1
Qualitative Analysis of Content
by
Yan Zhang and Barbara M. Wildemuth
If there were only one truth, you couldn’t paint a hundred canvases on the
same theme.
--Pablo Picasso, 1966
Introduction
As one of today’s most extensively employed analytical tools, content analysis
has been used fruitfully in a wide variety of research applications in information and
library science (ILS) (Allen & Reser, 1990). Similar to other fields, content analysis has
been primarily used in ILS as a quantitative research method until recent decades. Many
current studies use qualitative content analysis, which addresses some of the weaknesses
of the quantitative approach.
Qualitative content analysis has been defined as:
“a research method for the subjective interpretation of the content of text data
through the systematic classification process of coding and identifying themes
or patterns” (Hsieh & Shannon, 2005, p.1278),
“an approach of empirical, methodological controlled analysis of texts within
their context of communication, following content analytic rules and step by
step models, without rash quantification” (Mayring, 2000, p.2), and
“any qualitative data reduction and sense-making effort that takes a volume of
qualitative material and attempts to identify core consistencies and meanings”
(Patton, 2002, p.453).
These three definitions illustrate that qualitative content analysis emphasizes an
integrated view of speech/texts and their specific contexts. Qualitative content analysis
goes beyond merely counting words or extracting objective content from texts to examine
meanings, themes and patterns that may be manifest or latent in a particular text. It allows
researchers to understand social reality in a subjective but scientific manner.
Comparing qualitative content analysis with its rather familiar quantitative
counterpart can enhance our understanding of the method. First, the research areas from
which they developed are different. Quantitative content analysis (discussed in the
previous chapter) is used widely in mass communication as a way to count manifest
textual elements, an aspect of this method that is often criticized for missing syntactical
and semantic information embedded in the text (Weber, 1990). By contrast, qualitative
content analysis was developed primarily in anthropology, qualitative sociology, and
psychology, in order to explore the meanings underlying physical messages. Second,
quantitative content analysis is deductive, intended to test hypotheses or address
questions generated from theories or previous empirical research. By contrast, qualitative
content analysis is mainly inductive, grounding the examination of topics and themes, as
well as the inferences drawn from them, in the data. In some cases, qualitative content
2
analysis attempts to generate theory. Third, the data sampling techniques required by the
two approaches are different. Quantitative content analysis requires that the data are
selected using random sampling or other probabilistic approaches, so as to ensure the
validity of statistical inference. By contrast, samples for qualitative content analysis
usually consist of purposively selected texts which can inform the research questions
being investigated. Last but not the least, the products of the two approaches are
different. The quantitative approach produces numbers that can be manipulated with
various statistical methods. By contrast, the qualitative approach usually produces
descriptions or typologies, along with expressions from subjects reflecting how they view
the social world. By this means, the perspectives of the producers of the text can be better
understood by the investigator as well as the readers of the study’s results (Berg, 2001).
Qualitative content analysis pays attention to unique themes that illustrate the range of
the meanings of the phenomenon rather than the statistical significance of the occurrence
of particular texts or concepts.
In real research work, the two approaches are not mutually exclusive and can be
used in combination. As suggested by Smith, “qualitative analysis deals with the forms
and antecedent-consequent patterns of form, while quantitative analysis deals with
duration and frequency of form”(Smith, 1975, p.218). Weber (1990) also pointed out that
the best content-analytic studies use both qualitative and quantitative operations.
Inductive vs. Deductive
Qualitative content analysis involves a process designed to condense raw data into
categories or themes based on valid inference and interpretation. This process uses
inductive reasoning, by which themes and categories emerge from the data through the
researcher’s careful examination and constant comparison. But qualitative content
analysis does not need to exclude deductive reasoning (Patton, 2002). Generating
concepts or variables from theory or previous studies is also very useful for qualitative
research, especially at the inception of data analysis (Berg, 2001).
Hsieh and Shannon (2005) discussed three approaches to qualitative content
analysis, based on the degree of involvement of inductive reasoning. The first is
conventional qualitative content analysis, in which coding categories are derived directly
and inductively from the raw data. This is the approach used for grounded theory
development. The second approach is directed content analysis, in which initial coding
starts with a theory or relevant research findings. Then, during data analysis, the
researchers immerse themselves in the data and allow themes to emerge from the data.
