stages in a research project

Research Process: 8 Steps in Research Process

The research process starts with identifying a research problem and conducting a literature review to understand the context. The researcher sets research questions, objectives, and hypotheses based on the research problem.

A research study design is formed to select a sample size and collect data after processing and analyzing the collected data and the research findings presented in a research report.

What is the Research Process?

There are a variety of approaches to research in any field of investigation, irrespective of whether it is applied research or basic research. Each research study will be unique in some ways because of the particular time, setting, environment, and place it is being undertaken.

Nevertheless, all research endeavors share a common goal of furthering our understanding of the problem, and thus, all traverse through certain primary stages, forming a process called the research process.

Understanding the research process is necessary to effectively carry out research and sequence the stages inherent in the process.

How Research Process Work?

Eight steps research process is, in essence, part and parcel of a research proposal. It is an outline of the commitment that you intend to follow in executing a research study.

A close examination of the above stages reveals that each of these stages, by and large, is dependent upon the others.

One cannot analyze data (step 7) unless he has collected data (step 6). One cannot write a report (step 8) unless he has collected and analyzed data (step 7).

Research then is a system of interdependent related stages. Violation of this sequence can cause irreparable harm to the study.

It is also true that several alternatives are available to the researcher during each stage stated above. A research process can be compared with a route map.

The map analogy is useful for the researcher because several alternatives exist at each stage of the research process.

Choosing the best alternative in terms of time constraints, money, and human resources in our research decision is our primary goal.

Before explaining the stages of the research process, we explain the term ‘iterative’ appearing within the oval-shaped diagram at the center of the schematic diagram.

The key to a successful research project ultimately lies in iteration: the process of returning again and again to the identification of the research problems, methodology, data collection, etc., which leads to new ideas, revisions, and improvements.

By discussing the research project with advisers and peers, one will often find that new research questions need to be added, variables to be omitted, added or redefined, and other changes to be made. As a proposed study is examined and reexamined from different perspectives, it may begin to transform and take a different shape.

This is expected and is an essential component of a good research study.

Besides, examining study methods and data collected from different viewpoints is important to ensure a comprehensive approach to the research question.

In conclusion, there is seldom any single strategy or formula for developing a successful research study, but it is essential to realize that the research process is cyclical and iterative.

What is the primary purpose of the research process?

The research process aims to identify a research problem, understand its context through a literature review, set research questions and objectives, design a research study, select a sample, collect data, analyze the data, and present the findings in a research report.

Why is the research design important in the research process?

The research design is the blueprint for fulfilling objectives and answering research questions. It specifies the methods and procedures for collecting, processing, and analyzing data, ensuring the study is structured and systematic.

8 Steps of Research Process

Identifying the research problem.

The first and foremost task in the entire process of scientific research is to identify a research problem .

A well-identified problem will lead the researcher to accomplish all-important phases of the research process, from setting objectives to selecting the research methodology .

But the core question is: whether all problems require research.

We have countless problems around us, but all we encounter do not qualify as research problems; thus, these do not need to be researched.

Keeping this point in mind, we must draw a line between research and non-research problems.

Intuitively, researchable problems are those that have a possibility of thorough verification investigation, which can be effected through the analysis and collection of data. In contrast, the non-research problems do not need to go through these processes.

Researchers need to identify both;

Non-Research Problems

Statement of the problem, justifying the problem, analyzing the problem.

A non-research problem does not require any research to arrive at a solution. Intuitively, a non-researchable problem consists of vague details and cannot be resolved through research.

It is a managerial or built-in problem that may be solved at the administrative or management level. The answer to any question raised in a non-research setting is almost always obvious.

The cholera outbreak, for example, following a severe flood, is a common phenomenon in many communities. The reason for this is known. It is thus not a research problem.

Similarly, the reasons for the sudden rise in prices of many essential commodities following the announcement of the budget by the Finance Minister need no investigation. Hence it is not a problem that needs research.

How is a research problem different from a non-research problem?

A research problem is a perceived difficulty that requires thorough verification and investigation through data analysis and collection. In contrast, a non-research problem does not require research for a solution, as the answer is often obvious or already known.

Non-Research Problems Examples

A recent survey in town- A found that 1000 women were continuous users of contraceptive pills.

But last month’s service statistics indicate that none of these women were using contraceptive pills (Fisher et al. 1991:4).

The discrepancy is that ‘all 1000 women should have been using a pill, but none is doing so. The question is: why the discrepancy exists?

Well, the fact is, a monsoon flood has prevented all new supplies of pills from reaching town- A, and all old supplies have been exhausted. Thus, although the problem situation exists, the reason for the problem is already known.

Therefore, assuming all the facts are correct, there is no reason to research the factors associated with pill discontinuation among women. This is, thus, a non-research problem.

A pilot survey by University students revealed that in Rural Town-A, the goiter prevalence among school children is as high as 80%, while in the neighboring Rural Town-A, it is only 30%. Why is a discrepancy?

Upon inquiry, it was seen that some three years back, UNICEF launched a lipiodol injection program in the neighboring Rural Town-A.

This attempt acted as a preventive measure against the goiter. The reason for the discrepancy is known; hence, we do not consider the problem a research problem.

A hospital treated a large number of cholera cases with penicillin, but the treatment with penicillin was not found to be effective. Do we need research to know the reason?

Here again, there is one single reason that Vibrio cholera is not sensitive to penicillin; therefore, this is not the drug of choice for this disease.

In this case, too, as the reasons are known, it is unwise to undertake any study to find out why penicillin does not improve the condition of cholera patients. This is also a non-research problem.

In the tea marketing system , buying and selling tea starts with bidders. Blenders purchase open tea from the bidders. Over the years, marketing cost has been the highest for bidders and the lowest for blenders. What makes this difference?

The bidders pay exorbitantly higher transport costs, which constitute about 30% of their total cost.

Blenders have significantly fewer marketing functions involving transportation, so their marketing cost remains minimal.

Hence no research is needed to identify the factors that make this difference.

Here are some of the problems we frequently encounter, which may well be considered non-research problems:

Rises in the price of warm clothes during winter;
Preferring admission to public universities over private universities;
Crisis of accommodations in sea resorts during summer
Traffic jams in the city street after office hours;
High sales in department stores after an offer of a discount.

Research Problem

In contrast to a non-research problem, a research problem is of primary concern to a researcher.

A research problem is a perceived difficulty, a feeling of discomfort, or a discrepancy between a common belief and reality.

As noted by Fisher et al. (1993), a problem will qualify as a potential research problem when the following three conditions exist:

There should be a perceived discrepancy between “what it is” and “what it should have been.” This implies that there should be a difference between “what exists” and the “ideal or planned situation”;
A question about “why” the discrepancy exists. This implies that the reason(s) for this discrepancy is unclear to the researcher (so that it makes sense to develop a research question); and
There should be at least two possible answers or solutions to the questions or problems.

The third point is important. If there is only one possible and plausible answer to the question about the discrepancy, then a research situation does not exist.

It is a non-research problem that can be tackled at the managerial or administrative level.

Research Problem Examples

Research problem – example #1.

While visiting a rural area, the UNICEF team observed that some villages have female school attendance rates as high as 75%, while some have as low as 10%, although all villages should have a nearly equal attendance rate. What factors are associated with this discrepancy?

We may enumerate several reasons for this:

Villages differ in their socio-economic background.
In some villages, the Muslim population constitutes a large proportion of the total population. Religion might play a vital role.
Schools are far away from some villages. The distance thus may make this difference.

Because there is more than one answer to the problem, it is considered a research problem, and a study can be undertaken to find a solution.

Research Problem – Example #2

The Government has been making all-out efforts to ensure a regular flow of credit in rural areas at a concession rate through liberal lending policy and establishing many bank branches in rural areas.

Knowledgeable sources indicate that expected development in rural areas has not yet been achieved, mainly because of improper credit utilization.

More than one reason is suspected for such misuse or misdirection.

These include, among others:

Diversion of credit money to some unproductive sectors
Transfer of credit money to other people like money lenders, who exploit the rural people with this money
Lack of knowledge of proper utilization of the credit.

Here too, reasons for misuse of loans are more than one. We thus consider this problem as a researchable problem.

Research Problem – Example #3

Let’s look at a new headline: Stock Exchange observes the steepest ever fall in stock prices: several injured as retail investors clash with police , vehicles ransacked .

Investors’ demonstration, protest and clash with police pause a problem. Still, it is certainly not a research problem since there is only one known reason for the problem: Stock Exchange experiences the steepest fall in stock prices. But what causes this unprecedented fall in the share market?

Experts felt that no single reason could be attributed to the problem. It is a mix of several factors and is a research problem. The following were assumed to be some of the possible reasons:

The merchant banking system;
Liquidity shortage because of the hike in the rate of cash reserve requirement (CRR);
IMF’s warnings and prescriptions on the commercial banks’ exposure to the stock market;
Increase in supply of new shares;
Manipulation of share prices;
Lack of knowledge of the investors on the company’s fundamentals.

The choice of a research problem is not as easy as it appears. The researchers generally guide it;

own intellectual orientation ,
level of training,
experience,
knowledge on the subject matter, and
intellectual curiosity.

Theoretical and practical considerations also play a vital role in choosing a research problem. Societal needs also guide in choosing a research problem.

Once we have chosen a research problem, a few more related steps must be followed before a decision is taken to undertake a research study.

These include, among others, the following:

Statement of the problem.
Justifying the problem.
Analyzing the problem.

A detailed exposition of these issues is undertaken in chapter ten while discussing the proposal development.

A clear and well-defined problem statement is considered the foundation for developing the research proposal.

It enables the researcher to systematically point out why the proposed research on the problem should be undertaken and what he hopes to achieve with the study’s findings.

A well-defined statement of the problem will lead the researcher to formulate the research objectives, understand the background of the study, and choose a proper research methodology.

Once the problem situation has been identified and clearly stated, it is important to justify the importance of the problem.

In justifying the problems, we ask such questions as why the problem of the study is important, how large and widespread the problem is, and whether others can be convinced about the importance of the problem and the like.

Answers to the above questions should be reviewed and presented in one or two paragraphs that justify the importance of the problem.

As a first step in analyzing the problem, critical attention should be given to accommodate the viewpoints of the managers, users, and researchers to the problem through threadbare discussions.

The next step is identifying the factors that may have contributed to the perceived problems.

Issues of Research Problem Identification

There are several ways to identify, define, and analyze a problem, obtain insights, and get a clearer idea about these issues. Exploratory research is one of the ways of accomplishing this.

The purpose of the exploratory research process is to progressively narrow the scope of the topic and transform the undefined problems into defined ones, incorporating specific research objectives.

The exploratory study entails a few basic strategies for gaining insights into the problem. It is accomplished through such efforts as:

Pilot Survey

A pilot survey collects proxy data from the ultimate subjects of the study to serve as a guide for the large study. A pilot study generates primary data, usually for qualitative analysis.

This characteristic distinguishes a pilot survey from secondary data analysis, which gathers background information.

Case Studies

Case studies are quite helpful in diagnosing a problem and paving the way to defining the problem. It investigates one or a few situations identical to the researcher’s problem.

Focus Group Interviews

Focus group interviews, an unstructured free-flowing interview with a small group of people, may also be conducted to understand and define a research problem .

Experience Survey

Experience survey is another strategy to deal with the problem of identifying and defining the research problem.

It is an exploratory research endeavor in which individuals knowledgeable and experienced in a particular research problem are intimately consulted to understand the problem.

These persons are sometimes known as key informants, and an interview with them is popularly known as the Key Informant Interview (KII).

Reviewing of Literature

A review of relevant literature is an integral part of the research process. It enables the researcher to formulate his problem in terms of the specific aspects of the general area of his interest that has not been researched so far.

Such a review provides exposure to a larger body of knowledge and equips him with enhanced knowledge to efficiently follow the research process.

Through a proper review of the literature, the researcher may develop the coherence between the results of his study and those of the others.

A review of previous documents on similar or related phenomena is essential even for beginning researchers.

Ignoring the existing literature may lead to wasted effort on the part of the researchers.

Why spend time merely repeating what other investigators have already done?

Suppose the researcher is aware of earlier studies of his topic or related topics . In that case, he will be in a much better position to assess his work’s significance and convince others that it is important.

A confident and expert researcher is more crucial in questioning the others’ methodology, the choice of the data, and the quality of the inferences drawn from the study results.

In sum, we enumerate the following arguments in favor of reviewing the literature:

It avoids duplication of the work that has been done in the recent past.
It helps the researcher discover what others have learned and reported on the problem.
It enables the researcher to become familiar with the methodology followed by others.
It allows the researcher to understand what concepts and theories are relevant to his area of investigation.
It helps the researcher to understand if there are any significant controversies, contradictions, and inconsistencies in the findings.
It allows the researcher to understand if there are any unanswered research questions.
It might help the researcher to develop an analytical framework.
It will help the researcher consider including variables in his research that he might not have thought about.

Why is reviewing literature crucial in the research process?

Reviewing literature helps avoid duplicating previous work, discovers what others have learned about the problem, familiarizes the researcher with relevant concepts and theories, and ensures a comprehensive approach to the research question.

What is the significance of reviewing literature in the research process?

Reviewing relevant literature helps formulate the problem, understand the background of the study, choose a proper research methodology, and develop coherence between the study’s results and previous findings.

Setting Research Questions, Objectives, and Hypotheses

After discovering and defining the research problem, researchers should make a formal statement of the problem leading to research objectives .

An objective will precisely say what should be researched, delineate the type of information that should be collected, and provide a framework for the scope of the study. A well-formulated, testable research hypothesis is the best expression of a research objective.

A hypothesis is an unproven statement or proposition that can be refuted or supported by empirical data. Hypothetical statements assert a possible answer to a research question.

Step #4: Choosing the Study Design

The research design is the blueprint or framework for fulfilling objectives and answering research questions .

It is a master plan specifying the methods and procedures for collecting, processing, and analyzing the collected data. There are four basic research designs that a researcher can use to conduct their study;

experiment,
secondary data study, and
observational study.

The type of research design to be chosen from among the above four methods depends primarily on four factors:

The type of problem
The objectives of the study,
The existing state of knowledge about the problem that is being studied, and
The resources are available for the study.

Deciding on the Sample Design

Sampling is an important and separate step in the research process. The basic idea of sampling is that it involves any procedure that uses a relatively small number of items or portions (called a sample) of a universe (called population) to conclude the whole population.

It contrasts with the process of complete enumeration, in which every member of the population is included.

Such a complete enumeration is referred to as a census.

A population is the total collection of elements we wish to make some inference or generalization.

A sample is a part of the population, carefully selected to represent that population. If certain statistical procedures are followed in selecting the sample, it should have the same characteristics as the population. These procedures are embedded in the sample design.

Sample design refers to the methods followed in selecting a sample from the population and the estimating technique vis-a-vis the formula for computing the sample statistics .

The fundamental question is, then, how to select a sample.

To answer this question, we must have acquaintance with the sampling methods.

These methods are basically of two types;

probability sampling , and
non-probability sampling .

Probability sampling ensures every unit has a known nonzero probability of selection within the target population.

If there is no feasible alternative, a non-probability sampling method may be employed.

The basis of such selection is entirely dependent on the researcher’s discretion. This approach is called judgment sampling, convenience sampling, accidental sampling, and purposive sampling.

The most widely used probability sampling methods are simple random sampling , stratified random sampling , cluster sampling , and systematic sampling . They have been classified by their representation basis and unit selection techniques.

Two other variations of the sampling methods that are in great use are multistage sampling and probability proportional to size (PPS) sampling .

Multistage sampling is most commonly used in drawing samples from very large and diverse populations.

The PPS sampling is a variation of multistage sampling in which the probability of selecting a cluster is proportional to its size, and an equal number of elements are sampled within each cluster.

Collecting Data From The Research Sample

Data gathering may range from simple observation to a large-scale survey in any defined population. There are many ways to collect data. The approach selected depends on the objectives of the study, the research design, and the availability of time, money, and personnel.

With the variation in the type of data (qualitative or quantitative) to be collected, the method of data collection also varies .

The most common means for collecting quantitative data is the structured interview .

Studies that obtain data by interviewing respondents are called surveys. Data can also be collected by using self-administered questionnaires . Telephone interviewing is another way in which data may be collected .

Other means of data collection include secondary sources, such as the census, vital registration records, official documents, previous surveys, etc.

Qualitative data are collected mainly through in-depth interviews, focus group discussions , Key Informant Interview ( KII), and observational studies.

Process and Analyze the Collected Research Data

Processing And Analyzing The Collected Research Data

Data processing generally begins with the editing and coding of data . Data are edited to ensure consistency across respondents and to locate omissions if any.

In survey data, editing reduces errors in the recording, improves legibility, and clarifies unclear and inappropriate responses. In addition to editing, the data also need coding.

Because it is impractical to place raw data into a report, alphanumeric codes are used to reduce the responses to a more manageable form for storage and future processing.

This coding process facilitates the processing of the data. The personal computer offers an excellent opportunity for data editing and coding processes.

Data analysis usually involves reducing accumulated data to a manageable size, developing summaries, searching for patterns, and applying statistical techniques for understanding and interpreting the findings in light of the research questions.

Further, based on his analysis, the researcher determines if his findings are consistent with the formulated hypotheses and theories.

The techniques used in analyzing data may range from simple graphical techniques to very complex multivariate analyses depending on the study’s objectives, the research design employed, and the nature of the data collected.

As in the case of data collection methods, an analytical technique appropriate in one situation may not be suitable for another.

Writing Research Report – Developing Research Proposal, Writing Report, Disseminating and Utilizing Results

The entire task of a research study is accumulated in a document called a proposal or research proposal.

A research proposal is a work plan, prospectus, outline, offer, and a statement of intent or commitment from an individual researcher or an organization to produce a product or render a service to a potential client or sponsor .

The proposal will be prepared to keep the sequence presented in the research process. The proposal tells us what, how, where, and to whom it will be done.

It must also show the benefit of doing it. It always includes an explanation of the purpose of the study (the research objectives) or a definition of the problem.

It systematically outlines the particular research methodology and details the procedures utilized at each stage of the research process.

The end goal of a scientific study is to interpret the results and draw conclusions.

To this end, it is necessary to prepare a report and transmit the findings and recommendations to administrators, policymakers, and program managers to make a decision.

There are various research reports: term papers, dissertations, journal articles , papers for presentation at professional conferences and seminars, books, thesis, and so on. The results of a research investigation prepared in any form are of little utility if they are not communicated to others.

The primary purpose of a dissemination strategy is to identify the most effective media channels to reach different audience groups with study findings most relevant to their needs.

The dissemination may be made through a conference, a seminar, a report, or an oral or poster presentation.

The style and organization of the report will differ according to the target audience , the occasion, and the purpose of the research. Reports should be developed from the client’s perspective.

A report is an excellent means that helps to establish the researcher’s credibility. At a bare minimum, a research report should contain sections on:

An executive summary;
Background of the problem;
Literature review;
Methodology;
Discussion;
Conclusions and
Recommendations.

The study results can also be disseminated through peer-reviewed journals published by academic institutions and reputed publishers both at home and abroad. The report should be properly evaluated .

These journals have their format and editorial policies. The contributors can submit their manuscripts adhering to the policies and format for possible publication of their papers.

There are now ample opportunities for researchers to publish their work online.

The researchers have conducted many interesting studies without affecting actual settings. Ideally, the concluding step of a scientific study is to plan for its utilization in the real world.

Although researchers are often not in a position to implement a plan for utilizing research findings, they can contribute by including in their research reports a few recommendations regarding how the study results could be utilized for policy formulation and program intervention.

Why is the dissemination of research findings important?

Dissemination of research findings is crucial because the results of a research investigation have little utility if not communicated to others. Dissemination ensures that the findings reach relevant stakeholders, policymakers, and program managers to inform decisions.

How should a research report be structured?

A research report should contain sections on an executive summary, background of the problem, literature review, methodology, findings, discussion, conclusions, and recommendations.

Why is it essential to consider the target audience when preparing a research report?

The style and organization of a research report should differ based on the target audience, occasion, and research purpose. Tailoring the report to the audience ensures that the findings are communicated effectively and are relevant to their needs.

Now that you are familiar with research process; explore complete guideline on research and research methodology concepts .

Education Research: Definition, Examples
Legal Research Design and Structure [11 Elements]
Observation Method of Data Collection: Advantages, Disadvantages, Techniques, Types
Evaluative Research: Definition, Examples
Thurstone Scale: Definition, Example
Semantic Differential: Definition, Example
Validity in Experimentation
Top 10 Trending Research Topics to Write About
Design Effect: Definition, Examples
Population Research: Definition, Examples
Writing a Research Report
Level of Measurement: 4 Scales of Measurement
Exploratory Research: Definition, Types, Examples
Monitoring and Evaluation: Process, Design, Methods
Non-Probability Sampling

Research Guides

6 Stages of Research

1: Task Definition
2: Information Seeking
3: Location & Access
4: Use of Information
5: Synthesis
6: Evaluation

Ask a Librarian

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We are here to help!

