visualization of seismic profiles for the exploration of hydrocarbon using a seismic and synthetic seismogram modeling of Khipro Block, Southern Indus Basin, Sindh Province, Pakistan." Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 2013. 35(22): 2101-2112.

[18] Ahmad, Z., G. Akhter, F., Bashir, M.A., Khan, and M., Ahmad. Structural interpretation of seismic profiles integrated with reservoir characteristics of Bitrism block (Sind Province), Pakistan." Energy Sources, Part A: Recovery, Utilization, and Environmental Effects. 2009. 32(4): 303-314,

[19] Burg, J.P., J.L., Bodinier, S.H., Chaudhry and H., Dawood. Infra-arc mantle-crust transition and intra-arc mantle diapirs in the Kohistan complex (Pakistani Himalaya): petro-structural evidence." TERRA NOVA-OXFORD 1998. 10: 74-80.

[20] Khan, M.A., S., Rehman, M., Fahad ullah and N., Ahsan. Geochemistry and tectonic environments of Babusar amphibolites in southeast Kohistan, Pakistan. Geol. Bull. Punjab Univ 2009. 44: 105-116.

[21] Khan, M.A., S., Rehman and N., Ahsan. Geology and geochemistry of Sumal amphibolites, Kamila amphibolite unit, southeast Kohistan, Pakistan. Int. J. Agric. Appl. Sci, 2012. 4(2): 99-111.

[22] Qadri I.B., Petroleum geology of Pakistan: Pakistan Petroleum Limited. Karachi, Pakistan. 1995.

[23] Zaigham, N.A., and K.A., Mallick. Prospect of hydrocarbon associated with fossil-rift structures of the southern Indus basin, Pakistan."AAPG bulletin. 2000. 84(11): 1833-1848.

[24] Faisal, M., F.,Rehman, S., Rehman and N., Ahsan. Better perceptive and enhanced visualization of seismic profiles for the exploration of hydrocarbon using a seismic and synthetic seismogram modeling of Khipro Block, Southern Indus Basin, Sindh Province, Pakistan." Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 2013. 35(22): 2101-2112.

Novel Light Trapping in Thin film Solar Cells with Nano Particles and Integrated Diffraction Grating

Vol.6, Issue 04, PP. 126-131, April 2019

Published online Novel Light Trapping in Thin film Solar Cells with Nano Particles and Integrated Diffraction Grating

PDF

Abstract

To over come the lower absorption of solar radiation in thin film solar cell a novel technique of combining metallic grating and metallic nano particle is presented. The increase in absorption is associated with localized surface Plasmon’s resonance that depends on many factors ranging from the size of nano particle to its shape, material of nano particle, polarization of light and the medium of enviroment in which the solar cell is placed. The solar cell is designed in COMSOL Multiphysics environment which uses the numerical finite element method (FEM). The enhancement of absorption of spectral density in the solar radiation is demonstrated, theoretically. The collective oscillaton of the metallic nano particles and metallic grating produces individual electric field thus interacting with each other to produce higher modes of excitation. This collective mode supports the dark modes of nano partiles which is very useful for harnessing the long range of radiation. To reduce reflection from the top of solar cell, anti reflection coating is provided at the top whereas the back of solar cell is made of metallic reflector aluminium. The different simulations reveals that the antireflection coating has negligent effect on the absorption of solar cell by using the integrated structure of metallic grating and nano particles. Moreover, this approach is suited for thin film solar cell which will absorb more radiations due to the multiple peaks in the spectrum of the aforementioned proposed structure.

Author

Fazal E Hilal: University of Engineering and Technology Peshawar, Pakistan, U.S Pakistan Center for Advanced Studies in Energy (USPCAS-E)
Adnan Daud Khan: University of Engineering and Technology Peshawar, Pakistan, U.S Pakistan Center for Advanced Studies in Energy (USPCAS-E)
Muhammad Noman: University of Engineering and Technology Peshawar, Pakistan, U.S Pakistan Center for Advanced Studies in Energy (USPCAS-E)
Fazal E Subhan: University of Engineering and Technology Peshawar, Pakistan, U.S Pakistan Center for Advanced Studies in Energy (USPCAS-E)
Mohsin Hamid: University of Engineering and Technology Peshawar, Pakistan, U.S Pakistan Center for Advanced Studies in Energy (USPCAS-E)
Aimal Daud Khan: Sarhad University of Science and Information Tecnology (SUIT)

Cite

Fazal E Hilal Adnan Daud Khan Muhammad Noman Fazal E Subhan Mohsin Hamid and Aimal Daud Khan, Novel Light Trapping in Thin Film Solar Cells with Nano Particles and Integrated Diffraction Grating, International Journal of Engineering Works, Vol. 6 Issue 04 PP. 126-131 April 2019

