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200 10$aAcoustic and Elastic Waves $eRecent Trends in Science and Engineering /$fDimitrios G. Aggelis, Nathalie Godin
210  1$aBasel ; Beijing ; Wuhan ; Barcelona ; Belgrade :$cMDPI - Multidisciplinary Digital Publishing Institute,$d2017.
215   $a1 online resource (xv, 445 pages)
311   $a3-03842-297-5 
327   $aList of Contributors -- About the Guest Editors -- Preface to "Acoustic and Elastic Waves: Recent Trends in Science and Engineering" -- The Ultrasonic Polar Scan for Composite Characterization and Damage Assessment: Past, Present and Future -- Dispersion of Functionalized Silica Micro- and Nanoparticles into Poly(nonamethylene Azelate) by Ultrasonic Micro-Molding -- Enhancement of Spatial Resolution Using a Metamaterial Sensor in Nondestructive Evaluation -- Monitoring Techniques of Cerium Stabilized Zirconia for Medical Prosthesis -- Correlation between Earthquakes and AE Monitoring of Historical Buildings in Seismic Areas -- Electromagnetic Acoustic Transducers Applied to High Temperature Plates for Potential Use in the Solar Thermal Industry -- Acoustic Emission Activity for Characterizing Fracture of Marble under Bending -- Lamb Wave Interaction with Adhesively Bonded Stiffeners and Disbonds Using 3D Vibrometry -- Proof of Concept of Crack Localization Using Negative Pressure Waves in Closed Tubes for Later Application in Effective SHM System for Additive Manufactured Components -- Identification of a Critical Time with Acoustic Emission Monitoring during Static Fatigue Tests on Ceramic Matrix Composites: Towards Lifetime Prediction -- Wavelet Packet Decomposition to Characterize Injection Molding Tool Damage -- Dynamic Characterization of Cohesive Material Based on Wave Velocity Measurements -- Design of a Stability Augmentation System for an Unmanned Helicopter Based on Adaptive Control Techniques -- Numerical and Experimental Characterization of Fiber-Reinforced Thermoplastic Composite Structures with Embedded Piezoelectric Sensor-Actuator Arrays for Ultrasonic Applications -- Acoustic Emissions to Measure Drought-Induced Cavitation in Plants -- The Stiffness and Damping Characteristics of a Dual-Chamber Air Spring Device Applied to Motion Suppression of Marine Structures -- Correlation of Plastic Strain Energy and Acoustic Emission Energy in Reinforced Concrete Structures -- Numerical Models for the Assessment of Historical Masonry Structures and Materials, Monitored by Acoustic Emission -- Detecting the Presence of High Water-to-Cement Ratio in Concrete Surfaces Using Highly Nonlinear Solitary Waves -- Opto-Acoustic Method for the Characterization of Thin-Film Adhesion -- On Site Investigation and Health Monitoring of a Historic Tower in Mantua, Italy.
330   $aThe present Special Issue intends to explore new directions in the field of acoustics and ultrasonics. The interest includes, but is not limited to, the use of acoustic technology for condition monitoring of materials and structures.Topics of interest (among others):{u2022} Acoustic emission in materials and structures (without material limitation){u2022} Innovative cases of ultrasonic inspection{u2022} Wave dispersion and waveguides{u2022} Monitoring of innovative materials{u2022} Seismic waves{u2022} Vibrations, damping and noise control{u2022} Combination of mechanical wave techniques with other types for structural health monitoring purposes. Experimental and numerical studies are welcome.
517   $aAcoustic and Elastic Waves
606   $aElastic wave propagation
606   $aAcoustical materials
615  0$aElastic wave propagation.
615  0$aAcoustical materials.
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200 10$aMission AI $eThe New System Technology /$fby Haroon Sheikh, Corien Prins, Erik Schrijvers
205   $a1st ed. 2023.
210  1$aCham :$cSpringer International Publishing :$cImprint: Springer,$d2023.
215   $a1 online resource (421 pages)
225 1 $aResearch for Policy, Studies by the Netherlands Scientific Council for Government Policy,$x2662-3692
311 08$a3-031-21447-1 
327   $aPart I Building blocks: introducing and interpreting AI as a new system technology, similar to electricity and the internal combustion engine -- Introduction -- Chapter 1 Artificial Intelligence: definition and background -- Chapter 2 AI is leaving the lab and entering society -- Chapter 3 AI as a system technology -- Part II Five tasks: discussion of the tasks for embedding AI into society -- Chapter 4 Demystification -- Chapter 5 Contextualization -- Chapter 6 Engagement -- Chapter 7 Regulation -- Chapter 8 Consider AI as a system technology -- Part III Agenda: conclusions and recommendations for AI policy in the Netherlands -- Chapter 9 Policy for AI as a system technology -- Appendix: Examples of AI applications in the Netherlands -- Terms and definitions -- Keywords -- Bibliography.
330   $aThis open access book offers a strategic perspective on AI and the process of embedding it in society. After decades of research, Artificial Intelligence (AI) is now entering society at large. Due to its general purpose character, AI will change society in multiple, fundamental and unpredictable ways. Therefore, the Netherlands Scienti?c Council for Government Policy (WRR) characterizes AI as a system technology: a rare type of technologies that have a systemic impact on society. Earlier system technologies include electricity, the combustion engine and the computer. The history of these technologies provides us with useful insights about what it takes to direct the introduction of AI in society. The WRR identifies five key tasks to structurally work on this process: demystification, contextualisation, engagement, regulation and positioning. By clarifying what AI is (demystification), creating a functional ecosystem (contextualisation), involving diverse stakeholders (engagement), developing directive frameworks (regulation) and engaging internationally (positioning), societies can meaningfully influence how AI settles. Collectively, these activities steer the process of co-development between technology and society, and each representing a different path to safeguard public values. Mission AI - The New System Technology was originally published as an advisory report for the government of the Netherlands. The strategic analysis and the outlined recommendations are, however, relevant to every government and organization that aims to take up 'misson AI' and embed this newest system technology in our world.
410  0$aResearch for Policy, Studies by the Netherlands Scientific Council for Government Policy,$x2662-3692
606   $aTechnology$xSociological aspects
606   $aArtificial intelligence
606   $aScience, Technology and Society
606   $aArtificial Intelligence
615  0$aTechnology$xSociological aspects.
615  0$aArtificial intelligence.
615 14$aScience, Technology and Society.
615 24$aArtificial Intelligence.
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701   $aPrins$b Corien$049945
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