Date
|
Task
|
July 30, 2013
|
IRB Submission
|
no later than
September 21, 2013
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Second IRB Resubmission with requested changes
|
TBD
October X, 2013
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IRB Approval
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September 20, 2013 until IRB approval
|
Compile an email list of high school mathematics teachers in preparation for administering the survey
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October X, 2013 (upon IRB approval)
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Administer Survey Solicitation E-mail
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October X, 2013 (upon IRB approval) - November 1, 2013
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Survey Administration and Data Collection
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November 1 - 8, 2013
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Data Analysis
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November 9 - 17, 2013
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Write up findings and conclusions
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November 18 - 22, 2013
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Edit Paper
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December 2, 2013
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Stakeholder Presentation
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December 4, 2013
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UWG Presentation
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December 7, 2013
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Final Submission
|
Sunday, September 22, 2013
Timeline of Pilot Study
Sunday, July 7, 2013
Introduction and Purpose Statement
Integrating Technology Resources in a
Secondary Mathematics Classroom
Molly
McKee
University of West Georgia
Introduction
Technology
and education are both areas that are constantly changing and evolving. To provide students with the best possible
education, educators must learn how to effectively incorporate technology into
the classroom. The use of technology in the
classroom is lagging behind current technology trends. Classroom technology needs to parallel the
types of technology students are using outside the classroom. In the area of mathematics, the primary
technology resource is a calculator. Greater
efforts need to be made to integrate all sorts of technology into the secondary
mathematics classroom. Secondary
mathematics units that consist primarily of technology centered learning have
the potential to increase student comprehension on district benchmark tests and
raise student engagement depending on the level of proficiency the instructor
has with the given technological tools.
Technology
is one of the six principles created by the National Council of Teachers of
Mathematics (NCTM) for school Mathematics.
The Technology Principle states that “technology is essential in
teaching and learning mathematics; it influences the mathematics that is taught
and enhances students’ learning (NCTM, 2005, p.24). The Common Core Standards that are currently
being implemented across the nation align with the goals of NCTM’s technology
principle. The Common Core State
Standards for Mathematics number five, entitled use appropriate tools strategically,
states:
When making mathematical models, [students] know that technology can
enable them to visualize the results of varying assumptions, explore
consequences, and compare predictions with data. Mathematically proficient students at various grade
levels are able to identify relevant external mathematical resources, such as
digital content located on a website, and use them to pose or solve problems. They are able to use technological tools to explore
and deepen their understanding of concepts. (p.7)
Although
the ideal mathematics curricula presented by NCTM and the Common Core standards
are attainable, implementation can prove to be challenging. It is the responsibility of educators and the
educational system to ensure that integrating technology in to the classroom
and curricula are successful. Teachers
must be open to learning new ways to teach, and administrators must offer
teachers an opportunity to learn new techniques. It is impossible for teachers to make
substantial and effective changes in their classrooms, if they are not provided
with proper direction and instruction on how to achieve success (Apple, 1992).
As technology changes and becomes
more prevalent in everyday society, educators need to become comfortable with
using technology as an instruction tool and students need to learn how to
operate the tools they will be using in future professions. Research needs to be done to establish if
instructional technology is an enhancement to current teaching styles or if it
will hinder student learning. Since
student engagement and retention is always an important factor in education, we
need to discover if integrating technology into the classroom will increase
these factors.
Research Questions
The
purpose of this mixed methods pilot study is to investigate the effects
technology integration has on student mathematical comprehension and subsequent
standardized test scores. The research questions
being addressed through this study are: Does a technology enhanced unit plan
increase student comprehension and retention in high school mathematics? How does technology affect student
comprehension in the secondary mathematics classroom? How do teacher perceptions and expertise with
technology affect technology integration in the secondary mathematics
classroom?