References

M. Green, "Lambertian light trapping in textured solar cells and light-emitting diodes: analytical solutions", Progress in Photovoltaics: Research and Applications, vol. 10, no. 4, pp. 235-241, 2002.
H. Atwater and A. Polman, "Plasmonics for improved photovoltaic devices", Nature Materials, vol. 9, no. 3, pp. 205-213, 2010.
V. Ferry, J. Munday and H. Atwater, "Design Considerations for Plasmonic Photovoltaics", Advanced Materials, vol. 22, no. 43, pp. 4794-4808, 2010.
W. Barnes, A. Dereux and T. Ebbesen, "Surface plasmon subwavelength optics", Nature, vol. 424, no. 6950, pp. 824-830, 2003.
C. Rockstuhl, S. Fahr and F. Lederer, "Absorption enhancement in solar cells by localized plasmon polaritons", Journal of Applied Physics, vol. 104, no. 12, p. 123102, 2008.
H. Lu and W. Wang, "Surface plasmon resonance absorption of composite films doped with metal nanoparticles", Optical Engineering, vol. 56, no. 6, p. 067110, 2017.
X. Li, "Plasmonic nanostructures for custom photonic devices", SPIE Newsroom, 2014.
P. Spinelli and A. Polman, "Light Trapping in Thin Crystalline Si Solar Cells Using Surface Mie Scatterers", IEEE Journal of Photovoltaics, vol. 4, no. 2, pp. 554-559, 2014.
C. Fei Guo, T. Sun, F. Cao, Q. Liu and Z. Ren, "Metallic nanostructures for light trapping in energy-harvesting devices", Light: Science & Applications, vol. 3, no. 4, pp. e161-e161, 2014.
H. Tran, V. Nguyen, B. Nguyen and D. Vu, "Light trapping and plasmonic enhancement in silicon, dye-sensitized and titania solar cells", Advances in Natural Sciences: Nanoscience and Nanotechnology, vol. 7, no. 1, p. 013001, 2016.
Chu, Steven, and Arun Majumdar. "Opportunities and challenges for a sustainable energy future." nature 488.7411 (2012): 294.
Kamat, Prashant V. "Meeting the clean energy demand: nanostructure architectures for solar energy conversion." The Journal of Physical Chemistry C 111.7 (2007): 2834-2860.
Serrano, Elena, Guillermo Rus, and Javier Garcia-Martinez. "Nanotechnology for sustainable energy." Renewable and Sustainable Energy Reviews 13.9 (2009): 2373-2384
Senthil Kumar, N., et al. "Green mediated synthesis of plasmonic nanoparticle (Ag) for antireflection coating in bare mono silicon solar cell." Journal of Materials Science: Materials in Electronics (2018): 1-10.
Heidarzadeh, Hamid, et al. "Plasmon-enhanced performance of an ultrathin silicon solar cell using metal-semiconductor core-shell hemispherical nanoparticles and metallic back grating." Applied optics 55.7 (2016): 1779-1785.
Al-Adhami, Yasir, and Ergun Ercelebi. "A Plasmonic Monopole Antenna Array on Flexible Photovoltaic Panels for Further Use of the Green Energy Harvesting." Progress in Electromagnetics Research 68 (2018): 143-152.
Jiao, Hongfei, et al. "Ultra-broadband perfect absorber based on successive Nano-Cr-film." Advances in Optical Thin Films VI. Vol. 10691. International Society for Optics and Photonics, 2018.
Saravanan, S., et al. "Efficiency improvement in dye sensitized solar cells by the plasmonic effect of green synthesized silver Nano-particles." Journal of Science: Advanced Materials and Devices 2.4 (2017): 418-424.
Sakir, Menekse, et al. "Fabrication of Plasmonically Active Substrates Using Engineered Silver Nanostructures for SERS Applications." ACS applied materials & interfaces 9.45 (2017): 39795-39803.
Katyal, Jyoti, and R. K. Soni. "Localized surface Plasmon resonance and refractive index sensitivity of metal–dielectric–metal multilayered nanostructures." Plasmonics 9.5 (2014): 1171-1181
Ge, Lixin, et al. "Unidirectional scattering induced by the toroidal dipolar excitation in the system of plasmonic nanoparticles." Optics Express 25.10 (2017): 10853-10862.
N.-N. Feng, J. Michel, L. Zeng, J. Liu, C.-Y. Hong, L. C. Kimerling, and X. Duan, “Design of Highly Efficient Light-Trapping Structures of Thin-Film Crystalline Silicon Solar Cells,” IEEE Trans. Electron. Dev. 54(8), 1926–1933 (2007).
H. Sai, Y. Kanamori, K. Arafune, Y. Ohshita, and M. Yamaguchi, “Light trapping effect of submicron surface textures in crystalline Si solar cells,” Prog. Photovoltaics 15(5), 415–423 (2007).
V. E. Ferry, M. A. Verschuuren, H. B. T. Li, E. Verhagen, R. J. Walters, R. E. I. Schropp, H. A. Atwater, and A. Polman, Light trapping in ultrathin plasmonic solar cells, Opt. Express 18, A237 (2010).
V.Ferry,L.Sweatlock,D.Paciﬁci,andH.Atwater,Plasmonicnanostructuredesign for efﬁcient light coupling into solar cells, Nano Lett. 8, 4391 (2008).
V. E. Ferry, J. N. Munday, and H. A. Atwater, Design considerations for plasmonic photovoltaics, Adv. Mater. 22, 4785 (2010)
D. Bouhafs, "Design and simulation of antireflection coating systems for optoelectronic devices: Application to silicon solar cells", Solar Energy Materials and Solar Cells, vol. 52, no. 1-2, pp. 79-93, 1998.
K. Park, H. Choi, C. Chang, R. Cohen, G. McKinley and G. Barbastathis, "Nanotextured Silica Surfaces with Robust Superhydrophobicity and Omnidirectional Broadband Supertransmissivity", ACS Nano, vol. 6, no. 5, pp. 3789-3799, 2012
J. Son, S. Kundu, L. Verma, M. Sakhuja, A. Danner, C. Bhatia and H. Yang, "A practical superhydrophilic self cleaning and antireflective surface for outdoor photovoltaic applications", Solar Energy Materials and Solar Cells, vol. 98, pp. 46-51, 2012.
T. Yang, X. Wang, W. Liu, Y. Shi and F. Yang, "Double-layer anti-reflection coating containing a nanoporous anodic aluminum oxide layer for GaAs solar cells", Optics Express, vol. 21, no. 15, p. 18207, 2013
Jung, S., Kim, Y., Kim, S. and Yoo, S. (2011). Design and fabrication of multi-layer antireflection coating for III-V solar cell. Current Applied Physics, 11(3), pp.538-541
Saravanan, S. and Dubey, R. (2017). Grating influence study of GaAs solar cell structures. Nanosystems: Physics, Chemistry, Mathematics, pp.503-506.
T. Markvart, "Beyond the Yablonovitch limit: Trapping light by frequency shift", Applied Physics Letters, vol. 98, no. 7, p. 071107, 2011
Y. Shi, X. Wang, W. Liu, T. Yang and F. Yang, "Light-absorption enhancement in thinfilm silicon solar cells with front grating and rear-located nanoparticle grating", physica status solidi (a), vol. 212, no. 2, pp. 312-316, 2014.
S. Castelletto and A. Boretti, "Noble Metal Nanoparticles in Thin Film Solar Cells", Nanoscience and Nanotechnology Letters, vol. 5, no. 1, pp. 36-40, 2013.
] C. Joshi, Y. Shim, T. Bigioni and J. Amar, "Critical island size, scaling, and ordering in colloidal nanoparticle self-assembly", Physical Review E, vol. 90, no. 3, 2014.
A. Baca, M. Meitl, H. Ko, S. Mack, H. Kim, J. Dong, P. Ferreira and J. Rogers, "Printable Single-Crystal Silicon Micro/Nanoscale Ribbons, Platelets and Bars Generated from Bulk Wafers", Advanced Functional Materials, vol. 17, no. 16, pp. 3051-3062, 2007
J. Yoon, A. Baca, S. Park, P. Elvikis, J. Geddes, L. Li, R. Kim, J. Xiao, S. Wang, T. Kim, M. Motala, B. Ahn, E. Duoss, J. Lewis, R. Nuzzo, P. Ferreira, Y. Huang, A. Rockett and J. Rogers, "Ultrathin silicon solar microcells for semitransparent, mechanically flexible and microconcentrator module designs", Nature Materials, vol. 7, no. 11, pp. 907-915, 2008.
W. Chen, A. Cardin, M. Koirala, X. Liu, T. Tyler, K. West, C. Bingham, T. Starr, A. Starr, N. Jokerst and W. Padilla, "Role of surface electromagnetic waves in metamaterial absorbers", Optics Express, vol. 24, no. 6, p. 6783, 2016.
G. Wang, M. Liu, X. Hu, L. Kong, L. Cheng and Z. Chen, "Multi-band microwave metamaterial absorber based on coplanar Jerusalem crosses", Chinese Physics B, vol. 23, no. 1, p. 017802, 2014
S. Liu, J. Zhuge, S. Ma, H. Chen, D. Bao, Q. He, L. Zhou and T. Cui, "A bi-layered quad-band metamaterial absorber at terahertz frequencies", Journal of Applied Physics, vol. 118, no. 24, p. 245304, 2015.
C. Sun and X. Wang, "Efficient Light Trapping Structures of Thin Film Silicon Solar Cells Based on Silver Nanoparticle Arrays", Plasmonics, vol. 10, no. 6, pp. 1307-1314, 2015.
S. Saravanan, R. Dubey, S. Kalainathan, M. More and D. Gautam, "Design and optimization of ultrathin crystalline silicon solar cells using an efficient back reflector", AIP Advances, vol. 5, no. 5, p. 057160, 2015.
Sangjun Lee and Sangin Kim, "Optical Absorption Characteristic in Thin a-Si Film Embedded Between an Ultrathin Metal Grating and a Metal Reflector", IEEE Photonics Journal, vol. 5, no. 5, pp. 4800610-4800610, 2013.
L. Zhu, M. Shao, R. Peng, R. Fan, X. Huang and M. Wang, "Broadband absorption and efficiency enhancement of an ultra-thin silicon solar cell with a plasmonic fractal", Optics Express, vol. 21, no. 3, p. A313, 2013.
L. Hong, Rusli, X. Wang, H. Zheng, L. He, X. Xu, H. Wang and H. Yu, "Design principles for plasmonic thin film GaAs solar cells with high absorption enhancement", Journal of Applied Physics, vol. 112, no. 5, p. 054326, 2012.
D. Bouhafs, "Design and simulation of antireflection coating systems for optoelectronic devices: Application to silicon solar cells", Solar Energy Materials and Solar Cells, vol. 52, no. 1-2, pp. 79-93, 1998
Ferry, Vivian E., et al. "Light trapping in ultrathin plasmonic solar cells." Optics express 18.102 (2010): A237-A245.
Catchpole, KR and, Albert Polman. "Plasmonic solar cells." Optics express 16.26 (2008): 21793- 21800.
Temple, T. L., et al. "Influence of localized surface Plasmon excitation in silver nanoparticles on the performance of silicon solar cells." Solar Energy Materials and Solar Cells 93.11 (2009): 1978-1985.
Dodson, Stephanie, et al. "Optimizing electromagnetic hotspots in plasmonic bowtie Nano antennae." The journal of physical chemistry letters 4.3 (2013): 496-501.
Katyal, Jyoti, and R. K. Soni. "Localized surface Plasmon resonance and refractive index sensitivity of metal–dielectric–metal multilayered nanostructures." Plasmonics 9.5 (2014): 1171-1181.
Sakir, Menekse, et al. "Fabrication of Plasmonically Active Substrates Using Engineered Silver Nanostructures for SERS Applications." ACS applied materials & interfaces 9.45 (2017): 39795-39803.
Roelli, Philippe, et al. "Molecular cavity optomechanics as a theory of plasmon-enhanced Raman scattering." Nature nanotechnology 11.2 (2016): 164-169.
Katyal, Jyoti, and R. K. Soni. "Localized surface Plasmon resonance and refractive index sensitivity of metal–dielectric–metal multilayered nanostructures." Plasmonics 9.5 (2014): 1171-1181.

