Applying
Theory and Research
The
following presents findings extracted from scholarly works that address
learning theories' applications for resolving worldwide dilemmas related to
human-welfare issues. Human-welfare
issues relate to societies, cultures, ethics, economies, governance, and
communications. The information from
existing research answers the manner in which learning theories guide
instructional strategies for post-secondary e-learning. Also included are examples of learning
theories applied within learning environments, and assessments of the
appropriateness of those theories.
Applying Learning
Theories to Guide Instructional Practice
Christensen
(2008) wrote that every learning setting includes learning goals that require
instructional strategies specifically focused toward achieving each goal. Consequently, each goal requires one or more learning
theories tied to learning strategies. Organizing
the dozens of learning theories into succinct categories aids an instructor's
decision-making required for each learning setting. Christensen (2008) explained that four
categories aid instructors in designing teaching activities as each learning
setting arises. The "behavioral,
information processing, psychological/individual constructivist, and
social/situated constructivist views" (Christensen, 2008, p. 27) represent
such categories.
An
example of an instructor's learning theory selection process for guiding
students in solving a problem related to a current societal issue may combine
the social constructivist and behaviorist learning theories (Christensen,
2008). Combining these theories presents
learning activities wherein students co-construct knowledge via learning teams,
and the instructor uses motivational strategies from the behaviorist theory in
connection to the learning activities by providing extra points for exceptional
teamwork (Christensen, 2008).
Christensen
(2008) provided insight regarding designing instruction based upon one or more
instructional issues such as training, preparation, and education. The appropriate learning theories for
training learners who need improvement or an upgrade in computer skills could use
Bloom's mastery learning model, Skinner's program instruction, or Keller's personalized
systems of instruction (Christensen, 2008).
Combining theories to transition learners from training to preparation
provides instructors with an opportunity to teach learners "critical
prerequisite concepts necessary for performing a job" (Christensen, 2008,
p. 30). Applying learning theories such
as "Ausubel's meaningful reception learning or Gagné's theory of instruction"
(Christensen, 2008, p. 30) supports this transition.
Finally,
if the instructional problem requires further learning, such as working
cooperatively in teams while solving work problems, learning theories added to
the previous two stages could include "Schank's goal-based scenarios,
Savery and Duffy's problem-based learning, or Michaelsen's team-based learning"
(Christensen, 2008, p. 30). The
instructor includes considerations of "time, cost, and contextual
constraints" (Christensen, 2008, p. 30).
By selecting theories that can achieve maximum learning, achievement of instructional
goals increases exponentially.
A
study by Hamat and Embi (2010) indicates that the constructivist learning
theory represents the philosophy applicable to a set of several learning
theories. From a learner's perspective,
the set involves constructing knowledge.
From an instructor's perspective, the set requires supporting learners
as knowledge is constructed. The four
principles embodying constructivism explain that learners' interfaces with the
environment and experiences provide deconstruction and
reconstruction of the learning matter using "assimilation and accommodation"
(Hamat & Embi, 2010, p. 238). As
learners accommodate the reconstruction process, a "higher level theory or
logic" (Hamat & Embi, 2010, p. 238) occurs. Constructivism's third principle explains
that student learning derives via "investigation, predicting, imagining,
manipulation of information and invention" (Hamat & Embi, 2010, p.
238). Reflection occurring during the
development of learner's constructs focuses upon resolving conflicts (Hamat
& Embi, 2010).
Important Issues Attributable
to Applying Learning Theories to Practice
Nworie
and Haughton (2008) remarked that online instruction has posed new issues for
teachers due to disruptions from learning caused by "instant messaging,
computer games, web surfing, and personal projects" (p. 52), which adversely
impacts an effective application of learning theories. Furthermore, instructors, and students
develop technological skills at varying levels.
Even as instructor's intentions for improving learning via new and
quickly changing technologies persist, such changes impede rather than construct
learning.
The
Law of Unintended Consequences explains that unexpected effects that accompany
change cause unanticipated negative or positive results (Nworie & Haughton,
2008). The introduction of new
e-learning tools cause such effects. Unanticipated
results caused by "ignorance, error, immediacy, basic values, and
self-defeating prophecy" (Nworie & Haughton, 2008, p. 54) arise from
instructors who fail to fully examine and comprehend the implications of using
new technologies.
