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    Journals >Journal of Electronic Science and Technology >Volume 22 >Issue 4 >Page 100289 > Article
    • Journal of Electronic Science and Technology
    • Vol. 22, Issue 4, 100289 (2024)
    Airborne ultra-low profile ultra-wideband omnidirectional antenna based on tightly coupled arrays
    Jun Chen1, Feng Yang2,*, Sheng-Jian Zhao2, Xiao-Bo Shi2..., Ming Huang1 and Shi-Wen Yang2|Show fewer author(s)
    Author Affiliations
  • 1Southwest China Institute of Electronic Technology, Chengdu, 610036, China
  • 2School of Electronic Science and Engineering, University of Electronic Science and Technology of China, Chengdu, 611731, China
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    DOI: 10.1016/j.jnlest.2024.100289 Cite this Article
    Jun Chen, Feng Yang, Sheng-Jian Zhao, Xiao-Bo Shi, Ming Huang, Shi-Wen Yang. Airborne ultra-low profile ultra-wideband omnidirectional antenna based on tightly coupled arrays[J]. Journal of Electronic Science and Technology, 2024, 22(4): 100289 Copy Citation Text show less
    Schematic diagram of omnidirectional conformal ring array based on tightly coupled antenna element. ( denates the amplitude excitation of the n-th port, ra represents the distance from the centroid of the regular octagon to the center of the antenna element.)
    Fig. 1. Schematic diagram of omnidirectional conformal ring array based on tightly coupled antenna element. ( denates the amplitude excitation of the n-th port, ra represents the distance from the centroid of the regular octagon to the center of the antenna element.)
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    Structure diagram of tightly coupled long slot element: (a) traditional element and (b) element with short-circuit wall. (h denotes the height between the ground and long slot element.)
    Fig. 2. Structure diagram of tightly coupled long slot element: (a) traditional element and (b) element with short-circuit wall. (h denotes the height between the ground and long slot element.)
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    Standing wave ratio of the planar element model after the use of short-circuit processing and resistive loading (fl denotes the lowest operating frequency in the working band).
    Fig. 3. Standing wave ratio of the planar element model after the use of short-circuit processing and resistive loading (fl denotes the lowest operating frequency in the working band).
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    Final tightly coupled long slot element model.
    Fig. 4. Final tightly coupled long slot element model.
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    Resistive frequency selective unit and its simulation results.
    Fig. 5. Resistive frequency selective unit and its simulation results.
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    Comparison of the standing wave ratio curves between the tightly coupled long slot element and a connected array element.
    Fig. 6. Comparison of the standing wave ratio curves between the tightly coupled long slot element and a connected array element.
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    Impact of different element numbers on the azimuth radiation pattern of the circular array. (φ is the azimuth angle, N is the antenna element number, f denotes the highest operating frequency, and a represents the radius of the circular array.)
    Fig. 7. Impact of different element numbers on the azimuth radiation pattern of the circular array. (φ is the azimuth angle, N is the antenna element number, f denotes the highest operating frequency, and a represents the radius of the circular array.)
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    Tightly coupled antenna element structure for circular conformal array: (a) before improvement and (b) after improvement.
    Fig. 8. Tightly coupled antenna element structure for circular conformal array: (a) before improvement and (b) after improvement.
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    Schematic diagram of the construction process of the omnidirectional circular conformal array.
    Fig. 9. Schematic diagram of the construction process of the omnidirectional circular conformal array.
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    Actual antenna prototype of the omnidirectional conformal ring array.
    Fig. 10. Actual antenna prototype of the omnidirectional conformal ring array.
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    Measured active VSWR for each port of the omnidirectional conformal ring array.
    Fig. 11. Measured active VSWR for each port of the omnidirectional conformal ring array.
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    Measured and simulated gain patterns of the omnidirectional conformal ring array at some typical frequency points: (a) 2fl , (b) 4fl , and (c) 10fl .
    Fig. 12. Measured and simulated gain patterns of the omnidirectional conformal ring array at some typical frequency points: (a) 2fl , (b) 4fl , and (c) 10fl .
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    Jun Chen, Feng Yang, Sheng-Jian Zhao, Xiao-Bo Shi, Ming Huang, Shi-Wen Yang. Airborne ultra-low profile ultra-wideband omnidirectional antenna based on tightly coupled arrays[J]. Journal of Electronic Science and Technology, 2024, 22(4): 100289
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