This Second Volume in the series Handbook of Dynamic Data Driven Applications Systems (DDDAS) expands the scope of the methods and the application areas presented in the first Volume and aims to provide additional and extended content of the increasing set of science and engineering advances for new capabilities enabled through DDDAS. The methods and examples of breakthroughs presented in the book series capture the DDDAS paradigm and its scientific and technological impact and benefits. The DDDAS paradigm and the ensuing DDDAS-based frameworks for systems’ analysis and design have been shown to engender new and advanced capabilities for understanding, analysis, and management of engineered, natural, and societal systems (“applications systems”), and for the commensurate wide set of scientific and engineering fields and applications, as well as foundational areas. The DDDAS book series aims to be a reference source of many of the important research and development efforts conducted under the rubric of DDDAS, and to also inspire the broader communities of researchers and developers about the potential in their respective areas of interest, of the application and the exploitation of the DDDAS paradigm and the ensuing frameworks, through the examples and case studies presented, either within their own field or other fields of study.
As in the first volume, the chapters in this book reflect research work conducted over the years starting in the 1990’s to the present. Here, the theory and application content are considered for:
- Foundational Methods
- Materials Systems
- Structural Systems
- Energy Systems
- Environmental Systems: Domain Assessment & Adverse Conditions/Wildfires
- Surveillance Systems
- Space Awareness Systems
- Healthcare Systems
- Decision Support Systems
- Cyber Security Systems
- Design of Computer Systems
The readers of this book series will benefit from DDDAS theory advances such as object estimation, information fusion, and sensor management. The increased interest in Artificial Intelligence (AI), Machine Learning and Neural Networks (NN) provides opportunities for DDDAS-based methods to show the key role DDDAS plays in enabling AI capabilities; address challenges that ML-alone does not, and also show how ML in combination with DDDAS-based methods can deliver the advanced capabilities sought; likewise, infusion of DDDAS-like approaches in NN-methods strengthens such methods. Moreover, the “DDDAS-based Digital Twin” or “Dynamic Digital Twin”, goes beyond the traditional DT notion where the model and the physical system are viewed side-by-side in a static way, to a paradigm where the model dynamically interacts with the physical system through its instrumentation, (per the DDDAS feed-back control loop between model and instrumentation).
Arvustused
The Dynamic Data Driven Applications Systems (DDDAS) Paradigm and
Emerging Directions.- Dynamic Data Driven Applications Systems and
Information-Inference Couplings.- Polynomial Chaos Expansion Based Nonlinear
Filtering for Dynamic State Estimation.- Measure-Invariant Symbolic Systems
for Pattern Recognition and Anomaly Detection.- EquationFree Computations as
DDDAS Protocols for Bifurcation Studies: A Granular Chain Example.- A
Stochastic Dynamic Data-Driven Framework for Real-time Prediction of
Materials Damage in Composites.- Dynamic Data-Driven Monitoring of
Nanoparticle Self Assembly Processes.- From Data to Decisions: A Real-Time
Measurement -Inversion-Prediction-Steering Framework for Hazardous Events and
Structural Health Monitoring.- Bayesian Computational Sensor Networks:
Small-Scale Structural Health Monitoring.- A Dynamic Data Driven Sensor
Tasking with Application of Aerospace Systems.- Dynamic Data-Driven
Application Systems for Reservoir Simulation-Based Optimization: Lessons
Learned and Future Trends.- DDDAS within the Oil and Gas Industry.- A
Simulation-Based Online Dynamic Data-Driven Framework for Large-Scale
Wind-turbine Farm Systems Operation.- Towards Dynamic Data Driven Systems for
Rapid Adaptive Interdisciplinary Ocean Forecasting.- Towards Cyber-Eco
Systems: Networked Sensing, Inference and Control for Ecological and
Agricultural Systems.- An Energy-Aware Airborne Dynamic Data-Driven
Application System for Persistent Sampling and Surveillance.- Using Dynamic
Data Driven Cyberinfrastructure for Next Generation Wildland Fire
Intelligence.- Autonomous Monitoring of Wildfires with Vision-Equipped UAS
and Temperature Sensors via Evidential Reasoning.- Airborne Fire Detection
and Modeling using Unmanned Aerial Vehicles Imagery: Datasets and
Approaches.- DDDAS-based Remote Sensing.- Advances in Domain Adaptation for
Aerial Imagery.- Retrospective Cost Parameter Estimation with Application to
Space Weather Modeling.- A Dynamic Data Driven Approach to Space Situational
Awareness.- Data driven cancer research with digital microscopy and
Pathomics.- Robust Data Driven Region of Interest Segmentation for Breast
Thermography.- Adaptive Data Stream Mining (DSM) Systems.- Deception
Detection in Videos using Robust Facial Features with Attention
Feedback.- Manufacturing the Future via Dynamic Data Driven Applications
Systems (DDDAS).- DDDAS in the Social Sciences.- Anomaly-Detection Defense
against Test-Time Evasion Attacks on Robust DNNs.- Dynamic Data-Driven
Approach for Cyber Resilient and Secure Critical Energy Systems.- Dynamic
Network-centric Multi-cloud Platform for Real-Time and Data-Intensive Science
Workflows.- INDICES: Applying DDDAS Principles for Performance
Interferenceaware CloudtoFog Application Migration.- Adaptive Routing for
Hybrid Photonic-Plasmonic (HyPPI) Interconnection Network for Manycore
Processors using DDDAS on the Chip.
