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The Cognitive Perspective on Learning: Its Theoretical Underpinnings and Implications for Classroom Practices

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The Clearing House: A Journal of Educational Strategies, Issues and Ideas
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Abstract

Learning theories are essential for effective teaching in that they shed light on different aspects of the learning process. The spectrum of learning theories can be categorized into three main areas: behaviorism, cognitivism, and constructivism. Behaviorism as a teacher-centered instructional framework for a long time dominated educational settings, shaping every aspect of curriculum and instruction. In contrast to behaviorism, cognitivism is a relatively recent learning theory and its features are not well known or are confused with constructivism by teachers. This article aims to provide an overview of the core characteristics of cognitivism, its philosophical and theoretical basis, its implications for classroom practices, and its illustrative teaching methods. Cognitive apprenticeship, reciprocal teaching, anchored instruction, inquiry learning, discovery learning, and problem-based learning are explicated as the most distinctive methods of the cognitive perspective on learning.
The Clearing House, 84: 204–212, 2011
Copyright C
Taylor & Francis Group, LLC
ISSN: 0009-8655 print; 1939-912x online
DOI: 10.1080/00098655.2011.568989
The Cognitive Perspective on
Learning: Its Theoretical
Underpinnings and Implications
for Classroom Practices
KAYA YILMAZ
Abstract: Learning theories are essential for effective
teaching in that they shed light on different aspects of
the learning process. The spectrum of learning theo-
ries can be categorized into three main areas: behav-
iorism, cognitivism, and constructivism. Behaviorism as
a teacher-centered instructional framework for a long
time dominated educational settings, shaping every as-
pect of curriculum and instruction. In contrast to behav-
iorism, cognitivism is a relatively recent learning theory
and its features are not well known or are confused with
constructivism by teachers. This article aims to provide
an overview of the core characteristics of cognitivism,
its philosophical and theoretical basis, its implications
for classroom practices, and its illustrative teaching
methods. Cognitive apprenticeship, reciprocal teaching,
anchored instruction, inquiry learning, discovery learn-
ing, and problem-based learning are explicated as the
most distinctive methods of the cognitive perspective
on learning.
Keywords: cognitivism, cognitive learning theory, in-
structional frameworks, teaching methods
Familiarity with subject matter is not enough
for teachers to engage in effective and pedagogi-
cally meaningful instructional practices. This is because
professionalism in teacher education and development
demands that teachers have not only a disciplinary
knowledge base related to their subject but also a strong
command of learning theories and their applications for
instructional practices in the classroom. In other words,
teachers should possess both subject-matter knowledge
Kaya Yilmaz is at the College of Education, Marmara University, Istanbul, Turkey.
and pedagogical-content knowledge and skills to be
able to effectively accomplish their subject’s goals. They
also need to understand what philosophical assump-
tions and theoretical perspectives characterize a given
instructional framework without succumbing to the no-
tion that teachers first and foremost should be con-
cerned with day-to-day practical issues and problems
in the classroom rather than the theoretical ones that
are supposed to concern academics or theorists. This
artificial divide between the theoretical world and the
practical world in the eyes of teachers ought to be elimi-
nated if new and innovative reform efforts are to be put
into practice successfully in actual classroom settings
(Yilmaz 2008a). As Fosnot (1996) argues: “We again
run the risk of short-lived reform unless educators un-
derstand the theory behind the practice” (x).
There are a plethora of labels used to describe a variety
of learning theories. However, the typology of learning
theories can be classified into three main domains: be-
haviorism, cognitivism, and constructivism. As a dom-
inant approach to teaching, behaviorism provided the
primary theoretical bases of curriculum development
and implementation in schools for decades. The behav-
iorist approach was basically preoccupied with objec-
tively observable and measurable teacher and student
behaviors through a stimulus-response framework.
Even though behaviorism did explain how behaviors
got changed, it failed to account for how conceptual
change occurred. Because it does not explore men-
tal processes or what is going on in human minds,
cognitivism, and its varieties that view learning as
an active process of knowledge construction, came to
204
The Cognitive Perspective on Learning 205
compete with the behaviorist orientation. Cognitivism
now constitutes an alternative framework for teach-
ing. But, the cognitive perspective on learning is not
well-known by teachers. A review of recently published
works on educational psychology or teaching methods
indicates that teachers do not recognize how learning
is viewed or defined from a cognitive perspective (Yil-
maz 2008b). Hence, it is imperative that cognitivism be
given a full consideration to help teachers make sense
of it. Interested in addressing this need, this article aims
to elucidate the essential characteristics of cognitivism.
