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Produktbild: AI for Cybersecurity

AI for Cybersecurity Research and Practice

164,99 €

inkl. gesetzl. MwSt., Versandkostenfrei


Beschreibung

Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

12.01.2026

Herausgeber

Alvaro Vasquez + weitere

Verlag

Wiley

Seitenzahl

656

Maße (L/B/H)

23,7/16,1/4,2 cm

Gewicht

1044 g

Sprache

Englisch

ISBN

978-1-394-29374-2

Beschreibung

Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

12.01.2026

Herausgeber

Verlag

Wiley

Seitenzahl

656

Maße (L/B/H)

23,7/16,1/4,2 cm

Gewicht

1044 g

Sprache

Englisch

ISBN

978-1-394-29374-2

Herstelleradresse

Libri GmbH
Europaallee 1
36244 Bad Hersfeld
DE

Email: gpsr@libri.de

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  • Produktbild: AI for Cybersecurity
  • List of Contributors xix

    Foreword xxvii

    About the Editors xxxi

    Preface xxxv

    Acknowledgments xxxvii

    1 LLMs Are Not Few-shot Threat Hunters 1
    Glenn A. Fink, Luiz M. Pereira, and Christian W. Stauffer

    1.1 Overview 1

    1.1.1 AI Is Not Magic 1

    1.1.2 Inherent Difficulty of Human Tasks in Cybersecurity and Threat Hunting 3

    1.2 Large Language Models 4

    1.2.1 Background 4

    1.2.2 Transformers 4

    1.2.3 Pretraining and Fine-tuning 9

    1.2.4 General Limitations 9

    1.3 Threat Hunters 12

    1.3.1 Introduction to Threat Hunting 12

    1.3.2 The Dimensions of Threat Hunting 13

    1.3.3 The Approaches to Threat Hunting 15

    1.3.4 The Process of Threat Hunting 16

    1.3.5 Challenges to Modern Threat Hunting 17

    1.4 Capabilities and Limitations of LLMs in Cybersecurity 18

    1.4.1 General Limitations of LLMs for Cybersecurity 18

    1.4.2 General Capabilities of LLMs Useful for Cybersecurity 20

    1.4.3 Applications of LLMs in Cybersecurity 22

    1.5 Conclusion: Reimagining LLMs as Assistant Threat Hunter 24

    References 27

    2 LLMs on Support of Privacy and Security of Mobile Apps: State-of-the-art and Research Directions 29
    Tran Thanh Lam Nguyen, Barbara Carminati, and Elena Ferrari

    2.1 Introduction 29

    2.2 Background on LLMs 32

    2.2.1 Large Language Models 32

    2.2.2 FSL and RAG 39

    2.3 Mobile Apps: Main Security and Privacy Threats 43

    2.4 LLM-based Solutions: State-of-the-art 47

    2.4.1 Vulnerabilities Detection 48

    2.4.2 Bug Detection and Reproduction 50

    2.4.3 Malware Detection 52

    2.5 An LLMs-based Approach for Mitigating Image Metadata Leakage Risks 53

    2.6 Research Challenges 57

    2.7 Conclusion 60

    Acknowledgment 61

    References 61

    3 Machine Learning-based Intrusion Detection Systems: Capabilities, Methodologies, and Open Research Challenges 67
    Chaoyu Zhang, Ning Wang, Y. Thomas Hou, and Wenjing Lou