Frederica Darema, PhD, is President and CEO of the InfoSymbiotic Systems Society. She has retired as Senior Executive Service (SES) member and Director of the Air Force Office of Scientific Research, Arlington, Virginia, where she led the entire basic research investment for the AF, and she concurrently served as Research Director in the Air Forces Chief Data Office, and as Associate Deputy Assistant Secretary at the Air Force Office for Science, Technology and Engineering. Prior career history includes research staff positions at the University of Pittsburgh, Brookhaven National Laboratory, and Schlumberger-Doll; management and executive-level positions at the T. J. Watson IBM Research Center and the IBM Corporate Strategy Group, the National Science Foundation, and the Defense Advanced Research Projects Agency; and director of the AFOSR Directorate for Information, Math, and Life Sciences. Dr. Darema, PhD in nuclear physics, is a Fellow of the Institute of Electrical and Electronics Engineers (IEEE), among other professional recognitions. In 1983, she pioneered the SPMD computational model which is the predominant model for parallel (super)computing; and in 1980, she pioneered the DDDAS paradigm, and since 2000 she has organized and led research initiatives, programs, workshops, conferences (including the biannual DDDAS/InfoSymbiotic Systems Conference series, co-led with co-editors: Blasch, Ravela, and Aved; 2016-present), and other forums to foster and promote DDDAS-based science and technology advances. Erik P. Blasch, PhD, is a Program Officer with the Air Force Office of Scientific Research. His focus areas are in multi-domain (space, air, ground) data fusion, target tracking, pattern recognition, and robotics. He has authored 750+ scientific papers, 22 patents, 30 tutorials, and 5 books. Recognitions include the Military Sensing Society Mignogna leadership in data fusion award, IEEE Aerospace and Electronics Systems Society Mimno best magazine paper award, IEEE Russ bioengineering award, and founding member of the International Society of Information Fusion (ISIF). Previous appointments include adjunct associate professor at Wright State University, exchange scientist at Defense Research and Development Canada, and officer in the Air Force Research Laboratory. Dr. Blasch is an associate fellow of AIAA, fellow of SPIE, and fellow of IEEE. Sai Ravela, PhD, directs the Earth Signals and Systems Group (ESSG) in the Earth Atmospheric and Planetary Sciences (EAPS) Department at the MassachusettsInstitute of Technology. In addition, he is presently an Engineering Fellow at Cytonome conducting Cell Imaging & Biofluidic Control R&D, he is a co-Founder of WindrisktechLLC, quantifying Hurricane-induced Risk in a changing climate. Dr. Ravelas primary interests are in statistical pattern recognition, stochastic nonlinear systems science, and computational intelligence, withapplication to earth, planets, climate, and life. Dr. Ravela introduced new methods for coherent fluid dynamical regimes, applying them to DDDAS-based observing systems of localized atmospheric phenomena, laboratory studies, and wildlife. He has advanced learning-based approaches to DDDAS, and introduced the ensemble-based informative approach for DDDASbased learning and hybrid stochastic systems. Dr. Ravela is the recipient of the MIT 2016 Infinite Kilometer award for exceptional research and mentorship. Dr. Ravela organized the Dynamic Data Driven Environmental Systems Science Conference (DyDESS 2014, Cambridge), and has co-organized all DDDAS conferences (2016-2022). Alex J. Aved, PhD, is a Senior Researcher with the Air Force Research Laboratory, Information Directorate, Rome, NY, USA. His research interests include multimedia databases, stream processing (via CPU, GPU, or coprocessor), and dynamically executing models with feedback loops incorporating measurement and error data to improve the accuracy of the model. He has published over 50 papers and given numerous invited lectures. Previously, he was a programmer at the University of Central Florida and database administrator and programmer at Anderson University.
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