DOE Glossary: Difference between revisions

From ReliaWiki
Jump to navigation Jump to search
No edit summary
No edit summary
 
(5 intermediate revisions by 2 users not shown)
Line 1: Line 1:
{{Doebook|F}}
{{Template:Doebook|Appendix G|DOE Glossary}}


'''Alias'''
'''Alias'''
Line 15: Line 15:
'''ANOVA Model'''
'''ANOVA Model'''


The regression model where all factors are treated as qualitative factors. ANOVA models are used in the analysis of experiments to identify significant factor(s) by investigating each level of the factor(s) individually.
The regression model where all factors are treated as qualitative factors. ANOVA models are used in the analysis of experiments to identify significant factors by investigating each level of the factors individually.


   
   
Line 27: Line 27:
'''Blocking'''
'''Blocking'''


Separation of experiment runs based on the levels of a nuisance factor. Blocking is used to deal with known nuisance factors. You should block what you can and randomize what you cannot. See also Nuisance Factors, Randomization.
Separation of experiment runs based on the levels of a nuisance factor. Blocking is used to deal with known nuisance factors. You should block what you can and randomize what you cannot. ''See also'' Nuisance Factors, Randomization.


   
   
Line 47: Line 47:
A closed interval where a certain percentage of the population is likely to lie. For example, a 90% confidence interval with a lower limit of ''A'' and an upper limit of ''B'' implies that 90% of the population lies between the values of ''A'' and ''B''.
A closed interval where a certain percentage of the population is likely to lie. For example, a 90% confidence interval with a lower limit of ''A'' and an upper limit of ''B'' implies that 90% of the population lies between the values of ''A'' and ''B''.


 


'''Confounding'''
'''Confounding'''


Confounding occurs in a design when certain effects cannot be distinguished from the block effect. This happens when full factorial designs are run using incomplete blocks. In such designs the same linear combination of observations estimates the block effect and the confounded effects. See also Incomplete Blocks.
Confounding occurs in a design when certain effects cannot be distinguished from the block effect. This happens when full factorial designs are run using incomplete blocks. In such designs the same linear combination of observations estimates the block effect and the confounded effects. ''See also'' Incomplete Blocks.
 




'''Contrast'''
'''Contrast'''
Line 59: Line 59:
Any linear combination of two or more factor level means such that the coefficients in the combination add up to zero. The difference between the means at any two levels of a factor is an example of a contrast.
Any linear combination of two or more factor level means such that the coefficients in the combination add up to zero. The difference between the means at any two levels of a factor is an example of a contrast.


 


'''Control Factors'''
'''Control Factors'''


The factors affecting the response that are easily manipulated and set by the operator. See also Noise Factors.
The factors affecting the response that are easily manipulated and set by the operator. ''See also'' Noise Factors.


   
   
Line 69: Line 69:
'''Cross Array Design'''
'''Cross Array Design'''


The experiment design in which every treatment of the inner array is replicated for each run of the outer array. See also Inner Array, Outer Array.
The experiment design in which every treatment of the inner array is replicated for each run of the outer array. ''See also'' Inner Array, Outer Array.


   
   
Line 75: Line 75:
'''Curvature Test'''
'''Curvature Test'''


The test that investigates if the relation between the response and the factors is linear by using center points. See also Center Point.
The test that investigates if the relation between the response and the factors is linear by using center points. ''See also'' Center Point.


   
   
Line 81: Line 81:
'''Defining Relation'''
'''Defining Relation'''


For two level fractional factorial experiments, the equation that is used to obtain the fraction from the full factorial experiment. The equation shows which of the columns of the design matrix in the fraction are identical to the first column. For example, the defining relation ''I''=''ABC'' can be used to obtain a half-fraction of the two level full factorial experiment with three factors ''A'', ''B'' and ''C''. The effect(s) used in the equation is called the generator or word.
For two level fractional factorial experiments, the equation that is used to obtain the fraction from the full factorial experiment. The equation shows which of the columns of the design matrix in the fraction are identical to the first column. For example, the defining relation ''I''=''ABC'' can be used to obtain a half-fraction of the two level full factorial experiment with three factors ''A'', ''B'' and ''C''. The effects used in the equation are called the ''generators'' or ''words''.


