A Dual Band Microstrip-fed Slot Antenna
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*A Dual Band Microstrip-fed Slot Antenna Tuner
*A Dual Band Microstrip-fed Slot Antenna Combo
The microstrip-fed UWB slot antenna has a low profile with a simple structure. The design is successfully realized and verified by both simulations and measurements and could be used in UWB applications. This paper is organized as follows. The design procedure for the dual band-notch antenna is described in detail in the next section. 43 designed the dual- and wideband slot loaded stacked microstrip patch antenna for WLAN/WiMAX applications. The bandwidth of the proposed dual-band antenna at lower resonance frequency is 9.53%, whereas at upper resonance frequency, 6.95% is achieved. 2.4 Parasitic MSAs.
In this paper a novel design of microstrip-fed slot antenna with dual-band characteristics is proposed. The proposed antenna has advantages such as simple structure, compact size and easy fabrication. By introducing a pair of U-shaped strips to the antenna, dual-band operation and good radiation performance suitable for the WLAN systems can be. Moosazadeh et al. Proposed a novel microstrip-fed monopole antenna for a triple-band operation in 9. The proposed antenna consisted of a pair of symmetrical L and U shape slots inside the rectangular patch that enables proper adjusting of the resonant bands. Proposed antenna geometry was simulated and fabricated on FR4 substrate. MODIFICATIONS OF ANTENNA STRUCTURE FOR DUAL BAND The dual band microstrip antenna (MSA) is realized by cutting the slots of different shapes like, U-slot, V-slot, pair of rectangular slots and step slots, etc 9–13. The geometry of dual band rectangular microstrip antenna is shown in fig 3.
2006 IEEE Antennas and Propagation Society International Symposium>3597 - 3600 Abstract A compact dual- and wide-band cavity-backed slot antenna subarray has been presented in this paper. Ridged slots have been employed in the design to shorten the slot length. Four slots are fed by two feeding networks printed on the upper layer of a substrate for great design flexibility. The designed antenna has been measured and experimental results have shown that the 10 dB return loss bandwidth is 7.5% for 900 MHz band and 26% for 1800 MHz band, respectively. Because of its compact size and good radiation patterns at both frequency bands, this described subarray can be very useful for dual-band array applications Identifiers book ISBN : 1-4244-0123-2 DOI 10.1109/APS.2006.1711398 Authors User assignment Assignment remove confirmation You’re going to remove this assignment. Are you sure?A Dual Band Microstrip-fed Slot Antenna TunerYijun Liu
*Sch. of Electr.&Electron. Eng., Nanyang Technol. Univ.Boyu Zheng
*Sch. of Electr.&Electron. Eng., Nanyang Technol. Univ.Zhongxiang Shen
*Sch. of Electr.&Electron. Eng., Nanyang Technol. Univ. Keywords
UHF antennasantenna feedsantenna radiation patternsbroadband antennasmultifrequency antennasslot antenna arrays1800 MHzdual-band microstrip-fed cavity-backed subarraywide-band cavity-backed slot antenna subarrayridged slotsfeeding networksreturn loss bandwidthradiation patterns900 MHz
UHF antennasantenna feedsantenna radiation patternsbroadband antennasmultifrequency antennasslot antenna arrays1800 MHzdual-band microstrip-fed cavity-backed subarraywide-band cavity-backed slot antenna subarrayridged slotsfeeding networksreturn loss bandwidthradiation patterns900 MHz Additional information Publisher Share Export to bibliography Main Article ContentAbstract
A new compact microstrip slot antenna with Y-shaped coupling aperture is proposed. This antenna is based on a rectangular form with a microstrip fed line for excitation, and consists of slots on the edge of the radiation patch to provide dual-band operation. The design and simulation of the antenna were performed using CST Microwave Studio simulator. A prototype of the proposed antenna has been constructed and tested. In order to validate the return loss of the prototype antenna, the experimental results are presented. The results show two available bands with –10 dB band S at 2.7 GHz and band C at 5 GHz. Also, good radiation performance and antenna gain over the two frequency ranges have been obtained. Computation results confirm the experimental findings.A Dual Band Microstrip-fed Slot Antenna Combo Keywords Microstrip antennaDual band antennaSlot antennaCST microwave studio simulator.Article DetailsWali, R., Ghnimi, S., Hand, A., & Razban, T. (2014). Analysis and Design of a New Dual Band Microstrip Patch Antenna Based on Slot Matching Y-Shaped. The Journal of Engineering Research [TJER], 11(2), 89–97. https://doi.org/10.24200/tjer.vol11iss2pp89-97 Endnote/Zotero/Mendeley (RIS)
BibTeX
References
*Abdelaziz AA (2006), Bandwidth enhancement of microstrip antenna. Progress In Electromagnetics Research, PIER 63:311–317.
