Your search keyword '"lens antennas"' showing total 1,292 results

1. A 3D printed low‐profile wideband circularly polarised elliptical integrated lens antenna

Author

Bin Xu, Bing Zhang, and Xiao An

Subjects

lens antennas, lenses, Telecommunication, TK5101-6720, Electricity and magnetism, QC501-766

Abstract

Abstract The authors presents a low‐profile wideband circularly polarised (CP) millimetre‐wave (mmWave) elliptical integrated lens antenna (ILA) fabricated by dielectric 3D printing technology. The proposed lens is integrated with a dielectric polariser and an air cavity for phase compensation, which can transfer incident waves from linearly polarised (LP) to planar CP waves over a wide bandwidth. Compared to the classic bifocal ILA, the proposed lens has a low profile. The phase compensation is performed by introducing a specifically shaped air cavity, which greatly reduces the length and weight of the lens. The polariser causes the two electric field components Ex and Ey to degenerate with an orthogonal phase difference, which results in the wideband characteristics of the antenna. The polariser, air cavity and lens can be conveniently and precisely fabricated by low‐cost 3D printing technology. Measurements show that the proposed ILA has a wide axial ratio (AR) bandwidth of 21.9–32.6 GHz, while the gain reaches 22.54 dBic with a 38% size reduction and a 60.7% weight reduction. Benefiting from the low profile, high gain, wide bandwidth and low cost, the proposed ILA has great potential to be the candidate antenna for 5G applications and satellite communications.

Published

2024

2. A 3D printed low‐profile wideband circularly polarised elliptical integrated lens antenna.

Author

Xu, Bin, Zhang, Bing, and An, Xiao

Subjects

*ANTENNAS (Electronics), *TELECOMMUNICATION satellites, *THREE-dimensional printing, *ELECTRIC fields, *BANDWIDTHS

Abstract

The authors presents a low‐profile wideband circularly polarised (CP) millimetre‐wave (mmWave) elliptical integrated lens antenna (ILA) fabricated by dielectric 3D printing technology. The proposed lens is integrated with a dielectric polariser and an air cavity for phase compensation, which can transfer incident waves from linearly polarised (LP) to planar CP waves over a wide bandwidth. Compared to the classic bifocal ILA, the proposed lens has a low profile. The phase compensation is performed by introducing a specifically shaped air cavity, which greatly reduces the length and weight of the lens. The polariser causes the two electric field components Ex and Ey to degenerate with an orthogonal phase difference, which results in the wideband characteristics of the antenna. The polariser, air cavity and lens can be conveniently and precisely fabricated by low‐cost 3D printing technology. Measurements show that the proposed ILA has a wide axial ratio (AR) bandwidth of 21.9–32.6 GHz, while the gain reaches 22.54 dBic with a 38% size reduction and a 60.7% weight reduction. Benefiting from the low profile, high gain, wide bandwidth and low cost, the proposed ILA has great potential to be the candidate antenna for 5G applications and satellite communications. [ABSTRACT FROM AUTHOR]

Published

2024

3. The low‐cost inhomogeneous multi‐section flat lens antenna with minimum F over D design in Ku‐band

Author

Mohammad Mahdi Taskhiri

Subjects

geometrical optics, inhomogeneous media, lens antennas, Telecommunication, TK5101-6720, Electricity and magnetism, QC501-766

Abstract

Abstract This article uses the ray inserting method to design a low‐cost inhomogeneous lens in the Ku‐band. The focal length to the diametre ratio of the designed lens is 0.45, which is lower than most designed lenses in this area. Also, no approximation is considered to yield the refractive index profile. The refractive index changes from the centre to the sides have been made in two sections to limit the maximum calculated refractive index of the structure to the Plexiglass refractive index. The designed lens proposed a good match to the source and surroundings. The theoretical design is validated by the finite difference time domain scheme and full‐wave simulation. The lens structure is realised and fabricated on a multilayer Plexiglass sheet. The results of simulations and experiments indicate good performances of the designed lens in the wide frequency bandwidth.

Published

2024

4. The low-cost inhomogeneous multi-section flat lens antenna with minimum F over D design in Ku-band.

Author

Taskhiri, Mohammad Mahdi

Subjects

*ANTENNAS (Electronics), *REFRACTIVE index, *FOCAL length, *FINITE differences, *GEOMETRICAL optics

Abstract

This article uses the ray inserting method to design a low-cost inhomogeneous lens in the Ku-band. The focal length to the diametre ratio of the designed lens is 0.45, which is lower than most designed lenses in this area. Also, no approximation is considered to yield the refractive index profile. The refractive index changes from the centre to the sides have been made in two sections to limit the maximum calculated refractive index of the structure to the Plexiglass refractive index. The designed lens proposed a good match to the source and surroundings. The theoretical design is validated by the finite difference time domain scheme and full-wave simulation. The lens structure is realised and fabricated on a multilayer Plexiglass sheet. The results of simulations and experiments indicate good performances of the designed lens in the wide frequency bandwidth. [ABSTRACT FROM AUTHOR]

Published

2024

5. Top shelf.

Subjects

HOME theaters, PERFORMANCES, OPTICAL resolution, TECHNOLOGY, LENS antennas

Abstract

The article presents the discussion on BenQ W5800 home cinema projector, known for its impressive performance showcased at the Australian Hi-Fi Show. Topics include large size, flexible positioning options, and capability to project up to 200-inch screens with 4K UHD resolution using Texas Instruments' DLP technology; and optical zoom, motorized lens shift, and the projection capabilities suitable for expansive home theater setups.

Published

2024

6. 6G energy‐efficient systems based on arrays combined with dielectric lenses.

Author

Wang, Hairu, Castillo‐Tapia, Pilar, Manholm, Lars, Johansson, Martin, Quevedo‐Teruel, Oscar, and Algaba‐Brazález, Astrid

Subjects

*ANTENNA arrays, *DIELECTRICS, *TELECOMMUNICATION systems, *PHASED array antennas, *ENERGY consumption

Abstract

It is demonstrated that combining phased array antennas with dielectric lenses constitutes a suitable solution to increase the energy efficiency in next‐generation communication systems. A dielectric lens is designed to increase the gain of an array antenna working in the 3GPP n257 band (26.5–29.5 GHz). The simulated results demonstrate that the dielectric lens increases the gain between 0.4 and 1.3 dB in a large scanning range from 0° to 60° at 28 GHz; meaning that the output RF power can be decreased by up to 26% for a same equivalent isotropic radiated power required from the base station. [ABSTRACT FROM AUTHOR]

Published

2023

7. Design, Simulation, and Construction of a SWB Antenna Using a Metasurface Luneburg LENS

Author

Bagheri, Vahid Reza, Yahaghi, Alireza, and Abiri, Habibollah

Published

2024

8. A novel metasurface lens antenna design for over‐the‐air testing in millimetre wave radio resource management measurement

Author

Yu Zhang, Zhiqin Wang, Zhiwen Xue, Ying Zhu, and Yuxin Ren

Subjects

antenna testing, lens antennas, metamaterial antennas, microwave measurement, millimetre wave antennas, millimetre wave measurement, Telecommunication, TK5101-6720, Electricity and magnetism, QC501-766

Abstract

Abstract In millimetre wave (mmWave) frequency band, radio resource management (RRM) performance is characterised in plane wave conditions using radiated over‐the‐air test method, which is a challenging combination of protocol and radio frequency performance measurement. This article presents a novel design of multiple lens‐based compact antenna test ranges (CATRs) to simulate multiple angles of arrival from different base‐stations in RRM measurement. Only four lens‐based CATRs are proposed to create plane wave conditions at the device under test with six different angles of arrival and capable of accurately constructing the wireless propagation condition and minimising the diffraction and scattering between adjacent CATRs. The lens‐based CATR is the key element in the RRM measurement system, which is composed of a metasurface lens for phase alignment and a 2 × 2 feed array antenna for the emission of electromagnetic signals. The function and capability of the proposed lens‐based CATR is validated through simulation and measurement, that the worst‐case amplitude variation in the quiet zone region is lower than ±0.8 dB at 26 GHz, and phase variation is lower than ±7.5° in the designed quiet zone, which could be used in the fifth‐generation mmWave RRM measurement.