It explains the philosophical and theoretical basis of
cognitive learning theory and its implications for class-
room practices. Methods of teaching drawing on cogni-
tive principles are also explained.
Cognitivism
The genesis of cognitivism as a learning theory can
be traced back to the early twentieth century. The shift
from behaviorism to cognitivism stemmed from the be-
haviorist tradition’s failure to explain why and how in-
dividuals make sense of and process information (i.e.,
how the mental processes work). In other words, it was
the limitations of behaviorism that spawned the cogni-
tive movement. Dissatisfied with behaviorism’s heavy
emphasis on observable behavior, many disillusioned
psychologists challenged the basic assumptions of be-
haviorism. They claimed that prior knowledge and men-
tal processes not only play a bigger role than stimuli
in orienting behavior or response (Deubel 2003) but
also intervene between a stimulus and response (Winn
and Snyder 1996). It is argued that people are neither
machines nor animals that respond to environmental
stimuli in the same way (Matlin 1994).
The works of Edward Chase Tolman, Jean Piaget, Lev
Vygotsky, Jerome Bruner, and German Gestalt psychol-
ogists were instrumental in engendering the dramatic
shift from behaviorism to cognitive theories. Edward
Tolman is usually considered a pioneer in initiating the
cognitive movement (Bruner 1990, 2). In the 1920s,
Tolman’s experiment with rats suggested that rats knew
how the maze in which they were put was structured
because they had its mental map. Accordingly, Tolman
asserted that rather than an automatic response to an
event, behavior had both purpose and direction and
occurred without reinforcement. He saw motivation as
the key to transmuting expectations into behavior. For
these reasons, “Tolman’s system was often justly treated
as a precursor of contemporary cognitive psychology”
(Greenwood 1999, 9).
It was during the mid-1950s that the impact of cog-
nitive theories in education was so tremendous as to
be called the “cognitive revolution.” The second half of
the twentieth century witnessed an outburst of theoret-
ical and empirical works on such cognitive processes
as memory, attention, concept formation, and informa-
tion processing within a cognitive framework. This new
line of research is characterized by a search for new
ways to understand what learning is and how it occurs.
These cognitive psychologists investigated mental struc-
tures and processes to explain learning and change in
behavior. Like behaviorists, they have also observed be-
havior empirically but only in order to make inferences
about the internal mental processes. As opposed to be-
haviorist orientation’s emphasis on behavior, the cog-
nitive school focuses on meaning and semantics (Winn
and Snyder 1996). The primary emphasis is placed on
how knowledge is acquired, processed, stored, retrieved,
and activated by the learner during the different phases
of the learning process (Anderson, Reder, and Simon
1997; Greeno, Collins, and Resnick 1996).
The cognitive school views (1) learning as an active
process “involving the acquisition or reorganization of
the cognitive structures through which humans process
and store information” and (2) the learner as an active
participant in the process of knowledge acquisition and
integration (Good and Brophy 1990, 187; Merriam and
Caffarella 1999, 254; Simon 2001, 210). This theory
describes knowledge acquisition as a mental activity in-
volving internal coding and structuring by the learner
(Derry 1996; Spiro et al. 1992) and suggests that learn-
ing happens best under conditions that are aligned with
human cognitive architecture (Sobel 2001). Cognitive
psychologists place more emphasis on what learners
know and how they come to acquire it than what they
do. For this reason, the cognitive approach focuses on
making knowledge meaningful and helping learners or-
ganize and relate new information to prior knowledge
in memory. Instruction should be based on a student’s
existing mental structures or schema to be effective
(Ertmer and Newby 1993).
Contributors to the Theory: Major Types of Cognitivism
Cognitivism is not based on the works of a single
theorist or a unified group of theorists. Rather, it is in-
formed by a number of theorists’ contributions and is
quite multifaceted. The following theorists and accom-
panying theories have contributed to the continuous
growth of cognitive theories: Piaget’s theory of individual
cognitive development, Vygotsky’s theory of social cognitive
growth or zone of proximal development, Festinger’s cog-
nitive dissonance theory,Spiroscognitive flexibility theory,
Sweller’s cognitive load theory, Bruner’s cognitive construc-
tivist learning theory,andTolmanstheory of sign learning
as a bridge between behaviorism and cognitive theory.
