A tapered CPW fed leaky‐wave antenna based on substrate integrated waveguide with reduced side‐lobe level

Javanbakht, Nima; Amaya, Rony E.; Shaker, J.; Syrett, Barry

doi:10.1002/mmce.22607

Cited by 5 publications

(6 citation statements)

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“…However, this is achieved at the expense of increasing the complexity and the cost of the DC bias circuitry. Sidelobe level (SLL) can also be reduced by changing the spacing of reconfigurable cells [10], the slots' size [11]- [13], or the feed transition [15].…”

Section: (B)mentioning

confidence: 99%

“…Therefore, implementing a low-profile, low-loss, and beam-steerable antenna is crucial. Beam-steering can be achieved by sweeping the frequency [6]- [15] or electrically [16]- [29] by implementing sets of switches or diodes. The electronic beam-steering antennas are widely applicable in modern communication and navigation systems.…”

Section: Introductionmentioning

confidence: 99%

“…Depending on the slots' spacing and the frequency band, conventional SIW-based LWA can scan forward or backward quadrants [9]. Tapering the slots' size, shape, and spacing changes the radiation characteristics, such as gain and main-lobe pointing angle [10]- [15]. It should be noted that if the via spacing is not selected correctly, undesired leakage occurs from the via fence [30].…”

Section: Introductionmentioning

confidence: 99%

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Reconfigurable SIW-Based Leaky-Wave Antenna Composed of Longitudinal Cells

et al. 2021

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A novel fixed frequency beam-steering leaky-wave antenna (LWA) is presented in this manuscript. Radiation occurs through thin offset longitudinal slots etched on a substrate integrated waveguide (SIW). The beam-steering is achieved by implementing GaAs varactor diodes on the backside of the antenna. Sweeping the bias voltage from 1V to 15V causes the phase constant variation, leading to the 25 • beam-steering at 28.5 GHz. The key novelties of the proposed reconfigurable antenna are the lowprofile and electronic beam-steering capability using a single varactor diode per cell located on the antenna's backside. Moreover, placing the components on the backside reduces the unwanted blockage effects on the radiation. The antenna's thickness, length, and width are 0.32 mm, 95 mm, 24 mm, respectively. The measured peak realized gain of the proposed antenna at 28.5 GHz is 9 ± 0.8 dBi. Low-profile, small gain variation, ease of fabrication, and electronic beam-steering capability make the proposed LWA suitable for the 5G beam-steering applications. A detailed sensitivity analysis along with the experimental validations were performed to prove the validity of the proposed novel design.

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Section: (B)mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Reconfigurable SIW-Based Leaky-Wave Antenna Composed of Longitudinal Cells

et al. 2021

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“…It is obvious that microstrip Yagi antenna array 8,9 is a more suitable solution, since most of these designs 10,11 are limited by bandwidth. Leaky wave antenna is another form of endfire radiation 12‐15 . Similar to the electric or magnetic Yagi antenna, the endfire radiation feature is achieved by array characteristics, so a larger antenna size is inevitable.…”

Section: Introductionmentioning

confidence: 99%

Design of wideband end‐fire composite microstrip‐monopole antenna

Yang

Liu

et al. 2021

Int J RF Microw Comput Aided Eng

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This article introduces a wideband composite antenna with end‐fire radiation. The structure is achieved by uniting a center‐fed microstrip shorted patch and a parasitical monopole. The monopole is vertical to the substrate and work as an electric current source. Because the loaded monopole breaks the symmetry of the center‐fed microstrip antenna, the original patch antenna can work as in‐phase equivalent magnetic current sources radiation. Then complementary sources are generated by orthometric magnetic current source and electric current source. The typical unidirectional radiation capacity has a good endfire beam. The loaded monopole adds a resonant mode to the original microstrip antenna, which makes the composite microstrip‐monopole antenna to exhibit an enhanced bandwidth of 26.9% and an average gain of 7.5 dBi. The complementary sources radiation mechanism can generate special unidirectional radiation patterns in a compact space, so this antenna type is an excellent candidate for array applications. The prototype's planar size is only 0.36λ0 × 0.39λ0 (λ0 is the free space wavelength in center frequency). The eight elements phased array with the proposed antenna show perfect simulated scanning performance.

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“…SIW [35]- [39] has been widely implemented to design LWAs mainly because of its integration capability [48]− [62]. Dispersion response is defined as the behavior of the complex propagation constant throughout the operating frequency band [134]− [136].…”

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confidence: 99%

Analysis and Design of Low-Profile Reconfigurable Leaky-Wave Antennas Based on Substrate Integrated Waveguide for 5G Millimeter-Wave Applications

Javanbakht¹

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5G millimeter-wave (mm-wave) applications have several challenges, such as detection accuracy, interference from other channels, high path loss, covering several users in a dense area, and vulnerability to the environmental conditions. Several antenna technologies were proposed in this dissertation to address some of the above-mentioned challenges in 5G applications with a focus on wireless networks and vehicle to everything (V2X) communications.Leaky-wave antennas (LWAs) are suitable candidates for 5G mm-wave applications due to their beam-scanning capability, compactness, low cost, and ease of fabrication.Substrate integrated waveguide (SIW) and half-mode substrate integrated waveguide (HMSIW) are suitable candidates for realizing LWAs because of their low-profile and integration capability.Several design approaches were introduced in this dissertation to improve the performance of SIW/HMSIW LWAs in 5G mm-wave applications. Some of the proposed antennas have a relatively wide beam-scanning range, suitable for radar systems and V2X communications, while others have small beam-squint, suitable for point-to-point communications and seeker antennas.Tapering the side aperture of an HMSIW and the feed transition of a SIW resulted in side-lobe level (SLL) reduction to enhance the detection accuracy and reduce sensitivity to interference. Applying the proposed methods reduced the SLL of an HMSIW LWA and a SIW LWA to -11.2 dB and -11.4 dB, respectively, in the mm-wave frequency band. I want to thank my wonderful family, Mr. Saeed Javanbakht, Mrs. Mozhdeh Etminan, and Ms. Ayda Javanbakht, for all their supports. I also want to thank my magnificent supervisors, Prof. Barry Syrett, Prof. Rony E. Amaya, and Prof. Jafar Shaker, for their supports and guidance during my Ph.D. studies, as they are like mentors and role models to me. I am grateful to the Ph.D. examination committee, Prof. Dereck McNamara, Prof.

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A tapered CPW fed leaky‐wave antenna based on substrate integrated waveguide with reduced side‐lobe level

Cited by 5 publications

References 45 publications

Reconfigurable SIW-Based Leaky-Wave Antenna Composed of Longitudinal Cells

Reconfigurable SIW-Based Leaky-Wave Antenna Composed of Longitudinal Cells

Design of wideband end‐fire composite microstrip‐monopole antenna

Analysis and Design of Low-Profile Reconfigurable Leaky-Wave Antennas Based on Substrate Integrated Waveguide for 5G Millimeter-Wave Applications

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