البحوث العلمية
2024
A low‐profile circularly polarized cavity‐based waveguide aperture antenna
2024-04
Microwave and Optical Technology Letters (القضية : 4) (الحجم : 66)
Abstract
This article proposes a new design of a circularly polarized (CP) aperture
antenna based on a dual‐mode rectangular waveguide cavity‐resonator. A
capacitive iris is employed to attain a strong coupling between the cavity and
the input port, resulting in a larger fractional bandwidth (FBW) than a
conventional aperture antenna. Another capacitive iris is embedded at the
corner of the radiating aperture and extended into the cavity to maintain equal
amplitude and a phase difference of 90° between the radiated electric (E) fields
of the TE101 and TE110 modes, and thus yielding CP radiation. The proposed
antenna has been fabricated using a computer numerical control machine.
The antenna has an FBW of 18% at center frequency (f0) f0 = 10 GHz when the
reflection coefficient (S11) S11 = −10 dB. The 3‐dB axial ratio bandwidth is 7%.
A gain of 8.0 dBic is found at 10.06 GHz. The low profile and competitive
performance of the antenna make it a good candidate in radar applications.
2023
A Monolithically Printed Filtering Waveguide Aperture Antenna
2023-01
IEEE antennas and Wireless Propagation Letters (القضية : 1548)
This letter presents the design of a 3rd order filtering waveguide aperture antenna based on coupled cavity resonators. Three offset-coupled rectangular waveguide cavities are employed in the design realizing two nested loaded-stubs without costing extra structure and size. The loaded-stubs introduce two
controllable transmission zeroes and enhance the out-of-band realized gain selectivity. To validate the predicted results, a prototype operating at the X-band frequencies has been fabricated monolithically using the 3-D selective laser melting printing technique. The measured results are in very good agreement with the simulated results, showing a flat gain response of 7.0 ± 0.2 dBi from 9.5-10.5 GHz with very good out-of-band selectivity. The fractional bandwidth is about 10% at 10 GHz when S11=-20 dB. Compared to the previously designed filtering antennas, the proposed design has the advantages of stronger out-of-band gain selectivity and low profile.
2022
A new design of the 2×2-element subarray antenna based on all-cavity resonator structure is presented in this article. A novel topology which employs only two resonators to layout the subarray is proposed, and two X-band rectangular waveguide cavity resonators are utilized for the subarray physical implementation. The first resonator is a conventional half-guided resonator operating at the TE101 mode. The second resonator, which is an oversized TE102 resonator based, is modified in order to keep the TE101 mode to propagate within the bandwidth of interest and facilitate the connection with the four radiating apertures. The developed coupling matrix approach is utilized to calculate the desirable frequency response, which is a standard 2nd order Chebyshev response with introducing filtering functionality to the realised gain response of the subarray. The simulation results obtained by two simulation softwares (CST and Ansoft HFSS) validate the calculation results. An extremely wide impedance bandwidth of 23% at center frequency 10 GHz when the reflection coefficient (S11 = −10 dB) is obtained. A very stable realised gain with less than 0.5 dBi variations over the bandwidth of interest (8.8–11.1 GHz) is obtained with a peak gain value of 13.1 dBi at 11 GHz. The radiation patterns have very low side lobe levels, particularly in the E-plane, due to the existence of small non-radiating area and maintaining small spacing between the radiating apertures. The proposed 2 × 2-element subarray has the advantages of wider bandwidth and low-profile comparing with our and other previous 2×2-element subarrays.A new design of the 2×2-element subarray antenna based on all-cavity resonator structure is presented in this article. A novel topology which employs only two resonators to layout the subarray is proposed, and two X-band rectangular waveguide cavity resonators are utilized for the subarray physical implementation. The first resonator is a conventional half-guided resonator operating at the TE101 mode. The second resonator, which is an oversized TE102 resonator based, is modified in order to keep the TE101 mode to propagate within the bandwidth of interest and facilitate the connection with the four radiating apertures. The developed coupling matrix approach is utilized to calculate the desirable frequency response, which is a standard 2nd order Chebyshev response with introducing filtering functionality to the realised gain response of the subarray. The simulation results obtained by two simulation softwares (CST and Ansoft HFSS) validate the calculation results. An extremely wide impedance bandwidth of 23% at center frequency 10 GHz when the reflection coefficient (S11 = −10 dB) is obtained. A very stable realised gain with less than 0.5 dBi variations over the bandwidth of interest (8.8–11.1 GHz) is obtained with a peak gain value of 13.1 dBi at 11 GHz. The radiation patterns have very low side lobe levels, particularly in the E-plane, due to the existence of small non-radiating area and maintaining small spacing between the radiating apertures. The proposed 2 × 2-element subarray has the advantages of wider bandwidth and low-profile comparing with our and other previous 2×2-element subarrays.A new design of the 2×2-element subarray antenna based on all-cavity resonator structure is presented in this article. A novel topology which employs only two resonators to layout the subarray is proposed, and two X-band rectangular waveguide cavity resonators are utilized for the subarray physical implementation. The first resonator is a conventional half-guided resonator operating at the TE101 mode. The second resonator, which is an oversized TE102 resonator based, is modified in order to keep the TE101 mode to propagate within the bandwidth of interest and facilitate the connection with the four radiating apertures. The developed coupling matrix approach is utilized to calculate the desirable frequency response, which is a standard 2nd order Chebyshev response with introducing filtering functionality to the realised gain response of the subarray. The simulation results obtained by two simulation softwares (CST and Ansoft HFSS) validate the calculation results. An extremely wide impedance bandwidth of 23% at center frequency 10 GHz when the reflection coefficient (S11 = −10 dB) is obtained. A very stable realised gain with less than 0.5 dBi variations over the bandwidth of interest (8.8–11.1 GHz) is obtained with a peak gain value of 13.1 dBi at 11 GHz. The radiation patterns have very low side lobe levels, particularly in the E-plane, due to the existence of small non-radiating area and maintaining small spacing between the radiating apertures. The proposed 2 × 2-element subarray has the advantages of wider bandwidth and low-profile comparing with our and other previous 2×2-element subarrays.
2022-05
Progress In Electromagnetics Research M (القضية : 8726) (الحجم : 110)
A new design of the 2×2-element subarray antenna based on all-cavity resonator structure
is presented in this article. A novel topology which employs only two resonators to layout the subarray
is proposed, and two X-band rectangular waveguide cavity resonators are utilized for the subarray
physical implementation. The first resonator is a conventional half-guided resonator operating at the
TE101 mode. The second resonator, which is an oversized TE102 resonator based, is modified in order
to keep the TE101 mode to propagate within the bandwidth of interest and facilitate the connection
with the four radiating apertures. The developed coupling matrix approach is utilized to calculate
the desirable frequency response, which is a standard 2nd order Chebyshev response with introducing
filtering functionality to the realised gain response of the subarray. The simulation results obtained by
two simulation softwares (CST and Ansoft HFSS) validate the calculation results. An extremely wide
impedance bandwidth of 23% at center frequency 10 GHz when the reflection coefficient (S11 = −10 dB)
is obtained. A very stable realised gain with less than 0.5 dBi variations over the bandwidth of interest
(8.8–11.1 GHz) is obtained with a peak gain value of 13.1 dBi at 11 GHz. The radiation patterns have
very low side lobe levels, particularly in the E-plane, due to the existence of small non-radiating area and
maintaining small spacing between the radiating apertures. The proposed 2 × 2-element subarray has
the advantages of wider bandwidth and low-profile comparing with our and other previous 2×2-element
subarrays.
الرجوع