Ask the Right Questions

The scope of an investigation determines how large or small your investigation will be. Determining the scope of an investigation is the critical first step in the research process because you will know how far and how deep to look for answers. This lesson will teach you how to develop a research question as a way to determine the scope of an investigation.

Click the image to open the tutorial in a new window.

Keyword(s): 5W Criteria, Ask the Right Questions, Guided Inquiry, Information Literacy, Library, New Literacies Alliance, Research as Inquiry, Research Question

Purpose of this guide

The purpose of this guide is to walk you through the 6 stages of writing an effective research paper. By breaking the process down into these 6 stages, your paper will be better and you will get more out of the research experience.

The 6 stages are:

Task Definition (developing a topic)
Information Seeking (coming up with a research plan)
Location & Access (finding good sources)
Use of Information (Reading, taking notes, and generally making the writing process easier)
Synthesis (coming up with your own ideas and presenting them well)
Evaluation (reflection)

This research guide is based on the Big6 Information Literacy model from https://thebig6.org/

Task Definition

The purpose of task definition is to help you develop an effective topic for your paper. .

Developing a topic is often one of the hardest and most important steps in writing a paper or doing a research project. But here are some tips:

A research topic is a question, not a statement. You shouldn't already know the answer when you start researching.
Research something you actually care about or find interesting. It turns the research process from a chore into something enjoyable and whoever reads your work can tell the difference.
Read the assignment before and after you think you have come up with your topic to make sure you are answering the prompt.

Steps to Developing a Topic

Assignment Requirements
General Idea
Background Research
Ask Questions
Topic Question

Read your assignment and note any requirements.

Is there a required page length?
How many sources do you need?
Does the paper have to be in a specific format like APA?
Are there any listed goals for the topic, such as synthesizing different opinions, or applying a theory to a real-life example?

Formulate a general idea.

Look at your syllabus or course schedule for broad topic ideas.
Think about reading assignments or class lectures that you found interesting.
Talk with your professor or a librarian.
Check out social media and see what has been trending that is related to your course.
Think about ideas from popular videos, TV shows, and movies.
Read The New York Times (FHSU students have free access through the Library)
Watch NBC Learn (FHSU students have free access through the Library)
Search your library for relevant journals and publications related to your course and browse them for ideas
Browse online discussion forums, news, and blogs for professional organizations for hot topics

Do some background research on your general idea.

You have access to reference materials through the Library for background research.
See what your course notes and textbook say about the subject.
Google it.

Reference e-books on a wide range of topics. Sources include dictionaries, encyclopedias, key concepts, key thinkers, handbooks, atlases, and more. Search by keyword or browse titles by topic.

Over 1200 cross-searchable reference e-books on a wide variety of subjects.

Mind map it.

A mind map is an effective way of organizing your thoughts and generating new questions as you learn about your topic.

Video on how to do a mind map.
Coggle Free mind mapping software that is great for beginners and easy to use.
MindMup Mindmup is a free, easy to use online software that allows you to publish and share your mind maps with others.

Ask Questions to focus on what interests you.

Who? What? When? Where? Why?

We can focus our ideas by brainstorming what interests us when asking who, what, when where, and why:

anonymous by Gregor Cresnar from the Noun Project

Research Question: Does flexible seating in an elementary classroom improve student focus?

Write out your topic question & reread the assignment criteria.

Can you answer your question well in the number of pages required?
Does your topic still meet the requirements of the paper? Ex: is the question still about the sociology of gender studies and women?
Is the topic too narrow to find research?

Developing a Topic Tutorial

The following tutorial from Forsyth Library will walk you through the process of defining your topic.

Next: 2: Information Seeking >>
Last Updated: Jan 29, 2024 10:10 AM
URL: https://fhsuguides.fhsu.edu/6stages

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Research projects & dissertations

Managing a research project.

The following guide has been created for you by the Student Learning Advisory Service . For more detailed guidance and to speak to one of our advisers, please book an appointment or join one of our workshops . Alternatively, have a look at our SkillBuilder skills videos.

The stages of a research project

The basic stages involved in undertaking a university research project are as follows:

1. Choose your research area

Usually, it is best choose an area that you have already studied or are studying within your academic field. Not only will this help you identify potential research, but you can be confident in finding a suitable supervisor and reliable sources within the university. Choosing an area that you also find particularly interesting will help sustain your engagement.

2. Conduct preliminary research (scope out the topic)

Survey current research surrounding your chosen subject area. Reflect on it carefully, and take advice from academic staff to establish what has already been written on your chosen subject area. This will enable you to identify what you can do that has not been done before.

3. Decide your research topic

Clearly define and delineate your research topic. The more clearly you do so the more confidence and clarity you will have in what you are trying to achieve, and the easier it will be for you to monitor your progress. If you’re uncertain what you’re trying to achieve, how will you know whether you’re on course or not?

At this stage you might also formulate a provisional research question – that is, the question your research will answer:

Research topic: Investigate ‘A’ and ‘B’ to see if/how they interrelate.

Research Question: ‘To what extent is A caused by B?’

4. Decide your methodology

As you are deciding your topic, you should be investigating and considering your research methodology – how you will conduct your research. Is it going to be experimental, observational, theoretical, textual, qualitative, quantitative? Will it involve human subjects? Are there ethical considerations – specific protocols, procedures or approaches to follow? Think about the research method you have chosen; what advantages does it give? What insights might it yield? What difficulties might it pose? How has it been used before in your field of study?

5. Submit/present your research proposal for approval

Most schools have a formal deadline for receiving research proposals/dissertation plans, and a formal approval process. In some cases this is an assessment stage – so make sure you know exactly what you need to submit, and when, in order to progress with your project. Your school will have given you guidance about what your proposal should include. Generally, the common elements are:

Your main research question/problem/title
Questions or concerns that will help you solve your main research problem
A brief literature review or list of key texts/sources
An overview of your methodology
A timeline showing your main research project tasks

6. Finalise your topic and methodology

You may need to revise your research plan in the light of feedback you receive during the approval process. Many students are overambitious in their aims; academic staff have a much clearer idea of what is achievable and necessary in terms of a successful research project, so be guided by their advice. You may also need to modify your methodology in the light of your initial research, or a pilot study. It may be necessary, for example, to alter a questionnaire that isn’t generating the data you were expecting.

7. Conduct your research (fieldwork)

This might take place in a laboratory, in a library or archive, at a computer, on the streets or in a field. Whatever the location, this is the practical activity of collecting raw information or data. Be aware that what you think you are going to find out, and what you actually do find out, can often be very different, so be prepared to alter your research aims/question accordingly.

8. Analysis/data processing

Whatever your research topic, you will need to analyse and process the information you have collected in order to make sense of it. This might involve statistical analysis, generating graphs, charts or tables, organising information into categories, or critical appraisal of texts or events. As well as finding out something, you need to understand what it means within your academic field.

9. Writing up

This is the process of producing the written document – your dissertation or thesis – upon which your research project will be assessed. Allow enough time to improve and revise your work through a series of drafts, and to edit and proof-read the final document – including ensuring that any graphs/images referred to in the text are properly numbered and labelled, and that your referencing is error-free – before formatting and binding the finished document. Do not underestimate how long the writing up process will take.

10. Submission

All academic research projects are time constrained, so you will have a specific deadline for submitting your work. With longer research projects, you will also have intermediate deadlines (e.g. progress/upgrade boards). Consequently, you will need to time-manage each stage of your work to ensure that you complete the overall project on time.

Project managing your research

Any complex project involving multiple activities and deadlines requires some form of management. Using simple project management techniques will allow you to keep control of your research project – to schedule your work more effectively, to identify how much time you have to spend on each stage, to create intermediate milestones that will tell you if you’re on schedule or not (and allow you to respond accordingly) and give you a clear overview of your progress.

One simple but highly effective technique is to produce a Gantt chart. This provides you with a clear visual plan of your research project, based on scheduling the different stages involved against a time base. The example below (Figure 1) is based on the ten basic research project stages, scheduled against two (hypothetical) formal deadlines – submission of the proposal in week 10 and submission of the finished dissertation in week 24:

Figure 1: Simple research project Gantt chart

This example is typical of an undergraduate or taught Masters’ dissertation. Longer research projects (PhD, Masters by research, etc.) will generally have more activities spread over a longer timeframe (See below, Figure 2, for an example of a project plan for a humanities PhD).

Figure 2: Humanities PhD example Gantt chart

In project management, the scheduling of individual activities is always worked backwards from the deadline. Thus, the amount of time that you have to complete each task is a function of the overall project schedule. As shown above, some tasks have to be carried out consecutively (i.e., you can’t start the next task until you’ve completed the previous one), but other tasks can be carried out at the same time, or started before the previous task has been completed, (e.g. you might be able to start analysing your data whilst you’re still collecting it). What you also need to bear in mind with undergraduate dissertations is that your research project constitutes only one part (25%) of your academic activities, and that you’ll be working on other assignments, reading, exam revision, etc, at the same time. As such, it is important that you make full use of the available time period and balance your priorities accordingly.

Tip: With longer-term projects such as these, it can be difficult to stay focused and motivated. Try to dedicate some time to your project every day/week (depending on your other academic commitments) and break your tasks down into smaller chunks so that they are more manageable. The Pomodoro technique can also be helpful for generating small bursts of concentration. If you are struggling, maybe read an article on your topic to remind yourself of your interest in the area, or talk to fellow students or your supervisor(s).

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Overview of research process.

The Research Process

Anything you write involves organization and a logical flow of ideas, so understanding the logic of the research process before beginning to write is essential. Simply put, you need to put your writing in the larger context—see the forest before you even attempt to see the trees.

In this brief introductory module, we’ll review the major steps in the research process, conceptualized here as a series of steps within a circle, with each step dependent on the previous one. The circle best depicts the recursive nature of the process; that is, once the process has been completed, the researcher may begin again by refining or expanding on the initial approach, or even pioneering a completely new approach to solving the problem.

Identify a Research Problem

You identify a research problem by first selecting a general topic that’s interesting to you and to the interests and specialties of your research advisor. Once identified, you’ll need to narrow it. For example, if teenage pregnancy is your general topic area, your specific topic could be a comparison of how teenage pregnancy affects young fathers and mothers differently.

Review the Literature

Find out what’s being asked or what’s already been done in the area by doing some exploratory reading. Discuss the topic with your advisor to gain additional insights, explore novel approaches, and begin to develop your research question, purpose statement, and hypothesis(es), if applicable.

Determine Research Question

A good research question is a question worth asking; one that poses a problem worth solving. A good question should:

Be clear . It must be understandable to you and to others.
Be researchable . It should be capable of developing into a manageable research design, so data may be collected in relation to it. Extremely abstract terms are unlikely to be suitable.
Connect with established theory and research . There should be a literature on which you can draw to illuminate how your research question(s) should be approached.
Be neither too broad nor too narrow. See Appendix A for a brief explanation of the narrowing process and how your research question, purpose statement, and hypothesis(es) are interconnected.

Appendix A Research Questions, Purpose Statement, Hypothesis(es)

Develop Research Methods

Once you’ve finalized your research question, purpose statement, and hypothesis(es), you’ll need to write your research proposal—a detailed management plan for your research project. The proposal is as essential to successful research as an architect’s plans are to the construction of a building.

See Appendix B to view the basic components of a research proposal.

Appendix B Components of a Research Proposal

Collect & Analyze Data

In Practical Research–Planning and Design (2005, 8th Edition), Leedy and Ormrod provide excellent advice for what the researcher does at this stage in the research process. The researcher now

collects data that potentially relate to the problem,
arranges the data into a logical organizational structure,
analyzes and interprets the data to determine their meaning,
determines if the data resolve the research problem or not, and
determines if the data support the hypothesis or not.

Document the Work

Because research reports differ by discipline, the most effective way for you to understand formatting and citations is to examine reports from others in your department or field. The library’s electronic databases provide a wealth of examples illustrating how others in your field document their research.

Communicate Your Research

Talk with your advisor about potential local, regional, or national venues to present your findings. And don’t sell yourself short: Consider publishing your research in related books or journals.

Refine/Expand, Pioneer

Earlier, we emphasized the fact that the research process, rather than being linear, is recursive—the reason we conceptualized the process as a series of steps within a circle. At this stage, you may need to revisit your research problem in the context of your findings. You might also investigate the implications of your work and identify new problems or refine your previous approach.

The process then begins anew . . . and you’ll once again move through the series of steps in the circle.

Continue to Module Two

Appendix C - Key Research Terms

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Research Process – Steps, Examples and Tips

Table of Contents

Research Process

Definition:

Research Process is a systematic and structured approach that involves the collection, analysis, and interpretation of data or information to answer a specific research question or solve a particular problem.

Research Process Steps

Research Process Steps are as follows:

Identify the Research Question or Problem

This is the first step in the research process. It involves identifying a problem or question that needs to be addressed. The research question should be specific, relevant, and focused on a particular area of interest.

Conduct a Literature Review

Once the research question has been identified, the next step is to conduct a literature review. This involves reviewing existing research and literature on the topic to identify any gaps in knowledge or areas where further research is needed. A literature review helps to provide a theoretical framework for the research and also ensures that the research is not duplicating previous work.

Formulate a Hypothesis or Research Objectives

Based on the research question and literature review, the researcher can formulate a hypothesis or research objectives. A hypothesis is a statement that can be tested to determine its validity, while research objectives are specific goals that the researcher aims to achieve through the research.

Design a Research Plan and Methodology

This step involves designing a research plan and methodology that will enable the researcher to collect and analyze data to test the hypothesis or achieve the research objectives. The research plan should include details on the sample size, data collection methods, and data analysis techniques that will be used.

Collect and Analyze Data

This step involves collecting and analyzing data according to the research plan and methodology. Data can be collected through various methods, including surveys, interviews, observations, or experiments. The data analysis process involves cleaning and organizing the data, applying statistical and analytical techniques to the data, and interpreting the results.

Interpret the Findings and Draw Conclusions

After analyzing the data, the researcher must interpret the findings and draw conclusions. This involves assessing the validity and reliability of the results and determining whether the hypothesis was supported or not. The researcher must also consider any limitations of the research and discuss the implications of the findings.

Communicate the Results

Finally, the researcher must communicate the results of the research through a research report, presentation, or publication. The research report should provide a detailed account of the research process, including the research question, literature review, research methodology, data analysis, findings, and conclusions. The report should also include recommendations for further research in the area.

Review and Revise

The research process is an iterative one, and it is important to review and revise the research plan and methodology as necessary. Researchers should assess the quality of their data and methods, reflect on their findings, and consider areas for improvement.

Ethical Considerations

Throughout the research process, ethical considerations must be taken into account. This includes ensuring that the research design protects the welfare of research participants, obtaining informed consent, maintaining confidentiality and privacy, and avoiding any potential harm to participants or their communities.

Dissemination and Application

The final step in the research process is to disseminate the findings and apply the research to real-world settings. Researchers can share their findings through academic publications, presentations at conferences, or media coverage. The research can be used to inform policy decisions, develop interventions, or improve practice in the relevant field.

Research Process Example

Following is a Research Process Example:

Research Question : What are the effects of a plant-based diet on athletic performance in high school athletes?

Step 1: Background Research Conduct a literature review to gain a better understanding of the existing research on the topic. Read academic articles and research studies related to plant-based diets, athletic performance, and high school athletes.

Step 2: Develop a Hypothesis Based on the literature review, develop a hypothesis that a plant-based diet positively affects athletic performance in high school athletes.

Step 3: Design the Study Design a study to test the hypothesis. Decide on the study population, sample size, and research methods. For this study, you could use a survey to collect data on dietary habits and athletic performance from a sample of high school athletes who follow a plant-based diet and a sample of high school athletes who do not follow a plant-based diet.

Step 4: Collect Data Distribute the survey to the selected sample and collect data on dietary habits and athletic performance.

Step 5: Analyze Data Use statistical analysis to compare the data from the two samples and determine if there is a significant difference in athletic performance between those who follow a plant-based diet and those who do not.

Step 6 : Interpret Results Interpret the results of the analysis in the context of the research question and hypothesis. Discuss any limitations or potential biases in the study design.

Step 7: Draw Conclusions Based on the results, draw conclusions about whether a plant-based diet has a significant effect on athletic performance in high school athletes. If the hypothesis is supported by the data, discuss potential implications and future research directions.

Step 8: Communicate Findings Communicate the findings of the study in a clear and concise manner. Use appropriate language, visuals, and formats to ensure that the findings are understood and valued.

Applications of Research Process

The research process has numerous applications across a wide range of fields and industries. Some examples of applications of the research process include:

Scientific research: The research process is widely used in scientific research to investigate phenomena in the natural world and develop new theories or technologies. This includes fields such as biology, chemistry, physics, and environmental science.
Social sciences : The research process is commonly used in social sciences to study human behavior, social structures, and institutions. This includes fields such as sociology, psychology, anthropology, and economics.
Education: The research process is used in education to study learning processes, curriculum design, and teaching methodologies. This includes research on student achievement, teacher effectiveness, and educational policy.
Healthcare: The research process is used in healthcare to investigate medical conditions, develop new treatments, and evaluate healthcare interventions. This includes fields such as medicine, nursing, and public health.
Business and industry : The research process is used in business and industry to study consumer behavior, market trends, and develop new products or services. This includes market research, product development, and customer satisfaction research.
Government and policy : The research process is used in government and policy to evaluate the effectiveness of policies and programs, and to inform policy decisions. This includes research on social welfare, crime prevention, and environmental policy.

Purpose of Research Process

The purpose of the research process is to systematically and scientifically investigate a problem or question in order to generate new knowledge or solve a problem. The research process enables researchers to:

Identify gaps in existing knowledge: By conducting a thorough literature review, researchers can identify gaps in existing knowledge and develop research questions that address these gaps.
Collect and analyze data : The research process provides a structured approach to collecting and analyzing data. Researchers can use a variety of research methods, including surveys, experiments, and interviews, to collect data that is valid and reliable.
Test hypotheses : The research process allows researchers to test hypotheses and make evidence-based conclusions. Through the systematic analysis of data, researchers can draw conclusions about the relationships between variables and develop new theories or models.
Solve problems: The research process can be used to solve practical problems and improve real-world outcomes. For example, researchers can develop interventions to address health or social problems, evaluate the effectiveness of policies or programs, and improve organizational processes.
Generate new knowledge : The research process is a key way to generate new knowledge and advance understanding in a given field. By conducting rigorous and well-designed research, researchers can make significant contributions to their field and help to shape future research.

Tips for Research Process

Here are some tips for the research process:

Start with a clear research question : A well-defined research question is the foundation of a successful research project. It should be specific, relevant, and achievable within the given time frame and resources.
Conduct a thorough literature review: A comprehensive literature review will help you to identify gaps in existing knowledge, build on previous research, and avoid duplication. It will also provide a theoretical framework for your research.
Choose appropriate research methods: Select research methods that are appropriate for your research question, objectives, and sample size. Ensure that your methods are valid, reliable, and ethical.
Be organized and systematic: Keep detailed notes throughout the research process, including your research plan, methodology, data collection, and analysis. This will help you to stay organized and ensure that you don’t miss any important details.
Analyze data rigorously: Use appropriate statistical and analytical techniques to analyze your data. Ensure that your analysis is valid, reliable, and transparent.
I nterpret results carefully : Interpret your results in the context of your research question and objectives. Consider any limitations or potential biases in your research design, and be cautious in drawing conclusions.
Communicate effectively: Communicate your research findings clearly and effectively to your target audience. Use appropriate language, visuals, and formats to ensure that your findings are understood and valued.
Collaborate and seek feedback : Collaborate with other researchers, experts, or stakeholders in your field. Seek feedback on your research design, methods, and findings to ensure that they are relevant, meaningful, and impactful.

About the author

Muhammad Hassan

Researcher, Academic Writer, Web developer

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Basic Steps in the Research Process

The following steps outline a simple and effective strategy for writing a research paper. Depending on your familiarity with the topic and the challenges you encounter along the way, you may need to rearrange these steps.

Step 1: Identify and develop your topic

Selecting a topic can be the most challenging part of a research assignment. Since this is the very first step in writing a paper, it is vital that it be done correctly. Here are some tips for selecting a topic:

Select a topic within the parameters set by the assignment. Many times your instructor will give you clear guidelines as to what you can and cannot write about. Failure to work within these guidelines may result in your proposed paper being deemed unacceptable by your instructor.
Select a topic of personal interest to you and learn more about it. The research for and writing of a paper will be more enjoyable if you are writing about something that you find interesting.
Select a topic for which you can find a manageable amount of information. Do a preliminary search of information sources to determine whether existing sources will meet your needs. If you find too much information, you may need to narrow your topic; if you find too little, you may need to broaden your topic.
Be original. Your instructor reads hundreds of research papers every year, and many of them are on the same topics (topics in the news at the time, controversial issues, subjects for which there is ample and easily accessed information). Stand out from your classmates by selecting an interesting and off-the-beaten-path topic.
Still can't come up with a topic to write about? See your instructor for advice.

