LEADER 10716nam 2200469 450 001 9910830877503321 005 20230329094737.0 010 $a1-119-84231-X 010 $a1-119-84230-1 035 $a(MiAaPQ)EBC7135410 035 $a(Au-PeEL)EBL7135410 035 $a(CKB)25315240700041 035 $a(EXLCZ)9925315240700041 100 $a20230329d2023 uy 0 101 0 $aeng 135 $aurcnu|||||||| 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 00$aDigital twin technology $efundamentals and applications /$fedited by Manisha Vohra 210 1$aHoboken, New Jersey :$cWiley-Scrivener,$d[2023] 210 4$dİ2023 215 $a1 online resource (273 pages) 311 08$aPrint version: Vohra, Manisha Digital Twin Technology Newark : John Wiley & Sons, Incorporated,c2022 9781119842200 320 $aIncludes bibliographical references and index. 327 $aCover -- Title Page -- Copyright Page -- Contents -- Preface -- Chapter 1 Overview of Digital Twin -- 1.1 A Simplistic Introduction to Digital Twin -- 1.2 Basic Definition and Explanation of What is Digital Twin -- 1.3 The History of Digital Twin -- 1.4 Working -- 1.5 Features -- 1.5.1 Replication of Each and Every Aspect of the Original Device or Product -- 1.5.2 Helps in Product Lifecycle Management -- 1.5.3 Digital Twin can Prevent Downtime -- 1.6 Advantages of Digital Twin -- 1.6.1 Digital Twin is Helpful in Preventing Issues or Errors in the Actual Object, Product or Process -- 1.6.2 Helps in Well Utilization of Resources -- 1.6.3 Keeping Vigilance of the Actual Object, Product or Process Through Digital Twin is Possible -- 1.6.4 Helps in Efficient Handling and Managing of Objects, Device, Equipment, etc. -- 1.6.5 Reduction in Overall Cost of Manufacturing of Objects, Products, etc. -- 1.7 Applications -- 1.8 A Simple Example of Digital Twin Application -- 1.9 Digital Twin Technology and the Metaverse -- 1.10 Challenges -- 1.10.1 Careful Handling of Different Factors Involved in Digital Twin -- 1.10.2 Expertise Required -- 1.10.3 Data Security and Privacy -- 1.11 Conclusion -- References -- Chapter 2 Introduction, History, and Concept of Digital Twin -- 2.1 Introduction -- 2.2 History of Digital Twin -- 2.3 Concept of Digital Twin -- 2.3.1 DTP -- 2.3.2 DTI -- 2.3.3 DTE -- 2.3.4 Conceptualization -- 2.3.5 Comparison -- 2.3.6 Collaboration -- 2.4 Working Principle -- 2.5 Characteristics of Digital Twin -- 2.5.1 Homogenization -- 2.5.2 Digital Trail -- 2.5.3 Connectivity -- 2.6 Advantages -- 2.6.1 Companies Can Benefit From Digital Twin by Tracking Performance-Related Data -- 2.6.2 Different Sector's Progress Can Be Accelerated -- 2.6.3 Digital Twins Can Be Used for Various Application -- 2.6.4 Digital Twin Can Help Decide Future Course of Work. 327 $a2.6.5 Manufacturing Work Can Be Monitored -- 2.7 Limitations -- 2.7.1 Data Transmission Could Have Delays and Distortions -- 2.7.2 Digital Twin Implementation Will Need Required Skills and Sound Knowledge About It -- 2.8 Example of Digital Twin Application -- 2.8.1 Digital Twin Application in General Electric (GE) Renewable Energy -- 2.9 Conclusion -- References -- Chapter 3 An Insight to Digital Twin -- 3.1 Introduction -- 3.2 Understanding Digital Twin -- 3.3 Digital Twin History -- 3.4 Essential Aspects From Working Perspectives of Digital Twin -- 3.5 How Does a Digital Twin Work? -- 3.6 Insights to Digital Twin Technology Concept -- 3.6.1 Parts Twins -- 3.6.2 Product Twins -- 3.6.3 System Twins -- 3.6.4 Process Twins -- 3.7 Types of Digital Twin -- 3.7.1 Digital Twin Prototype (DTP) -- 3.7.2 Digital Twin Instance (DTI) -- 3.7.3 Digital Twin