Advanced Image Analysis for Learning Underlying Partial Differential Equations for Anomaly Identification

2020 ◽  
Vol 64 (2) ◽  
pp. 20510-1-20510-10
Author(s):  
Andrew Miller ◽  
Jan Petrich ◽  
Shashi Phoha
Keyword(s):  
Partial Differential Equations ◽  
Differential Equations ◽  
Real Time ◽  
Heat Diffusion ◽  
Series Data ◽  
Model Parameters ◽  
Model Structure ◽  
Partial Differential ◽  
Individual Parameter ◽  
Heat Diffusion Equation

Abstract In this article, the authors adapt and utilize data-driven advanced image processing and machine learning techniques to identify the underlying dynamics and the model parameters for dynamic processes driven by partial differential equations (PDEs). Potential applications include non-destructive inspection for material crack detection using thermal imaging as well as real-time anomaly detection for process monitoring of three-dimensional printing applications. A neural network (NN) architecture is established that offers sufficient flexibility for spatial and temporal derivatives to capture the physical dependencies inherent in the process. Predictive capabilities are then established by propagating the process forward in time using the acquired model structure as well as individual parameter values. Moreover, deviations in the predicted values can be monitored in real time to detect potential process anomalies or perturbations. For concept development and validation, this article utilizes well-understood PDEs such as the homogeneous heat diffusion equation. Time series data governed by the heat equation representing a parabolic PDE is generated using high-fidelity simulations in order to construct the heat profile. Model structure and parameter identification are realized through a shallow residual convolutional NN. The learned model structure and associated parameters resemble a spatial convolution filter, which can be applied to the current heat profile to predict the diffusion behavior forward in time.

scholarly journals Applying the Swept Rule for Solving Two-Dimensional Partial Differential Equations on Heterogeneous Architectures

2021 ◽  
Vol 26 (3) ◽  
pp. 52
Author(s):  
Anthony S. Walker ◽  
Kyle E. Niemeyer
Keyword(s):  
Partial Differential Equations ◽  
Differential Equations ◽  
Heterogeneous Computing ◽  
Heat Diffusion ◽  
Fixed Cost ◽  
Two Dimensional ◽  
Partial Differential ◽  
Computing Systems ◽  
Heat Diffusion Equation ◽  
Work Distribution

The partial differential equations describing compressible fluid flows can be notoriously difficult to resolve on a pragmatic scale and often require the use of high-performance computing systems and/or accelerators. However, these systems face scaling issues such as latency, the fixed cost of communicating information between devices in the system. The swept rule is a technique designed to minimize these costs by obtaining a solution to unsteady equations at as many possible spatial locations and times prior to communicating. In this study, we implemented and tested the swept rule for solving two-dimensional problems on heterogeneous computing systems across two distinct systems and three key parameters: problem size, GPU block size, and work distribution. Our solver showed a speedup range of 0.22–2.69 for the heat diffusion equation and 0.52–1.46 for the compressible Euler equations. We can conclude from this study that the swept rule offers both potential for speedups and slowdowns and that care should be taken when designing such a solver to maximize benefits. These results can help make decisions to maximize these benefits and inform designs.

scholarly journals Modeling transport of antibiotic resistant bacteria in aquatic environment using stochastic differential equations

2020 ◽  
Vol 10 (1) ◽  
Author(s):  
Ritu Gothwal ◽  
Shashidhar Thatikonda
Keyword(s):  
Antibiotic Resistance ◽  
Partial Differential Equations ◽  
Differential Equations ◽  
Aquatic Environment ◽  
Stochastic Partial Differential Equations ◽  
Resistant Bacteria ◽  
Model Parameters ◽  
Antibiotic Resistant Bacteria ◽  
Partial Differential ◽  
Antibiotic Resistant