Once you have identified your topic, it may help to state it as a question. For example, if you are interested in finding out about the epidemic of obesity in the American population, you might pose the question "What are the causes of obesity in America ?" By posing your subject as a question you can more easily identify the main concepts or keywords to be used in your research.

Step 2 : Do a preliminary search for information

Before beginning your research in earnest, do a preliminary search to determine whether there is enough information out there for your needs and to set the context of your research. Look up your keywords in the appropriate titles in the library's Reference collection (such as encyclopedias and dictionaries) and in other sources such as our catalog of books, periodical databases, and Internet search engines. Additional background information may be found in your lecture notes, textbooks, and reserve readings. You may find it necessary to adjust the focus of your topic in light of the resources available to you.

Step 3: Locate materials

With the direction of your research now clear to you, you can begin locating material on your topic. There are a number of places you can look for information:

If you are looking for books, do a subject search in One Search . A Keyword search can be performed if the subject search doesn't yield enough information. Print or write down the citation information (author, title,etc.) and the location (call number and collection) of the item(s). Note the circulation status. When you locate the book on the shelf, look at the books located nearby; similar items are always shelved in the same area. The Aleph catalog also indexes the library's audio-visual holdings.

Use the library's electronic periodical databases to find magazine and newspaper articles. Choose the databases and formats best suited to your particular topic; ask at the librarian at the Reference Desk if you need help figuring out which database best meets your needs. Many of the articles in the databases are available in full-text format.

Use search engines ( Google , Yahoo , etc.) and subject directories to locate materials on the Internet. Check the Internet Resources section of the NHCC Library web site for helpful subject links.

Step 4: Evaluate your sources

See the CARS Checklist for Information Quality for tips on evaluating the authority and quality of the information you have located. Your instructor expects that you will provide credible, truthful, and reliable information and you have every right to expect that the sources you use are providing the same. This step is especially important when using Internet resources, many of which are regarded as less than reliable.

Step 5: Make notes

Consult the resources you have chosen and note the information that will be useful in your paper. Be sure to document all the sources you consult, even if you there is a chance you may not use that particular source. The author, title, publisher, URL, and other information will be needed later when creating a bibliography.

Step 6: Write your paper

Begin by organizing the information you have collected. The next step is the rough draft, wherein you get your ideas on paper in an unfinished fashion. This step will help you organize your ideas and determine the form your final paper will take. After this, you will revise the draft as many times as you think necessary to create a final product to turn in to your instructor.

Step 7: Cite your sources properly

Give credit where credit is due; cite your sources.

Citing or documenting the sources used in your research serves two purposes: it gives proper credit to the authors of the materials used, and it allows those who are reading your work to duplicate your research and locate the sources that you have listed as references. The MLA and the APA Styles are two popular citation formats.

Failure to cite your sources properly is plagiarism. Plagiarism is avoidable!

Step 8: Proofread

The final step in the process is to proofread the paper you have created. Read through the text and check for any errors in spelling, grammar, and punctuation. Make sure the sources you used are cited properly. Make sure the message that you want to get across to the reader has been thoroughly stated.

Additional research tips:

Work from the general to the specific -- find background information first, then use more specific sources.
Don't forget print sources -- many times print materials are more easily accessed and every bit as helpful as online resources.
The library has books on the topic of writing research papers at call number area LB 2369.
If you have questions about the assignment, ask your instructor.
If you have any questions about finding information in the library, ask the librarian.

Contact Information

Craig larson.

Librarian 763-424-0733 [email protected] Zoom: myzoom Available by appointment

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The purpose of this paper is to provide an overview of the process and stages involved in developing a research idea from its inception to realisation. It is not designed to be an all encompassing summary of the research process. It fprovides a brief guide to the most common sequence of stages involved in the development of a research idea into a viable research proposal. Useful references for further reading on important issues that are beyond the scope of this article are also provided.

Familiarity with the topic

Reviewing the literature.

Most literature searches begin with one of the many electronic databases available, using the author's name or a combination of carefully selected keywords. Individual databases are limited as to which journals are listed. Within sports and exercise science, Sports Discus and Medline are widely used. To avoid missing pertinent articles, it is suggested that a number of electronic databases are searched. Medline covers biomedically orientated journals, Sports Discus covers sport and exercise orientated sources, and the Science Citation Index covers scientific articles in general. In addition, the National Sports Medicine Institute has recently released the Sports Medicine and Related Topics (SMART) database of journal articles, which covers all aspects of sports and exercise science and medicine from 1985. Addresses for these databases on the internet are: for Medline, http://www.ncbi.nlm.nih.gov/PubMed/medline.html; for the Science Citation Index (United Kingdom higher education institutions only), http://www.bids.ac.uk/; for SMART, http://smart.nsmi.org.uk .

Most universities offering courses in sports and exercise science courses have access to Sports Discus available on a centrally accessed CD-ROM. Further relevant papers may be obtained by studying their reference lists. Papers that provide a critical review of the topic are also very useful. Many journals such as Sports Medicine specialise in reviews, although these can also be found in other mainstream journals such as the British Journal of Sports Medicine, Medicine and Science in Sports and Exercise , and Journal of Sports Sciences . If the library does not hold a particular journal, it should be possible to obtain issues through the university's interlibrary loan service, although this is expensive and may limit the number of papers obtained.

When writing a review paper or conducting a more sophisticated empirically based review, such as a meta-analysis, it is important to endeavour to obtain all papers asking a given research question, 2 whether they are published or not. Although this may not be practically possible, the researcher should be careful not to select only those papers that are easiest to obtain as this may bias the review. Hence, further steps should be taken to obtain more elusive papers and/or obtain a random selection of relevant papers. Rosenthal 3 has written a comprehensive paper on bibliographic retrieval for researchers wishing to conduct a meta-analysis.

The research hypothesis and rationale

The typical empirical journal article and research proposal commences with a brief literature review to provide the background and rationale for the research. Questions that remain unanswered, or findings that need clarifying, are often highlighted here. This leads into explicit statements about the importance and necessity of the planned research.

Once the research problem has been stated, the hypothesis is normally presented. 4 However, often, hypotheses are not stated in research papers, primarily because of authors' assumptions that the reader can implicitly determine the hypotheses being tested from the description of the purpose or statement of the problem, which is most commonly stated at the end of the introduction. 1

The expected results form the research hypothesis. For example, it may be hypothesised that the mean cholesterol levels of trained men are lower than those of sedentary men. This is a research hypothesis, as it states what the results are expected to be. Conversely, the null hypothesis often states what the researcher does not expect to be the case. Its purpose is for use in the statistical test of reliability of results. It usually, although not always, 1 states that there are no differences between treatments, or that there is no relation between variables. 4 For example, the null hypothesis for the above study may state that there is no difference between the mean cholesterol levels of trained and sedentary men. If the null hypothesis were true, any observed differences would be due to chance alone, and the statistically non-significant differences that existed in the sample would not be inferred to exist in the population. Huck and Cormier 1 (chapters 7 and 8) give a detailed description of the different forms of hypotheses and the stages of hypothesis testing.

The design of the study

A study should be designed to answer the research question being asked. A thorough evaluation of the literature can help the researcher avoid repeating design mistakes that have been made in the past. Theoretically, research studies should become better and better with time as past mistakes are rectified and studies become more and more robust. However, this is generally not the case as in reality each study is a new and novel endeavour. 5

TYPES OF STUDY

As in medical research, broadly speaking the types of study used in sports science research can be split into two groups: observational and experimental. 5

Observational design

In observational studies, the participants receive no treatment or experimental manipulation. As the name suggests, the variables of interest are recorded from the participant with no attempt to influence the variables in any way. This is a descriptive study. In observational studies, the researcher analyses the data with the aim of determining differences or relations between variables and reasons why they do or do not exist. In experimental studies, the effect of treatment or manipulation of the independent variable is examined. 5 Examples of observational studies include those that have recorded skinfold levels and other estimates of body fat, 6– 9 or the measurement of body fat and physical activity in children to assess whether there is a relation between the two. 10, 11 In the latter examples, if the participants had received an aerobic training programme to assess the effects on body fat, the independent variable in the study would have been directly manipulated and the study would be experimental in nature. 12

Experimental design

If the study has an experimental design—that is, one of the independent variables is to be manipulated, it is important to be sure that any observed changes in the dependent variable—for example, power output—are due to the experimental treatment—for example, creatine ingestion—and not due to chance, growth, learning, or other extraneous factors. For example, in a study to investigate the effects of creatine supplementation on maximal anaerobic capacity—for example, that of Worth et al 13 —a control group was necessary to separate the treatment effect from any other causes that may have improved performance. A placebo group was also included in the above study to determine whether any improvement in performance was due to the creatine supplementation or to a psychological effect. 4

There are situations in which the inclusion of a placebo is not possible. For example, in studies in which the treatment is obvious to the participant (and the investigator). An example of this is a study to examine the effects of cryotherapy on exercise induced muscle damage and the soreness that accompanies it—for example, the study of Eston and Peters. 14 In this study, the control group had no treatment for the symptoms of delayed onset muscle soreness, while the treatment group received cryotherapy by immersing the damaged arm in cool water for a limited period of time on several occasions after the eccentric exercise bout. It was not possible to have a placebo group in this study because it would be very clear to the participants what treatment they were receiving.

Repeated measures and independent groups design

Experimental studies can be conducted using separate groups for treatment, control, and placebo conditions (independent groups design) or by using the same group for all conditions (repeated measures design). The option chosen depends on the design of the experiment. There are advantages and disadvantages to each method.

REPEATED MEASURES DESIGN

In a repeated measures design, the same group is tested under all conditions. The experiment is more powerful, as the within group variability due to individual differences is removed 15 and thus the number of participants (n) in each condition can be smaller than if separate groups are required for each condition. However, the commitment required from each participant is greater. In addition, there may need to be a large gap between conditions because there may be long lasting effects that may remain during the subsequent condition. For example, if the treatment is a drug, it may remain in the participant's system after the drug course has finished. It is important that the drug is completely flushed out from the system or it may affect the results from the control or placebo condition. An example of this type of study is that of Head et al . 16 In this study, all participants received two types of β-blockers and a placebo for five days in a double blind randomised cross over design. A minimum of two days was allowed for wash out.

For many studies a repeated measures design is the best tool for tackling the research question. In a study of this nature, in which the same group of participants are exposed to several conditions, it is essential that the order in which they are exposed to the conditions is randomised. 4 This helps control for any learning effect or acclimatisation related to the testing procedure. For example, when the effects of practice in using ratings of perceived exertion (RPE) to regulate exercise intensity were assessed, healthy 17 and blind participants 18 performed bouts of exercise at randomised RPEs.

INDEPENDENT GROUPS DESIGN

If two or more independent groups are used in a study, the groups should be similar except for the factor that is being investigated. For example, if the treatment group is comprised of young men, the control group should also consist of young men, not older men or young women. Ideally the participants should only differ with respect to the variable of interest. The method of allocating participants to groups must not be affected by the characteristics of the participants, therefore each participant should have an equal chance of being in any group. Bland 5 (chapter 2) describes various methods of randomly allocating participants to groups. There are numerous examples of random assignment of participants to independent groups—for example, Doyle and Parfitt 19 and Ehrlich and Haber. 20

The equivalence of the groups with respect to various measures can be checked before treatment by simple independent groups t tests or, in the case of more than two groups, by a one way analysis of variance. Provided that there is sufficient power to detect differences that are meaningful, these tests can provide an assurance of the equivalence of the groups. Alternatively, but less commonly, the investigators may adjust the scores after treatment on the basis of differences in the groups' scores before the test by using analysis of covariance procedures—for example, the study of Eston et al . 21 In this study, scores on muscle strength after treatment were adjusted for each group using the score obtained before the test as the covariate. 22 This reduced the possibility of the scores obtained after treatment being influenced by initial group differences.

When independent groups are used, the commitment required from the participant is less. Normally, he/she will experience the procedure only once. The time taken is therefore less, as all groups may be studied simultaneously. However, the design is less powerful, as the within group variability is greater because of individual differences between groups. 15 This implies that more participants per group are necessary (in comparison with a repeated measures design) for the design to have sufficient power.

MIXED MODEL DESIGN

Perhaps the most commonly used experimental design in sports and exercise science research is the mixed model analysis of variance. This contains at least one repeated measures factor and one independent groups factor. A typical example of this would be an experimental study that compares effects before and after treatment. For example, the effects of aerobics training on peak oxygen uptake and submaximal heart rate measures in girls, 23 or the effects of a prophylactic anti-inflammatory drug on muscle soreness after strenuous eccentric exercise—for example, the study of Semark et al . 24 In both of these studies, the participants were randomly assigned to an experimental group and a control group. In the latter study, the control group received a placebo. There are many other examples of the mixed model type of study.

Blind/double blind studies

In a single blind study, participants do not know whether they are receiving the placebo or the experimental treatment. A double blind study is when the tester also does not know what treatment the participant is receiving. This strengthens the design as it also reduces the tester's potential influence on the participants' results. Hence, neither the participant's nor the tester's expectations of the effects of the treatment should affect the outcome of the study. This is obviously important in studies to determine the effects of orally administered substances on performance, such as in the study by Head et al , 16 which assessed the effects of two different types of β-blocker on exercise metabolism, or in studies to assess the effects of oral creatine supplementation on anaerobic capacity. 13

Power of the study

There is increasing criticism about the lack of statistical power of papers published in sports and exercise science and psychology journals. 25 – 27 Statistical power refers to the probability of rejecting the null hypothesis—that is, the probability that the study will lead to significant results. 26 If the null hypothesis is false but not rejected, a type 2 error is incurred. Cohen 26 suggested that a power of 0.80 is adequate when an alpha is set at 0.05—that is, the risk of type 1 error, which is rejection of the null hypothesis when it is true, is 0.05. This means that the risk of a type 2 error is 0.20.

An important consideration in relation to the statistical power of the study is the magnitude of the relation or treatment effect. This is known as the effect size. When calculated a priori, this quantifies the degree to which the investigator believes the null hypothesis to be false. 26 Each statistical test has an effect size index, which ranges from zero upwards and is scale free. 26 For example, the effect size index for a correlation is simply r ; no conversion is necessary. For assessment of the difference between two sample means, Cohen's d , Hedges g , or Glass's Δ can be used. These divide the difference between two means by a standard deviation (see Rosenthal, 28 p 35). Formulae are available for converting other test statistics—for example, t test, one way analysis of variance, and χ 2 results—into effect size indexes (see Rosenthal, 28 p 19).

To evaluate an effect size, some idea of its scale is needed. 26 Effect sizes are often described as small, medium, and large. Correlations ( r ) equalling 0.1, 0.3, and 0.5 and Cohen's d equalling 0.2, 0.5, and 0.8 equate to small, medium, and large effect sizes respectively. A table detailing the magnitude of other effect size indexes equal to small, medium, and large effect sizes is presented in Cohen. 26 The smaller the expected effect size, the larger the sample size necessary if the study is to have sufficient power to detect that effect size.

An example of a study in which the effect size may be medium, could be one to assess the effects of habitual physical activity on body fat in children—for example, that of Rowlands et al . 10 In this study, there was a moderate correlation between habitual physical activity and body fat, corresponding to a medium effect size. A large effect size may be expected in a study to assess the effects of a very low energy diet on body fat in overweight women; an example is the study of Eston et al . 29 In this study, a greatly reduced energy intake (daily intake 1695 kJ a day for six weeks) resulted in a substantial decrease in total body mass and percentage body fat.

The effect size should be estimated during the design stage of a study. This allows the determination of the sample size required to give adequate power for a given alpha. Hence, the study can be designed to ensure it has sufficient power to detect the effect of interest—that is, minimising type 2 error. A simple table detailing sample sizes necessary to detect small, medium, and large effect sizes, with a power of 0.80 and an alpha of 0.05, is presented in Cohen. 26 This table covers eight statistical tests including the difference between independent means, product-moment correlation, χ 2 , and one way analysis of variance. More detailed descriptions of power analysis and methods for determining the sample size necessary in more complex tests can be found in the texts by Cohen 30 and Stevens. 15 Power calculations can also be carried out on interactive sites on the internet—for example, http://members.aol.com/johnp71/javastat.html#Power .

When empirical data are available, this can sometimes be used to estimate the effect size for a study. However, for some research questions it is difficult to find enough information to estimate the expected effect size. Here, the expected effect size may be difficult to calculate because of the limited number of studies that provide empirical information on the topic, or there may be insufficient detail provided in the results of the relevant studies. To enable comparison of effect sizes from studies that differ in sample size, it is recommended that, in addition to reporting the test statistic and p value, the appropriate effect size index is also reported.

A review of 108 articles published in the Australian Journal of Science and Medicine in Sport (AJMS; now The Journal of Science and Medicine in Sport ) in 1996 or 1997 showed that the median power to detect small, medium, and large effect sizes was 0.10, 0.46, and 0.84 respectively. 27 No study had adequate power to detect a small effect size, 38% had adequate power to detect a medium effect size, and 75% had adequate power to detect a large effect size. It is clear that, as recently as two to three years ago, the power of studies was often not being considered at the design stage of a study, if at all.

Ethical considerations

A further consideration in the design of a study involves the ethics of the testing procedures. Some journals will not accept papers unless the study has had ethics approval from a recognised ethics committee. The ethical implications of the study are dependent on the procedures to be undertaken and the nature of the participants. For example, the British Association of Sport and Exercise Sciences (BASES) recommend that ethical clearance should be obtained before imposing unusual or severe psychological or physiological stress, administering any ergogenic aid, working with clients with disabilities, or using biopsy or venepuncture techniques. 31 The above list is not complete, and where there is any doubt cases should be looked at individually. Certain procedures that may be approved for adult participants may not be approved for children. Children are recognised as a vulnerable group with a limited comprehension capacity. 32 Consequently, they are unable legally to give consent. However, it is generally accepted that parents/guardians can give parental permission, and children who are old enough can choose whether or not to participate. Rowland 32 (chapter 5) presents a thorough discussion on the ethical aspects of research with children.

Whether the participants are children or not, the relevance of each of the measures or treatments should be considered during the design stage of the research. There should be a clear and justifiable rationale for the necessity of invasive procedures, particularly if there are valid alternative and non-invasive measures available. The frequency of the invasive procedures and the effect this has on the participants should be considered.

A further ethical consideration involves the denial of potentially beneficial treatment. For example, in an experimental design there may be one group of participants who receive the treatment, one group who receive the placebo, and one group who receive the control treatment. Those who receive the placebo will, by definition, think they are receiving the treatment. In this case, both the placebo and control group have been denied the treatment. It is important to consider the ethics of denying these groups the treatment, particularly if the treatment is expected to be beneficial. This does not arise in a repeated measures design as all participants are exposed to all treatments.

A possible solution is to offer all groups the treatment after the study. This would not be possible with some studies—for example, when the purpose of the treatment is to reduce the symptoms of delayed onset muscle soreness, because the symptoms would have dissipated by the end of the study. However, if the effects of an ergogenic aid were studied, the participants may volunteer because they believe they will have the opportunity to benefit from the ergogenic aid. In this situation it would be possible to offer the aid to all participants after the study. Ethically, this may be preferable to withholding the treatment from two thirds of the volunteers. It may also prevent participants from withdrawing from a study which they consider is providing little or no benefit to them.

This issue becomes increasingly important if the treatment is for a medical condition or for rehabilitation. This is a common scenario in clinical trials. It has been argued that withholding a potentially beneficial treatment from patients is ethically justified, as any biologically active treatment is also potentially harmful. Hence, the benefits need to be conclusively demonstrated in properly controlled trials before general administration. 5 The ethics of withholding treatment clearly depend on the type of treatment and participants involved.

Before a study is embarked on, it is necessary to ensure that the study is viable. This involves making a realistic assessment of the costs, time, and availability of the participants. If there is an application for funding, these details have to be approved by the host institution and the funding body. Costs will be related to the sample size, duration of the study, equipment needed, consumables, research assistants or other staff, travel, conference presentations, and institutional overheads.

tk;3The facilities available for conducting the research also need to be considered. If the study is laboratory based, it may be necessary to book laboratory time relatively early, as many people typically share laboratory facilities. This can only be achieved if a reasonably accurate estimate of the laboratory time needed to conduct the research is known. A pilot study can help answer these questions, identify problems, and prevent or limit methodological faults in the main study. Piloting procedures are an essential part of preparing a study. 4

Most studies within sports science and sports medicine require human participants. It is important to consider how these participants will be obtained and how representative of the relevant population they are. It may be necessary to advertise or send letters to request participation. If this is so, consideration should be given as to where to advertise, or where to obtain addresses of potential participants. For example, an advertisement in a leisure centre is likely to attract a different type of participant from a similar advertisement in a doctors surgery or outpatients clinic. The methods of obtaining participants will be largely determined by the population the sample is supposed to represent. For some studies, it is acceptable to use the most convenient sample of sports and exercise science undergraduates, but this is not appropriate for all proposed research.