The purpose of this approach usually is to validate or extend a conceptual framework or
theory. The third approach is summative content analysis, which starts with the counting
of words or manifest content, then extends the analysis to include latent meanings and
themes. This approach seems quantitative in the early stages, but its goal is to explore the
usage of the words/indicators in an inductive manner.
The Process of Qualitative Content Analysis
The process of qualitative content analysis often begins during the early stages of
data collection. This early involvement in the analysis phase will help you move back and
forth between concept development and data collection, and may help direct your
3
subsequent data collection toward sources that are more useful for addressing the
research questions (Miles & Huberman, 1994). To support valid and reliable inferences,
qualitative content analysis involves a set of systematic and transparent procedures for
processing data. Some of the steps overlap with the traditional quantitative content
analysis procedures (Tesch, 1990), while others are unique to this method. Depending on
the goals of your study, your content analysis may be more flexible or more standardized,
but generally it can be divided into the following steps, beginning with preparing the data
and proceeding through writing up the findings in a report.
Step 1: Prepare the Data
Qualitative content analysis can be used to analyze various types of data, but
generally the data need to be transformed into written text before analysis can start. If the
data come from existing texts, the choice of the content must be justified by what you
want to know (Patton, 2002). In ILS studies, qualitative content analysis is most often
used to analyze interview transcripts in order to reveal or model people’s information
related behaviors and thoughts. When transcribing interviews, the following questions
arise: (1) should all the questions of the interviewer or only the main questions from the
interview guide be transcribed; (2) should the verbalizations be transcribed literally or
only in a summary; and (3) should observations during the interview (e.g., sounds,
pauses, and other audible behaviors) be transcribed or not (Schilling, 2006)? Your
answers to these questions should be based on your research questions. While a complete
transcript may be the most useful, the additional value it provides may not justify the
additional time required to create it.
Step 2: Define the Unit of Analysis
The unit of analysis refers to the basic unit of text to be classified during content
analysis. Messages have to be unitized before they can be coded, and differences in the
unit definition can affect coding decisions as well as the comparability of outcomes with
other similar studies (De Wever et al., 2006). Therefore, defining the coding unit is one
of your most fundamental and important decisions (Weber, 1990).
Qualitative content analysis usually uses individual themes as the unit for
analysis, rather than the physical linguistic units (e.g., word, sentence, or paragraph) most
often used in quantitative content analysis. An instance of a theme might be expressed in
a single word, a phrase, a sentence, a paragraph, or an entire document. When using
theme as the coding unit, you are primarily looking for the expressions of an idea
(Minichiello et al., 1990). Thus, you might assign a code to a text chunk of any size, as
long as that chunk represents a single theme or issue of relevance to your research
question(s).
Step 3: Develop Categories and a Coding Scheme
Categories and a coding scheme can be derived from three sources: the data,
previous related studies, and theories. Coding schemes can be developed both inductively
and deductively. In studies where no theories are available, you must generate categories
inductively from the data. Inductive content analysis is particularly appropriate for
studies that intend to develop theory, rather than those that intend to describe a particular
phenomenon or verify an existing theory. When developing categories inductively from
4
raw data, you are encouraged to use the constant comparative method (Glaser & Strauss,
1967), since it is not only able to stimulate original insights, but is also able to make
differences between categories apparent. The essence of the constant comparative method
is (1) the systematic comparison of each text assigned to a category with each of those
already assigned to that category, in order to fully understand the theoretical properties of
the category; and (2) integrating categories and their properties through the development
of interpretive memos.
For some studies, you will have a preliminary model or theory on which to base
your inquiry. You can generate an initial list of coding categories from the model or
theory, and you may modify the model or theory within the course of the analysis as new
categories emerge inductively (Miles & Huberman, 1994). The adoption of coding
schemes developed in previous studies has the advantage of supporting the accumulation
and comparison of research findings across multiple studies.
In quantitative content analysis, categories need to be mutually exclusive because
confounded variables would violate the assumptions of some statistical procedures
(Weber, 1990). However, in reality, assigning a particular text to a single category can be
very difficult. Qualitative content analysis allows you to assign a unit of text to more than
one category simultaneously (Tesch, 1990). Even so, the categories in your coding
scheme should be defined in a way that they are internally as homogeneous as possible
and externally as heterogeneous as possible (Lincoln & Guba, 1985).
