Machine Unlearning: Principles, Methods, and Evolving Frontiers
Autor Bitan Misra, Sayan Chakraborty, Nilanjan Deyen Limba Engleză Hardback – 10 sep 2026
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Specificații
ISBN-13: 9781041295310
ISBN-10: 1041295316
Pagini: 136
Ilustrații: 20
Dimensiuni: 156 x 234 mm
Ediția:1
Editura: CRC Press
Colecția Chapman and Hall/CRC
ISBN-10: 1041295316
Pagini: 136
Ilustrații: 20
Dimensiuni: 156 x 234 mm
Ediția:1
Editura: CRC Press
Colecția Chapman and Hall/CRC
Public țintă
AcademicCuprins
Preface
Chapter 1
1. Introduction to Machine Unlearning
1.1. Potential Approaches
1.2. Motivation for Unlearning
1.3. Unlearning Framework
1.4. Unlearning requests
1.5. Design Requirements
1.6. Machine unlearning applications
Chapter 2
2. Technological Approaches to Unlearning
2.1. Algorithmic Strategies for Unlearning
2.2. Data Deletion Techniques
2.3. Model Retraining vs. Unlearning
2.4. Naïve Unlearning Approaches
2.4.1. Retraining from Scratch
2.4.2. Model Reset and Data Exclusion
2.5. Approximate Unlearning Methods
2.5.1. Fine-tuning and Gradient Reversal
2.5.2. Knowledge Distillation and Substitution
2.6. Exact Unlearning Methods
Chapter 3
3. Machine Unlearning in GenAI and LLM
3.1 Overview of unlearning challenges in Generative AI and LLMs.
3.2. Unlearning in Generative AI
3.2.1. Retraining from Scratch
3.2.2. Knowledge Distillation
3.2.3. Gradient reversal and model editing
3.3. Unlearning in Large Language Models (LLMs)
3.3.1. Parameter-tuning Approaches
3.3.2. Parameter-Agnostic Methods
3.3.3. LLM Unlearning Taxonomy
3.4. Comparative Insights
Chapter 4
4. Benchmark Datasets and Experimental Frameworks
4.1. Benchmark datasets and experimental frameworks
4.1.1. TOFU
4.1.2. WMDP
4.1.3. CIFAR-10
4.1.4. MNIST
4.1.5. Fashion MNIST
4.1.6. UTKFace
4.1.7. Machine Unlearning for Facial Age Classifier (MUFAC)
4.1.8. Machine Unlearning for Celebrity Attribute Classifier (MUCAC)
4.2. Unlearning-Specific Benchmarks
4.2.1. Machine Unlearning Six-way Evaluation (MUSE)
4.2.2. Real-World Knowledge Unlearning (RWKU)
4.3. Unlearning Efficiency
4.4. Model Utility
4.5. Machine Unlearning Tools and Frameworks
4.5.1. Design requirements
4.5.2. Validation of machine unlearning
4.5.3. Metrics
4.6. Unlearning verification
4.6.1. Feature Injection Test
4.6.2. Forgetting Measuring
4.6.3. Information leakage
4.6.4. Membership inference attacks
4.6.5. Backdoor attacks
4.6.6. Slow-down attacks
4.6.7. Interclass confusion test
4.6.8. Federated verification
4.6.9. Cryptographic proofs
Chapter 5
5. Case Studies in Machine Unlearning
5.1. Unlearning in Healthcare
5.1.1. Unlearning Versus Deskilling
5.1.2. Technical Challenges
5.1.3. Limitations of Machine Unlearning in Healthcare
5.1.4. Unlearning in Digital Healthcare
5.2. Unlearning in Financial Services and Data Retention
5.3. Machine unlearning in social media and user data control
5.3.1. Challenges and Future Directions
5.4. Social Bias Mitigation in Language Models via Machine Unlearning
5.4.1. Machine unlearning techniques
Chapter 6
6. Data Privacy Ethical Implications
6.1. Right to be Forgotten (RTBF)
6.1.1. Reasons behind the increase in RTBF
6.1.2. Issues of LLMs related to Personal Data
6.1.3. The origin and development of the right to be forgotten
6.2. Toward a Multifaceted Strategy
6.3. Recommendations to maintain data privacy
Chapter 7
7. Challenges in Applying RTBF to AI Systems
7.1. Technical challenges
7.2. Conceptual challenges
7.3. Ethical Concerns Related to AI Inferences
7.4. Jurisdictional and cross-border data flows
7.5. Commercial Interests and Data Monetization
7.6. Societal and Cultural Implications
7.7. Stochasticity of training
7.8. Incrementality of training
7.9. Catastrophic unlearning.
7.10. Challenges of Applying RTBF to LLMs
7.11. Computational expense
7.12. Loss of important information
7.13. Lack interpretability
7.14. Enhancing Public Understanding of RTBF and AI
7.15. Balancing Privacy Rights with the Benefits of AI
7.16. Hyperparameter search
7.17. Uncertainty
Chapter 8
8. Conclusions and Future Research Directions
8.1. Future research trajectories
8.1.1. Influence functions are the dominant methods
8.1.2. Reachability of the model parameters
8.1.3. Unlearning verification (Data auditing)
8.1.4. Federated unlearning
8.1.5. Model repair by unlearning
8.1.6. Proposed Changes to the GDPR and CCPA to Better Address the AI Challenge
8.1.7. Unlearning for Diverse Data Structures
8.1.8. Unlearning for Nonconvex Models
8.1.9. User-Specified Granularity of Unlearning
8.1.10. Privacy Assurance for Unlearning
8.1.11. Quantitative evaluation metrics
8.1.12. Adversarial Machine Unlearning
8.1.13. Interpretable Machine Unlearning