Expected outcomes

During the planning stages of the study, the potential benefits should be considered. The expected outcomes are strongly linked with the literature review, hypothesis, and rationale. A useful exercise is to plot a graph of the expected outcomes for each group. This also helps to identify the most appropriate statistical analysis of the prospective data. An assessment of the expected outcomes and the potential value of these outcomes will help show whether or not the study is worth while.

We have considered some of the most important factors involved in designing a viable study that will adequately address the research question. Although we do not profess to be experts in all aspects of the above, we have learned through experience that attention to many of the above points will help to avoid frustration during the experimental process and when the study is presented for external review and subsequent presentation and publication. Good luck in your research.

↵ Huck SW, Cormier WH. Reading statistics and research . New York: Harper Collins College Publishers, 1996.
↵ Rosenthal R. Writing meta-analytic reviews. Psychol Bull 1995 ; 118 : 183 –92. OpenUrl CrossRef Web of Science
↵ Rosenthal MC. Bibliographic retrieval for the social and behavioural scientist. Research in Higher Education 1985 ; 22 : 315 –33.
↵ Thomas JR, Nelson JK. Research methods in physical activity . Champaign, IL: Human Kinetics, 1990.
↵ Bland M. An introduction to medical statistics , 2nd ed. Oxford: Oxford Medical Publications, Oxford University Press, 1996.
↵ Durnin JVGA, Womersley J. Body fat assessed from total body density and its estimation from skinfold thickness: measurements on 481 men and women aged from 16 to 72 years. Br J Nutr 1974 ; 32 : 77 –97. OpenUrl CrossRef PubMed Web of Science
Jackson AS, Pollock ML. Generalized equations for predicting body density of men. Br J Nutr 1978 ; 40 : 497 –504. OpenUrl CrossRef PubMed Web of Science
Eston, RG, Fu F. Fung L. Validity of conventional anthropometric techniques for estimating body composition in Chinese adults. Br J Sports Med 1995 ; 29 : 52 –6. OpenUrl Abstract / FREE Full Text
↵ Eston RG, Evans R, Fu F. Estimation of body composition in Chinese and British males by ultrasonic assessment of segmental adipose tissue volume. Br J Sports Med 1994 ; 28 : 9 –13. OpenUrl Abstract / FREE Full Text
↵ Rowlands AV, Eston RG, Ingledew DK. The relationship between activity levels, body fat and aerobic fitness in 8–10 year old children. J Appl Physiol 1999 ; 86 : 1428 –35. OpenUrl Abstract / FREE Full Text
↵ Taylor W, Baranowski T. Physical activity, cardiovascular fitness and adiposity in children. Res Q Exerc Sport 1991 ; 62 : 157 –63. OpenUrl PubMed Web of Science
↵ Epstein LH, Wing RR, Koeske R, et al . Comparison of lifestyle change and programmed aerobic exercise on weight and fitness changes in obese children. Behavioural Therapy 1982 ; 13 : 651 –65. OpenUrl CrossRef Web of Science
↵ Worth SJ, Eston RG, Lemmey AB. Effects of oral creatine supplementation on anaerobic capacity in young trained men and women. J Sports Sci 1999 ; 17 : 565 –6P. OpenUrl
↵ Eston RG, Peters D. Effects of cold water immersion on the symptoms of exercise-induced muscle damage. J Sports Sci 1999 ; 17 : 231 –8. OpenUrl CrossRef PubMed Web of Science
↵ Stevens J. Applied multivariate statistics for the social sciences , 3rd ed. Mahwah, NJ: Lawrence Erlbaum Associates, 1996.
↵ Head A, Maxwell S, Kendall MJ. Exercise metabolism in healthy volunteers taking celipropol, atenelol and placebo. Br J Sports Med 1997 ; 31 : 120 – 5. OpenUrl Abstract / FREE Full Text
↵ Eston RG, Williams JG. Reliability of ratings of perceived effort for regulation of exercise intensity. Br J Sports Med 1988 ; 22 : 153 –5. OpenUrl Abstract / FREE Full Text
↵ Buckley JP, Eston RG, Sims JW, et al . Reliability of regulating exercise intensity using a braille ratings of perceived exertion scale with blind subjects. Med Sci Sports Exerc 1999 ; 31 : S113 . OpenUrl
↵ Doyle J, Parfitt G. The effect of induced mood states on performance profile areas of perceived need. J Sports Sci 1999 ; 17 : 115 –27. OpenUrl PubMed Web of Science
↵ Erhlich D, Haber P. Influence of acupuncture on physical performance capacity and haemodynamic parameters. Int J Sports Med 1992 ; 13 : 486 –91. OpenUrl CrossRef PubMed Web of Science
↵ Eston RG, Finney S, Baltzopoulos V, et al . Muscle soreness and strength loss changes after downhill running following a prior bout of isokinetic eccentric exercise. J Sports Sci 1996 ; 14 : 291 –9. OpenUrl CrossRef PubMed
↵ Vincent WJ. Statistics in kinesiology . Champaign, IL: Human Kinetics, 1995:189.
↵ Welsman JR, Armstrong N, Withers S. Responses of young girls to two modes of aerobic training. Br J Sports Med 1997 ; 31 : 139 –42. OpenUrl Abstract / FREE Full Text
↵ Semark A, Noakes TD, St Clair Gibson A, et al . The effect of a prophylactic dose of flurbiprofen on muscle soreness and sprinting performance in trained subjects. J Sports Sci 1999 ; 17 : 197 –203. OpenUrl CrossRef PubMed Web of Science
↵ Christensen JE, Christensen CE. Statistical power analysis of health, physical education and recreation research. Res Q 1977 ; 48 : 204 –8. OpenUrl PubMed Web of Science
↵ Cohen J. A power primer. Psychol Bull 1992 ; 112 : 155 –9. OpenUrl CrossRef PubMed Web of Science
↵ Speed HD, Anderson MB. Power, effect size and the misinterpretation of statistical inference in exercise science. 1998 Australian Conference of Science and Medicine in Sport . Bruce, Australia: Sports Medicine Australia, 1998:215P.
↵ Rosenthal R. Meta-analytic procedures for social research (revised edition). Newbury Park, CA: Sage, 1991.
↵ Eston RG, Shephard S, Kreitzman S, et al . Effect of very low calorie diet on body composition and exercise response in sedentary women. Eur J Appl Physiol 1992 ; 65 : 452 –8. OpenUrl
↵ Cohen J. Statistical power analysis for the behavioural sciences , 2nd ed. Mahwah, NJ: Hillsdale, Lawrence Erlbaum Associates, 1988.
↵ BASES, British Association of Sport and Exercise Sciences. Code of conduct . Headingley, Leeds: BASES, 1995.
↵ Rowland TW. Developmental exercise physiology . Champaign, IL: Human Kinetics, 1996.

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The Defense Acquisition Encyclopedia

Program Management

The research process entails a systematic endeavor to acquire knowledge, resolve issues, or address particular inquiries. The process is a series of systematic procedures that a researcher must undertake to generate valuable knowledge that is relevant to the project and focused on the relevant subject matter. The process is iterative, with each subsequent step being influenced by the preceding one. The successful execution of this task necessitates meticulous strategic planning, meticulous attention to intricate particulars, and an unwavering dedication to acquiring knowledge and comprehension.

5 Steps in the Research Process Overview

The following steps outline a simple and effective process for conducting both basic and practical research. The five (5) steps in the research process are: [1]

Step 1: Locating and Defining Issues or Problems – Understanding the questions that need to be answered or studied
Step 2: Designing the Research Project – Creating a research plan
Step 3: Collecting Data – Obtaining the information needed to solve the identified issue or problem
Step 4: Interpreting Research Data – examining the research data and coming up with a conclusion that solves the problem
Step 5: Report Research Findings – Presenting the information

AcqNotes Tutorial

Step 1 – Locating and Defining Issues or Problems

This step focuses on uncovering the nature and boundaries of a situation or question that needs to be answered or studied. In defining the issues or problems, the researcher should take into account the purpose of the study, the relevant background information, what information is needed, and how it will be used in decision-making. A well-defined problem will help the researcher through all steps of the research process, from setting goals to choosing a method. There are a number of ways to learn more about a subject and get a better grasp on it in Step 2.

Step 2 – Designing the Research Project

This step is focused on creating a research plan or overall approach to how you are going to solve the issue or problem identified. A research plan or approach is a framework or blueprint for conducting a research project. It details the procedures necessary for obtaining the required information, and its purpose is to design a study that will test the hypotheses of interest, determine possible answers to the research questions, and provide the information needed for decision-making.

The research design involves the following steps:

Step 1: Conduct secondary data analysis
Step 2: Do qualitative research
Step 3: Determine methods of collecting quantitative data (survey, observation, and experimentation)
Step 4: Determine the definition of the information needed
Step 5: Determine measurement and scaling procedures
Step 6: Design a questionnaire
Step 7: Sampling process and sample size
Step 8: Plan of data analysis

Step 3 – Collecting Data

This step revolved around obtaining the information needed to solve the identified issue or problem. Data collection can involve experiments, observations, personal interviewing (in-home, mall intercept, or computer-assisted personal interviewing), from an office by telephone (telephone or computer-assisted telephone interviewing), or through the mail (traditional mail and mail panel surveys with recruited households). The two groups of researchers must provide data.

Data collection techniques can include:

Interviews: Asking people questions about their known information
Observations: collecting data without asking questions.
Questionnaires: Ask questions among a group of people
Focus Groups: Interviewing and observing a group of people
Documents and Records: Old-fashioned research
Literature review: Old-fashioned research
Library Sources: Old reports and articles/books

Step 4 – Interpreting Research Data

This step is focused on interpreting and examining the research data and coming up with a conclusion that solves the problem. Make sure the conclusion is easy to understand and well thought out based on the data collected.

Analysis Steps

Step A: Review your research plan
Step B: Organize your findings and the information you have collected from Step 3.
Step C: Create a rough draft of your findings, recommendations, and conclusion. The rough draft will help you get your thoughts organized.
Step D: Polish the rough draft into your final research finding. You will most likely revise the draft many times before the final product is ready for Step 5.

Step 5 – Report Research Findings

The final step is to report the research findings to those who need the data to make decisions. The findings should be presented in an understandable format so that they can be readily used in the decision-making process. In addition, an oral presentation should be made to management using tables, figures, and graphs to enhance clarity and impact.

Research Reporting Formats:

Formal Paper
Published Article
PowerPoint Presentation
Audio or Video
Spreadsheet

Typical Formal Research Report Format

A formal research report typically consists of several sections organized in a specific order to present the research findings clearly and structured. Here is a notional format of a research report, including the typical sections:

Title Page: – Title of the Research Report – Name(s) of the Author(s) – Affiliation(s) of the Author(s) – Date of Submission
Abstract: – A brief summary of the research objectives, methods, key findings, and conclusions. – Usually limited to a specific word count or length.
Table of Contents: – A list of the main sections, subsections, and page numbers in the report. – Helps readers navigate through the report easily.
Introduction: – Provides an overview of the research topic, including background information, context, and significance. – States the research problem, objectives, and research questions. – Outlines the scope and limitations of the study.
Literature Review: – Reviews relevant literature and previous studies related to the research topic. – Summarizes existing knowledge, theories, and methodologies. – Identifies gaps, controversies, or unresolved issues that the current research aims to address.
Methodology: – Describes the research design, methods, and procedures used to collect and analyze data. – Includes information on the sample size, data sources, data collection tools, and data analysis techniques. – Provides sufficient details for replication and validation of the study.
Results: – Presents the findings of the research in a clear and organized manner. – Utilizes tables, figures, charts, or graphs to present data. – Includes descriptive statistics, qualitative analysis, or any other relevant analysis outputs.
Discussion: – Interprets and discusses the research findings in relation to the research objectives. – Compares the results with existing literature and theories. – Analyzes patterns, trends, correlations, or discrepancies in the data. – Provides explanations, justifications, or hypotheses to support the findings.
Conclusion: – Summarizes the main findings of the research. – Restates the research objectives and addresses the research questions. – Highlights the contributions and implications of the study. – Suggests recommendations for future research or practical applications.
References: – Lists all the sources cited within the research report. – Follows a specific referencing style (e.g., APA, MLA, IEEE) as per the guidelines.
Appendices: – Includes supplementary information or additional data that supports the research findings but is not necessary for the main body of the report. – May include survey questionnaires, interview transcripts, data tables, software code, or any other relevant materials.

It’s important to note that the structure and specific section names may vary depending on the discipline, research field, or journal requirements. Always refer to the specific guidelines your institution or publisher-provided when preparing a research report.

Research Process Lessons Learned

Embarking on a research journey is a dynamic and enlightening experience that often leads to a multitude of lessons learned. The research process is not merely a sequence of steps but a complex exploration that demands critical thinking, adaptability, and perseverance. Through the course of conducting research, individuals encounter challenges, make discoveries, and refine their methodologies. These lessons extend beyond the acquisition of academic knowledge, encompassing skills such as effective communication, time management, and the ability to navigate through the vast sea of information.

Define the research challenge and goals in detail: It’s crucial to grasp exactly what you’re attempting to learn and what you want to achieve. This will make it easier to direct your research efforts and guarantee that you are gathering pertinent facts.
Select the best research design possible: Various research designs are applicable for various research topics. Choosing the proper design will help ensure your study’s validity and reliability.
Collect reliable information: because it will directly impact how well your research turns out. Use the right data-gathering techniques, and make sure the data is gathered reliably and consistently.
Analyze the data correctly: If you want to draw reliable findings from your research, your data analysis must be done correctly. It is crucial to employ the proper statistical methods and interpret the findings cautiously.
Effectively explain your findings: It’s critical to provide your research’s conclusions in a clear, succinct manner. Writing a research report, presenting your findings at a conference, or publishing your study in a journal are all examples of how to do this.

Qualitative Research in the Research Process

Information, industry experts, and secondary data may not be sufficient to define the research problem. Sometimes qualitative research must be undertaken to gain a qualitative understanding of the problem and its underlying factors. Qualitative research is unstructured, exploratory in nature, based on small samples, and may utilize popular qualitative techniques such as focus groups (group interviews), word association (asking respondents to indicate their first responses to stimulus words), and depth interviews (one-on-one interviews which probe the respondents’ thoughts in detail). Other exploratory research techniques, such as pilot surveys with small samples of respondents, may also be undertaken.

There are various steps in the research process, which makes it simple to accomplish the research successfully. The above-described steps in the research process are interdependent, hence the order must be followed. So, if we want to conduct research, we should adhere to the steps of the research process to obtain good and reliable results.

AcqLinks and References:

[1] Pride, Ferel (2010). Marketing. South-Western Cengage Learning

Updated: 1/18/2024

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Research Process

Dissertation markers expect you to include the explanation of research process in methodology chapter. A typical research process comprises the following stages:

1. Selecting the research area . Your dissertation marker expects you to state that you have selected the research area due to professional and personal interests in the area and this statement must be true. Students often underestimate the importance of this first stage in the research process. If you find a research area and research problem that is genuinely interesting to you it is for sure that the whole process of writing your dissertation will be much easier. Therefore, it is never too early to start thinking about the research area for your dissertation.

2. Formulating research aim, objectives and research questions or developing hypotheses . The choice between the formulation of research questions and the development of hypotheses depends on your research approach as it is discussed further below in more details. Appropriate research aims and objectives or hypotheses usually result from several attempts and revisions.

Accordingly, you need to mention in your dissertation that you have revised your research aims and objectives or hypotheses during the research process several times to get their final versions. It is critically important that you get confirmation from your supervisor regarding your research questions or hypotheses before moving forward with the work.

3. Conducting the literature review . Literature review is usually the longest stage in the research process. Actually, the literature review starts even before the formulation of research aims and objective. This is because you have to check if exactly the same research problem has been addressed before and this task is a part of the literature review. Nevertheless, you will conduct the main part of the literature review after the formulation of research aim and objectives. You have to use a wide range of secondary data sources such as books, newspapers, magazines, journals, online articles etc.

4. Selecting data collection methods . Data collection method(s) need to be selected on the basis of critically analyzing advantages and disadvantages associated with several alternative methods. In studies involving primary data collection, you need to write about advantages and disadvantages of selected primary data collection method(s) in detailed manner in methodology.

5. Collecting the primary data . You will have to start primary data collection only after detailed preparation. Sampling is an important element of this stage. You may have to conduct pilot data collection if you chose questionnaire primary data collection method. Primary data collection is not a compulsory stage for all dissertations and you will skip this stage if you are conducting a desk-based research.

6. Data analysis . Analysis of data plays an important role in the achievement of research aim and objectives. This stage involves an extensive editing and coding of data. Data analysis methods vary between secondary and primary studies, as well as, between qualitative and quantitative studies. In data analysis coding of primary data plays an instrumental role to reduce sample group responses to a more manageable form for storage and future processing. Data analysis is discussed in Chapter 6 in great details.

7. Reaching conclusions . Conclusions relate to the level of achievement of research aims and objectives. In this final part of your dissertation you will have to justify why you think that research aims and objectives have been achieved. Conclusions also need to cover research limitations and suggestions for future research .

8. Completing the research . Following all of the stages described above, and organizing separate chapters into one file leads to the completion of the first draft. You need to prepare the first draft of your dissertation at least one month before the submission deadline. This is because you will need to have sufficient amount of time to address feedback to be provided by your supervisor.

Individual stages in the research process outlined above are interdependent and the sequence has to be maintained. Moreover, the process of any research tends to be iterative, meaning that you may have to return back to the previous stages of the research process several times for revisions and improvement. In other words, no stage of the research process is fully completed until the whole dissertation is completed.

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Research Process – The 5 Stages of Your Research

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Research is the creative and systematic work done to increase knowledge on a particular topic or phenomenon. It involves multiple steps such as defining a research question, conducting a literature review, collecting data, analyzing results, and drawing conclusions to contribute to the existing body of knowledge. This post discusses the entire research process and everything you should know about it.

Inhaltsverzeichnis

1 Research process – In a Nutshell
2 Definition: Research process
3 Step 1 of the research process: Choosing a topic
4 Step 2 of the research process: Identify a problem
5 Step 3 of the research process: Research question
6 Step 4 of the research process: Research design
7 Step 5 of the research process: Research proposal
8 Overview of all research process articles

Research process – In a Nutshell

The research process involves the critical steps between choosing a topic and presenting it for approval.
It is the first process of starting a research project.
The research processes include selecting a topic, problem identification, research question, research design formulation, and writing a proposal.

Definition: Research process

This process involves the steps of conducting research work to get effective or desired results from your project. It entails selecting the topic, conducting problem research, developing a research design, and establishing a proposal.

Step 1 of the research process: Choosing a topic

Choosing a topic for your research is not as easy as you may assume, especially if you have not done it before. For instance, you must become well-versed in the material surrounding the topic, the possible research topics , and if there is room for more knowledge. Furthermore, choosing a topic for your research process may take a while and involve the methods below.

Brainstorming ideas

You can come up with a research topic by brainstorming ideas. For instance, you can find a field of interest or classes where you want to choose your idea. However, you may have already thought of a topic, like when applying to graduate school. However, even with an existing topic idea, you still need to write a statement of purpose. The purpose of brainstorming ideas is to choose a specific topic.

Familiarize yourself with your topic

Once you have landed on the topic you want to write about; the next step is to familiarize yourself with it. You can get a good sense of the chosen topic by reviewing existing literature. While reading about the topic, taking notes, and identifying problem areas, debates, and questions would be wise. This helps you find a specific niche for your research.

Considering the practicalities

The next part of choosing a topic is considering the practicalities. For instance, you should consider the factors below:

The requirements of your program
The time you have to conduct the research and submit your report
The resources you will need to research the particular topic

Step 2 of the research process: Identify a problem

Consider the following elements when identifying a research problem .

Theoretical and practical problems

A well-identified research problem will help the researcher accomplish all the vital phases of the research process, like selecting objectives and research methodology and making your project manageable. There are two types of problems in research: practical and theoretical .

Practical research focuses on processes that are not working properly. Examples of practical research problems are:

Performance/ productivity issues in an organization
Processes that need improvement in an institution
Areas of concern in a field

On the other hand, theoretical research is associated with unexplored phenomena. For example:

A context that has not been studied closely (like long-term effects of radiation from Wi-Fi)
A contradiction between various perspectives (like the difference between racism and colorism)
A correlation that is not well-understood (like the link between Vitamin D deficiency and cardiovascular health)

Writing a problem statement

A problem statement is a precise description of the issues your research project will address. It is crucial for finding and implementing effective solutions in a research project. Additionally, a problem statement helps you contextualize and understand the implication of your research problem. An effective problem statement should:

Put the problem in context
Describe the precise problem
Show the relevance of the problem
Set objectives

Step 3 of the research process: Research question

A research question aims to help you get perspectives on what you should focus on when conducting research for your project.

A strong research question should be, focused, researchable, feasible, specific, complex, and relevant. Other types of research require a conceptual framework and testable hypotheses before coming up with research questions.