Published

2023

9. 6G energy‐efficient systems based on arrays combined with dielectric lenses

Author

Hairu Wang, Pilar Castillo‐Tapia, Lars Manholm, Martin Johansson, Oscar Quevedo‐Teruel, and Astrid Algaba‐Brazález

Subjects

5G mobile communication, arrays, lens antennas, radomes, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Abstract It is demonstrated that combining phased array antennas with dielectric lenses constitutes a suitable solution to increase the energy efficiency in next‐generation communication systems. A dielectric lens is designed to increase the gain of an array antenna working in the 3GPP n257 band (26.5–29.5 GHz). The simulated results demonstrate that the dielectric lens increases the gain between 0.4 and 1.3 dB in a large scanning range from 0° to 60° at 28 GHz; meaning that the output RF power can be decreased by up to 26% for a same equivalent isotropic radiated power required from the base station.

Published

2023

10. A novel metasurface lens antenna design for over‐the‐air testing in millimetre wave radio resource management measurement.

Author

Zhang, Yu, Wang, Zhiqin, Xue, Zhiwen, Zhu, Ying, and Ren, Yuxin

Subjects

*RADIO resource management, *ANTENNA design, *RADIO waves, *RADIO frequency measurement, *ANTENNA feeds

Abstract

In millimetre wave (mmWave) frequency band, radio resource management (RRM) performance is characterised in plane wave conditions using radiated over‐the‐air test method, which is a challenging combination of protocol and radio frequency performance measurement. This article presents a novel design of multiple lens‐based compact antenna test ranges (CATRs) to simulate multiple angles of arrival from different base‐stations in RRM measurement. Only four lens‐based CATRs are proposed to create plane wave conditions at the device under test with six different angles of arrival and capable of accurately constructing the wireless propagation condition and minimising the diffraction and scattering between adjacent CATRs. The lens‐based CATR is the key element in the RRM measurement system, which is composed of a metasurface lens for phase alignment and a 2 × 2 feed array antenna for the emission of electromagnetic signals. The function and capability of the proposed lens‐based CATR is validated through simulation and measurement, that the worst‐case amplitude variation in the quiet zone region is lower than ±0.8 dB at 26 GHz, and phase variation is lower than ±7.5° in the designed quiet zone, which could be used in the fifth‐generation mmWave RRM measurement. [ABSTRACT FROM AUTHOR]

Published

2023

11. Machine learning‐assisted direction‐of‐arrival accuracy enhancement technique using oversized lens‐loaded cavity

Author

Muhammad Ali Babar Abbasi, Okan Yurduseven, Mobayode O. Akinsolu, Vincent F. Fusco, Bo Liu, Mohsen Khalily, Simon L. Cotton, and Muhammad Ali Imran

Subjects

antennas, B5G mobile communication, channel estimation, diversity reception, lens antennas, Telecommunication, TK5101-6720, Electricity and magnetism, QC501-766

Abstract

Abstract This paper presents a framework for achieving machine learning (ML)‐assisted direction‐of‐arrival (DoA) accuracy enhancement using a millimetre‐wave (mmWave) dynamic aperture. The technique used for the enhanced DoA estimation accuracy leverages an over‐sized lens‐loaded cavity antenna connected to a single RF chain in the physical layer and a computational method in the computational layer of the framework. It is shown for the first time that by introducing a reconfigurable mode‐mixing mechanism inside the over‐sized lens‐loaded cavity hardware, a greater number of spatially orthogonal radiation modes can be achieved giving rise to many cavity states. If the best cavity state is determined and selected by means of design exploration using a contemporary ML‐assisted antenna optimisation method, the computational DoA estimation accuracy can be improved. The mode‐mixing mechanism in this work is a randomly oriented metallic scatterer located inside an over‐sized constant−ϵr lens‐loaded cavity, connected to a stepper motor that is electronically controlled by inputs from the computational layer of the presented framework. Measurement results in terms of near‐field radiation mode scans are included in this study to verify and validate that the proposed ML‐assisted framework enhances the DoA estimation accuracy. Moreover, this investigation simultaneously provides a simplification in the physical layer implementation of mmWave radio hardware, and DoA accuracy enhancement, which in turn lends itself favourably to the adoption of the proposed framework for channel sounding in mmWave communication systems.

Published

2022

12. First Demonstration of Dynamic High-Gain Beam Steering With a Scanning Lens Phased Array

Author

Sjoerd Bosma, Nick Van Rooijen, Maria Alonso-Delpino, Marco Spirito, and Nuria Llombart

Subjects

Beam steering, lens antennas, millimeter waves, phase shifting, phased arrays, Telecommunication, TK5101-6720, Electric apparatus and materials. Electric circuits. Electric networks, TK452-454.4

Abstract

We report on the first demonstration of dynamic beam steering using a scanning lens phased array. A scanning lens phased array relies on a combination of mechanical and electrical phase shifting to dynamically steer a high-gain beam beyond the grating-lobe free region using a sparse array. These two concepts have been demonstrated separately in the past, here we present, for the first time, a prototype demonstration where active mechanical and electrical phase shifting are combined. For this purpose, we have developed a sparse 4x1 scanning lens phased array at W-band (75-110 GHz) capable of beam steering a directive beam (>30 dBi) towards ± 20° with low grating lobe levels (around -10 dB). The lens array is fed by a waveguide-based leaky-wave feeding architecture that illuminates the lenses with high aperture efficiency over a wide bandwidth, which is required in the proposed scanning lens phased array architecture. The electrical phase shifting has been implemented using IQ-mixers around 15 GHz in combination with x6 multipliers to reach the W-band. The mechanical phase shifting relies on a piezo-electric motor, which is able to achieve displacements of the lens array of 6 mm with an accuracy of a few nanometers. The entire active array is calibrated over the air with an ad-hoc quasi-optical measurement setup. Resulting measurements show excellent agreement with the anticipated performance.

Published

2022

13. A Millimeter-Wave 2D Beam Steering Antenna Using Extended Hemispherical Dielectric Lens Antenna Subarrays

Author

Kiran A. Shila and Gokhan Mumcu

Subjects

Beam steering, lens antennas, millimeter-wave, phased arrays, three-dimensional (3-D) printing, subarray, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Recent work has proposed that millimeter-wave beam steering antennas consisting of lens antenna subarrays (LASs) reduce hardware complexity. This manuscript extends the concept to 2D beam steering with extended hemispherical dielectric lenses (EHDLs). To accomplish this, we introduce a design process to maximize scan range and side lobe level (SLL) performance. The design process first employs the solution of the geometric disk covering problem to identify the initial positions of the feed antennas such that the subarray size, $M$ , is minimized. This process is followed by systematic 3D full-wave simulation-based parametric sweeps of lens geometry and feed antenna positions to maximize scan range and minimize SLL. Finally, we demonstrate this process with a 38 GHz antenna consisting of $L$ = 7 LASs and $M$ = 17 feed antennas per LAS. The resulting antenna has a ±36° field of view, −9.5 dB SLL, 5° half-power beamwidth, and ~20 dBi maximum realized gain. Compared to the existing literature on subarray-based beam-steering antennas, this antenna performs with a more extensive scan range while offering a comparable SLL performance.

Published

2022

14. Analytical Formulas for Refractive Indices of a Telescopic GRIN Lens for Aperture Magnification.

Author

Paraskevopoulos, Anastasios, Gashi, Ilir, Albani, Matteo, and Maci, Stefano

Abstract

In this letter, we derive a new closed-form analytical formula for the refractive index of a telescopic lens based on inhomogeneous graded index (GRIN) material. The telescopic lens is composed of two cylindrical confocal GRIN lenses, one divergent and one convergent. The scope of the telescopic lens is to magnify the aperture of a flat antenna placed at the first interface of the divergent-convergent lens doublet. This telescopic GRIN lens is useful for reusing already available medium-gain arrays and bring them to a high-gain, occupying a reduced volume as compared to traditional lenses or multireflector systems. The formulation used here is based on the solution of a regularized ray-congruence integral equation recently introduced by the authors, and applied in a previous work to treat convergent cylindrical GRIN lenses. The formulation is extended here to the case of a telescopic lens leading to analytical formulas for the two inhomogenous refractive indexes that involve five independent parameters; these parameters are eventually optimized to get the maximum gain boost. [ABSTRACT FROM AUTHOR]

Published

2022

15. Compound GRIN Fanbeam Lens Antenna With Wideband Wide-Angle Beam-Scanning.

Author

Garcia, Nicolas C. and Chisum, Jonathan D.

