Prediction Technologies for Improving Engineering Product Efficiency:
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| Format: | Elektronisch E-Book |
| Sprache: | English |
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Cham
Springer International Publishing AG
2023
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| Ausgabe: | 1st ed |
| Schlagworte: | |
| Online-Zugang: | DE-2070s |
| Beschreibung: | Description based on publisher supplied metadata and other sources |
| Beschreibung: | 1 Online-Ressource (281 Seiten) |
| ISBN: | 9783031166556 |
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| 245 | 1 | 0 | |a Prediction Technologies for Improving Engineering Product Efficiency |
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| 505 | 8 | |a Intro -- Preface -- Introduction -- Why Does the Book Has This Title? -- References -- Contents -- About the Author -- Chapter 1: How Was Began Development of New Direction "Successful Prediction of Engineering Product Efficiency" -- References -- Chapter 2: Analysis of Current Situation with Prediction of New Product Reliability and Efficiency -- 2.1 Current Methodological Aspects of New Product Reliability and Efficiency Prediction -- 2.1.1 General Model -- 2.1.2 Classical Test Theory -- 2.1.3 Estimation -- 2.1.4 Reliability Prediction for Mean Time Between Failures -- 2.1.5 Reliability Software Overview -- 2.1.5.1 MIL-HDBK-217 Predictive Method -- 2.1.5.2 Bellcore/Telcordia Predictive Method -- 2.1.5.3 Discussion of Empirical Methods -- 2.1.6 Physics of Failure Methods -- 2.1.6.1 Arrhenius's Law -- 2.1.6.2 Black Model for Electromigration -- 2.1.6.3 Discussion of Physics of Failure Methods -- 2.1.7 Life Testing Method -- 2.2 Why the Level of New Product Current Prediction Is Low -- 2.3 Example of Low-Level Efficiency Prediction -- References -- Chapter 3: Technology of Successful Prediction of New Product Efficiency (Quality, Reliability, Durability, Maintainability, Safety, Life Cycle Cost, Profit, and Other Components) -- 3.1 The Basis of Successful Prediction of Product Efficiency -- 3.2 The Strategy of Successful Efficiency Prediction -- 3.3 Methodological Aspects (The First Key Factor) of Successful Efficiency Prediction -- 3.3.1 Criteria of Successful Prediction of Efficiency by Results of Accelerated Reliability/Durability Testing -- 3.3.2 Development of Techniques for Product Efficiency Prediction on the Basis of Accelerated Reliability/Durability Testing Results -- 3.3.3 Basic Concepts of Efficiency Prediction -- 3.3.4 Other Methodological Aspects of Successful Prediction | |
| 505 | 8 | |a 3.4 Improving Engineering Culture for Efficiency Successful Prediction -- 3.5 Organizational Culture as a Component of Improving Engineering Culture -- References -- Chapter 4: Accelerated Reliability and Durability Testing Technology as Second Key Factor for Successful Prediction of Product Efficiency -- 4.1 Introduction -- 4.2 Current Status of Accelerated Testing -- 4.2.1 Basic General Directions of Accelerated Testing Development -- 4.2.1.1 The First General Direction (Field Accelerated Testing) -- 4.2.1.2 The Second General Direction (Accelerated Testing Based on Computer/Software Simulation) -- 4.2.1.3 The Third General Direction (Laboratory, or Proving Ground, or Crash Testing with Physical Simulation of Field Conditions) -- 4.2.1.4 The Fourth General Direction of Accelerated Testing -- 4.2.1.5 The Fifth General Direction (Accelerated Reliability/Durability Testing) -- 4.2.2 Other Testing Approaches -- 4.3 The Basic Methodology of Accelerated Reliability and Durability Testing -- 4.4 Basic Aspects of Methodology for Selecting Representative Input Regions for Accurate Simulation of Real-World Conditions -- 4.4.1 The Problem -- 4.4.2 Basic Steps of Methodology for Selecting a Representative Region -- 4.5 The Role of Real-World Conditions' Accurate Simulation in the Development of Accelerated Reliability and Durability Testing and Successful Efficiency Prediction -- 4.6 Establishing the Concepts and Statistical Criteria for Providing Physical Simulation of Input Influences on a Product for Accelerated Reliability/Durability Testing -- 4.7 Equipment for Advanced Accelerated Testing -- 4.7.1 Introduction -- 4.7.2 General Situation -- 4.7.3 Environmental Combined Testing Equipment -- 4.7.4 Combined Testing for Vehicle Components -- 4.7.5 Equipment for Accelerated Reliability and Durability Testing -- References | |
