Physics-Informed Neural Networks (PINNs) have gained much attention in various fields of engineering thanks to their capability of incorporating physical laws into the models. However, the assessment of PINNs in industrial applications involving coupling between mechanical and thermal fields is still an active research topic. In this work, we present an application of PINNs to a non-Newtonian fluid thermo-mechanical problem which is often considered in the rubber calendering process. We demonstrate the effectiveness of PINNs when dealing with inverse and ill-posed problems, which are impractical to be solved by classical numerical discretization methods. We study the impact of the placement of the sensors and the distribution of unsupervised points on the performance of PINNs in a problem of inferring hidden physical fields from some partial data. We also investigate the capability of PINNs to identify unknown physical parameters from the measurements captured by sensors. The effect of noisy measurements is also considered throughout this work. The results of this paper demonstrate that in the problem of identification, PINNs can successfully estimate the unknown parameters using only the measurements on the sensors. In ill-posed problems where boundary conditions are not completely defined, even though the placement of the sensors and the distribution of unsupervised points have a great impact on PINNs performance, we show that the algorithm is able to infer the hidden physics from local measurements.
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神(shen)(shen)(shen)經(jing)(jing)(jing)網(wang)絡(luo)(luo)(luo)(luo)(Neural Networks)是世界上(shang)三個(ge)最(zui)古老的(de)(de)(de)神(shen)(shen)(shen)經(jing)(jing)(jing)建模學(xue)(xue)會(hui)(hui)(hui)的(de)(de)(de)檔案期刊(kan):國際神(shen)(shen)(shen)經(jing)(jing)(jing)網(wang)絡(luo)(luo)(luo)(luo)學(xue)(xue)會(hui)(hui)(hui)(INNS)、歐洲神(shen)(shen)(shen)經(jing)(jing)(jing)網(wang)絡(luo)(luo)(luo)(luo)學(xue)(xue)會(hui)(hui)(hui)(ENNS)和(he)(he)(he)(he)日本神(shen)(shen)(shen)經(jing)(jing)(jing)網(wang)絡(luo)(luo)(luo)(luo)學(xue)(xue)會(hui)(hui)(hui)(JNNS)。神(shen)(shen)(shen)經(jing)(jing)(jing)網(wang)絡(luo)(luo)(luo)(luo)提(ti)供(gong)了一(yi)個(ge)論(lun)壇,以(yi)發(fa)展和(he)(he)(he)(he)培育一(yi)個(ge)國際社(she)會(hui)(hui)(hui)的(de)(de)(de)學(xue)(xue)者和(he)(he)(he)(he)實踐者感興趣的(de)(de)(de)所有(you)方面(mian)的(de)(de)(de)神(shen)(shen)(shen)經(jing)(jing)(jing)網(wang)絡(luo)(luo)(luo)(luo)和(he)(he)(he)(he)相關方法(fa)的(de)(de)(de)計(ji)(ji)算(suan)智能。神(shen)(shen)(shen)經(jing)(jing)(jing)網(wang)絡(luo)(luo)(luo)(luo)歡迎高質量論(lun)文的(de)(de)(de)提(ti)交,有(you)助(zhu)于全面(mian)的(de)(de)(de)神(shen)(shen)(shen)經(jing)(jing)(jing)網(wang)絡(luo)(luo)(luo)(luo)研究(jiu),從行為和(he)(he)(he)(he)大腦(nao)建模,學(xue)(xue)習(xi)算(suan)法(fa),通過(guo)數(shu)學(xue)(xue)和(he)(he)(he)(he)計(ji)(ji)算(suan)分(fen)析,系統(tong)的(de)(de)(de)工程和(he)(he)(he)(he)技術(shu)應(ying)用(yong),大量使(shi)用(yong)神(shen)(shen)(shen)經(jing)(jing)(jing)網(wang)絡(luo)(luo)(luo)(luo)的(de)(de)(de)概念和(he)(he)(he)(he)技術(shu)。這一(yi)獨特而廣(guang)泛的(de)(de)(de)范圍促進了生(sheng)物(wu)(wu)和(he)(he)(he)(he)技術(shu)研究(jiu)之間的(de)(de)(de)思想(xiang)交流,并有(you)助(zhu)于促進對生(sheng)物(wu)(wu)啟發(fa)的(de)(de)(de)計(ji)(ji)算(suan)智能感興趣的(de)(de)(de)跨學(xue)(xue)科社(she)區的(de)(de)(de)發(fa)展。因(yin)此,神(shen)(shen)(shen)經(jing)(jing)(jing)網(wang)絡(luo)(luo)(luo)(luo)編委會(hui)(hui)(hui)代表(biao)的(de)(de)(de)專家領(ling)域包括心(xin)理(li)學(xue)(xue),神(shen)(shen)(shen)經(jing)(jing)(jing)生(sheng)物(wu)(wu)學(xue)(xue),計(ji)(ji)算(suan)機(ji)科學(xue)(xue),工程,數(shu)學(xue)(xue),物(wu)(wu)理(li)。該雜志發(fa)表(biao)文章、信件和(he)(he)(he)(he)評(ping)論(lun)以(yi)及給編輯的(de)(de)(de)信件、社(she)論(lun)、時事、軟件調查和(he)(he)(he)(he)專利信息。文章發(fa)表(biao)在五個(ge)部分(fen)之一(yi):認知科學(xue)(xue),神(shen)(shen)(shen)經(jing)(jing)(jing)科學(xue)(xue),學(xue)(xue)習(xi)系統(tong),數(shu)學(xue)(xue)和(he)(he)(he)(he)計(ji)(ji)算(suan)分(fen)析、工程和(he)(he)(he)(he)應(ying)用(yong)。
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Given its status as a classic problem and its importance to both theoreticians and practitioners, edit distance provides an excellent lens through which to understand how the theoretical analysis of algorithms impacts practical implementations. From an applied perspective, the goals of theoretical analysis are to predict the empirical performance of an algorithm and to serve as a yardstick to design novel algorithms that perform well in practice. In this paper, we systematically survey the types of theoretical analysis techniques that have been applied to edit distance and evaluate the extent to which each one has achieved these two goals. These techniques include traditional worst-case analysis, worst-case analysis parametrized by edit distance or entropy or compressibility, average-case analysis, semi-random models, and advice-based models. We find that the track record is mixed. On one hand, two algorithms widely used in practice have been born out of theoretical analysis and their empirical performance is captured well by theoretical predictions. On the other hand, all the algorithms developed using theoretical analysis as a yardstick since then have not had any practical relevance. We conclude by discussing the remaining open problems and how they can be tackled.