Subjects

*ANTENNAS (Electronics), *APERTURE antennas, *PARALLEL-plate waveguides, *ANTENNA feeds, *SIGNAL processing, *ARRAY processing

Abstract

This work presents a parallel-plate waveguide (PPWG) fanbeam antenna achieving a $\pm 48^\circ $ field of view with an average maximum scan loss of $2.7\,\textrm {dB}$ over the Ka-band for a flat feed surface. This approach uses a novel compound gradient index (GRIN) lens system, wherein two GRIN lenses are cascaded axially: an “aperture” lens at the antenna output provides the bulk of the phase collimation, while a “focal” lens near the feed surface corrects the spillover losses and provides additional phase collimation. This arrangement represents a wide-scanning alternative that requires 76% of the axial depth and only 37.3% of the actual material compared to a Luneburg lens fanbeam antenna with similar aperture size. A maximum scan loss of $2.58~$ dB at 48° and a scan loss exponent of 1.5 are achieved at $40~$ GHz. [ABSTRACT FROM AUTHOR]

Published

2022

16. Tailoring the Performance of Geodesic Lens Antennas By Defining their Footprint

Author

Clendinning, Sarah, Zetterström, Oskar, Rico-Fernández, J., Mesa, F., Quevedo-Teruel, Oscar, Clendinning, Sarah, Zetterström, Oskar, Rico-Fernández, J., Mesa, F., and Quevedo-Teruel, Oscar

Abstract

This paper discusses non-rotationally symmetric geodesic lens antennas. By defining the shape of the lens footprint, additional degrees of freedom are introduced into the design process, allowing for further tailoring of the electromagnetic performance of the lens while simultaneously reducing the volume occupied by the lens. An in-house ray-tracing model for geodesic lenses has been modified to analyze this class of lenses. Examples showing the effect of modifying the lens profile are presented, with a more detailed discussion on profile presenting improved side-lobe levels at the extreme ports. The examples presented operate at 30 GHz., QC 20240520Part of ISBN 978-883129909-1

Published

2024

17. Antennas Based on Rotationally Symmetric Lenses for High-Frequency Wireless Applications

Author

Zetterström, Oskar and Zetterström, Oskar

Abstract

This thesis investigates lens antennas for future wireless applications. The aim is to provide robust and cost-effective antenna solutions with wide-angle beam steering capabilities. The wide-angle beam steering is obtained using rotationally symmetric inhomogeneous lenses, such as the Luneburg lens. The derivation of the inhomogeneous refractive index using geometrical optics is outlined. Parallel plate waveguide (PPW) lens antennas and volumetric lens antennas are investigated. The studied PPW lens antennas are designed to be robust to manufacturing and assembly errors while enabling a high radiation efficiency and wide-angle steering of a fan-shaped beam. The refractive index distribution is mimicked using quasi-periodic structures or by shaping the PPW. Specifically, two robust and cost-effective glide-symmetric quasi-periodic structures are proposed. First, glide-symmetric substrate-integrated holes (SIHs) are proposed, since they enable a larger PPW spacing compared to previously reported fully-metallic designs. This large PPW spacing translates into a robust antenna solution, and the SIH structure can be cost-effectively manufactured. The presence of the dielectric introduces losses, but it is shown that these added losses are sufficiently low for many applications at Ka-band. Secondly, a glide-symmetric perforated dielectric slab is proposed to enable an even larger PPW spacing. The slab is produced using additive manufacturing and it is shown that by arranging the perforations glide-symmetrically, a wider range of effective refractive indices can be accurately realized. Again, it is shown that the added losses due to the dielectric are sufficiently low for practical applications at Ka-band. Fully-metallic (and therefore highly efficient) PPW lens antennas can be based on geodesic lenses. These lenses do not require the realization of any small features and can therefore be robust. A geodesic lens antenna demonstrator at V-band is presented, and techniques, Denna avhandling undersöker linsantenner för framtida trådlösa tillämpningar. Målet är att tillhandahålla robusta och kostnadseffektiva antennlösningarmed bred strålstyrningsförmåga. Den breda strålstyrningen uppnås med hjälp av rotationsymmetriska inhomogena linser, såsom Luneburg-linsen. Härledningen av det inhomogena brytningsindexet med geometrisk optik beskrivs. Linsantenner implementerade i planvågledare (PPW) och volymetriskalinsantenner undersöks. De studerade PPW-linsantennerna är konstruerade för att vara robusta mot tillverknings- och monteringsfel samtidigt som de möjliggör hög strålningseffektivitet och strålstyrning i ett brett vinkelspann. Linsens brytningsindex realiseras med hjälp av kvasiperiodiska strukturer eller genom att modifiera vågledaren. Specifikt föreslås två robusta och kostnadseffektiva glidsymmetriska kvasiperiodiska strukturer. För det första används glidsymmetriska substratintegrerade hål (SIHs) för att möjliggöra ett större PPW-avstånd jämfört med tidigare rapporterade helt metalliska konstruktioner. Detta stora PPW-avstånd leder till en robust antennlösning, och SIH-strukturen kan tillverkas kostnadseffektivt. Närvaron av dielektrikat medför förluster, men det visar sig att dessa uppkomna förluster är tillräckligt låga för många tillämpningar i Ka-bandet. För det andra används en glidsymmetrisk perforerad dielektrisk skiva för att möjliggöra ett ännu större PPW-avstånd. Skivan tillverkas additivt genom att arrangera perforationerna glidsymmetriskt vilket möjliggör att fler effektiva brytningsindex kan realiseras. Återigen visas det att de tillkomna förlusterna på grund av dielektrikat är tillräckligt låga för praktiska tillämpningar i Ka-bandet. Helt metalliska (och högeffektiva) PPW-linsantenner kan baseras på geodesiska linser. Dessa linser kräver inte realisering av små detaljer och kan därför vara robusta. En demonstrator av en geodesisk linsantenn för V-bandet presenteras, och tekniker för att minska känsligheten för tillverkn, QC 20240508

Published

2024

18. Analysis and Design of Lens Antenna Systems for Applications at Millimeter and Sub-millimeter Wavelengths

Author

Zhang, H. (author) and Zhang, H. (author)

Abstract

In recent decades, dielectric lens antennas have been more and more adopted and developed for sensing and imaging applications at sub-millimeter (sub-mm) wavelengths because they can achieve high gain while keeping their physical size and weight acceptable at these wavelengths. More recently, as low-loss and low-cost lens materials have become available and the lens fabrication is becoming easier and more accurate, lens antennas are attracting more interests for variety of applications at millimeter (mm) wavelengths such as high-data-rate wireless communication and automotive radars. However, the analysis and design of lens antennas at mm and sub-mm wavelengths present different challenges. In this thesis, we propose to use a field correlation technique to analyze lens antennas in reception and then optimize their aperture efficiency for different scenarios. Based on this optimization methodology, three examples of lens antenna systems are described at 28 GHz, 180 GHz, and beyond 200 GHz for the applications of 5G communication, wide field-of-view security imaging, and future mm-resolution THz imaging, respectively. The proposed methodology and design provide possible solutions for the potential challenges and can be used as guidelines for designing lens antennas at mm and sub-mm wavelengths....., Tera-Hertz Sensing

Published

2024

19. A Transformation-Optics-Based Flat Metamaterial Luneburg Lens Antenna With Zero Focal Length.

Author

Xu, Ruolei and Chen, Zhi Ning

Subjects

*FOCAL length, *METAMATERIAL antennas, *ANTENNA feeds, *ANTENNAS (Electronics), *TRANSFORMATION optics, *CONDUCTIVE ink

Abstract

The transformation optics (TO) technique has been widely applied in the volume reduction of Luneburg lens (LL) in both optical and microwave regimes. However, it is found that the focus is usually not located on the surface of the transformed LL anymore after applying TO. The focus location shift results in a limited volume reduction, severe reflection from the new lens surface, and limited scanning range with increased spillover loss. This article theoretically studies and proposes a TO-based LL antenna with zero focal length by considering the phase mismatch caused by space discontinuity. The study first reveals that the transformation of an LL alone without sustaining the original boundary inherently deteriorates the original focusing property even before exerting any approximation. To validate the idea, a flat metamaterial LL antenna using TO is proposed, approximated, and fabricated using an integrated dielectric and conductive 3-D printing manufacturing process. The feeding patch antenna remains on the surface of the transformed lens. The thickness of the proposed antenna is reduced to 1/3 of a traditional LL in its boresight, while a ±20° beam scanning range is achieved with linearly shifted feedings. The study verifies that it is essential to ensure phase matching at the radiation boundary to maintain the original focusing property of an LL. The information derived from the study evidences the conditions of the enforcement of TO in electromagnetic problems such as dielectric lenses. [ABSTRACT FROM AUTHOR]

Published

2022

20. 3-D-Printed Shaped and Material-Optimized Lenses for Next-Generation Spaceborne Wind Scatterometer Weather Radars.