    3.1 Introduction 67

    3.2 Basic Concepts and ML for Intrusion Detection 69

    3.2.1 Fundamental Concepts 69

    3.2.2 ml Algorithms for Intrusion Detection 70

    3.2.3 Taxonomy of IDSs 72

    3.2.4 Evaluation Metrics and Datasets 73

    3.3 Capability I: Zero-day Attack Detection with ml 75

    3.3.1 Understanding Zero-day Attacks and Their Impact 75

    3.3.2 General Workflow of ML-IDS for Identifying Zero-day Attacks 75

    3.3.3 Anomaly Detection Mechanisms 76

    3.3.4 Open Research Challenges 77

    3.4 Capability II: Intrusion Explainability Through XAI 79

    3.4.1 Enhancing Transparency and Trust in Intrusion Detection 79

    3.4.2 General Workflow of XAI 80

    3.4.3 XAI Methods for IDS Transparency Enhancement 80

    3.4.4 Open Research Challenges 83

    3.5 Capability III: Intrusion Detection in Encrypted Traffic 84

    3.5.1 Challenges in Intrusion Detection for Encrypted Traffic 84

    3.5.2 Workflow of ML-IDS for Encrypted Traffic 84

    3.5.3 ML-based Solutions for Encrypted Traffic Analysis 84

    3.5.4 Open Research Challenges 87

    3.6 Capability IV: Context-aware Threat Detection and Reasoning with GNNs 88

    3.6.1 Introduction to GNNs in IDS 88

    3.6.2 Workflow of GNNs for Intrusion Detection 88

    3.6.3 Provenance-based Intrusion Detection by GNNs 89

    3.6.4 Open Research Challenges 92

    3.7 Capability V: LLMs for Intrusion Detection and Understanding 93

    3.7.1 The Role of LLMs in Cybersecurity 93

    3.7.2 Leveraging LLMs for Intrusion Detection 94

    3.7.3 A Review of LLM-based IDS 94

    3.7.4 Open Research Challenges 97

    3.8 Summary 97

    References 98

    4 Generative AI for Advanced Cyber Defense 109
    Moqsadur Rahman, Aaron Sanchez, Krish Piryani, Siddhartha Das, Sai Munikoti, Luis de la Torre Quintana, Monowar Hasan, Joseph Aguayo, Monika Akbar, Shahriar Hossain, and Mahantesh Halappanavar

    4.1 Introduction 109

    4.2 Motivation and Related Work 111

    4.2.1 AI-supported Vulnerability Management 112

    4.3 Foundations for Cyber Defense 114

    4.3.1 Mapping Vulnerabilities, Weaknesses, and Attack Patterns Using LLMs 115

    4.4 Retrieval-augmented Generation 117

    4.5 KG and Querying 118

    4.5.1 Graph Schema 119

    4.5.2 Neo4j KG Implementation 122

    4.5.3 Cypher Queries 123

    4.6 Evaluation and Results 126

    4.6.1 RAG-based Response Generation 127

    4.6.2 CWE Predictions Using RAG 131

    4.6.3 CWE Predictions Using GPT4-o 136

    4.7 Conclusion 142

    References 142

    5 Enhancing Threat Detection and Response with Generative AI and Blockchain 147
    Driss El Majdoubi, Souad Sadki, Zakia El Uahhabi, and Mohamed Essaidi

    5.1 Introduction 147

    5.2 Cybersecurity Current Issues: Background 148

    5.3 Blockchain Technology for Cybersecurity 150

    5.3.1 Blockchain Benefits for Cybersecurity 150

    5.3.2 Existing Blockchain-based Cybersecurity Solutions 153

    5.4 Combining Generative AI and Blockchain for Cybersecurity 156

    5.4.1 Integration of Generative AI and Blockchain 160

    5.4.2 Understanding Capabilities and Risks 160

    5.4.3 Practical Benefits for Cybersecurity 161

    5.4.4 Limitations and Open Research Issues 161

    5.5 Conclusion 162

    References 163

    6 Privacy-preserving Collaborative Machine Learning 169
    Runhua Xu and James Joshi

    6.1 Introduction 169

    6.1.1 Objectives and Structure 171

    6.2 Collaborative Learning Overview 172

    6.2.1 Definition and Characteristics 172

    6.2.2 Related Terminologies 174

    6.2.3 Collaborative Decentralized Learning and Collaborative Distributed Learning 175

    6.3 Collaborative Learning Paradigms and Privacy Risks 177

    6.3.1 Key Collaborative Approaches 177

    6.3.2 Privacy Risks in Collaborative Learning 182

    6.3.3 Privacy Inference Attacks in Collaborative Learning 183

    6.4 Privacy-preserving Technologies 187

    6.4.1 The Need for Privacy Preservation 187

    6.4.2 Privacy-preserving Technologies 188

    6.5 Conclusion 195

    References 196

    7 Security and Privacy in Federated Learning 203
    Zhuosheng Zhang and Shucheng Yu

    7.1 Introduction 203

    7.1.1 Federated Learning 203

    7.1.2 Privacy Threats in FL 205

    7.1.3 Security Issues in FL 207

    7.1.4 Characterize FL 211

    7.2 Privacy-preserving FL 215

    7.2.1 Secure Multiparty Computation 215

    7.2.2 Trust Execution Environments 216

    7.2.3 Secure Aggregation 217

    7.2.4 Differential Privacy 218

    7.3 Enhance Security in FL 219

    7.3.1 Data-poisoning Attack and Nonadaptive Model-poisoning Attack 220

    7.3.2 Model-poisoning Attack 222

    7.4 Secure Privacy-preserving FL 225

    7.4.1 Enhancing Security in FL with DP 225

    7.4.2 Verifiability in Private FL 226

    7.4.3 Security in Private FL 227

    7.5 Conclusion 228

    References 229

    8 Machine Learning Attacks on Signal Characteristics in Wireless Networks 235
    Yan Wang, Cong Shi, Yingying Chen, and Zijie Tang