Out of the spectrum of cognitive theories, the indi-
vidual cognitive trend deriving from Piaget’s studies
and the sociocultural trend based on Vygotsky’s works
constitute the backbone of cognitivism (Deubel 2003;
Duffy and Cunningham 1996; Fosnot 1996; Gillani
2003). Both theories have also been inspirational for
the subsequent constructivist movement (Fosnot 1996,
206 The Clearing House 84(5) 2011
23; Gillani 2003, 49). For this reason, rather than ad-
dress each ramification of cognitivism, I will document
the core ideas and assumptions of these two distinct
strands of cognitivism.
Piaget’s Theory of Cognitive Development
Piaget explored the genesis of cognitive structures and
the process that underlies learning and knowledge con-
struction. Trained as a biologist, Piaget later shifted his
interest to how human beings make sense of their en-
vironment and experience. The key notions that Piaget
employed to elucidate his cognitive theory basically de-
rive from biological concepts. According to Piaget, the
process of intellectual and cognitive development re-
sembles a biological act, which requires adaptation to
environmental demands (Gillani 2003). Having done a
large number of experiments to explore the ways chil-
dren think, Piaget argued that children do not passively
receive environmental stimulation. Rather, they actively
seek it, naturally exploring and acting on their world in
order to understand it (Bransford, Brown, and Cocking
2000, 80; Fox 2001). Piaget’s studies and ideas focused
on the mechanism of learning within the context of nat-
ural sciences instead of the type of logic that learners use
(Booth 1994; Fosnot 1996). He posited that the biolog-
ical maturation that human beings go through causes
distinct stages in cognitive development. Each of these
stages is sequential, dependent on one another to de-
velop, characterized by acquisition of discernable skills,
and reflects qualitative differences in cognitive abilities
(Fosnot 1996; Gillani 2003; Jarvis, Holford, and Griffin
2003; Piaget 1970).1
According to Piaget, the mechanism of change in cog-
nition is equilibration, which is a dynamic interplay
of progressive equilibria, adaptation and organization,
and growth and change in the master developmental
process (Fosnot 1996, 13–14; Ho 2004). Once encoun-
tered with a new learning situation, the individual draws
on his or her prior knowledge to make the new expe-
rience understandable (Gillani 2003). Experiencing a
new event, situation, or learning environment at times
engenders contradictions to one’s present understand-
ings, which in turn makes them insufficient and leads
to perturbation and a state of disequilibration in the
mental schemata (Fosnot 1996; Gillani 2003; Ho 2004;
Palincsar 1998). To handle this situation and to form a
comfortable state of equilibrium in the cognitive struc-
ture, the individual needs to modify or reorganize his
or her schemata via adaptation. This internal process
of restructuring the schemata is done through assim-
ilation and accommodation (Gillani 2003). While as-
similation is a process of integrating new information
with existing knowledge, accommodation is a process
of modification or transformation in existing cognitive
structures in response to a new situation. Once con-
fronted with an imbalance, learners may resort to three
kinds of accommodations. They may (1) disregard the
contradictions and adhere to their original scheme; (2)
vacillate by maintaining both theories simultaneously
and trying to cope with the contradiction via viewing
each theory as separate or specific cases; or (3) form a
new, modified notion to explain and resolve the prior
contradiction. In each type of response to contradiction,
the learner’s internal and self-regulatory behavior leads
to the compensations (Fosnot 1996, 16).
The concept of schema occupies a central place and
has an explanatory power in Piaget’s theory. Schema2
refers to a hypothetical mental structure for organizing
and representing generic events and abstract concepts
stored in the mind in terms of their common patterns.
They can be considered “as a series of interrelated index
cards that represent different environmental patterns in
one’s mental structure” (Gillani 2003, 50). Schemata
constantly get restructured as one encounters new pat-
terns in his or her learning experiences. Three processes
characterize the schemata acquisition and the changes
in existing schemata: (1) accretion, which refers to re-
membering new information on the basis of existing
schema without altering the schema; (2) tuning, which
happens when new information that does not fit the
existing schema causes schema to get modified in or-
der to be more compatible with experience; and (3)
reconstructing, which is characterized by the formation
of totally new schema on the basis of previous ones
that cannot accommodate new experience (Rumelhart
and Norman 1978). Implications of schema theory for
instruction can be summarized as follows:
Provide unifying themes for content, because
information that lacks a theme can be difficult to
comprehend, or, worse, the learner may “accrete” the
information to the wrong schema.