Speed and Direction Control of a DC Motor using Dual Converter Technique

Vol. 6, Issue 04, PP. 120-125, April 2019

Published online Speed and Direction Control of a DC Motor using Dual Converter Technique

PDF

Abstract

This Paper presents the basic concept and methodology variable levels of DC voltage as well as reversal of polarity (without changing terminals physically). The circuit has been designed for this purpose can break into two parts: Dual H-bridge Converter and Microcontroller. Dual H-bridge converter is available in the form of L293D IC and L298N.The total power loss of existing system i.e. 8051 microcontroller with L293D was 1.7365W. While the total power loss of PIC microcontroller with L293D was1.56165W So, We have chosen proposed Atmega328 I.C because the power loss has been reduced to 1.560115w. The Microcontroller Atmega328is programmed with C++ language. The Atmega328 microcontroller provides pulses to the gate of the NPN and PNP transistor for the required output DC voltage and polarity, which runs the DC motor.

Author

Ubaid Hussain: PG Research student, Dept. of EEE, University of Engineering and technology Peshawar, KP, Pakistan.
Sohail Gul: PG Research student, Dept. of EEE, University of Engineering and technology Peshawar, KP, Pakistan.
Dr. Muhammad Naeem Arbaab: Research Scholar, Dept. of EEE, University of Engineering and technology Peshawar, KP, Pakistan.
Amjad Khan: PG Research student, Dept. of EEE, University of Engineering and technology Peshawar, KP, Pakistan.

Cite

Ubaid Hussain Sohail Gul Dr. Muhammad Naeem Arbaab and Amjad Khan, Speed and Direction Control of a DC Motor using Dual Converter Technique, International Journal of Engineering Works, Vol. 6 Issue 04 PP. 120-125 April 2019

