The design of experiments (DOE, DOX, or experimental design)
is the design of any task that aims to describe or explain the
variation of information under conditions that are hypothesized to
reflect the variation. The term is generally associated with experiments in which the design introduces conditions that directly affect the variation, but may also refer to the design of quasi-experiments, in which natural conditions that influence the variation are selected for observation.
In its simplest form, an experiment aims at predicting the
outcome by introducing a change of the preconditions, which is
represented by one or more independent variables,
also referred to as "input variables" or "predictor variables." The
change in one or more independent variables is generally hypothesized to
result in a change in one or more dependent variables, also referred to as "output variables" or "response variables." The experimental design may also identify control variables
that must be held constant to prevent external factors from affecting
the results. Experimental design involves not only the selection of
suitable independent, dependent, and control variables, but planning the
delivery of the experiment under statistically optimal conditions given
the constraints of available resources. There are multiple approaches
for determining the set of design points (unique combinations of the
settings of the independent variables) to be used in the experiment.
Main concerns in experimental design include the establishment of validity, reliability, and replicability.
For example, these concerns can be partially addressed by carefully
choosing the independent variable, reducing the risk of measurement
error, and ensuring that the documentation of the method is sufficiently
detailed. Related concerns include achieving appropriate levels of statistical power and sensitivity.
Correctly designed experiments advance knowledge in the natural
and social sciences and engineering. Other applications include
marketing and policy making.
History
Systematic clinical trials
In 1747, while serving as surgeon on HMS Salisbury, James Lind carried out a systematic clinical trial to compare remedies for scurvy. This systematic clinical trial constitutes a type of DOE.
Lind selected 12 men from the ship, all suffering from scurvy.
Lind limited his subjects to men who "were as similar as I could have
them," that is, he provided strict entry requirements to reduce
extraneous variation. He divided them into six pairs, giving each pair
different supplements to their basic diet for two weeks. The treatments
were all remedies that had been proposed:
- A quart of cider every day.
- Twenty five gutts (drops) of vitriol (sulphuric acid) three times a day upon an empty stomach.
- One half-pint of seawater every day.
- A mixture of garlic, mustard, and horseradish in a lump the size of a nutmeg.
- Two spoonfuls of vinegar three times a day.
- Two oranges and one lemon every day.
The citrus treatment stopped after six days when they ran out of
fruit, but by that time one sailor was fit for duty while the other had
almost recovered. Apart from that, only group one (cider) showed some
effect of its treatment. The remainder of the crew presumably served as
a control, but Lind did not report results from any control (untreated)
group.
Statistical experiments, following Charles S. Peirce
A theory of statistical inference was developed by Charles S. Peirce in "Illustrations of the Logic of Science" (1877–1878) and "A Theory of Probable Inference" (1883), two publications that emphasized the importance of randomization-based inference in statistics.
Randomized experiments
Charles S. Peirce randomly assigned volunteers to a blinded, repeated-measures design to evaluate their ability to discriminate weights.
Peirce's experiment inspired other researchers in psychology and
education, which developed a research tradition of randomized
experiments in laboratories and specialized textbooks in the 1800s.
Optimal designs for regression models
Charles S. Peirce also contributed the first English-language publication on an optimal design for regression models in 1876. A pioneering optimal design for polynomial regression was suggested by Gergonne in 1815. In 1918, Kirstine Smith published optimal designs for polynomials of degree six (and less).
Sequences of experiments
The use of a sequence of experiments, where the design of each may
depend on the results of previous experiments, including the possible
decision to stop experimenting, is within the scope of Sequential analysis, a field that was pioneered by Abraham Wald in the context of sequential tests of statistical hypotheses. Herman Chernoff wrote an overview of optimal sequential designs, while adaptive designs have been surveyed by S. Zacks. One specific type of sequential design is the "two-armed bandit", generalized to the multi-armed bandit, on which early work was done by Herbert Robbins in 1952.
