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46 results on '"Maghareh, Amin"'

1. Deep generative models for unsupervised delamination detection using guided waves

Author

Rautela, Mahindra, Maghareh, Amin, Dyke, Shirley, and Gopalakrishnan, S.

Subjects
Electrical Engineering and Systems Science - Signal Processing
Abstract

With the rising demands for robust structural health monitoring procedures for aerospace structures, the scope of intelligent algorithms and learning techniques is expanding. Supervised algorithms have shown promising results in the field provided a large, balanced, and labeled amount of data for training. For some applications like aerospace, the data collection process is cumbersome, time-taking, and costly. Also, generating possible damage scenarios in a laboratory setup is challenging because of the complexity of the damage initiation and failure mechanism. Besides this, the uncertainties of the real-time operation restrict the online prediction accuracy with supervised learning. In this paper, deep generative models are proposed for unsupervised delamination prediction as an anomaly detection problem. In this one-class-based model, the deep learning network is trained to learn the distribution of baseline signals. In the testing phase, damage signals and unseen baseline signals are fed into the trained network to predict the state of the structure, i.e., healthy or unhealthy (delamination). It is seen that the proposed method can successfully predict the delamination with high accuracy.

Published
2023

2. Real-time rapid leakage estimation for deep space habitats using exponentially-weighted adaptively-refined search

Author

Rautela, Mahindra, Mirfarah, Motahareh, Silva, Christian, Dyke, Shirley, Maghareh, Amin, and Gopalakrishnan, S.

Subjects
Electrical Engineering and Systems Science - Signal Processing, Electrical Engineering and Systems Science - Systems and Control
Abstract

The recent accelerated growth in space-related research and development activities makes the near-term need for long-term extraterrestrial habitats evident. Such habitats must operate under continuous disruptive conditions arising from extreme environments like meteoroid impacts, extreme temperature fluctuations, galactic cosmic rays, destructive dust, and seismic events. Loss of air or atmospheric leakage from a habitat poses safety challenges that demand proper attention. Such leakage may arise from micro-meteoroid impacts, crack growth, bolt/rivet loosening, and seal deterioration. In this paper, leakage estimation in deep space habitats is posed as an inverse problem. A forward pressure-based dynamical model is formulated for atmospheric leakage. Experiments are performed on a small-scaled pressure chamber where different leakage scenarios are emulated and corresponding pressure values are measured. An exponentially-weighted adaptively-refined search (EWARS) algorithm is developed and validated for the inverse problem of real-time leakage estimation. It is demonstrated that the proposed methodology can achieve real-time estimation and tracking of constant and variable leaks with accuracy.

Published
2022
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4. Estimating States for Nonlinear Systems Using the Particle Filter

Author

Condori, Johnny, Maghareh, Amin, and Dyke, Shirley

Subjects
Electrical Engineering and Systems Science - Systems and Control
Abstract

Kalman filtering has been traditionally applied in three application areas of estimation, state estimation, parameter estimation (a.k.a. model updating), and dual estimation. However, Kalman filter is often not sufficient when experimenting with highly uncertain nonlinear dynamic systems. In this study, a nonlinear estimator is developed by adopting a particle filter algorithm that takes advantage of measured signals. This approach is shown to significantly improve the ability to estimate states. To illustrate this approach, a model for a nonlinear device coupled with a hydraulic actuator plays the role of an actual plant and a nonlinear algebraic function is considered as an approximation of the nonlinear device, thus generating non-parametric and parametric uncertainties. Then we use displacement and force signals to improve the distribution of the states by resampling the set of particles. Finally, all of the states are estimated from these posterior density functions. A set of simulations considering three different noise levels demonstrates that the performance of the particle filter approach is superior to the Kalman filter, yielding substantially better performance when estimating nonlinear physical systems in the presence of modeling uncertainties.

