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What Is a Control Group?

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A control group in a scientific experiment is a group separated from the rest of the experiment, where the independent variable being tested cannot influence the results. This isolates the independent variable's effects on the experiment and can help rule out alternative explanations of the experimental results.

A control group definition can also be separated into two other types: positive or negative.

Positive control groups are groups where the conditions of the experiment are set to guarantee a positive result. A positive control group can show the experiment is functioning properly as planned.

Negative control groups are groups where the conditions of the experiment are set to cause a negative outcome.

Control groups are not necessary for all scientific experiments. Controls are extremely useful when the experimental conditions are complex and difficult to isolate.

Example of a Negative Control Group

Negative control groups are particularly common in science fair experiments , to teach students how to identify the independent variable . A simple example of a control group can be seen in an experiment in which the researcher tests whether or not a new fertilizer affects plant growth. The negative control group would be the plants grown without fertilizer but under the same conditions as the experimental group. The only difference between the experimental group would be whether or not the fertilizer was used.

Several experimental groups could differ in the fertilizer concentration, application method, etc. The null hypothesis would be that the fertilizer does not affect plant growth. Then, if a difference is seen in the growth rate or the height of plants over time, a strong correlation between fertilizer and growth would be established. Note the fertilizer could have a negative impact on growth rather than positive. Or, for some reason, the plants might not grow at all. The negative control group helps establish the experimental variable is the cause of atypical growth rather than some other (possibly unforeseen) variable.

Example of a Positive Control Group

A positive control demonstrates an experiment is capable of producing a positive result. For example, let's say you are examining bacterial susceptibility to a drug. You might use a positive control to make sure the growth medium is capable of supporting any bacteria. You could culture bacteria known to carry the drug resistance marker, so they should be capable of surviving on a drug-treated medium. If these bacteria grow, you have a positive control that shows other drug-resistant bacteria should be capable of surviving the test.

The experiment could also include a negative control. You could plate bacteria known not to carry a drug-resistant marker. These bacteria should be unable to grow on the drug-laced medium. If they do grow, you know there is a problem with the experiment .

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Control Group Definition and Examples

The control group is the set of subjects that does not receive the treatment in a study. In other words, it is the group where the independent variable is held constant. This is important because the control group is a baseline for measuring the effects of a treatment in an experiment or study. A controlled experiment is one which includes one or more control groups.

• The experimental group experiences a treatment or change in the independent variable. In contrast, the independent variable is constant in the control group.
• A control group is important because it allows meaningful comparison. The researcher compares the experimental group to it to assess whether or not there is a relationship between the independent and dependent variable and the magnitude of the effect.
• There are different types of control groups. A controlled experiment has one more control group.

Control Group vs Experimental Group

The only difference between the control group and experimental group is that subjects in the experimental group receive the treatment being studied, while participants in the control group do not. Otherwise, all other variables between the two groups are the same.

Control Group vs Control Variable

A control group is not the same thing as a control variable. A control variable or controlled variable is any factor that is held constant during an experiment. Examples of common control variables include temperature, duration, and sample size. The control variables are the same for both the control and experimental groups.

Types of Control Groups

There are different types of control groups:

• Placebo group : A placebo group receives a placebo , which is a fake treatment that resembles the treatment in every respect except for the active ingredient. Both the placebo and treatment may contain inactive ingredients that produce side effects. Without a placebo group, these effects might be attributed to the treatment.
• Positive control group : A positive control group has conditions that guarantee a positive test result. The positive control group demonstrates an experiment is capable of producing a positive result. Positive controls help researchers identify problems with an experiment.
• Negative control group : A negative control group consists of subjects that are not exposed to a treatment. For example, in an experiment looking at the effect of fertilizer on plant growth, the negative control group receives no fertilizer.
• Natural control group : A natural control group usually is a set of subjects who naturally differ from the experimental group. For example, if you compare the effects of a treatment on women who have had children, the natural control group includes women who have not had children. Non-smokers are a natural control group in comparison to smokers.
• Randomized control group : The subjects in a randomized control group are randomly selected from a larger pool of subjects. Often, subjects are randomly assigned to either the control or experimental group. Randomization reduces bias in an experiment. There are different methods of randomly assigning test subjects.