Author

Papathanasopoulos, Anastasios, Budhu, Jordan, Rahmat-Samii, Yahya, Hodges, Richard E., and Ruffatto, Donald F.

Subjects

*FUSED deposition modeling, *ANTENNA design, *PARTICLE swarm optimization, *GEOMETRICAL optics, *MECHANICAL wear, *RADAR meteorology

Abstract

Current spaceborne wind scatterometers have shown failure due to mechanical wear from moving parts used to conically scan a directive beam. In order to eliminate the risk of mechanical rotation failure, an antenna design with no moving parts that achieve the conical beam sweep is desirable. In this article, a lightweight, 3-D-printed, inhomogeneous lens antenna is presented as an all-electronic alternative. Compared to the previous on-axis fed lenses, the real-life application requiring conical scanning necessitates significant developments regarding the synthesis, optimization, and prototyping of the off-axis fed lens. The lens antenna is designed using curved-ray geometrical optics coupled to particle swarm optimization to determine the optimum lens surface shapes and material inhomogeneity while obtaining a design with minimum volume and therefore mass. An 18 cm lens is designed using this approach. Instructions on how to 3-D-print the inhomogeneous lens are given using a unit cell design, which permits additive manufacturing using fused deposition modeling (FDM) techniques. The lens is measured for far-field pattern performance at various locations along with the ring-shaped focus of the azimuthally symmetric lens. The measurements agree well with predictions obtained by full-wave simulations. These all-electronic alternatives are expected to prolong the lifetime of future spaceborne wind scatterometers. [ABSTRACT FROM AUTHOR]

Published

2022

21. Machine learning‐assisted direction‐of‐arrival accuracy enhancement technique using oversized lens‐loaded cavity.

Author

Abbasi, Muhammad Ali Babar, Yurduseven, Okan, Akinsolu, Mobayode O., Fusco, Vincent F., Liu, Bo, Khalily, Mohsen, Cotton, Simon L., and Imran, Muhammad Ali

Subjects

*STEPPING motors, *TELECOMMUNICATION systems, *MACHINE learning, *CHANNEL estimation, *LENSES, *ANTENNAS (Electronics)

Abstract

This paper presents a framework for achieving machine learning (ML)‐assisted direction‐of‐arrival (DoA) accuracy enhancement using a millimetre‐wave (mmWave) dynamic aperture. The technique used for the enhanced DoA estimation accuracy leverages an over‐sized lens‐loaded cavity antenna connected to a single RF chain in the physical layer and a computational method in the computational layer of the framework. It is shown for the first time that by introducing a reconfigurable mode‐mixing mechanism inside the over‐sized lens‐loaded cavity hardware, a greater number of spatially orthogonal radiation modes can be achieved giving rise to many cavity states. If the best cavity state is determined and selected by means of design exploration using a contemporary ML‐assisted antenna optimisation method, the computational DoA estimation accuracy can be improved. The mode‐mixing mechanism in this work is a randomly oriented metallic scatterer located inside an over‐sized constant−ϵr lens‐loaded cavity, connected to a stepper motor that is electronically controlled by inputs from the computational layer of the presented framework. Measurement results in terms of near‐field radiation mode scans are included in this study to verify and validate that the proposed ML‐assisted framework enhances the DoA estimation accuracy. Moreover, this investigation simultaneously provides a simplification in the physical layer implementation of mmWave radio hardware, and DoA accuracy enhancement, which in turn lends itself favourably to the adoption of the proposed framework for channel sounding in mmWave communication systems. [ABSTRACT FROM AUTHOR]

Published

2022

22. Integrative Transmitarray With Gain-Filtering and Low-Scattering Characteristics.

Author

Feng, Peng-Yu, Qu, Shi-Wei, Chan, Ka Fai, Yang, Shiwen, and Chan, Chi Hou

Subjects

*INTERFERENCE suppression, *3-D printers, *THREE-dimensional printing, *FREQUENCY selective surfaces, *RADAR cross sections, *REFLECTOR antennas, *TRANSMITTING antennas

Abstract

This article presents a design concept of integrative transmitarray antenna (TAA) with gain-filtering and low-scattering characteristics. The integrative TAA element combines a bandpass frequency-selective surface (FSS) element and a square dielectric post with antireflection pyramidal structures (SDPP), achieving the simultaneous control of in-band transmitted waves and out-of-band reflected waves. The FSS element provides the phase-shifting and gain-filtering capabilities around the center operating frequency $f_{0}$. Meanwhile, the SDPP elements with different heights are utilized to reduce the scattering cross section (SCS) based on the phase cancellation principle. To realize wideband and wide-angle SCS reductions, also to mitigate the in-band radiation degradation, the optimal SDPP arrangement is determined with subarray segmentation. In the experiment, a $42\times42$ -element integrative TAA is designed. Against only the FSS TAA, the simulated results show that loading the optimal SDPP array can realize the scattering reduction in a 10:1 bandwidth up to 60°, including $\sim 5/\sim 10$ dB SCS reductions in 0.5– $1.5~f_{0}$ /1.5– $5~f_{0}$ , respectively. Moreover, the integrative TAA achieves gain-filtering responses with out-of-band suppression levels higher than 20 dB. After fabricating the FSS TAA and the SDPP array by the technologies of standard PCB fabrication and 3-D printing, respectively, the proposed design is further demonstrated by experiments. [ABSTRACT FROM AUTHOR]

Published

2022

23. On the Near-Field Spherical Wave Formation in Resonant Leaky-Wave Antennas: Application to Small Lens Design.

Author

Bosma, Sjoerd, Neto, Andrea, and Llombart, Nuria

Subjects

*LEAKY-wave antennas, *SPHERICAL waves, *GREEN'S functions, *FOURIER transform optics, *ALGEBRAIC field theory

Abstract

In this work, we show that the near field of leaky-wave resonant antennas (LWAs) radiating into a dense medium can be locally represented as a spherical wave in a certain solid angle around broadside using an accurate definition of the phase center. The near field in this solid angle can be efficiently evaluated through the integration of the spectral Green’s function along the steepest descent path (SDP). Beyond this solid angle, defined as the shadow boundary angle, a residual contribution due to the leaky-wave pole must also be added to fully describe the near field. It is found that this shadow boundary angle can be used to define the phase center and geometry of a truncated lens that couples well to leaky-wave antennas, even in electrically small-to-medium sized lenses and low-contrast cases. To demonstrate the applicability of the proposed study, we combine the SDP field calculation with a Fourier optics (FO) methodology to evaluate the aperture efficiency and radiation patterns of small-to-medium sized lenses in reception. A truncated silicon lens with a diameter of only four free-space wavelengths is presented with almost 80% aperture efficiency. Excellent agreement with full-wave simulations is achieved, which demonstrates the accuracy of the proposed design and analysis methodology. [ABSTRACT FROM AUTHOR]

Published

2022

24. Shaped Parallel-Plate Lens for Mechanical Wide-Angle Beam Steering.

Author

Strober, Thomas, Tubau, Segolene, Girard, Etienne, Legay, Herve, Goussetis, George, and Ettorre, Mauro

Subjects

*BROADBAND antennas, *BEAM steering, *GEOMETRICAL optics, *TELECOMMUNICATION satellites, *OPTICAL waveguides, *SCANNING systems

