Data-driven comparison of spatio-temporal monitoring techniques

Shallow landslides in alpine environments can constitute a serious threat to the exposed elements. The spatio-temporal occurrence of such slope movements is controlled by a combination of predisposing factors (e.g. topography), preparatory factors (e.g. wet periods, snow melting) and landslide triggers (e.g. heavy precipitation events). &#160;For large study areas, landslide assessments frequently focus either on the static predisposing factors to estimate landslide susceptibility using data-driven procedures, or exclusively on the triggering events to derive empirical rainfall thresholds. For smaller areas, dynamic physical models can reasonably be parameterized to simultaneously account for static and dynamic landslide controls. &#160;The recently accepted Proslide project aims to develop and test methods with the potential to improve the predictability of landslides for the Italian province of South Tyrol. It is envisaged to account for a variety of innovative input data at multiple spatio-temporal scales. In this context, we seek to exploit remote sensing data for the spatio-temporal description of landslide controlling factors (e.g. precipitation RADAR; satellite soil moisture) and to develop models that allow an integration of heterogeneous model inputs using both, data-driven approaches (regional scale) and physically-based models (catchment scale). This contribution presents the core ideas and methodical framework behind the Proslide project and its very first results (e.g. relationships between landslide observations and gridded daily precipitation data at regional scale).&#160;

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On a Semiparametric Data‐Driven Nonlinear Model with Penalized Spatio‐Temporal Lag Interactions

Journal of Time Series Analysis ◽

10.1111/jtsa.12442 ◽

2018 ◽

Vol 40 (3) ◽

pp. 327-342

Author(s):

Dawlah Al‐Sulami ◽

Zhenyu Jiang ◽

Zudi Lu ◽

Jun Zhu

Keyword(s):

Nonlinear Model ◽

Data Driven ◽

Spatio Temporal

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Damage Detection in Flexible Propeller Beam Structures by Exploiting Impact-Induced Coupled Acceleration Signals

ASME 2011 Conference on Smart Materials, Adaptive Structures and Intelligent Systems, Volume 2 ◽

10.1115/smasis2011-4993 ◽

2011 ◽

Author(s):

Ioannis T. Georgiou

Keyword(s):

Data Driven ◽

Distributed Information ◽

Modal Expansion ◽

Shape Difference ◽

Spatio Temporal ◽

Temporal Sample ◽

High Level ◽

Proper Orthogonal ◽

Acceleration Signals

A local damage at the tip of a composite propeller is diagnosed by properly comparing its impact-induced free coupled dynamics to that of a pristine wooden propeller of the same size and shape. This is accomplished by creating indirectly via collocated measurements distributed information for the coupled acceleration field of the propellers. The powerful data-driven modal expansion analysis delivered by the Proper Orthogonal Decomposition (POD) Transform reveals that ensembles of impact-induced collocated coupled experimental acceleration signals are underlined by a high level of spatio-temporal coherence. Thus they furnish a valuable spatio-temporal sample of coupled response induced by a point impulse. In view of this fact, a tri-axial sensor was placed on the propeller hub to collect collocated coupled acceleration signals induced via modal hammer nondestructive impacts and thus obtained a reduced order characterization of the coupled free dynamics. This experimental data-driven analysis reveals that the in-plane unit components of the POD modes for both propellers have similar shapes-nearly identical. For the damaged propeller this POD shape-difference is quite pronounced. The shapes of the POD modes are used to compute indices of difference reflecting directly damage. At the first POD energy level, the shape-difference indices of the damaged composite propeller are quite larger than those of the pristine wooden propeller.