8.1.14. Causality in Machine Unlearning
8.1.15. Verifiable Machine Unlearning
8.2. Summary
Chapter 1
1. Introduction to Machine Unlearning
1.1. Potential Approaches
1.2. Motivation for Unlearning
1.3. Unlearning Framework
1.4. Unlearning requests
1.5. Design Requirements
1.6. Machine unlearning applications
Chapter 2
2. Technological Approaches to Unlearning
2.1. Algorithmic Strategies for Unlearning
2.2. Data Deletion Techniques
2.3. Model Retraining vs. Unlearning
2.4. Naïve Unlearning Approaches
2.4.1. Retraining from Scratch
2.4.2. Model Reset and Data Exclusion
2.5. Approximate Unlearning Methods
2.5.1. Fine-tuning and Gradient Reversal
2.5.2. Knowledge Distillation and Substitution
2.6. Exact Unlearning Methods
Chapter 3
3. Machine Unlearning in GenAI and LLM
3.1 Overview of unlearning challenges in Generative AI and LLMs.
3.2. Unlearning in Generative AI
3.2.1. Retraining from Scratch
3.2.2. Knowledge Distillation
3.2.3. Gradient reversal and model editing
3.3. Unlearning in Large Language Models (LLMs)
3.3.1. Parameter-tuning Approaches
3.3.2. Parameter-Agnostic Methods
3.3.3. LLM Unlearning Taxonomy
3.4. Comparative Insights
Chapter 4
4. Benchmark Datasets and Experimental Frameworks
4.1. Benchmark datasets and experimental frameworks
4.1.1. TOFU
4.1.2. WMDP
4.1.3. CIFAR-10
4.1.4. MNIST
4.1.5. Fashion MNIST
4.1.6. UTKFace
4.1.7. Machine Unlearning for Facial Age Classifier (MUFAC)
4.1.8. Machine Unlearning for Celebrity Attribute Classifier (MUCAC)
4.2. Unlearning-Specific Benchmarks
4.2.1. Machine Unlearning Six-way Evaluation (MUSE)
4.2.2. Real-World Knowledge Unlearning (RWKU)
4.3. Unlearning Efficiency
4.4. Model Utility
4.5. Machine Unlearning Tools and Frameworks
4.5.1. Design requirements
4.5.2. Validation of machine unlearning
4.5.3. Metrics
4.6. Unlearning verification
4.6.1. Feature Injection Test
4.6.2. Forgetting Measuring
4.6.3. Information leakage
4.6.4. Membership inference attacks
4.6.5. Backdoor attacks
4.6.6. Slow-down attacks
4.6.7. Interclass confusion test
4.6.8. Federated verification
4.6.9. Cryptographic proofs
Chapter 5
5. Case Studies in Machine Unlearning
5.1. Unlearning in Healthcare
5.1.1. Unlearning Versus Deskilling
5.1.2. Technical Challenges
5.1.3. Limitations of Machine Unlearning in Healthcare
5.1.4. Unlearning in Digital Healthcare
5.2. Unlearning in Financial Services and Data Retention
5.3. Machine unlearning in social media and user data control
5.3.1. Challenges and Future Directions
5.4. Social Bias Mitigation in Language Models via Machine Unlearning
5.4.1. Machine unlearning techniques
Chapter 6
6. Data Privacy Ethical Implications
6.1. Right to be Forgotten (RTBF)
6.1.1. Reasons behind the increase in RTBF
6.1.2. Issues of LLMs related to Personal Data
6.1.3. The origin and development of the right to be forgotten
6.2. Toward a Multifaceted Strategy
6.3. Recommendations to maintain data privacy
Chapter 7
7. Challenges in Applying RTBF to AI Systems
7.1. Technical challenges
7.2. Conceptual challenges
7.3. Ethical Concerns Related to AI Inferences
7.4. Jurisdictional and cross-border data flows
7.5. Commercial Interests and Data Monetization
7.6. Societal and Cultural Implications
7.7. Stochasticity of training
7.8. Incrementality of training
7.9. Catastrophic unlearning.
7.10. Challenges of Applying RTBF to LLMs
7.11. Computational expense
7.12. Loss of important information
7.13. Lack interpretability
7.14. Enhancing Public Understanding of RTBF and AI
7.15. Balancing Privacy Rights with the Benefits of AI
7.16. Hyperparameter search
7.17. Uncertainty
Chapter 8
8. Conclusions and Future Research Directions
8.1. Future research trajectories
8.1.1. Influence functions are the dominant methods
8.1.2. Reachability of the model parameters
8.1.3. Unlearning verification (Data auditing)
8.1.4. Federated unlearning
8.1.5. Model repair by unlearning
8.1.6. Proposed Changes to the GDPR and CCPA to Better Address the AI Challenge
8.1.7. Unlearning for Diverse Data Structures
8.1.8. Unlearning for Nonconvex Models
8.1.9. User-Specified Granularity of Unlearning
8.1.10. Privacy Assurance for Unlearning
8.1.11. Quantitative evaluation metrics
8.1.12. Adversarial Machine Unlearning
8.1.13. Interpretable Machine Unlearning
8.1.14. Causality in Machine Unlearning
8.1.15. Verifiable Machine Unlearning
8.2. Summary
Notă biografică
