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What Is a Control Variable? Definition and Examples

A control variable is any factor that is controlled or held constant during an experiment . For this reason, it’s also known as a controlled variable or a constant variable. A single experiment may contain many control variables . Unlike the independent and dependent variables , control variables aren’t a part of the experiment, but they are important because they could affect the outcome. Take a look at the difference between a control variable and control group and see examples of control variables.

Importance of Control Variables

Remember, the independent variable is the one you change, the dependent variable is the one you measure in response to this change, and the control variables are any other factors you control or hold constant so that they can’t influence the experiment. Control variables are important because:

• They make it easier to reproduce the experiment.
• The increase confidence in the outcome of the experiment.

For example, if you conducted an experiment examining the effect of the color of light on plant growth, but you didn’t control temperature, it might affect the outcome. One light source might be hotter than the other, affecting plant growth. This could lead you to incorrectly accept or reject your hypothesis. As another example, say you did control the temperature. If you did not report this temperature in your “methods” section, another researcher might have trouble reproducing your results. What if you conducted your experiment at 15 °C. Would you expect the same results at 5 °C or 35 5 °C? Sometimes the potential effect of a control variable can lead to a new experiment!

Sometimes you think you have controlled everything except the independent variable, but still get strange results. This could be due to what is called a “ confounding variable .” Examples of confounding variables could be humidity, magnetism, and vibration. Sometimes you can identify a confounding variable and turn it into a control variable. Other times, confounding variables cannot be detected or controlled.

Control Variable vs Control Group

A control group is different from a control variable. You expose a control group to all the same conditions as the experimental group, except you change the independent variable in the experimental group. Both the control group and experimental group should have the same control variables.

Control Variable Examples

Anything you can measure or control that is not the independent variable or dependent variable has potential to be a control variable. Examples of common control variables include:

• Duration of the experiment
• Size and composition of containers
• Temperature
• Sample volume
• Experimental technique
• Chemical purity or manufacturer
• Species (in biological experiments)

For example, consider an experiment testing whether a certain supplement affects cattle weight gain. The independent variable is the supplement, while the dependent variable is cattle weight. A typical control group would consist of cattle not given the supplement, while the cattle in the experimental group would receive the supplement. Examples of control variables in this experiment could include the age of the cattle, their breed, whether they are male or female, the amount of supplement, the way the supplement is administered, how often the supplement is administered, the type of feed given to the cattle, the temperature, the water supply, the time of year, and the method used to record weight. There may be other control variables, too. Sometimes you can’t actually control a control variable, but conditions should be the same for both the control and experimental groups. For example, if the cattle are free-range, weather might change from day to day, but both groups have the same experience. When you take data, be sure to record control variables along with the independent and dependent variable.

• Box, George E.P.; Hunter, William G.; Hunter, J. Stuart (1978). Statistics for Experimenters : An Introduction to Design, Data Analysis, and Model Building . New York: Wiley. ISBN 978-0-471-09315-2.
• Giri, Narayan C.; Das, M. N. (1979). Design and Analysis of Experiments . New York, N.Y: Wiley. ISBN 9780852269145.
• Stigler, Stephen M. (November 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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Controlled Experiment

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This is when a hypothesis is scientifically tested.

In a controlled experiment, an independent variable (the cause) is systematically manipulated, and the dependent variable (the effect) is measured; any extraneous variables are controlled.

The researcher can operationalize (i.e., define) the studied variables so they can be objectively measured. The quantitative data can be analyzed to see if there is a difference between the experimental and control groups.

What is the control group?

In experiments scientists compare a control group and an experimental group that are identical in all respects, except for one difference – experimental manipulation.

Unlike the experimental group, the control group is not exposed to the independent variable under investigation and so provides a baseline against which any changes in the experimental group can be compared.

Since experimental manipulation is the only difference between the experimental and control groups, we can be sure that any differences between the two are due to experimental manipulation rather than chance.

Randomly allocating participants to independent variable groups means that all participants should have an equal chance of participating in each condition.