Consequently,
sustained by standard operating procedures, instructors roll out previously
used teaching strategies without allowing for disruptions to learning
theories. Not reflecting upon possible
unintended consequences marginalizes learning.
As instructors increasingly convert teaching strategies to the online
class, budgeting restrictions and development creates new issues that require
revisions in the selection of appropriate learning theories (Nworie & Haughton,
2008). Evolution conflicts with
sensitive equilibriums inherent within instructional systems and processes.
Gijbels,
Segers, and Struyf (2008) investigated
if a constructivist learning episode shifted learners into deeper learning. In addition, Gijbels et al. (2008) examined
students' perceptions of increasing assessment demands. Learners were differentiated by either a
restricted or variable learning approach (Gijbels, Segers, & Struyf, 2008),
which impacted transitions to higher or lower surface learning. The study by Gijbels et al. (2008) disclosed
that increased deep learning was not achieved in a "constructivist
learning and assessment environment" (p. 435).
Specifically, the restricted learning
approach demonstrated a low variability in both deep and surface learning
attributes. Conversely, the variable
group demonstrated high variability in deep and surface learning attributes. Therefore, the depth of learning approaches
was affected by learners' perceptibility, and limited an ability to change
learning approaches. The constructivist
learning theory states that knowledge is actively constructed by the learner. Apparently, instructors should consider the
study by Gijbels, Segers, and Struyf (2008) before applying the constructivist
learning theory because inconsistent deep learning arises during active
knowledge construction. However, there is one caveat for instructors
to consider, which is that Gijbels et al. (2008) suggested that their study's
results needed further examination to strengthen validity.
Snyder
(2010) taps into the impact that constructivism bears upon instructional-design
theories, which guides the selection of instructional methods. Instructors who present "authentic
learning scenarios and problems" (Snyder, 2010, p. 50) to learners proffer
new information. The new information merges
with learners' current understanding and experiences, and results in knowledge
construction. Presenting authentic
learning is by no means easily mastered, and some instructors are more
challenged than others.
Therefore,
"meaningful and transferable learning" (Snyder, 2010, p. 50) occurs
at varying degrees from little to nearly limitless amounts. In addition to the challenges faced by
instructors, students at various levels in the construction process act
differently to new knowledge and fail to resolve "physical, mental, or
social dissonance" (Snyder, 2010, p. 50).
Skilled instructors sense such breakdowns in knowledge creation, and can
anticipate and provide supportive information to prevent such issues. Because students require improved electronic proficiencies
to create solutions to the growing number of complex problems, an instructor's
responsibility for recognizing, researching, and devising methods that enrich
learners' constructive processes continues to increase.
Examples of the
Constructivist Learning Theory Applied
Gijbels,
Segers, and Struyf (2008) tested previous researchers' empirical work in a
non-constructivist learning environment.
The previous work concentrated upon students' intended and actual
approaches to learning as new assessment methods were integrated (Gijbels,
Segers, & Struyf, 2008). The study
intention of Gijbels et al. (2008) focused upon determining if a constructivist
learning environment for education students altered learning approaches when provided
with assessment requirements. Apparently,
a commonly accepted concept by instructors explained that students employ
"surface and deep approaches" (Gijbels et al., 2008, p. 432) according
to assessment demands.
A description of the methodology
used by Gijbels, Segers, and Struyf (2008) included an instructional goals-linked
constructivist learning environment that blended active learning with
assessments that provided the students with "guided self-study, activating
lectures, two authentic group assignments, and two individual assignments"
(p. 435). Because the essay's focus is
presenting application of the constructivist learning theory, the study
findings by Gijbels et al. (2008) note only that learners do not change
learning approaches toward deeper learning.
In addition, the article represented examples of the manner in which the
constructivist learning theory was applied during an empirical research
project.
Gijbels, Segers, and Struyf (2008) recommended
that instructors reflect upon learners' variability in learning approaches
before using the constructivist theory.
For example, Gijbels et al. (2008) suggested that learners may require
extra time to become accommodated to learning approaches, which provides a
buffer so that instructors can aid learners in adapting. In response to the need for a buffer,
Lucariello (2012) suggested initiatives to instructors rolling out new learning
concepts and theories. For example,
instructors' initiatives should provide learning opportunities that students
perceive as "plausible, high-quality, intelligible, and generative"
(Lucariello, 2012, para. 3). Group discussions
require learners' access to personal knowledge during the preparation of verbal
responses (Lucariello, 2012). Other initiatives
included "model-based reasoning, diverse instruction, raising student
metacognition, and epistemological thinking" (Lucariello, 2012, para. 3).