References

Asha K R, SuhadaTasleemP“RealS Time Speed Control of a DC motor by Temperature Variation using LabVIEW and Arduino” 2017 International Conference on Recent Advances in Electronics and Communication Technology, 16-17 March 2017
Mario Gavran*, MatoFruk** and GoranVujisić“ PI controller for DC motor speed realized with Arduino and Simulink” 22-26 May 2017
L.Boaz1, S.Priyatharshini2“DC Motor Direction and Speed Control byArduino through RF Wireless Technique” International Journal of Innovative Research in Computerand Communication Engineering ,Vol. 4, Special Issue 2, April 2016.
Lei Zhao, ChuangyuXu, XuemeiZheng and Haoyu Li “A Dual Half-Bridge Converter with Adaptive EnergyStorage to Achieve ZVS over Full Range ofOperation Conditions” Energies Article, 28 March 2017.
ShashiBhushan Kumar, Mohammed Hasmat Ali*, AnshuSinha, “Design and Simulation of Speed Control of DC Motor by Artificial Neural Network Technique” International Journal of Scientific and Research Publications, Volume 4, Issue 7, July 2014.
Oun Lee, Shin-Young Cho, and Gun-Woo Moon “Phase-Shifted Dual H-Bridge Converter with a Wide ZVS Rangeand Reduced Output Filter” IEEE, 2012.
Zhe Zhang and Michael A. E. Andersen“Interleaved Boost-Half-Bridge Dual–Input DC-DCConverter with a PWM plus Phase-Shift Control forFuel Cell Applications” IECON, IEEE, 2013.
WasanPhetphimoon “Modeling and Simulation of Bidirectional Half Bridge DC-DC Converter” ELEKTRO, IEEE, 2016
G.SUDHA1, “Performance Based Comparison Between Various Z-N Tuninng PID And Fuzzy Logic PID Controller In Position Control System Of Dc”, International Journal on Soft Computing (IJSC) Vol.3, No.3, August 2012.
Manoj Kushwah1 and Prof. Ashis Patra2, “Tuning PID Controller for Speed Control of DC Motor Using Soft Computing Techniques-A Review” Advance in Electronic and Electric Engineering, Volume 4, Number 2 (2014), pp. 141-148.
J. C. Basilio and S. R. Matos, “Design of PI and PID Controllers With Transient Performance Specification”,,” IEEE Trans. Education, vol. 45, Issue No. 4, 2002, pp. 364- 370
AdityaPratap Singh, “Speed Control of DC Motor using PID Controller Based on Matlab” International Conference on Recent Trends in Applied Sciences with Engineering Applications, Vol.4, No.6, 2013.
Rahul Malhotra1, Narinder Singh2, Yaduvir Singh3, “SOFT COMPUTING TECHNIQUES FOR PROCESS CONTROL APPLICATIONS” International Journal on Soft Computing (IJSC), Vol.2, No.3, August 2011.
MdAkram Ahmad, PankajRai, “Speed control of a DC motor using Controllers” Automation, Control and Intelligent Systems,2014; 2(6-1): 1-9
Ramesh Chandra Chourasia, Mukesh Kumar, “Speed Control of S.E.D.C. Motor by Using Pi and Fuzzy Logic Controller” International Journal of Soft Computing and Engineering (IJSCE),Volume-3, Issue-2, May 2013.
J. C. Basilio and S. R. Matos,“Design of PI and PID Controllers With Transient Performance Specification”, ,” IEEE Trans. Education, vol. 45, Issue No. 4, 2002, pp. 364- 370.
ShashiBhushan Kumar, Mohammed Hasmat Ali*, AnshuSinha, “Design and Simulation of Speed Control ofDC Motor by Artificial Neural Network Technique” International Journal of Scientific and Research Publications, Volume 4, Issue 7, July 2014.
KapinjayUcharia, Himmat Singh, “International Journal of Scientific Engineering and Technology” Volume No.3 Issue No.3, pp : 235 – 239 1 March 2014.
AdityaPratap Singh, “Speed Control of DC Motor using Pid Controller Based on Matlab” Innovative Systems Design and Engineering, Vol.4, No.6, 2013 - Selected from International Conference on Recent Trends in Applied Sciences with Engineering Applications.
P. M. Meshram, Rohit G. Kanojiya “Tuning of PID Controller using Ziegler-Nichols Method for Speed Control of DC Motor” IEEE- International Conference On Advances In Engineering, Science And Management (ICAESM -2012) March 30, 31,2012 117.

Bandwidth Improvement and Reduced Size MPA Design using HIS

Vol. 6, Issue 04, PP. 113-119, April 2019

Published online Bandwidth Improvement and Reduced Size MPA Design using HIS

PDF

Abstract

Recently, there has been extensive research on high impedance structure (HIS) and their applications in microstrip antennas and transmission lines. These periodic structures have unique property of preventing the propagation of electromagnetic waves for specific frequencies and directions which are defined by the shape, size, symmetry, and material used in their construction. These structures also facilitate in bandwidth enhancement of planar antennas. In this article, a mizrostrip patch antenna (MPA) is designed to operate at 3.5 GHz. Then a mushroom type HIS ground plane is designed in the operating band of MPA which is further integrated. Aim of this configuration is to enhance bandwidth of the MPA through incorporation of HIS plane, Bandwidth of the MPA is evaluated with and without HIS plane. All the designs and simulations are carried out in CST microwave studio.

Author

Muhammad Saleem Khan:University of Engineering and Technology Peshawar Pakistan
Irfan Khattak: University of Engineering and Technology Peshawar Pakistan
Muhammad Sulman Khan: University of Engineering and Technology Peshawar Pakistan
Asaf Khan: University of Engineering and Technology Peshawar Pakistan

Cite

Muhammad Saleem Khan Irfan Khattak Muhammad Salman Khan and Asaf Khan, Bandwidth Improvement and Reduced Size MPA Design using HIS, International Journal of Engineering Works, Vol. 6 Issue 03 PP. 113-118March 2019,