Fisher's principles
A methodology for designing experiments was proposed by Ronald Fisher, in his innovative books: The Arrangement of Field Experiments (1926) and The Design of Experiments
(1935). Much of his pioneering work dealt with agricultural
applications of statistical methods. As a mundane example, he described
how to test the lady tasting tea hypothesis,
that a certain lady could distinguish by flavour alone whether the milk
or the tea was first placed in the cup. These methods have been broadly
adapted in the physical and social sciences, are still used in agricultural engineering and differ from the design and analysis of computer experiments.
- Comparison
- In some fields of study it is not possible to have independent measurements to a traceable metrology standard. Comparisons between treatments are much more valuable and are usually preferable, and often compared against a scientific control or traditional treatment that acts as baseline.
- Randomization
- Random assignment is the process of assigning individuals at random to groups or to different groups in an experiment, so that each individual of the population has the same chance of becoming a participant in the study. The random assignment of individuals to groups (or conditions within a group) distinguishes a rigorous, "true" experiment from an observational study or "quasi-experiment". There is an extensive body of mathematical theory that explores the consequences of making the allocation of units to treatments by means of some random mechanism (such as tables of random numbers, or the use of randomization devices such as playing cards or dice). Assigning units to treatments at random tends to mitigate confounding, which makes effects due to factors other than the treatment to appear to result from the treatment.
- The risks associated with random allocation (such as having a serious imbalance in a key characteristic between a treatment group and a control group) are calculable and hence can be managed down to an acceptable level by using enough experimental units. However, if the population is divided into several subpopulations that somehow differ, and the research requires each subpopulation to be equal in size, stratified sampling can be used. In that way, the units in each subpopulation are randomized, but not the whole sample. The results of an experiment can be generalized reliably from the experimental units to a larger statistical population of units only if the experimental units are a random sample from the larger population; the probable error of such an extrapolation depends on the sample size, among other things.
- Statistical replication
- Measurements are usually subject to variation and measurement uncertainty; thus they are repeated and full experiments are replicated to help identify the sources of variation, to better estimate the true effects of treatments, to further strengthen the experiment's reliability and validity, and to add to the existing knowledge of the topic. However, certain conditions must be met before the replication of the experiment is commenced: the original research question has been published in a peer-reviewed journal or widely cited, the researcher is independent of the original experiment, the researcher must first try to replicate the original findings using the original data, and the write-up should state that the study conducted is a replication study that tried to follow the original study as strictly as possible.
- Blocking
- Blocking is the non-random arrangement of experimental units into groups (blocks/lots) consisting of units that are similar to one another. Blocking reduces known but irrelevant sources of variation between units and thus allows greater precision in the estimation of the source of variation under study.
- Orthogonality concerns the forms of comparison (contrasts) that can be legitimately and efficiently carried out. Contrasts can be represented by vectors and sets of orthogonal contrasts are uncorrelated and independently distributed if the data are normal. Because of this independence, each orthogonal treatment provides different information to the others. If there are T treatments and T – 1 orthogonal contrasts, all the information that can be captured from the experiment is obtainable from the set of contrasts.
- Factorial experiments
- Use of factorial experiments instead of the one-factor-at-a-time method. These are efficient at evaluating the effects and possible interactions of several factors (independent variables). Analysis of experiment design is built on the foundation of the analysis of variance, a collection of models that partition the observed variance into components, according to what factors the experiment must estimate or test.
Example
This example is attributed to Harold Hotelling. It conveys some of the flavor of those aspects of the subject that involve combinatorial designs.
Weights of eight objects are measured using a pan balance
and set of standard weights. Each weighing measures the weight
difference between objects in the left pan vs. any objects in the right
pan by adding calibrated weights to the lighter pan until the balance is
in equilibrium. Each measurement has a random error. The average error is zero; the standard deviations of the probability distribution of the errors is the same number σ on different weighings; errors on different weighings are independent. Denote the true weights by
We consider two different experiments:
- Weigh each object in one pan, with the other pan empty. Let Xi be the measured weight of the object, for i = 1, ..., 8.
- Do the eight weighings according to the following schedule and let Yi be the measured difference for i = 1, ..., 8:
- Then the estimated value of the weight θ1 is
- Similar estimates can be found for the weights of the other items. For example
The question of design of experiments is: which experiment is better?