Quantum communications is a promising technology that will play a fundamental role in the design of future networks. In fact, significant efforts are being dedicated by both the quantum physics and the classical communications communities on developing new architectures, solutions, and practical implementations of quantum communication networks (QCNs). Although these efforts led to various advances in today's technologies, there still exists a non-trivial gap between the research efforts of the two communities on designing and optimizing the QCN performance. For instance, most prior works by the classical communications community ignore important quantum physics-based constraints when designing QCNs. For example, many works on entanglement distribution do not account for the decoherence of qubits inside quantum memories and, thus, their designs become impractical since they assume an infinite quantum states' lifetime. In this paper, we introduce a novel framework, dubbed physics-informed QCNs, for designing and analyzing the performance of QCNs, by relying on the quantum physics principles that underly the different QCN components. The need of the proposed approach is then assessed and its fundamental role in designing practical QCNs is analyzed across various open research areas. Moreover, we identify novel physics-informed performance metrics and controls that enable QCNs to leverage the state-of-the-art advancements in quantum technologies to enhance their performance. Finally, we analyze multiple pressing challenges and open research directions in QCNs that must be treated using a physics-informed approach to lead practically viable results. Ultimately, this work attempts to bridge the gap between the classical communications and the quantum physics communities in the area of QCNs to foster the development of future communication networks (6G and beyond, and the quantum Internet).
In this work we describe an Adaptive Regularization using Cubics (ARC) method for large-scale nonconvex unconstrained optimization using Limited-memory Quasi-Newton (LQN) matrices. ARC methods are a relatively new family of optimization strategies that utilize a cubic-regularization (CR) term in place of trust-regions and line-searches. LQN methods offer a large-scale alternative to using explicit second-order information by taking identical inputs to those used by popular first-order methods such as stochastic gradient descent (SGD). Solving the CR subproblem exactly requires Newton's method, yet using properties of the internal structure of LQN matrices, we are able to find exact solutions to the CR subproblem in a matrix-free manner, providing large speedups and scaling into modern size requirements. Additionally, we expand upon previous ARC work and explicitly incorporate first-order updates into our algorithm. We provide experimental results when the SR1 update is used, which show substantial speed-ups and competitive performance compared to Adam and other second order optimizers on deep neural networks (DNNs). We find that our new approach, ARCLQN, compares to modern optimizers with minimal tuning, a common pain-point for second order methods.
In this paper we present a deep learning method to predict the temporal evolution of dissipative dynamic systems. We propose using both geometric and thermodynamic inductive biases to improve accuracy and generalization of the resulting integration scheme. The first is achieved with Graph Neural Networks, which induces a non-Euclidean geometrical prior with permutation invariant node and edge update functions. The second bias is forced by learning the GENERIC structure of the problem, an extension of the Hamiltonian formalism, to model more general non-conservative dynamics. Several examples are provided in both Eulerian and Lagrangian description in the context of fluid and solid mechanics respectively, achieving relative mean errors of less than 3% in all the tested examples. Two ablation studies are provided based on recent works in both physics-informed and geometric deep learning.