*Adnan S, Mustafa HB, Ucar, Yunus EE (2009), Loop-loaded printed dipole array design for a dual-band radar application. Antennas & Propagation Conference, LAPC Loughborough. 529–532.
*Adnen R, Ghnimi S, Ali G (2010, Electrical characteristics of a dual-band microstrip patch antenna for GSM/ UMTS / WLAN operations. International Journal of Communication Networks and Information Security (IJCNIS) 2(1):54-59.
*Allen CM, Eldek AA, Elsherbeni AZ, Smith CE (2005), Dual tapered meander slot antenna for radar applications. IEEE transactions on antennas and propagation 53(7):2324- 2328.
*BALANIS CA (1997), Antenna theory: analysis and design. 2nd Edition, John Wiley & Sons, New York, USA.
*Christina F, Jou JWW, Chien-Jen W (2009), Novel broadband monopole antennas with dual-band circular polarization. IEEE transactions on antennas and propagation 57(4):1027-1034.
*Gai S, Jiao YC, Yang YB, Li CY, Gong JG (2010), Design of a novel microstrip-fed dual-band slot antenna for WLAN applications. Progress In Electromagnetics Research Letters 13:75- 81.
*Ghnimi S, Rawia W, Ali G, Razban T (2013), A new design of an S/X dual band circular slot antenna for radar applications. Journal of Microwave Power and Electromagnetic Energy 47(2):138-146.
*Khaled EEM, Saad AAR (2008), Multiwide band compact microstrip patch antenna based on slot matching. Progress In Electromagnetics Research C 4:169–177.
*Khunead G, Nakasuwan J, Songthanapitak N, Anantrasirichai N (2007), Investigate rectangular slot antenna with L-shaped strip. Piers online 3(7):1076-1079.
*Qu X, Zhong S, Zhang YM (2006), Dualband dual-polarised microstrip antenna array for SAR applications. Electronic letters 42(24):1376-1377.
*Saidatul NA, Azremi AAH, Ahmad RB, Soh PJ, Malek F (2009), Multiband fractal planar inverted F antenna (F-PIFA) for mobile phone application. Progress In Electromagnetics Research B 14:127–148.
*Zhilong M, Cheng H, Qin Z, Mingbo P, Xiaoliang M, Xiangang L (2012), Design of a patch antenna with dual-band radar cross section reduction. International Conference on Microwave and Millimeter Wave Technology (ICMMT) 5:1–3. References
Abdelaziz AA (2006), Bandwidth enhancement of microstrip antenna. Progress In Electromagnetics Research, PIER 63:311–317.
Adnan S, Mustafa HB, Ucar, Yunus EE (2009), Loop-loaded printed dipole array design for a dual-band radar application. Antennas & Propagation Conference, LAPC Loughborough. 529–532.
Adnen R, Ghnimi S, Ali G (2010, Electrical characteristics of a dual-band microstrip patch antenna for GSM/ UMTS / WLAN operations. International Journal of Communication Networks and Information Security (IJCNIS) 2(1):54-59.