Control Group Examples

Here are some examples of different control groups in action:

Negative Control and Placebo Group

For example, consider a study of a new cancer drug. The experimental group receives the drug. The placebo group receives a placebo, which contains the same ingredients as the drug formulation, minus the active ingredient. The negative control group receives no treatment. The reason for including the negative group is because the placebo group experiences some level of placebo effect, which is a response to experiencing some form of false treatment.

Positive and Negative Controls

For example, consider an experiment looking at whether a new drug kills bacteria. The experimental group exposes bacterial cultures to the drug. If the group survives, the drug is ineffective. If the group dies, the drug is effective.

The positive control group has a culture of bacteria that carry a drug resistance gene. If the bacteria survive drug exposure (as intended), then it shows the growth medium and conditions allow bacterial growth. If the positive control group dies, it indicates a problem with the experimental conditions. A negative control group of bacteria lacking drug resistance should die. If the negative control group survives, something is wrong with the experimental conditions.

• Bailey, R. A. (2008).  Design of Comparative Experiments . Cambridge University Press. ISBN 978-0-521-68357-9.
• Chaplin, S. (2006). “The placebo response: an important part of treatment”.  Prescriber . 17 (5): 16–22. doi: 10.1002/psb.344
• Hinkelmann, Klaus; Kempthorne, Oscar (2008).  Design and Analysis of Experiments, Volume I: Introduction to Experimental Design  (2nd ed.). Wiley. ISBN 978-0-471-72756-9.
• Pithon, M.M. (2013). “Importance of the control group in scientific research.” Dental Press J Orthod . 18 (6):13-14. doi: 10.1590/s2176-94512013000600003
• Stigler, Stephen M. (1992). “A Historical View of Statistical Concepts in Psychology and Educational Research”. American Journal of Education . 101 (1): 60–70. doi: 10.1086/444032

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Control Group

What is a control group in an experiment.

A control group is a set of subjects in an experiment who are not exposed to the independent variable. The purpose of a control group is to serve as a baseline for comparison. By having a group that is not exposed to the treatment, researchers can compare the results of the experimental group and determine whether the independent variable had an impact.

In some cases, there may be more than one control group. This is often done when there are multiple treatments or when researchers want to compare different groups of subjects. Having multiple control groups allows researchers to isolate the effect of each treatment and better understand how each one works.

Control groups are an important part of any experiment, as they help ensure that the results are accurate and reliable. Without a control group, it would be difficult to determine whether the results of an experiment are due to the independent variable or other factors.

When designing an experiment, it is important to carefully consider what kind of control group you will need. There are many different ways to set up a control group, and the best approach will depend on the specific goals of your research.

Control Group vs. Experimental Group

A control group is a group in an experiment that does not receive the experimental treatment. The purpose of a control group is to provide a baseline against which to compare the experimental group results.

An experimental group is a group in an experiment that receives the experimental treatment. The purpose of an experimental group is to test whether or not the experimental treatment has an effect.

The differences between control and experimental groups are important to consider when designing an experiment. The most important difference is that the control group provides a comparison for the results of the experimental group. This comparison is essential in order to determine whether or not the experimental treatment had an effect. Without a control group, it would be impossible to know if the results of the experiment are due to the treatment or not.

Another important difference between a control group and an experimental group is that the experimental group is the only group that receives the experimental treatment. This is necessary in order to ensure that any results seen in the experimental group can be attributed to the treatment and not to other factors.

Control groups and experimental groups are both essential parts of experiments. Without a control group, it would be impossible to know if the results of an experiment are due to the treatment or not. Without an experimental group, it would be impossible to test whether or not a treatment has an effect.

What Is the Purpose of a Control Group

The purpose of a control group is to serve as a baseline for comparison. By having a group that is not exposed to the treatment, researchers can compare the results of the experimental group and determine whether the independent variable had an impact.