Abstract Contaminated sites are recognized as the “hotspot” for the development and spread of antibiotic resistance in environmental bacteria. It is very challenging to understand mechanism of development of antibiotic resistance in polluted environment in the presence of different anthropogenic pollutants. Uncertainties in the environmental processes adds complexity to the development of resistance. This study attempts to develop mathematical model by using stochastic partial differential equations for the transport of fluoroquinolone and its resistant bacteria in riverine environment. Poisson’s process is assumed for the diffusion approximation in the stochastic partial differential equations (SPDE). Sensitive analysis is performed to evaluate the parameters and variables for their influence over the model outcome. Based on their sensitivity, the model parameters and variables are chosen and classified into environmental, demographic, and anthropogenic categories to investigate the sources of stochasticity. Stochastic partial differential equations are formulated for the state variables in the model. This SPDE model is then applied to the 100 km stretch of river Musi (South India) and simulations are carried out to assess the impact of stochasticity in model variables on the resistant bacteria population in sediments. By employing the stochasticity in model variables and parameters we came to know that environmental and anthropogenic variations are not able to affect the resistance dynamics at all. Demographic variations are able to affect the distribution of resistant bacteria population uniformly with standard deviation between 0.087 and 0.084, however, is not significant to have any biological relevance to it. The outcome of the present study is helpful in simplifying the model for practical applications. This study is an ongoing effort to improve the model for the transport of antibiotics and transport of antibiotic resistant bacteria in polluted river. There is a wide gap between the knowledge of stochastic resistant bacterial growth dynamics and the knowledge of transport of antibiotic resistance in polluted aquatic environment, this study is one step towards filling up that gap.

scholarly journals Reliable Real-Time Solution of Parametrized Partial Differential Equations: Reduced-Basis Output Bound Methods

2001 ◽  
Vol 124 (1) ◽  
pp. 70-80 ◽  
Author(s):  
C. Prud’homme ◽  
D. V. Rovas ◽  
K. Veroy ◽  
L. Machiels ◽  
Y. Maday ◽  
...  
Keyword(s):  
Partial Differential Equations ◽  
Differential Equations ◽  
Real Time ◽  
Galerkin Projection ◽  
Real Time Control ◽  
Reduced Basis ◽  
Partial Differential ◽  
Approximation Process ◽  
Essential Components ◽  
On Line

We present a technique for the rapid and reliable prediction of linear-functional outputs of elliptic (and parabolic) partial differential equations with affine parameter dependence. The essential components are (i) (provably) rapidly convergent global reduced-basis approximations—Galerkin projection onto a space WN spanned by solutions of the governing partial differential equation at N selected points in parameter space; (ii) a posteriori error estimation—relaxations of the error-residual equation that provide inexpensive yet sharp and rigorous bounds for the error in the outputs of interest; and (iii) off-line/on-line computational procedures methods which decouple the generation and projection stages of the approximation process. The operation count for the on-line stage in which, given a new parameter value, we calculate the output of interest and associated error bound, depends only on N (typically very small) and the parametric complexity of the problem; the method is thus ideally suited for the repeated and rapid evaluations required in the context of parameter estimation, design, optimization, and real-time control.

scholarly journals Large-Scale Dynamics of Self-propelled Particles Moving Through Obstacles: Model Derivation and Pattern Formation

2020 ◽  
Vol 82 (10) ◽  
Author(s):  
P. Aceves-Sanchez ◽  
P. Degond ◽  
E. E. Keaveny ◽  
A. Manhart ◽  
S. Merino-Aceituno ◽  
...  
Keyword(s):  
Partial Differential Equations ◽  
Differential Equations ◽  
Large Scale ◽  
Coupled System ◽  
Model Parameters ◽  
Partial Differential ◽  
Pattern Size ◽  
Non Local ◽  
Model Derivation ◽  
Macroscopic Equations

Abstract We model and study the patterns created through the interaction of collectively moving self-propelled particles (SPPs) and elastically tethered obstacles. Simulations of an individual-based model reveal at least three distinct large-scale patterns: travelling bands, trails and moving clusters. This motivates the derivation of a macroscopic partial differential equations model for the interactions between the self-propelled particles and the obstacles, for which we assume large tether stiffness. The result is a coupled system of nonlinear, non-local partial differential equations. Linear stability analysis shows that patterning is expected if the interactions are strong enough and allows for the predictions of pattern size from model parameters. The macroscopic equations reveal that the obstacle interactions induce short-ranged SPP aggregation, irrespective of whether obstacles and SPPs are attractive or repulsive.

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