Allen CM, Eldek AA, Elsherbeni AZ, Smith CE (2005), Dual tapered meander slot antenna for radar applications. IEEE transactions on antennas and propagation 53(7):2324- 2328.
BALANIS CA (1997), Antenna theory: analysis and design. 2nd Edition, John Wiley & Sons, New York, USA.
Christina F, Jou JWW, Chien-Jen W (2009), Novel broadband monopole antennas with dual-band circular polarization. IEEE transactions on antennas and propagation 57(4):1027-1034. Roulette free spins.
Gai S, Jiao YC, Yang YB, Li CY, Gong JG (2010), Design of a novel microstrip-fed dual-band slot antenna for WLAN applications. Progress In Electromagnetics Research Letters 13:75- 81.
Ghnimi S, Rawia W, Ali G, Razban T (2013), A new design of an S/X dual band circular slot antenna for radar applications. Journal of Microwave Power and Electromagnetic Energy 47(2):138-146.
Khaled EEM, Saad AAR (2008), Multiwide band compact microstrip patch antenna based on slot matching. Progress In Electromagnetics Research C 4:169–177.
Khunead G, Nakasuwan J, Songthanapitak N, Anantrasirichai N (2007), Investigate rectangular slot antenna with L-shaped strip. Piers online 3(7):1076-1079.
Qu X, Zhong S, Zhang YM (2006), Dualband dual-polarised microstrip antenna array for SAR applications. Electronic letters 42(24):1376-1377.
Saidatul NA, Azremi AAH, Ahmad RB, Soh PJ, Malek F (2009), Multiband fractal planar inverted F antenna (F-PIFA) for mobile phone application. Progress In Electromagnetics Research B 14:127–148.
Zhilong M, Cheng H, Qin Z, Mingbo P, Xiaoliang M, Xiangang L (2012), Design of a patch antenna with dual-band radar cross section reduction. International Conference on Microwave and Millimeter Wave Technology (ICMMT) 5:1–3.
Register here: http://gg.gg/x7cr4
https://diarynote.indered.space
Source
*A Dual Band Microstrip-fed Slot Antenna Tuner
*A Dual Band Microstrip-fed Slot Antenna Combo
The microstrip-fed UWB slot antenna has a low profile with a simple structure. The design is successfully realized and verified by both simulations and measurements and could be used in UWB applications. This paper is organized as follows. The design procedure for the dual band-notch antenna is described in detail in the next section. 43 designed the dual- and wideband slot loaded stacked microstrip patch antenna for WLAN/WiMAX applications. The bandwidth of the proposed dual-band antenna at lower resonance frequency is 9.53%, whereas at upper resonance frequency, 6.95% is achieved. 2.4 Parasitic MSAs.
In this paper a novel design of microstrip-fed slot antenna with dual-band characteristics is proposed. The proposed antenna has advantages such as simple structure, compact size and easy fabrication. By introducing a pair of U-shaped strips to the antenna, dual-band operation and good radiation performance suitable for the WLAN systems can be. Moosazadeh et al. Proposed a novel microstrip-fed monopole antenna for a triple-band operation in 9. The proposed antenna consisted of a pair of symmetrical L and U shape slots inside the rectangular patch that enables proper adjusting of the resonant bands. Proposed antenna geometry was simulated and fabricated on FR4 substrate. MODIFICATIONS OF ANTENNA STRUCTURE FOR DUAL BAND The dual band microstrip antenna (MSA) is realized by cutting the slots of different shapes like, U-slot, V-slot, pair of rectangular slots and step slots, etc 9–13. The geometry of dual band rectangular microstrip antenna is shown in fig 3.