| 505 | 8 | |a Chapter 5: Negative Trends in the Development of Simulation, Testing, and Prediction in Engineering -- 5.1 Introduction -- 5.2 Some of the Basic Negative Trends in the Technology Development of Simulation and Accelerated Testing -- 5.3 Trends in Using Virtual (Computer) Simulation and Testing as a Replacement for Real-World Conditions -- 5.4 Consideration of the Newly Trends in the Development of Real-World Simulation, Accelerated Testing, and Efficiency Prediction -- References -- Chapter 6: Implementation Successful Prediction of Product Efficiency, Accelerated: Reliability and Durability Testing, and Accurate Simulation -- 6.1 Introduction -- 6.2 Common Principles -- 6.3 Direct Implementation: Economic Results -- 6.4 Implementation Through Standardization -- 6.4.1 Implementation of Reliability Testing and Successful Reliability Prediction Through the Application of Standard EP-456 "Test and Reliability Guidelines" for Farm Machinery -- 6.4.2 How the Work in SAE G-11 Division Assisted to Implement Accelerated Reliability Testing as a Component of Successful Efficiency Prediction -- 6.4.3 Implementation of Reliability Testing During the Work for the International Electrotechnical Commission (IEC), US Representative for International Organizations in Standardization (ISO), IEC/ISO Joint Study Group in Safety Aspects of Risk As -- 6.5 Implementation Through Author's and His Colleagues Seminars, Publications, Lectures, and Presentations over the World -- 6.6 Implementation Through Published Citations -- 6.7 Implementation Through Published Reviews -- References -- Index | |
| 650 | 4 | |a Industrial efficiency | |
| 650 | 4 | |a Production engineering-Technological innovations | |
| 776 | 0 | 8 | |i Erscheint auch als |n Druck-Ausgabe |a Klyatis, Lev M. |t Prediction Technologies for Improving Engineering Product Efficiency |d Cham : Springer International Publishing AG,c2023 |z 9783031166549 |
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Datensatz im Suchindex
| _version_ | 1810600619788992512 |
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| adam_text | |
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| author | Klyatis, Lev M. |
| author_facet | Klyatis, Lev M. |
| author_role | aut |
| author_sort | Klyatis, Lev M. |
| author_variant | l m k lm lmk |
| building | Verbundindex |
| bvnumber | BV049873581 |
| collection | ZDB-30-PQE |
| contents | Intro -- Preface -- Introduction -- Why Does the Book Has This Title? -- References -- Contents -- About the Author -- Chapter 1: How Was Began Development of New Direction "Successful Prediction of Engineering Product Efficiency" -- References -- Chapter 2: Analysis of Current Situation with Prediction of New Product Reliability and Efficiency -- 2.1 Current Methodological Aspects of New Product Reliability and Efficiency Prediction -- 2.1.1 General Model -- 2.1.2 Classical Test Theory -- 2.1.3 Estimation -- 2.1.4 Reliability Prediction for Mean Time Between Failures -- 2.1.5 Reliability Software Overview -- 2.1.5.1 MIL-HDBK-217 Predictive Method -- 2.1.5.2 Bellcore/Telcordia Predictive Method -- 2.1.5.3 Discussion of Empirical Methods -- 2.1.6 Physics of Failure Methods -- 2.1.6.1 Arrhenius's Law -- 2.1.6.2 Black Model for Electromigration -- 2.1.6.3 Discussion of Physics of Failure Methods -- 2.1.7 Life Testing Method -- 2.2 Why the Level of New Product Current Prediction Is Low -- 2.3 Example of Low-Level Efficiency Prediction -- References -- Chapter 3: Technology of Successful Prediction of New Product Efficiency (Quality, Reliability, Durability, Maintainability, Safety, Life Cycle Cost, Profit, and Other Components) -- 3.1 The Basis of Successful Prediction of Product Efficiency -- 3.2 The Strategy of Successful Efficiency Prediction -- 3.3 Methodological Aspects (The First Key Factor) of Successful Efficiency Prediction -- 3.3.1 Criteria of Successful Prediction of Efficiency by Results of Accelerated Reliability/Durability Testing -- 3.3.2 