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Transcript of I MPLEMENTING S ELF -R EGULATION S TRATEGIES IN M ATH TO P ROMOTE I NTRINSIC M OTIVATION AND S ELF -...
IMPLEMENTING SELF-REGULATION STRATEGIES IN MATH TO PROMOTE INTRINSIC MOTIVATION AND SELF-EFFICACY GROWTH IN 8TH GRADE STUDENTS
Grant Stephenson, M.S.Ed.
Yojanna Cuenca-Carlino, Ph.D.
TEACHER PARTICIPATING IN RESEARCH
Grant Stephenson M.S.Ed. Secondary math and history undergraduate
degree. Currently teaching 8th grade math
Interest in special education led to pursuing my current master’s degree from Illinois State University.
I am NOT an expert! I just wanted to share my research. I hope it is helpful.
A VIDEO?
Or 2..
AGENDA
Research study used to guide implication Background Research questions Overview
SRSD Stages Specific Lessons
Data Measurements Results Teaching a Lesson Implications for Practice
What I learned as an educator and why I feel it is important
BACKGROUND/ LITERATURE REVIEW
Math and CCSS
• Only 34% and 27% of fourth and eighth grade students respectively are proficient in math.
• Students with learning disabilities have difficulty assessing their ability to solve problems, identify and select appropriate strategies, organize information, monitor problem solving processes, evaluate problems for accuracy, and generalize strategies to appropriate situations (Miller & Mercer, 1997).
SRSD •SRSD involves six basic stages of instruction that include (a) developing and activating background knowledge; (b) discussing the strategy including benefits and expectations; (c) cognitive modeling of the strategy; (d) memorization of the strategy; (e) collaborative support of the strategy; and (f) independent practice (Lienemann & Reid, 2006).
BACKGROUND/ LITERATURE REVIEW
Math and CCSS
•One way to assist students with learning disabilities with the shift to more content-focused classes is to provide them with effective and efficient learning strategies.
SRSD •During instruction, students are taught to self-regulate their learning by setting goals, self-instructing, self-monitoring, and self-reinforcing •To date, the majority of SRSD research has sought to improve the writing process of students with LD and emotional and behavioral disorders, but it has been used in mathematics on a select number of times.
RESEARCH QUESTIONS
To what extent does the SRSD model of instruction improve students at-risk for mathematical difficulties or identified with a LD, computational skills and accuracy on grade level multi-step equations?
Would students be able to maintain gains after instruction is provided?
To what extent was the intervention provided with fidelity by the classroom teacher after training was provided?
Would student’s self-efficacy improve as a result of instruction?
How do students perceive the effectiveness of SRSD instruction?
RESEARCH OVERVIEW
Self-Regulated Strategy Development Instruction to Solve Multi-step
Equations for Middle School Students with Learning Disabilities or Identified
At-Risk
A multiple probe across
participants design
6 middle school students both with and without learning disabilities.
5 females1 males
Part of school’s RtI program
Classroom Teacher
Research team: one professors, 2
undergrad students, one graduate student
Instruction was provided during
the student’s tier 2 math intervention
Three groups of students1- N=22- N= 23- N= 2
DATA MEASUREMENTS
Equation Probe Assessed on percentage correct Baseline, post, maintenance
Self-Efficacy Survey Given during baseline and post intervention.
Student Interviews Only given during post intervention.
Equation Probe
Self-Efficacy Measure
“SELF-REGULATED STRATEGY DEVELOPMENT”
•Increase background knowledge•Sign the contract•Discuss self-determination•Discuss solving equations•Discuss terminology associated with equations
SRSD : Stage 1Develop
background knowledge
• Introduce DCMCR• “Don’t Catch My Cat Whiskers”• Introduced visual aid to show mnemonic with
the equations
SRSD: Stage 2
Discuss the strategy
• Discuss self-statements and write self-statements• Observe the teacher modeling how to work through the
mnemonic• Learn about the checklist to use for solving equations• Introduce self-monitoring sheet
SRSD-Stage 3 Modeling the
strategy
•Practice memorizing the strategy
SRSD- Stage 4Memorize the
strategy
•Longest of the stages, student practice solving equations with the guide of the teacher•Students use self-statements and self-monitoring sheets throughout these stages
SRSD- Stage 5Guided practice
SRSD- Stage 6Independent
PracticeStudents require little or no support while solving
equationsStudents remain on this
stage until they successfully solve all equation
consistentlyChecklist and other materials
are not usedessays
SRSD-STAGE 1“DEVELOP BACKGROUND KNOWLEDGE”
Discuss relevant information and background
BACKGROUND KNOWLEDGE FOR SOLVING EQUATIONS
Purpose of solving an equation and how to check an equation
Terminology Variables, constant, coefficient, etc.