The variance of the estimate X1 of θ1 is σ2 if we use the first experiment. But if we use the second experiment, the variance of the estimate given above is σ2/8.
Thus the second experiment gives us 8 times as much precision for the
estimate of a single item, and estimates all items simultaneously, with
the same precision. What the second experiment achieves with eight would
require 64 weighings if the items are weighed separately. However, note
that the estimates for the items obtained in the second experiment have
errors that correlate with each other.
Many problems of the design of experiments involve combinatorial designs, as in this example and others.
Avoiding false positives
False positive conclusions, often resulting from the pressure to publish or the author's own confirmation bias,
are an inherent hazard in many fields. A good way to prevent biases
potentially leading to false positives in the data collection phase is
to use a double-blind design. When a double-blind design is used,
participants are randomly assigned to experimental groups but the
researcher is unaware of what participants belong to which group.
Therefore, the researcher can not affect the participants' response to
the intervention.
Experimental designs with undisclosed degrees of freedom are a problem. This can lead to conscious or unconscious "p-hacking":
trying multiple things until you get the desired result. It typically
involves the manipulation - perhaps unconsciously - of the process of statistical analysis and the degrees of freedom until they return a figure below the p less than 0.05 level of statistical significance.
So the design of the experiment should include a clear statement
proposing the analyses to be undertaken. P-hacking can be prevented by
preregistering researches, in which researchers have to send their data
analysis plan to the journal they wish to publish their paper in before
they even start their data collection, so no data manipulation is
possible (https://osf.io).
Another way to prevent this is taking the double-blind design to the
data-analysis phase, where the data are sent to a data-analyst unrelated
to the research who scrambles up the data so there is no way to know
which participants belong to before they are potentially taken away as
outliers.
Clear and complete documentation of the experimental methodology is also important in order to support replication of results.
Discussion topics when setting up an experimental design
An
experimental design or randomized clinical trial requires careful
consideration of several factors before actually doing the experiment.
An experimental design is the laying out of a detailed experimental
plan in advance of doing the experiment. Some of the following topics
have already been discussed in the principles of experimental design
section:
- How many factors does the design have, and are the levels of these factors fixed or random?
- Are control conditions needed, and what should they be?
- Manipulation checks; did the manipulation really work?
- What are the background variables?
- What is the sample size. How many units must be collected for the experiment to be generalisable and have enough power?
- What is the relevance of interactions between factors?
- What is the influence of delayed effects of substantive factors on outcomes?
- How do response shifts affect self-report measures?
- How feasible is repeated administration of the same measurement instruments to the same units at different occasions, with a post-test and follow-up tests?
- What about using a proxy pretest?
- Are there lurking variables?
- Should the client/patient, researcher or even the analyst of the data be blind to conditions?
- What is the feasibility of subsequent application of different conditions to the same units?
- How many of each control and noise factors should be taken into account?
The independent variable of a study often has many levels or
different groups. In a true experiment, researchers can have an
experimental group, which is where their intervention testing the
hypothesis is implemented, and a control group, which has all the same
element as the experimental group, without the interventional element.
Thus, when everything else except for one intervention is held constant,
researchers can certify with some certainty that this one element is
what caused the observed change. In some instances, having a control
group is not ethical. This is sometimes solved using two different
experimental groups. In some cases, independent variables cannot be
manipulated, for example when testing the difference between two groups
who have a different disease, or testing the difference between genders
(obviously variables that would be hard or unethical to assign
participants to). In these cases, a quasi-experimental design may be
used.
Causal attributions
In
the pure experimental design, the independent (predictor) variable is
manipulated by the researcher - that is - every participant of the
research is chosen randomly from the population, and each participant
chosen is assigned randomly to conditions of the independent variable.
Only when this is done is it possible to certify with high probability
that the reason for the differences in the outcome variables are caused
by the different conditions. Therefore, researchers should choose the
experimental design over other design types whenever possible. However,
the nature of the independent variable does not always allow for
manipulation. In those cases, researchers must be aware of not
certifying about causal attribution when their design doesn't allow for
it. For example, in observational designs, participants are not assigned
randomly to conditions, and so if there are differences found in
outcome variables between conditions, it is likely that there is
something other than the differences between the conditions that causes
the differences in outcomes, that is - a third variable. The same goes
for studies with correlational design. (Adér & Mellenbergh, 2008).