   
   
Line 99: Line 99:
'''Design Resolution'''
'''Design Resolution'''


The number of factors in the smallest word in a defining relation. Design resolution indicates the degree of aliasing in a fractional factorial design. See also Defining Relation, Word.
The number of factors in the smallest word in a defining relation. Design resolution indicates the degree of aliasing in a fractional factorial design. ''See also'' Defining Relation, Word.


   
   
Line 105: Line 105:
'''Error'''
'''Error'''


The natural variations that occur in a process, even when all the factors are maintained at the same level. See also Residual.
The natural variations that occur in a process, even when all the factors are maintained at the same level. ''See also'' Residual.


   
   
Line 111: Line 111:
'''Error Sum of Squares'''
'''Error Sum of Squares'''


The variation in the data not captured by the model. The error sum of squares is also called the residual sum of squares. See also Model Sum of Squares, Total Sum of Squares.
The variation in the data not captured by the model. The error sum of squares is also called the residual sum of squares. ''See also'' Model Sum of Squares, Total Sum of Squares.


   
   
Line 147: Line 147:
'''Fixed Effects Model'''
'''Fixed Effects Model'''


The ANOVA model used in the experiments where only a limited number of the factor levels are of interest to the experimenter. See also Random Effects Model.
The ANOVA model used in the experiments where only a limited number of the factor levels are of interest to the experimenter. ''See also'' Random Effects Model.


   
   
Line 153: Line 153:
'''Full Model'''
'''Full Model'''


The model that includes all the main effects and their interactions. In DOE++, a full model is the model that contains all the effects that are specified by the user. See also Reduced Model.
The model that includes all the main effects and their interactions. In Weibull++ DOE folios, a full model is the model that contains all the effects that are specified by the user. ''See also'' Reduced Model.


   
   
Line 165: Line 165:
'''Hierarchical Model'''
'''Hierarchical Model'''


In DOE++, a model is said to be hierarchical, if, corresponding to every interaction, the main effects of the related factors are included in the model.
In Weibull++ DOE folios, a model is said to be hierarchical if, corresponding to every interaction, the main effects of the related factors are included in the model.


   
   
Line 177: Line 177:
'''Inner Array'''
'''Inner Array'''


The experiment design used to investigate the control factors under Taguchi's philosophy to design a robust system. See also Robust System, Outer Array, Cross Array.
The experiment design used to investigate the control factors under Taguchi's philosophy to design a robust system. ''See also'' Robust System, Outer Array, Cross Array.


   
   
Line 189: Line 189:
'''Lack-of-Fit Sum of Squares'''
'''Lack-of-Fit Sum of Squares'''


The portion of the error sum of squares that represents variation in the data not captured because of using a reduced model. See also Reduced Model, Pure Error Sum of Squares.
The portion of the error sum of squares that represents variation in the data not captured because of using a reduced model. ''See also'' Reduced Model, Pure Error Sum of Squares.
 




'''Least Squares Means'''
'''Least Squares Means'''
Line 197: Line 197:
The predicted mean response value for a given factor level while the remaining factors in the model are set to the coded value of zero.
The predicted mean response value for a given factor level while the remaining factors in the model are set to the coded value of zero.


 


'''Level'''
'''Level'''
Line 219: Line 219:
'''Model Sum of Squares'''
'''Model Sum of Squares'''


The portion of the total variability in the data that is explained by the model. See also Error Sum of Squares, Total Sum of Squares.
The portion of the total variability in the data that is explained by the model. ''See also'' Error Sum of Squares, Total Sum of Squares.


   
   
Line 233: Line 233:
Observations that are not part of the data set used to fit the model.
Observations that are not part of the data set used to fit the model.