References

[1] A. Pirhadi, F. Keshmiri, M.Hakkak, and M. Tayarani, “Analysis and design of dual band high directivity EBG resonator antenna using square loop FSS AS superstrate layer,” Progress in Electromagnetics Research, vol. 70, pp. 1–20, 2007.
[2] A. Sihvola, “Electromagnetic emergence in metamaterials”, Advances in Electromagnetics of Complex Media and Metamaterials, vol. 89, pp. 1-17, 2003.
[3] J. Zehentner and J. Machac, “Volumetric single negative metamaterials”, Proceedings of Metamaterials Congress, pp. 22–24, 2007
[4] N. Engheta, “Metamaterials with negative permittivity and permeability: background, salient features, and new trends”, IEEE MTT-S International Microwave Symposium Digest, pp. 187-190, 2003.
[5] N. Engheta, “Design, fabrication, and testing of double negative metamaterials”, IEEE Transactions on Antennas and Propagation, vol. 51, issue. 7, pp. 1516-1529, 2003
[6] W. R. Ziolkowski and N. Engheta, “Metamaterials: Physics and Engineering Explorations”, John Wiley & Sons, Inc., 18 September 2006.
[7] D. Sievenpiper, “High Impedance Electromagnetic Surfaces”, Ph.D. dissertation, Electrical Engineering Department, University of California, Los Angeles, 1999.
[8] P. Kovács, Z. Raida, M. Martínez-Vázquez, “Parametric study of mushroom-like and planar periodic Structures in terms of simultaneous AMC and EBG Properties”, Radio Engineering, vol. 17, no. 4, pp. 19-24, December 2008.
[9] S. K. Hampel, O. Schmitz, O. Klemp, and H. Eul, “Design of Sievenpiper HIS for use in planar broadband antennas by means of effective medium theory”, Adv. Radio Sci., pp. 87-94, 2007.
[10] F. Yang and Y. Rahmat-samii, “Reflection phase characterisation of EBG ground plane for low profile wire antenna applications”, IEEE Transactions on Antennas and Propagation, vol. 51, no. 10, October 2003
[11] D. F. Sievenpiper, J. H. Schaffner, H. J. Song, R. Y. Loo, “Two-dimensional beam steering using an electrically tunable impedance surface”, IEEE Transactions on Antennas and Propagation, vol. 51, no. 10, pp. 2713-2722, October 2003.
[12] G. Poilasne, “Antennas on High impedance ground planes: on the importance of the antenna isolation,” Progress in Electromagnetics Research, vol. 41, pp. 237–255, 2003.
[13] S. Zhu and R. Langley, “Dual-band wearable textile antenna on an EBG substrate,” IEEE Transactions on Antennas and Propagation, vol. 57, no. 4, pp. 926–935, 2009.
[14] M. Mantash, A. C. Tarot, S. Collardey, and K. Mahdjoubi, “Dual-band antenna for WLAN application with EBG,” in the 4th International Congress on Advanced Electromagnetic Materials in Microwaves and Optics, pp. 794–796, Karlsruhe, Germany, September 2010.
[15] M. Mantash, A. C. Tarot, S. Collardey, and K. Mahdjoubi, “Dual-band CPW-fed G-antenna using an EBG structure,” in Antennas and Propagation Conference (LAPC), pp. 453–456, Loughborough, UK, 2010.
[16] Shakelford, A., Lee, K.F., Luk, K.M.,“ Design of small-size wide-bandwidth microstrip patch antennas,” Antennas and Propagation Magazine, IEEE, vol. 45, Issue 1, pp. 75-83, Feb. 2003.
[17] Ting-Hua Liu and Wen Xun Zhang, “Compound techniques for broadening the bandwidth of microstrip patch antenna,” Microwave Conference Proceedings, vol. 1, pp. 241-244, Dec. 1997.
[18] AdilenaSlavova, A. Abdel Rahman and A.S. Omar, “Broadband bandwidth enhancement of an Aperture coupled microstrip patch antenna,” Antennas and Propagation Society International Symposium, vol. 4, pp. 3737-3740, June 2004.
[19] Tao Yuan, Jian-Ying Li, Le-Wei Li, Lei Zhang, and Mook-Seng Leong, “Improvement of Microstrip Antenna Performance Using Two Triangular Structures”, Digest of 2005 IEEE Antennas and Propagation Society International Symposium, vol. 1A, pp. 301-304, 3-8 July 2005.
[20] J.Y. Li, Zaw-ZawOo, and Le-Wei Li, “Improvement of characteristics of microstrip antennas using unbalanced structures,” IEEE Antennas and wireless Propagat. Lett, vol. 1, pp. 71-73, 2002
[21] E. Yablonvitch, “Photonic band-gap structures,” J. Opt. Soc. Amer. B, Opt. Phys. , vol. 10, no. 2, pp. 283-295, Feb 1993.
[22] Balanis, C.A., Antenna Theory: Analysis and Design, John Wiley & Sons, Inc, 1997.
[23] Kumar, G. and Ray, K.P., Broadband Microstrip Antennas, Artech House, Inc, 2003.
[24] Cisco, "Antenna Pattern and Their Meaning," Copyright © 1992–2007 Cisco Systems, Inc.
[25] B. Jecko, T. Monediere, L. Leger, “High Gain EBG Resonator Antenna”, 18th International Conference on Applied Electromagnetics and Communications, ICECom 2005, pp. 1-3, 12-14 Oct. 2005 12] R. Garg, I. Bhartia, I. Bahl, and A. Ittipiboon, Microstrip Antenna Design Handbook, Artech House, Boston, Mass, USA, 2001.
[26] G. Kumar and K. C. Gupta, “Directly coupled multiple resonator wide-band microstrip antenna,” IEEE Transactions on Antennas and Propagation, vol. 33, no. 6, pp. 588–593, 1985.
[27] F. Yang, X. X. Zhang, X. Ye, and Y. Rahmat-Samii, “Wide-band E-shaped patch antennas for wireless communications,” IEEE Transactions on Antennas and Propagation, vol. 49, no. 7, pp. 1094–1100, 2001.
[28] E. Rajo-Iglesias, L. Incl´an-S´anchez, and O. Quevedo-Teruel, “Back radiation reduction in patch antennas using planar soft surfaces,” Progress In Electromagnetics Research Letters, vol. 6, pp. 123–130, 2009.
[29] Z. Duan, S. Qu, and Y. Hou, “Electrically small antenna inspired by spired split ring resonator,” Progress In Electromagnetics Research Letters, vol. 7, pp. 47–57, 2009.
[30] F. Yang and Y. Rahmat-Samii, “Electromagnetic Band-Gap Structures in Antenna Engineering”, The Cambridge RF and Microwave Engineering Series, Cambridge University Press, Cambridge, Mass, USA, 2008.
[31] M. E. De Cos, F. L. Heras, and M. Franco, “Design of planar artificial magnetic conductor ground plane using frequency selective surfaces for frequencies below 1GHz,” IEEE Antennas and Wireless Propagation Letters, vol. 8, pp. 951–954, 2009.
[32] O. Luukkonen, C. R. Simovski, and S. A. Tretyakov, “Grounded uniaxial material slabs as magnetic conductors,” Progress in Electromagnetics Research B, no. 15, pp. 267–283, 2009.
[33] H. Shaban, H. Elmikaty, and A. A. Shaalan, “Study the effects of electromagnetic band-gap (EBG) substrate on two patch microstrip antenna,” Progress in Electromagnetics Research B, vol. 10, pp. 55–74, 2008.
[34] F. Yang and Y. Rahmat-Samii, “Reflection phase characterizations of the EBG ground plane for low profile wire antenna,” IEEE Transactions on Antennas and Propagation, vol. 51, no. 10, pp. 2691–2703, 2003.
[35] J. R. Sohn, K. Y. Kim, H. S. Tae, and J. H. Lee, “Comparative study on various artificialmagnetic conductors for low-profile antenna,” Progress in Electromagnetics Research, vol. 61, pp. 27–37, 2006.
[36] S. Chaimool, K. L. Chung, and P. Akkaraekthalin, “Bandwidth and gain enhancement of microstrip patch antennas using reflective metasurface,” IEICE Transactions on Communications, vol. E93-B, no. 10, pp. 2496–2503, 2010.
[37] J. Liang and H. Y. D. Yang, “Radiation characteristics of a microstrip patch over an electromagnetic bandgapsurface,”IEEE Transactions on Antennas and Propagation, vol. 55, no. 6, pp. 1691–1697, 2007.
[38] D. Sievenpiper, L. Zhang and E. Yablonovitch, “High-Impedance Electromagnetic Ground Planes”, IEEE MlT-S Digest, vol. 4, pp. 1529-1532, 1999.
[39] Qian Y., Coccioli R., Sievenpiper D., Radisic V., Yablonovitch E., and Itoh T., “A Microstrip Patch Antenna using novel photonic bandgap structures”, Microwave J., vol 42, pp. 66-76, Jan 1999.
[40] Z. Duan, D. Linton, W. Scanlon, and G. Conway, “Using EBG to Improve Antenna Efficiency in Proximity to the Human Body”, Institution of Engineering and Technology Seminar on Wideband, Multiband Antennas and Arrays for Defence or Civil Applications, pp. 173-180, London, 13-13 March 2008.
[41] X. L. Bao, G. Ruvio, M. J. Ammann, and M. John, “A novel GPS patch antenna on fractal Hi-Impedance surface Substrate”, IEEE Antenna and Wireless Propagation Letters, vol. 5, 2006.
[42] R. Baggen, M. Martínez-Vázquez and J. Leiss, “Low Profile GALILEO Antenna using EBG Technology”, IEEE Transactions on Antennas and Propagation, vol. 56, no. 3, pp. 667-674, March 2008.
[43] F. Yang, Y. Rahmat-Samii, “Polarization-Dependent Electromagnetic Band Gap (PDEBG) structures: designs and applications”, Microwave and Optical Technology Letters, vol. 41, issue. 6, pp. 439–444, June 20, 2004.
[44] Y. Fu and N. Yuan, “Surface-wave bandgap of Polarisation dependent Electromagnetic bandgap Structures”, Microwave and Optical Technology Letters, vol. 49, issue 4, pp. 946–949, 26 February 2007.
[45] D. Yan, Q. Gao, C. Wang, C. Zhu, N. Yuan, “A novel polarisation convert surface based on artificial magnetic conductor”, Asia-Pacific Microwave Conference Proceedings, APMC 2005, vol. 3, pp. 4-7, December 2005.
[46] P. J. Ferrer, B. Kelem and C. Craeye, “Design of broadband transpolarizing surfaces”, Microwave and Optical Technology Letters, vol. 48, no. 12, pp. 2606-2611, December 2006.

