Technology For Teaching And Learning 1 PDF

Summary

This document details different models of technology-enhanced instructional lessons such as Dale's Cone of Experience and TPACK. It explains different categories of learning experiences and the importance of using different materials and mediums to maximize learner experiences. The document also includes a discussion of Bloom's Digital Taxonomy and learning theories.

Full Transcript

**TECHNOLOGY FOR TEACHING AND LEARNING 1**

**Topics:**

Edgar Dales Core of Experience

TPACK

SAMR

Bloom's Digital Taxonomy

The assure Model, and Model of Technology- Enhanced Instructional Lesson

**[EDGAR DALE'S CONE OF EXPERIENCE]**

Dale's Cone of Experience showcases how we can use a variety of
materials and mediums to maximise learner experiences. It was developed
to show the difference on how learners retain information. Dale
categorized the modes of learning experiences into three modes; Learning
by Doing, Learning through Observation and Learning through
Abstractions.

**3 Categories:**

- First we have Learning by doing is a theory that places heavy
emphasis on student engagement and is a hands-on, task-oriented,
process to education. The theory refers to the process in which
students actively participate in more practical and imaginative ways
of learning.

- Second, observational learning is the process of learning a new
skill or task by watching others performs the same task. Albert
Bandura (1925 - 2021) was the psychologist who introduced the social
learning theory in 1977. In social learning theory, Bandura
explains, people learn from what they see.

- Third, Abstraction in learning is the process of taking away or
removing certain characteristics of a complex problem to reduce it
to its most essential components. This helps to simplify or break
down the problem to make it easier to resolve.

**The Cone of Experience**

In his first edition of Audiovisual Methods in Teaching (1946), Dale
introduced the 'Cone of Experience'. The Cone placed different
educational media and methods in a continuum from the most concrete
experiences at the bottom to the most abstract at the top.

When a learner moves from direct and purposeful experiences to verbal
symbols, the degree of abstraction gradually grows. And as a result,
learners become spectators rather than participants.

Learners can see, handle, taste, touch, feel and smell the most
purposeful experiences. By contrast, verbal symbols, such as use of
words, speech or auditory language, at the peak of the Cone are highly
abstract. This means they do not have a physical resemblance to the
objects or ideas in question.

As such, the Cone of Experience explains the interrelationships of the
various types of media and their individual 'positions' in the learning
process. This makes it a valuable tool that helps instructional
designers and L&D professionals incorporate the right audiovisual
materials into their classroom or online training interventions.

The peak of the Cone displays the most abstract experiences, which are
represented with limited degrees of realism by symbols. These include
visual and verbal symbols, like listening to the spoken word.

As such, the arrangement of the levels in the Cone is not based on its
difficulty. Instead, it focuses on abstraction and the number of senses
involved. Instructional designers can mix and interrelate these
experiences to foster more meaningful learning.

11\. Verbal Symbols

Verbal symbols are highly abstract as they bear no physical resemblance
to the objects or ideas they stand for. In fact, these verbal symbols
provide no visual representation or clues to their meaning.

10\. Visual Symbols

The other highly abstract level includes visual symbols, such as charts,
maps, graphs and diagrams that are used for conceptual representation.
These visual symbols help to make just about any reality into something
easier to understand.

9\. Recordings, Radio and Still Pictures

Edgar Dale first created this model in 1946. As such, he included the
multimedia assets of his time, such as recordings, radio and still
pictures. In more modern terms, this level could include photos,
podcasts or audio files.

8\. Motion Pictures and 7. Educational Television

Most recent publications combine levels eight and seven into one
category. After all, motion pictures and television are similar mediums.
They enable learners to process real-life processes or events through
on-screen recordings.

6\. Exhibits

The sixth level of Dale's Cone of Experience moves us away from the most
abstract experiences. This is the first level that opens the door for an
expanded range of sensory and participatory experiences.

As a result, this experience allows learners to see the meaning and
relevance of things based on the different pictures and representations
presented. Visiting exhibits in educational outlets like museums are a
common way to provide learning opportunities.

After all, exhibits are a great way to present students with exposure to
new ideas, discoveries and inventions that would be more difficult to
display in a classroom setting.

5\. Study Trips

Study trips offer the sights and sounds of real-world settings. The main
activity focuses on observing from the sidelines, aside from occasional
opportunities to participate. Participation could include, for instance,
hopping in a fire truck or milking a cow.

These rich experiences help learners to learn more about different
objects, systems and situations. As such, study trips provide an
opportunity to experience something that learners cannot be encounter
within the traditional classroom space.