 


'''Noise Factors'''
'''Noise Factors'''
Line 261: Line 261:
'''Outer Array'''
'''Outer Array'''


The experiment design used to investigate noise factors under Taguchi's philosophy to design a robust system. See also Robust System, Inner Array, Cross Array.
The experiment design used to investigate noise factors under Taguchi's philosophy to design a robust system. ''See also'' Robust System, Inner Array, Cross Array.


   
   
Line 267: Line 267:
'''Partial Sum of Squares'''
'''Partial Sum of Squares'''


The type of extra sum of squares that is calculated assuming that all terms other than the given term are included in the model. The partial sum of squares is also referred to as the adjusted sum of squares. See also Extra Sum of Squares, Sequential Sum of Squares.
The type of extra sum of squares that is calculated assuming that all terms other than the given term are included in the model. The partial sum of squares is also referred to as the adjusted sum of squares. ''See also'' Extra Sum of Squares, Sequential Sum of Squares.


   
   
Line 279: Line 279:
'''Pure Error Sum of Squares'''
'''Pure Error Sum of Squares'''


The portion of the error sum of squares that represents variation due to replicates. See also Lack-of-Fit Sum of Squares.
The portion of the error sum of squares that represents variation due to replicates. ''See also'' Lack-of-Fit Sum of Squares.


   
   
Line 291: Line 291:
'''Random Effects Model'''
'''Random Effects Model'''


The ANOVA model used in the experiments where the factor levels to be investigated are randomly selected from a large or infinite population. See also Fixed Effects Model.
The ANOVA model used in the experiments where the factor levels to be investigated are randomly selected from a large or infinite population. ''See also'' Fixed Effects Model.


   
   
Line 297: Line 297:
'''Randomization'''
'''Randomization'''


Conducting experiment runs in a random order to cancel out the effect of unknown nuisance factors. See also Blocking.
Conducting experiment runs in a random order to cancel out the effect of unknown nuisance factors. ''See also'' Blocking.


   
   
Line 309: Line 309:
'''Reduced Model'''
'''Reduced Model'''


A model that does not contain all the main effects and interactions. In DOE++, a reduced model is the model that does not contain all the effects specified by the user. See also Full Model.
A model that does not contain all the main effects and interactions. In Weibull++ DOE folios, a reduced model is the model that does not contain all the effects specified by the user. ''See also'' Full Model.


   
   
Line 333: Line 333:
'''Residual'''
'''Residual'''


An estimate of error which is obtained by calculating the difference between an observation and the corresponding fitted value. See also Error, Fitted Value.
An estimate of error which is obtained by calculating the difference between an observation and the corresponding fitted value. ''See also'' Error, Fitted Value.


   
   
Line 369: Line 369:
'''Sequential Sum of Squares'''
'''Sequential Sum of Squares'''


The type of extra sum of squares that is calculated assuming that all terms preceding the given term are included in the model. See also Extra Sum of Squares, Partial Sum of Squares.
The type of extra sum of squares that is calculated assuming that all terms preceding the given term are included in the model. ''See also'' Extra Sum of Squares, Partial Sum of Squares.


   
   

Latest revision as of 19:05, 15 September 2023

New format available! This reference is now available in a new format that offers faster page load, improved display for calculations and images, more targeted search and the latest content available as a PDF. As of September 2023, this Reliawiki page will not continue to be updated. Please update all links and bookmarks to the latest reference at help.reliasoft.com/reference/experiment_design_and_analysis

Chapter Appendix G: DOE Glossary


DOEbox.png

Chapter Appendix G  
DOE Glossary  

Synthesis-icon.png

Available Software:
Weibull++

Examples icon.png

More Resources:
DOE examples



Alias

Two or more effects are said to be aliased in an experiment if these effects cannot be distinguished from each other. This happens when the columns of the design matrix corresponding to these effects are identical. As a result, the aliased effects are estimated by the same linear combination of observations instead of each effect being estimated by a unique combination.


ANOVA

ANOVA is the acronym for Analysis of Variance. It refers to the procedure of splitting the variability of a data set to conduct various significance tests.


ANOVA Model

The regression model where all factors are treated as qualitative factors. ANOVA models are used in the analysis of experiments to identify significant factors by investigating each level of the factors individually.