Development of Techniques for Product Efficiency Prediction on the Basis of Accelerated Reliability/Durability Testing Results -- 3.3.3 Basic Concepts of Efficiency Prediction -- 3.3.4 Other Methodological Aspects of Successful Prediction 3.4 Improving Engineering Culture for Efficiency Successful Prediction -- 3.5 Organizational Culture as a Component of Improving Engineering Culture -- References -- Chapter 4: Accelerated Reliability and Durability Testing Technology as Second Key Factor for Successful Prediction of Product Efficiency -- 4.1 Introduction -- 4.2 Current Status of Accelerated Testing -- 4.2.1 Basic General Directions of Accelerated Testing Development -- 4.2.1.1 The First General Direction (Field Accelerated Testing) -- 4.2.1.2 The Second General Direction (Accelerated Testing Based on Computer/Software Simulation) -- 4.2.1.3 The Third General Direction (Laboratory, or Proving Ground, or Crash Testing with Physical Simulation of Field Conditions) -- 4.2.1.4 The Fourth General Direction of Accelerated Testing -- 4.2.1.5 The Fifth General Direction (Accelerated Reliability/Durability Testing) -- 4.2.2 Other Testing Approaches -- 4.3 The Basic Methodology of Accelerated Reliability and Durability Testing -- 4.4 Basic Aspects of Methodology for Selecting Representative Input Regions for Accurate Simulation of Real-World Conditions -- 4.4.1 The Problem -- 4.4.2 Basic Steps of Methodology for Selecting a Representative Region -- 4.5 The Role of Real-World Conditions' Accurate Simulation in the Development of Accelerated Reliability and Durability Testing and Successful Efficiency Prediction -- 4.6 Establishing the Concepts and Statistical Criteria for Providing Physical Simulation of Input Influences on a Product for Accelerated Reliability/Durability Testing -- 4.7 Equipment for Advanced Accelerated Testing -- 4.7.1 Introduction -- 4.7.2 General Situation -- 4.7.3 Environmental Combined Testing Equipment -- 4.7.4 Combined Testing for Vehicle Components -- 4.7.5 Equipment for Accelerated Reliability and Durability Testing -- References Chapter 5: Negative Trends in the Development of Simulation, Testing, and Prediction in Engineering -- 5.1 Introduction -- 5.2 Some of the Basic Negative Trends in the Technology Development of Simulation and Accelerated Testing -- 5.3 Trends in Using Virtual (Computer) Simulation and Testing as a Replacement for Real-World Conditions -- 5.4 Consideration of the Newly Trends in the Development of Real-World Simulation, Accelerated Testing, and Efficiency Prediction -- References -- Chapter 6: Implementation Successful Prediction of Product Efficiency, Accelerated: Reliability and Durability Testing, and Accurate Simulation -- 6.1 Introduction -- 6.2 Common Principles -- 6.3 Direct Implementation: Economic Results -- 6.4 Implementation Through Standardization -- 6.4.1 Implementation of Reliability Testing and Successful Reliability Prediction Through the Application of Standard EP-456 "Test and Reliability Guidelines" for Farm Machinery -- 6.4.2 How the Work in SAE G-11 Division Assisted to Implement Accelerated Reliability Testing as a Component of Successful Efficiency Prediction -- 6.4.3 Implementation of Reliability Testing During the Work for the International Electrotechnical Commission (IEC), US Representative for International Organizations in Standardization (ISO), IEC/ISO Joint Study Group in Safety Aspects of Risk As -- 6.5 Implementation Through Author's and His Colleagues Seminars, Publications, Lectures, and Presentations over the World -- 6.6 Implementation Through Published Citations -- 6.7 Implementation Through Published Reviews -- References -- Index |
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| dewey-full | 658.515 |
| dewey-hundreds | 600 - Technology (Applied sciences) |
| dewey-ones | 658 - General management |
| dewey-raw | 658.515 |
| dewey-search | 658.515 |
| dewey-sort | 3658.515 |
| dewey-tens | 650 - Management and auxiliary services |
| discipline | Wirtschaftswissenschaften |
| edition | 1st ed |
| format | Electronic eBook |
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| id | DE-604.BV049873581 |
| illustrated | Not Illustrated |
| indexdate | 2024-09-19T05:21:48Z |