Abstract

This article presents a parallel-plate lens beamformer for continuous wide-angle scanning. The design is based on a compact dual-lens system with extended scanning range and is optimized using a previously developed geometrical optics technique. Beam steering is accomplished with a mechanical feed system based on the noncontact characteristic of groove gap waveguides, offering large bandwidth, low profile, and mechanical ruggedness. The proposed concept is validated by an all-metal prototype of a $20.5\lambda $ lens operating in the uplink Ka-band allocated to satellite communications (27.5–31 GHz). Good agreement is obtained between the simulated and measured performances. The measured return loss is greater than 12 dB over the entire frequency band and beyond. High scanning performances are achieved over an angular range of ±50° (±14 beamwidths), with maximum scan losses in the order of 3 dB and good pattern stability over the entire band. The proposed solution is particularly suited for next-generation satellite terminals requiring compact broadband antennas with continuous beam-steering capability over a large angular range. [ABSTRACT FROM AUTHOR]

Published

2021

25. Dual-Polarized Filtering Transmitarray Antennas With Low-Scattering Characteristic.

Author

Feng, Peng-Yu, Qu, Shi-Wei, and Yang, Shiwen

Subjects

*ANTENNAS (Electronics), *FREQUENCY selective surfaces, *DIELECTRIC resonator antennas, *TRANSMITTING antennas

Abstract

A filtering transmitarray antenna (TAA) with high-gain in-band radiations at the $X$ -band and an out-of-band low-scattering characteristic is presented in this communication. The proposed composite TAA element consists of a dual-polarized resistive sheet, a fixed bandstop frequency-selective surface (FSS) element, and an adjustable bandpass FSS element also serving as a phase shifter. The resistive element is constructed by inserting a parallel inductor–capacitor (PLC) resonant structure into the center of a lumped-resistor-loaded metallic dipole. A transparent frequency-domain window at the center operating frequency ($f_{c}$) is created by the PLC resonance and is further shared by both FSS elements, hence allowing for high in-band transmission herein. At frequencies below or above $f_{c}$ , the whole composite TAA element acts as an absorber with the bandpass or bandstop FSS elements as the ground planes for the resistive sheet, respectively. The measured results show that the composite TAA can achieve gain-filtering responses with out-of-band suppression levels ≥25 dB, ~8 dB scattering cross section (SCS) reductions in 4–7 and 14–20 GHz, and the radiation gain of 25.3 dBi simultaneously. Because of these merits, the proposed design can relieve the stress on filtering circuit designs, also offering an attractive solution in stealth technology. [ABSTRACT FROM AUTHOR]

Published

2021

26. Multimaterial 3-D Printed Compressed Luneburg Lens for mm-Wave Beam Steering.

Author

Giddens, Henry, Andy, Andre Saker, and Hao, Yang

Abstract

Conformal, steerable lens antennas are of particular interest for millimeter-wave (mm-wave) antenna designers, as they enable low cost solutions for applications such as 5G mobile communications, radio-wave imaging, and satellite communications. Recent advances in additive manufacturing technology have opened up new possibilities for realizing graded-dielectric electromagnetic devices. In this letter, a compressed Luneburg lens fabricated from multimaterial 3-D printing is presented. Such a device has a steep dielectric gradient and cannot be easily realized using an effective medium approach that has become typical of 3-D printed graded-index devices. Instead, five different dielectric filaments were used to print the lens with a 100% filament fill-factor. The lens is excited by a WR-10 open-ended waveguide probe across the 75–110 GHz band, and achieves a bore sight gain of 22 dBi, and $-$ 3 dBi scan angle of 25 $^\circ$ at 84 GHz. [ABSTRACT FROM AUTHOR]

Published

2021

27. Metamaterial Lenses and Their Applications at Microwave Frequencies

Author

Wenxuan Tang, Jia Chen, and Tie Jun Cui

Subjects

lens antennas, metalenses, metamaterials, metasurfaces, microwaves, Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467

Abstract

Metamaterials (MTMs) are artificial structures characterized by flexible and designable electromagnetic (EM) properties, including permittivity, permeability, and refractive index. Because of their subwavelength‐scale composing units, MTMs are able to manipulate the propagation of EM waves at extremely fine resolutions and offer solutions for new‐concept devices and components with novel functionalities and challenge‐breaking properties. From among the attractive applications of MTMs, this review article focuses on MTM lenses (also termed metalenses) developed in recent years for the purpose of microwave engineering, including beam forming, beam steering, and imaging. Bulk lenses made of 3D MTMs and planar lenses made of 2D transmission‐type metasurfaces are both involved and investigated. Different categories of metalenses, together with the theory, principles, methods, and advantages of their designs, are introduced and discussed. Potential and future applications of metalenses at microwave frequencies are also presented.

Published

2021

28. A Multibeam Tapered Cylindrical Luneburg Lens.

Author

Mirmozafari, M., Tursunniyaz, M., Luyen, H., Booske, J. H., and Behdad, N.

Subjects

*COPLANAR waveguides, *ANTENNA feeds, *ANTENNA design, *ROAD vehicle radar, *REFLECTANCE, *REFRACTIVE index, *SURVEILLANCE radar

Abstract

We present a cylindrical, multibeam, modified Luneburg lens antenna. The proposed antenna features low-profile, good impedance match, high gain, and wide angle scanning capability. We tapered the thickness of a dielectric disk along its radius to achieve the required refractive index profile of the lens in a nondispersive fashion. Seventeen dielectric-filled waveguide feeds, arranged circumferentially around the focal arc of the lens, provide almost invariant azimuthal scanning in the range of ±60° from broadside direction. The lens and the interior of the waveguide feeds are made of the same dielectric material, offering a smooth impedance transition from the feed antenna to the lens. A prototype of the antenna was fabricated and characterized. Measured reflection coefficient is better than −10 dB from 14 to 16 GHz. The isolations between feeds remain higher than 24 dB over the entire operational frequency range. We measured a maximum antenna gain of 20.5 dB with only 1.5 dB gain loss near the maximum 60° scanning angle. The proposed high-gain, multibeam antenna design can be used in a wide range of applications including automotive and surveillance radars. [ABSTRACT FROM AUTHOR]

Published

2021

29. Broadband Small-Aperture High-Gain Ridge Horn Antenna Array Element.

Author

Marzall, Laila, Danielson, Paige, Lasser, Gregor, and Popovic, Zoya

Abstract

This letter presents the design and characterization of an octave-bandwidth, small-aperture, linearly polarized, high-gain horn antenna operating in the 6–12 GHz band for active arrays. The aperture size is limited by the waveguide feed cutoff at lower frequencies and by grating lobes at higher frequencies. The radiating structure is composed of an E-plane flared horn with an exponential double ridge fed by a low-loss waveguide-to-microstrip transition, eliminating the need for additional connections between the antenna elements and the beamforming and amplification circuits. The horn is loaded with an artificial dielectric with 1 < εr,eff <  2.2, which lowers the cutoff frequency and improves phase distribution over the aperture. The lens and feed loading structure are designed together to improve matching without degrading the radiation pattern. A prototype is fabricated in brass using split-block machining, and the lens is machined from 16 parallel dielectric slabs. The measured performance is in agreement with simulations. [ABSTRACT FROM AUTHOR]

Published

2021

30. Zoned near-zero refractive index fishnet lens antenna: Steering millimeter waves.

Author

Pacheco-Peña, V., Orazbayev, B., Beaskoetxea, U., Beruete, M., and Navarro-Cía, M.

Subjects

*LENS antennas, *REFRACTIVE index, *BEAM steering, *METAMATERIALS, *DIFFRACTIVE optical elements

Abstract

A zoned fishnet metamaterial lens is designed, fabricated, and experimentally demonstrated at millimeter wavelengths to work as a negative near-zero refractive index lens suitable for compact lens antenna configurations. At the design frequency f=56.7 GHz (λ0=5.29 mm), the zoned fishnet metamaterial lens, designed to have a focal length FL=9λ0, exhibits a refractive index n=–0.25. The focusing performance of the diffractive optical element is briefly compared with that of a non-zoned fishnet metamaterial lens and an isotropic homogeneous zoned lens made of a material with the same refractive index. Experimental and numerically-computed radiation diagrams of the fabricated zoned lens are presented and compared in detail with that of a simulated non-zoned lens. Simulation and experimental results are in good agreement, demonstrating an enhancement generated by the zoned lens of 10.7 dB, corresponding to a gain of 12.26 dB. Moreover, beam steering capability of the structure by shifting the feeder on the xz-plane is demonstrated. [ABSTRACT FROM AUTHOR]

Published

2014

31. BEYOND THE CLASSROOM WALLS: Place-Based Writing in K-12 Classrooms.

Author

BARNWELL, PAUL

Subjects

READING, ESSAYS, LENS antennas, PANDEMICS, STUDENTS

Abstract

The article focuses on, along with reading responses, short essays, and other standard writing assignments, many of our restless young students may view the act of writing particularly during pandemic times—through the lens of the constant demand for sedentary screen time. In a nutshell: writing may sometimes seem to students like a chore instead of an opportunity.