Koohang, Riley, Smith, and Schreurs (2009)
presented three components of constructivism in an e-learning model, which
warrants a review due to the article focusing upon teaching business students
online, which is part of the aforementioned specialization. Koohang et al. (2009) presented several
examples of their model in practice, and summarized 18 characteristics of the
constructivist theory. The model's three constructivist components
included the "design of learning activities, learning assessments, and
instructor's roles" (Koohang, Riley, Smith, & Schreurs, 2009, p.
94).
Designing learning activities
referred to elements that embodied fundamental and collaborative designs
espousing learning activities such as "collaboration, cooperation,
multiple perspectives, real world examples, scaffolding, self-reflection,
multiple representations of ideas, and social negotiation" (Koohan, Riley, Smith, & Schreurs, 2009, p.
94).
Instructors explained to learners that using "experiences
and/or knowledge" (Koohang et al., 2009, p. 95) encouraged
"interrelatedness and interdisciplinary learning" (Koohang et al.,
2009, p. 95). Consequently, the learning
situation challenged learners to assimilate new knowledge that additionally
pushed learners beyond their comfort levels (Koohang et al., 2009).
The second component referred to
elements explained as the learning assessment, which advocated assessments
for the "instructor, learner collaboration, and self" (Koohang, Riley, Smith, & Schreurs, 2009,
p. 94). The third component portrayed
as instructor's roles included "coaching,
guiding, mentoring, acknowledging, providing feedback, and assessing student
learning" (Koohang et al., 2009,
p. 94). The students
participating in the study by Koohang, Riley,
Smith, and Schreurs (2009) were not informed of the model's use although
feedback to students encompassed all components of their model. Withholding the model's information could
imply that Koohang's et al. (2009) team wanted responses driven by the learners
rather than the learners attempting to second guess what the instructor might
be seeking.
One of the
assignments designed by Koohang, Riley,
Smith, and Schreurs (2009) included an assignment for the e-learning
business students. Specifically, the
assignment stipulated that learners investigate an actual knowledge management
(KM) business. Learners were required to
investigate the online company's management and "improve its key
performance indicators such as page views, server load, network traffic, and
transactions per second" (Koohang Riley,
Smith, & Schreurs, 2009, p. 96).
The instructor communicated the reading and writing assignment to the
students, which required "clear, concise, and persuasive" (Koohang et
al., 2009, p. 103) responses.
Santally
et al. (2012) questioned if e-learning could evolve with constructivism (a.k.a.
socio-constructivism) as a new paradigmatic learning framework, and discussed
possible implications for teaching and learning applications. Santally et al. (2012) proffered principles
for designing a learning system grounded in the constructivist learning theory that
included:
Learning (that) should be internally
controlled and mediated by the learner…(focusing) on realistic approaches to (solve) real-world problems…fostering
reflective practice… …presenting
authentic tasks…(enabling) context-and content dependent knowledge construction…(and) supporting
collaborative construction of knowledge through social negotiation. (p. 13)
Santally's
et al. (2012) project confirmed the application of the principles noted above. For example, participants' remarks revealed (a)
controlled learning; (b) that the design and teaching approaches sustained
learners' focus by embracing "realistic and…creative approaches"
(Santally et al., 2012, p. 13); (c) that learning journals demonstrated levels
of efficiency and effectiveness that cultivated deep, reflective thinking; and (d)
that authentic learning tools supported learning and application of new
knowledge in various learning scenarios, such as in discussion forums and
Facebook.
Peng, Su,
Chou, and Tsai (2009) attempted to conceptualize a constructivist framework for
wireless mobile learning (m-learning). Technologies have emerged as
"intellectual partners, or mind tool(s)" (Peng, Su, Chou, & Tsai,
2009, p. 179) that augment constructive learning. For example, learners increasingly choose
e-tools and other electronic devices according to their potential learning
value. Also, potential learning values
materialize as learners take advantage of accessing the Internet from any place
at anytime with ever-increasing numbers of people and resources. The most important impact upon knowledge
construction that m-learning provides that differs from wired technologies includes
"convenience, expediency, and immediacy" (Peng et al., 2009, p.
174). Learners and instructors alike are
increasingly challenged to learn as much and as quickly as possible how to maximize
the utility of m-tools for knowledge construction.