Step 4 of the research process: Research design

A research design is an approach for answering your research questions using empirical data. A research design aims to ensure that our methods match your project’s aims. It also ensures that you use the right methods for data analysis. Creating a research design entails the following steps:

When creating a research design, you must consider primary or secondary data and qualitative or quantitative methods. Your choice will influence your entire research design.

Step 5 of the research process: Research proposal

Finally, you must write a research proposal through which you present your objectives, content, and plan. The proposal will demonstrate the relevance of your study and should include a problem statement, research objectives, questions, and methodology.

Additionally, your research proposal needs a literature review section that shows that you have researched and understood your topic. It also shows that you are not repeating what others have said or done.

You must present the research proposal to your professor or instructor for approval before conducting the study.

Overview of all research process articles

Research question examples
Problem statement example
Research problem
Relevance of research

What are the five stages of the research process?

The five stages are choosing a topic, identifying a problem, formulating a research process, creating a research design, and writing a research proposal.

What is the best way to choose a topic for your research process?

There are many methods for choosing a topic for your research process. The best ones are brainstorming ideas, familiarizing yourself with your topic, and considering the practicalities of your options.

What is the difference between choosing a research topic and identifying a problem?

The difference is that you can choose a topic in a general area while identifying a problem helps you focus your research on a specific subject in your topic.

What is the value of the research process?

The research process helps you get effective results from your project. It also helps you design your project.

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Illustration by James Round

How to plan a research project

Whether for a paper or a thesis, define your question, review the work of others – and leave yourself open to discovery.

by Brooke Harrington + BIO

is professor of sociology at Dartmouth College in New Hampshire. Her research has won international awards both for scholarly quality and impact on public life. She has published dozens of articles and three books, most recently the bestseller Capital without Borders (2016), now translated into five languages.

Edited by Sam Haselby

Need to know

‘When curiosity turns to serious matters, it’s called research.’ – From Aphorisms (1880-1905) by Marie von Ebner-Eschenbach

Planning research projects is a time-honoured intellectual exercise: one that requires both creativity and sharp analytical skills. The purpose of this Guide is to make the process systematic and easy to understand. While there is a great deal of freedom and discovery involved – from the topics you choose, to the data and methods you apply – there are also some norms and constraints that obtain, no matter what your academic level or field of study. For those in high school through to doctoral students, and from art history to archaeology, research planning involves broadly similar steps, including: formulating a question, developing an argument or predictions based on previous research, then selecting the information needed to answer your question.

Some of this might sound self-evident but, as you’ll find, research requires a different way of approaching and using information than most of us are accustomed to in everyday life. That is why I include orienting yourself to knowledge-creation as an initial step in the process. This is a crucial and underappreciated phase in education, akin to making the transition from salaried employment to entrepreneurship: suddenly, you’re on your own, and that requires a new way of thinking about your work.

What follows is a distillation of what I’ve learned about this process over 27 years as a professional social scientist. It reflects the skills that my own professors imparted in the sociology doctoral programme at Harvard, as well as what I learned later on as a research supervisor for Ivy League PhD and MA students, and then as the author of award-winning scholarly books and articles. It can be adapted to the demands of both short projects (such as course term papers) and long ones, such as a thesis.

At its simplest, research planning involves the four distinct steps outlined below: orienting yourself to knowledge-creation; defining your research question; reviewing previous research on your question; and then choosing relevant data to formulate your own answers. Because the focus of this Guide is on planning a research project, as opposed to conducting a research project, this section won’t delve into the details of data-collection or analysis; those steps happen after you plan the project. In addition, the topic is vast: year-long doctoral courses are devoted to data and analysis. Instead, the fourth part of this section will outline some basic strategies you could use in planning a data-selection and analysis process appropriate to your research question.

Step 1: Orient yourself

Planning and conducting research requires you to make a transition, from thinking like a consumer of information to thinking like a producer of information. That sounds simple, but it’s actually a complex task. As a practical matter, this means putting aside the mindset of a student, which treats knowledge as something created by other people. As students, we are often passive receivers of knowledge: asked to do a specified set of readings, then graded on how well we reproduce what we’ve read.

Researchers, however, must take on an active role as knowledge producers . Doing research requires more of you than reading and absorbing what other people have written: you have to engage in a dialogue with it. That includes arguing with previous knowledge and perhaps trying to show that ideas we have accepted as given are actually wrong or incomplete. For example, rather than simply taking in the claims of an author you read, you’ll need to draw out the implications of those claims: if what the author is saying is true, what else does that suggest must be true? What predictions could you make based on the author’s claims?

In other words, rather than treating a reading as a source of truth – even if it comes from a revered source, such as Plato or Marie Curie – this orientation step asks you to treat the claims you read as provisional and subject to interrogation. That is one of the great pieces of wisdom that science and philosophy can teach us: that the biggest advances in human understanding have been made not by being correct about trivial things, but by being wrong in an interesting way . For example, Albert Einstein was wrong about quantum mechanics, but his arguments about it with his fellow physicist Niels Bohr have led to some of the biggest breakthroughs in science, even a century later.

Step 2: Define your research question

Students often give this step cursory attention, but experienced researchers know that formulating a good question is sometimes the most difficult part of the research planning process. That is because the precise language of the question frames the rest of the project. It’s therefore important to pose the question carefully, in a way that’s both possible to answer and likely to yield interesting results. Of course, you must choose a question that interests you, but that’s only the beginning of what’s likely to be an iterative process: most researchers come back to this step repeatedly, modifying their questions in light of previous research, resource limitations and other considerations.

Researchers face limits in terms of time and money. They, like everyone else, have to pose research questions that they can plausibly answer given the constraints they face. For example, it would be inadvisable to frame a project around the question ‘What are the roots of the Arab-Israeli conflict?’ if you have only a week to develop an answer and no background on that topic. That’s not to limit your imagination: you can come up with any question you’d like. But it typically does require some creativity to frame a question that you can answer well – that is, by investigating thoroughly and providing new insights – within the limits you face.

In addition to being interesting to you, and feasible within your resource constraints, the third and most important characteristic of a ‘good’ research topic is whether it allows you to create new knowledge. It might turn out that your question has already been asked and answered to your satisfaction: if so, you’ll find out in the next step of this process. On the other hand, you might come up with a research question that hasn’t been addressed previously. Before you get too excited about breaking uncharted ground, consider this: a lot of potentially researchable questions haven’t been studied for good reason ; they might have answers that are trivial or of very limited interest. This could include questions such as ‘Why does the area of a circle equal π r²?’ or ‘Did winter conditions affect Napoleon’s plans to invade Russia?’ Of course, you might be able to make the argument that a seemingly trivial question is actually vitally important, but you must be prepared to back that up with convincing evidence. The exercise in the ‘Learn More’ section below will help you think through some of these issues.

Finally, scholarly research questions must in some way lead to new and distinctive insights. For example, lots of people have studied gender roles in sports teams; what can you ask that hasn’t been asked before? Reinventing the wheel is the number-one no-no in this endeavour. That’s why the next step is so important: reviewing previous research on your topic. Depending on what you find in that step, you might need to revise your research question; iterating between your question and the existing literature is a normal process. But don’t worry: it doesn’t go on forever. In fact, the iterations taper off – and your research question stabilises – as you develop a firm grasp of the current state of knowledge on your topic.

Step 3: Review previous research

In academic research, from articles to books, it’s common to find a section called a ‘literature review’. The purpose of that section is to describe the state of the art in knowledge on the research question that a project has posed. It demonstrates that researchers have thoroughly and systematically reviewed the relevant findings of previous studies on their topic, and that they have something novel to contribute.

Your own research project should include something like this, even if it’s a high-school term paper. In the research planning process, you’ll want to list at least half a dozen bullet points stating the major findings on your topic by other people. In relation to those findings, you should be able to specify where your project could provide new and necessary insights. There are two basic rhetorical positions one can take in framing the novelty-plus-importance argument required of academic research:

Position 1 requires you to build on or extend a set of existing ideas; that means saying something like: ‘Person A has argued that X is true about gender; this implies Y, which has not yet been tested. My project will test Y, and if I find evidence to support it, that will change the way we understand gender.’
Position 2 is to argue that there is a gap in existing knowledge, either because previous research has reached conflicting conclusions or has failed to consider something important. For example, one could say that research on middle schoolers and gender has been limited by being conducted primarily in coeducational environments, and that findings might differ dramatically if research were conducted in more schools where the student body was all-male or all-female.

Your overall goal in this step of the process is to show that your research will be part of a larger conversation: that is, how your project flows from what’s already known, and how it advances, extends or challenges that existing body of knowledge. That will be the contribution of your project, and it constitutes the motivation for your research.

Two things are worth mentioning about your search for sources of relevant previous research. First, you needn’t look only at studies on your precise topic. For example, if you want to study gender-identity formation in schools, you shouldn’t restrict yourself to studies of schools; the empirical setting (schools) is secondary to the larger social process that interests you (how people form gender identity). That process occurs in many different settings, so cast a wide net. Second, be sure to use legitimate sources – meaning publications that have been through some sort of vetting process, whether that involves peer review (as with academic journal articles you might find via Google Scholar) or editorial review (as you’d find in well-known mass media publications, such as The Economist or The Washington Post ). What you’ll want to avoid is using unvetted sources such as personal blogs or Wikipedia. Why? Because anybody can write anything in those forums, and there is no way to know – unless you’re already an expert – if the claims you find there are accurate. Often, they’re not.

Step 4: Choose your data and methods

Whatever your research question is, eventually you’ll need to consider which data source and analytical strategy are most likely to provide the answers you’re seeking. One starting point is to consider whether your question would be best addressed by qualitative data (such as interviews, observations or historical records), quantitative data (such as surveys or census records) or some combination of both. Your ideas about data sources will, in turn, suggest options for analytical methods.

You might need to collect your own data, or you might find everything you need readily available in an existing dataset someone else has created. A great place to start is with a research librarian: university libraries always have them and, at public universities, those librarians can work with the public, including people who aren’t affiliated with the university. If you don’t happen to have a public university and its library close at hand, an ordinary public library can still be a good place to start: the librarians are often well versed in accessing data sources that might be relevant to your study, such as the census, or historical archives, or the Survey of Consumer Finances.

Because your task at this point is to plan research, rather than conduct it, the purpose of this step is not to commit you irrevocably to a course of action. Instead, your goal here is to think through a feasible approach to answering your research question. You’ll need to find out, for example, whether the data you want exist; if not, do you have a realistic chance of gathering the data yourself, or would it be better to modify your research question? In terms of analysis, would your strategy require you to apply statistical methods? If so, do you have those skills? If not, do you have time to learn them, or money to hire a research assistant to run the analysis for you?

Please be aware that qualitative methods in particular are not the casual undertaking they might appear to be. Many people make the mistake of thinking that only quantitative data and methods are scientific and systematic, while qualitative methods are just a fancy way of saying: ‘I talked to some people, read some old newspapers, and drew my own conclusions.’ Nothing could be further from the truth. In the final section of this guide, you’ll find some links to resources that will provide more insight on standards and procedures governing qualitative research, but suffice it to say: there are rules about what constitutes legitimate evidence and valid analytical procedure for qualitative data, just as there are for quantitative data.

Circle back and consider revising your initial plans

As you work through these four steps in planning your project, it’s perfectly normal to circle back and revise. Research planning is rarely a linear process. It’s also common for new and unexpected avenues to suggest themselves. As the sociologist Thorstein Veblen wrote in 1908 : ‘The outcome of any serious research can only be to make two questions grow where only one grew before.’ That’s as true of research planning as it is of a completed project. Try to enjoy the horizons that open up for you in this process, rather than becoming overwhelmed; the four steps, along with the two exercises that follow, will help you focus your plan and make it manageable.

Key points – How to plan a research project

Planning a research project is essential no matter your academic level or field of study. There is no one ‘best’ way to design research, but there are certain guidelines that can be helpfully applied across disciplines.
Orient yourself to knowledge-creation. Make the shift from being a consumer of information to being a producer of information.
Define your research question. Your question frames the rest of your project, sets the scope, and determines the kinds of answers you can find.
Review previous research on your question. Survey the existing body of relevant knowledge to ensure that your research will be part of a larger conversation.
Choose your data and methods. For instance, will you be collecting qualitative data, via interviews, or numerical data, via surveys?
Circle back and consider revising your initial plans. Expect your research question in particular to undergo multiple rounds of refinement as you learn more about your topic.

Good research questions tend to beget more questions. This can be frustrating for those who want to get down to business right away. Try to make room for the unexpected: this is usually how knowledge advances. Many of the most significant discoveries in human history have been made by people who were looking for something else entirely. There are ways to structure your research planning process without over-constraining yourself; the two exercises below are a start, and you can find further methods in the Links and Books section.

The following exercise provides a structured process for advancing your research project planning. After completing it, you’ll be able to do the following:

describe clearly and concisely the question you’ve chosen to study
summarise the state of the art in knowledge about the question, and where your project could contribute new insight
identify the best strategy for gathering and analysing relevant data

In other words, the following provides a systematic means to establish the building blocks of your research project.

Exercise 1: Definition of research question and sources

This exercise prompts you to select and clarify your general interest area, develop a research question, and investigate sources of information. The annotated bibliography will also help you refine your research question so that you can begin the second assignment, a description of the phenomenon you wish to study.

Jot down a few bullet points in response to these two questions, with the understanding that you’ll probably go back and modify your answers as you begin reading other studies relevant to your topic:

What will be the general topic of your paper?
What will be the specific topic of your paper?

b) Research question(s)

Use the following guidelines to frame a research question – or questions – that will drive your analysis. As with Part 1 above, you’ll probably find it necessary to change or refine your research question(s) as you complete future assignments.

Your question should be phrased so that it can’t be answered with a simple ‘yes’ or ‘no’.
Your question should have more than one plausible answer.
Your question should draw relationships between two or more concepts; framing the question in terms of How? or What? often works better than asking Why ?

c) Annotated bibliography

Most or all of your background information should come from two sources: scholarly books and journals, or reputable mass media sources. You might be able to access journal articles electronically through your library, using search engines such as JSTOR and Google Scholar. This can save you a great deal of time compared with going to the library in person to search periodicals. General news sources, such as those accessible through LexisNexis, are acceptable, but should be cited sparingly, since they don’t carry the same level of credibility as scholarly sources. As discussed above, unvetted sources such as blogs and Wikipedia should be avoided, because the quality of the information they provide is unreliable and often misleading.

To create an annotated bibliography, provide the following information for at least 10 sources relevant to your specific topic, using the format suggested below.

Name of author(s):

Publication date:

Title of book, chapter, or article:

If a chapter or article, title of journal or book where they appear:

Brief description of this work, including main findings and methods ( c 75 words):

Summary of how this work contributes to your project ( c 75 words):

Brief description of the implications of this work ( c 25 words):

Identify any gap or controversy in knowledge this work points up, and how your project could address those problems ( c 50 words):

Exercise 2: Towards an analysis

Develop a short statement ( c 250 words) about the kind of data that would be useful to address your research question, and how you’d analyse it. Some questions to consider in writing this statement include:

What are the central concepts or variables in your project? Offer a brief definition of each.
Do any data sources exist on those concepts or variables, or would you need to collect data?
Of the analytical strategies you could apply to that data, which would be the most appropriate to answer your question? Which would be the most feasible for you? Consider at least two methods, noting their advantages or disadvantages for your project.

Links & books

One of the best texts ever written about planning and executing research comes from a source that might be unexpected: a 60-year-old work on urban planning by a self-trained scholar. The classic book The Death and Life of Great American Cities (1961) by Jane Jacobs (available complete and free of charge via this link ) is worth reading in its entirety just for the pleasure of it. But the final 20 pages – a concluding chapter titled ‘The Kind of Problem a City Is’ – are really about the process of thinking through and investigating a problem. Highly recommended as a window into the craft of research.

Jacobs’s text references an essay on advancing human knowledge by the mathematician Warren Weaver. At the time, Weaver was director of the Rockefeller Foundation, in charge of funding basic research in the natural and medical sciences. Although the essay is titled ‘A Quarter Century in the Natural Sciences’ (1960) and appears at first blush to be merely a summation of one man’s career, it turns out to be something much bigger and more interesting: a meditation on the history of human beings seeking answers to big questions about the world. Weaver goes back to the 17th century to trace the origins of systematic research thinking, with enthusiasm and vivid anecdotes that make the process come alive. The essay is worth reading in its entirety, and is available free of charge via this link .

For those seeking a more in-depth, professional-level discussion of the logic of research design, the political scientist Harvey Starr provides insight in a compact format in the article ‘Cumulation from Proper Specification: Theory, Logic, Research Design, and “Nice” Laws’ (2005). Starr reviews the ‘research triad’, consisting of the interlinked considerations of formulating a question, selecting relevant theories and applying appropriate methods. The full text of the article, published in the scholarly journal Conflict Management and Peace Science , is available, free of charge, via this link .

Finally, the book Getting What You Came For (1992) by Robert Peters is not only an outstanding guide for anyone contemplating graduate school – from the application process onward – but it also includes several excellent chapters on planning and executing research, applicable across a wide variety of subject areas. It was an invaluable resource for me 25 years ago, and it remains in print with good reason; I recommend it to all my students, particularly Chapter 16 (‘The Thesis Topic: Finding It’), Chapter 17 (‘The Thesis Proposal’) and Chapter 18 (‘The Thesis: Writing It’).

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The 5 Steps of the Research Process | Helpfull

Knowing how each of the 5 phases of the research process work in tandem helps keep your project on track.

What is the Research Process?

The research process outlines the key steps taken in order to complete a thorough and procedurally sound research project. Knowing how each of the 5 phases of the research process work in tandem helps keep the project on track.

The first step of the research process identifies the problem or topic that is going to be studied. From there, the proceeding steps take the researcher through various models and methodologies designed to bring about quality, valid data.

The 5 Steps of the Research Process

The research process can be broken down into 5 simple and clearly defined stages. Understanding how these steps flow will enable you to generate stronger results; make sure to review them before you develop your methodology. It will save you a lot of time and frustration down the line.

Defining the Problem

This is where you state the issue. In the form of a hypothesis, researchers make a judgement about the world around them; trying to either improve an existing condition, streamline a process, or probe a question for deeper thought.

A good research problem should seek to find answers for a clear and specific issue. Issues like:

“Do our customers have difficulty purchasing our product from our website?” or

“Will changing our brand logo design improve customer favorability?”

The more issues one question seeks to address, the less likely you are to collect quality research data.

Remember to keep your problem specific and concise. You can always run more tests if you need to address multiple research questions. This keeps your data organized, and is the best practice for ensuring the integrity of your results.

Designing your Research Project

The next step in your research process is to develop a framework. This can involve creating a research plan, or developing a step-by-step methodology for how you plan to approach your research. These outlines will frame your work as you progress through the actual testing process; ensuring you’re getting all of the critical information you need to properly develop your data.

Generally, designing a research project involves completing many of these objective-driven activities:

Researching primary and secondary sources
Defining the scope of your research project
Selecting the right tools and applications for conducting and analyzing research
Designing surveys and questionnaires
Choose a target audience for your research
Plan for data analysis
Create a research deadline

Once your research project has been clearly defined and your audience has been selected, you’re ready to begin testing.

Collecting the Data

This is where your research study officially begins. The data collection process is a crucial step in providing the information you need to address your research question. It begins with defining the concepts that will be researched; what happens next are the research collection steps you outlined in the previous step. Oftentimes, researchers will invite participants to engage in their tests. These tests can be something as simple as a survey, or require activities as lengthy and complex as a one-on-one interview, or a user experience test.

Researchers will sometimes choose to passively observe a case, instead of actively involving themselves in a phenomenon. This type of observational study is useful in cases where researchers are resource-limited, or want to learn more about events that have happened in the past.

Remember to stick to the processes you’ve outlined in step 2, and you’re well on your way to success.

Data collection method in Research Process

Data analysis begins when all results have been collected and the testing process is complete. This can often be the most lengthy and labor-intensive part of the research process. It requires careful thought and attention be paid to following the data analysis plan developed in step 2; as well as making accommodations to the plan where necessary.

After the data set has been properly reviewed, researchers measure their results against previous experiments and data sets - trying to establish a statistical significance.

Data Visualization and Reporting

The final and perhaps most vital part of your research process involves taking your data and making it accessible to non-researchers. For the most part, you should have already synthesized your data into an answer that either rejects or supports your initial hypothesis. This conclusion can take the form of a blanket generalization, a new formula, or a recommendation for actions to take.

The way you choose to report your findings can have a tremendous impact on how your results are received. Scientific reports are often published in formal science journals as peer-reviewed studies; whereas business research may be reported in a video or presentation format. Whenever you encounter a snag in your research process, remember to: plan ahead, get advice from your fellow researchers, and stick to your research plan.

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J Pharmacol Pharmacother
v.4(2); Apr-Jun 2013

The critical steps for successful research: The research proposal and scientific writing: (A report on the pre-conference workshop held in conjunction with the 64 th annual conference of the Indian Pharmaceutical Congress-2012)

Pitchai balakumar.