The
instrument used
to collect the quantitative research data will be benchmark
exams created and administered by the district. Benchmark exams are local
formative assessments that have been previously used to gauge student
achievement, comprehension, and retention. The qualitative research
will be conducted by using a variation of the Survey
of Preservice Teachers' Knowledge of Teaching and Technology created by Schmidt,
Baran, Thompson, Koehler, Mishra, and Shin. The survey must be altered because the
original is intended for pre-service teachers the research for this study will be
conducted with in-service teachers. The reliability of the scores of the
survey, documented by Schmidt (2009), is as follows:
Reliability of the Scores (from Schmidt et al, 2009).
TPACK Doman
|
Internal Consistency (alpha)
|
Technology Knowledge (TK)
|
.86
|
Content Knowledge (CK)
|
|
Social Studies
|
.82
|
Mathematics
|
.83
|
Science
|
.78
|
Literacy
|
.83
|
Pedagogy Knowledge (PK)
|
.87
|
Pedagogical Content
Knowledge (PCK)
|
.87
|
Technological
Pedagogical Knowledge (TPK)
|
.93
|
Technological
Content Knowledge (TCK)
|
.86
|
Technological
Pedagogical Content Knowledge (TPACK)
|
.89
|
Purpose
The purpose of this pilot study
is to measure how effective technology integration is on student engagement and
comprehension in secondary mathematics classrooms. The direct goal of this study is to use the
results of other researchers in conjunction with research on available
technology resources to determine if it is possible to create an effective
mathematics unit taught primarily through the integration of technology. The research from this study will contribute
to the current literature and research on technology integration in a variety
of ways. The existing research conducted
by scholars such as Stiler (2007), focuses specifically on integrating one type
of technology to enhance an entire curriculum, rather than using a variety of
resources to expand the enrichment a specific unit.
The results of this study will
directly benefit all teachers of the new common core mathematics curriculum. Siegle (2004) discusses the benefits of
technology for the advancement of gifted students, while Smith and Robinson
(2003) stress how the use of technology can be used to aid in the remediation
and advancement of students with special needs.
Therefore, the secondary goal of this study is to demonstrate how
technology can be integrated into any type of classroom environment to increase
student comprehension and engagement on all levels.
References
Apple, M. (1992). Do the
Standards Go Far Enough? Power, Policy, and Practice, in Mathematics Education.
Journal for Research in Mathematics
Education, 23(5), 258-291.
Beaver,
R. & Moore, J. (2004). Curriculum design and technology integration: a
model to use technology in support of knowledge generation and higher-order
thinking skills, Learning & Leading
with Technology, 32(1), 42–45.
Delen, E. & Bulut, O. (2011).
The relationship between students’ exposure to technology and their achievement
in science and math. The Turkish Online Journal of Educational Technology,
10, 311-317.
Georgia Department of Education. (2005).
Office of
curriculum, and testing. Available
from Georgia Department of Education, http://:public.doe.k12.ga.us
Lawrenz, F., Gravely, A., &
Ooms, A. (2006). Perceived helpfulness and amount of use of technology in
science and mathematics classes at different grade levels. School Science
& Mathematics, 106(3), 133-139.
National Council of Teachers of
Mathematics (2005). Principles and
Standards for School Mathematics. Reston, Virginia:NCTM.
National Governors Association
Center for Best Practices and Council of Chief State School Officers (2012). Common
Core State Standards Initiative . Common
Core State Standards for Mathematics.
Safdar, A., Yousuf, M., Parveen,
Q., & Behlol, M. (2011). Effectiveness of information and communication
technology (ICT) in teaching Mathematics at secondary level. International Journal of Academic Research,
3(5), 67-72.
Schmidt,
D. A., Baran, E., Thompson A. D., Koehler, M. J., Mishra, P. & Shin, T. (2010).
Technological pedagogical content knowledge (TPACK): The development and
validation of an assessment instrument for preservice teachers. Journal
of Research on Technology in Education, 42(2), 123-149.