The principle of random allocation is to avoid bias in how the experiment is carried out and limit the effects of participant variables.

What are extraneous variables?

The researcher wants to ensure that the manipulation of the independent variable has changed the changes in the dependent variable.

Hence, all the other variables that could affect the dependent variable to change must be controlled. These other variables are called extraneous or confounding variables.

Extraneous variables should be controlled were possible, as they might be important enough to provide alternative explanations for the effects.

In practice, it would be difficult to control all the variables in a child’s educational achievement. For example, it would be difficult to control variables that have happened in the past.

A researcher can only control the current environment of participants, such as time of day and noise levels.

Why conduct controlled experiments?

Scientists use controlled experiments because they allow for precise control of extraneous and independent variables. This allows a cause-and-effect relationship to be established.

Controlled experiments also follow a standardized step-by-step procedure. This makes it easy for another researcher to replicate the study.

Key Terminology

Experimental group.

The group being treated or otherwise manipulated for the sake of the experiment.

Control Group

They receive no treatment and are used as a comparison group.

Ecological validity

The degree to which an investigation represents real-life experiences.

Experimenter effects

These are the ways that the experimenter can accidentally influence the participant through their appearance or behavior.

Demand characteristics

The clues in an experiment lead the participants to think they know what the researcher is looking for (e.g., the experimenter’s body language).

Independent variable (IV)

The variable the experimenter manipulates (i.e., changes) – is assumed to have a direct effect on the dependent variable.

Dependent variable (DV)

Variable the experimenter measures. This is the outcome (i.e., the result) of a study.

Extraneous variables (EV)

All variables that are not independent variables but could affect the results (DV) of the experiment. Extraneous variables should be controlled where possible.

Confounding variables

Variable(s) that have affected the results (DV), apart from the IV. A confounding variable could be an extraneous variable that has not been controlled.

Random Allocation

Randomly allocating participants to independent variable conditions means that all participants should have an equal chance of participating in each condition.

Order effects

Changes in participants’ performance due to their repeating the same or similar test more than once. Examples of order effects include:

(i) practice effect: an improvement in performance on a task due to repetition, for example, because of familiarity with the task;

(ii) fatigue effect: a decrease in performance of a task due to repetition, for example, because of boredom or tiredness.

What is the control in an experiment?

In an experiment , the control is a standard or baseline group not exposed to the experimental treatment or manipulation. It serves as a comparison group to the experimental group, which does receive the treatment or manipulation.

The control group helps to account for other variables that might influence the outcome, allowing researchers to attribute differences in results more confidently to the experimental treatment.

Establishing a cause-and-effect relationship between the manipulated variable (independent variable) and the outcome (dependent variable) is critical in establishing a cause-and-effect relationship between the manipulated variable.

What is the purpose of controlling the environment when testing a hypothesis?

Controlling the environment when testing a hypothesis aims to eliminate or minimize the influence of extraneous variables. These variables other than the independent variable might affect the dependent variable, potentially confounding the results.

By controlling the environment, researchers can ensure that any observed changes in the dependent variable are likely due to the manipulation of the independent variable, not other factors.

This enhances the experiment’s validity, allowing for more accurate conclusions about cause-and-effect relationships.

It also improves the experiment’s replicability, meaning other researchers can repeat the experiment under the same conditions to verify the results.

Why are hypotheses important to controlled experiments?

Hypotheses are crucial to controlled experiments because they provide a clear focus and direction for the research. A hypothesis is a testable prediction about the relationship between variables.

It guides the design of the experiment, including what variables to manipulate (independent variables) and what outcomes to measure (dependent variables).

The experiment is then conducted to test the validity of the hypothesis. If the results align with the hypothesis, they provide evidence supporting it.

The hypothesis may be revised or rejected if the results do not align. Thus, hypotheses are central to the scientific method, driving the iterative inquiry, experimentation, and knowledge advancement process.

What is the experimental method?

The experimental method is a systematic approach in scientific research where an independent variable is manipulated to observe its effect on a dependent variable, under controlled conditions.

