Your search keyword '"Angel Palomares-Caballero"' showing total 6 results

1. Holey SIW Horn Antenna Based on an H-Plane Lenswise Wavefront Collimation

Author

Andres Biedma-Perez, Pablo Padilla, Cleofas Segura-Gomez, and Angel Palomares-Caballero

Subjects

Electrical and Electronic Engineering

Published

2023

2. Millimeter-Wave 3-D-Printed Antenna Array Based on Gap-Waveguide Technology and Split E-Plane Waveguide

Author

Antonio Alex-Amor, Angel Palomares-Caballero, Juan F. Valenzuela-Valdes, and Pablo Padilla

Subjects

Waveguide (electromagnetism), Materials science, business.industry, Aperture, Antenna aperture, Astrophysics::Instrumentation and Methods for Astrophysics, 020206 networking & telecommunications, 02 engineering and technology, Antenna efficiency, Antenna array, Optics, Extremely high frequency, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Antenna (radio), Reflection coefficient, business

Abstract

A multilayer aperture antenna array in millimeter-wave band is presented in this article. The antenna array is based on glide-symmetric holey gap-waveguide technology combined with E-plane insertion gaps for a low-cost and low-loss design. The radiating part of the antenna array is formed by an array of sixteen aperture antennas, grouped in four sets of 2x2 antenna subarrays in E-plane configuration. The 2x2 subarrays are fed by a one-to-four corporate feeding network in E-plane with holey gap-waveguide technology. The antenna array has been manufactured with high precision stereolithography (SLA) and subsequent metal plating. This design procedure yields a low-cost and low-weight manufacturing process for functional prototypes. The complete array has been manufactured and measured, comparing its performance with the simulation results. Measurements show an input reflection coefficient below -10 dB which ranges from 68 GHz to 74 GHz. The measured radiation patterns suit adequately the defined ones in the design stage. Moreover, gain above 19 dBi in the entire operating frequency band is achieved with a 74.1% mean antenna efficiency.

Published

2021

3. Glide-Symmetric Holey Leaky-Wave Antenna With Low Dispersion for 60 GHz Point-to-Point Communications

Author

Elena Pucci, Oscar Quevedo-Teruel, Qiao Chen, Oskar Zetterstrom, Angel Palomares-Caballero, and Pablo Padilla

Subjects

Physics, Waveguide (electromagnetism), Aperture, business.industry, Leaky wave antenna, Metamaterial, 020206 networking & telecommunications, 02 engineering and technology, Optics, Dispersion (optics), 0202 electrical engineering, electronic engineering, information engineering, Prism, Electrical and Electronic Engineering, Propagation constant, business, Beam (structure)

Abstract

In this article, two novel efficient leaky-wave antennas (LWAs) with stable radiation patterns operating in the 60 GHz band are proposed. The LWAs are implemented in groove-gap waveguide (GGW) technology. To mitigate the beam squint due to the dispersive nature of LWAs, complementary-dispersive prisms are coupled to the LWA radiation aperture. The antennas are implemented in fully metallic purely holey periodic structures, resulting in a more cost-effective and robust manufacturing process compared to previously reported pin-based structures. Two prisms are proposed, one with mirror symmetry and one with glide symmetry. When the prism possesses a glide symmetry, much fewer holes are required while maintaining a similar performance, which even further decreases the fabrication costs. The complex propagation constant is optimized for low sidelobe levels (SLLs) with tailored hole diameters and waveguide dimensions, thus for the first time demonstrating the capability of using glide-symmetric holes to control the leakage rate. Two prototypes with mirror- and glide-symmetric prisms are theoretically synthesized and validated by the simulated and experimental results. A frequency bandwidth of 11% is achieved for both prototypes with the beam squint within ±0.9° (mirror) and ±1.7° (glide), SLLs below −15 dB (mirror) and −13 dB (glide), total efficiency almost 90%, and realized gain of 17 ± 0.5 dB at a fixed observing angle. The developed antennas are intended for mm-wave point-to-point communications.

