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Design and Analysis of Engineering Experiments

Design and Analysis of Engineering Experiments. Ali Ahmad, PhD. Response Surface Methodology. Text reference, Chapter 11 Primary focus of previous chapters is factor screening Two-level factorials, fractional factorials are widely used Objective of RSM is optimization

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Design and Analysis of Engineering Experiments

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  1. Design and Analysis of Engineering Experiments Ali Ahmad, PhD Based on Design & Analysis of Experiments 7E 2009 Montgomery

  2. Response Surface Methodology Design & Analysis of Experiments 7E 2009 Montgomery

  3. Text reference, Chapter 11 • Primary focus of previous chapters is factorscreening • Two-level factorials, fractional factorials are widely used • Objective of RSM is optimization • RSM dates from the 1950s; early applications in chemical industry • Modern applications of RSM span many industrial and business settings Design & Analysis of Experiments 7E 2009 Montgomery

  4. Response Surface Methodology • Collection of mathematical and statistical techniques useful for the modeling and analysis of problems in which a response of interest is influenced by several variables • Objective is to optimize the response Design & Analysis of Experiments 7E 2009 Montgomery

  5. Steps in RSM Find a suitable approximation for y = f(x) using LS {maybe a low – order polynomial} Move towards the region of the optimum When curvature is found find a new approximation for y = f(x) {generally a higher order polynomial} and perform the “Response Surface Analysis” Design & Analysis of Experiments 7E 2009 Montgomery

  6. Response Surface Models • Screening • Steepest ascent • Optimization Design & Analysis of Experiments 7E 2009 Montgomery

  7. RSM is a Sequential Procedure • Factor screening • Finding the region of the optimum • Modeling & Optimization of the response Design & Analysis of Experiments 7E 2009 Montgomery

  8. The Method of Steepest Ascent • Text, Section 11.2 • A procedure for moving sequentially from an initial “guess” towards to region of the optimum • Based on the fitted first-order model • Steepest ascent is a gradient procedure Design & Analysis of Experiments 7E 2009 Montgomery

  9. Example 11.1: An Example of Steepest Ascent Design & Analysis of Experiments 7E 2009 Montgomery

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  17. Points on the path of steepest ascent are proportional to the magnitudes of the model regression coefficients • The direction depends on the sign of the regression coefficient • Step-by-step procedure: Design & Analysis of Experiments 7E 2009 Montgomery

  18. Second-Order Models in RSM • These models are used widely in practice • The Taylor series analogy • Fitting the model is easy, some nice designs are available • Optimization is easy • There is a lot of empirical evidence that they work very well Design & Analysis of Experiments 7E 2009 Montgomery

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  22. Characterization of the Response Surface • Find out where our stationary point is • Find what type of surface we have • Graphical Analysis • Canonical Analysis • Determine the sensitivity of the response variable to the optimum value • Canonical Analysis Design & Analysis of Experiments 7E 2009 Montgomery

  23. Finding the Stationary Point • After fitting a second order model take the partial derivatives with respect to the xi’s and set to zero • δy / δx1 = . . . = δy / δxk = 0 • Stationary point represents… • Maximum Point • Minimum Point • Saddle Point Design & Analysis of Experiments 7E 2009 Montgomery

  24. Stationary Point Design & Analysis of Experiments 7E 2009 Montgomery

  25. Canonical Analysis • Used for sensitivity analysis and stationary point identification • Based on the analysis of a transformed model called: canonical form of the model • Canonical Model form: • y = ys + λ1w12 + λ2w22 + . . . + λkwk2 Design & Analysis of Experiments 7E 2009 Montgomery

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  27. Eigenvalues • The nature of the response can be determined by the signs and magnitudes of the eigenvalues • {e} all positive: a minimum is found • {e} all negative: a maximum is found • {e} mixed: a saddle point is found • Eigenvalues can be used to determine the sensitivity of the response with respect to the design factors • The response surface is steepest in the direction (canonical) corresponding to the largest absolute eigenvalue Design & Analysis of Experiments 7E 2009 Montgomery

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  34. Ridge Systems Design & Analysis of Experiments 7E 2009 Montgomery

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  38. Overlay Contour Plots Design & Analysis of Experiments 7E 2009 Montgomery

  39. Mathematical Programming Formulation Design & Analysis of Experiments 7E 2009 Montgomery

  40. Desirability Function Method Design & Analysis of Experiments 7E 2009 Montgomery

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  45. Addition of center points is usually a good idea Design & Analysis of Experiments 7E 2009 Montgomery

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  47. The Rotatable CCD Design & Analysis of Experiments 7E 2009 Montgomery

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  49. The Box-Behnken Design Design & Analysis of Experiments 7E 2009 Montgomery

  50. A Design on A Cube – The Face-Centered CCD Design & Analysis of Experiments 7E 2009 Montgomery

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