Distributive Property Combine Like Terms Inverse Operations
Stu
den
t Con
tract
STAGE 2 – “DISCUSS IT”
Introduce and discuss the mnemonic created “Don’t Catch My Cat Whiskers” Don’t = Distribute Catch = Combine Like Terms
But Remember! “Pick the vine and never trip and ultimately intelligent oranges impress old shoes.
My = Multiply or Divide Cat = Check Whiskers = Way to go you are done!
LET’S PUT IT TOGETHER THROUGH AN EXAMPLE (SRSD – 3 MODEL)3(x + 2) + 2x = 3x + 14
DCMCW
Distribute 3(x + 2) + 2x = 3x + 14
3x + 6 + 2x = 3x + 14
*During stage 1 of instruction, the distributive property was reviewed and practiced. This was not the first time students were introduced to this property.
DCMCW“CATCH” OR COMBINE LIKE TERMS
There are two parts to this step. Like terms on the SAME SIDE Like terms on OPPOSITE SIDES
3x + 6 + 2x = 3x + 14
5x + 6 = 3x + 14
2x = 8
SAME SIDE (Pick the vine
and never trip)
OPPOSITE SIDES (Ultimately intelligent
oranges impress old shoes)
DCMCW – “MULTIPLY/ DIVIDE”
2x = 8
X = 4
DCMCR – ‘CHECK”
x = 4 Substitute the solutions in for the variables.3(x + 2) + 2x = 3x + 143(4 + 2) + 2(4) = 3(4) + 14
3(6) + 8 = 12 + 14
18 + 8 = 12 + 14
26 = 26 (It checks out!!)
DCMCW
Way to go you are done!!
STAGE 4
Memorize it Students spend a couple of days practicing
memorizing the mnemonic itself We used flash cards to help with this stage
STAGE 5 – GUIDED PRACTICE
STAGE 6 – INDEPENDENT PRACTICE
Students continue to self-monitor their work However, in this stage, students are working
without the visual aid and checklist Students continue on this stage until mastery
is complete
RESULTS
Overall, students math performance and self-efficacy increased significantly.
Motivation increased slightly, but the gains were not as significant as in the equations and self-efficacy data.
Also, maintenance data suggests that the strategy helped with the retention of equation solving.
So, what did this mean for me? Although the data was not exactly aligned to my
predetermined goals, I still felt as though many valuable lessons were learned.
DI SRSD
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0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18
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0% 100%200%300%400%500%600%700%800%900%1000%1100%1200%1300%1400%1500%1600%1700%1800%
Baseline Postinstruction
Sessions
Pe
rce
nta
ge
of
Ste
ps C
om
ple
ted
Co
rre
ctl
y
Maintenance
Nick
Nicole
MayLucy
Alice
April
IMPLICATIONS FOR PRACTICE
Stage 1“Develop Background”
Stage 2“Discuss Strategy”
Important to develop background in any subject.
Students need to know and understand the background to anything they are learning.
Understanding the background can help the students to better understand “Why” things happen in math.
Developing a strategy to help students process their thinking can be very students to check their progress themselves, which results in increased self-efficacy.
Developing a specific strategy can also promote self-regulation through a certain skill.
Student-created mnemonic?
SRSD stages Implications
IMPLICATIONS FOR PRACTICE
Stage 3“Model it”
Stage 4“Memorize it”
For any student, modeling is key! Students need to see what they
are expected to do, how to think, and what questions to ask themselves.
At first I thought using a script was difficulty, but later found that it really made me focus on the specifics of my modeling.
If a strategy is created, it is useless unless the students remember it.
Students need time. It is not helpful to students if you move on without them fully understanding what they are expected to do.
SRSD stages Implications
IMPLICATIONS FOR PRACTICE
Stage 5”Guided Practice”
Stage 6“Independent Practice”
To prevent incorrect application of a skill, guided practice is important.
This is also a great opportunity to provide positive support, which will then increase student self-efficacy.
Providing enough time to practice on their own is important for student growth.
As teachers, we are not really able to view what has been learned until the students work completely on their own.
Like with the checklist and self-monitoring sheets used, providing students with opportunities to reflect and record results is important for self-regulation.
SRSD stages Implications
Implications
SRSD can be an effective solution for implementing self-regulation to students both with and with out learning disabilities.
I think the process of breaking down a long processed problem into smaller pieces is what really helps makes this successful.
Even if not fully implemented, different concepts of SRSD can be adapted to fit many different lessons and many different skills.
Writing is most often associated with SRSD strategies. Writing involves a process and so does solving equations. I believe that SRSD could be applied to many different skills that require a process completion.
