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Full Description
Engineering the Future: Multi-Objective Optimization in Earthquake Resilience and Design develops a rigorous, decision-oriented treatment of performance-based earthquake engineering (PBEE) by placing multi-objective optimization (MOO) at the centre of modern seismic design and risk management. Moving beyond prescriptive "one-size-fits-all" compliance, the book frames seismic design as an explicit trade-off problem in which safety, functionality, downtime, repair cost, and sustainability targets must be satisfied simultaneously under uncertainty. It consolidates foundational concepts and current practice, then advances toward implementation pathways that connect hazard characterization, structural response assessment, damage and loss modelling, and stakeholder-informed performance objectives within a coherent PBEE-MOO workflow.
The book integrates technical methods with practice-facing considerations, including regulatory frameworks, governance and policy instruments, socio-economic consequences, and community resilience. It also surveys emerging computational capabilities, including advanced simulation and data-driven tools, and demonstrates their role in accelerating design-space exploration and improving transparency in decision-making. Case-based discussions across multiple structural systems illustrate how optimization can support defensible choices for new design, retrofit prioritization, and lifecycle resilience planning in earthquake-prone regions.
This book targets structural and earthquake engineers, seismic risk analysts, and engineering researchers who seek to advance beyond traditional code-based design approaches by implementing sophisticated multi-objective optimization methods for performance-based earthquake engineering in both academic research and professional practice.
Contents
1. Foundations and Scope of Performance-Based Earthquake Engineering and Multi-Objective Decision-Making 2. From Prescriptive Codes to PBEE: Evolution, Standards, and Computational Enablers 3. Seismic Performance Assessment of Building Systems: Hazards, Metrics, and Methods 4. Codes, Standards, and Legal Governance in Seismic Risk and Design 5. Public Policy, Risk Communication, and Community Participation in Earthquake Resilience 6. Contemporary Advances in PBEE: Probabilistic Methods, Metrics, and Performance Targets 7. PBEE in Practice Across Structural Systems: Concrete, Steel, and Braced Buildings 8. Multi-Objective Optimization for Seismic Resilience: Formulations, Algorithms, and Decision Support 9. Open Challenges and Research Priorities in PBEE and Multi-Objective Resilience Design 10. Implementation Pathways and International Case Studies in PBEE-MOO 11. Education, Competency, and Professional Practice for PBEE and Optimization-Based Design 12. Socio-Economic Dimensions of PBEE: Finance, Insurance, Equity, and Sustainable Development 13. Emerging Technologies for Seismic Resilience: Advanced Materials, AI, and Monitoring 14. Global Collaboration, Standardization, and Policy Coordination for Seismic Resilience 15. Strategic Roadmap for PBEE-MOO: Innovation, Climate Adaptation, and Stakeholder Action
