Improved Modeling of Microwave Structures Using Performance-Driven Fully-Connected Regression Surrogate

Koziel, Slawomir; Mahoutı, Peyman; Çalık, Nurullah; Belen, Mehmet A.; Szczepański, S.

doi:10.1109/access.2021.3078432

Cited by 26 publications

(19 citation statements)

References 61 publications

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“…x (17) where x (i) , i = 0, 1, …, are approximations to the optimum design x*. The yield estimated in the ith iteration, Ys (i) , is computed based on the surrogate model established in the current domain being the interval [x (i) -dl, x (i) -dl], with x (i) = [x1 (i) … xn (i) ] T , i.e., the domain is always centred at the current iteration point.…”

Section: Reference Algorithmsmentioning

confidence: 99%

“…Undeniably, the most widespread approaches today are surrogate-assisted methods, where statistical analysis or yield optimization are carried out using a fast replacement model (e.g., neural networks [12], response surface approximation [13], polynomial chaos expansion, PCE [14][15][16]). A practical limitation is the dimensionality of the parameter space, i.e., the number of training data samples (translating into a computational cost of its acquisition) required for a construction of a reliable surrogate quickly increases with the number of the circuit parameters (also called the curse of dimensionality [17]). Available mitigation techniques include diminishing a number of directly handled dimensions [18], the usage of advanced modeling techniques (e.g., PC kriging, in which traditional trend functions, such as polynomials of low order, are substituted with PCE [19]), incorporation of model order reduction [20], as well as variable-resolution methods (co-kriging [21], space mapping [22]).…”

Section: Introductionmentioning

confidence: 99%

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Design Centering of Compact Microwave Components Using Response Features and Trust Regions

Pietrenko‐Dabrowska

Koziel

2021

Energies

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Fabrication tolerances, as well as uncertainties of other kinds, e.g., concerning material parameters or operating conditions, are detrimental to the performance of microwave circuits. Mitigating their impact requires accounting for possible parameter deviations already at the design stage. This involves optimization of appropriately defined statistical figures of merit such as yield. Although important, robust (or tolerance-aware) design is an intricate endeavor because manufacturing inaccuracies are normally described using probability distributions, and their quantification has to be based on statistical analysis. The major bottleneck here is high computational cost: for reliability reasons, miniaturized microwave components are evaluated using full-wave electromagnetic (EM) models, whereas conventionally utilized analysis methods (e.g., Monte Carlo simulation) are associated with massive circuit evaluations. A practical approach that allows for circumventing the aforementioned obstacles offers surrogate modeling techniques, which have been a dominant trend over the recent years. Notwithstanding, a construction of accurate metamodels may require considerable computational investments, especially for higher-dimensional cases. This paper brings in a novel design-centering approach, which assembles forward surrogates founded at the level of response features and trust-region framework for direct optimization of the system yield. Formulating the problem with the use of characteristic points of the system response alleviates the issues related to response nonlinearities. At the same time, as the surrogate is a linear regression model, a rapid yield estimation is possible through numerical integration of the input probability distributions. As a result, expenditures related to design centering equal merely few dozens of EM analyses. The introduced technique is demonstrated using three microstrip couplers. It is compared to recently reported techniques, and its reliability is corroborated using EM-based Monte Carlo analysis.

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Section: Reference Algorithmsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Design Centering of Compact Microwave Components Using Response Features and Trust Regions

Pietrenko‐Dabrowska

Koziel

2021

Energies

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“…As a matter of fact, the list of advantages of data-driven surrogates is considerably longer: low evaluation cost, flexibility, no need for physical insight into the system under design, and transferability between various application areas. Some of widely used techniques of this class include kriging 35 , 36 , radial basis functions (RBF) 37 , Gaussian process regression (GPR) 38 , support vector regression 39 , and neural networks in many variations 40 , 41 . Still, a construction of data-driven surrogates for modern antennas featuring intricate topologies and large numbers of geometry parameters is challenging.…”

