Machine Learning and Optimization Techniques in Antenna Design

A special issue of Electronics (ISSN 2079-9292). This special issue belongs to the section "Artificial Intelligence".

Deadline for manuscript submissions: 15 May 2025 | Viewed by 127

Special Issue Editor


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Guest Editor
Group of Electromagnetics, Department of Electrical Engineering, Eindhoven University of Technology, Eindhoven, The Netherlands
Interests: full-wave analysis and design of passive devices and antennas for satellite, wireless, and radar applications; development of analytically based numerical techniques devoted to the modeling of wave propagation and diffraction processes; theory of special functions for electromagnetics; deterministic synthesis of sparse antenna arrays; solution of boundary value problems for partial differential equations of mathematical physics
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Special Issue Information

Dear Colleagues,

In recent years, antenna design has seen significant advancements driven by the increasing demands of modern wireless communication systems, such as 5G, IoT, satellite communications, and radar systems. Traditional antenna design methodologies, relying heavily on numerical simulations, parametric sweeps, and manual optimization, often fail to deliver optimal solutions in the face of growing complexity. The advent of machine learning (ML) and optimization techniques presents a transformative approach to addressing the challenges in antenna design, offering novel ways to enhance performance, automate the design process, and reduce development time.

This Special Issue focuses on the intersection of machine learning and optimization techniques in antenna design. The integration of these technologies allows for the more efficient exploration of vast design spaces, automating tasks such as parameter tuning, topology selection, and performance prediction. ML models, such as deep neural networks (DNNs), support vector machines (SVMs), and Gaussian process regression (GPR), can be trained on simulation or measurement data to predict antenna performance metrics like gain, bandwidth, directivity, and radiation patterns, significantly speeding up the design cycle.

Moreover, optimization algorithms such as genetic algorithms (GAs), particle swarm optimization (PSO), and differential evolution (DE) can be combined with machine learning to identify globally optimal antenna designs. These hybrid approaches are particularly effective in solving multi-objective optimization problems where trade-offs between conflicting objectives, such as size, efficiency, and bandwidth, must be carefully balanced.

This Special Issue invites contributions that cover various aspects of the application of machine learning and optimization techniques in antenna design, including but not limited to the following:

  1. ML-Based Antenna Design Automation: Contributions that demonstrate the application of machine learning models to automate the design process, including design space exploration, parameter optimization, and topology selection. This may include the use of reinforcement learning (RL) for adaptive design systems and unsupervised learning techniques for clustering and dimensionality reduction in antenna feature spaces.
  2. Predictive Models for Antenna Performance: Research that applies ML techniques like convolutional neural networks (CNNs) or random forests to predict the electromagnetic behavior of antennas based on geometric and material properties. These models aim to reduce the reliance on time-consuming full-wave electromagnetic simulations by providing near-instantaneous performance predictions.
  3. Optimization-Driven Antenna Synthesis: Studies focusing on the use of advanced optimization techniques to enhance the design of antennas. Metaheuristic algorithms such as simulated annealing (SA) and evolutionary algorithms are of particular interest for solving complex, nonlinear optimization problems in the design of multi-band, reconfigurable, and MIMO antennas.
  4. ML for Inverse Antenna Design: Contributions that explore the use of inverse design methods, where machine learning models are employed to generate antenna geometries that meet specific target performance requirements. This could include generative adversarial networks (GANs) or variational autoencoders (VAEs) to propose novel antenna structures.
  5. Applications in Emerging Technologies: Papers that highlight how machine learning and optimization techniques are applied in the design of antennas for cutting-edge applications such as massive MIMO, mmWave communication, metamaterial antennas, and phased arrays.
  6. Challenges and Future Directions: This Special Issue also welcomes discussions on the current challenges in applying machine learning to antenna design, such as data scarcity, model interpretability, and computational resource constraints, as well as promising directions for future research.

By combining the power of machine learning and optimization, this Special Issue aims to provide antenna designers with new tools and techniques that will streamline the design process, improve performance, and enable the creation of antennas that are more efficient, compact, and adaptable to the evolving needs of communication systems.

Focus:

The Special Issue will focus on the application of ML and optimization techniques to revolutionize the field of antenna design. It aims to address the increasing complexity of modern antenna systems by leveraging ML algorithms to automate and accelerate design processes and employing optimization techniques to enhance performance. Specific areas of focus include automated design workflows, performance prediction models, inverse design approaches, and multi-objective optimization for antennas. This issue will particularly target novel approaches that integrate machine learning with established electromagnetic simulation tools and optimization frameworks, aiming to improve antenna characteristics such as gain, bandwidth, radiation patterns, and efficiency.

Scope:

The scope of the Special Issue encompasses a wide range of topics at the intersection of ML and antenna design, including but not limited to the following:

  • ML-based predictive models that reduce the reliance on computationally expensive full-wave simulations.
  • Optimization algorithms (e.g., genetic algorithms, particle swarm optimization) applied to antenna synthesis and parameter tuning.
  • Inverse design methods using ML models, such as generative models or reinforcement learning, to propose novel antenna geometries based on specific performance criteria.
  • Hybrid approaches combining ML and optimization for solving complex, multi-objective problems in the design of antennas for emerging technologies such as 5G, mmWave communication, and massive MIMO systems.
  • Case studies demonstrating the successful application of ML in practical antenna design projects, including real-world antenna implementations and performance improvements.
  • Discussions on the challenges and future trends in applying machine learning techniques to antenna design, addressing issues like data availability, model interpretability, and computational efficiency.

The issue encourages interdisciplinary contributions from the fields of machine learning, electromagnetics, optimization theory, and antenna engineering. 

Purpose:

The purpose of this Special Issue is to showcase the transformative potential of machine learning and optimization techniques in automating and enhancing antenna design. As the demand for highly efficient, compact, and reconfigurable antennas grows in various communication systems, traditional design methods are often insufficient to keep pace. This issue aims to highlight research that demonstrates how machine learning can fill this gap by enabling faster design cycles, improving performance prediction accuracy, and solving complex design challenges. Furthermore, the integration of optimization algorithms allows for the identification of optimal antenna designs that balance conflicting objectives, such as size, gain, bandwidth, and efficiency. This Special Issue will contribute to the ongoing research in antenna design by presenting state-of-the-art methods that leverage machine learning, ultimately helping researchers and engineers develop more effective and efficient antennas for future communication systems.

Dr. Diego Caratelli
Guest Editor

Manuscript Submission Information

Manuscripts should be submitted online at www.mdpi.com by registering and logging in to this website. Once you are registered, click here to go to the submission form. Manuscripts can be submitted until the deadline. All submissions that pass pre-check are peer-reviewed. Accepted papers will be published continuously in the journal (as soon as accepted) and will be listed together on the special issue website. Research articles, review articles as well as short communications are invited. For planned papers, a title and short abstract (about 100 words) can be sent to the Editorial Office for announcement on this website.

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Keywords

  • antenna design
  • machine learning
  • optimization techniques
  • electromagnetic simulation
  • predictive modeling
  • inverse design
  • genetic algorithms
  • particle swarm optimization
  • multi-objective optimization
  • antenna synthesis
  • performance prediction
  • deep learning
  • reinforcement learning
  • metamaterial antennas
  • massive MIMO
  • mmWave antennas
  • phased arrays
  • evolutionary algorithms

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