| institution | BVB |
| isbn | 9783031166556 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-035213039 |
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| owner | DE-2070s |
| owner_facet | DE-2070s |
| physical | 1 Online-Ressource (281 Seiten) |
| psigel | ZDB-30-PQE ZDB-30-PQE HWR_PDA_PQE |
| publishDate | 2023 |
| publishDateSearch | 2023 |
| publishDateSort | 2023 |
| publisher | Springer International Publishing AG |
| record_format | marc |
| spelling | Klyatis, Lev M. Verfasser aut Prediction Technologies for Improving Engineering Product Efficiency 1st ed Cham Springer International Publishing AG 2023 ©2023 1 Online-Ressource (281 Seiten) txt rdacontent c rdamedia cr rdacarrier Description based on publisher supplied metadata and other sources Intro -- Preface -- Introduction -- Why Does the Book Has This Title? -- References -- Contents -- About the Author -- Chapter 1: How Was Began Development of New Direction "Successful Prediction of Engineering Product Efficiency" -- References -- Chapter 2: Analysis of Current Situation with Prediction of New Product Reliability and Efficiency -- 2.1 Current Methodological Aspects of New Product Reliability and Efficiency Prediction -- 2.1.1 General Model -- 2.1.2 Classical Test Theory -- 2.1.3 Estimation -- 2.1.4 Reliability Prediction for Mean Time Between Failures -- 2.1.5 Reliability Software Overview -- 2.1.5.1 MIL-HDBK-217 Predictive Method -- 2.1.5.2 Bellcore/Telcordia Predictive Method -- 2.1.5.3 Discussion of Empirical Methods -- 2.1.6 Physics of Failure Methods -- 2.1.6.1 Arrhenius's Law -- 2.1.6.2 Black Model for Electromigration -- 2.1.6.3 Discussion of Physics of Failure Methods -- 2.1.7 Life Testing Method -- 2.2 Why the Level of New Product Current Prediction Is Low -- 2.3 Example of Low-Level Efficiency Prediction -- References -- Chapter 3: Technology of Successful Prediction of New Product Efficiency (Quality, Reliability, Durability, Maintainability, Safety, Life Cycle Cost, Profit, and Other Components) -- 3.1 The Basis of Successful Prediction of Product Efficiency -- 3.2 The Strategy of Successful Efficiency Prediction -- 3.3 Methodological Aspects (The First Key Factor) of Successful Efficiency Prediction -- 3.3.1 Criteria of Successful Prediction of Efficiency by Results of Accelerated Reliability/Durability Testing -- 3.3.2 Development of Techniques for Product Efficiency Prediction on the Basis of Accelerated Reliability/Durability Testing Results -- 3.3.3 Basic Concepts of Efficiency Prediction -- 3.3.4 Other Methodological Aspects of Successful Prediction 3.4 Improving Engineering Culture for Efficiency Successful Prediction -- 3.5 Organizational Culture as a Component of Improving Engineering Culture -- References -- Chapter 4: Accelerated Reliability and Durability Testing Technology as Second Key Factor for Successful Prediction of Product Efficiency -- 4.1 Introduction -- 4.2 Current Status of Accelerated Testing -- 4.2.1 Basic General Directions of Accelerated Testing Development -- 4.2.1.1 The First General Direction (Field Accelerated Testing) -- 4.2.1.2 The Second General Direction (Accelerated Testing Based on Computer/Software Simulation) -- 4.2.1.3 The Third General Direction (Laboratory, or Proving Ground, or Crash Testing with Physical Simulation of Field Conditions) -- 4.2.1.4 The Fourth General Direction of Accelerated Testing -- 4.2.1.5 The Fifth General Direction (Accelerated Reliability/Durability Testing) -- 4.2.2 Other Testing Approaches -- 4.3 The Basic Methodology of Accelerated Reliability and Durability Testing -- 4.4 Basic Aspects of Methodology for Selecting Representative Input Regions for Accurate Simulation of Real-World Conditions -- 4.4.1 The Problem -- 4.4.2 Basic Steps of Methodology for Selecting a Representative Region -- 4.5 The Role of Real-World Conditions' Accurate Simulation in the Development of Accelerated Reliability and Durability Testing and Successful Efficiency Prediction -- 4.6 Establishing the Concepts and Statistical Criteria for Providing Physical Simulation of Input Influences on a Product for Accelerated Reliability/Durability Testing -- 4.7 Equipment for Advanced Accelerated Testing -- 4.7.1 Introduction -- 