Lossy resonator with high Q for switchable absorptive bandstop to bandpass filter

Lossy resonator with high Q for switchable absorptive bandstop to bandpass filter

New developments in the design of the switchable microwave filters in some cognitive radio system are essential to meet the ever increasing demands to discriminate between wanted and unwanted signals. There also has a demand for miniaturization of microwave communications systems. A compact design c...

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Main Author: Zahari, Mohd Khairy
Format: Thesis
Language:English
English
Published: 2018
Subjects:
T Technology (General)
Online Access:http://eprints.utem.edu.my/id/eprint/23307/1/Lossy%20Resonator%20With%20High%20Q%20For%20Switchable%20Absorptive%20Bandstop%20To%20Bandpass%20Filter.pdf
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institution Universiti Teknikal Malaysia Melaka
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language English
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advisor Ahmad, Badrul Hisham
topic T Technology (General)
T Technology (General)
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T Technology (General)
Zahari, Mohd Khairy
Lossy resonator with high Q for switchable absorptive bandstop to bandpass filter
description New developments in the design of the switchable microwave filters in some cognitive radio system are essential to meet the ever increasing demands to discriminate between wanted and unwanted signals. There also has a demand for miniaturization of microwave communications systems. A compact design can be achieved through the implementation of planar microstrip technology. However, conventional electronically tunable bandstop filters suffer performance degradation due to the finite unloaded Q of the resonators and also the loss associated with the switching elements. Therefore, two low Q lossy resonator filter topology has been implemented where the topology can be used to partially compensate for the loss where a high Q absorptive bandstop filter can be achieved. The filter consists of λ/2 resonator with K-inverter, parallel with an Allpass nominally-90°-phase-shift element. A frequency agile bandstop filter based on this topology has been developed, but such filters as well as conventional switchable bandstop filters encounter performance degradation in terms of tuning bandwidth and stopband bandwidth due to the frequency dependant losses and couplings. Through this thesis a new switchable microwave filter is investigated and developed, where this filter is able to switch from high Q absorptive bandstop response (ON state) to bandpass response (OFF state). This switchable filter is designed using four different types of resonator which are parallel coupled, dual mode ring, stepped impedance dual mode and T-shape. The parallel coupled resonator consisted of two low-Q lossy resonator connected with 90° wavelength and with correct k-inverter to produce high Q absorptive bandstop response. T-shape resonator consisted of T resonator coupled with 90° wavelength. While for the dual mode ring resonator structure is composed by two degenerate modes or splitting resonant frequencies, where the ring can be excited by perturbing stub. For stepped impedance resonator, the structure is consisted of the stepped impedance resonator with mid-plane of via hole and connected with 90° wavelength to achieve the high Q absorptive bandstop response. The filters are integrated with switching element, such as PIN and a varactor diode to switch the filter response and biasing circuit is needed to make the PIN or the varactor diode working properly. The absorptive bandstop filter operates at 2.4 GHz where S11 is below than 15 dB and S21 has high selectivity with the narrow bandstop response with high Q factor. The unloaded Q factor of the absorptive bandstop filter is more than 60 for measuring and 150 for simulation. For a bandpass response, the response depends on the filter structure. Where, each resonator produced different character of a bandpass filter. The dual mode bandpass response for stepped impedance, was achieved by switched ‘OFF’ the PIN diodes, where the insertion loss, S21 4.9 dB, return loss, S11 is below 15 dB, and passband bandwidth is 200 MHz at centre frequency of 2.35 GHz. A good agreement is observed between simulated and measured results. The benefits of this filter is not only can produce a bandpass response, but also high quality factor in bandstop response which offer a better performance and high selectivity. The outcomes of the proposed switchable filters may facilitate improvements and the solution in cognitive radio.
format Thesis
qualification_name Doctor of Philosophy (PhD.)
