Difference between revisions of "DiBiano Personally Relevant Algebra Problems"
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== Robust Learning in Culturally and Personally Relevant Algebra Problem Scenarios == | == Robust Learning in Culturally and Personally Relevant Algebra Problem Scenarios == | ||
− | ''Candace DiBiano, Anthony Petrosino, Jim Greeno, and Milan Sherman'' | + | ''Candace Walkington (DiBiano), Anthony Petrosino, Jim Greeno, and Milan Sherman'' |
=== Summary Tables === | === Summary Tables === | ||
{| border="1" cellspacing="0" cellpadding="5" style="text-align: left;" | {| border="1" cellspacing="0" cellpadding="5" style="text-align: left;" | ||
− | | '''PIs''' || Candace | + | | '''PIs''' || Candace Walkington & Anthony Petrosino |
|- | |- | ||
| '''Other Contributers''' || | | '''Other Contributers''' || | ||
Line 15: | Line 15: | ||
| '''Study Start Date''' || 09/01/08 | | '''Study Start Date''' || 09/01/08 | ||
|- | |- | ||
− | | '''Study End Date''' || | + | | '''Study End Date''' || 4/15/10 |
|- | |- | ||
− | | '''Study Site''' || Austin | + | | '''Study Site''' || Austin, Texas & Pittsburgh, PA |
|- | |- | ||
− | | '''Number of Students''' || ''N'' = | + | | '''Number of Students''' || ''N'' = 125 |
|- | |- | ||
| '''Average # of hours per participant''' || 3 hrs. | | '''Average # of hours per participant''' || 3 hrs. | ||
Line 27: | Line 27: | ||
'' Full Study '' | '' Full Study '' | ||
{| border="1" cellspacing="0" cellpadding="5" style="text-align: left;" | {| border="1" cellspacing="0" cellpadding="5" style="text-align: left;" | ||
− | | '''Study Start Date''' || 9/1/ | + | | '''Study Start Date''' || 9/1/08 |
|- | |- | ||
− | | '''Study End Date''' || | + | | '''Study End Date''' || 4/15/10 |
|- | |- | ||
− | | '''LearnLab Site''' || | + | | '''LearnLab Site''' || Hopewell High |
|- | |- | ||
| '''LearnLab Course''' || Algebra | | '''LearnLab Course''' || Algebra | ||
|- | |- | ||
− | | '''Number of Students''' || ''N'' = | + | | '''Number of Students''' || ''N'' = 125 |
|- | |- | ||
− | | '''Average # of hours per participant''' || | + | | '''Average # of hours per participant''' || 3 hr |
|- | |- | ||
− | | '''Data in DataShop''' || | + | | '''Data in DataShop''' || Yes - Personalization Hopewell 2010 |
|} | |} | ||
<br> | <br> | ||
=== Abstract === | === Abstract === | ||
− | In the original development of the PUMP Algebra Tutor (PAT), teachers had designed the algebra problem scenarios to be "culturally and personally relevant to students" (Koedinger, 2001). However, observations and discussions with teachers in Austin ISD suggest that the problem scenarios are disconnected from the lives of typical urban students. This study will examine whether and the mechanisms by which | + | In the original development of the PUMP Algebra Tutor (PAT), teachers had designed the algebra problem scenarios to be "culturally and personally relevant to students" (Koedinger, 2001). However, observations and discussions with teachers in Austin ISD suggest that the problem scenarios are disconnected from the lives of typical urban students. This study will examine whether and the mechanisms by which familiarity with problem scenario context affect comprehension and [[robust learning]]. We will use the medium of [[cognitive tutor|Cognitive Tutor]] Algebra for the in-vivo portion of this study, but our aim is not to improve the quality of the software’s problem scenarios. It is instead to study how student diversity affects cognition, motivation, and learning, by using the power of a computer system that has the ability to do what classroom teachers cannot – [[personalization|personalize]] each problem to the background and interests of each individual student. |
− | The research | + | The research began in Fall of 2008 with a study of the personal interests of urban students at an "Academically Unacceptable" school in Austin, TX (75% free/reduced lunch). Freshman algebra students were surveyed and interviewed over their interests, such as sports, music, movies, etc., as well as how they use mathematics in their everyday lives. Students were also asked to solve a number of cognitive tutor problems, rewritten to have varying levels of "relevancy," while thinking aloud. Results of this study were used to rewrite the algebra problem scenarios in one section of the [[cognitive tutor|Cognitive Tutor]] software, Section 5, "Linear Models and Independent Variables." In Fall of 2009 at the Pittsburgh Learnlab site the [[cognitive tutor|Cognitive Tutor]] software was programmed to give students an initial interests survey, and then select problem scenarios that match user interests. The resulting [[robust learning]], measured by ''delayed post-test'', ''curriculum progress'' and ''mastery of knowledge components'', will be analyzed with a 2-group design (experimental vs. control) to measure the effects of the [[personalization]]. |
− | |||
− | |||
=== Background and Significance === | === Background and Significance === | ||
Line 56: | Line 54: | ||
=== Research Questions === | === Research Questions === | ||
− | * How will | + | * How will performance and time on task be affected when [[personalization]] through relevant problem scenarios is implemented instead of the current problem scenarios in the [[cognitive tutor|Cognitive Tutor]] Algebra I software? |
− | * How will [[robust learning]] be affected when current problem scenarios in the [[cognitive tutor|Cognitive Tutor]] Algebra I software | + | * How will [[robust learning]] be affected when [[personalization]] through relevant problem scenarios is implemented instead of the current problem scenarios in the [[cognitive tutor|Cognitive Tutor]] Algebra I software? |