25 Control Variables Examples

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Control variables, sometimes called “controlled” variables or “constant” variables, are elements within a study that researchers deliberately keep constant.

In a research study, it is often required to determine the possible impact of one or more independent variables on a dependent variable. To maintain the validity of the results, scientists keep certain variables in check, known as the control variables, ensuring they do not influence the study outcome.

Through careful control of these variables, scientists can prevent confounding effects, allowing for the clear understanding of the relationship between the independent and dependent variables (Scharrer & Ramasubramanian 2021; Knapp 2017).

Control Variables Examples

Here are some concrete examples to better understand the role of control variables:

1. Participant Age When studying the effect of a new teaching method on students’ mathematical abilities, the age of the participants (all students studied are in the 8th grade) remains a control variable.

2. Participant Gender In investigating the impact of a physical fitness program on participants’ cardiovascular health, researchers control for participants’ gender (only female participants are included).

3. Socioeconomic Status (SES) While examining the effect of job training programs on employment rates, scientists control the socioeconomic status of participants (all participants fall under the same socioeconomic category).

4. Educational Level In a research study examining the impact of management styles on worker productivity, educational level (all workers involved hold a Bachelor’s degree in their corresponding fields) is considered a control variable.

5. Cultural Background In studying the influence of music therapy on stress reduction, researchers maintain cultural background constant (only participants from a specific cultural group are included).

6. Time of Day If a researcher is testing the effect of caffeine on alertness, the time of day (all tests are conducted in the morning) is controlled to ensure that circadian rhythms do not confound results.

7. Previous Experience In evaluating the effectiveness of a new software tutorial, previous experience with the software (all participants are novice users) is hold constant to avoid confounding effects.

8. Medication Usage When researching the correlation between a balanced diet and blood pressure, medication usage (none of the participants are on any medication) is a control variable.

9. Sleep Quality In correlating cognitive performance and sleep patterns, sleep quality (all participants are healthy sleepers, as assessed by a sleep quality questionnaire) is maintained constant.

10. Hunger/Fullness While exploring the link between taste perception and caloric intake, researchers control for hunger/fullness (all tests are conducted two hours after a standardized meal) to eliminate any potential confounding effects.

11. Caffeine Intake When evaluating the impact of a mindfulness exercise on attention spans, caffeine intake (participants are required to abstain from caffeine on the day of the testing) is controlled.

12. Mental Health Status During a research study exploring the effects of exercise on sleep quality, the mental health status of participants (all participants do not have any known mental health issues as per a screening survey) is kept constant.

13. Motivation Level In research on the effectiveness of a language learning app, the motivation level (participants are all deemed to have a high level of motivation as assessed by a standardized motivational questionnaire) is a control variable.

14. Instructions Given When scientists are studying the effect of a new fitness routine on muscle strength, the instructions given (all participants receive the same detailed instructions about the exercises) remain consistent.

15. Testing Environment In studying the impact of ambient noise on focus and concentration, the testing environment (all testing is conducted in a silent room) is controlled for.

16. Researcher Presence While experimenting to assess the influence of color on memory recall, researcher presence (all testing happens without the presence of the researcher to avoid pressure or distraction) is kept constant.

17. Mode of Data Collection When comparing coping styles and resilience, mode of data collection (all data is collected through online self-report surveys) is controlled.

18. Order of Questionnaires or Tasks During a study to understand the relation between personality traits and career choices, the order of questionnaires or tasks (participants are all subjected to the tasks and questionnaires in the exact same order) is maintained same.

19. Familiarity with Technology In researching the benefits of virtual reality in improving social skills, the familiarity with technology (all participants have basic computer skills) is considered constant.

20. Expectations/Briefing In a study of the correlation between study habits and academic performance, expectations/briefing about the study (all participants receive the same briefing regarding what the study entails) is controlled to maintain uniformity.

21. Physical Activity Level In a study analyzing the correlation between diet and energy levels, the physical activity level of participants (all participants engage in a moderate level of daily physical activity) is controlled.