    8.1 Introduction 235

    8.2 Threat Model and Targeted Models 239

    8.2.1 Backdoor Attack Scenarios 239

    8.2.2 Attackers' Capability 240

    8.2.3 Attackers' Objective 240

    8.2.4 Targeted ML Models 241

    8.3 Attack Formulation and Challenges 241

    8.3.1 Backdoor Attack Formulation 241

    8.3.2 Challenges 244

    8.4 Poison-label Backdoor Attack 246

    8.4.1 Stealthy Trigger Designs 246

    8.4.2 Backdoor Trigger Optimization 249

    8.5 Clean-label Backdoor Trigger Design 252

    8.5.1 Clean-label Backdoor Trigger Optimization 253

    8.6 Evaluation 255

    8.6.1 Victim ML Model 255

    8.6.2 Experimental Methodology 255

    8.6.3 RF Backdoor Attack Performance 257

    8.6.4 Resistance to Backdoor Defense 259

    8.7 Related Work 261

    8.8 Conclusion 262

    References 263

    9 Secure by Design 267
    Mehdi Mirakhorli and Kevin E. Greene

    9.1 Introduction 267

    9.1.1 Definitions and Contexts 268

    9.1.2 Core Principles of "Secure by Design" 269

    9.1.3 Principle of Compartmentalization and Isolation 273

    9.2 A Methodological Approach to Secure by Design 275

    9.2.1 Assumption of Breach 275

    9.2.2 Misuse and Abuse Cases to Drive Secure by Design 276

    9.2.3 Secure by Design Through Architectural Tactics 277

    9.2.4 Shifting Software Assurance from Coding Bugs to Design Flaws 282

    9.3 AI in Secure by Design: Opportunities and Challenges 283

    9.4 Conclusion and Future Directions 284

    References 284

    10 DDoS Detection in IoT Environments: Deep Packet Inspection and Real-world Applications 289
    Nikola Gavric, Guru Bhandari, and Andrii Shalaginov

    10.1 Introduction 289

    10.2 DDoS Detection Techniques in Research 294

    10.2.1 Network-based Intrusion Detection Systems 295

    10.2.2 Host-based Intrusion Detection Systems 300

    10.3 Limitations of Research Approaches 303

    10.4 Industry Practices for DDoS Detection 305

    10.5 Challenges in DDoS Detection 309

    10.6 Future Directions 311

    10.7 Conclusion 313

    References 314

    11 Data Science for Cybersecurity: A Case Study Focused on DDoS Attacks 317
    Michele Nogueira, Ligia F. Borges, and Anderson B. Neira

    11.1 Introduction 317

    11.2 Background 319

    11.2.1 Cybersecurity 320

    11.2.2 Data Science 326

    11.3 State of the Art 333

    11.3.1 Data Acquisition 334

    11.3.2 Data Preparation 335

    11.3.3 Feature Preprocessing 336

    11.3.4 Data Visualization 337

    11.3.5 Data Analysis 338

    11.3.6 ml in Cybersecurity 339

    11.4 Challenges and Opportunities 340

    11.5 Conclusion 341

    Acknowledgments 342

    References 342

    12 AI Implications for Cybersecurity Education and Future Explorations 347
    Elizabeth Hawthorne, Mihaela Sabin, and Melissa Dark

    12.1 Introduction 347

    12.2 Postsecondary Cybersecurity Education: Historical Perspective and Current Initiatives 348

    12.2.1 ACM Computing Curricula 348

    12.2.2 National Centers for Academic Excellence in Cybersecurity 356

    12.2.3 ABET Criteria 359

    12.3 Cybersecurity Policy in Secondary Education 361

    12.3.1 US High School Landscape 362

    12.4 Conclusion 367

    12.5 Future Explorations 368

    References 368

    13 Ethical AI in Cybersecurity: Quantum-resistant Architectures and Decentralized Optimization Strategies 371
    Andreou Andreas, Mavromoustakis X. Constandinos, Houbing Song, and Jordi Mongay Batalla