In addition, students can see connections between their training
experiences and the 'real world'. This type of elaboration is known to
be an effective learning technique.

4\. Demonstrations

A demonstration is a visualised explanation of facts, ideas or
processes. They are a common way to train employees or students, as they
require relatively little preparation and resources. After all,
individuals observe a lot simply By watching others.

On top of that, demonstrations can include pictures, drawings, film and
other types of media in order to facilitate clear and effective
learning. This approach helps to showcase how individuals can complete
these tasks in real life.

3\. Dramatised Experiences

Dramatised experiences can be seen as role-play exercises. This means
reconstructing situations for learning purposes. As a result, the third
level involves shifting learners --- at least some of them --- from
observers to active participants.

2\. Contrived Experiences

The second level is called contrived experiences, which focuses on the
'editing' of reality. At this level, teachers use representative models
and mock-ups to provide an experience that is as close to reality as
possible.

This can make the concept easier to grasp. After all, some realities are
far too complex to take in all at once. As such, contrived experiences
are imitations that sometimes teach better than the realities they
imitate.

1\. Direct Purposeful Experiences

The bottom level of Dale's Cone of Experience is also the least
abstract. Direct purposeful experiences are hands-on activities that
grant us responsibility for driving a specific outcome. We are active
agents in the learning experience. In a sense, direct purposeful
experiences are an unabridged version of life itself.

These rich, full-bodied experiences can be considered the bedrock of all
education. After all, learners can see, handle, taste, feel, touch and
smell these experiences. As such, at this level, learners use more
senses in order to build up their knowledge.

Learners learn by doing tasks themselves. As a result, learning happens
through actual hands-on experiences.

**[TPACK]**

**(Technological Pedagogical Content Knowledge Framework)**

The TPACK framework builds on Shulman's, 1986)
descriptions of PCK to describe how teachers' understanding of
educational technologies and PCK interact with one another to produce
effective teaching with technology. Other authors have discussed similar
ideas, though often using different labelling schemes. The conception of
TPACK described here has developed over time and through a series of
publications, with the most complete descriptions of the framework found
in Mishra and Koehler (2006) and Koehler and Mishra (2008).

**THREE MAIN PILLARS:**

1. Content Knowledge (CK): This refers to the teacher\'s deep
understanding of the subject matter they teach. This includes
knowledge of concepts, theories, principles, and the ability to
explain and illustrate them effectively. Teachers with strong CK can
effectively identify relevant content and design learning activities
that promote deep understanding \[2\].

2. Pedagogical Knowledge (PK): This encompasses the teacher\'s
knowledge of teaching and learning processes. It includes
understanding how students learn, effective teaching strategies,
classroom management techniques, and assessment methods. Teachers
with strong PK can effectively plan and deliver lessons that cater
to diverse learning styles and needs \[2\].

3. Technological Knowledge (TK): This refers to the teacher\'s
understanding of technology and its potential applications in
education. It includes knowledge of various technologies, their
capabilities, limitations, and how they can be used to enhance
learning. Teachers with strong TK can choose appropriate
technologies, design engaging digital learning experiences, and
troubleshoot technical issues effectively \[2\].

**Technological Content Knowledge**

Technology and content knowledge have a deep historical relationship.
Progress in fields as diverse as medicine, history, archeology, and
physics have coincided with the development of new technologies that
afford the representation and manipulation of data in new and fruitful
ways. Consider Roentgen's discovery of X-rays or the technique of
carbon-14 dating and the influence of these technologies in the fields
of medicine and archeology. Consider also how the advent of the digital
computer changed the nature of physics and mathematics and placed a
greater emphasis on the role of simulation in understanding phenomena.
Technological changes have also offered new metaphors for understanding
the world. Viewing the heart as a pump, or the brain as an
information-processing machine are just some of the ways in which
technologies have provided new perspectives for understanding phenomena.
These representational and metaphorical connections are not superficial.
They often have led to fundamental changes in the natures of the
disciplines.

**Technological Pedagogical Knowledge**

TPK is an understanding of how teaching and learning can change when
particular technologies are used in particular ways. This includes
knowing the pedagogical affordances and constraints of a range of
technological tools as they relate to disciplinarily and developmentally
appropriate pedagogical designs and strategies. To build TPK, a deeper
understanding of the constraints and affordances of technologies and the
disciplinary contexts within which they function is needed.

