Coleman, Hugh W.,
Experimentation, validation, and uncertainty analysis for engineers / Hugh W. Coleman and W. Glenn Steele. - Fourth edition. - 1 online resource (xvi, 358 pages)
First edition entitled: Experimentation and uncertainty analysis for engineers.
Includes bibliographical references and index.
Cover; Title Page; Copyright; Contents; Preface; Chapter 1: Experimentation, Errors, and Uncertainty; 1-1 Experimentation; 1-1.1 Why Is Experimentation Necessary?; 1-1.2 Degree of Goodness and Uncertainty Analysis; 1-1.3 Experimentation and Validation of Simulations; 1-2 Experimental Approach; 1-2.1 Questions to Be Considered; 1-2.2 Phases of Experimental Program; 1-3 Basic Concepts and Definitions; 1-3.1 Errors and Uncertainties; 1-3.2 Categorizing and Naming Errors and Uncertainties; 1-3.3 Estimating Standard Uncertainties; 1-3.4 Determining Combined Standard Uncertainties. 1-3.5 Elemental Systematic Errors and Effects of Calibration1-3.6 Expansion of Concept from ""Measurement Uncertainty"" to ""Experimental Uncertainty; 1-3.7 Repetition and Replication; 1-3.8 Associating a Percentage Coverage or Confidence with Uncertainty Estimates; 1-4 Experimental Results Determined from a Data Reduction Equation Combining Multiple Measured Variables; 1-5 Guides and Standards; 1-5.1 Experimental Uncertainty Analysis; 1-5.2 Validation of Simulations; 1-6 A Note on Nomenclature; References; Problems. Chapter 2: Coverage and Confidence Intervals for an Individual Measured Variable2-1 Coverage Intervals from the Monte Carlo Method for a Single Measured Variable; 2-2 Confidence Intervals from the Taylor Series Method for a Single Measured Variable, Only Random Errors Considered; 2-2.1 Statistical Distributions; 2-2.2 The Gaussian Distribution; 2-2.3 Confidence Intervals in Gaussian Parent Populations; 2-2.4 Confidence Intervals in Samples from Gaussian Parent Populations; 2-2.5 Tolerance and Prediction Intervals in Samples from Gaussian Parent Populations. 2-2.6 Statistical Rejection of Outliers from a Sample Assumed from a Gaussian Parent Population2-3 Confidence Intervals from the Taylor Series Method for a Single Measured Variable: Random and Systematic Errors Considered; 2-3.1 The Central Limit Theorem; 2-3.2 Systematic Standard Uncertainty Estimation; 2-3.3 The TSM Expanded Uncertainty of a Measured Variable; 2-3.4 The TSM Large-Sample Expanded Uncertainty of a Measured Variable; 2-4 Uncertainty of Uncertainty Estimates and Confidence Interval Limits for a Measured Variable; 2-4.1 Uncertainty of Uncertainty Estimates. 2-4.2 Implications of the Uncertainty in Limits of High Confidence Uncertainty Intervals Used in Analysis and DesignReferences; Problems; Chapter 3: Uncertainty in a Result Determined from Multiple Variables; 3-1 General Uncertainty Analysis vs. Detailed Uncertainty Analysis; 3-2 Monte Carlo Method for Propagation of Uncertainties; 3-2.1 Using the MCM in General Uncertainty Analysis; 3-2.2 Using the MCM in Detailed Uncertainty Analysis; 3-3 Taylor Series Method for Propagation of Uncertainties; 3-3.1 General Uncertainty Analysis Using the Taylor Series Method (TSM).
9781119417668 111941766X 9781119417705 1119417708 9781119417989 1119417988
2017056271
Engineering--Experiments.
Uncertainty.
TECHNOLOGY & ENGINEERING--Engineering (General)
TECHNOLOGY & ENGINEERING--Reference.
Engineering--Experiments.
Uncertainty.
Electronic books.