Optimization of off Grid Solar-Gas Generator Hybrid Power System for Rural Area of District Karak, Pakistan

Vol. 6, Issue 03, PP. 106-112, March 2019

Published online Optimization of off Grid Solar-Gas Generator Hybrid Power System for Rural Area of District Karak, Pakistan

PDF

Abstract

The environmental impact of using conventional thermal energy sources for generating electricity and fossil fuel’s depletion fear are two major factor pushing world towards alternative energy resources. Pakistan is blessed with high potential of solar energy but hight initial cost and unpredictable nature of solar energy makes it uneconomical. Because of the shortfall and due to the bad geographical location, most of the rural areas in Pakistan have no access to central grid.Although some of the remote community is served by the local fuel generator for just a couple of hour at night, but increasing rate of fuel is issue which makes this system non-economical and also have harmful effect on the surrounding to emit carbon dioxide and carbon mono oxide gases. To decrease dependency on hydrocarbon base generator and cope the unpredictable nature of Photovoltaic (PV) system, an off grid hybrid solar-gas generator with battery storage is presented in this research work for the electrification of rural areas of Pakistan. Purpose of this research work is to model optimize and stable system with minimum net present cost and low cost of electricity using HOMER software.

Author

Shifaat Ur Rehman: US Pakistan Center For Advanced Studies in Energy, University of Engineering and Technology, Peshawar, Pakistan

Tanvir Ahmad: US Pakistan Center For Advanced Studies in Energy, University of Engineering and Technology, Peshawar, Pakistan

Rizwan Kamal: US Pakistan Center For Advanced Studies in Energy, University of Engineering and Technology, Peshawar, Pakistan

Muhammad Ilyas: US Pakistan Center For Advanced Studies in Energy, University of Engineering and Technology, Peshawar, Pakistan

Cite

Shifaat Ur Rehman Tanvir Ahmad Rizwan Kamal Muhammad Ilyas, Optimization of off Grid Solar-Gas Generator Hybrid Power System for Rural Area of District Karak Pakistan, International Journal of Engineering Works, Vol. 6 Issue 03 PP. 106-112 March 2019

References

[1] International Energy Agency, ‘sWEO – Energy Access Database’, 2016

[2] https:en.wikipedia.org/wiki/electricity_sector_in_pakistan

[3] Current status of research on optimum sizing of stand-alone hybrid solar-wind power generation systems by Wei Zhou, chengzhi Lou, zhongshi li, lin lu, hongxing yang (applied energy 87(2011) 380-389)

[4] “Chaos in power: Pakistan’s electricity crisis” Development Research Group, The World Bank I.N. Kessides / Energy Policy 55 (2013) 271–285

[5] R. Szweda. “Renewable energy applications in the Indian subcontinent,” photovoltaics bulletin, vol. 2003, pp. 7-9 2003

[6] Prospects for harnessing renewable energy sources in Pakistan by S.M Hasnain and B.M Grabs

[7] A. Bhomik, et al., “Renewable energy for sustainable development in India: Review on status, potential and policies,” 2012

[8] I. Dinecr, “Renewable and sustainable development: a crucial review,” Renewable and sustainable review, vol 9, pp.157-175, 2000

[9] [9] Yang HX, Zhou E, Lu, L, Fang ZH. Optimal sizing for standalone hybrid solar-wind system with LPS technology by using genetic algorithm, Sola energy 2008; 82(4):354-67

[10] http://www.fallingrain.com/world/PK/03/Karak.html

[11] 1998 District Census report of Karak Census publication. 97. Islamabad: Population Census Organization, Statistics Division, Government of Pakistan. 2000.

[12] "Pakistan Bureau of Statistics Census 2017" (PDF). www.pbscensus.gov.pk. Retrieved 26 September2017.

[13] "Vast reserves of oil, gas in Karak". DAWN.COM. 20 December 2009. Retrieved 27 September 2017

[14] http://www.pbs.gov.pk/content/district-glance-karak

[15] “Photovoltaic Application in Rural Area of the Developing World” by Gerald Foley

Statistical Determination of Climate-Specific defects and Degradation Modes in PV Modules

Vol. 6, Issue 03, PP. 98-105, March 2019

Published online Statistical Determination of Climate-Specific defects and Degradation Modes in PV Modules

PDF

Abstract

In the last decade, there has been a dramatic increase in the numbers of photovoltaic (PV) Systems as the world shifts toward clean and sustainable energy resources. Seeing this rise in the Solar PV market, multiple new manufacturers are seeking entry into the marketplace and the need to identify the good performance modules from the bad becomes an absolute necessity. The Performance and reliable operation of PV Modules depend on many factors including materials, manufacturing processes and environmental constraints. Even best quality PV modules and systems degrade with time. The degradation rate largely depends on field conditions and manufacturers, as well as test engineers are highly interested in accurate performance modeling of the field installed PV modules. Thus two factors have been seen to give good indications of the degradation: the Performance Ratio and the Performance Index. As a power plant in Pakistan is analyzed for its degradation using these two factors in this paper, an indication on its possible lifetime can be predicted. The performance ratio method indicated at degradation of 0.61% while the performance index method indicated a degradation of 1.09%.