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Modelling the Risk of Imported COVID-19 Infections at Maritime Ports Based on the Mobility of International-Going Ships

ISPRS International Journal of Geo-Information ◽

10.3390/ijgi11010060 ◽

2022 ◽

Vol 11 (1) ◽

pp. 60

Author(s):

Zhihuan Wang ◽

Chenguang Meng ◽

Mengyuan Yao ◽

Christophe Claramunt

Keyword(s):

Clustering Algorithm ◽

Infection Risk ◽

Data Driven ◽

Risk Level ◽

Automatic Identification ◽

Identification System ◽

Prevention Measures ◽

Increase Rate ◽

Spatio Temporal ◽

Imported Infections

Maritime ports are critical logistics hubs that play an important role when preventing the transmission of COVID-19-imported infections from incoming international-going ships. This study introduces a data-driven method to dynamically model infection risks of international ports from imported COVID-19 cases. The approach is based on global Automatic Identification System (AIS) data and a spatio-temporal clustering algorithm that both automatically identifies ports and countries approached by ships and correlates them with country COVID-19 statistics and stopover dates. The infection risk of an individual ship is firstly modeled by considering the current number of COVID-19 cases of the approached countries, increase rate of the new cases, and ship capacity. The infection risk of a maritime port is mainly calculated as the aggregation of the risks of all of the ships stopovering at a specific date. This method is applied to track the risk of the imported COVID-19 of the main cruise ports worldwide. The results show that the proposed method dynamically estimates the risk level of the overseas imported COVID-19 of cruise ports and has the potential to provide valuable support to improve prevention measures and reduce the risk of imported COVID-19 cases in seaports.

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Data-Driven Time Series Forecasting for Social Studies Using Spatio-Temporal Graph Neural Networks

10.1145/3462203.3475929 ◽

2021 ◽

Author(s):

Yi-Fan Li ◽

Bo Dong ◽

Latifur Khan ◽

Bhavani Thuraisingham ◽

Patrick T. Brandt ◽

...

Keyword(s):

Neural Networks ◽

Time Series ◽

Social Studies ◽

Time Series Forecasting ◽

Data Driven ◽

Temporal Graph ◽

Spatio Temporal ◽

Graph Neural Networks

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Applied Koopman Theory for Partial Differential Equations and Data-Driven Modeling of Spatio-Temporal Systems

Complexity ◽

10.1155/2018/6010634 ◽

2018 ◽

Vol 2018 ◽

pp. 1-16 ◽

Cited By ~ 9

Author(s):

J. Nathan Kutz ◽

J. L. Proctor ◽

S. L. Brunton

Keyword(s):

Partial Differential Equations ◽

Differential Equations ◽

Data Driven ◽

Nonlinear Pdes ◽

Dynamic Mode ◽

Partial Differential ◽

Koopman Operator ◽

Dimensional Approximation ◽

Spatio Temporal ◽

The Impact

We consider the application of Koopman theory to nonlinear partial differential equations and data-driven spatio-temporal systems. We demonstrate that the observables chosen for constructing the Koopman operator are critical for enabling an accurate approximation to the nonlinear dynamics. If such observables can be found, then the dynamic mode decomposition (DMD) algorithm can be enacted to compute a finite-dimensional approximation of the Koopman operator, including its eigenfunctions, eigenvalues, and Koopman modes. We demonstrate simple rules of thumb for selecting a parsimonious set of observables that can greatly improve the approximation of the Koopman operator. Further, we show that the clear goal in selecting observables is to place the DMD eigenvalues on the imaginary axis, thus giving an objective function for observable selection. Judiciously chosen observables lead to physically interpretable spatio-temporal features of the complex system under consideration and provide a connection to manifold learning methods. Our method provides a valuable intermediate, yet interpretable, approximation to the Koopman operator that lies between the DMD method and the computationally intensive extended DMD (EDMD). We demonstrate the impact of observable selection, including kernel methods, and construction of the Koopman operator on several canonical nonlinear PDEs: Burgers’ equation, the nonlinear Schrödinger equation, the cubic-quintic Ginzburg-Landau equation, and a reaction-diffusion system. These examples serve to highlight the most pressing and critical challenge of Koopman theory: a principled way to select appropriate observables.

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