EQT373 STATISTIC FOR ENGINEERS Design of Experiment (DOE) Noorulnajwa Diyana Yaacob School of Bioprocess Engineering Universiti Malaysia Perlis 30 April 2012 DKD 1
DOE Objectives At the end of this class, the student will be able to : Understand the basic concepts and advantages of designed experiments Understand key terminology used in experimental design Use different techniques to deal with noise in an experiment Make good design decisions
What Experiments Can Do Characterize a Process/Product determines which X’s most affect the Y’s includes controllable and uncontrollable X’s identifies critical X’s and noise variables identifies those variables that need to be carefully controlled provides direction for controlling X’s rather than control charting the Y’s Optimize a Process/Product determines where the critical X’s should be set determines “real” specification limits provides direction for “robust” designs
Definition of Terms Factor - A controllable experimental variable thought to influence response (example air flow rate, or in the case of the Frisbee thrower: angle, tire speed, tire pressure) Response - The outcome or result; what you are measuring (cycle time to produce one bottle, distance Frisbee goes) Levels - Specific value of the factor (fast flow vs. slow flow, 15 degrees vs. 30 degrees) Interaction - Factors may not be independent, therefore combinations of factors may be important. Note that these interactions can easily be missed in a straight “hold all other variables constant” scientific approach. If you have interaction effects you can NOT find the global optimum using the “OFAT” (one factor at a time) approach! Replicate – performance of the basic experiment
How Can DOE Help? run a relatively small number of tests to isolate the most important factors (screening test). determine if any of the factors interact (combined effects are as important as individual effects) and the level of interaction. predict response for any combination of factors using only empirical results optimize using only empirical results determine the design space for simulation models
What makes up an experiment? Response Variable(s) Factors Randomization Repetition and Replication
Response Variable The variable that is measured and the object of the characterization or optimization (the Y) Defining the response variable can be difficult Often selected due to ease of measurement Some questions to ask : How will the results be quantified/analyzed? How good is the measurement system? What are the baseline mean and standard deviation? How big of a change do we care about? Are there several response variables of interest?
Factor A variable which is controlled or varied in a systematic way during the experiment (the X) Tested at 2 or more levels to observe its effect on the response variable(s) (Ys) Some questions to ask : what are reasonable ranges to ensure a change in Y? knowledge of relationship, i.e. linear or quadratic, etc? Examples material, supplier, EGR rate, injection timing can you think of others?
Randomization Randomization can be done in several ways : run the treatment combinations in random order assign experimental units to treatment combinations randomly an experimental unit is the entity to which a specific treatment combination is applied Advantage of randomization is to “average out” the effects of extraneous factors (called noise) that may be present but were not controlled or measured during the experiment spread the effect of the noise across all runs these extraneous factors (noise) cause unexplained variation in the response variable(s)
Repetition and Replication Repetition : Running several samples during one experimental setup (short-term variability) Replication : Repeating the entire experiment (long-term variability) You can use both in the same experiment Repetition and Replication provide an estimate of the experimental error this estimate will be used to determine whether observed differences are statistically significant
Steps in DOE 1. Statement of the Problem 2. Selection of Response Variable 3. Choice of Factors and Levels Factors are the potential design parameters, such as angle or tire pressure Levels are the range of values for the factors, 15 degrees or 30 degrees 4. Choice of Design screening tests response prediction factor interaction 5. Perform Experiment 6. Data Analysis
Process Noise Factors “z” Controllable Factors “x” Responses “y” DOE (Design of Experiments) is: “A systematic series of tests, in which purposeful changes are made to input factors, so that you may identify causes for significant changes in the output responses.” Design of Experiments
Process Noise Factors “z” Controllable Factors “x” Responses “y” Let’s brainstorm. What process might you experiment on for best payback? How will you measure the response? What factors can you control? Write it down.
Motivation for Factorial Design Want to estimate factor effects well; this implies estimating effects from averages. Want to obtain the most information in the fewest number of runs. Want to estimate each factor effect independent of the existence of other factor effects. Want to keep it simple.
Two-Level Full Factorial Design (1 ST Approach) Run all high/low combinations of 2 (or more) factors Use statistics to identify the critical factors 2 2 Full Factorial Two-level full factorials include experiments at all combinations of the factor levels: 2x2 = 4, 2x2x2 = 8, etc.
Design Construction 2 3 Full Factorial StdABCABACBCABC 1–––+++–y1y1 2+––––++y2y2 3–+––+–+y3y3 4++–+–––y4y4 5––++––+y5y5 6+–+–+––y6y6 7–++––+–y7y y8y8 This is a two-level, three factor design, called a 2 3 factorial design, which produces 8 runs. This is the complete design matrix, including interactions. It includes all seven of the effects we can evaluate (in addition to the overall mean) with the eight runs: -- three main effects (MEs), three 2-factor interactions (2fi) and one 3-factor interaction (3fi).
Two Level Factorial Design As Easy As Popping Corn! Kitchen scientists* conducted a 2 3 factorial experiment on microwave popcorn. The factors are: A.Brand of popcorn B.Time in microwave C.Power setting A panel of neighborhood kids rated taste from one to ten and weighed the un-popped kernels (UPKs). We will analyze the first response “Taste” by hand and using a computer both the “Taste” and the second response “UPKs” (weight of un-popped kernels, technically called “UPKs” by popcorn manufacturers). Then we will look for the best operating conditions.
Two Level Factorial Design As Easy As Popping Corn! ABCR1R1 R2R2 RunBrandTimePowerTasteUPKsStd Ordexpenseminutespercentrating*oz.Ord 1Costly Cheap Cheap Costly Costly Costly Cheap Cheap
Two Level Factorial Design As Easy As Popping Corn! ABCR1R1 R2R2 RunBrandTimePowerTasteUPKsStd Ordexpenseminutespercentratingoz.Ord 1+–– –+– –– – – – ––– Factors shown in coded values
R 1 - Popcorn Taste Average A-Effect There are four comparisons of factor A (Brand), where levels of factors B and C (time and power) are the same: 75 – 74 = – 71 = – 81 = – 4 32 – 42 = – 10 We will use the matrix to calculate effects. But before we do, let’s get a picture of what we mean by an effect. For example if we want to determine effect of Brand (factor A), we simply compare the results of A at its high level versus A at its low level, at the four combinations where the other two factors constant.
R 1 - Popcorn Taste Average A-Effect
R 1 - Popcorn Taste Analysis Matrix in Standard Order Std. OrderIABCABACBCABC Taste rating 1+–––+++–74 2++–––– –+––+– –+–––80 5+––++–– –+–+––77 7+–++––+– This is the complete design matrix in standard order. It includes columns for all eight of the effects we can evaluate with the eight runs: the overall mean (column labeled I for identity) plus seven effects -- three main effects (MEs), three 2-factor interactions (2FIs) and one 3-factor interaction (3FI). How are the signs for the interaction columns computed?
Popcorn Taste Compute the effect of C and BC Std.Taste OrderABCABACBCABCrating 1–––+++–74 2+––––++75 3–+––+– –+–––80 5––++––+81 6+–+–+––77 7–++––+– yy
THANK YOU ANY QUESTION???