**Pedagogical Content Knowledge**

PCK is consistent with and similar to Shulman's idea of knowledge of
pedagogy that is applicable to the teaching of specific content. Central
to Shulman's conceptualization of PCK is the notion of the
transformation of the subject matter for teaching. Specifically,
according to Shulman (1986), this transformation occurs as the teacher
interprets the subject matter, finds multiple ways to represent it, and
adapts and tailors the instructional materials to alternative
conceptions and students' prior knowledge. PCK covers the core business
of teaching, learning, curriculum, assessment and reporting, such as the
conditions that promote learning and the links among curriculum,
assessment, and pedagogy. An awareness of common misconceptions and ways
of looking at them, the importance of forging connections among
different content-based ideas, students' prior knowledge, alternative
teaching strategies, and the flexibility that comes from exploring
alternative ways of looking at the same idea or problem are all
essential for effective teaching.

**Technology, Pedagogy, and Content Knowledge**

TPACK is an emergent form of knowledge that goes beyond all three "core"
components (content, pedagogy, and technology). Technological
pedagogical content knowledge is an understanding that emerges from
interactions among content, pedagogy, and technology knowledge.
Underlying truly meaningful and deeply skilled teaching with technology,
TPACK is different from knowledge of all three concepts individually.
Instead, TPACK is the basis of effective teaching with technology,
requiring an understanding of the representation of concepts using
technologies; pedagogical techniques that use technologies in
constructive ways to teach content; knowledge of what makes concepts
difficult or easy to learn and how technology can help redress some of
the problems that students face; knowledge of students' prior knowledge
and theories of epistemology; and knowledge of how technologies can be
used to build on existing knowledge to develop new epistemologies or
strengthen old ones.

In addition, the TPACK framework offers several possibilities for
promoting research in teacher education, teacher professional
development, and teachers' use of technology. It offers options for
looking at a complex phenomenon like technology integration in ways that
are now amenable to analysis and development. Moreover, it allows
teachers, researchers, and teacher educators to move beyond
oversimplified approaches that treat technology as an "add-on" instead
to focus again, and in a more ecological way, upon the connections among
technology, content, and pedagogy as they play out in classroom
contexts.

**[SAMR]**

**(Substitution, Augmentation, Modification and Redefinition Model)**

The SAMR model, developed by Dr. Ruben Puentedura in 2006, is a
framework for educators to understand and effectively integrate
technology into their teaching practices. It outlines four levels of
technology integration, progressing from simple substitution to
transformative redefinition, emphasizing the importance of using
technology to enhance learning rather than just for the sake of using
it.

Four stages of the SAMR Model:

- SUBSTITUTION -- Technology operates as a direct tool substitute,
with no functional change. For example, students can enter notes on
a program such as Word instead of handing in an exercise book.

- AUGMENTATION -- Technology serves as a direct tool substitute with
functional enhancements. Augmenting learning processes, such as
typing on a word processor, can improve efficiency and engagement.
Images can be uploaded, text can be linked together, and text
updates can be made rapidly.

- MODIFICATION- At this point, technology not only improves but also
significantly transforms learning. An example might be students
setting up a blog in which they open up their work to a worldwide
audience. The blog means that students are much more accountable for
the work they present so will tend to spend more refining their
written work. In this way, both student learning and literacy
improve.

- REDEFINITION- This level requires the teacher to consider learning
activities that were previously impossible without the use of
technology. This could involve, for example, a Google Hangout
session with students from different nations in which students
provide information about their home countries in real time.
Similarly, using Google Docs to collaborate on a shared assignment
allows students from all over the world to learn in ways that would
not be possible without such technology.

Substitution and Augmentation are grouped as 'enhancement' tools while
Modification and Redefinition are considered as 'transformation' tools.
Puentedura's framework has substitution at the lowest level and
redefinition at the highest level. For educators that are more familiar
with bloom's taxonomy the substitution and augmentation methods are
typically equated with the first three levels of blooms framework which
is the knowledge comprehension and application while modification and
redefinition are perceived as on the same level as the upper three of
bloom's learning stages which is analysis synthesis and evaluation.

With the SAMR model, Puentedura suggests that as teachers reflect on
integrating technology with the learning experience, they often have
questions on how they can effectively use technology.

**The Importance of SAMR**

The SAMR model provides a valuable framework for understanding and
promoting effective technology integration in education. It encourages
educators to think critically about how technology can be used to
enhance student learning and to move beyond simply substituting
technology for traditional tools. The model also helps educators to
identify opportunities for using technology to create innovative and
engaging learning experiences that are not possible without it.

By applying the SAMR model, educators can ensure that technology is used
effectively to support student learning and to create a more dynamic and
engaging learning environment.