Balanced Design

An experiment in which equal number of observations are taken for each treatment.


Blocking

Separation of experiment runs based on the levels of a nuisance factor. Blocking is used to deal with known nuisance factors. You should block what you can and randomize what you cannot. See also Nuisance Factors, Randomization.


Center Point

The experiment run that corresponds to the mid-level of all the factor ranges.


Coded Values

The factor values that are such that the upper limit of the investigated range of the factor becomes +1 and the lower limit becomes -1. Using coded values makes the experiments with all factors at two levels orthogonal.


Confidence Interval

A closed interval where a certain percentage of the population is likely to lie. For example, a 90% confidence interval with a lower limit of A and an upper limit of B implies that 90% of the population lies between the values of A and B.


Confounding

Confounding occurs in a design when certain effects cannot be distinguished from the block effect. This happens when full factorial designs are run using incomplete blocks. In such designs the same linear combination of observations estimates the block effect and the confounded effects. See also Incomplete Blocks.


Contrast

Any linear combination of two or more factor level means such that the coefficients in the combination add up to zero. The difference between the means at any two levels of a factor is an example of a contrast.


Control Factors

The factors affecting the response that are easily manipulated and set by the operator. See also Noise Factors.


Cross Array Design

The experiment design in which every treatment of the inner array is replicated for each run of the outer array. See also Inner Array, Outer Array.


Curvature Test

The test that investigates if the relation between the response and the factors is linear by using center points. See also Center Point.


Defining Relation

For two level fractional factorial experiments, the equation that is used to obtain the fraction from the full factorial experiment. The equation shows which of the columns of the design matrix in the fraction are identical to the first column. For example, the defining relation I=ABC can be used to obtain a half-fraction of the two level full factorial experiment with three factors A, B and C. The effects used in the equation are called the generators or words.


Degrees of Freedom

The number of independent observations made in excess of the unknowns.


Design Matrix

The matrix whose columns correspond to the levels of the variables (and their interactions) at which observations are recorded.


Design Resolution

The number of factors in the smallest word in a defining relation. Design resolution indicates the degree of aliasing in a fractional factorial design. See also Defining Relation, Word.


Error

The natural variations that occur in a process, even when all the factors are maintained at the same level. See also Residual.


Error Sum of Squares

The variation in the data not captured by the model. The error sum of squares is also called the residual sum of squares. See also Model Sum of Squares, Total Sum of Squares.


Extra Sum of Squares

The increase in the model sum of squares when a term is added to the model.


Factorial Experiment

The experiment in which all combinations of the factor levels are run.


Fractional Factorial Experiment

The experiment where only a fraction of the combinations of the factor levels are run.


Factor

The entity whose effect on the response is investigated in the experiment.


Fitted Value

The estimate of an observation obtained using the model that has been fit to all the observations.


Fixed Effects Model

The ANOVA model used in the experiments where only a limited number of the factor levels are of interest to the experimenter. See also Random Effects Model.


Full Model

The model that includes all the main effects and their interactions. In Weibull++ DOE folios, a full model is the model that contains all the effects that are specified by the user. See also Reduced Model.


Generator

See Word.


Hierarchical Model

In Weibull++ DOE folios, a model is said to be hierarchical if, corresponding to every interaction, the main effects of the related factors are included in the model.


Incomplete Blocks

Blocks that do not contain all the treatments of a factorial experiment.


Inner Array

The experiment design used to investigate the control factors under Taguchi's philosophy to design a robust system. See also Robust System, Outer Array, Cross Array.


Interactions

Interaction between factors means that the effect produced by a change in a factor on the response depends on the level of the other factor(s).


Lack-of-Fit Sum of Squares

The portion of the error sum of squares that represents variation in the data not captured because of using a reduced model. See also Reduced Model, Pure Error Sum of Squares.


Least Squares Means

The predicted mean response value for a given factor level while the remaining factors in the model are set to the coded value of zero.


Level

The setting of a factor used in the experiment.


