Napoli : Università degli studi di Napoli "Federico II", 1997-1998

66 p. ; 30 cm

DMEPE

1997-1998 Coraggio

Italiano

Washington, D.C. : , : U.S. Department of Transportation, Federal Highway Administration, Office of Safety, , July 2007

1 online resource (xi, 158 pages) : illustrations

Roads - Design and construction

Traffic safety

Inglese

"July 2007."

"FHWA-SA-07-011"--Technical report documentation page.

"Author(s): William J. Stein and Timothy R. Neuman"--Technical report documentation page.

"Performing organization: CH2M HILL, Inc."--Technical report documentation page.

"FHWA/HSSD"--Technical report documentation page.

Includes bibliographical references (pages 157-158).

Newark : , : John Wiley & Sons, Incorporated, , 2024

©2024

1-119-91141-9

1-119-91142-7

1-119-91140-0

1 online resource (238 pages)

OtiAkponanabofa Henry

Inglese

Cover -- Title Page -- Copyright -- Brief Contents -- Contents -- About the Authors -- Foreword -- Acknowledgements -- 1: The Smart Estate: Collaborative Working with Digital Information Management -- 1.1 Introduction to the Book -- 1.2 Context and Background to Collaborative Working in Estates and Construction -- 1.3 The Importance of Digital Information Management to Assist Collaborative Working -- 1.4 Structure of the Book -- 1.5 Summary -- References -- 2: Introduction and Background to Collaborative Working and Partnering -- 2.1 Introduction -- 2.2 Background to the Concept of Collaborative Working and Partnering -- 2.3 What is Partnering, Collaborative Working, and Alliancing? -- 2.4 The Traditional Adversarial Nature of the Construction Industry -- 2.5 Perfection through Procurement -- 2.6 Different Types and Variations of Collaborative Working -- 2.7 The Importance of Trust within the Context of Collaboration -- 2.7.1 Trust as a Collaborative Necessity -- 2.7.2 What Do We Mean by Trust in the Context of Collaboration and Partnering? -- 2.8 Summary -- References -- 3: The Importance of Trust, Collaboration, and Partnering for the Built Environment -- 3.1 Introduction -- 3.2 Potential Benefits and Incentives to Trust -- 3.3

Trust as a Collaborative Necessity in Benefitting Construction Partnering -- 3.4 The Importance of Trust in Partnering and Collaborative Working -- 3.5 Providing the Right Environment for Trust in Partnering -- Possible Trust-building Mechanisms -- 3.6 Successful Outcomes Brought about by Partnering and Collaborative Working -- 3.6.1 Construction Cost Predictability, Value for Money, and Client Risk -- 3.6.2 Early Integration of Main Contractors and Subcontractors into the Project Team -- 3.6.3 Programme Timescales and Quality Control.

3.7 Suitability of Partnering and Collaborative Working to Different Types of Building Project -- Complexity and Specialism -- 3.8 The Importance of the Contractor Selection Process and Appointing a Trustworthy Partner -- 3.9 Summary -- References -- 4: Analysis for the Lack of Collaborative Working and Partnering in the Built Environment -- 4.1 Introduction -- 4.2 Context for the Lack of Collaborative Working and Partnering -- 4.3 Possible Move from Partnering Philosophies Back to Traditional Procurement Practices -- 4.4 Opportunities for Unethical Practices under Partnering Arrangements -- 4.5 The Influence of Economic Uncertainty on Partnering and Collaborative Working -- 4.6 Suspicion and Scepticism of Realisable Benefits from Partnering and Collaborative Working -- 4.7 The Effects of a Downturn in the Economic Climate on Partnering and Collaborative Working -- 4.8 Summary -- References -- 5: Potential Risks, Problems, and Barriers for Collaborative Working in Estates and the Built Environment -- 5.1 Introduction -- 5.2 Challenges for Developing Trust in Construction Partnering -- 5.3 Potential Barriers to Collaborative Working and Partnering -- 5.4 Further Potential Problems for Collaborative Procurement -- 5.5 Factors Which Could Inhibit Trust in Partnering -- 5.6 Challenging the Philosophy of Collaboration -- 5.7 Collaboration in Practice -- 5.8 Summary -- References -- 6: Collaborative Working with Digital Information Management in Estates and Construction -- 6.1 Introduction -- 6.2 Definition and Scope of Digital Information Management in Construction -- 6.3 The Origin and Development of Digital Information Management -- 6.4 Digital Information Management Requirements -- 6.4.1 Generality -- 6.4.2 Formality -- 6.4.3 Flexibility -- 6.4.4 Ease-of-Use -- 6.4.5 Scalability -- 6.4.6 Time Efficiency.