Provide a relevant context for learning in order to
activate an existing schema.
Develop and apply techniques for students to use to
impose structure on what they learn and thus make
it more memorable, such as the use of information
mapping or advance organizer.
Represent what the experts know in order to facilitate
the learning process and use case-based reasoning for
knowledge representation.
Make instructional material meaningful by iden-
tifying the learner’s mental model and providing
conceptual models invented by teachers, designers,
scientists, or engineers to help make some target sys-
tem understandable.
Choose texts with “standard” arrangement so that
they conform to student expectations.
Encourage students to read titles and headings.
Point out the structure of particular kinds of texts; for
example, what are the common features of published
research articles?
The Cognitive Perspective on Learning 207
Ask questions to determine what students’ current
schemata might be.
Pay attention to student answers and remarks that
may give clues about how they are organizing in-
formation; that is, what schemata are they using?
(Alexander 2003; Ho 2004)
Vygotsky’s Social Cognitivism
While Piaget attempted to study and explain learn-
ing in terms of the role of contradiction and equilibra-
tion, Vygotsky explained learning by means of dialogue
(Fosnot 1996). Another key difference between their
works is that while Piaget explored the development of
logical thinking, Vygotsky focused on categorical per-
ception, logical memory, conceptual thinking, and self-
regulated attention (Gredler 1997, 269). In contrast to
Piaget’s assertion that children’s development must pre-
cede their learning, Vygotsky posited that social learning
is likely to precede development. Vygotsky’s social cog-
nition learning model views culture as playing a key
role in the development of cognition. Vygotsky’ s study
of learning concentrated on the interplay between the
individual and society, and how social interaction and
language come into play in affecting learning or the de-
velopment of cognition (Fosnot 1996; Gredler 1997;
Jarvis, Holford, and Griffin 2003; Schunk 2004).
The following principles come to the fore in Vygot-
sky’s work (Fosnot 1996; Palincsar 1998): the general
law of genetic development,auxiliary stimuli, and the zone
of proximal development (ZPD). The general law of genetic
development states that every complex mental process
is first and foremost an interaction between people. The
auxiliary stimuli affects the mastery of one’s own be-
havior. That is, the individual can remember and think
in an innovative ways by means of auxiliary stimuli. The
ZPD is defined by Vygotsky (1978) as “the distance be-
tween the actual developmental level as determined by
independent problem solving and the level of potential
development as determined through problem solving
under adult guidance or in collaboration with more ca-
pable peers” (86). That is, the ZPD represents the po-
tential levels of development or what one can do with
assistance. It basically proposes that learning should be
compatible with the child’s level of development, and
interaction should orient instruction toward the ZPD
if it is to avoid lagging behind the development of the
child (Palincsar 1998).
ZPD stipulates that concepts are not in a ready-made
form for learners to absorb. Instead, they go through sig-
nificant development depending on the existing level of
the child’s ability to grasp the adult’s model (Fosnot
1996, 19). A child’s spontaneous concepts emerging
naturally from everyday experiences meet scientific con-
cepts evolving out of the structured activity of classroom
instruction as more formal abstraction and logically de-
fined concepts. For example, “Historical concepts can
begin to develop only when the child’s everyday con-
cept of the past is sufficiently differentiated—when his
own life and the life of those around him can be fit-
ted into the elementary generalization in the past and
now” (Vygotsky 1986, 194). Vygotsky’s work on social
cognition was further explored in subsequent works by
other psychologists who developed the notion of scaf-
folding (Fosnot 1996). The instructional implications of
Vygotsky’s social cognitive theory can be summarized
as follows:
Instruction should provide learners with authentic situ-
ations in which they must resolve dilemmas. From Vy-
gotsky’s perspective, the child has not yet learned to
operate at an entirely abstract level; thus, instruction
should focus on tasks and goals that are relevant to
the child. After all, according to Vygotsky, the very
origin of human thought is in socially meaningful
activity.
Instruction should lead (i.e., precede) development.In-
struction should be targeted at the “leading” edge
of the zone of proximal development. For example,
suppose a particular nine-year-old can solve most
arithmetic problems independently, can solve some
simple algebraic problems with guidance from a
teacher, and cannot solve calculus problems no mat-
ter how much help she is given. We would say that
algebra problems are within her ZPD, and that this is
the level at which instruction will be most profitable.
