Forum for Electromagnetic Research Methods and Application Technologies (FERMAT) Effect of slow wave structures on scan angles in microstrip

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Forum for Electromagnetic Research Methods and Application Technologies (FERMAT) Semnan University Semnan, I. R. Iran Effect of slow wave structures on scan angles in microstrip Leaky-Wave Antennas BY: S. Mohammadpour Jaghargh, P. Rezaei, J. S. Meiguni E-MAIL: javad.meiguni@semnan.ac.ir *This use of this work is restricted solely for academic purposes. The author of this work owns the copyright and no reproduction in any form is permitted without written permission by the author. *

Abstract This paper presents two miniaturized slow wave structures in microstrip leaky-wave antennas (MLWAs) which operate about 8 GHz. The effects of these structures on the scan angles have been compared in the paper. The designed interdigital capacitors and folded-back line have been investigated with ADS Momentum software. It has been shown that the interdigital capacitors (IDCs) yield to a broad scan angles from +53 to -74 degree, while the foldedback line inductor scans only the positive angles. Index Terms leaky-wave antenna (LWA), scan angle, slow wave structure, periodic structure. 2

Contents Introduction History Classification Recent attention Introduction to Slow wave structure Topologies of proposed LWAs Properties of proposed LWAs Effects of slow wave structure on scan angles and Results Conclusion References 3

Introduction Definition of Leaky Wave Antennas (LWA) LWA is guiding structure that supports wave propagation along it. Waves are leaking along it continuously. Application: light and speedy vehicle, missile, plane and automotive Radar. LWA is travelling wave and non-resonant antenna. 4

Introduction Advantages of LWAs Semnan University Semnan, Iran High directivity. Simple and cheap structure. Not-complicated feed network. Ideally suits for frequency beam scanning applications (Beam scans with frequency inherently). So popular in Microwave and millimeter bands. 5

Introduction Disadvantages of LWAs Narrow pattern beam width (1% to 10%). So, not appropriate for Point-to-Point communication. 6

History of LWAs Started at 1940s. Introducing as slotted rectangular waveguide. Some prototype LWA structures, See below! Honey LWA-1959 Dimensions: 46-61 cm 7-13 GHz Transverse resonance method Φ(f) 7

Classification of LWAs Classification based on feed location (Right chart) Classification based on wave propagating (Left chart) LWA LWA 2-Dimension 1-Dimension Unidirectional case Bidirectional case Periodic Uniform / Quasi-uniform (Feed at one side) (Feed at center) 8

Classification of LWAs Based on feed location Semnan University Semnan, Iran Figure (a): Unidirectional case (Feed at one side) Figure (b): Bidirectional case (Feed at center): So useful because of creating beam at broadside. 9

Classification of LWAs Based on wave propagating 1D: Wave is guided in 1 directional. 1) Uniform (or Quasi-uniform): Guiding structure is uniform along length (support fast waves, 0< β < k 0 ). 2) Periodic: Non-radiating changes to radiating by periodic structures (support slow wave, β > k 0 ). 2D: Wave is propagated on 2D guiding surface. 10

Recent Attention on LWA Full space scanning continuously. Means: full-space continuous beam scanning, from backfire to endfire, including the broadside direction. Create broadside beam by bidirectional LWA. Overcoming the open stop band problem. Power recycling to avoid wasting non-radiated power. LWA for curved surface. 11

Slow wave structures (SWSs) Controlling and handle the wave velocity in certain direction. SWS is non-resonant circuit. SWS is designed for producing large gain antennas. 12

Some slow wave structures Zigzag line Corrugated waveguide Helical line Folded-back line inductor Interdigital capacitor (IDC) Effects of them on scan angles in LWA will be investigated. Interdigital Capacitor (typical IDC) Folded back line inductor 13

Unit cell of each proposed LWAs Zoom in 3D view of proposed LWA with periodic IDC. Unit cell of IDC Zoom in 3D view of proposed LWA with periodic folded-back line. Unit cell of folded-back line 14

3D view of 16-cell periodic LWAs 3D view of LWA with IDCs formed by 16 cells. 3D view of LWA with folded-back line formed by 16 cells. 15

Properties of proposed LWAs Semnan University Semnan, Iran Property LWA with IDCs LWA with folded back Type of LWA CRLH RH Fabrication Technology Microstrip Microstrip Number of cells 16 16 Frequency band analyzing X-band X-band Dimensions of unit cell 4.5mm * 4mm 4.5mm * 4mm Dimensions of 16-cell 4.5mm * 64mm 4.5mm * 64mm Substrate and height Rogers 5880, h = 0.508mm Rogers 5880, h = 0.508mm Ԑ r of substrate 10.2 10.2 16

Results of radiation pattern and scan angles for both MLWAs 20 0 17.647 db 13.393 db 12.066 db 20 0 2.106 db 11.236 db Gain (db) -20-40 -60 Pattern at 8GHz -80 Max gain at 9.285GHz Pattern at 10.363GHz -100-100 -80-60 -40-20 0 20 40 60-74 -18 Theta (degree) +53 80 100 Radiation pattern of LWA with IDC Gain (db) -20-40 -60-80 Pattern at 8GHz -100-100 Pattern,Max gain at 8.714GHz -80-60 -40-20 0 20 40 60 Theta (deg) +3 +54 80 100 Radiation pattern of LWA with folded back 17