6.5 Trends and Innovations in Digital Information Management -- 6.6 Summary -- References -- 7: Technologies for Collaborative Digital Information Management in Estates and Construction -- 7.1 Introduction -- 7.2 Technologies Featuring in the Digital Transformation of Estates -- 7.3 The Uptake of Digital Technologies in Estates -- 7.3.1 Digital Transformation in FM Hard Services -- 7.3.2 Digital Transformation in FM Soft Services -- 7.4 Factors Affecting Adoption of Digital Technology Applications in Estates -- 7.5 Summary -- References -- 8: Infrastructures for Collaborative Digital Information Management for Estates -- 8.1 Introduction -- 8.2 Elements of Digital Transformation Infrastructure -- 8.3 Digital Transformation Processes in Estates -- 8.3.1 FM in Relation to Buildings, People, Services, and Resources -- 8.3.2 Asset Management: Buildings, Plant, and Equipment -- 8.3.3 Property and Space Management -- 8.3.4 Flexible Workspace and Hot-Desk Management -- 8.3.5 Resource Management -- 8.3.6 Environmental Management and Control -- 8.4 Aspects and Tools of Data Acquisition Aiding Digital Transformation -- 8.5 Digital Information Management Cases in Healthcare Facilities -- 8.5.1 Peterborough Hospital - Computer-Aided Facilities Management (CAFM) System for Service Desk and Hard FM Delivery (Case Study 1 -- Case Study 1 -- 8.5.2 Implementation of a Comprehensive FM Software Solution for Reactive and Planned Maintenance in an Educational Facility

(Case Study 2 -- Case Study 2 -- References -- 9: Actors in Digital Information Management for Estates -- 9.1 Introduction -- 9.2 Key Actors in Digital Information Management and Transformation -- 9.3 Actors and Professional Institutions in Estates Digital Information Management -- 9.4 Emerging Roles in Estates Digital Information Management -- 9.4.1 Asset Data Exploitation Technician.

9.4.2 Data Quality Controller in Computer-Aided Facilities Management (CAFM) -- 9.4.3 Document Controller -- 9.4.4 Energy Solutions Manager -- 9.5 Digital Information Management Case in an Educational Institution -- 9.5.1 Implementation of a Software Solution for Controlling Maintenance and Asset Reliability at the National Oceanography Centre (Case Study 3 -- Case Study 3 -- References -- 10: The Role of Digital Technology in Healthcare Facilities Management -- 10.1 Introduction -- 10.2 The Advancement of Digital Technology in Healthcare Facilities Management (FM) -- 10.3 Digital Technologies within Healthcare Facilities Management (FM) -- 10.4 Geographic Information Systems (GIS) -- 10.5 The Internet of Things (IoT)) -- 10.6 Mobile-First -- 10.7 Machine Learning and Predictive Analytics -- 10.8 Building Information Modelling (BIM) -- 10.9 Conclusions -- 10.10 Summary -- References -- 11: An Introduction to Smart Estates and Digital Information Management for Collaboration in the Built Environment Using Case Studies -- 11.1 Introduction -- 11.2 The Digital Revolution -- 11.3 Information Management Framework -- 11.4 Background and Context to Digital Twins -- 11.4.1 Description of a Digital Twin -- 11.4.2 The Digital Twin Concept -- 11.4.3 The Evolution of Digital Twins -- 11.5 Digital Twins, the Built Environment, and Urbanisation -- 11.5.1 The Importance of the Built Environment and Urbanisation on a Global Scale -- 11.5.2 Challenges around the Built Environment -- 11.6 The Use of Digital Twins in the Built Environment -- 11.6.1 Digital Urban Twins as a Collaborative Tool for Smart Cities -- 11.6.2 Digital Twins in Urban Modelling and Planning -- 11.6.3 Real-Time Monitoring and Control of Urban Transport Infrastructure -- 11.6.4 Future Mobility -- 11.6.5 Sustainability Using the Case Study of Singapore -- 11.6.6 Scenario and Risk Assessments.