qualification_level Doctorate
author Zahari, Mohd Khairy
author_facet Zahari, Mohd Khairy
author_sort Zahari, Mohd Khairy
title Lossy resonator with high Q for switchable absorptive bandstop to bandpass filter
title_short Lossy resonator with high Q for switchable absorptive bandstop to bandpass filter
title_full Lossy resonator with high Q for switchable absorptive bandstop to bandpass filter
title_fullStr Lossy resonator with high Q for switchable absorptive bandstop to bandpass filter
title_full_unstemmed Lossy resonator with high Q for switchable absorptive bandstop to bandpass filter
title_sort lossy resonator with high q for switchable absorptive bandstop to bandpass filter
granting_institution Universiti Teknikal Malaysia Melaka
granting_department Faculty Of Electronic And Computer Engineering
publishDate 2018
url http://eprints.utem.edu.my/id/eprint/23307/1/Lossy%20Resonator%20With%20High%20Q%20For%20Switchable%20Absorptive%20Bandstop%20To%20Bandpass%20Filter.pdf
http://eprints.utem.edu.my/id/eprint/23307/2/Lossy%20resonator%20with%20high%20Q%20for%20switchable%20absorptive%20bandstop%20to%20bandpass%20filter.pdf
_version_ 1747834032063774720
spelling my-utem-ep.233072022-06-13T11:45:11Z Lossy resonator with high Q for switchable absorptive bandstop to bandpass filter 2018 Zahari, Mohd Khairy T Technology (General) TK Electrical engineering. Electronics Nuclear engineering New developments in the design of the switchable microwave filters in some cognitive radio system are essential to meet the ever increasing demands to discriminate between wanted and unwanted signals. There also has a demand for miniaturization of microwave communications systems. A compact design can be achieved through the implementation of planar microstrip technology. However, conventional electronically tunable bandstop filters suffer performance degradation due to the finite unloaded Q of the resonators and also the loss associated with the switching elements. Therefore, two low Q lossy resonator filter topology has been implemented where the topology can be used to partially compensate for the loss where a high Q absorptive bandstop filter can be achieved. The filter consists of λ/2 resonator with K-inverter, parallel with an Allpass nominally-90°-phase-shift element. A frequency agile bandstop filter based on this topology has been developed, but such filters as well as conventional switchable bandstop filters encounter performance degradation in terms of tuning bandwidth and stopband bandwidth due to the frequency dependant losses and couplings. Through this thesis a new switchable microwave filter is investigated and developed, where this filter is able to switch from high Q absorptive bandstop response (ON state) to bandpass response (OFF state). This switchable filter is designed using four different types of resonator which are parallel coupled, dual mode ring, stepped impedance dual mode and T-shape. The parallel coupled resonator consisted of two low-Q lossy resonator connected with 90° wavelength and with correct k-inverter to produce high Q absorptive bandstop response. T-shape resonator consisted of T resonator coupled with 90° wavelength. While for the dual mode ring resonator structure is composed by two degenerate modes or splitting resonant frequencies, where the ring can be excited by perturbing stub. For stepped impedance resonator, the structure is consisted of the stepped impedance resonator with mid-plane of via hole and connected with 90° wavelength to achieve the high Q absorptive bandstop response. The filters are integrated with switching element, such as PIN and a varactor diode to switch the filter response and biasing circuit is needed to make the PIN or the varactor diode working properly. The absorptive bandstop filter operates at 2.4 GHz where S11 is below than 15 dB and S21 has high selectivity with the narrow