Optimisation and implementation for a non‐focal Rotman lens design

Rajabalian, Mojtaba; Zakeri, Bijan

doi:10.1049/iet-map.2014.0797

Cited by 23 publications

(12 citation statements)

References 25 publications

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“…Many researchers contributed to reduce the produced phase error in the lens. 28,31,32 Good coupling energy between the beam and receive ports with amplitude rate varying below −10 dB are indicated in Figure 8B. However, an oscillation that can be observed within the level range (−11.5 to −16.5 dB) may be due to inside reflections within the lens junction.…”

Section: Comprehensive Lens Modelmentioning

confidence: 94%

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A new impedance matching approach for microstrip Rotman lens based on analyzing the standing wave pattern of an electric field

Al-Obaidi

Abdullah

Dahlan

et al. 2019

Micro & Optical Tech Letters

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This article proposes a new impedance matching method to provide an energy transformer between 50 Ω beam ports and the cavity of a Rotman lens. The model is derived from a quarter length transition line impedance transformer. The suggested matching technique is based on determining and analyzing standing wave patterns of electric field signals underneath feeding lines of the beam ports when they are excited with a designed frequency of 2.45 GHz. The proposed approach demonstrates the ability of the model to achieve an acceptable return loss compared to traditional taper line model matching methods, even though it increases the operating bandwidth frequency based on the measured results. Moreover, it solves the optimization iteration time consuming that is required to determine the tapering line length used in the conventional impedance matching techniques. The predicted results of the return loss are validated by measurements of the fabricated prototype microstrip lens printed on an FR‐4 substrate that is designed to work in the industrial, scientific, and medical (ISM) band in order to form five beams in the directions −26°, −13°, 0°, 13°, and 26°.

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Section: Comprehensive Lens Modelmentioning

confidence: 94%

“…On the other hand, a discontinuity in the linearity can be observed due to a phase error. Many researchers contributed to reduce the produced phase error in the lens . Good coupling energy between the beam and receive ports with amplitude rate varying below −10 dB are indicated in Figure B.…”

Section: Rotman Lens Designmentioning

confidence: 99%

A new impedance matching approach for microstrip Rotman lens based on analyzing the standing wave pattern of an electric field

Al-Obaidi

Abdullah

Dahlan

et al. 2019

Micro & Optical Tech Letters

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“…The MTLs, with the effective dielectric constant of ε e , are routed with the appropriate curvature in order to guarantee the separation and non-overlapping required for the array contour, and also to maintain the same electrical length among all the output meandered MTLs. In the generalised RL model, it is assumed that the focal angle α is equal to the scan angle θ, and although the angles can be different, by applying which, it can be used for the potential computations and optimisations regarding the compactness of the beam region and phase error reductions [35]. The following equations govern the design of the trifocal RL based on the GO, in order to maintain the performance of the device, in terms of generating multiple beams with a linear progressive phase shift across the array ports (i.e., due to the different electrical lengths between a specific beam port and all output ports), as well as preventing the array from changing the scanning direction with frequency variation, i.e., the high-performance wideband true-time-delay (TTD) operation of the microwave/mmwave lens.…”

Section: Theoretical Design and Analysismentioning

confidence: 99%

Design and Performance Analysis of Millimetre-Wave Rotman Lens-Based Array Beamforming Networks for Large-Scale Antenna Subsystems

Rahimian¹,

Alfadhl²,

Alomainy³

2017

PIER C

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Abstract-This paper presents the comprehensive analytical design and numerical performance evaluation of novel millimetre-wave (mm-wave) switched-beam networks, based on the Rotman lens (RL) array feeding concept. These passive array devices have been designed for operation in the 28-GHz frequency band, covering the whole 18-38 GHz frequency range. The primary objective of the work is to conduct a thorough feasibility study of designing wideband mm-wave beamformers based on liquid-crystal polymer (LCP) substrates, to be potentially employed as low-cost and high-performance subsystems for the advanced transceiver units and large-scale antennas. The presented RLs exhibit significant output behaviours for electronic beam steering, in terms of the scattering (S) parameters, phase characteristics, and surface current distributions, as the feeding systems' primary functionality indicators.

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“…The inputs include the desired scan angle of the array, the operating frequency, the number of beams and array ports, and the array element spacing. The geometry optimisation, phase error and coupling analysis are also considered while designing the device, as thoroughly discussed in [23][24][25][26]. For the sake of brevity, the design equations are not provided.…”

Section: Analytical Modelling and Evaluationmentioning

confidence: 99%

Analytical and Numerical Evaluations of Flexible v-Band Rotman Lens Beamforming Network Performance for Conformal Wireless Subsystems

Rahimian¹,

Alfadhl²,

Alomainy³

2016

PIER B

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This paper presents the analytical design and numerical performance evaluation of novel V-band millimetre-wave (mm-wave) beamforming networks (BFNs), based on the Rotman lens array feeding concept. The devices are intended for operation in the unlicensed 60-GHz frequency band. The primary objective of this work is to study the feasibility of designing flexible V-band beamformers, based on liquid-crystal polymer (LCP) substrates. The planar Rotman lens device has been initially developed, and the output performances, in terms of the scattering parameters and accuracy, have been analysed. This is further continued with the detailed designs of the Rotman lens BFNs based on the four different proposed flexural cases, namely the concave-axial bending, the convex-axial bending, the concave-circumferential bending, and the convex-circumferential bending. Each of the flexures has been analysed, and the performance in terms of the surface currents and phase distributions, as the primary functionality indicators, has been presented. The presented flexible beamformers exhibit significant characteristics to be potentially employed as low-cost and efficient units of the mm-wave transceivers with the in-built electronic beam steering capabilities for the conformal wireless subsystems.

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Optimisation and implementation for a non‐focal Rotman lens design

Cited by 23 publications

References 25 publications

A new impedance matching approach for microstrip Rotman lens based on analyzing the standing wave pattern of an electric field

A new impedance matching approach for microstrip Rotman lens based on analyzing the standing wave pattern of an electric field

Design and Performance Analysis of Millimetre-Wave Rotman Lens-Based Array Beamforming Networks for Large-Scale Antenna Subsystems

Analytical and Numerical Evaluations of Flexible v-Band Rotman Lens Beamforming Network Performance for Conformal Wireless Subsystems

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