To ensure the consistency of coding, especially when multiple coders are
involved, you should develop a coding manual, which usually consists of category
names, definitions or rules for assigning codes, and examples (Weber, 1990). Some
coding manuals have an additional field for taking notes as coding proceeds. Using the
constant comparative method, your coding manual will evolve throughout the process of
data analysis, and will be augmented with interpretive memos.
Step 4: Test Your Coding Scheme on a Sample of Text
If you are using a fairly standardized process in your analysis, you’ll want to
develop and validate your coding scheme early in the process. The best test of the clarity
and consistency of your category definitions is to code a sample of your data. After the
sample is coded, the coding consistency needs to be checked, in most cases through an
assessment of inter-coder agreement. If the level of consistency is low, the coding rules
must be revised. Doubts and problems concerning the definitions of categories, coding
rules, or categorization of specific cases need to be discussed and resolved within your
research team (Schilling, 2006). Coding sample text, checking coding consistency, and
revising coding rules is an iterative process and should continue until sufficient coding
consistency is achieved (Weber, 1990).
Step 5: Code All the Text
When sufficient consistency has been achieved, the coding rules can be applied to
the entire corpus of text. During the coding process, you will need to check the coding
repeatedly, to prevent “drifting into an idiosyncratic sense of what the codes mean”
(Schilling, 2006). Because coding will proceed while new data continue to be collected,
it’s possible (even quite likely) that new themes and concepts will emerge and will need
to be added to the coding manual.
5
Step 6: Assess Your Coding Consistency
After coding the entire data set, you need to recheck the consistency of your
coding. It is not safe to assume that, if a sample was coded in a consistent and reliable
manner, the coding of the whole corpus of text is also consistent. Human coders are
subject to fatigue and are likely to make more mistakes as the coding proceeds. New
codes may have been added since the original consistency check. Also, the coders’
understanding of the categories and coding rules may change subtly over the time, which
may lead to greater inconsistency (Miles & Huberman, 1994; Weber, 1990). For all these
reasons, you need to recheck your coding consistency.
Step 7: Draw Conclusions from the Coded Data
This step involves making sense of the themes or categories identified, and their
properties. At this stage, you will make inferences and present your reconstructions of
meanings derived from the data. Your activities may involve exploring the properties and
dimensions of categories, identifying relationships between categories, uncovering
patterns, and testing categories against the full range of data (Bradley, 1993). This is a
critical step in the analysis process, and its success will rely almost wholly on your
reasoning abilities.
Step 8: Report Your Methods and Findings
For the study to be replicable, you need to monitor and report your analytical
procedures and processes as completely and truthfully as possible (Patton, 2002). In the
case of qualitative content analysis, you need to report your decisions and practices
concerning the coding process, as well as the methods you used to establish the
trustworthiness of your study (discussed below).
Qualitative content analysis does not produce counts and statistical significance;
instead, it uncovers patterns, themes, and categories important to a social reality.
Presenting research findings from qualitative content analysis is challenging. Although it
is a common practice to use typical quotations to justify conclusions (Schilling, 2006),
you also may want to incorporate other options for data display, including matrices,
graphs, charts, and conceptual networks (Miles & Huberman, 1994). The form and extent
of reporting will finally depend on the specific research goals (Patton, 2002).
When presenting qualitative content analysis results, you should strive for a
balance between description and interpretation. Description gives your readers
background and context and thus needs to be rich and thick (Denzin, 1989). Qualitative
research is fundamentally interpretive, and interpretation represents your personal and
theoretical understanding of the phenomenon under study. An interesting and readable
report “provides sufficient description to allow the reader to understand the basis for an
interpretation, and sufficient interpretation to allow the reader to understand the
description” (Patton, 2002, p.503-504).
6
Computer Support for Qualitative Content Analysis
Qualitative content analysis is usually supported by computer programs, such as
NVivo
1
or ATLAS.ti.
2
The programs vary in their complexity and sophistication, but
their common purpose is to assist researchers in organizing, managing, and coding
qualitative data in a more efficient manner. The basic functions that are supported by
such programs include text editing, note and memo taking, coding, text retrieval, and
node/category manipulation. More and more qualitative data analysis software
incorporates a visual presentation module that allows researchers to see the relationships
between categories more vividly. Some programs even record a coding history to allow
researchers to keep track of the evolution of their interpretations. Any time you will be
working with more than a few interviews or are working with a team of researchers, you
should use this type of software to support your efforts.