Published

2020

4. Multilayer Network Optimization for 5G & 6G

Author

Pablo H. Zapata-Cano, Angel Palomares-Caballero, Javier Carmona-Murillo, Juan F. Valenzuela-Valdes, Francisco Luna-Valero, and Alejandro Ramirez-Arroyo

Subjects

General Computer Science, Computer science, business.industry, Distributed computing, General Engineering, 020206 networking & telecommunications, 020302 automobile design & engineering, 02 engineering and technology, Energy consumption, Telecommunications network, Base station, 0203 mechanical engineering, 0202 electrical engineering, electronic engineering, information engineering, Cellular network, General Materials Science, Network performance, Mobile telephony, business, Heterogeneous network, Efficient energy use

Abstract

Mobile communications are growing and the number of users is constantly increasing at an accelerated rate, as well as the demand for the services they request. In the last few years, many efforts have focused on the design and deployment of the new fifth generation (5G) cellular networks. However, novel highly demanding applications, which are already emerging, need to go beyond 5G in order to meet the requirements in terms of network performance. But, at the same time, as the Earth does not allow us to increase the carbon footprint anymore, the energy consumption of the communication networks has to be critically taken into consideration. A multi-objective approach for addressing all these issues is therefore required. This work develops a cellular network framework that allows the evaluation of different system parameters over dynamic traffic patterns, as well as optimizing the different conflicting objectives simultaneously. The novelty relies on that the optimization process integrates key performance indicators from different layers of the network, namely the radio and the network layers, aiming at reaching solutions that account for the power consumption of the base stations, the total capacity provided to mobile users and also the signaling cost generated by handovers. Moreover, new metrics are needed to evaluate different solutions. Starting from the well-known energy efficiency merit factor (bits/Joule), three new merit factors are proposed to classify the network performance since they take into account several network parameters at the same time. These indicators show us the ideal working point that can be used to plan the point of operation of the network. These operation points are a medium-high power and capacity load and a low signaling load.

Published

2020

5. A 1-to-8 Fully Modular Stacked SIW Antenna Array for Millimeter-Wave Applications

Author

Cleofas Segura-Gomez, Angel Palomares-Caballero, and Pablo Padilla

Subjects

Millimeter waves, Modularity, Electrical and Electronic Engineering, Antenna array, SIW

Abstract

This paper presents a vertically stacked SIW antenna array that enables different array configurations with the minimum number of SIW layers. This achievement lies in the modular feature offered by the proposed design. Specifically, 4 distinct array configurations can be produced with only 3 different design of SIW layers. Depending on the number of SIW layers employed in the stacked antenna, the directivity in the E-plane is modified. To obtain an equal and in-phase power distribution among the array elements, H- and E-plane corporate feeding networks are efficiently implemented in each array configuration. Array configurations of 1, 2, 4 and 8 radiating layers are offered by the proposed modular array, where each radiating layer is formed by 8 H-plane horn antennas. The simulated directivity for the array configurations ranges from 15.8 dBi to 23.8 dBi and the main beam direction remains fixed along the operating frequency range. The array design has been manufactured and agreement between simulated and measured results are observed. The measured impedance bandwidth in all the array configurations is from 35 GHz to 41 GHz (15.79% bandwidth) with a reduction in the E-plane beamwidth as the number of radiating layers increases., Spanish Government, European Commission PID2020-112545RB-C54 Junta de Andalucia B-TIC-402-UGR18 A-TIC-608-UGR20 P18.RT.4830 PYC20-RE-012-UGR FPU20/00256 FPU18/01965

Published

2022

6. Metamaterial-Based Reconfigurable Intelligent Surface: 3-D Meta-Atoms Controlled by Graphene Structures

Author

Carlos Molero, Angel Palomares-Caballero, Juan F. Valenzuela-Valdes, Antonio Alex-Amor, Francisco Gamiz, Pablo Padilla, and Ignacio Parellada-Serrano

Subjects

Computer Networks and Communications, business.industry, Computer science, Metamaterial, Reconfigurability, Polarization (waves), Radio spectrum, Computer Science Applications, Splitter, Electronic engineering, Wireless, Ray tracing (graphics), Electrical and Electronic Engineering, business, Voltage

Abstract

The upcoming high-speed wireless communication systems will be hosted by millimeter and sub-millimeter-wave frequency bands. At these frequencies, electromagnetic waves suffer from severe propagation losses and non-line-of-sight (NLOS) scenarios. A new wireless communication paradigm has arrived to resolve this situation through the use of reconfigurable intelligent surfaces (RIS). These metadevices are designed to reconfigure the wireless environment in a smart way. Traditional RIS designs based on the implementation of 2-D configurations have been considered up to now. However, 3-D structures enable an extra degree of freedom in the design that can be taken as an advantage for the development of improved RIS structures with advanced functionalities. This article proposes the implementation of a novel electronically-reconfigurable RIS based on the use of 3-D graphene meta-atoms. The reconfigurability lies on the graphene conductivity, easily tunable with a biasing voltage. Different conductivity values vary the meta-atom electromagnetic response, modifying the RIS functionality. A multi-objective optimization framework determines the optimal phase state of each meta-atom to accomplish the desired RIS performance. The operation of the RIS as an efficient beam steerer/splitter, absorber and polarization selector is validated with full-wave results.

Published

2021