In an instructional setting, social “partners” should be at
different levels of development, and they should jointly
construct the problem solution. This helps to ensure that
the teacher or more advanced student can assist the
less advanced one, and that they will be operating
within his or her ZPD.
Individualized testing (which is generally the only kind we
do) can give only a partial picture of the child’s capabilities
because it fails to account for the ZPD (Perry 2002).
Implications of Cognitivism for Classroom Practices
Instruction based on cognitive principles should be
authentic and real. The teacher is expected to provide
a rich classroom environment that fosters a child’s
spontaneous exploration. Students are encouraged to
explore instructional materials and to become active
constructors of their own knowledge through experi-
ences that encourage assimilation and accommodation
(Wadsworth 1996). Teaching is tailored to the needs,
interests, and backgrounds of students (Fenstermacher
and Richardson 2005; McLeod 2003). The teacher is
more concerned with constructing a meaningful con-
text than directly teaching specific skills. From the cog-
nitive perspective, because students learn by receiving,
storing, and retrieving information, the teacher is urged
to thoroughly analyze and consider the instructional
208 The Clearing House 84(5) 2011
materials, proper tasks, and relevant learner characteris-
tics to help learners to effectively and efficiently process
the information received (McLeod 2003).
Instructional materials should include demonstra-
tions, illustrative examples, and constructive feedback
so that students can have mental models to embody. Be-
cause information contained in instructional material
is first processed by working memory, for schema ac-
quisition to occur instruction should be designed to re-
duce working memory load and to facilitate the changes
in the long-term memory associated with schema ac-
quisition (Sweller 1988). In order to activate and uti-
lize schema for learning, Barton states that the learner
should be “made aware of his background knowledge
and exposed to strategies to ‘bridge’ from pre-requisite
skills to learning objectives” (in McLeod 2003). The
teacher also is expected to have a set of schemata for
instructional activities in order to adroitly handle inter-
actions between disparate goals and activities. “These
schemata include structures at differing levels of gen-
erality, with some schemata for quite global activi-
ties such as checking homework and some for smaller
units of activity such as distributing paper to the class”
(Leinhardt and Greeno 1986). The teacher uses ad-
vanced organizer techniques to help students under-
stand and organize ideas, concepts, themes, issues, and
principles (Marzano 1998). Students are encouraged to
use metacognitive strategies such as goal specification,
process specification, process monitoring, and dispo-
sition monitoring (Marzano 1998, 127). To help stu-
dents process information effectively and efficiently, the
teacher needs to employ the following strategies and
principles when teaching their subjects:
Provide organized instruction. Make the structure and
relations of the material evident to learners through
concept maps or other graphic representations. In
multimedia instruction, present animation and audio
narration (and/or text descriptions) simultaneously
rather than sequentially.
Use single, coherent representations. These allow the
learner to focus attention rather than split attention
between two places, for example, between a diagram
and the text or even between a diagram with labels
not located close to their referents.
Link new material with what is currently known.This
provides a sort of mental “scaffolding” for the new
material.
Carefully analyze the attention demands of instruction.
Count the number of elements in instructional mes-
sages. Make sure that the learner will not attend to too
many different elements at the same time.
Recognize the limits of attention (sensory register).Help
learners focus their attention through techniques such
as identifying the most important points to be learned
in advance of studying new material.
Recognize the limitations of short-term memory. Use the
concept of chunking. Do not present 49 separate
items. Make them 7 groups of 7. Use elaboration and
multiple contexts.
Match encoding strategies with the material to be learned.
For example, do not encourage the use of mnemonic
techniques unless it is essential to memorize the ma-
terial. If you want it to be processed more “deeply,”
then find encoding strategies that are more inherently
meaningful.
Provide opportunities for both verbal and imaginal encod-
ing. Even though it is not clear whether these are actu-
ally two different systems, imaging does help students
remember.
Arrange for a variety of practice opportunities. The goal
is to help the learner generalize the concept, prin-
ciple, or skill to be learned so that it can be ap-
plied outside of the original context in which it was
taught. Provide for systematic problem-space explo-
ration instead of conventional repeated practice. Pro-
vide worked examples as alternatives to conventional
problem-based instruction.
Eliminate redundancy. Redundant information be-
tween text and diagram has been shown to decrease
learning.