Author

Shakeel Ahmed: US Pakistan Center For Advance Studies in Energy, University of Engineering and Technology, Peshawar
Muhammad Younas: US Pakistan Center For Advance Studies in Energy, University of Engineering and Technology, Peshawar
Fahim-ur-Rehman:US Pakistan Center For Advance Studies in Energy, University of Engineering and Technology, Peshawar

Cite

Shakeel Ahmed Muhammad Younas and Fahim-ur-Rehman, Statistical Determination of Climate-Specific defects and Degradation Modes in PV Modules, International Journal of Engineering Works, Vol. 6 Issue 03 PP. 98-105 March 2019

References

[1] D. C. Jordan and S. R. Kurtz, âPhotovoltaic degradation rates - An Analytical Review,â Prog. Photovoltaics Res. Appl., vol. 21, no. 1, pp. 12â29, 2013.

[2] Z. Campeau, M. Mikofski PhD, E. Hasselbrink PhD, Y.-C.
Shen PhD, D. Kavulak PhD, A. Terao PhD, R. Lacerda, W. Caldwell PhD, M. Anderson PhD, Z. Defreitas, D. Degraaff PhD, A. Budiman PhD, and L. Leonard, âSunPower Module Degradation Rate,â p. 61, 2013.
[3] K. Sakuta, T. Sugiura, N. Van Der Borg, K. Van Otterdijk, S. Gmbh, A. Ohrberg, and D.- Emmerthal, âInternational Energy Agency Pvps Task 2: Analysis of the Operational Performance of the Iea Database Pv Systems,â no. May 2000, pp. 3â7, 2000.

[4] A. Chaita and J. Kluabwang, âPerformance Evaluation of 3 . 5 kWp Rooftop Solar PV Plant in Thailand,â vol. II, no. 3, pp. 988â991, 2016.

[5] P. P. G. A. E. Fernandez and E. M. F. Almonacid, Photovoltaic systems installed at the University of Jaen,â pp. 169â172.

[6] B. Decker and U. Jahn,Performance of 170 grid connected PV plants in northern Germany - Analysis of yields and optimization potentials,â Sol. Energy, vol. 59, no. 4â6â6 pt
4, pp. 127â133, 1997.

[7] K. Padmavathi and S. A. Daniel, Performance analysis of a 3MWp grid connected solar photovoltaic power plant in India,â Energy Sustain. Dev., vol. 17, no. 6, pp. 615â625, 2013.

[8] L. M. Ayompe, a. Duffy, S. J. McCormack, and M. Conlon, Measured performance of a 1.72 kW rooftop grid connected photovoltaic system in Ireland,â Energy Convers. Manag., vol. 52, no. 2, pp. 816â825, 2011.

Enhancing the Absorption and Power Conversion Efficiency of Organic Solar Cells

Vol. 6, Issue 03, PP. 94-97, March 2019

Published online Enhancing the Absorption and Power Conversion Efficiency of Organic Solar Cells

PDF

Abstract

Optimizing the thickness of organic solar cells (OSCs) is a potent way to enhance the power conversion efficiency (PCE). In the present work, we have investigated a novel structure in which poly (9, 9‐dioctylindenofluorene‐co‐benzothiadiazole) (PIF8BT): N′‐bis (1‐ethylpropyl) ‐3, 4, 9, 10‐perylene tetracarboxy diimide (PDI) is used as a photoactive absorber layer. The influence of window layer material such as Zinc oxide (ZnO) and titanium dioxide (TiO2) with various electrode materials including Indium tin oxide (ITO), Fluorine tin oxide (FTO), aluminum(Al) Silver (Ag) and Gold (Au) with different combinations have been investigated with the objective to enhance the absorption and PCE of the cell. Extracted results shows that the proposed scheme of the structure with ITO/Al as top and bottom electrode holds the highest performance parameters including Jsc=9.26 (mA/m2), Voc=0.59 (V), FF=68.86% and ƞ=3.86% respectively as compared to different electrode combination and window layers with the same photoactive absorber material( PIF8BT:PDI). This indicates that the proposed structure can be a good choice for replacing less efficient in-organic cell.

Author

Waqas Farooq: Sarhad University of Science & Information Technology, Peshawar 25000, Pakistan
Aimal Daud Khan: Sarhad University of Science & Information Technology, Peshawar 25000, Pakistan
Mahmood Khan: Sarhad University of Science & Information Technology, Peshawar 25000, Pakistan
Javed Iqbal: Sarhad University of Science & Information Technology, Peshawar 25000, Pakistan

Cite

Waqas Farooq Aimal Daud Khan Mahmood Khan and Javed Iqbal, Enhancing the Absorption and Power Conversion Efficiency of Organic Solar Cells, International Journal of Engineering Works, Vol. 6 Issue 03 PP. 94-97 March 2019

