Scan impedance of RSW microstrip antennas in a finite array

Scan impedances of finite reduced surface wave (RSW) arrays are studied. Center element scan impedances of linear arrays and two-dimensional (2-D) square lattice arrays are calculated and compared with those of conventional microstrip arrays. Results show that compared with conventional microstrip a...

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Published in:IEEE transactions on antennas and propagation 2005-03, Vol.53 (3), p.1098-1104
Main Authors: Chen, R.L., Jackson, D.R., Williams, J.T., Long, S.A.
Format: Article
Language:English
Subjects:
Antennas
Antennas and propagation
Applied sciences
Arrays
Blindness
Exact sciences and technology
Feeds
Lattices
Linear antenna arrays
Microstrip antenna arrays
Microstrip antennas
Mutual coupling
Radiocommunications
reduced-surface-wave (RSW) antenna
scan blindness
scan impedance
Surface impedance
Surface waves
Telecommunications
Telecommunications and information theory
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cited_by cdi_FETCH-LOGICAL-c380t-5476dbc1988b2f03e4cc7eb5d97342fbbec5263fad39332a6e4f3ce883d706fe3
cites cdi_FETCH-LOGICAL-c380t-5476dbc1988b2f03e4cc7eb5d97342fbbec5263fad39332a6e4f3ce883d706fe3
container_end_page 1104
container_issue 3
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container_title IEEE transactions on antennas and propagation
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creator Chen, R.L.
Jackson, D.R.
Williams, J.T.
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description Scan impedances of finite reduced surface wave (RSW) arrays are studied. Center element scan impedances of linear arrays and two-dimensional (2-D) square lattice arrays are calculated and compared with those of conventional microstrip arrays. Results show that compared with conventional microstrip arrays, broadside scan impedance of RSW arrays has less variation and converges much faster when the array size increases. Scan performance of the linear and 2-D square lattice RSW arrays are also studied. Results show that the RSW array can avoid the scan blindness (when the array spacing is greater than 0.5/spl lambda//sub 0/) and the scan impedance has much less variation than that of conventional microstrip array with the same array spacing. However, due to the size limitation of RSW elements, the grating lobes cannot be avoided. Hence, the scan region is limited to about 20/spl deg/ (with 0.75/spl lambda//sub 0/ array spacing). Compared with conventional microstrip arrays with 0.5/spl lambda//sub 0/ array spacing, the results show no favor to RSW arrays.
doi_str_mv 10.1109/TAP.2004.842657
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Center element scan impedances of linear arrays and two-dimensional (2-D) square lattice arrays are calculated and compared with those of conventional microstrip arrays. Results show that compared with conventional microstrip arrays, broadside scan impedance of RSW arrays has less variation and converges much faster when the array size increases. Scan performance of the linear and 2-D square lattice RSW arrays are also studied. Results show that the RSW array can avoid the scan blindness (when the array spacing is greater than 0.5/spl lambda//sub 0/) and the scan impedance has much less variation than that of conventional microstrip array with the same array spacing. However, due to the size limitation of RSW elements, the grating lobes cannot be avoided. Hence, the scan region is limited to about 20/spl deg/ (with 0.75/spl lambda//sub 0/ array spacing). 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Center element scan impedances of linear arrays and two-dimensional (2-D) square lattice arrays are calculated and compared with those of conventional microstrip arrays. Results show that compared with conventional microstrip arrays, broadside scan impedance of RSW arrays has less variation and converges much faster when the array size increases. Scan performance of the linear and 2-D square lattice RSW arrays are also studied. Results show that the RSW array can avoid the scan blindness (when the array spacing is greater than 0.5/spl lambda//sub 0/) and the scan impedance has much less variation than that of conventional microstrip array with the same array spacing. However, due to the size limitation of RSW elements, the grating lobes cannot be avoided. Hence, the scan region is limited to about 20/spl deg/ (with 0.75/spl lambda//sub 0/ array spacing). 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Center element scan impedances of linear arrays and two-dimensional (2-D) square lattice arrays are calculated and compared with those of conventional microstrip arrays. Results show that compared with conventional microstrip arrays, broadside scan impedance of RSW arrays has less variation and converges much faster when the array size increases. Scan performance of the linear and 2-D square lattice RSW arrays are also studied. Results show that the RSW array can avoid the scan blindness (when the array spacing is greater than 0.5/spl lambda//sub 0/) and the scan impedance has much less variation than that of conventional microstrip array with the same array spacing. However, due to the size limitation of RSW elements, the grating lobes cannot be avoided. Hence, the scan region is limited to about 20/spl deg/ (with 0.75/spl lambda//sub 0/ array spacing). 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source IEEE Electronic Library (IEL) Journals
subjects Antennas
Antennas and propagation
Applied sciences
Arrays
Blindness
Exact sciences and technology
Feeds
Lattices
Linear antenna arrays
Microstrip antenna arrays
Microstrip antennas
Mutual coupling
Radiocommunications
reduced-surface-wave (RSW) antenna
scan blindness
scan impedance
Surface impedance
Surface waves
Telecommunications
Telecommunications and information theory
title Scan impedance of RSW microstrip antennas in a finite array
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