Trustworthiness
Validity, reliability, and objectivity are criteria used to evaluate the quality of
research in the conventional positivist research paradigm. As an interpretive method,
qualitative content analysis differs from the positivist tradition in its fundamental
assumptions, research purposes, and inference processes, thus making the conventional
criteria unsuitable for judging its research results (Bradley, 1993). Recognizing this gap,
Lincoln and Guba (1985) proposed four criteria for evaluating interpretive research work:
credibility, transferability, dependability, and confirmability.
Credibility refers to the “adequate representation of the constructions of the social
world under study” (Bradley, 1993, p.436). Lincoln and Guba (1985) recommended a set
of activities that would help improve the credibility of your research results: prolonged
engagement in the field, persistent observation, triangulation, negative case analysis,
checking interpretations against raw data, peer debriefing, and member checking. To
improve the credibility of qualitative content analysis, researchers not only need to design
data collection strategies that are able to adequately solicit the representations, but also to
design transparent processes for coding and drawing conclusions from the raw data.
Coders’ knowledge and experience have significant impact on the credibility of research
results. It is necessary to provide coders precise coding definitions and clear coding
procedures. It is also helpful to prepare coders through a comprehensive training program
(Weber, 1990).
Transferability refers to the extent to which the researcher’s working hypothesis
can be applied to another context. It is not the researcher’s task to provide an index of
transferability; rather, he or she is responsible for providing data sets and descriptions
that are rich enough so that other researchers are able to make judgments about the
findings’ transferability to different settings or contexts.
Dependability refers to “the coherence of the internal process and the way the
researcher accounts for changing conditions in the phenomena” (Bradley, 1993, p.437).
Confirmability refers to “the extent to which the characteristics of the data, as posited by
the researcher, can be confirmed by others who read or review the research results”
(Bradley, 1993, p.437). The major technique for establishing dependability and
1
http://www.qsrinternational.com/products_nvivo.aspx.
2
http://www.atlasti.com/.
7
confirmability is through audits of the research processes and findings. Dependability is
determined by checking the consistency of the study processes, and confirmability is
determined by checking the internal coherence of the research product, namely, the data,
the findings, the interpretations, and the recommendations. The materials that could be
used in these audits include raw data, field notes, theoretical notes and memos, coding
manuals, process notes, and so on. The audit process has five stages: preentry,
determinations of auditability, formal agreement, determination of trustworthiness
(dependability and confirmability), and closure. A detailed list of activities and tasks at
each stage can be found in Appendix B in Lincoln and Guba (1985).
Examples
Two examples of qualitative content analysis will be discussed here. The first
example study (Schamber, 2000) was intended to identify and define the criteria that
weather professionals use to evaluate particular information resources. Interview data
were analyzed inductively. In the second example, Foster (2004) investigated the
information behaviors of interdisciplinary researchers. Based on semi-structured
interview data, he developed a model of these researchers’ information seeking and use.
These two studies are typical of ILS research that incorporates qualitative content
analysis.
Example 1: Criteria for Making Relevance Judgments
Schamber (2000) conducted an exploratory inquiry into the criteria that
occupational users of weather information employ to make relevance judgments on
weather information sources and presentation formats. To get first-hand accounts from
users, she used the time-line interview method to collect data from 30 subjects: 10 each in
construction, electric power utilities, and aviation. These participants were highly
motivated and had very specific needs for weather information. In accordance with a
naturalistic approach, the interview responses were to be interpreted in a way that did not
compromise the original meaning expressed by the study participant. Inductive content
analysis was chosen for its power to make such faithful inferences.
The interviews were audio taped and transcribed. The transcripts served as the
primary sources of data for content analysis. Because the purpose of the study was to
identify and describe criteria used by people to make relevance judgments, Schamber
defined a coding unit as “a word or group of words that could be coded under one
criterion category” (Schamber, 2000, p.739). Responses to each interview were unitized
before they were coded.