Section: Introductionmentioning

confidence: 99%

Reduced-cost two-level surrogate antenna modeling using domain confinement and response features

Pietrenko‐Dabrowska

Kozieł

Ullah

2022

Sci Rep

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Electromagnetic (EM) simulation tools have become indispensable in the design of contemporary antennas. Still, the major setback of EM-driven design is the associated computational overhead. This is because a single full-wave simulation may take from dozens of seconds up to several hours, thus, the cost of solving design tasks that involve multiple EM analyses may turn unmanageable. This is where faster system representations (surrogates) come into play. Replacing expensive EM-based evaluations by cheap yet accurate metamodels seems to be an attractive solution. Still, in antenna design, application of surrogate models is hindered by the curse of dimensionality. A practical workaround has been offered by the recently reported reference-design-free constrained modeling techniques that restrict the metamodel domain to the parameter space region encompassing high-quality designs. Therein, the domain is established using only a handful of EM-simulations. This paper proposes a novel modeling technique, which incorporates the response feature technology into the constrained modeling framework. Our methodology allows for rendering accurate surrogates using exceptionally small training data sets, at the expense of reducing the generality of the modeling procedure to antennas that exhibit consistent shape of input characteristics. The proposed technique can be employed in other fields that employ costly simulation models (e.g., mechanical or aerospace engineering).

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“…[3][4][5][6] Datadriven surrogate models are based on approximating sampled data which allow the model to make a prediction of targeted output characteristics using the given inputs without the need of expert knowledge of the selected problem, high adaptation rate between similar problems, and high computational efficiency. 6,7 Modeling and development of data-driven models is a topic that being studied by many researchers. Some examples of the commonly used modeling methods for microwave applications from literature can be named as kriging, 8 neural networks, [9][10][11][12] support vector regression, [13][14][15] and deep learning.…”

Section: Introductionmentioning

confidence: 99%

“…Some examples of the commonly used modeling methods for microwave applications from literature can be named as kriging, 8 neural networks, [9][10][11][12] support vector regression, [13][14][15] and deep learning. 6,7,[16][17][18][19][20][21] Although the utilization of data-driven surrogate models is a viable technique for design and optimization of microwave components, these methods are also has challenging design problems which must be addressed with care. (I) Properly creating data set, either using three-dimensional (3D) EM simulation or experiential data, for model is one of the most crucial step.…”

Section: Introductionmentioning

confidence: 99%

Surrogate‐assisted optimization of 3D printed ceramic nonuniform nonplanar microstrip filter

Mahouti

Kuskonmaz

Yıldırım

2022

Micro & Optical Tech Letters

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Herein, by using 3D printing technology and data‐driven surrogate model‐assisted optimization method, design of a ceramic material‐based nonuniform nonplanar microstrip filter is taken into the consideration in a computationally efficient and low‐cost manner. For this aim, 3D EM model of the proposed design had been used for generating training and validation data sets. Then commonly used state‐of‐the‐art regression algorithms had been used for creating accurate and fast surrogate models to create a mapping between inputs of the model and outputs of the unit element design. After that, Grey Wolf Optimization algorithm had been used for design optimization of a bandpass filter. Then, via the use of 3D printer, the optimally designed filter had been prototyped and its performance characteristics are measured. As a result, by using 3D printer technology, ceramic material, and the proposed method, design optimization of nonuniform nonplanar microstrip filter can be achieved in a computationally efficient way.

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Improved Modeling of Microwave Structures Using Performance-Driven Fully-Connected Regression Surrogate

Cited by 26 publications

References 61 publications

Design Centering of Compact Microwave Components Using Response Features and Trust Regions

Design Centering of Compact Microwave Components Using Response Features and Trust Regions

Reduced-cost two-level surrogate antenna modeling using domain confinement and response features

Surrogate‐assisted optimization of 3D printed ceramic nonuniform nonplanar microstrip filter

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