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200 10$aState Estimation and Stabilization of Nonlinear Systems $eTheory and Applications
205   $a1st ed.
210  1$aCham :$cSpringer,$d2023.
210  4$d©2023.
215   $a1 online resource (439 pages)
225 1 $aStudies in Systems, Decision and Control Series ;$vv.491
311 08$aPrint version: Ben Makhlouf, Abdellatif State Estimation and Stabilization of Nonlinear Systems Cham : Springer,c2023 9783031379697 
327   $aContents --  Practical h-Stability of Nonlinear Impulsive Systems: A Survey --   1 Introduction --   2 Definitions, Notations and Hypotheses --   3 Main Results --     3.1 Sufficient Conditions for Practical h-stability --   4 Practical h-stability of Perturbed and Cascaded System --     4.1 Practical h-stability of Perturbed System --     4.2 Practical h-stability of Cascaded System --   5 Practical h-stabilization --   6 Examples --   References --  Practical Exponential Stabilization for Semi-Linear Systems in Hilbert Spaces --   1 Introduction --   2 Preliminaries --   3 Main Results --     3.1 Exponential Stabilization by Linear State Controller --     3.2 Exponential Stabilization by Nonlinear State Controller --   4 Examples --   5 Conclusion --   References --  An Observer Controller for Delay Impulsive Switched Systems --   1 Introduction --   2 System Description --   3 Asymptotic Stability Result --   4 Design of Feedback Controller --   5 Observer-Based Control Design --     5.1 System Under Consideration --     5.2 Observer Design --     5.3 Observer-Based Control$7Generated by AI.
330   $aThis book discusses the state estimation and stabilization of nonlinear systems, focusing on both theoretical and practical aspects. It aims to provide comprehensive insights into various stability concepts, particularly practical h-stability, using Lyapunov stability theory. The editors and contributors present new methods and sufficient conditions for ensuring stability in nonlinear impulsive systems, with applications across fields such as engineering, biology, and economics. The book is intended for researchers, practitioners, and students in systems control and related disciplines.$7Generated by AI.
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200 14$aDie Vorausschätzung von Brancheninvestitionen mit Hilfe von Faktor-Output-Relationen.
205   $a1st ed.
210   $cDuncker & Humblot$d1968
210  1$aBerlin :$cDuncker & Humblot,$d2019.
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225 1 $aSchriften des Rheinisch-Westfälischen Instituts für Wirtschaftsforschung
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200 10$aAutomated Machine Learning and Industrial Applications
205   $a1st ed.
210  1$aNewark :$cJohn Wiley & Sons, Incorporated,$d2025.
210  4$d©2025.
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327   $aCover -- Series Page -- Title Page -- Copyright Page -- Contents -- Preface -- Chapter 1 Design and Architecture of AutoML for Data Science in Next-Generation Industries -- 1.1 Introduction -- 1.2 Modular Design -- 1.3 Data Handling -- 1.4 Model Training and Selection -- Conclusion -- References -- Chapter 2 Automated Machine Learning Model in Secure Data Transmission in Sustainable Healthcare Sensor Network Using Quantum Blockchain Architecture -- 2.1 Introduction -- 2.2 Related Works -- 2.3 Proposed Model -- 2.4 Results and Discussion -- 2.5 Conclusion -- References -- Chapter 3 Automated Machine Learning in the Biological and Medical Healthcare Industries: Analysis Interpretation and Evaluation -- 3.1 Introduction -- 3.1.1 Rise of AutoML -- 3.1.2 Significance of AutoML in Biological and Medical Healthcare -- 3.2 Methodology for Effective Data Management -- 3.3 Foundations of Automated Machine Learning -- 3.3.1 Understanding Automated Machine Learning -- 3.3.2 Components and Workflow -- 3.3.3 Pros of AutoML Implementation -- 3.3.4 Cons of AutoML Implementation -- 3.4 Applications in Healthcare -- 3.4.1 Disease Diagnosis -- 3.4.2 Drug Discovery and Development -- 3.4.3 Personalized Medicine -- 3.4.4 Predictive Analytics in Healthcare -- 3.5 Case Studies and Success Stories -- 3.5.1 Noteworthy Implementations -- 3.5.2 Impact on Patient Outcomes -- 3.5.3 Challenges Encountered and Overcome -- 3.6 Ethical Implications -- 3.6.1 Data Privacy and Security -- 3.6.2 Fairness and Bias Considerations -- 3.7 Practical Implementation: From Concept to Application -- 3.7.1 Problem Formulation and Data Preparation -- 3.7.2 Tool Selection -- 3.7.3 Training and Evaluation -- 3.7.4 Explainability and Interpretability -- 3.7.5 Deployment and Monitoring -- 3.8 Future Directions and Trends -- 3.8.1 Integration with Emerging Technologies.