As Schamber pointed out, content analysis functions both as a secondary
observational tool for identifying variables in text and an analytical tool for
categorization. Content analysis was incorporated in this study at the pretest stage of
developing the interview guide as a basis for the coding scheme, as well as assessing the
effectiveness of particular interview items. The formal process of developing the coding
scheme began shortly after the first few interviews. The whole process was an iteration of
coding a sample of data, testing inter-coder agreement, and revising the coding scheme.
Whenever the percentage of agreement did not reach an acceptable level, the coding
scheme was revised (Schamber, 1991). The author reported that, “based on data from the
first few respondents, the scheme was significantly revised eight times and tested by 14
8
coders until inter-coder agreement reached acceptable levels” (Schamber, 2000, p.738).
The 14 coders were not involved in the coding at the same time; rather, they were spread
across three rounds of revision.
The analysis process was inductive and took a grounded theory approach. The
author did not derive variables/categories from existing theories or previous related
studies, and she had no intention of verifying existing theories; rather, she immersed
herself in the interview transcripts and let the categories emerge on their own. Some
categories in the coding scheme were straightforward and could be easily identified based
on manifest content, while others were harder to identify because they were partially
based on the latent content of the texts. The categories were expected to be mutually
exclusive (distinct from each other) and exhaustive. The iterative coding process resulted
in a coding scheme with eight main categories.
Credibility evaluates the validity of a researcher’s reconstruction of a social
reality. In this study, Schamber carefully designed and controlled the data collection and
data analysis procedures to ensure the credibility of the research results. First, the time-
line interview technique solicited respondents’ own accounts of the relevance judgments
they made on weather information in their real working environments instead of in
artificial experimental settings. Second, non-intrusive inductive content analysis was used
to identify the themes emerging from the interview transcripts. The criteria were defined
in respondents’ own language as it appeared in the interviews. Furthermore, a peer
debriefing process was involved in the coding development process, which ensures the
credibility of the research by reducing the bias of a single researcher. As reported by
Schamber (1991), “a group of up to seven people, mostly graduate students including the
researcher, met weekly for most of a semester and discussed possible criterion categories
based on transcripts from four respondents” (p.84-85). The credibility of the research
findings also was verified by the fact that most criteria were mentioned by more than one
respondent and in more than one scenario. Theory saturation was achieved as mentions of
criteria became increasingly redundant.
Schamber did not claim transferability of the research results explicitly, but the
transferability of the study was made possible by detailed documentation of the data
processing in a Codebook. The first part of the Codebook explained procedures for
handling all types of data (including quantitative). In the second part, the coding scheme
was listed; it included: identification numbers, category names, detailed category
definitions, coding rules, and examples. This detailed documentation of the data handling
and the coding scheme makes it easier for future researchers to judge the transferability
of the criteria to other user populations or other situational contexts. The transferability of
the identified criteria also was supported by the fact that the criteria identified in this
study were also widely documented in previous research works.
The dependability of the research findings in this study was established by the
transparent coding process and inter-coder verification. The inherent ambiguity of word
meanings, category definitions, and coding procedures threaten the coherence and
consistency of coding practices, hence negatively affecting the credibility of the findings.
To make sure that the distinctions between categories were clear to the coders, the
Codebook defined them. To ensure coding consistency, every coder used the same
version of the scheme to code the raw interview data. Both the training and the
experience of the coder are necessary for reliable coding (Neuendorf, 2002). In this study,
9
the coders were graduate students who had been involved the revision of the coding
scheme and, thus, were experienced at using the scheme (Schamber, 1991). The final
coding scheme was tested for inter-coder reliability with a first-time coder based on
simple percent agreement: the number of agreements between two independent coders
divided by the number of possible agreements. As noted in the previous chapter, more
sophisticated methods for assessing inter-coder agreement are available. If you’re using a
standardized coding scheme, refer to that discussion.
As suggested by Lincoln and Guba (1985), confirmability is primarily established
through a comfirmability audit, which Schamber did not conduct. However, the
significant overlap of the criteria identified in this study with those identified in other
studies indicates that the research findings have been confirmed by other researchers.
Meanwhile, the detailed documentation of data handling also provides means for
comfirmability checking.
When reporting the trustworthiness of the research results, instead of using the
terms, “credibility,” “transferability,” “dependability,” and “confirmability,” Schamber
used terms generally associated with positivist studies: “internal validity,” “external
validity,” “reliability,” and “generalizability.” It is worth pointing out that there is no
universal agreement on the terminology used when assessing the quality of a qualitative
inquiry. However, we recommend that the four criteria proposed by Lincoln and Guba
(1985) be used to evaluate the trustworthiness of research work conducted within an
interpretive paradigm.