bandstop response with high Q factor. The unloaded Q factor of the absorptive bandstop filter is more than 60 for measuring and 150 for simulation. For a bandpass response, the response depends on the filter structure. Where, each resonator produced different character of a bandpass filter. The dual mode bandpass response for stepped impedance, was achieved by switched ‘OFF’ the PIN diodes, where the insertion loss, S21 4.9 dB, return loss, S11 is below 15 dB, and passband bandwidth is 200 MHz at centre frequency of 2.35 GHz. A good agreement is observed between simulated and measured results. The benefits of this filter is not only can produce a bandpass response, but also high quality factor in bandstop response which offer a better performance and high selectivity. The outcomes of the proposed switchable filters may facilitate improvements and the solution in cognitive radio. 2018 Thesis http://eprints.utem.edu.my/id/eprint/23307/ http://eprints.utem.edu.my/id/eprint/23307/1/Lossy%20Resonator%20With%20High%20Q%20For%20Switchable%20Absorptive%20Bandstop%20To%20Bandpass%20Filter.pdf text en public http://eprints.utem.edu.my/id/eprint/23307/2/Lossy%20resonator%20with%20high%20Q%20for%20switchable%20absorptive%20bandstop%20to%20bandpass%20filter.pdf text en validuser https://plh.utem.edu.my/cgi-bin/koha/opac-detail.pl?biblionumber=112323 phd doctoral Universiti Teknikal Malaysia Melaka Faculty Of Electronic And Computer Engineering Ahmad, Badrul Hisham 1. Adoum, B.A. and Wen, W.P., 2011. Miniaturised Matched Band-Stop Filter Based Dual Mode Resonator. In National Postgraduate Conference (NPC), 2011 (pp. 1-3). IEEE. 2. Adoum, B. A. and Wen, W. P. 2012. Investigation of Band-Stop to All Pass Reconfigurable Filter. ICIAS 2012 - 2012 4th International Conference on Intelligent and Advanced Systems: A Conference of World Engineering, Science and Technology Congress (ESTCON) - Conference Proceedings, 1, pp. 190–193. 3. Adoum, B. A. and Wen, W. P. 2014. Numerical Investigation of Novel Switchable Microwave Band-Stop to Bandpass Filters. 2014 5th International Conference on Intelligent and Advanced Systems: Technological Convergence for Sustainable Future, ICIAS 2014 - Proceedings. 4. Adoum, B. A., Wen, W. P. and Osman, M. S. 2013. Switchable Matched Band-Stop Filter For High Power Interference Mitigation. Asia-Pacific Microwave Conference Proceedings, APMC, pp. 19–21. 5. Adoum, B. A. and Wong, P. W. 2013. Switchable Microwave Band-Stop to All Pass Filter Using Stepped Impedance Resonator. Progress In Electromagnetics Research B, 52(May), pp. 99–115. 6. Alqaisy, M., Chakrabraty, C.K., Ali, J.K., Alhawari, A.R. and Saeidi, T., 2017. Switchable Square Ring Bandpass to Bandstop Filter for Ultra-Wideband Applications. International Journal of Microwave and Wireless Technologies, 9(1), pp.51-60. 7. Arain, S., Abbassi, M.A.B., Nikolaou, S. and Vryonides, P., A Reconfigurable Bandpass to Bandstop Filter Using PIN Diodes Based on the Square Ring Resonator. 8. Čabrić, D., Mishra, S.M., Willkomm, D., Brodersen, R. and Wolisz, A., 2005, June. A Cognitive Radio Approach for Usage Of Virtual Unlicensed Spectrum. In 14th IST mobile and wireless communications summit. 9. Chan, K.Y., Ramer, R. and Mansour, R.R., 2017. A Switchable Iris Bandpass Filter Using RF MEMS Switchable Planar Resonators. IEEE Microwave and Wireless Components Letters, 27(1), pp.34-36. 10. Kim, C., Hyeon Lee, T., Shrestha, B. and Chul Son, K., 2017. Miniaturized Dual‐Band Bandpass Filter Based on Stepped Impedance Resonators. Microwave and Optical Technology Letters, 59(5), pp.1116-1119. 11. Chen, H., Jiang, D. and Wan, Y. 2015. A Miniature Low-Loss Wideband Dual-Mode BPF with Harmonic Suppression. 2015 IEEE International Conference on Communication Problem-Solving (ICCP), 2, pp. 530–532. 12. Chen, J.X., Shi, J., Bao, Z.H. and Xue, Q., 2011. Tunable and Switchable Bandpass Filters using Slot-Line Resonators. Progress In Electromagnetics Research, 111, pp.25-41. 