Help learners become “self-regulated.” Assist them in se-
lecting and using appropriate learning strategies such
as summarizing and questioning (Perry 2002; Wilson
1995).
Basic characteristics of a classroom instruction based
on cognitive theories can be summarized as follows:
Emphasis on the active involvement of the learner in
the learning process (learner control)
Metacognitive training (e.g., self-planning, monitor-
ing, and revising techniques)
Use of hierarchical analyses to identify and illus-
trate prerequisite relationships (cognitive task anal-
ysis procedures)
Emphasis on structuring, organizing, and sequenc-
ing information to facilitate optimal processing (use
of cognitive strategies such as outlining, summaries,
synthesizers, advanced organizers, etc.)
Creation of learning environments that allow and
encourage students to make connections with previ-
ously learned material (recall of prerequisite skills;
use of relevant examples, analogies) (Ertmer and
Newby 1993)
Teaching Methods Based on Some Principles
of Cognitive Learning Theory
Cognitive apprenticeship, reciprocal teaching, an-
chored instruction, inquiry learning, discovery learning,
and problem-based learning are the most distinctive
The Cognitive Perspective on Learning 209
methods of teaching based on a cognitive perspective
on learning. These teaching approaches are explained
in the following sections.
Cognitive Apprenticeship
Cognitive apprenticeship is a method of helping stu-
dents grasp concepts and procedures under the guid-
ance of an expert such as the teacher. Its basic principles
lie in the works of Vygotsky, including his theory of
the zone of proximal development. This approach to
instruction is marked by the following phases of in-
struction.
Modeling: The teacher performs a task or explains a
process for students to observe, which helps them
understand what it takes to accomplish the learn-
ing task. Modeling provides students with the oppor-
tunity to generate conditionalized knowledge (i.e.,
when, where, and how to use knowledge to solve
problems of different kinds).
Coaching: While students do the same task, the teacher
observes students and provides hints, cues, feedback,
and help, if needed.
Articulation: Students are asked to think out loud
about how they performed the task and offer reasons
for the strategies that they used. Having students ar-
ticulate their implicit knowledge and strategies makes
them explicit. The teacher can detect whether students
have any misconceptions or use improper and inad-
equate strategies.
Reflection: Students retrospectively think of their per-
formance on completing the task and compare their
actions with the teacher’s or other students’ actions.
Exploration: The teacher urges students to identify a
problem, formulate a hypothesis, and seek needed
information to solve it. Students look at the different
aspects of the problem from different perspectives on
their own. This strategy is intended to promote stu-
dents’ ability to think independently (Collins, Brown,
and Newman 1989, 481–82; Wilson and Cole 1991;
Wilson, Jonassen, and Cole 1993).
Reciprocal Teaching
Reciprocal teaching is based on information processing
theory, a branch of cognitive learning theory. Palinc-
sar (1986), who developed this method together with
Brown, defines it as an instructional activity in the form
of a dialogue happening between teachers and students
about parts of text. The aim is to bring meaning to the
text in question to facilitate learning and understand-
ing. The teacher incorporates four strategies into the
dialogue by asking students to employ cognitive tech-
niques of summarizing, question generating, clarify-
ing, and predicting. Reciprocal teaching is composed of
modeling, coaching, scaffolding, and fading to achieve
instructional objectives especially in the area of read-
ing (Palincsar and Brown 1985; Palincsar 1986; Wilson
and Cole 1991). This method aims at promoting the
effort between the teacher and students or among peers
of students to make sense of the instructional materials
(Palincsar 1986; Saskatchewan Education 1997).
Anchored Instruction
Anchored instruction refers to designing and imple-
menting instruction around anchors (i.e., cases, stories,
or situations) that involve some kinds of case-study or
problem situation. As its name implies, anchored in-
struction anchors teaching and learning in realistic con-
texts by urging the teachers and students to formulate
and seek answers to questions (Bransford, Sherwood,
Hasselbring, Kinzer, and Williams 1990). It is essentially
problem-based and technology-supported learning in
which interactive videodisc materials serve as anchors
for the subsequent teaching and learning. Technology
tools facilitate students’ exploration of the subject mat-
ter. John Bransford is a pioneer in developing what came
to be known as anchored instruction. The Cognition and
Technology Group at Vanderbilt (1993) explains how
this method works:
The design of these anchors was quite different from
the design of videos that were typically used in edu-
cation. . . our goal was to create interesting, realistic
contexts that encouraged the active construction of
knowledge by learners. Our anchors were stories rather
than lectures and were designed to be explored by stu-
dents and teachers. (52)
Inquiry Learning
This teaching method grows out of Piaget’s theory
of cognitive development and resembles the scientific
inquiry method. The primary goal is to help students
develop their higher-order thinking skills by engag-
ing them in a process of either investigating an is-
sue or formulating and testing a hypothesis in order
to find solutions to a problem (Saskatchewan Educa-
tion 1997). Three types of reasoning especially under-
lie this approach. Learners engage in combinational,
propositional, and hypothetical-deductive reasoning to
successfully practice inquiry learning (Gillani 2003).