Why Is a Control Group Important in an Experiment

A control group is an essential part of any experiment. It is a group of subjects who are not exposed to the independent variable being tested. The purpose of a control group is to provide a baseline against which the results from the treatment group can be compared.

Without a control group, it would be impossible to determine whether the results of an experiment are due to the treatment or some other factor. For example, imagine you are testing the effects of a new drug on patients with high blood pressure. If you did not have a control group, you would not know if the decrease in blood pressure was due to the drug or something else, such as the placebo effect.

A control group must be carefully designed to match the treatment group in all important respects, except for the one factor that is being tested. This ensures that any differences in the results can be attributed to the independent variable and not to other factors.

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The Importance of Control Group Analysis in Scientific Research

Explore the crucial role of control groups in scientific research, enhancing validity and ensuring accurate results.

Control groups are a fundamental component of scientific research, serving as a benchmark to measure the effects of experimental treatments. By comparing outcomes between the control group and the experimental group, researchers can attribute changes in the dependent variable to the independent variable, thus ensuring the internal validity of the study. Without control groups, it becomes challenging to draw accurate conclusions and determine the true efficacy of a treatment or intervention.

Key Takeaways

• Control groups are essential for ensuring the internal validity of scientific research.
• They serve as a baseline to compare the effects of the independent variable on the dependent variable.
• Control groups help in avoiding research biases and confounding variables.
• Different types of control groups, such as positive, negative, and placebo, are used depending on the study design.
• Properly designed control groups enhance the reproducibility and reliability of research findings.

The Role of Control Groups in Ensuring Internal Validity

Control groups are critical to the scientific method as they help ensure the internal validity of a study. Without a control group, it’s harder to be certain that the outcome was caused by the experimental treatment and not by other variables. This is essential for drawing accurate conclusions and avoiding research bias.

Defining Internal Validity

Internal validity refers to the extent to which a study can demonstrate a causal relationship between the treatment and the observed outcome. It ensures that the results are due to the independent variable and not other factors. Control groups play a pivotal role in maintaining this validity by providing a baseline for comparison.

How Control Groups Enhance Validity

Control groups help account for the placebo effect, where participants’ beliefs about the treatment can influence their behavior or responses. By comparing the treatment group to the control group, researchers can isolate the effect of the treatment itself. This increases the internal validity of the results and the confidence we can have in the conclusions.

Examples of Validity in Research

Consider a study testing a new medication for ADHD. One group receives the new medication, while the other group receives a placebo. The placebo group serves as the control group, allowing researchers to determine if changes in the treatment group are due to the medication or other variables. This method is crucial for the future of measurement: triangulating MTA, MMM, and incrementality testing . Triangulation offers a holistic view of marketing effectiveness, optimizing resource allocation for brands.

Types of Control Groups in Scientific Research

Control groups are critical to the scientific method as they help ensure the internal validity of a study. Using a control group means that any change in the dependent variable can be attributed to the independent variable. This helps avoid extraneous variables or confounding variables from impacting your work, as well as a few types of research bias, like omitted variable bias.

Positive Control Groups

Positive control groups are used to ensure that the experimental setup is capable of producing results. For example, if you are testing a new drug, a positive control group might receive a treatment that is already known to produce a certain effect. This helps to confirm that the experimental conditions are working as expected.

Negative Control Groups

Negative control groups are used to ensure that no confounding variable has affected the results. In a drug trial, a negative control group might receive a placebo, which is a treatment that has no therapeutic effect. This helps to show that any changes in the experimental group are due to the treatment itself and not some other factor.

Placebo Control Groups

Placebo control groups are a specific type of negative control group used in clinical trials. Participants in the placebo group receive a treatment that looks identical to the experimental treatment but has no active ingredient. This helps to account for the placebo effect, where participants experience changes simply because they believe they are receiving a treatment.

In clinical trials, the use of placebo control groups is essential for determining the true efficacy of a new treatment. Without this control, it would be difficult to distinguish between the actual effects of the treatment and the psychological impact of believing one is being treated.