327   $a3.8.2 AutoML in Clinical Trials and Research -- 3.9 Conclusion -- References -- Chapter 4 Advancements in AI and AutoML for Plant Leaf Disease Identification in Sustainable Agriculture -- 4.1 Introduction -- 4.2 Literature Survey -- 4.3 Preliminary Analysis for Agricultural Diseases -- 4.3.1 Datasets and Descriptions -- 4.3.2 Normalization and Scaling -- 4.3.3 Feature Extraction and Classification -- 4.3.4 Spectral Image Analysis -- 4.4 Proposed Methods -- 4.4.1 Leaf Disease Identification Using ResNet -- 4.4.2 Pixel-Based Information Extraction and Ant Colony Optimization -- 4.4.3 Image Enhancement and Segmentation -- 4.5 Conclusion -- References -- Chapter 5 Predictive Maintenance in Industrial Settings: Video Analytics at the Edge with AutoML -- 5.1 Introduction -- 5.2 Literature Review -- 5.3 Proposed Design of an Efficient Model for Enhancing Predictive Maintenance in Industrial Settings -- 5.4 Result Evaluation and Comparative Analysis -- 5.5 Conclusion and Future Scope -- Future Scope -- References -- Chapter 6 AutoCRM-An Automated Customer Relationship Management Learning System with Random Search Hyper-Parameter Optimization -- 6.1 Introduction -- 6.1.1 Opinion Mining or Sentiment Analysis -- 6.1.2 Machine Learning Approaches -- 6.1.3 Machine Learning Pipeline (ML) -- 6.1.4 Automated Machine Learning (AutoML) -- 6.1.4.1 AutoML Core Goals -- 6.1.4.2 AutoML Tools -- 6.1.5 Objectives of this Research -- 6.1.6 Outline -- 6.2 Literature Review -- 6.3 Methodology -- 6.3.1 Data Preparation -- 6.3.1.1 Data Collection -- 6.3.1.2 Data Cleaning and Labeling -- 6.3.1.3 Data Visualization -- 6.3.1.4 Feature Engineering -- 6.3.2 AutoKeras -- 6.3.2.1 Neural Architecture Search and Hyper-Parameter Tuning -- 6.3.3 Model Selection -- 6.4 Results and Discussions -- 6.4.1 Comparative Analysis: AutoML vs ML -- 6.5 Conclusion -- References.