Combinational reasoning involves considering and
examining several different issues simultaneously
from different angles in order to solve a problem.
Propositional reasoning entails an examination of
assumption and proposition to solve problems.
Hypothetical-deductive reasoning requires a consider-
ation of different hypotheses in addressing a problem.
Instruction based on inquiry method is composed of
the following five phases:
210 The Clearing House 84(5) 2011
1. Phase One: Puzzlement or intellectual confrontation
by presenting students with the problem to create a
state of disequilibrium in their mind.
2. Phase Two: Students will hypothesize a reason for the
puzzlement.
3. Phase Three: Students will gather new information in
regard to the hypothesis. Then they isolate relevant
information and organize it based on some core con-
cept or theme.
4. Phase Four: Students analyze the data they have gath-
ered and organized, and they postulate a possible an-
swer for the hypothesis, which explains the original
puzzlement.
5. Phase Five: Students test their hypothesis as a possible
answer (Gillani 2003, 60–61).
While implementing this method of teaching, the
teacher first engenders a state of disequilibrium in stu-
dents’ minds by presenting a situation that is complex
and perplexing to students, and then provides students
with sources in the environment. Next, students are
asked to formulate and test a hypothesis about the in-
tellectual puzzlement by gathering and analyzing infor-
mation. Finally, students explain their answers to the
hypothesis. The whole process may take several days,
weeks, or months. Research findings report the effec-
tiveness of the inquiry approach for both elementary
and secondary students (Gillani 2003).
Discovery Learning
As is the case for inquiry learning, this teaching
method is informed by Piaget’s theory of cognitive de-
velopment. Ormrod (1995) defines discovery learning
as “an approach to instruction through which students
interact with their environment by exploring and ma-
nipulating objects, wrestling with questions and contro-
versies, or performing experiments” (442). As its name
suggests, discovery learning encourages students to dis-
cover principles and important relationships by engag-
ing them in such activities as asking questions, for-
mulating hypothesis, doing experiments and research,
and investigating a phenomenon (Schunk 2004, 244).
The way students manipulate and process information
is more important than the outcome or the product
students produce, such as finding a specific answer to
the question. Implementing discovery learning involves
identifying a problem, formulating a hypothesis, gath-
ering and analyzing data, and making a conclusion
(Gillani 2003, 62). As a pioneer in proposing the basic
principles of this approach, Bruner argued that discov-
ery learning inherently urges learners to take responsi-
bility for their own learning and helps them not only
remember important factual information but also de-
velop their high-order thinking skills (Gillani 2003).
The assumption behind this method is that when stu-
dents discover concepts by themselves rather than be-
ing told by the teacher, those concepts are likely to be
firmly stored in memory and consequently are more eas-
ily retrieved and activated later when needed (Ormrod
1995). Jansen and Culpepper (1996, as cited in Gillani
2003) have suggested some questions for facilitating
inquiry-based projects as follows:
What needs to be done?
What can I use to find what I need?
WherecanIfindwhatIneed?
What information can I use?
How can I put my information together?
How can I know if I did my job well?
To increase students’ understanding of contemporary
issues confronting society via discovery learning, the
following procedure is suggested: (1) identify and focus
on the issue, (2) establish research questions and pro-
cedures, (3) gather and organize data, (4) analyze and
evaluate data, (5) synthesize data, (6) plan for individ-
ual or group action, (7) operationalize the action plan,
(8) evaluate the action plan process, and (9) begin a
new inquiry (Saskatchewan Education 1997).
Problem-based Learning
Problem-based learning involves presenting students
with an ill-structured, open-ended, authentic or real-
life problem with many possible correct solutions and
asking them to find answers to that authentic problem.