Schmidt,
D. A., Baran, E., Thompson A. D., Koehler, M. J., Mishra, P. & Shin, T. (2009).
The continuing development, validation and implementation of a TPACK assessment
instrument for preservice teachers. Paper
submitted to the 2010 Annual Meeting of the American Educational Research
Association. April 30-May 4, Denver, CO.
Siegle,
D. (2004) The merging of literacy and
technology in the 21st century: a bonus for gifted education, Gifted Child Today, 27(2), 32–35.
Smith, S. J. &
Robinson, S. (2003) Technology
integration through collaborative cohorts: preparing future teachers to use
technology, Remedial and Special
Education, 24(3), 154–160.
Stiler, G. (2007).
MP3 players: Applications and implications for the use of popular
technology in secondary schools. Education, 128(1), 20-33.
Washington
State, Office of Superintendent of Public Instruction (2002) Washington State
Educational Technology Plan: a blueprint for Washington’s K-12 common schools
and learning communities. Retrieved
from: http://www.k12.wa.us/ edtech/TechIntDef.aspx#_ftn1
Sunday, June 9, 2013
Theoretical Foundation
Enhancing student engagement and mathematical comprehension by integrating technology into instructional design is the overall goal of this research project. The constructivist learning theory is the most appropriate learning theory to describe this project. Led by theorist Piaget, the constructivist learning theory is centered around student led activities and a variety of learning techniques such as inquiry based, discovery, problem based, multimedia or web-based, and alternative learning (Roblyer, 2005).
Another influential theory associated with this area of research is the cognitive theory of multimedia learning proposed by Mayer (1997). It follows the theory that humans process information in two ways; visually and auditory. By utilizing both of these methods of learning and processing, more meaningful learning is likely to occur (Mayer, 1997; Mayer & Moreno, 2003). Using multiple methods of presenting information leads to more learning transfer. Importantly, it also focuses on the amount of information that can be successfully processed and held in the working memory. These theories and principles are the theoretical basis for integrating technology into secondary classrooms.
Mayer, R.E. (1997). Multimedia learning: Are we asking the right questions? Education Psychologist, (32) 1-19.
Mayer, R. E., & Moreno, R. (2003). Nine ways to reduce cognitive load in multimedia learning. Educational Psychologist, (38)43-52.
Roblyer, M.D. & Edwards, J., (2005). Integrating Educational Technology into Teaching (Fourth Edition). Upper Saddle River, NJ: Prentice Hall.
Worldview
At this point in my research, I am leaning towards a mixed methods approach. For this reason, I would say that the pragmatic worldview connects the best with my proposed research. The pragmatic worldview "[uses] pluralistic approaches to derive knowledge about the problem" (Creswell, p. 11). Both quantitative and qualitative methods are used to analyze data and develop a better understanding of the research question(s) at hand. "Pragmatism opens the door to multiple methods, different worldviews, and different assumptions, as well as different forms of data collection and data analysis" (Creswell, p.11).
Another worldview that also relates closely with my research project is the constructivist worldview. I hesitate to embrace this worldview completely due to the fact that it is primarily used in qualitative studies. However, I am interested in how teachers' perceptions of technology affect the way the technology is integrated into the classroom. My goal is to "understand the historical and cultural settings of the participants" through the qualitative data so that I can determine correlations between teacher perceptions and student posttest achievement (Creswell, p. 8).
Another worldview that also relates closely with my research project is the constructivist worldview. I hesitate to embrace this worldview completely due to the fact that it is primarily used in qualitative studies. However, I am interested in how teachers' perceptions of technology affect the way the technology is integrated into the classroom. My goal is to "understand the historical and cultural settings of the participants" through the qualitative data so that I can determine correlations between teacher perceptions and student posttest achievement (Creswell, p. 8).
Review of Research
Shirley, M. L.,
Irving, K. E., Sanalan, V. A., Pape, S. J., & Owens, D. T. (2011). The
practicality of implementing connected classroom technology in secondary
mathematics and science classrooms. International Journal of
Science & Mathematics Education, 9(2),
459-481.