327   $aChapter 7 The Competence of Customer Support Team for Sentiment Analysis in Chatbots Using AutoML -- 7.1 Introduction -- 7.1.1 Background -- 7.1.2 Problem Definition -- 7.1.3 Scope -- 7.1.4 Technical Highlights -- 7.1.5 Objectives -- 7.1.6 Common Chatbot Use Cases -- 7.1.7 The Basics of Sentiment Analysis -- 7.1.8 Levels of Sentiment Analysis -- 7.2 Literature Survey -- 7.3 Methodology for Chatbot Sentiment Analysis -- 7.3.1 AutoML-Based Exploratory Data Analysis and Subjectivity Detection -- 7.3.2 Trilateral Modifier Utilization -- 7.3.3 Sentiment Polarity Detection -- 7.3.4 Workflow of Customer Service Inquiry-Chatbot Response -- 7.3.5 Scoring -- 7.4 Experimentation and Results -- 7.4.1 Performance Metrics -- 7.4.2 Data Collection -- 7.4.3 Evaluation -- 7.5 Conclusion -- References -- Chapter 8 Financial Risk Prediction with Banking Monitoring for Cyber Security Analysis Using Automated Machine Learning -- 8.1 Introduction -- 8.2 Related Works -- 8.3 System Model -- 8.3.1 Cyber Security Detection Using Gaussian Encoder Belief Network -- 8.4 Results and Discussion -- 8.5 Conclusion -- References -- Chapter 9 AutoML Ecosystem and Open-Source Platforms: Challenges and Limitations -- 9.1 Introduction -- 9.2 Related Study -- 9.3 Ecosystem of AutoML -- 9.3.1 Data Preprocessing -- 9.3.2 Model Selection -- 9.3.3 Hyperparameter Tuning -- 9.3.4 Model Evaluation and Deployment -- 9.4 AutoML Frameworks -- 9.4.1 Google AutoML -- 9.4.2 IBM Watson AutoAI -- 9.4.3 Microsoft Azure AutoML -- 9.4.4 H2O.ai -- 9.4.5 Data Robot -- 9.4.6 Databricks AutoML -- 9.4.7 Tune -- 9.4.8 AutoKeras -- 9.4.9 H2O Driverless AI -- 9.4.10 RapidMiner -- 9.4.11 Google Cloud AutoML Tables -- 9.4.12 H2O Sparkling Water -- 9.4.13 Turi Create -- 9.4.14 Big ML -- 9.4.15 Hail -- 9.5 Open-Source AutoML Libraries -- 9.5.1 Auto-Sklearn -- 9.5.2 TPOT (Tree-Based Pipeline Optimization Tool).
327   $a9.5.3 AutoKeras -- 9.5.4 MLBox -- 9.5.5 AutoGluon -- 9.5.6 H2O AutoML -- 9.5.7 Auto-WEKA -- 9.5.8 AutoGluon Tabular -- 9.5.9 FLAML -- 9.5.10 Ludwig -- 9.6 Types of AutoML Approaches -- 9.6.1 Fully Automated -- 9.6.2 Human-in-the-Loop -- 9.6.3 Model Assisted -- 9.7 Benefits of AutoML -- 9.8 Challenges and Limitations -- 9.9 Conclusion -- References -- Chapter 10 Plant Disease Identification Using Extended-EfficientNet Deep Learning Model in Smart Farming -- 10.1 Introduction -- 10.1.1 Obstacles in the Agricultural Sector -- 10.1.1.1 Soil Erosion -- 10.1.1.2 Absence of High-Quality Seeds -- 10.1.1.3 Lack of Contemporary Farming Machinery -- 10.1.2 Challenges of AI in Agriculture -- 10.1.3 Existing Plant Disease Identification Methods -- 10.2 Literature Review -- 10.3 Materials and Methods -- 10.3.1 Dataset -- 10.3.2 Existing CNN Models -- 10.3.2.1 AlexNet -- 10.3.2.2 VGG16 -- 10.3.2.3 ResNet50 -- 10.3.2.4 Inception V3 -- 10.4 Methodology-E-ENet -- 10.4.1 Localization of the Leaf -- 10.4.2 Segmentation of Leaf Image -- 10.4.3 The Diseased Leaf Identification -- 10.5 Experimental Analysis -- 10.5.1 The Acquisition of Data -- 10.5.2 The Parameter Setup -- 10.5.2.1 The Configuration of Parameters for Leaf Localization -- 10.5.2.2 The Configuration of Parameters for Leaf Segmentation -- 10.5.2.3 The Configuration of Parameters for Leaf Retrieval -- 10.6 Results -- 10.6.1 The Leaf Localization Outcome -- 10.6.2 The Outcomes of Leaf Segmentation -- 10.6.3 The Result of Disease Identification -- 10.7 Comparative Test -- 10.8 Summary -- References -- Chapter 11 AutoML-Driven Deep Learning for Fake Currency Recognition -- 11.1 Introduction -- 11.2 Literature Review -- 11.2.1 Scope -- 11.2.2 Objectives -- 11.3 Proposed System -- 11.4 Methodology -- 11.5 Convolutional Neural Network -- 11.6 Analysis Modeling -- 11.6.1 Behavioral Modeling -- 11.7 Software Testing.