**[BLOOM'S DIGITAL TAXONOMY]**

Bloom\'s Digital Taxonomy: This taxonomy expands on the original one and
focuses on how technology and digital tools are used in education. It
emphasises the incorporation of technology into teaching and learning by
matching the cognitive levels of Bloom\'s Taxonomy with digital
competencies and activities.

The original Taxonomy of Educational Objectives, commonly referred to as
Bloom\'s Taxonomy, was created by Benjamin Bloom in 1956,


In 2001, Lorin Anderson and David Krathwohl updated Bloom\'s seminal
framework to create Bloom\'s Revised Taxonomy, focusing on the Cognitive
and Affective Domains.

- **Creating** -- To produce new or original work. Tools -- Animating,
blogging, filming, podcasting, publishing, simulating, wiki
building, video blogging, programming, directing

- **Evaluating** -- To justify a stand or decision; to make judgements
based on criteria and standards through checking and critiquing.
Tools -- Grading, networking, rating, testing, reflecting,
reviewing, blog commenting, posting, moderating

- **Analyzing** -- To draw connections among ideas, concepts, or
determining how each part interrelate to an overall structure or
purpose. Tools -- Mashing, mind mapping, surveying, linking,
validating

- **Applying** -- To use information in new situations such as models,
diagrams, or presentations. Tools -- Calculating, Charting, editing,
hacking, presenting, uploading, operating, sharing with a group

- **Understanding** -- To explain ideas, concepts, or construct
meaning from written material or graphics. Tools -- Advanced
searching, annotating, blog journaling, tweeting, tagging,
commenting, subscribing

- **Remembering** -- To recall facts, basic concepts, or retrieval of
material. Tools -- Bookmarking, copying, googling, bullet-pointing,
highlighting, group networking, searching.

**[The assure Model and Model of Technology- Enhanced Instructional
Lesson ]**

ASSURE is an instructional design model that has the goal of producing
more effective teaching and learning. "ASSURE" is an acronym that stands
for the various steps in the model. The following is a breakdown of each
step. Heinrich and Molenda created the ASSURE model in 1999. It is a
well-known Instructional Design guide incorporating multimedia and
technology to improve the learning environment from a constructivist
perspective. Its name is an acronym for its components, which we'll see
below.

**The 6 Model\'s Components**

1. Analyze Learners

The ASSURE model relies heavily on the learners, and its core is
designed based on their needs. This is why the first step involves
identifying the characteristics of the learners. Those can be their age,
existing knowledge, education level, learning specificities, and a
variety of other key details that are usually gathered through surveys
and assessments. Once you've collected all the important info, you can
start designing your lessons based on your learners' needs and
preferences. It involves understanding the characteristics, needs, and
learning styles of the target audience. Educators need to consider
factors such as age, prior knowledge, learning preferences, and any
special needs or accommodations required. This analysis helps ensure
that the chosen technology and materials are appropriate and accessible
to all learners

2. State Objectives

In the second step, you identify what learners should be able to do
after completing the instructional materials. You can set the objectives
based on the SMART method, so they should be specific, measurable,
achievable, relevant, and time-bound. This means that you should be able
to know precisely what skills and knowledge the learners are going to
acquire during a specific period. Additionally, you should set realistic
goals relevant to the lessons to achieve the best learning outcome.

3. Select Methods

\- Alignment with curriculum: Does the chosen method or material align
with the learning objectives and curriculum standards?

\- Clarity and accuracy: Is the information presented accurately and
clearly?

\- Learner engagement: Will the chosen method or material motivate and
engage learners?

\- Technical quality: Is the technology reliable and user-friendly?

\- Accessibility: Is the method or material accessible to all learners,
including those with disabilities?

4. Utilize Media And Materials

Once the methods, media, and materials are selected, educators must
prepare them for use. This involves ensuring that the technology is
operational, that the materials are organized, and that the instructor
is familiar with the chosen methods. It is crucial to practice using the
technology and materials beforehand to ensure a smooth and effective
delivery of the lesson.

5. Require Learner Participation

This step emphasizes active learning and engagement. Educators should
design activities that encourage learners to actively participate in the
lesson. This can include interactive exercises, discussions, group work,
hands-on activities, and opportunities for learners to apply their
knowledge in real-world scenarios. The lesson should be structured to
ensure that every learner is actively involved and has opportunities to
demonstrate their understanding

6. Evaluate And Revise

The final step involves evaluating the effectiveness of the lesson and
making necessary revisions. Educators should collect data on learner
performance, feedback, and any challenges encountered during the lesson.
This data can be used to identify areas for improvement and to refine
the lesson for future use. The evaluation process should align with the
learning objectives and should consider both learner and instructor
performance.