Pharmacology Unit, Faculty of Pharmacy, AIMST University, Semeling, 08100 Bedong. Kedah Darul Aman, Malaysia

Mohammed Naseeruddin Inamdar

1 Department of Pharmacology, Al-Ameen College of Pharmacy, Bengaluru, Karnataka, India

Gowraganahalli Jagadeesh

2 Division of Cardiovascular and Renal Products, Center for Drug Evaluation and Research, US Food and Drug Administration, Silver Spring, USA

An interactive workshop on ‘The Critical Steps for Successful Research: The Research Proposal and Scientific Writing’ was conducted in conjunction with the 64 th Annual Conference of the Indian Pharmaceutical Congress-2012 at Chennai, India. In essence, research is performed to enlighten our understanding of a contemporary issue relevant to the needs of society. To accomplish this, a researcher begins search for a novel topic based on purpose, creativity, critical thinking, and logic. This leads to the fundamental pieces of the research endeavor: Question, objective, hypothesis, experimental tools to test the hypothesis, methodology, and data analysis. When correctly performed, research should produce new knowledge. The four cornerstones of good research are the well-formulated protocol or proposal that is well executed, analyzed, discussed and concluded. This recent workshop educated researchers in the critical steps involved in the development of a scientific idea to its successful execution and eventual publication.

INTRODUCTION

Creativity and critical thinking are of particular importance in scientific research. Basically, research is original investigation undertaken to gain knowledge and understand concepts in major subject areas of specialization, and includes the generation of ideas and information leading to new or substantially improved scientific insights with relevance to the needs of society. Hence, the primary objective of research is to produce new knowledge. Research is both theoretical and empirical. It is theoretical because the starting point of scientific research is the conceptualization of a research topic and development of a research question and hypothesis. Research is empirical (practical) because all of the planned studies involve a series of observations, measurements, and analyses of data that are all based on proper experimental design.[ 1 – 9 ]

The subject of this report is to inform readers of the proceedings from a recent workshop organized by the 64 th Annual conference of the ‘ Indian Pharmaceutical Congress ’ at SRM University, Chennai, India, from 05 to 06 December 2012. The objectives of the workshop titled ‘The Critical Steps for Successful Research: The Research Proposal and Scientific Writing,’ were to assist participants in developing a strong fundamental understanding of how best to develop a research or study protocol, and communicate those research findings in a conference setting or scientific journal. Completing any research project requires meticulous planning, experimental design and execution, and compilation and publication of findings in the form of a research paper. All of these are often unfamiliar to naïve researchers; thus, the purpose of this workshop was to teach participants to master the critical steps involved in the development of an idea to its execution and eventual publication of the results (See the last section for a list of learning objectives).

THE STRUCTURE OF THE WORKSHOP

The two-day workshop was formatted to include key lectures and interactive breakout sessions that focused on protocol development in six subject areas of the pharmaceutical sciences. This was followed by sessions on scientific writing. DAY 1 taught the basic concepts of scientific research, including: (1) how to formulate a topic for research and to describe the what, why , and how of the protocol, (2) biomedical literature search and review, (3) study designs, statistical concepts, and result analyses, and (4) publication ethics. DAY 2 educated the attendees on the basic elements and logistics of writing a scientific paper and thesis, and preparation of poster as well as oral presentations.

The final phase of the workshop was the ‘Panel Discussion,’ including ‘Feedback/Comments’ by participants. There were thirteen distinguished speakers from India and abroad. Approximately 120 post-graduate and pre-doctoral students, young faculty members, and scientists representing industries attended the workshop from different parts of the country. All participants received a printed copy of the workshop manual and supporting materials on statistical analyses of data.

THE BASIC CONCEPTS OF RESEARCH: THE KEY TO GETTING STARTED IN RESEARCH

A research project generally comprises four key components: (1) writing a protocol, (2) performing experiments, (3) tabulating and analyzing data, and (4) writing a thesis or manuscript for publication.

Fundamentals in the research process

A protocol, whether experimental or clinical, serves as a navigator that evolves from a basic outline of the study plan to become a qualified research or grant proposal. It provides the structural support for the research. Dr. G. Jagadeesh (US FDA), the first speaker of the session, spoke on ‘ Fundamentals in research process and cornerstones of a research project .’ He discussed at length the developmental and structural processes in preparing a research protocol. A systematic and step-by-step approach is necessary in planning a study. Without a well-designed protocol, there would be a little chance for successful completion of a research project or an experiment.

Research topic

The first and the foremost difficult task in research is to identify a topic for investigation. The research topic is the keystone of the entire scientific enterprise. It begins the project, drives the entire study, and is crucial for moving the project forward. It dictates the remaining elements of the study [ Table 1 ] and thus, it should not be too narrow or too broad or unfocused. Because of these potential pitfalls, it is essential that a good or novel scientific idea be based on a sound concept. Creativity, critical thinking, and logic are required to generate new concepts and ideas in solving a research problem. Creativity involves critical thinking and is associated with generating many ideas. Critical thinking is analytical, judgmental, and involves evaluating choices before making a decision.[ 4 ] Thus, critical thinking is convergent type thinking that narrows and refines those divergent ideas and finally settles to one idea for an in-depth study. The idea on which a research project is built should be novel, appropriate to achieve within the existing conditions, and useful to the society at large. Therefore, creativity and critical thinking assist biomedical scientists in research that results in funding support, novel discovery, and publication.[ 1 , 4 ]

Elements of a study protocol

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Research question

The next most crucial aspect of a study protocol is identifying a research question. It should be a thought-provoking question. The question sets the framework. It emerges from the title, findings/results, and problems observed in previous studies. Thus, mastering the literature, attendance at conferences, and discussion in journal clubs/seminars are sources for developing research questions. Consider the following example in developing related research questions from the research topic.

Hepatoprotective activity of Terminalia arjuna and Apium graveolens on paracetamol-induced liver damage in albino rats.

How is paracetamol metabolized in the body? Does it involve P450 enzymes? How does paracetamol cause liver injury? What are the mechanisms by which drugs can alleviate liver damage? What biochemical parameters are indicative of liver injury? What major endogenous inflammatory molecules are involved in paracetamol-induced liver damage?

A research question is broken down into more precise objectives. The objectives lead to more precise methods and definition of key terms. The objectives should be SMART-Specific, Measurable, Achievable, Realistic, Time-framed,[ 10 ] and should cover the entire breadth of the project. The objectives are sometimes organized into hierarchies: Primary, secondary, and exploratory; or simply general and specific. Study the following example:

To evaluate the safety and tolerability of single oral doses of compound X in normal volunteers.

To assess the pharmacokinetic profile of compound X following single oral doses.

To evaluate the incidence of peripheral edema reported as an adverse event.

The objectives and research questions are then formulated into a workable or testable hypothesis. The latter forces us to think carefully about what comparisons will be needed to answer the research question, and establishes the format for applying statistical tests to interpret the results. The hypothesis should link a process to an existing or postulated biologic pathway. A hypothesis is written in a form that can yield measurable results. Studies that utilize statistics to compare groups of data should have a hypothesis. Consider the following example:

The hepatoprotective activity of Terminalia arjuna is superior to that of Apium graveolens against paracetamol-induced liver damage in albino rats.

All biological research, including discovery science, is hypothesis-driven. However, not all studies need be conducted with a hypothesis. For example, descriptive studies (e.g., describing characteristics of a plant, or a chemical compound) do not need a hypothesis.[ 1 ]

Relevance of the study

Another important section to be included in the protocol is ‘significance of the study.’ Its purpose is to justify the need for the research that is being proposed (e.g., development of a vaccine for a disease). In summary, the proposed study should demonstrate that it represents an advancement in understanding and that the eventual results will be meaningful, contribute to the field, and possibly even impact society.

Biomedical literature

A literature search may be defined as the process of examining published sources of information on a research or review topic, thesis, grant application, chemical, drug, disease, or clinical trial, etc. The quantity of information available in print or electronically (e.g., the internet) is immense and growing with time. A researcher should be familiar with the right kinds of databases and search engines to extract the needed information.[ 3 , 6 ]

Dr. P. Balakumar (Institute of Pharmacy, Rajendra Institute of Technology and Sciences, Sirsa, Haryana; currently, Faculty of Pharmacy, AIMST University, Malaysia) spoke on ‘ Biomedical literature: Searching, reviewing and referencing .’ He schematically explained the basis of scientific literature, designing a literature review, and searching literature. After an introduction to the genesis and diverse sources of scientific literature searches, the use of PubMed, one of the premier databases used for biomedical literature searches world-wide, was illustrated with examples and screenshots. Several companion databases and search engines are also used for finding information related to health sciences, and they include Embase, Web of Science, SciFinder, The Cochrane Library, International Pharmaceutical Abstracts, Scopus, and Google Scholar.[ 3 ] Literature searches using alternative interfaces for PubMed such as GoPubMed, Quertle, PubFocus, Pubget, and BibliMed were discussed. The participants were additionally informed of databases on chemistry, drugs and drug targets, clinical trials, toxicology, and laboratory animals (reviewed in ref[ 3 ]).

Referencing and bibliography are essential in scientific writing and publication.[ 7 ] Referencing systems are broadly classified into two major types, such as Parenthetical and Notation systems. Parenthetical referencing is also known as Harvard style of referencing, while Vancouver referencing style and ‘Footnote’ or ‘Endnote’ are placed under Notation referencing systems. The participants were educated on each referencing system with examples.

Bibliography management

Dr. Raj Rajasekaran (University of California at San Diego, CA, USA) enlightened the audience on ‘ bibliography management ’ using reference management software programs such as Reference Manager ® , Endnote ® , and Zotero ® for creating and formatting bibliographies while writing a manuscript for publication. The discussion focused on the use of bibliography management software in avoiding common mistakes such as incomplete references. Important steps in bibliography management, such as creating reference libraries/databases, searching for references using PubMed/Google scholar, selecting and transferring selected references into a library, inserting citations into a research article and formatting bibliographies, were presented. A demonstration of Zotero®, a freely available reference management program, included the salient features of the software, adding references from PubMed using PubMed ID, inserting citations and formatting using different styles.

Writing experimental protocols

The workshop systematically instructed the participants in writing ‘ experimental protocols ’ in six disciplines of Pharmaceutical Sciences.: (1) Pharmaceutical Chemistry (presented by Dr. P. V. Bharatam, NIPER, Mohali, Punjab); (2) Pharmacology (presented by Dr. G. Jagadeesh and Dr. P. Balakumar); (3) Pharmaceutics (presented by Dr. Jayant Khandare, Piramal Life Sciences, Mumbai); (4) Pharmacy Practice (presented by Dr. Shobha Hiremath, Al-Ameen College of Pharmacy, Bengaluru); (5) Pharmacognosy and Phytochemistry (presented by Dr. Salma Khanam, Al-Ameen College of Pharmacy, Bengaluru); and (6) Pharmaceutical Analysis (presented by Dr. Saranjit Singh, NIPER, Mohali, Punjab). The purpose of the research plan is to describe the what (Specific Aims/Objectives), why (Background and Significance), and how (Design and Methods) of the proposal.

The research plan should answer the following questions: (a) what do you intend to do; (b) what has already been done in general, and what have other researchers done in the field; (c) why is this worth doing; (d) how is it innovative; (e) what will this new work add to existing knowledge; and (f) how will the research be accomplished?

In general, the format used by the faculty in all subjects is shown in Table 2 .

Elements of a research protocol

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Biostatistics

Biostatistics is a key component of biomedical research. Highly reputed journals like The Lancet, BMJ, Journal of the American Medical Association, and many other biomedical journals include biostatisticians on their editorial board or reviewers list. This indicates that a great importance is given for learning and correctly employing appropriate statistical methods in biomedical research. The post-lunch session on day 1 of the workshop was largely committed to discussion on ‘ Basic biostatistics .’ Dr. R. Raveendran (JIPMER, Puducherry) and Dr. Avijit Hazra (PGIMER, Kolkata) reviewed, in parallel sessions, descriptive statistics, probability concepts, sample size calculation, choosing a statistical test, confidence intervals, hypothesis testing and ‘ P ’ values, parametric and non-parametric statistical tests, including analysis of variance (ANOVA), t tests, Chi-square test, type I and type II errors, correlation and regression, and summary statistics. This was followed by a practice and demonstration session. Statistics CD, compiled by Dr. Raveendran, was distributed to the participants before the session began and was demonstrated live. Both speakers worked on a variety of problems that involved both clinical and experimental data. They discussed through examples the experimental designs encountered in a variety of studies and statistical analyses performed for different types of data. For the benefit of readers, we have summarized statistical tests applied frequently for different experimental designs and post-hoc tests [ Figure 1 ].

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Conceptual framework for statistical analyses of data. Of the two kinds of variables, qualitative (categorical) and quantitative (numerical), qualitative variables (nominal or ordinal) are not normally distributed. Numerical data that come from normal distributions are analyzed using parametric tests, if not; the data are analyzed using non-parametric tests. The most popularly used Student's t -test compares the means of two populations, data for this test could be paired or unpaired. One-way analysis of variance (ANOVA) is used to compare the means of three or more independent populations that are normally distributed. Applying t test repeatedly in pair (multiple comparison), to compare the means of more than two populations, will increase the probability of type I error (false positive). In this case, for proper interpretation, we need to adjust the P values. Repeated measures ANOVA is used to compare the population means if more than two observations coming from same subject over time. The null hypothesis is rejected with a ‘ P ’ value of less than 0.05, and the difference in population means is considered to be statistically significant. Subsequently, appropriate post-hoc tests are used for pairwise comparisons of population means. Two-way or three-way ANOVA are considered if two (diet, dose) or three (diet, dose, strain) independent factors, respectively, are analyzed in an experiment (not described in the Figure). Categorical nominal unmatched variables (counts or frequencies) are analyzed by Chi-square test (not shown in the Figure)

Research and publication ethics

The legitimate pursuit of scientific creativity is unfortunately being marred by a simultaneous increase in scientific misconduct. A disproportionate share of allegations involves scientists of many countries, and even from respected laboratories. Misconduct destroys faith in science and scientists and creates a hierarchy of fraudsters. Investigating misconduct also steals valuable time and resources. In spite of these facts, most researchers are not aware of publication ethics.

Day 1 of the workshop ended with a presentation on ‘ research and publication ethics ’ by Dr. M. K. Unnikrishnan (College of Pharmaceutical Sciences, Manipal University, Manipal). He spoke on the essentials of publication ethics that included plagiarism (attempting to take credit of the work of others), self-plagiarism (multiple publications by an author on the same content of work with slightly different wordings), falsification (manipulation of research data and processes and omitting critical data or results), gift authorship (guest authorship), ghostwriting (someone other than the named author (s) makes a major contribution), salami publishing (publishing many papers, with minor differences, from the same study), and sabotage (distracting the research works of others to halt their research completion). Additionally, Dr. Unnikrishnan pointed out the ‘ Ingelfinger rule ’ of stipulating that a scientist must not submit the same original research in two different journals. He also advised the audience that authorship is not just credit for the work but also responsibility for scientific contents of a paper. Although some Indian Universities are instituting preventive measures (e.g., use of plagiarism detecting software, Shodhganga digital archiving of doctoral theses), Dr. Unnikrishnan argued for a great need to sensitize young researchers on the nature and implications of scientific misconduct. Finally, he discussed methods on how editors and peer reviewers should ethically conduct themselves while managing a manuscript for publication.

SCIENTIFIC COMMUNICATION: THE KEY TO SUCCESSFUL SELLING OF FINDINGS

Research outcomes are measured through quality publications. Scientists must not only ‘do’ science but must ‘write’ science. The story of the project must be told in a clear, simple language weaving in previous work done in the field, answering the research question, and addressing the hypothesis set forth at the beginning of the study. Scientific publication is an organic process of planning, researching, drafting, revising, and updating the current knowledge for future perspectives. Writing a research paper is no easier than the research itself. The lectures of Day 2 of the workshop dealt with the basic elements and logistics of writing a scientific paper.

An overview of paper structure and thesis writing

Dr. Amitabh Prakash (Adis, Auckland, New Zealand) spoke on ‘ Learning how to write a good scientific paper .’ His presentation described the essential components of an original research paper and thesis (e.g., introduction, methods, results, and discussion [IMRaD]) and provided guidance on the correct order, in which data should appear within these sections. The characteristics of a good abstract and title and the creation of appropriate key words were discussed. Dr. Prakash suggested that the ‘title of a paper’ might perhaps have a chance to make a good impression, and the title might be either indicative (title that gives the purpose of the study) or declarative (title that gives the study conclusion). He also suggested that an abstract is a succinct summary of a research paper, and it should be specific, clear, and concise, and should have IMRaD structure in brief, followed by key words. Selection of appropriate papers to be cited in the reference list was also discussed. Various unethical authorships were enumerated, and ‘The International Committee of Medical Journal Editors (ICMJE) criteria for authorship’ was explained ( http://www.icmje.org/ethical_1author.html ; also see Table 1 in reference #9). The session highlighted the need for transparency in medical publication and provided a clear description of items that needed to be included in the ‘Disclosures’ section (e.g., sources of funding for the study and potential conflicts of interest of all authors, etc.) and ‘Acknowledgements’ section (e.g., writing assistance and input from all individuals who did not meet the authorship criteria). The final part of the presentation was devoted to thesis writing, and Dr. Prakash provided the audience with a list of common mistakes that are frequently encountered when writing a manuscript.

The backbone of a study is description of results through Text, Tables, and Figures. Dr. S. B. Deshpande (Institute of Medical Sciences, Banaras Hindu University, Varanasi, India) spoke on ‘ Effective Presentation of Results .’ The Results section deals with the observations made by the authors and thus, is not hypothetical. This section is subdivided into three segments, that is, descriptive form of the Text, providing numerical data in Tables, and visualizing the observations in Graphs or Figures. All these are arranged in a sequential order to address the question hypothesized in the Introduction. The description in Text provides clear content of the findings highlighting the observations. It should not be the repetition of facts in tables or graphs. Tables are used to summarize or emphasize descriptive content in the text or to present the numerical data that are unrelated. Illustrations should be used when the evidence bearing on the conclusions of a paper cannot be adequately presented in a written description or in a Table. Tables or Figures should relate to each other logically in sequence and should be clear by themselves. Furthermore, the discussion is based entirely on these observations. Additionally, how the results are applied to further research in the field to advance our understanding of research questions was discussed.

Dr. Peush Sahni (All-India Institute of Medical Sciences, New Delhi) spoke on effectively ‘ structuring the Discussion ’ for a research paper. The Discussion section deals with a systematic interpretation of study results within the available knowledge. He said the section should begin with the most important point relating to the subject studied, focusing on key issues, providing link sentences between paragraphs, and ensuring the flow of text. Points were made to avoid history, not repeat all the results, and provide limitations of the study. The strengths and novel findings of the study should be provided in the discussion, and it should open avenues for future research and new questions. The Discussion section should end with a conclusion stating the summary of key findings. Dr. Sahni gave an example from a published paper for writing a Discussion. In another presentation titled ‘ Writing an effective title and the abstract ,’ Dr. Sahni described the important components of a good title, such as, it should be simple, concise, informative, interesting and eye-catching, accurate and specific about the paper's content, and should state the subject in full indicating study design and animal species. Dr. Sahni explained structured (IMRaD) and unstructured abstracts and discussed a few selected examples with the audience.

Language and style in publication

The next lecture of Dr. Amitabh Prakash on ‘ Language and style in scientific writing: Importance of terseness, shortness and clarity in writing ’ focused on the actual sentence construction, language, grammar and punctuation in scientific manuscripts. His presentation emphasized the importance of brevity and clarity in the writing of manuscripts describing biomedical research. Starting with a guide to the appropriate construction of sentences and paragraphs, attendees were given a brief overview of the correct use of punctuation with interactive examples. Dr. Prakash discussed common errors in grammar and proactively sought audience participation in correcting some examples. Additional discussion was centered on discouraging the use of redundant and expendable words, jargon, and the use of adjectives with incomparable words. The session ended with a discussion of words and phrases that are commonly misused (e.g., data vs . datum, affect vs . effect, among vs . between, dose vs . dosage, and efficacy/efficacious vs . effective/effectiveness) in biomedical research manuscripts.

Working with journals

The appropriateness in selecting the journal for submission and acceptance of the manuscript should be determined by the experience of an author. The corresponding author must have a rationale in choosing the appropriate journal, and this depends upon the scope of the study and the quality of work performed. Dr. Amitabh Prakash spoke on ‘ Working with journals: Selecting a journal, cover letter, peer review process and impact factor ’ by instructing the audience in assessing the true value of a journal, understanding principles involved in the peer review processes, providing tips on making an initial approach to the editorial office, and drafting an appropriate cover letter to accompany the submission. His presentation defined the metrics that are most commonly used to measure journal quality (e.g., impact factor™, Eigenfactor™ score, Article Influence™ score, SCOPUS 2-year citation data, SCImago Journal Rank, h-Index, etc.) and guided attendees on the relative advantages and disadvantages of using each metric. Factors to consider when assessing journal quality were discussed, and the audience was educated on the ‘green’ and ‘gold’ open access publication models. Various peer review models (e.g., double-blind, single-blind, non-blind) were described together with the role of the journal editor in assessing manuscripts and selecting suitable reviewers. A typical checklist sent to referees was shared with the attendees, and clear guidance was provided on the best way to address referee feedback. The session concluded with a discussion of the potential drawbacks of the current peer review system.