Other Results Scan angle (degree) 60 40 20 +53 deg +54 deg LWA with Folded back line LWA with Interdigital 0 +3 deg 10-20 Scan Interval 5.93 db for Folded 5 back line -40 0 LWA with Folded back line -60 LWA with Interdigital -77 deg -5 Average for Interdigital Scan Interval for Interdigital -80 Average for Folded back line -10 7.5 8 8.5 8.714 9 9.5 10 10.5 7.5 8 8.5 9 9.5 10 10.5 Frequency (GHz) Frequency (GHz) Details of scan angles in both proposed LWAs when frequency changes. Gain (db) 20 15 14 db Details of magnitude of the gain in both proposed LWAs when frequency changes and the average of gains in interval of scan. 18

Magnitude of S-parameter Semnan University Semnan, Iran Magnitude of S-parameter (db) 0-5 -10-15 -20-25 S11 of IDC S12 of IDC S12 of Folded back S11 of Folded back -30 8 8.5 9 9.5 10 10.5 11 Frequency (GHz) Red lines: S-Parameter for LWA with IDCs Blue lines: S-Parameter for LWA with folded-back line 19

Comparative results and conclusion Replacing an Interdigital capacitor with a folded back line inductor in this letter. LWA with Folded back line scans only positive angles (Forward radiation). Name of antenna LWA with IDC LWA with folded back Scan Freq (GHz) Scan angles (deg) in Φ= 0 plane Max gain (db) Forward / backward radiation descriptions 8 to 10.36-74 to +53 17.64 Yes / Yes CRLH 8 to 8.71 +3 to +54 11.23 Yes / No RH 20

References [1] D. R. Jackson and A. A. Oliner, Leaky-wave antennas in modern antenna handbook, New York: Wiley, 2008. [2] C. Caloz, D. R. Jackson, and T. Itoh, Leaky-wave antennas, IEEE Trans. Antennas Propag., vol. 100, no.7, pp. 2194-2206, July 2012. [3] V. Nguyen, A. Parsa, and C. Caloz, Power-recycling feedback system for maximization of leaky-wave antennas radiation efficiency, IEEE Trans. Microw.Theory Tech., vol. 58, no. 7, pp. 1641-1650, July 2010. [4] R. C. Honey, A flush-mounted leaky wave antenna with predictable patterns, IRE Trans. Antennas Propag., vol. 7, pp. 320-329, Oct. 1959. [5] S. Y. Liao, Microwave devices and circuits, New Jersey: Prentice Hall, 1990. [6] S. S. Gevorgian, T. Martinsson, P. L. J. Linner and E. L. Kollberg, CAD models for multilayered substrate interdigital capacitor, IEEE Trans. Microw. Theory Tech., vol. 44, no. 6, pp. 896-904, June 1996. [7] N. Amani, M. Kamyab, A. Jafargholi, A. Hosseinbeig and J.S. Meiguni, Compact tri-band metamaterial-inspired antenna based on CRLH resonant structures, Electronic Letts., vol. 50, no. 12, pp. 847-848, June 2014. [8] S. Mohammadpour Jaghargh, P. Rezaei and J. S. Meiguni, Simulation and design of a novel K-band microstrip leaky-wave antenna with metamaterial unit cell and slow-wave structure, 1st national conf. Development of civil eng. Archetecture, electricity and mechanichal in Iran., Gorgan, Iran, Dec 2014. 21

References [9] G. F. Cheng and C. K. C. Tzuang, Closely coupled half-width leakywave antenna array, 6th European Conf. Antennas and Propag., pp. 957-960, 2012. [10] J. Liu, D. R. Jackson, and Y. Long, Substrate integrated waveguide (SIW) leaky-wave antenna with transverse slots, IEEE Trans. Antennas Propag., vol. 60, no. 1, pp. 20-29, Jan. 2012. [11] C. Calm, T.Itoh, and A.Renning, CRLH metamaterial leaky-wave and resonant antennas, IEEE Antennas Propag. Mag., vol. 50, no.5, pp. 25-39, Oct. 2008. [12] Y. Li, Q. Xue, H.z. Tan, and Y. Long, The half-width microstrip leaky wave antenna with the periodic short circuits, IEEE Trans. Antennas Propag., vol. 9, no. 9, pp. 3421-3423, Sept. 2011. [13] A. Pourghorban Saghati, M. Mirsalehi and M.H. Neshati, A HMSIW circularly polarized leaky-wave antenna with backward, broadside, and forward radiation, IEEE Antennas and Wireless Propag Letts., vol. 13, pp. 451-454, Mar. 2014. [14] S. Paulotto, P. Baccarelli, F. Frezza1 and D. R. Jackson, A microstrip periodic leaky-wave antenna optimized for broadside scanning, Antennas and Propag. Society International Symposium IEEE, pp. 5789-5792, 2007. [15] A. Sutinjo, M. Okoniewski and R. H. Johnston, Radiation from fast and slow traveling waves, IEEE Antennas Propag. Mag., vol. 50, no. 4, pp. 175-181, Aug. 2008. 22

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