Designing Experiments with Control Groups

Designing experiments with control groups is a critical aspect of scientific research. It ensures that the results are reliable and can be attributed to the variables being tested. Here, we will discuss the key elements involved in this process.

Random Assignment

Random assignment is the process of assigning participants to different groups using randomization. This method ensures that each participant has an equal chance of being placed in any group, thereby eliminating selection bias. Random assignment is crucial for maintaining the internal validity of an experiment. For example, in a marketing experiment design, participants might be randomly assigned to either a control group or an experimental group to test the effectiveness of a new advertising strategy.

Blinding and Control Groups

Blinding is a technique used to prevent bias in research. In a single-blind experiment, the participants do not know whether they are in the control group or the experimental group. In a double-blind experiment, neither the participants nor the researchers know who is in which group. This method is particularly useful in medical research, where the placebo effect can influence results. For instance, in a study testing a new drug, blinding ensures that neither the patients nor the doctors know who is receiving the actual medication and who is receiving a placebo.

Maintaining Consistency

Maintaining consistency across all groups in an experiment is essential for obtaining valid results. This means that all conditions, except for the variable being tested, should be kept the same for both the control and experimental groups. For example, in geo experiments, researchers might implement geo-based incrementality testing to measure the real impact of a marketing campaign. By keeping all other variables constant, they can accurately determine the effectiveness of the campaign.

In any well-designed experiment, the control group serves as a benchmark, allowing researchers to measure the true effect of the independent variable. This is especially important in fields like marketing budget planning, where understanding the actual impact of different strategies can lead to more informed decisions.

Challenges and Limitations of Control Group Analysis

Ethical considerations.

When conducting Control Group Analysis , researchers must navigate various ethical dilemmas. For instance, withholding a potentially beneficial treatment from the control group can raise ethical concerns. Balancing the need for rigorous scientific methods with ethical responsibilities is crucial. Researchers often use alternative methodologies to address these challenges, such as crossover designs where participants receive both the treatment and control conditions at different times.

Practical Limitations

Implementing control groups can be resource-intensive. Researchers may face constraints related to time, budget, and participant availability. These limitations can impact the scope and scale of the study. Additionally, maintaining consistency across control and treatment groups can be challenging, especially in long-term studies. Practical solutions include using automated systems for data collection and employing robust randomization techniques.

Addressing Confounding Variables

Confounding variables can significantly impact the validity of a study. These are variables that the researcher failed to control or eliminate, which can cause a false association between the treatment and the outcome. To mitigate this, researchers can use techniques like stratified randomization and matching. Identifying and addressing confounding variables is essential for enhancing the reliability of the results.

Ensuring the internal validity of your research often hinges on how well you manage these challenges. By addressing ethical considerations, practical limitations, and confounding variables, you can significantly improve the robustness of your Control Group Analysis.

Case Studies Highlighting the Importance of Control Groups

Medical research examples.

In medical research, control groups are indispensable for determining the effectiveness of new treatments . For instance, in a clinical trial for a new drug, one group receives the drug while the control group receives a placebo. This setup helps in measuring the Incremental Lift in patient recovery rates attributable to the drug, rather than other factors.

Control groups in medical research ensure that the observed effects are due to the treatment and not external variables.

Psychological Studies

Psychological studies often use control groups to understand the impact of various interventions. For example, a study on the effects of cognitive-behavioral therapy (CBT) for depression might have one group undergo CBT while the control group receives no treatment. This helps in isolating the Incremental Contribution of CBT to improvements in mental health.

Social Science Research

In social science research, control groups help in understanding societal trends and behaviors. For example, a study on the impact of educational programs on student performance might have a control group that does not participate in the program. This allows researchers to measure the Conversion Lift in academic performance due to the educational intervention.

Without control groups, it would be challenging to attribute changes in the dependent variable to the independent variable accurately.

Measuring the Effectiveness of Control Groups

Baseline comparisons.

An important factor when measuring the effectiveness of a control group is the uniformity of samples. Ensuring the control group is both random and representative of the entire population will lead to more dependable results. The control group serves as a baseline , enabling researchers to see what impact changes to the independent variable produce and strengthening researchers’ ability to draw conclusions from a study.