Published

2021

32. Coherent Fourier Optics Model for the Synthesis of Large Format Lens-Based Focal Plane Arrays.

Author

Dabironezare, Shahab Oddin, Carluccio, Giorgio, Freni, Angelo, Neto, Andrea, and Llombart, Nuria

Subjects

*FOCAL plane arrays sensors, *FOURIER transform optics, *GEOMETRICAL optics, *PHYSICAL optics, *RECEIVING antennas, *INTRAOCULAR lenses

Abstract

Future sub millimeter imagers are being developed with large focal plane arrays (FPAs) of lenses to increase the field of view (FoV) and the imaging speed. A full-wave electromagnetic analysis of such arrays is numerically cumbersome and time-consuming. This article presents a spectral technique based on Fourier optics combined with geometrical optics for analyzing, in reception, lens-based FPAs with wide FoVs. The technique provides a numerically efficient methodology to derive the plane wave spectrum (PWS) of a secondary quasi-optical component. This PWS is used to calculate the power received by an antenna or absorber placed at the focal region of a lens. The method is applied to maximize the scanning performance of imagers with monolithically integrated lens feeds without employing an optimization algorithm. The derived PWS can be directly used to define the lens and feed properties. The synthesized FPA achieved scan losses much lower than the ones predicted by standard formulas for horn-based FPAs. In particular, an FPA with scan loss below 1 dB while scanning up to ±17.5° (~±44 beam-widths) is presented with directivity of 52 dBi complying with the needs for future sub millimeter imagers. The technique is validated via a physical optics code with excellent agreement. [ABSTRACT FROM AUTHOR]

Published

2021

33. An Ultralow-Loss and Lightweight Cellulose-Coated Silica Foam for Planar Fresnel Zone Plate Lens Applications in Future 6G Devices

Author

Mikko Kokkonen, Petra S. Palvolgyi, Rafal Sliz, Heli Jantunen, Krisztian Kordas, and Sami Myllymaki

Subjects

porous substrates, lens antennas, low-loss dielectrics, 6G telecommunication, Electrical and Electronic Engineering, Fresnel zone plate (FZP), low-permittivity materials

Abstract

Several passive components of fifth-generation (5G) and future sixth-generation (6G) telecommunication devices require substrate materials of very low dielectric permittivity and losses to avoid wave absorption, reflection, and interference. Apart from their dielectric properties, these materials shall be also affordable and sufficiently robust to enable postprocessing and integration of functional electrical components. Herein, we demonstrate a Fresnel zone plate lens for operation at 300 GHz, whose structure is supported on substrate made of an ultraporous silica foam with a nanocellulose thin film coating. The effective dielectric permittivity and loss of the substrate ( ϵ r = 1.018 ± 0.003 and tan δ < 3 × 10 −4 at 300 GHz) is close to that of air. Experiments show that the fabricated Fresnel zone plate lens connected to a waveguide with total gain of 20 dB and angular beamwidth of 2.9° in good agreement with microwave simulations. The proposed lens structure has additional advantages such as small volume, ultralight weight, and simulations indicate 60 GHz bandwidth making it particularly appealing for radio front-ends of future 6G devices.

Published

2023

34. X‐band, mechanically‐beam‐steerable lens antenna exploiting the Risley prism concept.

Author

Zhang, Zongtang, Luyen, Hung, Booske, John H., and Behdad, Nader

Abstract

This study presents a beam‐steerable antenna system that uses two mechanically‐rotatable, phase‐shifting surfaces (PSSs) functioning like a pair of Risley prisms for beam scanning operation at X‐band. One of the PSSs also acts as a lens, performing beam collimation in addition to providing a phase shift gradient. Unit cells constituting the two PSSs were co‐designed to determine the distance between the two surfaces that results in high transmission coefficients and small phase errors under different beam‐scanning conditions. Both simulation and measurement results have verified that the distance of 2 mm provides the best performance regarding to peak gain. Prototypes of the PSSs having circular apertures with diameters of 11.5λ0 at 10 GHz were fabricated and illuminated by a feed antenna to characterise the beam scanning performance. The measurement results of the proposed antenna system demonstrate the capability to steer the main beam within a ±60° scanning range with a maximum gain variation of less than 3.6 dB by rotating the two PSSs with respect to each other. The fabricated prototype provides side lobe levels less than −13.1dB, polarisation purity higher than 20 dB, and small beam pointing errors of no more than 1° in all examined beam scan scenarios. [ABSTRACT FROM AUTHOR]

Published

2020

35. Dielectric lens with stacked cone-shaped cavity for broadside radiation enhancement of circularly polarised patch antenna.

Author

Liu, Hongmei, Mu, Chen, Yan, Tuanyuan, Fang, Shaojun, Wang, Guofeng, and Wang, Zhongbao

Subjects

*ANTENNAS (Electronics), *MICROSTRIP antenna arrays, *DIELECTRICS, *POLARIZATION of electromagnetic waves, *ELECTROMAGNETIC waves

Abstract

A dielectric lens is proposed here to broaden the half-power beamwidth (HPBW) of conventional circularly polarised (CP) patch antenna. The lens printed by the 3D technique is constructed by a dielectric cylinder with a stacked cone-shaped cavity. To illustrate the working principle, the energy distribution of the electromagnetic wave refracted by the lens is analysed. Besides, the design procedures of the lens are introduced in detail. The applicability of lens is also discussed including the changing of permittivity and dimensions. For verification, prototypes of the designed CP antenna with the lens are fabricated and measured. The performances of the CP antenna without lens are also provided for comparison. The measurements show that by using the proposed lens, the HPBW of the CP patch antenna is extended effectively from 69° to 170° while maintaining a wide 3-dB axial ratio beamwidth of >200°. [ABSTRACT FROM AUTHOR]

Published

2020

36. Cascaded Fresnel Lens Antenna for Scan Loss Mitigation in Millimeter-Wave Access Points.

Author

Hill, Timothy A., Kelly, James R., Khalily, Mohsen, and Brown, Tim W. C.

Subjects

*FRESNEL lenses, *PHASED array antennas, *ANTENNAS (Electronics), *TELECOMMUNICATION satellites, *BEAM steering

Abstract

Millimeter-wave lens antennas will be essential for future wireless access. Conventionally, they increase the gain in the boresight direction only. In this article, cascaded Fresnel zone plate lenses are combined with a phased array to increase the gain at wide steering angles of ±52°. The side lenses are tilted to align with the maximum steering angle and cascaded to increase the focusing gain. The inner lenses increase the gain by 2.45 dB at boresight, and by 3.19 dB at the maximum steering angle. When the side lenses are repositioned, the simulated focusing gain increases to 4.69 dB. Asymmetric amplitude distributions are proposed to prevent the main lobe from splitting. An eight-element seven-lens prototype operating at 28 GHz achieved a gain from 12.96 to 15.35 dBi with a bandwidth of at least 1.3 GHz for all measured beam directions. The maximum measured azimuthal beamwidth was 27°. A design procedure and a theoretical analysis of diffraction through the lenses are provided. By increasing the SNR, this beamforming antenna could improve the coverage of three-sector 5G microcell base stations, and support gigabit wireless links for vehicular, rail, and satellite communications. [ABSTRACT FROM AUTHOR]

Published

2020

37. Detection of metallic and nonmetallic concealed targets based on millimeter‐wave inverse scattering approach.

Author

Haraz, Osama M., Ashraf, Muhammad Ahmad, Sebak, Abdel‐Razik, and Alshebeili, Saleh A.