Poster and oral presentations at conferences

Posters have become an increasingly popular mode of presentation at conferences, as it can accommodate more papers per meeting, has no time constraint, provides a better presenter-audience interaction, and allows one to select and attend papers of interest. In Figure 2 , we provide instructions, design, and layout in preparing a scientific poster. In the final presentation, Dr. Sahni provided the audience with step-by-step instructions on how to write and format posters for layout, content, font size, color, and graphics. Attendees were given specific guidance on the format of text on slides, the use of color, font type and size, and the use of illustrations and multimedia effects. Moreover, the importance of practical tips while delivering oral or poster presentation was provided to the audience, such as speak slowly and clearly, be informative, maintain eye contact, and listen to the questions from judges/audience carefully before coming up with an answer.

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Guidelines and design to scientific poster presentation. The objective of scientific posters is to present laboratory work in scientific meetings. A poster is an excellent means of communicating scientific work, because it is a graphic representation of data. Posters should have focus points, and the intended message should be clearly conveyed through simple sections: Text, Tables, and Graphs. Posters should be clear, succinct, striking, and eye-catching. Colors should be used only where necessary. Use one font (Arial or Times New Roman) throughout. Fancy fonts should be avoided. All headings should have font size of 44, and be in bold capital letters. Size of Title may be a bit larger; subheading: Font size of 36, bold and caps. References and Acknowledgments, if any, should have font size of 24. Text should have font size between 24 and 30, in order to be legible from a distance of 3 to 6 feet. Do not use lengthy notes

PANEL DISCUSSION: FEEDBACK AND COMMENTS BY PARTICIPANTS

After all the presentations were made, Dr. Jagadeesh began a panel discussion that included all speakers. The discussion was aimed at what we do currently and could do in the future with respect to ‘developing a research question and then writing an effective thesis proposal/protocol followed by publication.’ Dr. Jagadeesh asked the following questions to the panelists, while receiving questions/suggestions from the participants and panelists.

Does a Post-Graduate or Ph.D. student receive adequate training, either through an institutional course, a workshop of the present nature, or from the guide?
Are these Post-Graduates self-taught (like most of us who learnt the hard way)?
How are these guides trained? How do we train them to become more efficient mentors?
Does a Post-Graduate or Ph.D. student struggle to find a method (s) to carry out studies? To what extent do seniors/guides help a post graduate overcome technical difficulties? How difficult is it for a student to find chemicals, reagents, instruments, and technical help in conducting studies?
Analyses of data and interpretation: Most students struggle without adequate guidance.
Thesis and publications frequently feature inadequate/incorrect statistical analyses and representation of data in tables/graphs. The student, their guide, and the reviewers all share equal responsibility.
Who initiates and drafts the research paper? The Post-Graduate or their guide?
What kind of assistance does a Post-Graduate get from the guide in finalizing a paper for publication?
Does the guide insist that each Post-Graduate thesis yield at least one paper, and each Ph.D. thesis more than two papers, plus a review article?

The panelists and audience expressed a variety of views, but were unable to arrive at a decisive conclusion.

WHAT HAVE THE PARTICIPANTS LEARNED?

At the end of this fast-moving two-day workshop, the participants had opportunities in learning the following topics:

Sequential steps in developing a study protocol, from choosing a research topic to developing research questions and a hypothesis.
Study protocols on different topics in their subject of specialization
Searching and reviewing the literature
Appropriate statistical analyses in biomedical research
Scientific ethics in publication
Writing and understanding the components of a research paper (IMRaD)
Recognizing the value of good title, running title, abstract, key words, etc
Importance of Tables and Figures in the Results section, and their importance in describing findings
Evidence-based Discussion in a research paper
Language and style in writing a paper and expert tips on getting it published
Presentation of research findings at a conference (oral and poster).

Overall, the workshop was deemed very helpful to participants. The participants rated the quality of workshop from “ satisfied ” to “ very satisfied .” A significant number of participants were of the opinion that the time allotted for each presentation was short and thus, be extended from the present two days to four days with adequate time to ask questions. In addition, a ‘hands-on’ session should be introduced for writing a proposal and manuscript. A large number of attendees expressed their desire to attend a similar workshop, if conducted, in the near future.

ACKNOWLEDGMENT

We gratefully express our gratitude to the Organizing Committee, especially Professors K. Chinnasamy, B. G. Shivananda, N. Udupa, Jerad Suresh, Padma Parekh, A. P. Basavarajappa, Mr. S. V. Veerramani, Mr. J. Jayaseelan, and all volunteers of the SRM University. We thank Dr. Thomas Papoian (US FDA) for helpful comments on the manuscript.

The opinions expressed herein are those of Gowraganahalli Jagadeesh and do not necessarily reflect those of the US Food and Drug Administration

Source of Support: Nil

Conflict of Interest: None declared.

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Methodology

What Is a Research Design | Types, Guide & Examples

What Is a Research Design | Types, Guide & Examples

Published on June 7, 2021 by Shona McCombes . Revised on November 20, 2023 by Pritha Bhandari.

A research design is a strategy for answering your research question using empirical data. Creating a research design means making decisions about:

Your overall research objectives and approach
Whether you’ll rely on primary research or secondary research
Your sampling methods or criteria for selecting subjects
Your data collection methods
The procedures you’ll follow to collect data
Your data analysis methods

A well-planned research design helps ensure that your methods match your research objectives and that you use the right kind of analysis for your data.

Step 1: consider your aims and approach, step 2: choose a type of research design, step 3: identify your population and sampling method, step 4: choose your data collection methods, step 5: plan your data collection procedures, step 6: decide on your data analysis strategies, other interesting articles, frequently asked questions about research design.

Introduction

Before you can start designing your research, you should already have a clear idea of the research question you want to investigate.

There are many different ways you could go about answering this question. Your research design choices should be driven by your aims and priorities—start by thinking carefully about what you want to achieve.

The first choice you need to make is whether you’ll take a qualitative or quantitative approach.

Qualitative research designs tend to be more flexible and inductive , allowing you to adjust your approach based on what you find throughout the research process.

Quantitative research designs tend to be more fixed and deductive , with variables and hypotheses clearly defined in advance of data collection.

It’s also possible to use a mixed-methods design that integrates aspects of both approaches. By combining qualitative and quantitative insights, you can gain a more complete picture of the problem you’re studying and strengthen the credibility of your conclusions.

Practical and ethical considerations when designing research

As well as scientific considerations, you need to think practically when designing your research. If your research involves people or animals, you also need to consider research ethics .

How much time do you have to collect data and write up the research?
Will you be able to gain access to the data you need (e.g., by travelling to a specific location or contacting specific people)?
Do you have the necessary research skills (e.g., statistical analysis or interview techniques)?
Will you need ethical approval ?

At each stage of the research design process, make sure that your choices are practically feasible.

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Within both qualitative and quantitative approaches, there are several types of research design to choose from. Each type provides a framework for the overall shape of your research.

Types of quantitative research designs

Quantitative designs can be split into four main types.

Experimental and quasi-experimental designs allow you to test cause-and-effect relationships
Descriptive and correlational designs allow you to measure variables and describe relationships between them.

With descriptive and correlational designs, you can get a clear picture of characteristics, trends and relationships as they exist in the real world. However, you can’t draw conclusions about cause and effect (because correlation doesn’t imply causation ).

Experiments are the strongest way to test cause-and-effect relationships without the risk of other variables influencing the results. However, their controlled conditions may not always reflect how things work in the real world. They’re often also more difficult and expensive to implement.

Types of qualitative research designs

Qualitative designs are less strictly defined. This approach is about gaining a rich, detailed understanding of a specific context or phenomenon, and you can often be more creative and flexible in designing your research.

The table below shows some common types of qualitative design. They often have similar approaches in terms of data collection, but focus on different aspects when analyzing the data.

Your research design should clearly define who or what your research will focus on, and how you’ll go about choosing your participants or subjects.

In research, a population is the entire group that you want to draw conclusions about, while a sample is the smaller group of individuals you’ll actually collect data from.

Defining the population

A population can be made up of anything you want to study—plants, animals, organizations, texts, countries, etc. In the social sciences, it most often refers to a group of people.

For example, will you focus on people from a specific demographic, region or background? Are you interested in people with a certain job or medical condition, or users of a particular product?

The more precisely you define your population, the easier it will be to gather a representative sample.

Sampling methods

Even with a narrowly defined population, it’s rarely possible to collect data from every individual. Instead, you’ll collect data from a sample.

To select a sample, there are two main approaches: probability sampling and non-probability sampling . The sampling method you use affects how confidently you can generalize your results to the population as a whole.

Probability sampling is the most statistically valid option, but it’s often difficult to achieve unless you’re dealing with a very small and accessible population.

For practical reasons, many studies use non-probability sampling, but it’s important to be aware of the limitations and carefully consider potential biases. You should always make an effort to gather a sample that’s as representative as possible of the population.

Case selection in qualitative research

In some types of qualitative designs, sampling may not be relevant.

For example, in an ethnography or a case study , your aim is to deeply understand a specific context, not to generalize to a population. Instead of sampling, you may simply aim to collect as much data as possible about the context you are studying.

In these types of design, you still have to carefully consider your choice of case or community. You should have a clear rationale for why this particular case is suitable for answering your research question .

For example, you might choose a case study that reveals an unusual or neglected aspect of your research problem, or you might choose several very similar or very different cases in order to compare them.

Data collection methods are ways of directly measuring variables and gathering information. They allow you to gain first-hand knowledge and original insights into your research problem.

You can choose just one data collection method, or use several methods in the same study.

Survey methods

Surveys allow you to collect data about opinions, behaviors, experiences, and characteristics by asking people directly. There are two main survey methods to choose from: questionnaires and interviews .

Observation methods

Observational studies allow you to collect data unobtrusively, observing characteristics, behaviors or social interactions without relying on self-reporting.

Observations may be conducted in real time, taking notes as you observe, or you might make audiovisual recordings for later analysis. They can be qualitative or quantitative.

Other methods of data collection

There are many other ways you might collect data depending on your field and topic.

If you’re not sure which methods will work best for your research design, try reading some papers in your field to see what kinds of data collection methods they used.

Secondary data

If you don’t have the time or resources to collect data from the population you’re interested in, you can also choose to use secondary data that other researchers already collected—for example, datasets from government surveys or previous studies on your topic.

With this raw data, you can do your own analysis to answer new research questions that weren’t addressed by the original study.

Using secondary data can expand the scope of your research, as you may be able to access much larger and more varied samples than you could collect yourself.

However, it also means you don’t have any control over which variables to measure or how to measure them, so the conclusions you can draw may be limited.

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As well as deciding on your methods, you need to plan exactly how you’ll use these methods to collect data that’s consistent, accurate, and unbiased.

Planning systematic procedures is especially important in quantitative research, where you need to precisely define your variables and ensure your measurements are high in reliability and validity.

Operationalization

Some variables, like height or age, are easily measured. But often you’ll be dealing with more abstract concepts, like satisfaction, anxiety, or competence. Operationalization means turning these fuzzy ideas into measurable indicators.

If you’re using observations , which events or actions will you count?

If you’re using surveys , which questions will you ask and what range of responses will be offered?

You may also choose to use or adapt existing materials designed to measure the concept you’re interested in—for example, questionnaires or inventories whose reliability and validity has already been established.

Reliability and validity

Reliability means your results can be consistently reproduced, while validity means that you’re actually measuring the concept you’re interested in.

For valid and reliable results, your measurement materials should be thoroughly researched and carefully designed. Plan your procedures to make sure you carry out the same steps in the same way for each participant.

If you’re developing a new questionnaire or other instrument to measure a specific concept, running a pilot study allows you to check its validity and reliability in advance.

Sampling procedures

As well as choosing an appropriate sampling method , you need a concrete plan for how you’ll actually contact and recruit your selected sample.

That means making decisions about things like:

How many participants do you need for an adequate sample size?
What inclusion and exclusion criteria will you use to identify eligible participants?
How will you contact your sample—by mail, online, by phone, or in person?

If you’re using a probability sampling method , it’s important that everyone who is randomly selected actually participates in the study. How will you ensure a high response rate?

If you’re using a non-probability method , how will you avoid research bias and ensure a representative sample?

Data management

It’s also important to create a data management plan for organizing and storing your data.

Will you need to transcribe interviews or perform data entry for observations? You should anonymize and safeguard any sensitive data, and make sure it’s backed up regularly.

Keeping your data well-organized will save time when it comes to analyzing it. It can also help other researchers validate and add to your findings (high replicability ).

On its own, raw data can’t answer your research question. The last step of designing your research is planning how you’ll analyze the data.

Quantitative data analysis

In quantitative research, you’ll most likely use some form of statistical analysis . With statistics, you can summarize your sample data, make estimates, and test hypotheses.

Using descriptive statistics , you can summarize your sample data in terms of:

The distribution of the data (e.g., the frequency of each score on a test)
The central tendency of the data (e.g., the mean to describe the average score)
The variability of the data (e.g., the standard deviation to describe how spread out the scores are)

The specific calculations you can do depend on the level of measurement of your variables.

Using inferential statistics , you can:

Make estimates about the population based on your sample data.
Test hypotheses about a relationship between variables.

Regression and correlation tests look for associations between two or more variables, while comparison tests (such as t tests and ANOVAs ) look for differences in the outcomes of different groups.

Your choice of statistical test depends on various aspects of your research design, including the types of variables you’re dealing with and the distribution of your data.

Qualitative data analysis

In qualitative research, your data will usually be very dense with information and ideas. Instead of summing it up in numbers, you’ll need to comb through the data in detail, interpret its meanings, identify patterns, and extract the parts that are most relevant to your research question.

Two of the most common approaches to doing this are thematic analysis and discourse analysis .

There are many other ways of analyzing qualitative data depending on the aims of your research. To get a sense of potential approaches, try reading some qualitative research papers in your field.

If you want to know more about the research process , methodology , research bias , or statistics , make sure to check out some of our other articles with explanations and examples.

Simple random sampling
Stratified sampling
Cluster sampling
Likert scales
Reproducibility

Statistics

Null hypothesis
Statistical power
Probability distribution
Effect size
Poisson distribution

Research bias

Optimism bias
Cognitive bias
Implicit bias
Hawthorne effect
Anchoring bias
Explicit bias

A research design is a strategy for answering your research question . It defines your overall approach and determines how you will collect and analyze data.

A well-planned research design helps ensure that your methods match your research aims, that you collect high-quality data, and that you use the right kind of analysis to answer your questions, utilizing credible sources . This allows you to draw valid , trustworthy conclusions.

Quantitative research designs can be divided into two main categories:

Correlational and descriptive designs are used to investigate characteristics, averages, trends, and associations between variables.
Experimental and quasi-experimental designs are used to test causal relationships .

Qualitative research designs tend to be more flexible. Common types of qualitative design include case study , ethnography , and grounded theory designs.

The priorities of a research design can vary depending on the field, but you usually have to specify:

Your research questions and/or hypotheses
Your overall approach (e.g., qualitative or quantitative )
The type of design you’re using (e.g., a survey , experiment , or case study )
Your data collection methods (e.g., questionnaires , observations)
Your data collection procedures (e.g., operationalization , timing and data management)
Your data analysis methods (e.g., statistical tests or thematic analysis )

A sample is a subset of individuals from a larger population . Sampling means selecting the group that you will actually collect data from in your research. For example, if you are researching the opinions of students in your university, you could survey a sample of 100 students.

In statistics, sampling allows you to test a hypothesis about the characteristics of a population.

Operationalization means turning abstract conceptual ideas into measurable observations.

For example, the concept of social anxiety isn’t directly observable, but it can be operationally defined in terms of self-rating scores, behavioral avoidance of crowded places, or physical anxiety symptoms in social situations.

Before collecting data , it’s important to consider how you will operationalize the variables that you want to measure.

A research project is an academic, scientific, or professional undertaking to answer a research question . Research projects can take many forms, such as qualitative or quantitative , descriptive , longitudinal , experimental , or correlational . What kind of research approach you choose will depend on your topic.

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Stages of a Research Project

A research project will progress through many stages from its conception through publishing the results. Below is a mostly ordered list of the stages of an experimental research project in our laboratory. Sometimes these stages will be done in a different orde r, o r they may repeat, or they may blend into one another. Different fields of physics and different types of research (i.e., computational or theoretical) will likely have a different order or different stages . If you are part of our research group, you can use the outline below to evaluate and plan your projects.

Conception/inspiration
Development/feasibility study
Literature review
Simulations
Experimental design : Outline both the measurements to be done and the equipment that is necessary to do them.
Experimental setup, calibration, tests, troubleshooting : Construct and arrange the experimental equipment to do the planned measurements. This can take the majority of the time spent on an experiment.
Preliminary steps
Preliminary experimental measurements : Figure out how to do the measurements. This may require going back to steps 3 and 4 a few times.
Preliminary data analysis : Figure out how to analyze the raw data. This may require going back to steps 3 and 4 a few times.
Preliminary writing, essay-style : Start writing the paper because "writing is thinking". This is a first attempt at explaining the experiment and results. Use it to see what is missing, what additional data to take, and what additional analyses to do. This should continue throughout the rest of the project.
Pipeline development : This is an outgrowth of the preliminary steps above.
Experimental pipeline development : We often need to take all our data from one quantum dot (QD), and a given QD can't be easily re-found if the sample is changed. The experimental pipeline is an efficient method to collect all the data in a short amount of time. It takes time and effort to develop the procedures and programs to enable that.
Raw data analysis pipeline development : To ensure the data being collected is valid, it needs to be analyzed immediately so a human can evaluate it for validity. The analysis pipeline is code that raw data can be put through immediately after collection, and which produces plots and figures that enable human evaluation. Similar to the experimental pipeline, it takes time and effort to develop the analysis method and code for this task.
Experimental measurements directly into raw data analysis pipeline : This is when the data that will be used in the final analysis is recorded. This setup can take very little time if the experimental and analysis pipelines are well functioning. If the pipelines are not well functioning, then this step might be performed incorrectly and need to be repeated after redevelopment of the pipelines.
Analysis of processed data : If the preliminary writing and data analysis were done well, then this step can be straightforward. If it is not straightforward, then we may need to return to the preliminary steps again.
Writing : The order of writing is different from the order of the eventual paper. The order below starts with the easiest parts to write and ends with the hardest.
Experimental setup/methods : Equipment (figures); kinds of measurements (archetypal examples); data analysis methods. As the graduate student who did the experiment, this section is the easiest to write because you just describe what you did.
Data presentation/analysis : It is sometimes necessary to present all of the raw data, but sometimes the archetypal examples in the previous section are sufficient.
Results and discussion : Plots and models of information extracted from raw data. This includes analysis of processed data.
Conclusions : (Re)State main results and explanation. Describe how this fulfills the knowledge gap (see below) and enables useful and/or interesting things (outlook and future directions).
Here we show : Summary of experiment. Preview of conclusions.
Motivation and introduction : Why do this? Why is it interesting/useful? Describe the state of the field. Set up and describe the "gap in knowledge" that your work fills.
Abstract : ("to draw out from") Take out the most essential parts of the manuscript.
Reorder sections : The sections above are presented in the final manuscript in a different order than they are written: (1) abstract, (2) motivation and intro, (3) here we show, (4) experimental setup/methods, (5) data presentation and analysis, (6) results and discussion, (7) conclusions.

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Stages in the research process, leslie gelling reader in research ethics, faculty of health, social care and education, anglia ruskin university, cambridge, england.

Research should be conducted in a systematic manner, allowing the researcher to progress from a general idea or clinical problem to scientifically rigorous research findings that enable new developments to improve clinical practice. Using a research process helps guide this process. This article is the first in a 26-part series on nursing research. It examines the process that is common to all research, and provides insights into ten different stages of this process: developing the research question, searching and evaluating the literature, selecting the research approach, selecting research methods, gaining access to the research site and data, pilot study, sampling and recruitment, data collection, data analysis, and dissemination of results and implementation of findings.

Nursing Standard . 29, 27, 44-49. doi: 10.7748/ns.29.27.44.e8745

[email protected]

This article has been subject to double blind peer review

Received: 10 January 2014

Accepted: 03 October 2014

Clinical nursing research - nursing research - qualitative research - quantitative research - research - research ethics - research methodology - research process - sampling

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04 March 2015 / Vol 29 issue 27

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Stages in the research process

Affiliation.

1 Faculty of Health, Social Care and Education, Anglia Ruskin University, Cambridge, England.
PMID: 25736674
DOI: 10.7748/ns.29.27.44.e8745

Keywords: Clinical nursing research; nursing research; qualitative research; quantitative research; research; research ethics; research methodology; research process; sampling.