13. Chen, Y.M., Chang, S.F., Chou, C.Y. and Liu, K.H., 2009. A Reconfigurable Bandpass-Bandstop Filter Based on Varactor-Loaded Closed-Ring Resonators [Technical Committee]. IEEE Microwave Magazine, 10(1), pp.138-140. 14. Chi, P. L., Yang, T. and Tsai, T. Y. 2015. A Fully Tunable Two-Pole Bandpass Filter. IEEE Microwave and Wireless Components Letters, 25(5), pp. 292–294. 15. Cho, Y. H. and Rebeiz, G. M. 2014. 0.7-1.0-GHz Reconfigurable Bandpass-to-Bandstop Filter with Selectable 2- And 4-Pole Responses. IEEE Transactions on Microwave Theory and Techniques, 62(11), pp. 2626–2632. 16. Darlington, S. 1939. Synthesis of Reactance 4-Poles Which Produce Prescribed Insertion Loss Characteristics. J. Math. Phys., 28(6), pp. 257–353. 17. Deng, P. H., Tsai, J. T. and Liu, R. C. 2014. Design of a Switchable Microstrip Dual-Band Lowpass-Bandpass Filter. IEEE Microwave and Wireless Components Letters, 24(9), pp. 599–601. 18. Ge, C. and Zhu, X. W. 2013. A Compact Dual Mode Tunable Filter with Source and Load Coupling. 2013 IEEE Wireless Communications and Networking Conference Workshops, WCNCW 2013, pp. 85–88. 19. Ge, C. and Zhu, X. W. 2014. Highly-Selective Tunable Bandpass Filter with Two-Path Mixed Coupling. IEEE Microwave and Wireless Components Letters, 24(7), pp. 451–453. 20. Guyette, A.C., Hunter, I.C., Pollard, R.D. and Jachowski, D.R., 2005, June. Perfectly-Matched Bandstop Filters using Lossy Resonators. In Microwave Symposium Digest, 2005 IEEE MTT-S International (pp. 4-pp). IEEE. 21. Guyette, A. C. 2012. Intrinsically Switched Varactor-Tuned Filters and Filter Banks. IEEE Transactions on Microwave Theory and Techniques, 60(4), pp. 1044–1056. 22. Guyette, A.C., Naglich, E.J. and Shin, S., 2017. RF-Power-Activated and Signal-Tracking Tunable Bandstop Filters. IEEE Transactions on Microwave Theory and Techniques, 65(5), pp.1534-1544. 23. Guyette, A. C. and Naglich, E. J. 2016. Short-Through-Line Bandstop Filters using Dual-Coupled Resonators. IEEE Transactions on Microwave Theory and Techniques, 64(2), pp. 459–466. 24. Guyette, A. C., Naglich, E. J. and Shin, S. 2016. Switched Allpass-to-Bandstop Absorptive Filters With Constant Group Delay. IEEE Transactions on Microwave Theory and Techniques, 64(8), pp. 2590–2595. 25. Guyette, A., Hunter, I. C. and Pollard, R. D. 2004. A New Class of Selective Filters using Low-Q Components Suitable for MMIC Implementation. 2004 IEEE MTT-S International Microwave Symposium Digest (IEEE Cat. No.04CH37535), 3, pp. 1959–1962. 26. Guyette, A. C. 2010. Design of Fixed- And Varactor-Tuned Bandstop Filters with Spurious Suppression. Microwave Conference (EuMC), 2010 European, (September), pp. 288–291. 27. Hong, J. S. and Lancaster, M. J. 1995. Microstrip Bandpass Filter using Degenerate Modes of a Novel Meander Loop Resonator. IEEE Microwave and Guided Wave Letters, 5(11), pp. 371–372. 28. Hunter, I., Guyette, A. and Pollard, R.D., 2005. Passive Microwave Receive Filter Networks using Low-Q Resonators. IEEE microwave Magazine, 6(3), pp.46-53. 29. Hunter, I. C. 1982. Electronically Tunable Microwave Bandstop Filters. IEEE Transactions on Microwave Theory and Techniques, M(10475003), pp. 21–26. 30. Hunter, I. C. 1997. Filter Design With Lossy Circuit Elements. Advances in Passive Microwave Components (Digest No.: 1997/154), IEE Colloquium, pp. 1–6. 31. Hunter I. C., 2001. Theory And Design Of Microwave Filters. 32. J.A, C. and S.J, F. 1991. Miniature Dual Mode Microstrip Filters. Ieee, pp. 443–446. 33. Jachowski, D. R. 2004. Passive Enhancement of Resonator Q in Microwave Notch Filters. 2004 IEEE MTT-S International Microwave Symposium Digest (IEEE Cat. No.04CH37535), 3, pp. 1315–1318. 34. Jachowski, D. R. 2006. Cascadable Lossy Passive Biquad Bandstop Filter. Microwave Symposium Digest, 2006. IEEE MTT-S International, pp. 1213–1216. 