A novel distributed control law for consensus of networked double integrator systems with biased measurements is developed in this article. The agents measure relative positions over a time-varying, undirected graph with an unknown and constant sensor bias corrupting the measurements. An adaptive control law is derived using Lyapunov methods to estimate the individual sensor biases accurately. The proposed algorithm ensures that position consensus is achieved exponentially in addition to bias estimation. The results leverage recent advances in collective initial excitation based results in adaptive estimation. Conditions connecting bipartite graphs and collective initial excitation are also developed. The algorithms are illustrated via simulation studies on a network of double integrators with local communication and biased measurements.
We introduce Universal Solution Manifold Network (USM-Net), a novel surrogate model, based on Artificial Neural Networks (ANNs), which applies to differential problems whose solution depends on physical and geometrical parameters. Our method employs a mesh-less architecture, thus overcoming the limitations associated with image segmentation and mesh generation required by traditional discretization methods. Indeed, we encode geometrical variability through scalar landmarks, such as coordinates of points of interest. In biomedical applications, these landmarks can be inexpensively processed from clinical images. Our approach is non-intrusive and modular, as we select a data-driven loss function. The latter can also be modified by considering additional constraints, thus leveraging available physical knowledge. Our approach can also accommodate a universal coordinate system, which supports the USM-Net in learning the correspondence between points belonging to different geometries, boosting prediction accuracy on unobserved geometries. Finally, we present two numerical test cases in computational fluid dynamics involving variable Reynolds numbers as well as computational domains of variable shape. The results show that our method allows for inexpensive but accurate approximations of velocity and pressure, avoiding computationally expensive image segmentation, mesh generation, or re-training for every new instance of physical parameters and shape of the domain.
Recent decades, the emergence of numerous novel algorithms makes it a gimmick to propose an intelligent optimization system based on metaphor, and hinders researchers from exploring the essence of search behavior in algorithms. However, it is difficult to directly discuss the search behavior of an intelligent optimization algorithm, since there are so many kinds of intelligent schemes. To address this problem, an intelligent optimization system is regarded as a simulated physical optimization system in this paper. The dynamic search behavior of such a simplified physical optimization system are investigated with quantum theory. To achieve this goal, the Schroedinger equation is employed as the dynamics equation of the optimization algorithm, which is used to describe dynamic search behaviours in the evolution process with quantum theory. Moreover, to explore the basic behaviour of the optimization system, the optimization problem is assumed to be decomposed and approximated. Correspondingly, the basic search behaviour is derived, which constitutes the basic iterative process of a simple optimization system. The basic iterative process is compared with some classical bare-bones schemes to verify the similarity of search behavior under different metaphors. The search strategies of these bare bones algorithms are analyzed through experiments.
We propose a new design of a neural network for solving a zero shot super resolution problem for turbulent flows. We embed Luenberger-type observer into the network's architecture to inform the network of the physics of the process, and to provide error correction and stabilization mechanisms. In addition, to compensate for decrease of observer's performance due to the presence of unknown destabilizing forcing, the network is designed to estimate the contribution of the unknown forcing implicitly from the data over the course of training. By running a set of numerical experiments, we demonstrate that the proposed network does recover unknown forcing from data and is capable of predicting turbulent flows in high resolution from low resolution noisy observations.
The performance of a quantum information processing protocol is ultimately judged by distinguishability measures that quantify how distinguishable the actual result of the protocol is from the ideal case. The most prominent distinguishability measures are those based on the fidelity and trace distance, due to their physical interpretations. In this paper, we propose and review several algorithms for estimating distinguishability measures based on trace distance and fidelity. The algorithms can be used for distinguishing quantum states, channels, and strategies (the last also known in the literature as "quantum combs"). The fidelity-based algorithms offer novel physical interpretations of these distinguishability measures in terms of the maximum probability with which a single prover (or competing provers) can convince a verifier to accept the outcome of an associated computation. We simulate many of these algorithms by using a variational approach with parameterized quantum circuits. We find that the simulations converge well in both the noiseless and noisy scenarios, for all examples considered. Furthermore, the noisy simulations exhibit a parameter noise resilience.
Since deep neural networks were developed, they have made huge contributions to everyday lives. Machine learning provides more rational advice than humans are capable of in almost every aspect of daily life. However, despite this achievement, the design and training of neural networks are still challenging and unpredictable procedures. To lower the technical thresholds for common users, automated hyper-parameter optimization (HPO) has become a popular topic in both academic and industrial areas. This paper provides a review of the most essential topics on HPO. The first section introduces the key hyper-parameters related to model training and structure, and discusses their importance and methods to define the value range. Then, the research focuses on major optimization algorithms and their applicability, covering their efficiency and accuracy especially for deep learning networks. This study next reviews major services and toolkits for HPO, comparing their support for state-of-the-art searching algorithms, feasibility with major deep learning frameworks, and extensibility for new modules designed by users. The paper concludes with problems that exist when HPO is applied to deep learning, a comparison between optimization algorithms, and prominent approaches for model evaluation with limited computational resources.
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