References

[1] J. Conti, "International energy outlook 2016 with projections to 2040. 2016, USDOE Energy Information Administration (EIA)," Washington, DC (United States)
[2] D. Wöhrle and D. Meissner, " Organic solar cells," Advanced Materials, 1991. 3(3): p. 129-138.
[3] S. E. Shaheen, C. J. Brabec and N. S. Sariciftci, "2.5% efficient organic plastic solar cells," Applied Physics Letters, 2001. 78(6): p. 841-843.
[4] S. Mori, H. Ohoka, H. NAakao, T. Gotanda, Y. Nakano, H. Jung, A. Iida, R. Hayase, N.Shida, M.Saito, K. Todori, T. Asakura, A. Matsui and M. Hosoya, "Organic photovoltaic module development with inverted device structure," MRS Online Proceedings Library Archive, 2015. 173
[5] G. Li, R. Zhu and Y. Yang," Polymer solar cells. Nature photonics," 2012. 6(3): p. 153.
[6] R.Po, A. Bernardi, A. Calabrese, C. Carbonera, G. Corso and A. Pellegrino," From lab to fab: how must the polymer solar cell materials design change?–an industrial perspective," Energy & Environmental Science, 2014. 7(3): p. 925-943.
[7] M. C. Scharber and N. S. Sariciftci, "Efficiency of bulk-heterojunction organic solar cells," Progress in polymer science, 2013. 38(12): p. 1929-1940.
[8] [8] M. A. Green, "Corrigendum to ‘Solar cell efficiency tables (version 49)’[Prog. Photovolt: Res. Appl. 2017; 25: 3–13]," Progress in Photovoltaics: Research and Applications, 2017. 4(25): p. 333-334.
[9] S. Holiday, R. S. Ashraf, A. Wadsworth, D. Baran, S. A. Yousaf, C. B. Nielson, C. H. Tan, S. D. Dimitrov, Z. Shang, N. Gasparini, M. Alamoudi, F. Laquai, C. J. Brabec, A. Salleo, J. R. Durrant and I. McCulloch, " High-efficiency and air-stable P3HT-based polymer solar cells with a new non-fullerene acceptor," Nature communications, 2016. 7: p. 11585.
[10] S. Cavaliere, S. Subianto, L. Savych, D. J. Jones and J. Roziere, " Electrospinning: designed architectures for energy conversion and storage devices," Energy & Environmental Science, 2011. 4(12): p. 4761-4785.
[11] H. L. Yip and A. K,-Y. Jen, " Recent advances in solution-processed interfacial materials for efficient and stable polymer solar cells," Energy & Environmental Science, 2012. 5(3): p. 5994-6011.
[12] N. Marinova, S. Valero and J. L Delgado, " Organic and perovskite solar cells: working principles, materials and interfaces," Journal of colloid and interface science, 2017. 488: p. 373-389.
[13] A. D. Khan and A. D. Khan, " Optimization of highly efficient GaAs–silicon hybrid solar cell," Applied Physics A, 2018. 124(12): p. 851.
[14] J. Ouyang, "Solution-processed PEDOT: PSS films with conductivities as indium tin oxide through a treatment with mild and weak organic acids," ACS applied materials & interfaces, 2013. 5(24): p. 13082-13088.
[15] D. J. Lipomi, J. A. Lee, M. Vosgueritchain, B. C. -K. Tee, J. A. Bolander and Z. Bao, " Electronic properties of transparent conductive films of PEDOT: PSS on stretchable substrates," Chemistry of Materials, 2012. 24(2): p. 373-382.
[16] U. Lang, N. Naujoks and J. Dual, " Mechanical characterization of PEDOT: PSS thin films," Synthetic Metals, 2009. 159(5-6): p. 473-479.
[17] D. C. Look, " Recent advances in ZnO materials and devices," Materials Science and Engineering: B, 2001. 80(1-3): p. 383-387.
[18] N. R. Mlyuka, G. A. Niklasson, and C. G. Granqvist, " Thermochromic multilayer films of VO2 and TiO2 with enhanced transmittance," Solar Energy Materials and Solar Cells, 2009. 93(9): p. 1685-1687.
[19] J. Pala, M. Mordiya, D. Virpariya, A. Dangodara, P. Gandha, C. R. Savaliya, J. Joseph , T. Shiyani, D. Dhruv and J. H. Markna," Analysis and design optimization of organic dye sensitized solar cell based on simulation," in AIP Conference Proceedings. 2017. AIP Publishing.
[20] R. Stangl, C. Leendertz and J. Haschke, " Numerical simulation of solar cells and solar cell characterization methods: the open-source on demand program AFORS-HET," in Solar Energy. 2010, IntechOpen.
[21] H. Movla, " Optimization of the CIGS based thin film solar cells: Numerical simulation and analysis," Optik, 2014. 125(1): p. 67-70.
[22] M. Burgelman, J. Verschraegen, S. Degrave and P.Nollet, "Modeling thin‐film PV devices," Progress in Photovoltaics: Research and Applications, 2004. 12(2‐3): p. 143-153.
[23] H. Mohd. Zuhair, I. Saad, A. Roystone, A. M. Khairul, B. Ghosh and N. Bolong, " Enhancing efficiency of organic solar cells by interfacial materials modification," in 2017 IEEE Regional Symposium on Micro and Nanoelectronics (RSM). 2017. IEEE.
[24] R. C. I. MacKenzie, T. Kirchartz, G. F. A. Dibb and J. Nelson, " Modeling nongeminate recombination in P3HT: PCBM solar cells," The Journal of Physical Chemistry C, 2011. 115(19): p. 9806-9813.
[25] R. Hanfland, M. A. Fischer, W. Brütting, U. Würfel, and R. C. I. MacKenzie,"The physical meaning of charge extraction by linearly increasing voltage transients from organic solar cells," Applied Physics Letters, 2013. 103(6): p. 063904.
[26] F. Deschler, D. Riedel, B. Ecker, E. Hauff, E. D. Como and R. C. I. MacKenzie, "Increasing organic solar cell efficiency with polymer interlayers," Physical Chemistry Chemical Physics, 2013. 15(3): p. 764-769.
[27] R. C. I. MacKenzie, C. G. Shuttle , M. L. Chabinyc and J. Nelson, "Extracting microscopic device parameters from transient photocurrent measurements of P3HT: PCBM solar cells," Advanced Energy Materials, 2012. 2(6): p. 662-669.
[28] M. Lenes and L. J. A. Koster, "Thickness dependence of the efficiency of polymer: fullerene bulk heterojunction solar cells," Applied physics letters, 2006. 88(24): p. 243502.
[29] D. H. Apaydın, D. E. Yıldız, , A. Cirpan and L. Toppare, "Optimizing the organic solar cell efficiency: role of the active layer thickness" Solar Energy Materials and Solar Cells, 2013. 113: p. 100-105.
[30] M. C. Hanna and A. J. Nozik, "Solar conversion efficiency of photovoltaic and photoelectrolysis cells with carrier multiplication absorbers," Journal of Applied Physics, 2006. 100(7): p. 074510.
[31] S. Fabiano, Z. Chen, S. Vahedi, A. Facchetti, B. Pignataro and M. A. Loi, "Role of photoactive layer morphology in high fill factor all-polymer bulk heterojunction solar cells," Journal of Materials Chemistry, 2011. 21(16): p. 5891-5896.
[32] K.Vandewal ,A.Gadisa ,W.D. Oosterbaan, S.Bertho ,F.Banishoeib ,I. V.Severen ,L.Lutsen ,T.J. Cleij,D.Vanderzande and J.V. Manca, "The relation between open‐circuit voltage and the onset of photocurrent generation by charge‐transfer absorption in polymer: fullerene bulk heterojunction solar cells," Advanced Functional Materials, 2008. 18(14): p. 2064-2070.

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L Shaped via based Mushroom type High Impedance Structure

Vol. 6, Issue 04, PP. 143-147, April 2019

Published online L Shaped via based Mushroom type High Impedance Structure

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Abstract

Author

Touseef Ahmad:Universitivy of Engineering and Technology Peshawar Pakistan
Shahid Bashir: Universitivy of Engineering and Technology Peshawar Pakistan