2006 IEEE Antennas and Propagation Society International Symposium>3597 - 3600 Abstract A compact dual- and wide-band cavity-backed slot antenna subarray has been presented in this paper. Ridged slots have been employed in the design to shorten the slot length. Four slots are fed by two feeding networks printed on the upper layer of a substrate for great design flexibility. The designed antenna has been measured and experimental results have shown that the 10 dB return loss bandwidth is 7.5% for 900 MHz band and 26% for 1800 MHz band, respectively. Because of its compact size and good radiation patterns at both frequency bands, this described subarray can be very useful for dual-band array applications Identifiers book ISBN : 1-4244-0123-2 DOI 10.1109/APS.2006.1711398 Authors User assignment Assignment remove confirmation You’re going to remove this assignment. Are you sure?A Dual Band Microstrip-fed Slot Antenna TunerYijun Liu
*Sch. of Electr.&Electron. Eng., Nanyang Technol. Univ.Boyu Zheng
*Sch. of Electr.&Electron. Eng., Nanyang Technol. Univ.Zhongxiang Shen
*Sch. of Electr.&Electron. Eng., Nanyang Technol. Univ. Keywords
UHF antennasantenna feedsantenna radiation patternsbroadband antennasmultifrequency antennasslot antenna arrays1800 MHzdual-band microstrip-fed cavity-backed subarraywide-band cavity-backed slot antenna subarrayridged slotsfeeding networksreturn loss bandwidthradiation patterns900 MHz
UHF antennasantenna feedsantenna radiation patternsbroadband antennasmultifrequency antennasslot antenna arrays1800 MHzdual-band microstrip-fed cavity-backed subarraywide-band cavity-backed slot antenna subarrayridged slotsfeeding networksreturn loss bandwidthradiation patterns900 MHz Additional information Publisher Share Export to bibliography Main Article ContentAbstract
A new compact microstrip slot antenna with Y-shaped coupling aperture is proposed. This antenna is based on a rectangular form with a microstrip fed line for excitation, and consists of slots on the edge of the radiation patch to provide dual-band operation. The design and simulation of the antenna were performed using CST Microwave Studio simulator. A prototype of the proposed antenna has been constructed and tested. In order to validate the return loss of the prototype antenna, the experimental results are presented. The results show two available bands with –10 dB band S at 2.7 GHz and band C at 5 GHz. Also, good radiation performance and antenna gain over the two frequency ranges have been obtained. Computation results confirm the experimental findings.A Dual Band Microstrip-fed Slot Antenna Combo Keywords Microstrip antennaDual band antennaSlot antennaCST microwave studio simulator.Article DetailsWali, R., Ghnimi, S., Hand, A., & Razban, T. (2014). Analysis and Design of a New Dual Band Microstrip Patch Antenna Based on Slot Matching Y-Shaped. The Journal of Engineering Research [TJER], 11(2), 89–97. https://doi.org/10.24200/tjer.vol11iss2pp89-97 Endnote/Zotero/Mendeley (RIS)
BibTeX
References
*Abdelaziz AA (2006), Bandwidth enhancement of microstrip antenna. Progress In Electromagnetics Research, PIER 63:311–317.
*Adnan S, Mustafa HB, Ucar, Yunus EE (2009), Loop-loaded printed dipole array design for a dual-band radar application. Antennas & Propagation Conference, LAPC Loughborough. 529–532.
*Adnen R, Ghnimi S, Ali G (2010, Electrical characteristics of a dual-band microstrip patch antenna for GSM/ UMTS / WLAN operations. International Journal of Communication Networks and Information Security (IJCNIS) 2(1):54-59.
*Allen CM, Eldek AA, Elsherbeni AZ, Smith CE (2005), Dual tapered meander slot antenna for radar applications. IEEE transactions on antennas and propagation 53(7):2324- 2328.
*BALANIS CA (1997), Antenna theory: analysis and design. 2nd Edition, John Wiley & Sons, New York, USA.
*Christina F, Jou JWW, Chien-Jen W (2009), Novel broadband monopole antennas with dual-band circular polarization. IEEE transactions on antennas and propagation 57(4):1027-1034.
