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101 0 $aeng
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200 12$aA primer on experiments with mixtures$b[electronic resource] /$fJohn A. Cornell
210   $aHoboken, N.J. $cWiley$dc2011
215   $a1 online resource (376 p.)
225 1 $aWiley series in probability and statistics
300   $aDescription based upon print version of record.
311   $a0-470-64338-2 
320   $aIncludes bibliographical references and index.
327   $aA Primer on Experiments with Mixtures; Contents; Preface; 1. Introduction; 1.1 The Original Mixture Problem; 1.2 A Pesticide Example Involving Two Chemicals; 1.3 General Remarks About Response Surface Methods; 1.4 An Historical Perspective; References and Recommended Reading; Questions; Appendix 1A: Testing for Nonlinear Blending of the Two Chemicals Vendex and Kelthane While Measuring the Average Percent Mortality (APM) of Mites; 2. The Original Mixture Problem: Designs and Models for Exploring the Entire Simplex Factor Space; 2.1 The Simplex-Lattice Designs; 2.2 The Canonical Polynomials
327   $a2.3 The Polynomial Coefficients As Functions of the Responses at the Points of the Lattices2.4 Estimating The Parameters in the {q,m} Polynomials; 2.5 Properties of the Estimate of the Response y(x); 2.6 A Three-Component Yarn Example Using A {3, 2} Simplex-Lattice Design; 2.7 The Analysis of Variance Table; 2.8 Analysis of Variance Calculations of the Yarn Elongation Data; 2.9 The Plotting of Individual Residuals; 2.10 Testing the Degree of the Fitted Model: A Quadratic Model or Planar Model?; 2.11 Testing Model Lack of Fit Using Extra Points and Replicated Observations
327   $a2.12 The Simplex-Centroid Design and Associated Polynomial Model2.13 An Application of a Four-Component Simplex-Centroid Design: Blending Chemical Pesticides for Control of Mites; 2.14 Axial Designs; 2.15 Comments on a Comparison Made Between An Augmented Simplex-Centroid Design and a Full Cubic Lattice for Three Components Where Each Design Contains Ten Points; 2.16 Reparameterizing Scheff ?e's Mixture Models to Contain A Constant (?0) Term: A Numerical Example; 2.17 Questions to Consider at the Planning Stages of a Mixture Experiment; 2.18 Summary; References and Recommended Reading
327   $aQuestionsAppendix 2A: Least-Squares Estimation Formula for the Polynomial Coefficients and Their Variances: Matrix Notation; Appendix 2B: Cubic and Quartic Polynomials and Formulas for the Estimates of the Coefficients; Appendix 2C: The Partitioning of the Sources in the Analysis of Variance Table When Fitting the Scheffe? Mixture Models; 3. Multiple Constraints on the Component Proportions; 3.1 Lower-Bound Restrictions on Some or All of the Component Proportions; 3.2 Introducing L-Pseudocomponents; 3.3 A Numerical Example of Fitting An L-Pseudocomponent Model
327   $a3.4 Upper-Bound Restrictions on Some or All Component Proportions3.5 An Example of the Placing of an Upper Bound on a Single Component: The Formulation of a Tropical Beverage; 3.6 Introducing U-Pseudocomponents; 3.7 The Placing of Both Upper and Lower Bounds on the Component Proportions; 3.8 Formulas For Enumerating the Number of Extreme Vertices, Edges, and Two-Dimensional Faces of the Constrained Region; 3.9 McLean and Anderson's Algorithm For Calculating the Coordinates of the Extreme Vertices of a Constrained Region; 3.10 Multicomponent Constraints
327   $a3.11 Some Examples of Designs for Constrained Mixture Regions: CONVRT and CONAEV Programs
330   $aThe concise yet authoritative presentation of key techniques for basic mixtures experiments  Inspired by the author's bestselling advanced book on the topic, A Primer on Experiments with Mixtures provides an introductory presentation of the key principles behind experimenting with mixtures. Outlining useful techniques through an applied approach with examples from real research situations, the book supplies a comprehensive discussion of how to design and set up basic mixture experiments, then analyze the data and draw inferences from results.  Drawing from his extensive experi
410  0$aWiley series in probability and statistics.
606   $aMixtures$xExperiments
606   $aMixtures$xMathematical models
606   $aPowders$xMixing$xExperiments
606   $aPowders$xMixing$xMathematical models
606   $aSolution (Chemistry)$xExperiments
606   $aSolution (Chemistry)$xMathematical models
615  0$aMixtures$xExperiments.
615  0$aMixtures$xMathematical models.
615  0$aPowders$xMixing$xExperiments.
615  0$aPowders$xMixing$xMathematical models.
615  0$aSolution (Chemistry)$xExperiments.
615  0$aSolution (Chemistry)$xMathematical models.
676   $a660.294
676   $a660/.294
700   $aCornell$b John A.$f1941-$0105138
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910133222703321
996   $aA primer on experiments with mixtures$91944914
997   $aUNINA