22. Stress Levels When researching the impact of sleep duration on cognitive functions , the stress level of participants (all participants have reported average stress levels on a standard stress scale) is kept constant.

23. Relationship Status In researching the influence of relationships on happiness levels, the relationship status of participants (all participants are single at the time of the study) is kept constant.

24. Number of Hours Worked Recently While examining the effect of work-life balance on the job satisfaction of employees, the number of hours worked recently (all employees have worked standard 40 hour weeks) is considered a control variable.

25. Current Emotional State In a study evaluating the impact of a relaxation technique on anxiety levels, the current emotional state of the participants (all participants have to record a neutral emotional state at the time of testing) is maintained constant.

Related: Quantitative Reasoning Examples

How to Control a Variable

Controlling a variable in a research study involves ensuring that it is kept constant or unchanged throughout the entire experiment.

This technique allows the researchers to focus on the potential relationship between the remaining variables, the independent variable(s) and the dependent variable (Sproull, 2002).

Here’s an outline of the process:

• Identify Potential Control Variables Before beginning the experiment, identify all the variables that might potentially affect the outcome of your research. This process can be informed by a literature review on similar studies, brainstorming sessions, or consultations with other professionals in the field.
• Define the Conditions of Control Set specific conditions for each control variable. For example, if you’re studying the effects of a new teaching method on student learning outcomes, the students’ grade level might be a control variable. You would then decide to limit your study to only 8th-grade students.
• Maintain Consistent Environment Ensure that the environment or conditions in which your research is carried out stay constant. Changes in external variables might indirectly alter your control variables.
• Monitor Regularly Record data related to your control variables regularly. If there are changes, they will need to be corrected or accounted for in your final analysis.
• Analyze the Confounding Effect Once your experiment is completed, you should perform a statistical analysis to ensure that your controlled variables did not influence the outcome.

By regularly monitoring and adjusting these variables, you can limit their influence on your study, increasing the odds that any observed effects are due to the independent variable(s).

It’s important to note that it’s not always possible to control every variable in a study and that’s okay. In such cases, it is important that the researchers are aware of these uncontrollable variables and can discuss their potential impact when interpreting the results.

Types of Control Variables: Positive and Negative

Positive and negative controls are two types of control groups in experimental research. They act as a benchmark and provide context for interpreting the results of the experiment.

• Positive control refers to a test where the outcome is already known from the onset. It is implemented to ensure that an experimental procedure is working as intended. It is crucial for validating the test results and serves as a benchmark for comparison. These controls are used across various disciplines, from biology to engineering, cultivates consistency, reliability, and accuracy in experimental work.
• Negative control is a test that anticipates a negative result. It is carried out to ensure that no change occurs when no experimental variable is introduced. The key purpose of such controls is to rule out other factors that might lead to a change in the outcome. Overall, negative controls add credence to the experimental process, helping to confirm that observed changes in the positive control or experimental test result from the factor being tested.

Both positive and negative controls contribute to experimental reliability and validity. They allow scientists to have confidence in their results by reducing the likelihood of experimental error. They also facilitate a better understanding of the experimental processes and outcomes, which is key in research and experimentation.

These controls are, in essence, safeguards against inaccurate or skewed results, ensuring that the conclusions drawn are as accurate as possible, thus avoiding misleading deductions.

Go Deeper: Positive Control vs Negative Control

Control vs Confounding Variables

Control Variables and Confounding Variables each have substantial importance in research studies, and need to be accounted for. Both types of variables can influence results, but they serve different roles in the research process.

• Control Variables: Control variables are the variables that researchers control throughout a study, usually by ensuring they remain consistent and unchanged throughout the study (Lock et al., 2020; Parker & Berman, 2016). By controlling these variables, researchers can reduce the number of extraneous factors that could interfere with the results, thereby minimizing potential error, ensuring the integrity of the experiment, and reducing the risk of false outcomes.
• Confounding Variables : Confounding variables may pose a risk to the validity of a study’s results (Nestor & Schutt, 2018). These are variables that researchers didn’t account for, and they may influence both the independent and dependent variables, making it hard to determine if the effects were caused by the independent variable or the confounder.