Martens, Bastiaens, and Kirschner
(2007) discussed the pressures from "constructivism, information, and
communications technology on learning" (p. 81). A study by Martens et al. (2007) using a constructivist
e-learning environment (CEE) involved comparing the learning expectations of
the study's developers to students' actual learning experiences. The developers expected that if students were
provided with a badly constructed assignment, students would be motivated to
re-interpret the assignment, and in so doing, develop the skills required to
find solutions (Martens, Bastiaens, & Kirschner, 2007). Instead, students easily reconstructed the
assignment, and unchallenged, found solutions using surface thinking. Consequently, the developers wrongly
anticipated students' reactions to the assignment although the students
appreciated the challenge.
Martens,
Bastiaens, and Kirschner (2007) concluded
that although CEEs are used for generic students, instructors and researchers
need to be more cognizant of the combined effects from learners'
"characteristics, study outcomes, and appreciation of CEEs" (p.
90). Developers and instructors must
additionally acknowledge that an activity may seem to align with the
constructivist theory when learners' perceptions of the activity does not align
with the theory's activity. Students'
learning outcomes cannot be successful if a CCE does not assist learners in visualizing
a bridge for constructing new knowledge.
Appropriate Uses of the Constructivist Learning Theory
Gijbels,
Segers, and Struyf (2008) suggested their study's results needed re-examination
to strengthen validity because their study was the first of its kind. Gijbels et al. (2008) found that executing constructivist learning, and an assessment environment
did not result in students employing a deep learning approach. By not presenting an activity that challenged
learners, most students used surface learning techniques, which did not
motivate learners to construct new knowledge for problem-solving. Gijbels et al. (2008) additionally found that
if students did not perceive that an activity and its assessment was difficult,
knowledge construction was impaired. Consequently,
Gijbels et al. (2008) did not sufficiently apply the constructivist learning
theory, which resulted in learners not constructing new knowledge.
The study by Martens, Bastiaens, and Kirschner (2007) somewhat
mirrored the study by Gijbels, Segers, and Struyf (2008) because learners'
perceptions impacted their research project.
Martens et al. (2007) did not appropriately apply the constructivist
learning theory as seen in their unsuccessful attempt to use the theory to
activate construction of learner's knowledge.
Research projects frequently ask questions that require purposely
testing hypotheses using learning theories.
As a means to conduct a test, unexpected coincidental results may
occur. However, in the case of the
research project by Martens et al. (2007), the study's unexpected outcome was
due to failure in addressing generally accepted concepts known about the
constructivist learning theory. Martens
et al. (2007) did not design their activity fervently enough to motivate the
students because the team relied upon their perceptions instead of the students'
perceptions.
The article by Koohang, Riley, Smith, and Schreurs (2009)
discussed above noted that the intention of the writers was to use students'
feedback for their study. Appropriately,
the writers filed paperwork to an IRB, and the IRB approved the project's
application as written. The application provided
a process to assure the study's participants that their answers would be confidential. Koohang et al. (2009) accomplished a sound
literary review, which supported the constructivist theory's principles within
their model. However, Koohang et al. (2009)
did not include literature that contradicted or challenged the authors'
findings. Researchers have an obligation
to present unsupportive literature as much as supportive literature.
Koohang, Riley, Smith, and Schreurs (2009) noted that their model was designed and presented in an earlier work by Koohang. The model was applied in each case study presented in Koohang et al. (2009). A wise recommendation by Koohang et al. (2009) included that other researchers test their model to determine if the model could be improved. However, Koohang et al. (2009) did not recommend an empirical study by other researchers, which would test the model's reliability and validity. Because Koohang et al. (2009) mentioned that the design of the model occurred before his team performed the case studies, this writer takes an objection to Koohang et al. (2009) retrofitting the students' feedback to the model's conceptual theories, which included the constructivist learning theory.
By retrofitting participants'
feedback to a research model, some researchers could choose to modify feedback
to fit their desired research outcomes.
In fact, others less familiar with the model may have accepted that the
design represented an "advantage (when used) in e-leaning environments"
(Koohang, Riley, Smith, & Schreurs,
2009, p. 92). Koohang, Riley, Smith, and Schreurs (2009) fitted
feedback to the model. Subsequently,
Koohang et al. (2009) declared that the model integrated all of the
constructivism elements because feedback referred to each element. Koohang et al.'s (2009) retrofitting probably
biased the study, and invalidated the study's findings.