11.6.7 Security -- 11.6.8 Health and Well-Being -- 11.6.9 Efficiency and Streamlined Information Workflows in Capital Delivery -- 11.6.10 Streamlined Asset Operations -- 11.6.11 Building Automation -- 11.6.12 Predictive Maintenance -- 11.6.13 Remote Assistance Technology -- 11.6.14 Research and Development -- 11.7 Summary -- References -- 12: The Benefits and Value of Digital Twin Technologies for Collaborative Information Management -- 12.1 Introduction -- 12.2 Improvement to the Quality of Life -- 12.3 Creation of Value -- 12.4 Collaborative Insights -- 12.5 Optimisation of Urban Planning and City Science -- 12.6 Monitoring and Control of Scenarios in Real Time -- 12.7 Scenario Planning and Risk Assessments -- 12.8 Predictive Analytics and Scheduling -- 12.9 More Effective and Informed Support System for DecisionMaking -- 12.10 Better Synergies in Intra- and Inter-Team Collaboration -- 12.11 Optimisation of Asset Performance and Sustainability -- 12.12 Greater Efficiency in Safety -- 12.13 The Ecosystem of Connected Networks, Portfolios, and Sectors -- 12.14 Summary -- References -- 13: Digital Twin Enablers for Collaboration and the Risks and Barriers to Adoption of Digital Twins -- 13.1 Introduction -- 13.2 Enabling Technologies for the Urban Digital Twin -- 13.2.1 Building Information Modelling (BIM) -- 13.2.2 The Internet of Things (IoT) -- 13.2.3 Big Data -- 13.2.4 Cloud Computing and Data Analytics -- 13.2.5 3D and 5G Modelling and High-Definition Simulations -- 13.2.6 Artificial Intelligence (AI) -- 13.2.7 Digital Twin Ecosystems -- 13.2.8 Smart Buildings -- 13.2.9 Smart Cities -- 13.3

The Current State of Adoption and Development of Digital Twins -- 13.3.1 The Digital Twin Market Outlook -- 13.3.2 Global Digital Twin Uptake Outlook -- 13.3.3 Digital Twin Information Framework -- 13.4 Risks and Barriers to Adoption of Digital Twins.

13.4.1 Introduction to the Risks and Barriers.

Cambridge ; ; New York, : Cambridge University Press, 2005

1-107-15217-8

1-107-38608-X

1-139-00709-2

0-511-20145-1

1-280-91756-3

9786610917563

0-511-29696-7

0-511-13613-7

0-511-13723-0

0-511-54606-8

0-511-13506-8

1 online resource (xix, 454 pages) : digital, PDF file(s)

623.8/1231

Motorboats

Ships - Hydrodynamics

Hydrodynamics

Hydrofoil boats

Inglese

Title from publisher's bibliographic system (viewed on 05 Oct 2015).

Includes bibliographical references (p. 437-449) and index.

Cover; Half-title; Title; Copyright; Contents; Preface; List of symbols; 1 Introduction; 2 Resistance and Propulsion; 3 Waves; 4 Wave Resistance and Wash; 5 Surface Effect Ships; 6 Hydrofoil Vessels and Foil Theory; 7

Semi-displacement Vessels; 8 Slamming, Whipping, and Springing; 9 Planing Vessels; 10 Maneuvering; Appendix: Units of Measurement and Physical Constants; References; Index

Hydrodynamics of High-Speed Marine Vehicles, first published in 2006, discusses the three main categories of high-speed marine vehicles - vessels supported by submerged hulls, air cushions or foils. The wave environment, resistance, propulsion, seakeeping, sea loads and manoeuvring are extensively covered based on rational and simplified methods. Links to automatic control and structural mechanics are emphasized. A detailed description of waterjet propulsion is given and the effect of water depth on wash, resistance, sinkage and trim is discussed. Chapter topics include resistance and wash; slamming; air cushion-supported vessels, including a detailed discussion of wave-excited resonant oscillations in air cushion; and hydrofoil vessels. The book contains numerous illustrations, examples and exercises.