APPLICATION IN MY OWN CLASSROOM
Recently, I taught an equation unit to my four 8th grade math classes.
Spent much more time “developing background knowledge” than I have ever done in the past.
Didn’t use the exact mnemonic, but focused heavily on developing patterns in their work.
Consistent guided practice, followed by independent practice.
Provided many opportunities to “self-check” and “regulate their own progress” to work on those self-regulation skills as well.
Implementing the SRSD components, although not exactly as intended, has also proved beneficial to my students this year.
QUESTIONS?
REFERENCES Brodesky, A., Parker, C., Murray, E., & Katzman, L. (2002). Accessibility strategies toolkit for mathematics. Retrieved May 18, 2004,
fromhttp://www2.edc.org/accessmath/resources/strategiesToolkit.pdf Case, L. P., Harris K. R., Graham, S. (1992). Improving the mathematical problem-solving skills of students with learning disabilities: Self-
regulated strategy development. The Journal of Special Education, 26, 1-19. Cassel, J., & Reid, R. (1996). Use of a self-regulated strategy intervention to improve word problem-solving skills of students with mild
disabilities. Journal of Behavioral Education, 6(2), 153. Chung, K. H., & Tam, Y. H. (2005). Effects of cognitive-based instruction on mathematical problem solving by learners with mild intellectual
disabilities. Journal of Intellectual and Developmental Disability, 30, 207-216. Cuenca-Carlino, Y., & Mustian, A. L. (2013). Self-regulated strategy development: Connecting persuasive writing to self-advocacy for students
with emotional and behavioral disorders. Behavioral Disorders, 39(1), 3-15. Ennis, R. P., Jolivette, K., & Boden, L. J. (2013). STOP and DARE: Self-regulated strategy development for persuasive writing with elementary
students with E/BD in a residential facility. Education & Treatment of Children (West Virginia University Press), 36(3), 81-99. Gast, D. L. (2010). Single subject research methodology in behavioral sciences / david l. gast New York : Routledge, 2010. Gersten, R., Chard, D., Jayanthi, M., Baker, S., Morphy, P., & Flojo, J. (2008). Mathematics instruction for students with learning disabilities or
difficulty learning mathematics: A synthesis of the intervention research. Portsmouth, NH: RMC http://www.centeroninstruction.org/files/Teaching%20Math%20to%20SLD%20Meta-analysis.pdf
Harris, K. R., Graham, S., &Mason, L. H. (2003). Self-regulated strategy development in the classroom: Part of a balanced approach to writing instruction for students with disabilities. Focus on Exceptional Children, 35(7), 1.
Harris, K.R., Graham, S., Mason, L.H., & Friedlander, B. (2008). Powerful writing strategies for all students. Baltimore: Brookes. Hauth, C., Mastropieri, M., Scruggs, T., & Regan, K. (2013). Can students with emotional and/or behavioral disabilities improve on planning
and writing in the content areas of civics and mathematics? Behavioral Disorders, 38(3), 154-170. Hoover, T. M., Kubina, R. M., & Mason, L. H. (2012). Effects of self-regulated strategy development for POW+TREE on high school students
with learning disabilities. Exceptionality, 20(1), 20. Krawec, J., Huang, J., Montague, M., Kressler, B., & de Alba, A. M. (2013). The effects of cognitive strategy instruction on knowledge of math
problem-solving processes of middle school students with learning disabilities. Learning Disability Quarterly, 36(2), 80-92. doi:10.1177/0731948712463368
Leinemann, T. O., & Reid., R. (2006). Self-regulated strategy development for students with learning disabilities. Teacher Education and Special Education, 29(1), 3-11.
Miller, S. P., & Mercer, C. D. (1997). Educational aspects of mathematics disabilities. Journal of Learning Disabilities, 30, 47-56. Montague, M. (2007). Self-regulation and mathematics instruction. Learning Disabilities Research & Practice (Wiley-Blackwell), 22(1), 75-83.
doi:10.1111/j.1540-5826.2007.00232.x National Council of Teachers of Mathematics. (2000). Principles and standards for school mathematics. Reston, VA: Author. National Center for EducationStatistics (2013).The Nation’s Report Card:A First Look: 2013 Mathematics and Reading(NCES 2014-
451).Institute of Education Sciences, U.S. Department of Education, Washington, D.C. Scruggs, T. E., Mastropieri, M. A., Berkeley, S. L., and Marshak, L. (2010). Mnemonic strategies: Evidence-based practice and practice-based
evidence. Intervention in School and Clinic, 46, 79-86. doi: 10.1177/1053451210374985. Steele, M. M., & Steele, J. W. (2003). Teaching algebra to students with learning disabilities. Mathematics Teacher, 96, 622-624. The Center on Instruction (2008)