Research
Questions
- What features external to mathematics and science teachers’ class- rooms demonstrate instrumentality of connected classroom technology (CCT) implementation?
- What features of successful mathematics and science teachers’ class- room practice were congruent with CCT implementation?
- What relative costs and benefits of CCT implementation are described by mathematics and science teachers?
Theoretical Perspective
In my opinion, the
theoretical perspective used for this research is social constructivism. “The
goal of [constructivist] research is to rely as much as possible on the
participants’ views of the situation being studied” and “the researcher’s
intent is to make sense of (or interpret) the meanings others have about the world”
(Creswell, 8). Social constructivists also tend to have open ended, qualitative
research questions allowing for this interpretation of the problem being
addressed.
Research Paradigm
This was a mixed
methods study. Quantitative data analyzed posttest achievement between
treatment and control groups. The researchers also
collected and analyzed data from follow-up professional development sessions,
biannual interviews, and annual classroom observations.
Methodology
The data was
collected from 100 math teachers and 20 physical science teachers through two
phone interviews which were recorded and transcribed. Based on successful
implementation of the connected classroom technology, a subset of the original
participants contributed in a 2-day classroom observation and a
post-observation teacher interview (POI). The classroom observations were
videotaped and the POI interviews were recorded and later transcribed verbatim
and analyzed using the NVivo™ software package. The constant comparison method
outlined by Strauss and Corbin (1998) was used for this analysis.
Findings
What features external to
mathematics and science teachers’ class- rooms demonstrate instrumentality
of connected classroom technology (CCT) implementation?
- Teachers experienced initial challenges in setting up computer equipment
- Lack of familiarity with the technology sometimes impeded instruction
- Teachers attributed their success to support from administrative and other teachers
- Flexibility and creativity was sometimes negatively impacted
What features of
successful mathematics and science teachers’ class- room practice were
congruent with CCT implementation?
- The researchers defined congruence as how well the innovation matched the participating teachers’ teaching style
- Classroom discussions were improved due to the new content delivery method
- CCT was used to support district- and state-level testing and achieve goals mapped out by the curriculum
- Teachers were able to use CCT to track student learning and progress
What relative costs and
benefits of CCT implementation are described by mathematics and science
teachers?
- The majority of the costs involved time and professional development learning how to use the technology
- A major benefit of CCT was the ability of teachers to track and monitor student progress quickly and efficiently
Conclusions
Based on the
findings, implementing CCT appears to have been successful among the
participating math and science teachers assuming they have support from their
administration and can operate the technology correctly.
Relate
This study relates to
my own research on a number of levels. I plan to focus my study on the
implementation of technology in secondary mathematics classrooms. I am also
leaning towards a mixed methods study because I would like to analyze student
achievement through post testing as well as the teachers’ perceptions of
technology in the classroom.
Impressions
This study focused on one aspect of technology in the
classroom: audience response units. I would have liked to see a broader use of
technology in the classroom. By incorporating interactive whiteboards into the
classroom, a variety of technologies can be utilized in one lesson (audience
response units, videos, audio, webquests, and interactive activities). Also,
the number of participants in the study was far too small. Although they
started with 120 teachers, they eliminated the teachers who were unable to
successfully implement the CCT. I understand that being unable to use the
technology made it impossible to answer the interview questions regarding implementation,
but by eliminating participants, the researches drastically decreased the data
pool.
Additional Resources
Creswell, J. W. (2014). Research design: Qualitative, quantitative,
and mixed methods approaches (4th ed.). Thousand Oaks, CA: Sage.
Strauss, A. & Corbin, J. (1998). Basics of qualitative research: Techniques and procedures for developing grounded theory (2nd
ed.). Thousand Oaks: Sage.
Introduction
Welcome to my research journal. My topic is integrating technology in secondary mathematics classrooms. This blog will serve as my research journal as I prepare my action research project for EDSI 9963 at the University of West Georgia.
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