35. Jachowski, D. R. and Rauscher, C. 2009. Frequency-Agile Bandstop Filter with Tunable Attenuation. IEEE MTT-S International Microwave Symposium Digest, pp. 649–652. 36. Karim, M.F., Liu, A.Q., Alphones, A. and Yu, A.B., 2006, June. A Novel Reconfigurable Filter using Periodic Structures. In Microwave Symposium Digest, 2006. IEEE MTT-S International (pp. 943-946). IEEE. 37. Kumar, N. and Singh, Y. K. 2016. Switchable Compact Widestopband Bandstop Filter to Wideband Bandpass Filter. Asia-Pacific Microwave Conference Proceedings, APMC, 1, pp. 1–3. 38. Kumar, A. and Pathak N. P., 2017. Varactor-Incorporated Bandpass Filter with Reconfigurable Frequency and Bandwidth. Microwave and Optical Technology Letters. Vol. 59, Issue 8. 39. Kumar, N. and Singh, Y.K., 2017. RF-MEMS-Based Bandpass-to-Bandstop Switchable Single-and Dual-Band Filters With Variable FBW and Reconfigurable Selectivity. IEEE Transactions on Microwave Theory and Techniques. 40. Lee, J., Naglich, E.J., Sigmarsson, H.H., Peroulis, D. and Chappell, W.J., 2013. New Bandstop Filter Circuit Topology and its Application to Design of a Bandstop-To-Bandpass Switchable Filter. IEEE transactions on microwave theory and techniques, 61(3), pp.1114-1123. 41. Lee, T. C., Yang, W. and Peroulis, D. 2015. Reconfigurable Filter Design Using Resonators As Coupling Structures. 2015 IEEE MTT-S International Microwave Symposium, IMS 2015, 2(c), pp. 2–5. 42. Li, R. and Chen, F. 2016. A Tunable Bandpass-to-Bandstop Filter Using PIN Diode. (1), pp. 3–5. 43. Lin, T.W., Kuo, J.T., Tang, S.C. and Chung, S.J., 2014, March. Miniaturized Dual-Mode Ring Resonator Bandpass Filter with a Wide Passband. In Wireless Symposium (IWS), 2014 IEEE International(pp. 1-3). IEEE. 44. Mitola, J. 1999. Cognitive Radio For Flexible Mobile Multimedia Communications. Mobile Multimedia Communications, 1999. (MoMuC ’99) 1999 IEEE International Workshop on, 22102, pp. 3–10. 45. Mitola III, J. 2001. Cognitive Radio for Flexible Mobile Multimedia. Mobile Networks and Applications, 6(5), pp. 435–441. 46. Nachouane, H., Najid, A., Tribak, A. and Riouch, F., 2017. A Switchable Bandstop-to-Bandpass Reconfigurable Filter for Cognitive Radio Applications. International Journal of Microwave and Wireless Technologies, 9(4), pp.765-772. 47. Naglich, E.J., Lee, J., Peroulis, D. and Chappell, W.J., 2010. A tunable bandpass-to-bandstop reconfigurable filter with independent bandwidths and tunable response shape. IEEE Transactions on Microwave Theory and Techniques, 58(12), pp.3770-3779. 48. E. J. Naglich, J. Lee, D. Peroulis and W. J. Chappell, 2012. Switchless Tunable Bandstop-to-All-Pass Reconfigurable Filter, in IEEE Transactions on Microwave Theory and Techniques, vol. 60, no. 5, pp. 1258-1265. 49. Naglich, E. J., Guyette, A. C. and Peroulis, D. 2014. High-Q Intrinsically-Switched Quasi-Absorptive Tunable Bandstop Filter with Electrically-Short Resonators. IEEE MTT-S International Microwave Symposium Digest, pp. 2–5. 50. Ou, Y. C. and Rebeiz, G. M. 2011. Lumped-Element Fully Tunable Bandstop Filters for Cognitive Radio Applications. IEEE Transactions on Microwave Theory and Techniques, 59(10 PART 1), pp. 2461–2468. 51. Park, S. J. and Rebeiz, G. M. 2008. Low-Loss Two-Pole Tunable Filters with Three Different Predefined Bandwidth Characteristics. IEEE Transactions on Microwave Theory and Techniques, 56(5), pp. 1137–1148. 52. Perlman, B., Laskar, J. and Lim, K., 2008. Fine-Tuning Commercial and Military Radio Design. IEEE Microwave Magazine, 9(4). 53. Pozar D., 2005. Microwave Engineering, 4th Edition, Wiley. 54. Rebeiz, G.M., Entesari, K., Reines, I.C., Park, S.J., El-Tanani, M.A., Grichener, A. and Brown, A.R., 2009. Tuning in to RF MEMS. IEEE microwave magazine, 10(6). 55. Sánchez-Renedo, M., Gómez-García, R., Alonso, J.I. and Briso-Rodríguez, C., 2005. Tunable Combline Filter with Continuous Control of Centre Frequency and Bandwidth. IEEE Transactions on Microwave Theory and Techniques, 53(1), pp.191-199. 