Descriptive statistics, such as frequency of criteria occurrence, were reported in
the study. However, the purpose of the study was to describe the range of the criteria
employed to decide the degree of relevance of weather information in particular
occupations. Thus, the main finding was a list of criteria, along with their definitions,
keywords, and examples. Quotations excerpted from interview transcripts were used to
further describe the identified criteria, as well as to illustrate the situational contexts in
which the criteria were applied.
Example 2: Information Seeking in an Interdisciplinary Context
Foster (2004) examined the information seeking behaviors of scholars working in
interdisciplinary contexts. His goal was threefold: (1) to identify the activities, strategies,
contexts, and behaviors of interdisciplinary information seekers; (2) to understand the
relationships between behaviors and context; and (3) to represent the information seeking
behavior of interdisciplinary researchers in an empirically grounded model. This study is
a naturalist inquiry, using semi-structured interviews to collect direct accounts of
information seeking experiences from 45 interdisciplinary researchers. The respondents
were selected through purposive sampling, along with snowball sampling. To “enhance
contextual richness and minimize fragmentation” (Foster, 2004, p.230), all participants
were interviewed in their normal working places.
In light of the exploratory nature of the study, the grounded theory approach
guided the data analysis. Foster did not have any specific expectations for the data before
the analysis started. Rather, he expected that concepts and themes related to
interdisciplinary information seeking would emerge from the texts through inductive
content analysis and the constant comparative method.
10
Coding took place in multiple stages, over time. The initial coding process was an
open coding process. The author closely read and annotated each interview transcript.
During this process, the texts were unitized and concepts were highlighted and labeled.
Based on this initial analysis, Foster identified three stages of information seeking in
interdisciplinary contexts – initial, middle, and final – along with activities involved in
each stage. Subsequent coding took place in the manner of constantly comparing the
current transcript with previous ones to allow the emergence of categories and their
properties. As the coding proceeded, additional themes and activities emerged – not
covered by the initially-identified three-stage model. Further analysis of emergent
concepts and themes and their relationships to each other resulted in a two-dimensional
model of information seeking behaviors in the interdisciplinary context. One dimension
delineates three nonlinear core processes of information seeking activities: opening,
orientation, and consolidation. The other dimension consists of three levels of contextual
interaction: cognitive approach, internal context, and external context.
The ATLAS.ti software was used to support the coding process. It allows the
researcher to code the data, retrieve text based on keywords, rename or merge existing
codes without perturbing the rest of the codes, and generate visualizatios of emergent
codes and their relationships to one another. ATLAS.ti also maintains automatic logs of
coding changes, which makes it possible to keep track of the evolution of the analysis.
As reported by Foster, coding consistency in this study was addressed by
including three iterations of coding conducted over a period of one year. However, the
author did not report on the three rounds of coding in detail. For example, he did not say
how many coders were involved in the coding, how the coders were trained, how the
coding rules were defined, and what strategies were used to ensure transparent coding. If
all three rounds of coding were done by Foster alone, there was no assessment of coding
consistency. While this is a common practice in qualitative research, it weakens the
author’s argument for the dependability of the study.
The issue of trustworthiness of the study was discussed in terms of the criteria
suggested by Lincoln and Guba (1985): credibility, dependability, transferability, and
confirmability. Credibility was established mainly through member checking and peer
debriefing. Member checking was used in four ways at various stages of data collection
and data analysis: (1) at the pilot stage, the interviewer discussed the interview questions
with participants at the end of each interview; (2) during formal interviews, the
interviewer fed ideas back to participants to refine, rephrase, and interpret; (3) in an
informal post-interview session, each participant was given the chance to discuss the
findings; and (4) an additional session was conducted with a sample of five participants
willing to provide feedback on the transcripts of their own interview as well as evaluate
the research findings. Peer debriefing was used in the study to “confirm interpretations
and coding decisions including the development of categories” (Foster, 2004, p.231). No
further details about who conducted the debriefing or how it was conducted were
reported in the paper.