Published
2019

28. An adaptive sliding mode control system and its application to real‐time hybrid simulation.

Author

Li, HongWei, Maghareh, Amin, Wilfredo Condori Uribe, Johnny, Montoya, Herta, Dyke, Shirley J., and Xu, Zhaodong

Subjects
*SLIDING mode control, *HYBRID computer simulation, *ROBUST control, *ADAPTIVE control systems, *BENCHMARK problems (Computer science), *UNCERTAIN systems
Abstract

Summary: Real‐time hybrid simulation (RTHS) is intended to serve as a technique able to conduct experiments when the behavior of the plant is not well understood, i.e., when deep uncertainties are present in the physical specimen. By combining strategies from robust control and adaptive control, this paper develops an adaptive sliding mode control (ASMC) system for uncertain control plants. The ASMC consists of a bounded‐gain forgetting least‐squares estimator and a sliding mode controller, aimed at estimating parameters of the control plant and eliminating the negative effects of estimation errors, respectively. The ASMC is evaluated by applying it to the benchmark control problem in RTHS, where the fifth‐order control plant is reduced to a second‐order control plant to facilitate the control system's design and execution. High performance and robustness are achieved with the adoption of ASMC. The results demonstrate that an effective ASMC can be designed based on a significantly simplified control plant, making it a potent control system for RTHS. [ABSTRACT FROM AUTHOR]

Published
2022
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29. Hawaiian Lava Tubes with Extraterrestrial Habitat Applications

Author

Just, Jacob W, Theinat, Audai K, Maghareh, Amin, Bobet, Antonio, and Dyke, Shirley J

Subjects
Extraterrestrial habitats, stability of lava tubes, morphology and formation, Moon, skylight
Abstract

One of the next major steps in space exploration, as noted by agencies such as NASA and SpaceX, is the creation of extraterrestrial habitats. Most current extraterrestrial habitat designs focus on above-surface solutions and do not consider all the hazards that can impact this habitat. However, the existence of lava tubes on the moon, supported by data from Gravity Recovery and Interior Laboratory (GRAIL), SELenological and ENgineering Explorer (SELENE), and NASA’s Lunar Reconnaissance Orbiter (LRO), could impact extraterrestrial habitat designs. To support life, a prospective habitat must be safe from the harsh conditions of space, including meteorite impacts, radiation, and fluctuating temperatures. Lunar lava tubes, cave-like structures created during volcanic eruptions, can house a prospective habitat. This paper provides an understanding of lava tube morphology and formation methods on Earth which gives insight into extraterrestrial lava tubes, specifically their structure, stability, and formation methods. By studying lava tubes in Hawaii, a better understanding of these qualities is formed. This knowledge provides for a more accurate model in which stability is further investigated. Several factors are investigated in this model, including size and geometry. Using a case study of the Kaumana Cave and Thurston’s lava tube in Hawaii, it is found that stable terrestrial lava tubes share many similarities with extraterrestrial lava tubes. This shows the stability of lava tubes a few kilometers wide on the Moon. By knowing more about the stability of lunar lava tubes found through this research, future extraterrestrial habitat engineering designs will be impacted.

Published
2018

30. Extra-terrestrial Habitat Systems: Safety, Reliability, and Resilience

Author

Lyons, Jory C, Jr., Maghareh, Amin, Theinat, Audai, Dyke, Shirley, and Bobet, Antonio

Subjects
reliability, probabilistic risk assessment, extra-terrestrial habitat, Aerospace Engineering, resilience, failure analysis, Civil Engineering, Risk Analysis
Abstract

Developing a resilient extra-terrestrial habitat with regards to long-term reliability and safety from hazards including radiation, meteorites, and quakes is necessary to ensure human survival during interplanetary exploration. The objective of this study is to examine conventional aerospace safety and reliability analysis techniques to investigate whether they are sufficient to achieve resilience in extra-terrestrial habitats. These results will be obtained to complete a strengths, weaknesses, opportunities, and threats (SWOT) analysis of compiled techniques to design a sustainable habitat system. Failure modes, effects, and criticality analysis (FMECA) and probabilistic risk assessment (PRA) with their past applications will be assessed to provide the SWOT analysis to define the requirements for a resilient analysis technique capable of measuring safety and reliability. An in-depth analysis of aerospace engineering analysis techniques will be performed for historical successes and failures and then applied to a simple case study. The research findings are intended to be used as one step toward determining the feasibility of living in other extra-terrestrial environments, including different settlement concepts in surface habitats or lunar lava tubes, by refining conventional safety and reliability analysis procedures. Techniques including FMECA and PRA can determine necessary improvements to increase safety but may lack long-term resiliency. For this reason, there is a need to merge existing risk-based techniques and other design considerations to assess long-term reliability and resilience.