*Gai S, Jiao YC, Yang YB, Li CY, Gong JG (2010), Design of a novel microstrip-fed dual-band slot antenna for WLAN applications. Progress In Electromagnetics Research Letters 13:75- 81.
*Ghnimi S, Rawia W, Ali G, Razban T (2013), A new design of an S/X dual band circular slot antenna for radar applications. Journal of Microwave Power and Electromagnetic Energy 47(2):138-146.
*Khaled EEM, Saad AAR (2008), Multiwide band compact microstrip patch antenna based on slot matching. Progress In Electromagnetics Research C 4:169–177.
*Khunead G, Nakasuwan J, Songthanapitak N, Anantrasirichai N (2007), Investigate rectangular slot antenna with L-shaped strip. Piers online 3(7):1076-1079.
*Qu X, Zhong S, Zhang YM (2006), Dualband dual-polarised microstrip antenna array for SAR applications. Electronic letters 42(24):1376-1377.
*Saidatul NA, Azremi AAH, Ahmad RB, Soh PJ, Malek F (2009), Multiband fractal planar inverted F antenna (F-PIFA) for mobile phone application. Progress In Electromagnetics Research B 14:127–148.
*Zhilong M, Cheng H, Qin Z, Mingbo P, Xiaoliang M, Xiangang L (2012), Design of a patch antenna with dual-band radar cross section reduction. International Conference on Microwave and Millimeter Wave Technology (ICMMT) 5:1–3. References
Abdelaziz AA (2006), Bandwidth enhancement of microstrip antenna. Progress In Electromagnetics Research, PIER 63:311–317.
Adnan S, Mustafa HB, Ucar, Yunus EE (2009), Loop-loaded printed dipole array design for a dual-band radar application. Antennas & Propagation Conference, LAPC Loughborough. 529–532.
Adnen R, Ghnimi S, Ali G (2010, Electrical characteristics of a dual-band microstrip patch antenna for GSM/ UMTS / WLAN operations. International Journal of Communication Networks and Information Security (IJCNIS) 2(1):54-59.
Allen CM, Eldek AA, Elsherbeni AZ, Smith CE (2005), Dual tapered meander slot antenna for radar applications. IEEE transactions on antennas and propagation 53(7):2324- 2328.
BALANIS CA (1997), Antenna theory: analysis and design. 2nd Edition, John Wiley & Sons, New York, USA.
Christina F, Jou JWW, Chien-Jen W (2009), Novel broadband monopole antennas with dual-band circular polarization. IEEE transactions on antennas and propagation 57(4):1027-1034. Roulette free spins.
Gai S, Jiao YC, Yang YB, Li CY, Gong JG (2010), Design of a novel microstrip-fed dual-band slot antenna for WLAN applications. Progress In Electromagnetics Research Letters 13:75- 81.
Ghnimi S, Rawia W, Ali G, Razban T (2013), A new design of an S/X dual band circular slot antenna for radar applications. Journal of Microwave Power and Electromagnetic Energy 47(2):138-146.
Khaled EEM, Saad AAR (2008), Multiwide band compact microstrip patch antenna based on slot matching. Progress In Electromagnetics Research C 4:169–177.
Khunead G, Nakasuwan J, Songthanapitak N, Anantrasirichai N (2007), Investigate rectangular slot antenna with L-shaped strip. Piers online 3(7):1076-1079.
Qu X, Zhong S, Zhang YM (2006), Dualband dual-polarised microstrip antenna array for SAR applications. Electronic letters 42(24):1376-1377.
Saidatul NA, Azremi AAH, Ahmad RB, Soh PJ, Malek F (2009), Multiband fractal planar inverted F antenna (F-PIFA) for mobile phone application. Progress In Electromagnetics Research B 14:127–148.
Zhilong M, Cheng H, Qin Z, Mingbo P, Xiaoliang M, Xiangang L (2012), Design of a patch antenna with dual-band radar cross section reduction. International Conference on Microwave and Millimeter Wave Technology (ICMMT) 5:1–3.
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