Without the presence of a control group, a researcher cannot determine whether a particular treatment truly has an effect on an experimental group.

Statistical Methods

A chi-squared statistic can reveal differences between the observed results and the results you would expect if there was no relationship in the data. For example, the expectation of variations to have zero impact on conversion rate can be tested using this method. Here are some steps to execute this analysis:

• Define the null hypothesis that there is no difference between the control and test groups.
• Collect data from both groups.
• Calculate the chi-squared statistic.
• Compare the calculated value with the critical value from the chi-squared distribution table.
• Draw conclusions based on the comparison.

Interpreting Results

When interpreting results, it is crucial to consider the size of the control group. The tradeoff between confidence levels in the results and the opportunity cost of implementing a more successful variation should not be taken lightly. For instance, if the experiment is run on a population size of only 100 participants, a 5% control group would be only 5 individuals, which would certainly diminish the significance of the results. Therefore, maintaining an adequately sized control group is essential for reliable conclusions.

The Impact of Control Groups on Research Outcomes

Drawing accurate conclusions.

Control groups are essential for drawing accurate conclusions in scientific research. By comparing the treatment group to the control group, researchers can isolate the effect of the independent variable. This helps in determining whether the observed changes are due to the treatment or other external factors. For instance, in medical research , a control group receiving a placebo can help identify the true efficacy of a new drug.

Avoiding Research Bias

Control groups play a crucial role in avoiding research bias. They help mitigate the impact of confounding variables and ensure that the results are not skewed by external influences. This is particularly important in psychological studies , where participant expectations can influence outcomes. By using control groups, researchers can ensure that any observed effects are due to the treatment itself and not other factors.

Enhancing Reproducibility

The use of control groups enhances the reproducibility of research findings. When other researchers can replicate the study and achieve similar results, it strengthens the validity of the original findings. This is vital for the advancement of scientific knowledge. For example, in social science research , control groups help in verifying the impact of interventions across different populations and settings.

Control groups are the backbone of rigorous scientific research, ensuring that findings are both valid and reliable.

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In conclusion, control group analysis is indispensable in scientific research. Control groups serve as a baseline, allowing researchers to attribute changes in the dependent variable directly to the independent variable, thereby ensuring the internal validity of the study. Without control groups, it becomes challenging to determine whether observed changes are due to the treatment or other extraneous variables. By providing a clear comparison, control groups enhance the reliability and credibility of research findings, making them a cornerstone of the scientific method. Therefore, the inclusion of control groups in experimental design is not just beneficial but essential for drawing accurate and meaningful conclusions.

Frequently Asked Questions

What is a control group in scientific research.

A control group is a group of participants in an experiment who do not receive the experimental treatment. They serve as a baseline to compare the results of the experimental group against.

Why are control groups important in scientific research?

Control groups help ensure the internal validity of research by providing a baseline. This allows researchers to determine if changes in the dependent variable are due to the independent variable or other factors.

What are the different types of control groups?

There are several types of control groups, including positive control groups, negative control groups, and placebo control groups. Each type serves a different purpose in validating the results of an experiment.

How do control groups enhance the validity of an experiment?

Control groups enhance validity by isolating the effect of the independent variable. This helps to avoid confounding variables and research biases, ensuring that the observed effects are due to the treatment.

What are some challenges associated with using control groups?

Challenges include ethical considerations, practical limitations, and the need to address confounding variables. Researchers must design their studies carefully to mitigate these issues.

Can you provide an example of a control group in research?

In medical research, a control group might receive a placebo while the experimental group receives the actual medication. This allows researchers to determine if the medication has a real effect compared to no treatment.

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What is a control group psychology?

What is a Control Group in Psychology?

In the realm of psychology, a control group is a crucial component of research design, particularly in experimental research. In this article, we will delve into the concept of a control group, its significance, and its role in the research process.

What is a Control Group?