Published
2018

35. Modeling and Implementation of Distributed Real-time Hybrid Simulation

Author

Maghareh, Amin, Ozdagli, Ali, and Dyke, Shirley

Abstract

In order to improve the current knowledge on structural behavior subject to extreme dynamic loading and mitigate the existing threats against civil infrastructures, embracing the new technologies in experimental evaluation of civil structures are necessary. As civil structures evolve to achieve the needs of future generations, they need to achieve more robustness and resilience under an extremely wide range of operating conditions and hazards, for their design, implementation, validation, and evaluation. Thus, civil engineers are working to develop novel smart structures that are resilient to natural hazards and demonstrate the effectiveness of performance-based design. These challenges justify the need for more experimental capabilities in evaluating structural performances in a suitable and cost-effective manner. Hybrid simulation attempts to combine the realism of shake table testing with the economy and convenience of quasi-static testing. In hybrid simulation, the structure under investigation (i.e., the reference structure) is partitioned into two substructures, (1) numerical (or analytical) substructure, which usually includes well-studied components and (2) physical (or experimental) substructure, which usually includes more complex components while the coupling between the two substructures is achieved by enforcing equilibrium and compatibility at the interface. Real-time hybrid simulation (RTHS) provides the most advanced experimental technique to evaluate the performance of rate-dependent civil structures in laboratories. In RTHS, the interface interaction between the substructures is enforced by a transfer system which includes servo-hydraulic actuator(s) and/or shake table. To implement RTHS, there is a continuous exchange of information between the cyber and physical components. Due to the dynamics of the transfer system, communication and computation delays, the feedback force signals are dependent on the system state subject to delay. In RTHS, communication delays vary from almost negligible for an RTHS using a single processor (no network) to more than a hundred milliseconds for geographically distributed testing. Geographically distributed RTHS presents a challenge in which the required communication over the Internet results in random delays. In this paper, we propose a technique to enable researchers to conduct real-time hybrid simulations at unprecedented scales of size, timing, and complexity using a series of xPC target systems. xPC target system is a real-time software environment from MathWorks enabling researchers to execute Simulink and Stateflow models on a target computer for hardware-in-the-loop (HIL) simulation, rapid control prototyping, and other real-time testing applications. Herein, a simulation tool has been developed and published on the NEEShub (nees.org), a public collaboration platform developed for earthquake engineering research. Finally, an example of a distributed RTHS will be provided in which a four-story structure will be partitioned into two numerical substructures and a physical substructure. And results of (i) a pure simulation and (ii) a distributed RTHS will be shown and the integrity of numerical models and performance of the developed simulation tool will be evaluated.

Published
2014
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42. Predictive stability indicator: a novel approach to configuring a real-time hybrid simulation.

Author

Maghareh, Amin, Dyke, Shirley, Rabieniaharatbar, Siamak, and Prakash, Arun

Subjects
HYBRID computer simulation, DEGREES of freedom, COMPUTATIONAL mechanics, STABILITY (Mechanics), CONTROLLERSHIP
Abstract

Real-time hybrid simulation (RTHS) is an effective and versatile tool for the examination of complex structural systems with rate dependent behaviors. To meet the objectives of such a test, appropriate consideration must be given to the partitioning of the system into physical and computational portions (i.e., the configuration of the RTHS). Predictive stability and performance indicators (PSI and PPI) were initially established for use with only single degree-of-freedom systems. These indicators allow researchers to plan a RTHS, to quantitatively examine the impact of partitioning choices on stability and performance, and to assess the sensitivity of an RTHS configuration to de-synchronization at the interface. In this study, PSI is extended to any linear multi-degree-of-freedom (MDOF) system. The PSI is obtained analytically and it is independent of the transfer system and controller dynamics, providing a relatively easy and extremely useful method to examine many partitioning choices. A novel matrix method is adopted to convert a delay differential equation to a generalized eigenvalue problem using a set of vectorization mappings, and then to analytically solve the delay differential equations in a computationally efficient way. Through two illustrative examples, the PSI is demonstrated and validated. Validation of the MDOF PSI also includes comparisons to a MDOF dynamic model that includes realistic models of the hydraulic actuators and the control-structure interaction effects. Results demonstrate that the proposed PSI can be used as an effective design tool for conducting successful RTHS. Copyright © 2016 John Wiley & Sons, Ltd [ABSTRACT FROM AUTHOR]

Published
2017
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