The transferability of the present study was ensured by “rich description and
reporting of the research process” (Foster, 2004, p.230). Future researchers can make
transferability judgments based on the detailed description provided by Foster. The issues
of dependability and confirmability were addressed through the author’s “research notes,
which recorded decisions, queries, working out, and the development results” (Foster,
11
2004, p.230). By referring to these materials, Foster could audit his own inferences and
interpretations, and other interested researchers could review the research findings.
The content analysis findings were reported by describing each component in the
model of information seeking behaviors in interdisciplinary contexts that emerged from
this study. Diagrams and tables were used to facilitate the description. A few quotations
from participants were provided to reinforce the author’s abstraction of three processes of
interdisciplinary information seeking: opening, orientation, and consolidation. Finally,
Foster discussed the implications of the new model for the exploration of information
behaviors in general.
Conclusion
Qualitative content analysis is a valuable alternative to more traditional
quantitative content analysis, when the researcher is working in an interpretive paradigm.
The goal is to identify important themes or categories within a body of content, and to
provide a rich description of the social reality created by those themes/categories as they
are lived out in a particular setting. Through careful data preparation, coding, and
interpretation, the results of qualitative content analysis can support the development of
new theories and models, as well as validating existing theories and providing thick
descriptions of particular settings or phenomena.
Cited Works
Allen, B., & Reser, D. (1990). Content analysis in library and information science
research. Library & Information Science Research, 12(3), 251-260.
Berg, B.L. (2001). Qualitative Research Methods for the Social Sciences. Boston: Allyn
and Bacon.
Bradley, J. (1993). Methodological issues and practices in qualitative research. Library
Quarterly, 63(4), 431-449.
De Wever, B., Schellens, T., Valcke, M., & Van Keer, H. (2006). Content analysis
schemes to analyze transcripts of online asynchronous discussion groups: A review.
Computer & Education, 46, 6-28.
Denzin, N.K. (1989). Interpretive Interactionism. Newbury Park, CA: Sage.
Foster, A. (2004). A nonlinear model of information-seeking behavior. Journal of the
American Society for Information Science & Technology, 55(3), 228-237.
Glaser, B.G., & Strauss, A.L. (1967). The Discovery of Grounded Theory: Strategies for
Qualitative Research. New York: Aldine.
Hsieh, H.-F., & Shannon, S.E. (2005). Three approaches to qualitative content analysis.
Qualitative Health Research, 15(9), 1277-1288.
Lincoln, Y.S., & Guba, E.G. (1985). Naturalistic Inquiry. Beverly Hills, CA: Sage
Publications.
Mayring, P. (2000). Qualitative content analysis. Forum: Qualitative Social Research,
1(2). Retrieved July 28, 2008, from http://217.160.35.246/fqs-texte/2-00/2-
00mayring-e.pdf.
Miles, M., & Huberman, A.M. (1994). Qualitative Data Analysis. Thousand Oaks, CA:
Sage Publications.
12
Minichiello, V., Aroni, R., Timewell, E., & Alexander, L. (1990). In-Depth Interviewing:
Researching People. Hong Kong: Longman Cheshire.
Neuendorf, K.A. (2002). The Content Analysis Guidebook. Thousand Oaks, CA: Sage
Publications.
Patton, M.Q. (2002). Qualitative Research and Evaluation Methods. Thousand Oaks,
CA: Sage.
Picasso, P. (1966). Quoted in Hélène Parmelin, “Truth,” In Picasso Says. London: Allen
& Unwin (trans. 1969).
Schamber, L. (2000). Time-line interviews and inductive content analysis: Their
effectivenss for exploring cognitive behaviors. Journal of the American Society for
Information Science, 51(8), 734-744.
Schamber, L. (1991). Users’ Criteria for Evaluation in Multimedia Information Seeking
and Use Situations. Ph.D. dissertation, Syracuse University.
Schilling, J. (2006). On the pragmatics of qualitative assessment: Designing the process
for content analysis. European Journal of Psychological Assessment, 22(1), 28-37.
Smith, H.W. (1975). Strategies of Social Research: The Methodological Imagination.
Englewood Cliffs, NJ: Prentice-Hall.
Tesch, R. (1990). Qualitative Research: Analysis Types & Software Tools. Bristol, PA:
Falmer Press.
Weber, R.P. (1990). Basic Content Analysis. Newbury Park, CA: Sage Publications.