A control group, also known as a control condition, is a group of participants in an experiment that does not receive the independent variable or treatment being tested. In other words, they do not receive the intervention or treatment that the experimental group receives. The purpose of a control group is to serve as a baseline or standard against which the results of the experimental group can be compared.

Why is a Control Group Important?

The control group is essential in experimental research because it allows researchers to:

• Isolate the effect of the independent variable : By comparing the results of the experimental group to the control group, researchers can identify the specific effects of the independent variable on the dependent variable. • Establish a baseline : The control group provides a baseline against which changes in the experimental group can be measured, allowing researchers to determine if the treatment or intervention has had a significant impact. • Control for extraneous variables : By having a control group, researchers can control for variables that might otherwise influence the results, such as age, sex, or environmental factors.

Types of Control Groups

There are different types of control groups, including:

• External control group : This type of control group is external to the experiment, meaning that it is a separate group that does not participate in the experiment.
• Internal control group : This type of control group is internal to the experiment, meaning that it is also part of the same experiment, but does not receive the independent variable or treatment.
• Historical control group : This type of control group is not actually part of the current experiment, but rather a previous group that received a different treatment.

Designing a Study with a Control Group

When designing a study with a control group, researchers must consider the following:

• Sample size : Ensure that the control group is large enough to provide reliable and generalizable results.
• Matching : Match the control group to the experimental group in terms of demographics, such as age, sex, and other relevant characteristics.
• Randomization : Randomly assign participants to the control group or experimental group.

Advantages and Disadvantages of Control Groups

Advantages:

• Improved accuracy : Control groups help to improve the accuracy of the results by controlling for extraneous variables.
• Increased precision : By controlling for variables, researchers can be more precise in their conclusions.
• Generalizability : Control groups allow for more generalizable results to a broader population.

Disadvantages:

• Increased complexity : Designing a study with a control group can be more complex and time-consuming.
• Higher costs : Conducting a study with a control group can be more expensive due to the need for a larger sample size and additional resources.
• Ethical concerns : Researchers must ensure that the control group is not disadvantaged or harmed in any way by the study.

In conclusion, a control group is a crucial component of experimental research in psychology, allowing researchers to isolate the effect of an independent variable, establish a baseline, and control for extraneous variables. By understanding the importance and types of control groups, as well as the advantages and disadvantages, researchers can design more effective and accurate studies. As researchers continue to investigate the complexities of human behavior, the control group will remain a vital tool in the pursuit of knowledge and understanding.

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• Control Groups and Treatment Groups | Uses & Examples

Control Groups & Treatment Groups | Uses & Examples

Published on 6 May 2022 by Lauren Thomas . Revised on 13 April 2023.

In a scientific study, a control group is used to establish a cause-and-effect relationship by isolating the effect of an independent variable .

Researchers change the independent variable in the treatment group and keep it constant in the control group. Then they compare the results of these groups.

Using a control group means that any change in the dependent variable can be attributed to the independent variable.

Table of contents

Control groups in experiments, control groups in non-experimental research, importance of control groups, frequently asked questions about control groups.

Control groups are essential to experimental design . When researchers are interested in the impact of a new treatment, they randomly divide their study participants into at least two groups:

• The treatment group (also called the experimental group ) receives the treatment whose effect the researcher is interested in.
• The control group receives either no treatment, a standard treatment whose effect is already known, or a placebo (a fake treatment).

The treatment is any independent variable manipulated by the experimenters, and its exact form depends on the type of research being performed. In a medical trial, it might be a new drug or therapy. In public policy studies, it could be a new social policy that some receive and not others.

In a well-designed experiment, all variables apart from the treatment should be kept constant between the two groups. This means researchers can correctly measure the entire effect of the treatment without interference from confounding variables .

• You pay the students in the treatment group for achieving high grades.
• Students in the control group do not receive any money.

Studies can also include more than one treatment or control group. Researchers might want to examine the impact of multiple treatments at once, or compare a new treatment to several alternatives currently available.

• The treatment group gets the new pill.
• Control group 1 gets an identical-looking sugar pill (a placebo).
• Control group 2 gets a pill already approved to treat high blood pressure.