Subjects

*ANTENNA feeds, *HUMAN body, *ANTENNAS (Electronics), *WAVEGUIDE antennas, *DETECTORS

Abstract

A millimeter‐wave radar based on active invers scattering approach for two dimensional screening of metallic and nonmetallic concealed targets is presented. The perceived challenges of detecting a nonmetallic target exhibiting poor dynamic range for measurement systems are analyzed and discussed by comparing the performance of three different antenna sensors. A short time duration pulse with frequency sweep covering 27 to 33 GHz band is used to feed the antenna sensors. In our experimental test, we buried a concealed target consists of metallic or dielectric strips under a dielectric layer that simulates the human body model. Waveguide and printed antipodal Vivaldi antennas are considered to study the target detectability and the quality of the measured millimeter‐wave images. The use of proposed AVA resulted in a better‐quality image with lower noise effect for both metallic and nonmetallic cases. [ABSTRACT FROM AUTHOR]

Published

2020

38. OAM-Generating Transmitarray Antenna With Circular Phased Array Antenna Feed.

Author

Feng, Peng-Yu, Qu, Shi-Wei, and Yang, Shiwen

Subjects

*ANTENNA feeds, *PHASED array antennas, *TRANSMITTING antennas, *EXCITATION (Physiology), *ANGULAR momentum (Mechanics), *ANTENNAS (Electronics), *BEAM steering

Abstract

A transmitarray antenna (TAA) with a small-scale circular phased array antenna (PAA) feed is proposed in this article to generate orbital angular momentum (OAM)-carrying radio beams. After analyzing the operating mechanisms of the OAM-generating PAA-fed TAA, its numerical model is further developed to determine the TAA element arrangement and the PAA feed excitation coefficients. Furthermore, a three-layer element with polarization-conversion property and the traditional patch antenna element are identified as the elements of the TAA and PAA feed, respectively. Benefiting from the intrinsic multibeam capabilities of the TAA, the steering of the zero-OAM-mode beam is firstly discussed, where a conical scanning across an angular range of ±25° is realized. Meanwhile, the creation of multiple pure or mixed OAM beams with helical phase fronts is also presented, where the superposition of multiple OAM states provides more possibilities to increase the channel capacity and spectrum efficiency. To facilitate the experiments, an $8\times 8$ Butler matrix with a bandwidth over 30% is designed, which integrated with the array-fed TAA also provides an attractive solution to simultaneously generate multiple OAM modes without requiring any active modules. The experimental results agree reasonably well with the numerical ones, validating the feasibility of our idea to design a high-gain OAM-generating PAA-fed TAA. [ABSTRACT FROM AUTHOR]

Published

2020

39. Ultrawideband Low-Profile Transmitarray With Vivaldi Array Feed.

Author

Feng, Peng-Yu, Qu, Shi-Wei, and Yang, Shiwen

Subjects

*PHASED array antennas, *EXCITATION (Physiology), *COST functions, *FEED additives, *ANTENNA arrays, *ANIMAL feeds, *ULTRA-wideband antennas

Abstract

A transmitarray antenna (TAA) with a small-scale phased array antenna (PAA) feed is proposed in this communication. After modeling the PAA-fed TAAs and constructing the cost functions, a three-step optimization process is introduced to determine the TAA element arrangement as well as the PAA feed excitation coefficients. Then, a novel ultrawideband TAA element is proposed, which has a pair of connected sheep-horn metallic patterns in the middle layer sandwiched by two metallic orthogonal grid polarizers on the upper and bottom layers. Furthermore, traditional Vivaldi antenna element is identified as the element of a $4 \times 8$ -element PAA feed array (central $4\times 4$ active elements), which is employed to illuminate a $25\times 25$ -element circular TAA with a focus-to-diameter ($F/D)$ ratio of mere 0.43. The simulated results show that stable radiation patterns with good main beam shapes and reasonable sidelobe levels are obtained in the interested frequency band. The measured results agree reasonably well with the simulated ones, validating the feasibility of our method to design an ultrawideband low-profile PAA-fed TAA. [ABSTRACT FROM AUTHOR]

Published

2020

40. On the Use of Fly’s Eye Lenses with Leaky-Wave Feeds for Wideband Communications.

Author

Arias Campo, Marta, Blanco, Darwin, Bruni, Simona, Neto, Andrea, and Llombart, Nuria

Subjects

*LEAKY-wave antennas, *FLIES, *EYE, *ANTENNAS (Electronics), *FEED additives, *ANIMAL feeds, *APERTURE antennas

Abstract

In order to fulfill the exponential increase in the demand of high-speed wireless links, future XG wireless networks will be developed at higher carrier signal frequencies, reaching the hundreds of gigahertz. In this contribution, a leaky-wave-fed HDPE lens antenna working at ${G}$ -band which can be useful for future XG communications is presented. The proposed lens design enables the generation of up to 40 beams, with gains higher than 30 dB. Analytical tools have been applied to optimize the lens aperture efficiency, validating the results via full-wave simulations. The reached aperture efficiency for the broadside beam is higher than 80% over a 44% relative bandwidth. The measurement results for a fabricated prototype show excellent agreement with the simulated performance. [ABSTRACT FROM AUTHOR]

Published

2020

41. A Novel Collapsible Flat-Layered Metamaterial Gradient-Refractive-Index Lens Antenna.

Author

Papathanasopoulos, Anastasios, Rahmat-Samii, Yahya, Garcia, Nicolas C., and Chisum, Jonathan D.

Subjects

*ANTENNAS (Electronics), *UNIT cell, *BROADBAND antennas, *ANTENNA feeds, *FABRICATION (Manufacturing)

Abstract

With the advent of small-scale satellite technologies, there has been significant interest in developing low-profile antennas. This article presents a novel collapsible flat-layered lens based on gradient-refractive-index (GRIN) metamaterials. The 3-D lens consists of multilayer double-sided microstrip square-rings units of variable sizes distributed on planar dielectric substrates to satisfy the required refractive index distribution. Adjacent layers can be stored compressed in a stacked configuration with minimal height, then deployed to an operational arrangement to their full dimensions and capabilities. The key factor in this design is the judicious choice of the discretized metamaterial unit cell such that neighboring layers are separated by an air gap, which allows the lens to collapse. A proof-of-concept prototype operating at 13.4 GHz with a 11.2 cm diameter and a height of 0.4 and 2.1 cm in collapsed and operational arrangement, respectively, was manufactured within fabrication tolerances. A resonant patch array feed was used and the lens antenna was measured in the UCLA Plane Bi-Polar Near-Field measurement range achieving a 23 dBi directivity and 22.2 dBi gain. The numerical and experimental results agree well and demonstrate that this new lens is advantageous in terms of low packaging height without compromising high-performance. [ABSTRACT FROM AUTHOR]

Published

2020

42. Antennas in Automobile Radar

Author

Menzel, Wolfgang, Chen, Zhi Ning, editor, Liu, Duixian, editor, Nakano, Hisamatsu, editor, Qing, Xianming, editor, and Zwick, Thomas, editor

Published

2016

43. Dielectric Lens Antennas

Author

Fernandes, Carlos A., Lima, Eduardo B., Costa, Jorge R., Chen, Zhi Ning, editor, Liu, Duixian, editor, Nakano, Hisamatsu, editor, Qing, Xianming, editor, and Zwick, Thomas, editor

Published

2016

44. Frequency Selective Surfaces

Author

Wang, De Song, Qu, Shi-Wei, Chan, Chi Hou, Chen, Zhi Ning, editor, Liu, Duixian, editor, Nakano, Hisamatsu, editor, Qing, Xianming, editor, and Zwick, Thomas, editor

Published

2016

45. Three-dimensional broadband and high-directivity lens antenna made of metamaterials.

Author

Chen, Xi, Feng Ma, Hui, Ying Zou, Xia, Xiang Jiang, Wei, and Jun Cui, Tie

Subjects

*METAMATERIALS, *COMPOSITE materials research, *ELECTROMAGNETISM, *OPTICS, *LENS antennas

