In
statistics
Statistics (from German language, German: ''wikt:Statistik#German, Statistik'', "description of a State (polity), state, a country") is the discipline that concerns the collection, organization, analysis, interpretation, and presentation of ...
, fractional factorial designs are
experimental design
The design of experiments (DOE, DOX, or experimental design) is the design of any task that aims to describe and explain the variation of information under conditions that are hypothesized to reflect the variation. The term is generally associ ...
s consisting of a carefully chosen subset (fraction) of the experimental runs of a full
factorial design
In statistics, a full factorial experiment is an experiment whose design consists of two or more factors, each with discrete possible values or "levels", and whose experimental units take on all possible combinations of these levels across all ...
.
The subset is chosen so as to exploit the
sparsity-of-effects principle In the statistical analysis of the results from factorial experiments, the sparsity-of-effects principle states that a system is usually dominated by main effects and low-order interactions
Interaction is action that occurs between two or more o ...
to expose information about the most important features of the problem studied, while using a fraction of the effort of a full
factorial design
In statistics, a full factorial experiment is an experiment whose design consists of two or more factors, each with discrete possible values or "levels", and whose experimental units take on all possible combinations of these levels across all ...
in terms of experimental runs and resources. In other words, it makes use of the fact that many experiments in full
factorial design
In statistics, a full factorial experiment is an experiment whose design consists of two or more factors, each with discrete possible values or "levels", and whose experimental units take on all possible combinations of these levels across all ...
are often
redundant, giving little or no new information about the system.
Notation
Fractional designs are expressed using the notation ''l''
k − p, where ''l'' is the number of levels of each factor investigated, ''k'' is the number of factors investigated, and ''p'' describes the size of the fraction of the full factorial used. Formally, ''p'' is the number of ''generators'', assignments as to which effects or
interaction
Interaction is action that occurs between two or more objects, with broad use in philosophy and the sciences. It may refer to:
Science
* Interaction hypothesis, a theory of second language acquisition
* Interaction (statistics)
* Interactions o ...
s are ''confounded'', ''i.e.'', cannot be estimated independently of each other (see below). A design with ''p'' such generators is a 1/(''l
p'')=''l
−p'' fraction of the full factorial design.
For example, a 2
5 − 2 design is 1/4 of a two level, five factor factorial design. Rather than the 32 runs that would be required for the full 2
5 factorial experiment, this experiment requires only eight runs.
In practice, one rarely encounters ''l'' > 2 levels in fractional factorial designs, since
response surface methodology
In statistics, response surface methodology (RSM) explores the relationships between several explanatory variables and one or more response variables. The method was introduced by George E. P. Box and K. B. Wilson in 1951. The main idea of RSM ...
is a much more experimentally efficient way to determine the relationship between the experimental response and factors at multiple levels. In addition, the methodology to generate such designs for more than two levels is much more cumbersome.
The levels of a factor are commonly coded as +1 for the higher level, and −1 for the lower level. For a three-level factor, the intermediate value is coded as 0.
To save space, the points in a two-level factorial experiment are often abbreviated with strings of plus and minus signs. The strings have as many symbols as factors, and their values dictate the level of each factor: conventionally,
for the first (or low) level, and
for the second (or high) level. The points in this experiment can thus be represented as
,
,
, and
.
The factorial points can also be abbreviated by (1), a, b, and ab, where the presence of a letter indicates that the specified factor is at its high (or second) level and the absence of a letter indicates that the specified factor is at its low (or first) level (for example, "a" indicates that factor A is on its high setting, while all other factors are at their low (or first) setting). (1) is used to indicate that all factors are at their lowest (or first) values.
Generation
In practice, experimenters typically rely on statistical reference books to supply the "standard" fractional factorial designs, consisting of the ''principal fraction''. The ''principal fraction'' is the set of treatment combinations for which the generators evaluate to + under the treatment combination algebra. However, in some situations, experimenters may take it upon themselves to generate their own fractional design.
A fractional factorial experiment is generated from a full factorial experiment by choosing an ''alias structure''. The alias structure determines which effects are confounded with each other. For example, the five factor 2
5 − 2 can be generated by using a full three factor factorial experiment involving three factors (say ''A'','' B'', and ''C'') and then choosing to confound the two remaining factors ''D'' and ''E'' with interactions generated by ''D'' = ''A''*''B'' and ''E'' = ''A''*''C''. These two expressions are called the ''generators'' of the design. So for example, when the experiment is run and the experimenter estimates the effects for factor ''D'', what is really being estimated is a combination of the main effect of ''D'' and the two-factor interaction involving ''A'' and ''B''.