4.7.2 General Situation -- 4.7.3 Environmental Combined Testing Equipment -- 4.7.4 Combined Testing for Vehicle Components -- 4.7.5 Equipment for Accelerated Reliability and Durability Testing -- References Chapter 5: Negative Trends in the Development of Simulation, Testing, and Prediction in Engineering -- 5.1 Introduction -- 5.2 Some of the Basic Negative Trends in the Technology Development of Simulation and Accelerated Testing -- 5.3 Trends in Using Virtual (Computer) Simulation and Testing as a Replacement for Real-World Conditions -- 5.4 Consideration of the Newly Trends in the Development of Real-World Simulation, Accelerated Testing, and Efficiency Prediction -- References -- Chapter 6: Implementation Successful Prediction of Product Efficiency, Accelerated: Reliability and Durability Testing, and Accurate Simulation -- 6.1 Introduction -- 6.2 Common Principles -- 6.3 Direct Implementation: Economic Results -- 6.4 Implementation Through Standardization -- 6.4.1 Implementation of Reliability Testing and Successful Reliability Prediction Through the Application of Standard EP-456 "Test and Reliability Guidelines" for Farm Machinery -- 6.4.2 How the Work in SAE G-11 Division Assisted to Implement Accelerated Reliability Testing as a Component of Successful Efficiency Prediction -- 6.4.3 Implementation of Reliability Testing During the Work for the International Electrotechnical Commission (IEC), US Representative for International Organizations in Standardization (ISO), IEC/ISO Joint Study Group in Safety Aspects of Risk As -- 6.5 Implementation Through Author's and His Colleagues Seminars, Publications, Lectures, and Presentations over the World -- 6.6 Implementation Through Published Citations -- 6.7 Implementation Through Published Reviews -- References -- Index Industrial efficiency Production engineering-Technological innovations Erscheint auch als Druck-Ausgabe Klyatis, Lev M. Prediction Technologies for Improving Engineering Product Efficiency Cham : Springer International Publishing AG,c2023 9783031166549 |
| spellingShingle | Klyatis, Lev M. Prediction Technologies for Improving Engineering Product Efficiency Intro -- Preface -- Introduction -- Why Does the Book Has This Title? -- References -- Contents -- About the Author -- Chapter 1: How Was Began Development of New Direction "Successful Prediction of Engineering Product Efficiency" -- References -- Chapter 2: Analysis of Current Situation with Prediction of New Product Reliability and Efficiency -- 2.1 Current Methodological Aspects of New Product Reliability and Efficiency Prediction -- 2.1.1 General Model -- 2.1.2 Classical Test Theory -- 2.1.3 Estimation -- 2.1.4 Reliability Prediction for Mean Time Between Failures -- 2.1.5 Reliability Software Overview -- 2.1.5.1 MIL-HDBK-217 Predictive Method -- 2.1.5.2 Bellcore/Telcordia Predictive Method -- 2.1.5.3 Discussion of Empirical Methods -- 2.1.6 Physics of Failure Methods -- 2.1.6.1 Arrhenius's Law -- 2.1.6.2 Black Model for Electromigration -- 2.1.6.3 Discussion of Physics of Failure Methods -- 2.1.7 Life Testing Method -- 2.2 Why the Level of New Product Current Prediction Is Low -- 2.3 Example of Low-Level Efficiency Prediction -- References -- Chapter 3: Technology of Successful Prediction of New Product Efficiency (Quality, Reliability, Durability, Maintainability, Safety, Life Cycle Cost, Profit, and Other Components) -- 3.1 The Basis of Successful Prediction of Product Efficiency -- 3.2 The Strategy of Successful Efficiency Prediction -- 3.3 Methodological Aspects (The First Key Factor) of Successful Efficiency Prediction -- 3.3.1 Criteria of Successful Prediction of Efficiency by Results of Accelerated Reliability/Durability Testing -- 3.3.2 Development of Techniques for Product Efficiency Prediction on the Basis of Accelerated Reliability/Durability Testing Results -- 3.3.3 Basic Concepts of Efficiency Prediction -- 3.3.4 Other Methodological Aspects of Successful Prediction 3.4 Improving Engineering Culture for Efficiency Successful Prediction -- 3.5 Organizational Culture as a Component of Improving Engineering Culture -- References -- Chapter 4: Accelerated Reliability and Durability Testing Technology as Second Key Factor