Abstract

We present the theoretical modeling and prototype demonstration of a three-dimensional broadband, low-loss, dual-polarization, and high-directivity lens antenna using gradient index (GRIN) metamaterials, which is composed of multi-layer microstrip square-ring arrays. The elements of metamaterials, closed square-ring units of variable sizes, are distributed on the planar substrate to satisfy the radial gradient index function and the axial impedance matching layer configuration of the lens. The gradient-index metamaterials are designed to transform the spherical wave-front into the planar wave-front and to minimize the reflection loss. A prototype lens antenna, which consists of a metal conical horn and the gradient-index lens, are simulated, constructed, and measured. The resemblance of simulation and measurement results shows that the prototype lens antenna maintains low return loss and high directivity on the whole X-band (from 8 GHz to 12 GHz). Compared to the traditional horn antenna, the metamaterial GRIN lens antenna has much superior performance-for instance, the gain increases by 6 dBi at 12 GHz. These results demonstrate the feasibility of such a light weight slab metamaterial lens for broadband and high-directivity antenna applications, such as in radar and communication systems. We have used the lens antennas in the measurements of a three-dimensional invisibility cloak due to the high directivity. [ABSTRACT FROM AUTHOR]

Published

2011

46. Dual-polarized Geodesic Lens Antenna at sub-THz

Author

Chen, Qiao, Fu, Wenfu, Zhao, Kun, Quevedo-Teruel, Oscar, Chen, Qiao, Fu, Wenfu, Zhao, Kun, and Quevedo-Teruel, Oscar

Abstract

We present a dual-polarized lens antenna for point-to-multipoint communications at sub-THz. The lens is constructed by a doubly-curved parallel plate following a geodesic lens shape equivalent to the Luneburg index profile. The polarization is changed by metallic screens patterned with complementary split resonant rings (CSRRs). These screens are integrated in the radiation aperture of the lens. Two lenses are stacked up, one for each polarization. Each lens is fed by 11 waveguide ports, providing beam steering or multiple beams. The antenna is fully metallic and hence, highly efficient. In the operating band from 115 GHz to 125 GHz, the simulation shows a realized gain of 20 dBi with a maximum scan loss of 0.6 dB up to 60 degrees, a cross-polarization discrimination around 20 dB, and an insertion loss smaller than 1.5 dB., Part of ISBN 978-88-31299-07-7QC 20230911

Published

2023

47. A General Solution for Double-Layer Gradient-Index and Geodesic Lenses with Rotational Symmetry

Author

Chen, Qiao, Horsley, Simon A. R., Fonseca, Nelson J. G., Tyc, Tomas, Quevedo-Teruel, Oscar, Chen, Qiao, Horsley, Simon A. R., Fonseca, Nelson J. G., Tyc, Tomas, and Quevedo-Teruel, Oscar

Abstract

A double-layer lens consists of a pair of rotationally symmetric index profiles or geodesic lens shapes connected by a reflecting mirror partially covering their common periphery. Such a lens can provide a focus in each layer, and a wave travelling between the foci explores both layers. Here, we concentrate on the case with one layer being homogeneous or flat, and derive a general solution for the lens profiles by solving a Luneburg-like inverse problem with pre-specified foci inside or outside the lens, and different background indices in two layers. We demonstrate four examples of interest in ray-tracing plots. These lenses may find application in communications, sensing, and imaging from millimeter waves up to the optical bands., Part of ISBN 978-88-31299-07-7QC 20230911

Published

2023

48. Ray-Tracing Model for Generalized Geodesic-Lens Multiple-Beam Antennas

Author

Liao, Qingbi, Fonseca, Nelson J. G., Camacho, Miguel, Palomares-Caballero, Angel, Mesa, Francisco, Quevedo-Teruel, Oscar, Liao, Qingbi, Fonseca, Nelson J. G., Camacho, Miguel, Palomares-Caballero, Angel, Mesa, Francisco, and Quevedo-Teruel, Oscar

Abstract

Geodesic lenses are a compelling alternative to traditional planar dielectric lens antennas, as they are low loss and can be manufactured with a simple mechanical design. However, a general approach for the design and analysis of more advanced geodesic-lens antennas has been elusive, limiting the available tools to rotationally symmetric surfaces. In this article, we present a fast and efficient implementation built on geometrical optics and scalar diffraction theory. A numerical calculation of the shortest ray path (geodesic) using an open-source library helps quantify the phase of the electric field in the lens aperture, while the amplitude is evaluated by applying ray-tube power conservation theory. The Kirchhoff-Fresnel diffraction formula is then employed to compute the far field of the lens antenna. This approach is validated by comparing the radiation patterns of a transversely compressed geodesic Luneburg lens (elliptical base instead of circular) with the ones computed using commercial full-wave simulators, demonstrating a substantial reduction in computational resources. The proposed method is then used in combination with an optimization procedure to study possible compact alternatives of the geodesic Luneburg lens with size reduction in both the transverse and vertical directions., QC 20230508

Published

2023

49. Ray-Tracing Model for Generalized Geodesic-Lens Multiple-Beam Antennas

Author

Universidad de Sevilla. Departamento de Electrónica y Electromagnetismo, Universidad de Sevilla. Departamento de Física Aplicada I, Ministerio de Ciencia e Innovación (MICIN). España, Office of Naval Research (ONR). United States, Liao, Qingbi, Fonseca, Nelson J. G., Camacho Aguilar, Miguel, Palomares Caballero, Ángel, Mesa Ledesma, Francisco Luis, QuevedoTeruel, Óscar, Universidad de Sevilla. Departamento de Electrónica y Electromagnetismo, Universidad de Sevilla. Departamento de Física Aplicada I, Ministerio de Ciencia e Innovación (MICIN). España, Office of Naval Research (ONR). United States, Liao, Qingbi, Fonseca, Nelson J. G., Camacho Aguilar, Miguel, Palomares Caballero, Ángel, Mesa Ledesma, Francisco Luis, and QuevedoTeruel, Óscar

Abstract

Geodesic-lenses are a compelling alternative to traditional planar dielectric lens antennas, as they are low loss and can be manufactured with a simple mechanical design. However, a general approach for the design and analysis of more advanced geodesic-lens antennas has been elusive, limiting the available tools to rotationally symmetric surfaces. In this article, we present a fast and efficient implementation built on geometrical optics and scalar diffraction theory. A numerical calculation of the shortest ray path (geodesic) using an open-source library helps quantify the phase of the electric field in the lens aperture, while the amplitude is evaluated by applying ray-tube power conservation theory. The Kirchhoff-Fresnel diffraction formula is then employed to compute the far field of the lens antenna. This approach is validated by comparing the radiation patterns of a transversely compressed geodesic Luneburg lens (elliptical base instead of circular) with the ones computed using commercial full-wave simulators, demonstrating a substantial reduction in computational resources. The proposed method is then used in combination with an optimization procedure to study possible compact alternatives of the geodesic Luneburg lens with size reduction in both the transverse and vertical directions.

Published

2023

50. Scanning Lens Phased Array Antennas: Analysis, design and demonstrations at millimeter and submillimeter wavelengths using leaky-wave feeds

Author

Bosma, S. (author) and Bosma, S. (author)

Abstract

Millimeter- and submillimeter wave applications, such as point-to-point wireless communications in beyond-5G scenarios, long-range automotive radars and astronomy and astrophysics science cases from space require antennas with high-gain beams that are steerable. At lower (microwave) frequencies, fully sampled phased arrays with thousands of elements have been demonstrated for this purpose. However, above roughly 100 GHz, integrated-circuit technology faces major bottlenecks in terms of size, power efficiency, thermal management and technological immaturity. Consequently, only integrated phased arrays with very few elements have been reported in the literature above 100 GHz. To still achieve the gain and enable beam scanning, mechanically actuated reflectors are now typically employed. However, such solutions are bulky, power-hungry and do not allow rapid beam steering. To overcome these limitations, we propose, analyze, design, fabricate and demonstrate a new antenna architecture in this thesis: the scanning lens phased array. The scanning lens phased array is a compact, low-power and very sparse array of integrated lens antennas that we demonstrate with scanning capabilities up to 25 degrees around broadside. A hybrid electro-mechanical approach to beam steering is employed: the array factor is scanned electronically and the element patterns are steered mechanically. The grating lobes that arise in the array factor due to the array’s sparsity are suppressed by the high directivity of the lens elements. This results in a clean, highgain beam towards the desired scan angle..., Tera-Hertz Sensing

Published

2023