    13.1 Introduction 371

    13.1.1 Motivation 372

    13.1.2 Contribution 373

    13.1.3 Novelty 373

    13.2 Literature Review 373

    13.3 Overview and Ethical Considerations in AI-centric Cybersecurity 374

    13.4 AML and Privacy Risks in AI Systems 378

    13.5 Forensic and Formal Methods for AI Security 380

    13.5.1 Auditing Tools for Security and Privacy 383

    13.5.2 Transparency, Interpretability, and Trust 383

    13.5.3 Building Secure and Trustworthy AI Systems 384

    13.6 Generative AI and Quantum-resistant Architectures in Cybersecurity 385

    13.6.1 Opportunities and Risks 385

    13.6.2 Threats and Countermeasures 386

    13.6.3 Strategies for Resilience 387

    13.7 Future Directions and Ethical Considerations 387

    13.8 Conclusion 390

    References 391

    14 Security Threats and Defenses in AI-enabled Object Tracking Systems 397
    Mengjie Jia, Yanyan Li, and Jiawei Yuan

    14.1 Introduction 397

    14.2 Related Works 398

    14.2.1 UAV Object Tracking 398

    14.2.2 Adversarial Tracking Attacks 399

    14.2.3 Robustness Enhancement Against Attacks 400

    14.3 Methods 401

    14.3.1 Model Architecture 403

    14.3.2 Decision Loss 403

    14.3.3 Feature Loss 404

    14.3.4 l 2 Norm loss 405

    14.4 Evaluation 405

    14.4.1 Experiment Setup 405

    14.4.2 Evaluation Metrics 405

    14.4.3 Results 406

    14.4.4 Tracking Examples 409

    14.5 Conclusion 413

    Acknowledgment 413

    References 413

    15 AI for Android Malware Detection and Classification 419
    Safayat Bin Hakim, Muhammad Adil, Kamal Acharya, and Houbing Herbert Song

    15.1 Introduction 419

    15.1.1 Security Threats in Android Applications 420

    15.1.2 Challenges in Android Malware Detection 422

    15.1.3 Current Approaches and Limitations 423

    15.2 Design of the Proposed Framework 424

    15.2.1 Core Components and Architecture 424

    15.2.2 Feature Extraction with Attention Mechanism 425

    15.2.3 Feature Extraction with Attention Mechanism 425

    15.2.4 Dimensionality Reduction and Optimization 427

    15.2.5 Classification Using SVMs 427

    15.3 Implementation and Dataset Overview 428

    15.3.1 Dataset Insights 428

    15.3.2 Preprocessing Strategies 429

    15.3.3 Handling Class Imbalance 429

    15.3.4 Adversarial Training and Evaluation 429

    15.4 Results and Insights 431

    15.4.1 Experimental Setup 431

    15.4.2 Performance Analysis 435

    15.4.3 Performance Insights with Visualization 436

    15.4.4 Benchmarking Against Existing Methods 438

    15.4.5 Key Insights 439

    15.5 Feature Importance Analysis 439

    15.5.1 Top Feature Importance 439

    15.5.2 Feature Impact Analysis Using SHAP Values 441

    15.5.3 Global Feature Impact Distribution 442

    15.6 Comparative Analysis and Advancements over Existing Methods 442

    15.6.1 Feature Space Optimization 444

    15.6.2 Advances in Adversarial Robustness 445

    15.6.3 Performance Improvements 445

    15.6.4 Summary of Key Advancements 445

    15.7 Discussion 446

    15.7.1 Limitations and Future Work 446

    15.8 Conclusion 447

    References 447

    16 Cyber-AI Supply Chain Vulnerabilities 451
    Joanna C. S. Santos

    16.1 Introduction 451

    16.2 AI/ML Supply Chain Attacks via Untrusted Model Deserialization 452

    16.2.1 Model Deserialization 453

    16.2.2 AI/ML Attack Scenarios 457

    16.3 The State-of-the-art of the AI/ML Supply Chain 458

    16.3.1 Commonly Used Serialization Formats 458

    16.3.2 Deliberately Malicious Models Published on Hugging Face 460

    16.3.3 Developers' Perception on Safetensors 462

    16.4 Conclusion 466

    16.4.1 Implications for Research 466

    16.4.2 Implications for Practitioners 467

    References 467

    17 AI-powered Physical Layer Security in Industrial Wireless Networks 471
    Hong Wen, Qi Wang, and Zhibo Pang

    17.1 Introduction 471

    17.2 Radio Frequency Fingerprint Identification 474

    17.2.1 System Model 474

    17.2.2 Cross-device RFFI 476

    17.2.3 Experimental Investigation 480

    17.3 CSI-based PLA 481

    17.3.1 System Model 482

    17.3.2 Transfer Learning-based PLA 484

    17.3.3 Data Augmentation 488

    17.3.4 Experimental Investigation 490

    17.4 PLK Distribution 493

    17.4.1 System Model 493

    17.4.2 AI-powered Quantization 495

    17.5 Physical Layer Security Enhanced ZT Security Framework 498

    17.5.1 ZT Requirements in IIoT 499

    17.5.2 PLS Enhanced ZT Security Framework 500

    References 502

    18 The Security of Reinforcement Learning Systems in Electric Grid Domain 505
    Suman Rath, Zain ul Abdeen, Olivera Kotevska, Viktor Reshniak, and Vivek Kumar Singh