An important characteristic of a fractional design is the defining
relation
Relation or relations may refer to:
General uses
*International relations, the study of interconnection of politics, economics, and law on a global level
*Interpersonal relationship, association or acquaintance between two or more people
*Public ...
, which gives the set of interaction columns equal in the design matrix to a column of plus signs, denoted by ''I''. For the above example, since ''D'' = ''AB'' and ''E'' = ''AC'', then ''ABD'' and ''ACE'' are both columns of plus signs, and consequently so is ''BDCE''. In this case the defining relation of the fractional design is ''I'' = ''ABD'' = ''ACE'' = ''BCDE''. The defining relation allows the alias pattern of the design to be determined.
Resolution
An important property of a fractional design is its resolution or ability to separate main effects and low-order interactions from one another. Formally, if the factors are binary then the resolution of the design is the minimum word length in the defining relation excluding (''1''). The most important fractional designs are those of resolution III, IV, and V: Resolutions below III are not useful and resolutions above V are wasteful (with binary factors) in that the expanded experimentation has no practical benefit in most cases—the bulk of the additional effort goes into the estimation of very high-order interactions which rarely occur in practice. The 2
5 − 2 design above is resolution III since its defining relation is I = ABD = ACE = BCDE.
The resolution described is only used for regular designs. Regular designs have run size that equal a power of two, and only full aliasing is present. Nonregular designs are designs where run size is a multiple of 4; these designs introduce partial aliasing, and generalized resolution is used as design criterion instead of the resolution described previously.
Example fractional factorial experiment
Montgomery
[
] gives the following example of a fractional factorial experiment. An engineer performed an experiment to increase the filtration rate (output) of a process to produce a chemical, and to reduce the amount of formaldehyde used in the process. The full factorial experiment is described in the Wikipedia page
Factorial experiment
In statistics, a full factorial experiment is an experiment whose design consists of two or more factors, each with discrete possible values or "levels", and whose experimental units take on all possible combinations of these levels across all s ...
. Four factors were considered: temperature (A), pressure (B), formaldehyde concentration (C), and stirring rate (D). The results in that example were that the main effects A, C, and D and the AC and AD interactions were significant. The results of that example may be used to simulate a fractional factorial experiment using a half-fraction of the original 2
''4'' = 16 run design. The table shows the 2
''4''-''1'' = 8 run half-fraction experiment design and the resulting filtration rate, extracted from the table for the full 16 run
factorial experiment
In statistics, a full factorial experiment is an experiment whose design consists of two or more factors, each with discrete possible values or "levels", and whose experimental units take on all possible combinations of these levels across all s ...
.
In this fractional design, each main effect is aliased with a 3-factor interaction (e.g., A = BCD), and every 2-factor interaction is aliased with another 2-factor interaction (e.g., AB = CD). The aliasing relationships are shown in the table. This is a resolution IV design, meaning that main effects are aliased with 3-way interactions, and 2-way interactions are aliased with 2-way interactions.
The analysis of variance estimates of the effects are shown in the table below. From inspection of the table, there appear to be large effects due to A, C, and D. The coefficient for the AB interaction is quite small. Unless the AB and CD interactions have approximately equal but opposite effects, these two interactions appear to be negligible. If A, C, and D have large effects, but B has little effect, then the AC and AD interactions are most likely significant. These conclusions are consistent with the results of the full-factorial 16-run experiment.
Because B and its interactions appear to be insignificant, B may be dropped from the model. Dropping B results in a full factorial 2
''3'' design for the factors A, C, and D. Performing the anova using factors A, C, and D, and the interaction terms A:C and A:D, gives the results shown in the table, which are very similar to the results for the full
factorial experiment
In statistics, a full factorial experiment is an experiment whose design consists of two or more factors, each with discrete possible values or "levels", and whose experimental units take on all possible combinations of these levels across all s ...
experiment, but have the advantage of requiring only a half-fraction 8 runs rather than 16.
External links
Full Factorial and Fractional Factorial Experiments: Frequently Asked Questions (The Methodology Center, Penn State University)
See also
*
Robust parameter designs
References
{{DEFAULTSORT:Fractional Factorial Design
Design of experiments
Statistical process control