Since the only variable that differs between the three groups is the type of pill, any differences in average blood pressure between the three groups can be credited to the type of pill they received.

• The difference between the treatment group and control group 1 demonstrates the effectiveness of the pill as compared to no treatment.
• The difference between the treatment group and control group 2 shows whether the new pill improves on treatments already available on the market.

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Although control groups are more common in experimental research, they can be used in other types of research too. Researchers generally rely on non-experimental control groups in two cases: quasi-experimental or matching design.

Control groups in quasi-experimental design

While true experiments rely on random assignment to the treatment or control groups, quasi-experimental design uses some criterion other than randomisation to assign people.

Often, these assignments are not controlled by researchers, but are pre-existing groups that have received different treatments. For example, researchers could study the effects of a new teaching method that was applied in some classes in a school but not others, or study the impact of a new policy that is implemented in one region but not in the neighbouring region.

In these cases, the classes that did not use the new teaching method, or the region that did not implement the new policy, is the control group.

Control groups in matching design

In correlational research , matching represents a potential alternate option when you cannot use either true or quasi-experimental designs.

In matching designs, the researcher matches individuals who received the ‘treatment’, or independent variable under study, to others who did not – the control group.

Each member of the treatment group thus has a counterpart in the control group identical in every way possible outside of the treatment. This ensures that the treatment is the only source of potential differences in outcomes between the two groups.

Control groups help ensure the internal validity of your research. You might see a difference over time in your dependent variable in your treatment group. However, without a control group, it is difficult to know whether the change has arisen from the treatment. It is possible that the change is due to some other variables.

If you use a control group that is identical in every other way to the treatment group, you know that the treatment – the only difference between the two groups – must be what has caused the change.

For example, people often recover from illnesses or injuries over time regardless of whether they’ve received effective treatment or not. Thus, without a control group, it’s difficult to determine whether improvements in medical conditions come from a treatment or just the natural progression of time.

Risks from invalid control groups

If your control group differs from the treatment group in ways that you haven’t accounted for, your results may reflect the interference of confounding variables instead of your independent variable.

Minimising this risk

A few methods can aid you in minimising the risk from invalid control groups.

• Ensure that all potential confounding variables are accounted for , preferably through an experimental design if possible, since it is difficult to control for all the possible confounders outside of an experimental environment.
• Use double-blinding . This will prevent the members of each group from modifying their behavior based on whether they were placed in the treatment or control group, which could then lead to biased outcomes.
• Randomly assign your subjects into control and treatment groups. This method will allow you to not only minimise the differences between the two groups on confounding variables that you can directly observe, but also those you cannot.

An experimental group, also known as a treatment group, receives the treatment whose effect researchers wish to study, whereas a control group does not. They should be identical in all other ways.

A true experiment (aka a controlled experiment) always includes at least one control group that doesn’t receive the experimental treatment.

However, some experiments use a within-subjects design to test treatments without a control group. In these designs, you usually compare one group’s outcomes before and after a treatment (instead of comparing outcomes between different groups).

For strong internal validity , it’s usually best to include a control group if possible. Without a control group, it’s harder to be certain that the outcome was caused by the experimental treatment and not by other variables.

In a controlled experiment , all extraneous variables are held constant so that they can’t influence the results. Controlled experiments require:

• A control group that receives a standard treatment, a fake treatment, or no treatment
• Random assignment of participants to ensure the groups are equivalent

Depending on your study topic, there are various other methods of controlling variables .

A confounding variable , also called a confounder or confounding factor, is a third variable in a study examining a potential cause-and-effect relationship.

A confounding variable is related to both the supposed cause and the supposed effect of the study. It can be difficult to separate the true effect of the independent variable from the effect of the confounding variable.

In your research design , it’s important to identify potential confounding variables and plan how you will reduce their impact.

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Thomas, L. (2023, April 13). Control Groups & Treatment Groups | Uses & Examples. Scribbr. Retrieved 23 December 2024, from https://www.scribbr.co.uk/research-methods/control-groups/

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