Main Effect

The change in the response due to a change in the level of a factor.


Mean Square

The sum of squares divided by the respective degrees of freedom.


Model Sum of Squares

The portion of the total variability in the data that is explained by the model. See also Error Sum of Squares, Total Sum of Squares.


Multicollinearity

A model with strong dependencies between the independent variables is said to have multicollinearity.


New Observations

Observations that are not part of the data set used to fit the model.


Noise Factors

Those nuisance factors that vary uncontrollably or naturally and can only be controlled for experimental purposes. For example, ambient temperature, atmospheric pressure and humidity are examples of noise factors.


Nuisance Factors

Factors that have an effect on the response but are not of primary interest to the investigator.


Orthogonal Array

An array in which all the columns are orthogonal to each other. Two columns are said to be orthogonal if the sum of the terms resulting from the product of the columns is zero.


Orthogonal Design

An experiment design is orthogonal if the corresponding design matrix is such that the sum of the terms resulting from the product of any two columns is zero. In orthogonal designs the analysis of an effect does not depend on what other effects are included in the model.


Outer Array

The experiment design used to investigate noise factors under Taguchi's philosophy to design a robust system. See also Robust System, Inner Array, Cross Array.


Partial Sum of Squares

The type of extra sum of squares that is calculated assuming that all terms other than the given term are included in the model. The partial sum of squares is also referred to as the adjusted sum of squares. See also Extra Sum of Squares, Sequential Sum of Squares.


Prediction Interval

The confidence interval on new observations.


Pure Error Sum of Squares

The portion of the error sum of squares that represents variation due to replicates. See also Lack-of-Fit Sum of Squares.


Qualitative Factor

The factor where the levels represent different categories and no numerical ordering is implied. These factors are also called categorical factors.


Random Effects Model

The ANOVA model used in the experiments where the factor levels to be investigated are randomly selected from a large or infinite population. See also Fixed Effects Model.


Randomization

Conducting experiment runs in a random order to cancel out the effect of unknown nuisance factors. See also Blocking.


Randomized Complete Block Design

An experiment design where each block contains one replicate of the experiment and runs within the block are subjected to randomization.


Reduced Model

A model that does not contain all the main effects and interactions. In Weibull++ DOE folios, a reduced model is the model that does not contain all the effects specified by the user. See also Full Model.


Regression Model

A model that attempts to explain the relationship between two or more variables.


Repeated Runs

Experiment runs corresponding to the same treatment that are conducted at the same time.


Replicated Runs

Experiment runs corresponding to the same treatment that are conducted in a random order.


Residual

An estimate of error which is obtained by calculating the difference between an observation and the corresponding fitted value. See also Error, Fitted Value.


Residual Sum of Squares

See Error Sum of Squares.


Response

The quantity that is investigated in an experiment to see which of the factors affect it.


Robust System

A system that is insensitive to the effects of noise factors.


Rotatable Design

A design is rotatable if the variance of the predicted response at any point depends only on the distance of the point from the design center point.


Screening Designs

Experiments that use only a few runs to filter out important main effects and lower order interactions by assuming that higher order interactions are unimportant.


Sequential Sum of Squares

The type of extra sum of squares that is calculated assuming that all terms preceding the given term are included in the model. See also Extra Sum of Squares, Partial Sum of Squares.


Signal to Noise Ratio

The ratios defined by Taguchi to measure variation in the response caused by the noise factors.


Standard Order

The order of the treatments such that factors are introduced one by one with each new factor being combined with the preceding terms.


Sum of Squares

The quantity that is used to measure either a part or all of the variation in a data set.


Total Sum of Squares

The sum of squares that represent all of the variation in a data set.


Transformation

The mathematical function that makes the data follow a given characteristic. In the analysis of experiments transformation is used on the response data to make it follow the normal distribution.


Treatment

The levels of a factor in a single factor experiment are also referred to as treatments. In experiments with many factors a combination of the levels of the factors is referred to as a treatment.


Word

The effect used in the defining relation. For example, for the defining relation I=ABC, the word is ABC.