TA153 / .C66 2018
620.0072
Experimentation, validation, and uncertainty analysis for engineers / Hugh W. Coleman and W. Glenn Steele. - Fourth edition. - 1 online resource (xvi, 358 pages)
First edition entitled: Experimentation and uncertainty analysis for engineers.
Includes bibliographical references and index.
Cover; Title Page; Copyright; Contents; Preface; Chapter 1: Experimentation, Errors, and Uncertainty; 1-1 Experimentation; 1-1.1 Why Is Experimentation Necessary?; 1-1.2 Degree of Goodness and Uncertainty Analysis; 1-1.3 Experimentation and Validation of Simulations; 1-2 Experimental Approach; 1-2.1 Questions to Be Considered; 1-2.2 Phases of Experimental Program; 1-3 Basic Concepts and Definitions; 1-3.1 Errors and Uncertainties; 1-3.2 Categorizing and Naming Errors and Uncertainties; 1-3.3 Estimating Standard Uncertainties; 1-3.4 Determining Combined Standard Uncertainties. 1-3.5 Elemental Systematic Errors and Effects of Calibration1-3.6 Expansion of Concept from ""Measurement Uncertainty"" to ""Experimental Uncertainty; 1-3.7 Repetition and Replication; 1-3.8 Associating a Percentage Coverage or Confidence with Uncertainty Estimates; 1-4 Experimental Results Determined from a Data Reduction Equation Combining Multiple Measured Variables; 1-5 Guides and Standards; 1-5.1 Experimental Uncertainty Analysis; 1-5.2 Validation of Simulations; 1-6 A Note on Nomenclature; References; Problems. Chapter 2: Coverage and Confidence Intervals for an Individual Measured Variable2-1 Coverage Intervals from the Monte Carlo Method for a Single Measured Variable; 2-2 Confidence Intervals from the Taylor Series Method for a Single Measured Variable, Only Random Errors Considered; 2-2.1 Statistical Distributions; 2-2.2 The Gaussian Distribution; 2-2.3 Confidence Intervals in Gaussian Parent Populations; 2-2.4 Confidence Intervals in Samples from Gaussian Parent Populations; 2-2.5 Tolerance and Prediction Intervals in Samples from Gaussian Parent Populations. 2-2.6 Statistical Rejection of Outliers from a Sample Assumed from a Gaussian Parent Population2-3 Confidence Intervals from the Taylor Series Method for a Single Measured Variable: Random and Systematic Errors Considered; 2-3.1 The Central Limit Theorem; 2-3.2 Systematic Standard Uncertainty Estimation; 2-3.3 The TSM Expanded Uncertainty of a Measured Variable; 2-3.4 The TSM Large-Sample Expanded Uncertainty of a Measured Variable; 2-4 Uncertainty of Uncertainty Estimates and Confidence Interval Limits for a Measured Variable; 2-4.1 Uncertainty of Uncertainty Estimates. 2-4.2 Implications of the Uncertainty in Limits of High Confidence Uncertainty Intervals Used in Analysis and DesignReferences; Problems; Chapter 3: Uncertainty in a Result Determined from Multiple Variables; 3-1 General Uncertainty Analysis vs. Detailed Uncertainty Analysis; 3-2 Monte Carlo Method for Propagation of Uncertainties; 3-2.1 Using the MCM in General Uncertainty Analysis; 3-2.2 Using the MCM in Detailed Uncertainty Analysis; 3-3 Taylor Series Method for Propagation of Uncertainties; 3-3.1 General Uncertainty Analysis Using the Taylor Series Method (TSM).
9781119417668 111941766X 9781119417705 1119417708 9781119417989 1119417988
2017056271
Engineering--Experiments.
Uncertainty.
TECHNOLOGY & ENGINEERING--Engineering (General)
TECHNOLOGY & ENGINEERING--Reference.
Engineering--Experiments.
Uncertainty.
Electronic books.
TA153 / .C66 2018
620.0072