    18.1 Introduction 505

    18.2 RL for Control 506

    18.2.1 Overview of RL Algorithms 506

    18.2.2 DQN Algorithm 510

    18.3 Case Study: RL for Control in Cyber-physical Microgrids 513

    18.4 Related Work: Grid Applications of RL 516

    18.5 Open Challenges and Solutions 518

    18.6 Conclusion 522

    Acknowledgments 524

    References 524

    19 Geopolitical Dimensions of AI in Cybersecurity: The Emerging Battleground 533
    Felix Staicu and Mihai Barloiu

    19.1 Introduction 533

    19.1.1 A Conceptual Framework 534

    19.2 Foundations of AI in Geopolitics: From Military Origins to Emerging Strategic Trajectories 536

    19.2.1 Historical Foundations: The Military and Intelligence Roots of Key Technologies 536

    19.2.2 Early International Debates on AI Governance and Their Geopolitical Dimensions 537

    19.2.3 The Two-way Influence Between AI and Geopolitics: Early Signals of Strategic Catalysts and Normative Vectors 538

    19.3 The Contemporary Battleground: AI as a Strategic Variable 540

    19.3.1 AI-infused IO: Precision, Persistence, and Policy Dilemmas 540

    19.3.2 Fusion Technologies for Battlefield Control, Unmanned Vehicles, and AI Swarming 542

    19.3.3 Regulatory Power as Soft Power: Competing Models for Global AI Norms 543

    19.3.4 Global Rivalries: The US-China AI Race and the Fragmenting Digital Ecosystem 545

    19.4 Beyond Today's Conflicts: Future Horizons in AI-driven Security 548

    19.4.1 2050 Hypothesis-driven Scenarios in the International System 548

    19.4.2 AI in the Nuclear Quartet 551

    19.4.3 AI in Kinetic Conventional Military Capabilities 553

    19.4.4 AI in Cybersecurity and Information Warfare 554

    19.4.5 A Holistic View of AI's Impact on International Security 556

    19.5 Conclusions and Recommendations 558

    19.5.1 Integrative Insights 558

    19.6 Conclusion 560

    Acknowledgments 561

    References 561

    20 Robust AI Techniques to Support High-consequence Applications in the Cyber Age 567
    Joel Brogan, Linsey Passarella, Mark Adam, Birdy Phathanapirom, Nathan Martindale, Jordan Stomps, Olivera Kotevska, Matthew Yohe, Ryan Tokola, Ryan Kerekes, and Scott Stewart

    20.1 Introduction 567

    20.2 Motivation 568

    20.3 Explainability Measures for Deep Learning in High-consequence Scenarios 570

    20.3.1 Gradient-based Methods 571

    20.3.2 Perturbation-based Methods 572

    20.3.3 Comparisons Between Explainability Methods 572

    20.4 Improving Confidence and Robustness Measures for Deep Learning in Critical Decision-making Scenarios 573

    20.4.1 Introduction 573

    20.4.2 Dataset Description 574

    20.4.3 Methodology 575

    20.4.4 Attribution Algorithms 576

    20.4.5 Confidence Measure Algorithms 576

    20.4.6 Results and Analysis 581

    20.4.7 Discussion and Future Work 581

    20.5 Building Robust AI Through SME Knowledge Embeddings 583

    20.5.1 Explicit Knowledge in Structured Formats 586

    20.5.2 Fine-tuning and Evaluating Foundation Models 587

    20.6 Flight-path Vocabularies for Foundation Model Training 588

    20.6.1 Introduction 588

    20.6.2 Dataset 589

    20.6.3 Methodology 590

    20.6.4 Results and Discussion 591

    20.7 Promise and Peril of Foundation Models in High-consequence Scenarios 592

    20.7.1 Adversarial Vulnerabilities of Foundation Models 593

    20.7.2 Privacy Violation Vulnerabilities in Foundation Models 594

    20.7.3 Alignment Hazards When Training Foundation Models 594

    20.7.4 Performance Hazards When Inferring and Generating with Foundation Models 595

    20.8 Discussion 596

    Acknowledgments 596

    References 596

    Index 601