Statistical control
It
is best that a process be in reasonable statistical control prior to
conducting designed experiments. When this is not possible, proper
blocking, replication, and randomization allow for the careful conduct
of designed experiments.
To control for nuisance variables, researchers institute control checks
as additional measures. Investigators should ensure that uncontrolled
influences (e.g., source credibility perception) do not skew the
findings of the study. A manipulation check
is one example of a control check. Manipulation checks allow
investigators to isolate the chief variables to strengthen support that
these variables are operating as planned.
One of the most important requirements of experimental research designs is the necessity of eliminating the effects of spurious, intervening, and antecedent variables.
In the most basic model, cause (X) leads to effect (Y). But there could
be a third variable (Z) that influences (Y), and X might not be the
true cause at all. Z is said to be a spurious variable and must be
controlled for. The same is true for intervening variables
(a variable in between the supposed cause (X) and the effect (Y)), and
anteceding variables (a variable prior to the supposed cause (X) that is
the true cause). When a third variable is involved and has not been
controlled for, the relation is said to be a zero order
relationship. In most practical applications of experimental research
designs there are several causes (X1, X2, X3). In most designs, only one
of these causes is manipulated at a time.
Experimental designs after Fisher
Some efficient designs for estimating several main effects were found independently and in near succession by Raj Chandra Bose and K. Kishen in 1940 at the Indian Statistical Institute, but remained little known until the Plackett–Burman designs were published in Biometrika in 1946. About the same time, C. R. Rao introduced the concepts of orthogonal arrays as experimental designs. This concept played a central role in the development of Taguchi methods by Genichi Taguchi,
which took place during his visit to Indian Statistical Institute in
early 1950s. His methods were successfully applied and adopted by
Japanese and Indian industries and subsequently were also embraced by US
industry albeit with some reservations.
In 1950, Gertrude Mary Cox and William Gemmell Cochran published the book Experimental Designs, which became the major reference work on the design of experiments for statisticians for years afterwards.
Developments of the theory of linear models have encompassed and surpassed the cases that concerned early writers. Today, the theory rests on advanced topics in linear algebra, algebra and combinatorics.
As with other branches of statistics, experimental design is pursued using both frequentist and Bayesian approaches: In evaluating statistical procedures like experimental designs, frequentist statistics studies the sampling distribution while Bayesian statistics updates a probability distribution on the parameter space.
Some important contributors to the field of experimental designs are C. S. Peirce, R. A. Fisher, F. Yates, C. R. Rao, R. C. Bose, J. N. Srivastava, Shrikhande S. S., D. Raghavarao, W. G. Cochran, O. Kempthorne, W. T. Federer, V. V. Fedorov, A. S. Hedayat, J. A. Nelder, R. A. Bailey, J. Kiefer, W. J. Studden, A. Pázman, F. Pukelsheim, D. R. Cox, H. P. Wynn, A. C. Atkinson, G. E. P. Box and G. Taguchi.
The textbooks of D. Montgomery, R. Myers, and G. Box/W. Hunter/J.S.
Hunter have reached generations of students and practitioners.
Some discussion of experimental design in the context of system identification (model building for static or dynamic models) is given in and.
Human participant constraints
Laws and ethical considerations preclude some carefully designed
experiments with human subjects. Legal constraints are dependent on
jurisdiction. Constraints may involve
institutional review boards, informed consent
and confidentiality affecting both clinical (medical) trials and
behavioral and social science experiments.
In the field of toxicology, for example, experimentation is performed
on laboratory animals with the goal of defining safe exposure limits
for humans. Balancing
the constraints are views from the medical field. Regarding the randomization of patients,
"... if no one knows which therapy is better, there is no ethical
imperative to use one therapy or another." (p 380) Regarding
experimental design, "...it is clearly not ethical to place subjects
at risk to collect data in a poorly designed study when this situation
can be easily avoided...". (p 393)