327   $a11.7.1 Types of Testing -- 11.7.2 Test Cases -- 11.8 Results and Discussions -- 11.9 Conclusion -- References -- Chapter 12 Blockchain and Automated Machine Learning-Based Advancements for Banking and Financial Sectors -- 12.1 Introduction -- 12.2 Understanding Blockchain and AutoML -- 12.3 Need of Blockchain -- 12.4 Synergies Between Blockchain and AutoML -- 12.5 Applications in Banking and Finance -- 12.6 Applications of AutoML in Industries -- 12.7 Case Studies and Real-World Applications -- 12.8 Blockchain in Finance -- 12.9 Real-World Examples and Case Studies -- 12.10 Benefits and Challenges -- 12.11 Discussion -- 12.12 Limitations -- 12.13 Recommendations for Implementation -- 12.14 Ethical Considerations and Responsible AI -- 12.15 Future Directions and Emerging Trends -- 12.16 Future Scope -- 12.17 Conclusion -- References -- Chapter 13 Advances in Automated Machine Learning for Precision Healthcare and Biomedical Discoveries -- 13.1 Introduction -- 13.1.1 Some of the Recent Publications and their Findings -- 13.2 Current Day Usage of AI -- 13.2.1 Deep Learning and Neural Networks -- 13.2.2 Natural Language Processing (NLP) -- 13.2.2.1 Clinical Documentation -- 13.2.2.2 Disease Prediction -- 13.2.2.3 Chatbots and Virtual Assistants -- 13.2.2.4 Report Analysis -- 13.2.3 Automation -- 13.2.3.1 Appointment Scheduling -- 13.2.3.2 Medication Dispensary -- 13.2.3.3 Robotic Surgeries -- 13.2.3.4 Inventory Management -- 13.3 Data Management and Security in Healthcare AI -- 13.3.1 Data Acquisition and Storage -- 13.3.2 Data Processing and Analysis -- 13.3.3 Data Protection and Privacy -- 13.3.4 Balancing Technological Advancements with Data Governance -- 13.3.5 The Evolving Role of AI in Data Security -- 13.3.6 Continuous Education in Data Management and AI -- 13.3.7 Preparing for the Future of Healthcare AI and Data Management.
327   $a13.4 Challenges in Integrating AI into Healthcare Systems.
330   $aThe book provides a comprehensive understanding of Automated Machine Learning's transformative potential across various industries, empowering users to seamlessly implement advanced machine learning solutions without needing extensive expertise. Automated Machine Learning (AutoML) is a process to automate the responsibilities of machine learning concepts for real-world problems. The AutoML process is comprised of all steps, beginning with a raw dataset and concluding with the construction of a machine learning model for deployment. The purpose of AutoML is to allow non-experts to work with machine learning models and techniques without requiring much knowledge in machine learning. This advancement enables data scientists to produce the easiest solutions and most accurate results within a short timeframe, allowing them to outperform normal machine learning models. Meta-learning, neural network architecture, and hyperparameter optimization, are applied based on AutoML. Automated Machine Learning and Industrial Applications offers an overview of the basic architecture, evolution, and applications of AutoML. Potential applications in healthcare, banking, agriculture, aerospace, and security are discussed in terms of their frameworks, implementation, and evaluation. This book also explores the AutoML ecosystem, its integration with blockchain, and various open-source tools available on the AutoML platform. It serves as a practical guide for engineers and data scientists, offering valuable insights for decision-makers looking to integrate machine learning into their workflows. Readers will find the book: Aims to explore current trends such as augmented reality, virtual reality, blockchain, open-source platforms, and Industry 4.0; Serves as an effective guide for professionals, researchers, industrialists, data scientists, and application developers; Explores technologies such as IoT, blockchain, artificial intelligence, and robotics, serving as a core guide for undergraduate and postgraduate students. Audience Data and computer scientists, research scholars, professionals, and industrialists interested in technology for Industry 4.0 applications.
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