Environment (DTE) -- 3.8 Traits of Digital Twin -- 3.8.1 Look Same as the Original Object -- 3.8.2 Consists Different Details of the Original Object -- 3.8.3 Behaves Same as the Original Object -- 3.8.4 Can Predict and Inform in Advance About Problems That Could Occur -- 3.9 Value of Digital Twin -- 3.10 Advantages of Digital Twin -- 3.11 Real-World Examples of Use of Digital Twin -- 3.12 Conclusion -- References -- Chapter 4 Digital Twin Solution Architecture -- 4.1 Introduction -- 4.2 Previous Work -- 4.2.1 How This Work Differs -- 4.3 Use Cases -- 4.4 Architecture Considerations -- 4.5 Understanding the Physical Object -- 4.5.1 Modeling Considerations -- 4.6 Digital Twin and IoT -- 4.7 Digital Twin Solution Architecture -- 4.7.1 Conceptual Digital Twin Solution Architecture -- 4.7.2 Infrastructure Platform and IoT Services -- 4.7.3 Digital Twin Data and Process Model -- 4.7.4 Digital Twin Services -- 4.7.5 Digital Twin Applications -- 4.7.6 Sample Basic Data Flow through Digital Twin. 327 $a4.7.7 Sample Data Flow for Exception Handling -- 4.7.8 Sample Data Flow through Digital Twin Applications -- 4.7.9 Development Considerations -- 4.8 Database Considerations -- 4.9 Messaging -- 4.10 Interfaces -- 4.11 User Experience -- 4.12 Cyber Security -- 4.13 Use Case Coverage -- 4.14 Future Direction and Trends -- 4.15 Conclusion -- References -- Chapter 5 Role of Digital Twin Technology in Medical Sector-Toward Ensuring Safe Healthcare -- 5.1 Introduction to Digital Twin -- 5.2 Generic Applications of Digital Twin -- 5.3 Digital Twin Applications in Medical Field -- 5.3.1 Biosignal and Physiological Parameters Analysis for Body Area Network -- 5.3.2 Medicinal Drug Delivery -- 5.3.3 Surgical Preplanning -- 5.3.4 COVID 19 Screening and Diagnosis -- 5.4 Ongoing and Future Applications of Digital Twin in Healthcare Sector -- 5.5 Conclusion -- Acknowledgments -- References -- Chapter 6 Digital Twin as a Revamping Tool for Construction Industry -- 6.1 Introduction -- 6.2 Introduction to Digital Twin -- 6.3 Overview of Digital Twin in Construction -- 6.4 The Perks of Digital Twin -- 6.5 The Evolution of Digital Twin -- 6.6 Application of Digital Twin Technology in Construction Industry -- 6.7 Digital Twins Application for Construction Working Personnel Safety -- 6.8 Digital Twin Applications in Smart City Construction -- 6.9 Discussion -- 6.10 Conclusion -- References -- Chapter 7 Digital Twin Applications and Challenges in Healthcare -- 7.1 Introduction -- 7.2 Digital Twin -- 7.3 Applications of Digital Twin -- 7.3.1 Smart Cities -- 7.3.2 Manufacturing Sector -- 7.3.3 Healthcare -- 7.3.4 Aviation -- 7.3.5 The Disney Park -- 7.4 Challenges with Digital Twin -- 7.5 Digital Twin in Healthcare -- 7.5.1 Digital Twin for Hospital Workflow Management -- 7.5.2 Digital Twin for a Healthcare Facility. 327 $a7.5.3 Digital Twin for Different Medical Product Manufacturing -- 7.5.4 Cardiovascular Digital Twin -- 7.5.5 Digital Twin Utilization for Supporting Personalized Treatment -- 7.5.6 Digital Twin for Multiple Sclerosis (MS) -- 7.6 Digital Twin Challenges in Healthcare -- 7.6.1 Need of Training and Knowledge -- 7.6.2 Cost Factor -- 7.6.3 Trust Factor -- 7.7 Conclusion -- References -- Chapter 8 Monitoring Structural Health Using Digital Twin -- 8.1 Introduction -- 8.1.1 Digital Twin-The Approach and Uses -- 8.2 Structural Health Monitoring Systems (SHMS) -- 8.2.1 Criticality and Need for SHMS Approach -- 8.2.2 Passive and Active SHMS -- 8.3 Sensor Technology, Digital Twin (DT) and Structural Health Monitoring Systems (SHMS) -- 8.4 Conclusion -- References -- Chapter 9 Role and Advantages of Digital Twin in Oil and Gas Industry -- 9.1 Introduction -- 9.2 Digital Twin -- 9.3 Evolution of Digital Twin Technology -- 9.4 Various Digital Twins that Can Be Built -- 9.4.1 Parts Twins -- 9.4.2 Product Twins or Asset Twins -- 9.4.3 System Twins or Unit Twins -- 9.4.4 Process Twins -- 9.5 Advantage of Digital Twin -- 9.5.1 Paced Prototypin -- 9.5.2 Prediction -- 9.5.3 Enhanced Maintenance -- 9.5.4 Monitoring -- 9.5.5 Safety -- 9.5.6 Reduced Waste -- 9.6 Applications of Digital Twin -- 9.6.1 Aerospace -- 9.6.2 Power-Generation Equipment -- 9.6.3 Structures and Their Systems -- 9.6.4 Manufacturing Operations -- 9.6.5 Healthcare Services -- 9.6.6 Automotive Industry -- 9.6.7 Urban Planning and Construction -- 9.6.8 Smart Cities -- 9.6.9 Industrial Applications -- 9.7 Characteristics of Digital Twin -- 9.7.1 High-Fidelity -- 9.7.2 Lively -- 9.7.3 Multidisciplinary -- 9.7.4 Homogenization -- 9.7.5 Digital Footprint -- 9.8 Digital Twin in Oil and Gas Industry -- 9.9 Role of Digital Twin in the Various Areas of Oil and Gas Industry -- 9.9.1 Planning of Drilling Process. 327 $a9.9.2 Performance Monitoring of Oil Field -- 9.9.3 Data Analytics and Simulation for Oil Field Production -- 9.9.4 Improving Field Personnel and Workforce Safety -- 9.9.5 Predictive Maintenance -- 9.10 The Advantages of Digital Twin in the Oil and Gas Industry -- 9.10.1 Production Efficacy -- 9.10.2 Preemptive Maintenance -- 9.10.3 Scenario Development -- 9.10.4 Different Processes Monitoring -- 9.10.5 Compliance Criteria -- 9.10.6 Cost Savings -- 9.10.7 Workplace Safety -- 9.11 Conclusion -- References -- Chapter 10 Digital Twin in Smart Cities: Application and Benefits -- 10.1 Introduction -- 10.2 Introduction of Digital Twin in Smart Cities -- 10.3 Applications of Digital Twin in Smart Cities -- 10.3.1 Traffic Management -- 10.3.2 Construction -- 10.3.3 Structural Health Monitoring -- 10.3.4 Healthcare -- 10.3.5 Digital Twin for Drainage System -- 10.3.6 Digital Twin for Power Grid -- 10.4 Conclusion -- References -- Chapter 11 Digital Twin in Pharmaceutical Industry -- 11.1 Introduction -- 11.2 What is Digital Twin? -- 11.2.1 Digital Twin Prototype (DTP) -- 11.2.2 Digital Twin Instance -- 11.2.3 Parts Twins -- 11.2.4 Product Twins -- 11.2.5 System Twins -- 11.2.6 Process Twins -- 11.3 Digital Twin in the Pharmaceutical Industry -- 11.4 Digital Twin Applications in Pharmaceutical Industry -- 11.4.1 Digital Twin of the Pharmaceutical Manufacturing Process -- 11.4.2 Digital Twin for Pharmaceutical Supply Chains -- 11.5 Examples of Use of Digital Twin in Pharmaceutical Industry -- 11.5.1 Digital Twin Simulator for Supporting Scientific Exchange of Views With Expert Physicians -- 11.5.2 Digital Twin for Medical Products -- 11.5.3 Digital Twin for Pharmaceutical Companies -- 11.6 Advantages of Digital Twin in the Pharmaceutical Industry -- 11.6.1 Wastage Can Be Reduced -- 11.6.2 Cost Savings -- 11.6.3 Faster Time to Market -- 11.6.4 Smooth Management. 327 $a11.6.5 Remote Monitoring. 606 $aBusiness$xTechnological innovations 615 0$aBusiness$xTechnological innovations. 676 $a658.4063 702 $aVohra$b Manisha 801 0$bMiAaPQ 801 1$bMiAaPQ 801 2$bMiAaPQ 906 $aBOOK 912 $a9910830877503321 996 $aDigital twin technology$94063868 997 $aUNINA