The primary difference between control and confounding variables is how they’re managed in a study. Control variables are identified and kept constant by the researcher to isolate the relationship between the independent and dependent variables (Boniface, 2019; Lock et al., 2020).

On the other hand, confounding variables are extraneous factors that can influence the study results and have not been controlled (Riegelman, 2020). While researchers aim to identify possible confounding variables before a study to control or account for them, they often become clear during or after the experiment, introducing uncertainty about causation between dependent and independent variables.

Control variables are critical to maintaining the integrity and validity of research studies. By carefully selecting and managing these variables, researchers can limit confounding influences, allowing them to focus on the relationship between the independent and dependent variables. Understanding control variables assists researchers in developing robust study designs and reliable findings.

Boniface, D. R. (2019). Experiment Design and Statistical Methods For Behavioural and Social Research . CRC Press. ISBN: 9781351449298.

Knapp, H. (2017). Intermediate Statistics Using SPSS. SAGE Publications.

Lock, R. H., Lock, P. F., Morgan, K. L., Lock, E. F., & Lock, D. F. (2020). Statistics: Unlocking the Power of Data (3rd ed.). Wiley.

Nestor, P. G., & Schutt, R. K. (2018). Research Methods in Psychology: Investigating Human Behavior . SAGE Publications.

Parker, R. A., & Berman, N. G. (2016). Planning Clinical Research . Cambridge University Press.

Riegelman, R. K. (2020). Studying a Study and Testing a Test (7th ed.). Wolters Kluwer Health.

Scharrer, E., & Ramasubramanian, S. (2021). Quantitative Research Methods in Communication: The Power of Numbers for Social Justice . Taylor & Francis.

Sproull, N. L. (2002). Handbook of Research Methods: A Guide for Practitioners and Students in the Social Sciences . Scarecrow Press.

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• What Are Control Variables | Definition & Examples

What Are Control Variables? | Definition & Examples

Published on 4 May 2022 by Pritha Bhandari . Revised on 16 June 2023.

A control variable is anything that is held constant or limited in a research study. It’s a variable that is not of interest to the study’s aims but is controlled because it could influence the outcomes.

Variables may be controlled directly by holding them constant throughout a study (e.g., by controlling the room temperature in an experiment), or they may be controlled indirectly through methods like randomisation or statistical control (e.g., to account for participant characteristics like age in statistical tests).

Table of contents

Why do control variables matter, how do you control a variable, control variable vs control group, frequently asked questions about control variables.

Control variables enhance the internal validity of a study by limiting the influence of confounding and other extraneous variables . This helps you establish a correlational or causal relationship between your variables of interest.

Aside from the independent and dependent variables , all variables that can impact the results should be controlled. If you don’t control relevant variables, you may not be able to demonstrate that they didn’t influence your results. Uncontrolled variables are alternative explanations for your results.

Control variables in experiments

In an experiment , a researcher is interested in understanding the effect of an independent variable on a dependent variable. Control variables help you ensure that your results are solely caused by your experimental manipulation.

The independent variable is whether the vitamin D supplement is added to a diet, and the dependent variable is the level of alertness.

To make sure any change in alertness is caused by the vitamin D supplement and not by other factors, you control these variables that might affect alertness:

• Timing of meals
• Caffeine intake
• Screen time

Control variables in non-experimental research

In an observational study or other types of non-experimental research, a researcher can’t manipulate the independent variable (often due to practical or ethical considerations ). Instead, control variables are measured and taken into account to infer relationships between the main variables of interest.

To account for other factors that are likely to influence the results, you also measure these control variables:

• Marital status

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There are several ways to control extraneous variables in experimental designs, and some of these can also be used in observational or quasi-experimental designs.

Random assignment

In experimental studies with multiple groups, participants should be randomly assigned to the different conditions. Random assignment helps you balance the characteristics of groups so that there are no systematic differences between them.