Bitan Misra is currently working as an Assistant Professor, in Dept. of CSE, Techno International New Town, Kolkata, India. She received her B. Tech and M. Tech dual degree in Electronics and Telecommunication Engineering from KIIT University, Bhubaneswar, India in 2018. She received her Ph.D. in 2022 from National Institute of Technology, Durgapur, India. She has published almost 40 research papers in various international journals and conferences and is the author of 5 books. Her main research interests include optimization techniques, deep learning, evolutionary algorithms and soft computing techniques. She has worked as a reviewer in several national and international journals and conferences. She is an Associate Editor of International Journal of Ambient Computing and Intelligence, IGI Global. She is a member of IEEE and Internet Society.
Sayan Chakraborty is currently working as a Assistant Professor in the Department of Computer Science and Engineering at the Techno International New Town, West Bengal, India. He has completed his Ph.D. in Image registration from Sikkim Manipal University in the year 2023. He has completed M.Tech from Computer Science & Engineering, JIS College of Engineering. He also completed his B. Tech. from the same college. He has academic experience of 10 years. His research area includes digital image processing, nature inspired algorithms and machine learning. He has about 65 research papers published in international journals, book chapters and conferences on various topics such as optimization, artificial intelligence, pattern recognition and digital image processing. He has 1 book published in Springer. He is an Associate Editor of International Journal of Ambient Computing and Intelligence, IGI Global and Editorial Board member of International Journal of Rough Sets and Data Analysis (IJRSDA) , IGI Global. He is a senior member of IEEE.
Nilanjan Dey (Senior Member, IEEE) received the B.Tech. and M.Tech. in information technology from West Bengal Board of Technical University and the Ph.D. in electronics and telecommunication engineering from Jadavpur University, Kolkata, India, in 2005, 2011, and 2015. Currently, he is a professor with Techno International New Town, Kolkata, and a visiting fellow of the University of Reading, UK. He is the Editor-in-Chief of the International Journal of Ambient Computing and Intelligence, Associate Editor of IEEE Transactions on Technology and Society, and series Co-Editor of Springer Tracts in Nature-Inspired Computing and Data-Intensive Research (Springer Nature) and Advances in Ubiquitous Sensing Applications for Healthcare (Elsevier). He is also on the Editorial Board of IEEE Data Descriptions. He is a Fellow of IETE and member of IE, ISOC, etc.
Sayan Chakraborty is currently working as a Assistant Professor in the Department of Computer Science and Engineering at the Techno International New Town, West Bengal, India. He has completed his Ph.D. in Image registration from Sikkim Manipal University in the year 2023. He has completed M.Tech from Computer Science & Engineering, JIS College of Engineering. He also completed his B. Tech. from the same college. He has academic experience of 10 years. His research area includes digital image processing, nature inspired algorithms and machine learning. He has about 65 research papers published in international journals, book chapters and conferences on various topics such as optimization, artificial intelligence, pattern recognition and digital image processing. He has 1 book published in Springer. He is an Associate Editor of International Journal of Ambient Computing and Intelligence, IGI Global and Editorial Board member of International Journal of Rough Sets and Data Analysis (IJRSDA) , IGI Global. He is a senior member of IEEE.
Nilanjan Dey (Senior Member, IEEE) received the B.Tech. and M.Tech. in information technology from West Bengal Board of Technical University and the Ph.D. in electronics and telecommunication engineering from Jadavpur University, Kolkata, India, in 2005, 2011, and 2015. Currently, he is a professor with Techno International New Town, Kolkata, and a visiting fellow of the University of Reading, UK. He is the Editor-in-Chief of the International Journal of Ambient Computing and Intelligence, Associate Editor of IEEE Transactions on Technology and Society, and series Co-Editor of Springer Tracts in Nature-Inspired Computing and Data-Intensive Research (Springer Nature) and Advances in Ubiquitous Sensing Applications for Healthcare (Elsevier). He is also on the Editorial Board of IEEE Data Descriptions. He is a Fellow of IETE and member of IE, ISOC, etc.
Descriere
This book explores machine unlearning, a vital AI field for selectively removing learned data from models. Covering advanced techniques, real-world case studies, and ethical considerations like GDPR compliance, it equips readers to implement responsible AI systems while addressing data privacy and societal challenges.