Curious if Koohang had conducted an
empirical study after the 2009 article, the author responded to an inquiry on
November 1, 2012. Indeed, Koohang
published another article but did not conduct a scientific study of his
model. Instead, Koohang's purpose in his
2012 article was to advance concepts relative to the learning model presented
in his previous 2009 article (Koohang, 2012).
Koohang (2012) indicated that the model was tested twice since 2009 and would
be published in 2012. Four years post
the model's introduction, instructors employing the model by Koohang, Riley, Smith, and Schreurs (2009) may
already know if the model helps or hurts learning.
Santally
et al. (2012) based recommendations upon a wealth of literature but did not
include a scientific test of their model.
Remarks by Santally et al. (2012) indicated their learning model provided
"a new dimension to the conception of online distance learning courses"
(p. 13). However, the claim by Santally
et al. (2012) is concerning because they sought to dispel criticism rather than
conduct an empirical study that may have supported their integrated learning
model. If Santally et al. (2012) chose
not to do an empirical study because they sensed such a study would not support
their model, questionable ethical behavior could exist.
The
article by Santally et al. (2012) discussed two e-learning methodologies useful
for achieving productive learning outcomes.
Santally et al. (2012) combined methodologies with e-tools such as an
"e-book approach, rapid e-learning techniques, and online activity-based
instructional design" (p. 13). Santally
et al. (2012) remarked that (a) constructivist supporters thought that the
e-book learning approach merely dumps more information onto the electronic
global information network rather than adding value to learning, and (b) rapid
e-learning reduces interactions between the instructor and learner.
The
differences between the first and second teaching method is that the first
model presents learning resources such as "e-books, interactive quizzes,
and exercises" (Santally et al., 2012, p. 10) for use in completing individual
or group assignments. The second model progressively
adds resources relevant to the activities, and includes a more active instructor
role. Both teaching methods employed constructivist principles that supported
learner control, focused upon authentic problems needing reflection and
resolution, provided "context and content dependent knowledge
construction" (Santally et al., 2012, p. 10) while working with other
learners.
Santally
et al. (2012) remarked that his approach created a new paradigm for e-learning
that addresses criticisms of learning platforms, and provides a focus on the "educational
transaction" (p. 13). Unfortunately
for the reader, Santally et al. (2012) did not scientifically test their
proposed methods. Because Santally et al. (2012) failed to test
their proposed models, judgment of their models' value is untenable.
Peng, Su,
Chou, and Tsai (2009) discussed a constructivist framework for wireless mobile
learning (m-learning). Technologies, in
general, have emerged as "intellectual partners, or mindtool(s)"
(Peng, Su, Chou, & Tsai, 2009, p. 179) that augment constructive
learning. For example, learners and
instructors increasingly choose e-tools and other electronic devices according
to their potential learning value (Peng et al., 2009). Significant learning materializes as learners
take advantage of accessing the Internet from any place at anytime with
ever-increasing numbers of people (Peng et al., 2009).
Apparently,
the most important effect from m-learning that differs from wired technologies
relative to constructing knowledge are "convenience, expediency, and
immediacy" (Peng, Su, Chou, & Tsai, 2009, p. 174). Learners and instructors alike are
increasingly challenged to learn quickly and completely as well as adapt the
processes required of knowledge construction that maximize the utility of
m-tools. Other emerging challenges
include competing learning technologies that confuse students and instructors
alike, depletion of the available time for learning, and depression of
instructor-activated creativity as learning activities are designed (Peng et
al., 2009).
Peng, Su,
Chou, and Tsai (2009) suggested that researchers interested in investigating
the efficacy of advancing technologies such as m-learning to enlighten
constructivist learning environments use their article's information. There are countless numbers of such articles
that summarize others' works, and propose new concepts. However, without including a scientific study
to test the reliability and validity of conceptual recommendations, using such
a recommendation is difficult.
Conclusion
Exploring
the application of learning theories in scholarly works leads to new
discoveries for resolving worldwide dilemmas related to human-welfare issues. These issues include problems related to
societies, cultures, ethics, economies, governments, and communications. The information from existing research
answered the manner in which learning theories guided instructional strategies
for post-secondary e-learning. Also
included were examples of learning theories applied within learning
environments, and assessments of the appropriateness of those theories.
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