for Successful Prediction of Product Efficiency -- 4.1 Introduction -- 4.2 Current Status of Accelerated Testing -- 4.2.1 Basic General Directions of Accelerated Testing Development -- 4.2.1.1 The First General Direction (Field Accelerated Testing) -- 4.2.1.2 The Second General Direction (Accelerated Testing Based on Computer/Software Simulation) -- 4.2.1.3 The Third General Direction (Laboratory, or Proving Ground, or Crash Testing with Physical Simulation of Field Conditions) -- 4.2.1.4 The Fourth General Direction of Accelerated Testing -- 4.2.1.5 The Fifth General Direction (Accelerated Reliability/Durability Testing) -- 4.2.2 Other Testing Approaches -- 4.3 The Basic Methodology of Accelerated Reliability and Durability Testing -- 4.4 Basic Aspects of Methodology for Selecting Representative Input Regions for Accurate Simulation of Real-World Conditions -- 4.4.1 The Problem -- 4.4.2 Basic Steps of Methodology for Selecting a Representative Region -- 4.5 The Role of Real-World Conditions' Accurate Simulation in the Development of Accelerated Reliability and Durability Testing and Successful Efficiency Prediction -- 4.6 Establishing the Concepts and Statistical Criteria for Providing Physical Simulation of Input Influences on a Product for Accelerated Reliability/Durability Testing -- 4.7 Equipment for Advanced Accelerated Testing -- 4.7.1 Introduction -- 4.7.2 General Situation -- 4.7.3 Environmental Combined Testing Equipment -- 4.7.4 Combined Testing for Vehicle Components -- 4.7.5 Equipment for Accelerated Reliability and Durability Testing -- References Chapter 5: Negative Trends in the Development of Simulation, Testing, and Prediction in Engineering -- 5.1 Introduction -- 5.2 Some of the Basic Negative Trends in the Technology Development of Simulation and Accelerated Testing -- 5.3 Trends in Using Virtual (Computer) Simulation and Testing as a Replacement for Real-World Conditions -- 5.4 Consideration of the Newly Trends in the Development of Real-World Simulation, Accelerated Testing, and Efficiency Prediction -- References -- Chapter 6: Implementation Successful Prediction of Product Efficiency, Accelerated: Reliability and Durability Testing, and Accurate Simulation -- 6.1 Introduction -- 6.2 Common Principles -- 6.3 Direct Implementation: Economic Results -- 6.4 Implementation Through Standardization -- 6.4.1 Implementation of Reliability Testing and Successful Reliability Prediction Through the Application of Standard EP-456 "Test and Reliability Guidelines" for Farm Machinery -- 6.4.2 How the Work in SAE G-11 Division Assisted to Implement Accelerated Reliability Testing as a Component of Successful Efficiency Prediction -- 6.4.3 Implementation of Reliability Testing During the Work for the International Electrotechnical Commission (IEC), US Representative for International Organizations in Standardization (ISO), IEC/ISO Joint Study Group in Safety Aspects of Risk As -- 6.5 Implementation Through Author's and His Colleagues Seminars, Publications, Lectures, and Presentations over the World -- 6.6 Implementation Through Published Citations -- 6.7 Implementation Through Published Reviews -- References -- Index Industrial efficiency Production engineering-Technological innovations |
| title | Prediction Technologies for Improving Engineering Product Efficiency |
| title_auth | Prediction Technologies for Improving Engineering Product Efficiency |
| title_exact_search | Prediction Technologies for Improving Engineering Product Efficiency |
| title_full | Prediction Technologies for Improving Engineering Product Efficiency |
| title_fullStr | Prediction Technologies for Improving Engineering Product Efficiency |
| title_full_unstemmed | Prediction Technologies for Improving Engineering Product Efficiency |
| title_short | Prediction Technologies for Improving Engineering Product Efficiency |
| title_sort | prediction technologies for improving engineering product efficiency |
| topic | Industrial efficiency Production engineering-Technological innovations |
| topic_facet | Industrial efficiency Production engineering-Technological innovations |
| work_keys_str_mv | AT klyatislevm predictiontechnologiesforimprovingengineeringproductefficiency |