This method of assignment controls participant variables that might otherwise differ between groups and skew your results.

It’s possible that the participants who found the study through Facebook have more screen time during the day, and this might influence how alert they are in your study.

Standardised procedures

It’s important to use the same procedures across all groups in an experiment. The groups should only differ in the independent variable manipulation so that you can isolate its effect on the dependent variable (the results).

To control variables, you can hold them constant at a fixed level using a protocol that you design and use for all participant sessions. For example, the instructions and time spent on an experimental task should be the same for all participants in a laboratory setting.

• To control for diet, fresh and frozen meals are delivered to participants three times a day.
• To control meal timings, participants are instructed to eat breakfast at 9:30, lunch at 13:00, and dinner at 18:30.
• To control caffeine intake, participants are asked to consume a maximum of one cup of coffee a day.

Statistical controls

You can measure and control for extraneous variables statistically to remove their effects on other variables.

“Controlling for a variable” means modelling control variable data along with independent and dependent variable data in regression analyses and ANCOVAs . That way, you can isolate the control variable’s effects from the relationship between the variables of interest.

A control variable isn’t the same as a control group . Control variables are held constant or measured throughout a study for both control and experimental groups, while an independent variable varies between control and experimental groups.

A control group doesn’t undergo the experimental treatment of interest, and its outcomes are compared with those of the experimental group. A control group usually has either no treatment, a standard treatment that’s already widely used, or a placebo (a fake treatment).

Aside from the experimental treatment, everything else in an experimental procedure should be the same between an experimental and control group.

A control variable is any variable that’s held constant in a research study. It’s not a variable of interest in the study, but it’s controlled because it could influence the outcomes.

Control variables help you establish a correlational or causal relationship between variables by enhancing internal validity .

If you don’t control relevant extraneous variables , they may influence the outcomes of your study, and you may not be able to demonstrate that your results are really an effect of your independent variable .

‘Controlling for a variable’ means measuring extraneous variables and accounting for them statistically to remove their effects on other variables.

Researchers often model control variable data along with independent and dependent variable data in regression analyses and ANCOVAs . That way, you can isolate the control variable’s effects from the relationship between the variables of interest.

Internal validity is the extent to which you can be confident that a cause-and-effect relationship established in a study cannot be explained by other factors.

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Experimental Design - Independent, Dependent, and Controlled Variables

Scientific experiments are meant to show cause and effect of a phenomena (relationships in nature).  The “ variables ” are any factor, trait, or condition that can be changed in the experiment and that can have an effect on the outcome of the experiment.

An experiment can have three kinds of variables: i ndependent, dependent, and controlled .

• The independent variable is one single factor that is changed by the scientist followed by observation to watch for changes. It is important that there is just one independent variable, so that results are not confusing.
• The dependent variable is the factor that changes as a result of the change to the independent variable.
• The controlled variables (or constant variables) are factors that the scientist wants to remain constant if the experiment is to show accurate results. To be able to measure results, each of the variables must be able to be measured.

For example, let’s design an experiment with two plants sitting in the sun side by side. The controlled variables (or constants) are that at the beginning of the experiment, the plants are the same size, get the same amount of sunlight, experience the same ambient temperature and are in the same amount and consistency of soil (the weight of the soil and container should be measured before the plants are added). The independent variable is that one plant is getting watered (1 cup of water) every day and one plant is getting watered (1 cup of water) once a week. The dependent variables are the changes in the two plants that the scientist observes over time.

Can you describe the dependent variable that may result from this experiment? After four weeks, the dependent variable may be that one plant is taller, heavier and more developed than the other. These results can be recorded and graphed by measuring and comparing both plants’ height, weight (removing the weight of the soil and container recorded beforehand) and a comparison of observable foliage.

Using What You Learned: Design another experiment using the two plants, but change the independent variable. Can you describe the dependent variable that may result from this new experiment?

Think of another simple experiment and name the independent, dependent, and controlled variables. Use the graphic organizer included in the PDF below to organize your experiment's variables.

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