Data Collection / methods
Pilot Projects
Research Design / standards*
Research Personnel / education*
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Action Research: What it is, Stages & Examples

Action research is a method often used to make the situation better. It combines activity and investigation to make change happen.

The best way to get things accomplished is to do it yourself. This statement is utilized in corporations, community projects, and national governments. These organizations are relying on action research to cope with their continuously changing and unstable environments as they function in a more interdependent world.

In practical educational contexts, this involves using systematic inquiry and reflective practice to address real-world challenges, improve teaching and learning, enhance student engagement, and drive positive changes within the educational system.

This post outlines the definition of action research, its stages, and some examples.

Content Index

What is action research?

Stages of action research, the steps to conducting action research, examples of action research, advantages and disadvantages of action research.

Action research is a strategy that tries to find realistic solutions to organizations’ difficulties and issues. It is similar to applied research.

Action research refers basically learning by doing. First, a problem is identified, then some actions are taken to address it, then how well the efforts worked are measured, and if the results are not satisfactory, the steps are applied again.

It can be put into three different groups:

Positivist: This type of research is also called “classical action research.” It considers research a social experiment. This research is used to test theories in the actual world.
Interpretive: This kind of research is called “contemporary action research.” It thinks that business reality is socially made, and when doing this research, it focuses on the details of local and organizational factors.
Critical: This action research cycle takes a critical reflection approach to corporate systems and tries to enhance them.

All research is about learning new things. Collaborative action research contributes knowledge based on investigations in particular and frequently useful circumstances. It starts with identifying a problem. After that, the research process is followed by the below stages:

Stage 1: Plan

For an action research project to go well, the researcher needs to plan it well. After coming up with an educational research topic or question after a research study, the first step is to develop an action plan to guide the research process. The research design aims to address the study’s question. The research strategy outlines what to undertake, when, and how.

Stage 2: Act

The next step is implementing the plan and gathering data. At this point, the researcher must select how to collect and organize research data . The researcher also needs to examine all tools and equipment before collecting data to ensure they are relevant, valid, and comprehensive.

Stage 3: Observe

Data observation is vital to any investigation. The action researcher needs to review the project’s goals and expectations before data observation. This is the final step before drawing conclusions and taking action.

Different kinds of graphs, charts, and networks can be used to represent the data. It assists in making judgments or progressing to the next stage of observing.

Stage 4: Reflect

This step involves applying a prospective solution and observing the results. It’s essential to see if the possible solution found through research can really solve the problem being studied.

The researcher must explore alternative ideas when the action research project’s solutions fail to solve the problem.

Action research is a systematic approach researchers, educators, and practitioners use to identify and address problems or challenges within a specific context. It involves a cyclical process of planning, implementing, reflecting, and adjusting actions based on the data collected. Here are the general steps involved in conducting an action research process:

Identify the action research question or problem

Clearly define the issue or problem you want to address through your research. It should be specific, actionable, and relevant to your working context.

Review existing knowledge

Conduct a literature review to understand what research has already been done on the topic. This will help you gain insights, identify gaps, and inform your research design.

Plan the research

Develop a research plan outlining your study’s objectives, methods, data collection tools, and timeline. Determine the scope of your research and the participants or stakeholders involved.

Collect data

Implement your research plan by collecting relevant data. This can involve various methods such as surveys, interviews, observations, document analysis, or focus groups. Ensure that your data collection methods align with your research objectives and allow you to gather the necessary information.

Analyze the data

Once you have collected the data, analyze it using appropriate qualitative or quantitative techniques. Look for patterns, themes, or trends in the data that can help you understand the problem better.

Reflect on the findings

Reflect on the analyzed data and interpret the results in the context of your research question. Consider the implications and possible solutions that emerge from the data analysis. This reflection phase is crucial for generating insights and understanding the underlying factors contributing to the problem.

Develop an action plan

Based on your analysis and reflection, develop an action plan that outlines the steps you will take to address the identified problem. The plan should be specific, measurable, achievable, relevant, and time-bound (SMART goals). Consider involving relevant stakeholders in planning to ensure their buy-in and support.

Implement the action plan

Put your action plan into practice by implementing the identified strategies or interventions. This may involve making changes to existing practices, introducing new approaches, or testing alternative solutions. Document the implementation process and any modifications made along the way.

Evaluate and monitor progress

Continuously monitor and evaluate the impact of your actions. Collect additional data, assess the effectiveness of the interventions, and measure progress towards your goals. This evaluation will help you determine if your actions have the desired effects and inform any necessary adjustments.

Reflect and iterate

Reflect on the outcomes of your actions and the evaluation results. Consider what worked well, what did not, and why. Use this information to refine your approach, make necessary adjustments, and plan for the next cycle of action research if needed.

Remember that participatory action research is an iterative process, and multiple cycles may be required to achieve significant improvements or solutions to the identified problem. Each cycle builds on the insights gained from the previous one, fostering continuous learning and improvement.

Explore Insightfully Contextual Inquiry in Qualitative Research

Here are two real-life examples of action research.

Action research initiatives are frequently situation-specific. Still, other researchers can adapt the techniques. The example is from a researcher’s (Franklin, 1994) report about a project encouraging nature tourism in the Caribbean.

In 1991, this was launched to study how nature tourism may be implemented on the four Windward Islands in the Caribbean: St. Lucia, Grenada, Dominica, and St. Vincent.

For environmental protection, a government-led action study determined that the consultation process needs to involve numerous stakeholders, including commercial enterprises.

First, two researchers undertook the study and held search conferences on each island. The search conferences resulted in suggestions and action plans for local community nature tourism sub-projects.

Several islands formed advisory groups and launched national awareness and community projects. Regional project meetings were held to discuss experiences, self-evaluations, and strategies. Creating a documentary about a local initiative helped build community. And the study was a success, leading to a number of changes in the area.

Lau and Hayward (1997) employed action research to analyze Internet-based collaborative work groups.

Over two years, the researchers facilitated three action research problem -solving cycles with 15 teachers, project personnel, and 25 health practitioners from diverse areas. The goal was to see how Internet-based communications might affect their virtual workgroup.

First, expectations were defined, technology was provided, and a bespoke workgroup system was developed. Participants suggested shorter, more dispersed training sessions with project-specific instructions.

The second phase saw the system’s complete deployment. The final cycle witnessed system stability and virtual group formation. The key lesson was that the learning curve was poorly misjudged, with frustrations only marginally met by phone-based technical help. According to the researchers, the absence of high-quality online material about community healthcare was harmful.

Role clarity, connection building, knowledge sharing, resource assistance, and experiential learning are vital for virtual group growth. More study is required on how group support systems might assist groups in engaging with their external environment and boost group members’ learning.

Action research has both good and bad points.

It is very flexible, so researchers can change their analyses to fit their needs and make individual changes.
It offers a quick and easy way to solve problems that have been going on for a long time instead of complicated, long-term solutions based on complex facts.
If It is done right, it can be very powerful because it can lead to social change and give people the tools to make that change in ways that are important to their communities.

Disadvantages

These studies have a hard time being generalized and are hard to repeat because they are so flexible. Because the researcher has the power to draw conclusions, they are often not thought to be theoretically sound.
Setting up an action study in an ethical way can be hard. People may feel like they have to take part or take part in a certain way.
It is prone to research errors like selection bias , social desirability bias, and other cognitive biases.

LEARN ABOUT: Self-Selection Bias

This post discusses how action research generates knowledge, its steps, and real-life examples. It is very applicable to the field of research and has a high level of relevance. We can only state that the purpose of this research is to comprehend an issue and find a solution to it.

At QuestionPro, we give researchers tools for collecting data, like our survey software, and a library of insights for any long-term study. Go to the Insight Hub if you want to see a demo or learn more about it.

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Frequently Asked Questions(FAQ’s)

Action research is a systematic approach to inquiry that involves identifying a problem or challenge in a practical context, implementing interventions or changes, collecting and analyzing data, and using the findings to inform decision-making and drive positive change.

Action research can be conducted by various individuals or groups, including teachers, administrators, researchers, and educational practitioners. It is often carried out by those directly involved in the educational setting where the research takes place.

The steps of action research typically include identifying a problem, reviewing relevant literature, designing interventions or changes, collecting and analyzing data, reflecting on findings, and implementing improvements based on the results.

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Engineering and Construction Industry Poised for Growth, But Persistent Challenges Cast a Shadow

A majority of the engineering and construction (E&C) industry remains cautiously optimistic despite widespread economic and geopolitical uncertainty, according to KPMG’s 2023 Global Construction Survey .

The new report includes industry perspectives from more than 250 E&C professionals globally, as well as project managers from a variety of industries. The study analyzes the growth potential and challenges facing the E&C industry, the rising influence of environmental, social, governance (ESG) initiatives and the role of new, innovative technology in the construction landscape.

“With more and more employees looking for companies that prioritize DEI and employee health and wellbeing, amongst other factors, companies will need to offer fulfilling careers with flexible working conditions, greater work-life balance and varied career paths alongside cutting edge innovation in purposeful, sustainable organizations in order to succeed in an ever-changing, competitive industry,” said Geno Armstrong, International Sector Leader – Engineering & Construction, KPMG International.

The stars are aligned

As the global E&C industry continues to face a volatile environment, with sustained supply chain disruption, rising inflation of energy, materials and wages, labor shortages and a possible recession, 66% of respondents are optimistic about the direction of the construction industry. The industry is poised for outsized growth due to infrastructure demand, government stimulus, energy transition and new post-covid customer demands.

Four out of ten E&C respondents expect revenue growth of more than 10% in the next 12 months.
78% believe infrastructure stimuli will have a positive impact.
E&C firms remain more cautious than project owners, but only 7% express pessimism about the future state of the market – the corresponding figure for 2021 was 29%.

Cracking the code – project performance

Despite the confidence expressed by respondents, the industry still needs to solve the productivity and performance issues that have plagued the industry for decades and continues to face a number of challenges, in the form of continued supply chain disruption, high energy and materials prices, and labor shortages that are further pushing up costs and holding up projects.

45% of project owner respondents say they have experienced a pandemic-related schedule delay or cost impact of more than 20%.
37% say that they have missed budget and/or schedule performance targets due to lack of effective risk management and that only half of project owners’ projects are meeting completion deadlines.
36% of respondents are placing greater emphasis on accurate risk reporting (up from 25% in 2021) and establishing a dedicated risk management department (20%, up from 17%).

The rising influence of ESG

In our very first Global Construction survey in 2008, respondents revealed that the number one driver for sustainability amongst E&C companies was to position themselves as “environmentally aware”. This year’s report notes that ESG has become a more important and integrated part of leaders’ thinking.

54% say they fully envisage the benefits of ESG investments and are making improvements in this area. 50 % of E&C companies see the opportunity to gain a competitive edge through investing in ESG initiatives, suggesting that leaders are beginning to grasp the value of embracing ESG more fully.
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Project owners and E&C firms have differing views on the most crucial aspects of ESG, with project owners feeling that reducing greenhouse gas outputs and developing renewable facilities as the most important, while contractors are more concerned with social considerations such as Diversity, Equity and Inclusion (DEI) and meeting government requirements.

The stage is set for continued innovation

The construction industry is starting to embrace the power of technology to transform performance. The adoption of innovative technologies such as robotic process automation (RPA), virtual reality (VR), project management information systems (PMIS), drones, smart sensors and artificial intelligence (AI) has increased significantly. When it comes to improving ROI on capability projects, PMIS, building information modeling (BIM) and advanced data analytics are considered to have the greatest potential; digital twins, modular/offsite manufacturing, AI, and BIM are driving the greatest gains in project performance.

81% of E&C firms say they are adopting mobile platforms, 43% use RPA and 40% are adopting AI—although many are in the early stages.
However, a smaller proportion of the respondents’ companies are applying these technologies across all projects, creating a lack of consistency in standards across the industry.
A vast majority of respondents say prefabrication is an important solution for capability projects, although just one-quarter of E&C companies use modular manufacturing across all projects.

For more insight, check out the full 2023 Global Construction Survey .

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IMAGES

Infographic: Steps in the Research Process
The Research Process
Components of Research Process
6 Preliminary Steps In Making A Statistical Study
How to Create a Strong Research Design: 2-Minute Summary
Writing a Research Proposal

VIDEO

What is research
Choosing a Research Topic
Research Methodology Presentations
First step to select research topic
What is a Research Project?

COMMENTS

A Beginner's Guide to Starting the Research Process
Step 4: Create a research design. The research design is a practical framework for answering your research questions. It involves making decisions about the type of data you need, the methods you'll use to collect and analyze it, and the location and timescale of your research. There are often many possible paths you can take to answering ...
Research Process Steps: What they are + How To Follow
Step 1: Identify the Problem. Finding an issue or formulating a research question is the first step. A well-defined research problem will guide the researcher through all stages of the research process, from setting objectives to choosing a technique. There are a number of approaches to get insight into a topic and gain a better understanding ...
Research Process: 8 Steps in Research Process
Before explaining the stages of the research process, we explain the term 'iterative' appearing within the oval-shaped diagram at the center of the schematic diagram. ... The key to a successful research project ultimately lies in iteration: the process of returning again and again to the identification of the research problems, methodology ...
Research Guides: 6 Stages of Research: 1: Task Definition
The 6 stages are: Task Definition (developing a topic) Information Seeking (coming up with a research plan) Location & Access (finding good sources) Use of Information (Reading, taking notes, and generally making the writing process easier) Synthesis (coming up with your own ideas and presenting them well)
Managing a Research Project
The basic stages involved in undertaking a university research project are as follows: 1. Choose your research area. Usually, it is best choose an area that you have already studied or are studying within your academic field. Not only will this help you identify potential research, but you can be confident in finding a suitable supervisor and ...
Overview of Research Process
See Appendix B to view the basic components of a research proposal. Appendix B Components of a Research Proposal. Collect & Analyze Data. In Practical Research-Planning and Design (2005, 8th Edition), Leedy and Ormrod provide excellent advice for what the researcher does at this stage in the research process. The researcher now
Research Process
Step 2: Develop a Hypothesis Based on the literature review, develop a hypothesis that a plant-based diet positively affects athletic performance in high school athletes. Step 3: Design the Study Design a study to test the hypothesis. Decide on the study population, sample size, and research methods.
Basic Steps in the Research Process
Step 1: Identify and develop your topic. Selecting a topic can be the most challenging part of a research assignment. Since this is the very first step in writing a paper, it is vital that it be done correctly. Here are some tips for selecting a topic: Select a topic within the parameters set by the assignment.
How to do a research project for your academic study
Methodology - the methods you will use for your primary research. Findings and results - presenting the data from your primary research. Discussion - summarising and analysing your research and what you have found out. Conclusion - how the project went (successes and failures), areas for future study.
Stages in the development of a research project: putting the idea
The purpose of this paper is to provide an overview of the process and stages involved in developing a research idea from its inception to realisation. It is not designed to be an all encompassing summary of the research process. It fprovides a brief guide to the most common sequence of stages involved in the development of a research idea into a viable research proposal. Useful references for ...
5 Steps in the Research Process
The five (5) steps in the research process are: [1] Step 1: Locating and Defining Issues or Problems - Understanding the questions that need to be answered or studied. Step 2: Designing the Research Project - Creating a research plan. Step 3: Collecting Data - Obtaining the information needed to solve the identified issue or problem.
Research Process
A typical research process comprises the following stages: 1. Selecting the research area. Your dissertation marker expects you to state that you have selected the research area due to professional and personal interests in the area and this statement must be true. Students often underestimate the importance of this first stage in the research ...
Research Process ~ The 5 Stages of Your Research
A research question aims to help you get perspectives on what you should focus on when conducting research for your project. A strong research question should be, focused, researchable, feasible, specific, complex, and relevant. Other types of research require a conceptual framework and testable hypotheses before coming up with research questions.
How to plan a research project
Planning research projects is a time-honoured intellectual exercise: one that requires both creativity and sharp analytical skills. The purpose of this Guide is to make the process systematic and easy to understand. While there is a great deal of freedom and discovery involved - from the topics you choose, to the data and methods you apply ...
What Are the Steps of the Research Process? (Plus Tips)
1. Identify the project topic. A successful research process often begins with a clearly defined intent for the research project. You can focus on a topic in nearly any field of study, as the research process broadly applies across all academic and professional fields. The more precisely you identify the topic for your research, the more ...
The 5 Steps of the Research Process
The research process outlines the key steps taken in order to complete a thorough and procedurally sound research project. Knowing how each of the 5 phases of the research process work in tandem helps keep the project on track. ... The research process can be broken down into 5 simple and clearly defined stages. Understanding how these steps ...
The critical steps for successful research: The research proposal and
Completing any research project requires meticulous planning, experimental design and execution, and compilation and publication of findings in the form of a research paper. All of these are often unfamiliar to naïve researchers; thus, the purpose of this workshop was to teach participants to master the critical steps involved in the ...
What Is a Research Design
Step 1: Consider your aims and approach. Step 2: Choose a type of research design. Step 3: Identify your population and sampling method. Step 4: Choose your data collection methods. Step 5: Plan your data collection procedures. Step 6: Decide on your data analysis strategies. Other interesting articles.
Stages of a Research Project
Stages of a Research Project. A research project will progress through many stages from its conception through publishing the results. Below is a mostly ordered list of the stages of an experimental research project in our laboratory. Sometimes these stages will be done in a different orde r, o r they may repeat, or they may blend into one another. . Different fields of physics and different ...
Stages in the research process
This article is the first in a 26-part series on nursing research. It examines the process that is common to all research, and provides insights into ten different stages of this process: developing the research question, searching and evaluating the literature, selecting the research approach, selecting research methods, gaining access to the ...
Stages in the research process
This article is the first in a 26-part series on nursing research. It examines the process that is common to all research, and provides insights into ten different stages of this process: developing the research question, searching and evaluating the literature, selecting the research approach, selecting research methods, gaining access to the ...
Action Research: What it is, Stages & Examples
Stage 1: Plan. For an action research project to go well, the researcher needs to plan it well. After coming up with an educational research topic or question after a research study, the first step is to develop an action plan to guide the research process. The research design aims to address the study's question.
ISRO Announces Internship & Student Project Trainee Schemes, Know How
Apply for ISRO's Internship & Student Project Trainee Schemes and gain hands-on experience in cutting-edge space research. Open to undergraduate, postgraduate, and PhD students in Science ...
KPMG Global Construction Survey: Familiar Challenges
A majority of the engineering and construction (E&C) industry remains cautiously optimistic despite widespread economic and geopolitical uncertainty, according to KPMG's 2023 Global Construction Survey. The new report includes industry perspectives from more than 250 E&C professionals globally, as well as project managers from a variety of industries.

Research Process: 8 Steps in Research Process

What is the Research Process?

How Research Process Work?

What is the primary purpose of the research process?

Why is the research design important in the research process?

8 Steps of Research Process

Non-Research Problems

How is a research problem different from a non-research problem?

Non-Research Problems Examples

Research Problem

Research Problem Examples

Research Problem – Example #2

Research Problem – Example #3

Issues of Research Problem Identification

Pilot Survey

Case Studies

Focus Group Interviews

Experience Survey

Reviewing of Literature

Why is reviewing literature crucial in the research process?

What is the significance of reviewing literature in the research process?

Setting Research Questions, Objectives, and Hypotheses

Step #4: Choosing the Study Design

Deciding on the Sample Design

Collecting Data From The Research Sample

Process and Analyze the Collected Research Data

Writing Research Report – Developing Research Proposal, Writing Report, Disseminating and Utilizing Results

Why is the dissemination of research findings important?

How should a research report be structured?

Why is it essential to consider the target audience when preparing a research report?

6 Stages of Research

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Purpose of this guide

Task Definition

Steps to Developing a Topic

Read your assignment and note any requirements.

Formulate a general idea.

Do some background research on your general idea.

Mind map it.

Ask Questions to focus on what interests you.

Write out your topic question & reread the assignment criteria.

Developing a Topic Tutorial

Search for a course

Fees and funding

Why study at Kent

Research institutes

Research students

Popular searches

Research projects & dissertations

The stages of a research project

1. Choose your research area

2. Conduct preliminary research (scope out the topic)

3. Decide your research topic

4. Decide your methodology

5. Submit/present your research proposal for approval

6. Finalise your topic and methodology

7. Conduct your research (fieldwork)

8. Analysis/data processing

9. Writing up

10. Submission

Project managing your research

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The Research Process

Identify a Research Problem

Review the Literature

Determine Research Question

Develop Research Methods

Collect & Analyze Data

Document the Work

Communicate Your Research

Refine/Expand, Pioneer

Research Process – Steps, Examples and Tips

Research Process

Research Process Steps

Identify the Research Question or Problem

Conduct a Literature Review

Formulate a Hypothesis or Research Objectives

Design a Research Plan and Methodology

Collect and Analyze Data

Interpret the Findings and Draw Conclusions