56. Shairi, N. a., Ahmad, B. H. and Wong, P. W. 2014. Absorptive SPDT Switch Design using Cascaded Switchable Parallel-Coupled Stub Resonator and Switchable Radial Stub Resonator. Region 10 Symposium, 2014 IEEE, 2, pp. 310–314. 57. Shairi, N. A., Ahmad, B. H. and Wong, P. W. 2013. SPDT Discrete Switch Design using Switchable Radial Stub Resonator for Wimax and LTE In 3.5 Ghz Band. RFM 2013 - 2013 IEEE International RF and Microwave Conference, Proceedings, pp. 1–5. 58. Shairi, N. A., Wong, P. W. and Hisham, B. 2014. Switchable Matched Ring Resonator in SPDT Discrete Switch Design for WiMAX and LTE in 3.5 GHz Band. Asia-Pacific Microwave Conference Proceedings, APMC, 7, pp. 6–8. 59. Shin, S., Guyette, A. C. and Naglich, E. J. 2017. Low-Loss Self-Switching Bandstop Filter. European Microwave Week 2016: ‘Microwaves Everywhere’, EuMW 2016 - Conference Proceedings; 46th European Microwave Conference, EuMC 2016, pp. 882–885. 60. Sinha, T., Pandey, A.K. and Chauhan, R.K., 2016, November. A Compact Dualband Bandpass-to-Bandstop Tunable Filter for Wireless Applications. In Emerging Trends in Communication Technologies (ETCT), International Conference on (pp. 1-4). IEEE. 61. Sorrentino, R., Farinelli, P., Cazzorla, A. and Pelliccia, L., 2017. RF-MEMS Application to RF Tuneable Circuits. In Advances in Science and Technology (Vol. 100, pp. 100-108). Trans Tech Publications. 62. Sovuthy, C. and Wen, W. P. 2012. Design and Synthesis of Microwave Dual Mode Filter. 2012 IEEE Asia-Pacific Conference on Applied Electromagnetics (APACE), (Apace), pp. 226–229. 63. Thomas L. Flyod, 2003. Electrical Circutis Fundamentals, 6th Edition, Prentice Hall. 64. Xiang, T.Y., Lei, T., and Peng, M., 2015. Miniature Dual-Mode Bandpass Filter Based on Meander Loop Resonator with Source-Load Coupling. In Asia Pacific Microwave Conference Proceedings (APMC), Nanjing, China, 6 – 9 Dec 2015. 65. Wong, P.W., 2010. Miniaturised Dual Mode Microwave Filter. In 2010 Asia-Pacific Microwave Conference, Yokohama, 2010, pp. 1090-1093.. 66. Wolff, I. 1972. Microstrip Bandpass Filter using Degenerate Modes of a Microstrip Ring Resonator. Electronics Letters, 8(12), p. 302. 67. Wong, P. W. 2011. Miniaturised Stepped-Impedance Dual-Mode Resonator Filter. ICMTCE2011 - Proceedings 2011 IEEE International Conference on Microwave Technology and Computational Electromagnetics, pp. 174–176. 68. Wong, P. W., Hunter, I. C. and Pollard, R. D. 2007. Matched Bandstop Resonator With Tunable K-Inverter. In Proceedings of the 37th European Microwave Conference, EUMC, (October), pp. 664–667. 69. Wong, P. W. P. and Hunter, I. 2009. Electronically Tunable Filters. IEEE Microwave Magazine, 10(6), pp. 46–54. 70. Wu, Z., Shim, Y. and Rais-Zadeh, M. 2011. Switchable Wide Tuning Range Bandstop Filters for Frequency-Agile Radios. Technical Digest - International Electron Devices Meeting, IEDM, pp. 493–496. 71. Yang, T. and Rebeiz, G. M. 2017. Bandpass-to-Bandstop Reconfigurable Tunable Filters with Frequency and Bandwidth Controls. In IEEE Transactions on Microwave Theory and Techniques, pp. 1–10. 72. Yang, W., Allen, W.N., Psychogiou, D. and Peroulis, D., 2016, April. Tunable bandpass-bandstop filter cascade for VHF applications. In Wireless and Microwave Technology Conference (WAMICON), 2016 IEEE 17th Annual (pp. 1-4). IEEE. 73. Zahari, M.K., Ahmad, B.H., Shairi, N.A. and Wong, P.W., 2011, December. Reconfigurable Matched Bandstop Filter. In RF and Microwave Conference (RFM), 2011 IEEE International (pp. 230-233). IEEE. 74. Zahari, M.K., Ahmad, B.H., Shairi, N.A. and Wong, P.W., 2012, September. Reconfigurable Dual-Mode Ring Resonator Matched Bandstop Filter. In Wireless Technology and Applications (ISWTA), 2012 IEEE Symposium on (pp. 71-74). IEEE.

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