As opposed to traditional instruction that teaches facts
and skills first and then introduces the problem, this
method introduces the problem at the very beginning of
instruction on the basis of what students already know
(or students’ existing knowledge) and teaches facts and
skills in a relevant context. Rather than a well-structured
set of resources, this approach provides students with
access to substantial resources for research. To practice
this method, the teacher follows these steps:
Students are divided into groups
A real problem is presented and discussed
Students identify what is known, what information is
needed, and what strategies or next steps should be
taken
Individuals research different issues and gather re-
sources
Resources are evaluated in a group
The cycle repeats until students feel that the problem
has been framed adequately and that all issues have
been addressed
Possible actions, recommendations, solutions, or hy-
potheses are generated
Tutor groups conduct peer and self-assessments (FDI
2002)
The Cognitive Perspective on Learning 211
Conclusion
A wide variety of learning theories can be classified
on a continuum in terms of whether they place the
teacher and overt behaviors or the learner and internal
mental processes at the center of instruction. While one
end of the continuum represents behaviorism, the other
end of the continuum represents cognitivism and con-
structivism. Whereas behaviorist theoretical framework
characterizes the underpinnings of teacher-centered in-
struction, cognitive and constructivist perspectives come
into play in shaping learner-centered instruction. It is
now commonly suggested that rather than behavior-
ism, cognitivism and its accompanying teaching meth-
ods should be integrated into teachers’ instructional
agendas. Teachers are expected to teach their subject
in accordance with the principles of cognitive learning
theories. New curriculum programs urge them to em-
brace and practice those teaching approaches that pay
attention to individual differences in students’ cognitive
structures or previous knowledge bases in order to help
students integrate new knowledge with the knowledge
they already have. Omnipresent in new curriculum de-
velopment is the notion that teachers do their best to
find innovative ways that not only facilitate but also op-
timize students’ learning to the greatest extent possible.
Because cognitivism is concerned with illuminating how
the process of learning occurs in different contexts by of-
fering strategies that promote students’ learning, teach-
ers can benefit from this invaluable learning paradigm
in their effort to help students attain the subject’s goals.
Notes
1. The implications of Jerome Bruner’s theory of learning for
instruction resemble those of Piaget in some respects (e.g.,
teaching new concepts to students via enactive, iconic, and
symbolic presentations).
2. Bartlett is the originator of the notion of schema in the early
1930s.
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ames Greeno has written a reply to our recently pub- lished challenge (Anderson, Reder, & Simon, 1996) to the soundness of ma n y educational implications that ave been drawn from the "situated learning" move- ment. Greeno's response (p. 5, this issue) has largely taken the discussion onto a more abstract plane rather than dis- p u t i n g our recommendations for educational practice. Along with his meta-level discussion, he has described several results and ma de a number of comments that help to clarify the educational issues. Greeno acknowledges the persuasiveness of our evi- dence for our findings and reco~n~endatf6~ns, and agrees that there is a consensus between the cognitive and situ- ated perspectives on certain important educational issues. So we want to begin our response by emphasizing those issues on which we all seem to be in a ~ 1. Learning need not be bound to t h e ~ s i t u a t i o n of its application, i n s t r u c t ~ - ~ e n g ~ 6 ~ e ~ fr0-m the classroom to "real world" situations. Greeno cites a list of studies from the situated camp which are consistent with this conclusion. We no longer have to contemplate aban- doning the classroom but can focus our attention on those factors that promote transfer from one situation to other situations. Our original paper contained pointers to the abundant research in cognitive psychology describing and examining these factors. 2. Knowledge can indeed transfer between different sorts of tasks. Again Greeno Cites situated papers which, if they do not provide new evidence for this proposition, at least accept it. Thus, we can aspire to see mathematics ed- ucation transfer to science, engineering, and jobs which require it. We need not teach every different competence anew. Again, our original paper provided references to the very powerful empirical and theoretical base that has de- veloped in cognitive psychology for understanding such transfer. 3. Abstract instruction can be very effectiv e a n d one need not teach everything in concrete, almost vocational settings. Greeno points out some looseness in our use of the terms "concrete" and "specific." If we caused any con- fusion we apologize, but apparently it is not in dispute that real value is to be found in the abstractions that students are taught in school. Again, the issue is how one makes abstract instruction effective, and again we cited cognitive
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