=== Independent variables === | === Independent variables === | ||
− | This experiment will manipulate level of [[personalization]] through | + | This experiment will manipulate level of [[personalization]] through two treatment groups: |
*Students recieve current Cognitive Tutor Algebra problems | *Students recieve current Cognitive Tutor Algebra problems | ||
− | |||
*Students receive matched culturally relevant Cognitive Tutor Algebra problems personalized according to student interest survey | *Students receive matched culturally relevant Cognitive Tutor Algebra problems personalized according to student interest survey | ||
<BR> | <BR> | ||
{| border="1" cellspacing="0" cellpadding="5" style="text-align: left;" | {| border="1" cellspacing="0" cellpadding="5" style="text-align: left;" | ||
| '''Treatment'''|| '''Example Problem''' || '''Received By''' | | '''Treatment'''|| '''Example Problem''' || '''Received By''' | ||
− | |||
− | |||
|- | |- | ||
| Normal Cognitive Tutor Algebra problem scenarios || A skier noticed that she can complete a run in about 30 minutes. A run consists of riding the ski lift up the hill, and skiing back down. If she skiis for 3 hours, how many runs will she have completed? || 25-30 randomly-assigned Algebra I students at Learnlab site | | Normal Cognitive Tutor Algebra problem scenarios || A skier noticed that she can complete a run in about 30 minutes. A run consists of riding the ski lift up the hill, and skiing back down. If she skiis for 3 hours, how many runs will she have completed? || 25-30 randomly-assigned Algebra I students at Learnlab site | ||
|- | |- | ||
− | | | + | | Relevant [[personalization|personalized]] problem scenarios || (student selects personal interest in T.V. shows, cultural survey/interview shows strong interest among urban youth in reality shows) |
You noticed that the reality shows you watch on T.V. are all 30 minutes long. If you’ve been watching reality shows for 3 hours, how many have you watched? | You noticed that the reality shows you watch on T.V. are all 30 minutes long. If you’ve been watching reality shows for 3 hours, how many have you watched? | ||
− | || | + | || 110 randomly-assigned Algebra I students at Learnlab site |
|} | |} | ||
<BR> | <BR> | ||
Line 81: | Line 76: | ||
=== Hypothesis === | === Hypothesis === | ||
− | Students in the treatment with | + | Students in the treatment with [[personalization|personally relevant]] problem scenarios will show improved performance in terms of some measures of [[robust learning]] as a result of two factors: <BR> |
* Increased intrinsic motivation (such as with the [[REAP_Study_on_Personalization_of_Readings_by_Topic_%28Fall_2006%29|REAP Tutor study]])<BR> | * Increased intrinsic motivation (such as with the [[REAP_Study_on_Personalization_of_Readings_by_Topic_%28Fall_2006%29|REAP Tutor study]])<BR> | ||
* Formation of a more detailed and meaningful situation model (Nathan, Kintsh, & Young, 1992). | * Formation of a more detailed and meaningful situation model (Nathan, Kintsh, & Young, 1992). | ||
Line 95: | Line 90: | ||
*Hint-seeking and reading behavior in Cognitive Tutor software | *Hint-seeking and reading behavior in Cognitive Tutor software | ||
*Time on task in Cognitive Tutor software | *Time on task in Cognitive Tutor software | ||
− | |||
=== Method === | === Method === | ||
− | This experiment | + | This experiment began in the Fall of 2008 with a study of student interests. An interests survey was administered to high school classes in Austin ISD that contain a high proportion of diverse students, as well as at a Pittsburgh Learnlab. Structured in-depth interviews relating to student interests were conducted with around 29 of the surveyed students. Based on the results of the survey and interviews, culturally relevant problem scenarios that correspond to current problem scenarios in [[cognitive tutor|Cognitive Tutor]] Algebra I were formulated for Section 5, Linear Models and Independent Variables. Approximately 27 problem scenarios from the selected section will be replaced, with 4 variations on each problem scenario that correspond to different student interests, in order to obtain [[personalization]]. I wrote these problem scenarios while consulting with Jim Greeno and Milan Sherman; they will have the same underlying mathematics as the original [[cognitive tutor|Cognitive Tutor]] problems, with changes to the objects or nouns (what the problem is about) and the pronouns (who the problem is about). See the table above for an example of how these two changes might occur. |
− | |||
− | |||
− | The | + | The culturally relevant problem scenarios were reviewed by two master Algebra I teachers. In a pilot study, 24 Algebra I students participated in [[think-aloud data|think-aloud protocols]] where they solved five story problems with varying degrees of relevancy, that were based on Cognitive Tutor problems. Problem scenarios that students have difficulties or issues with will be reworked. |
− | + | The new problem scenarios were integrated into the [[cognitive tutor|Cognitive Tutor]] Algebra software in Summer 2009 with the cooperation of Carnegie Learning. Once the new problem scenarios were placed into the software, they were used in an [[in vivo experiment]] at a Learnlab school site in Pittsburgh by approximately 50-55 randomly-assigned students during the 09-10 school year. An additional 50-55 randomly-assigned students received the regular problem scenarios. See table above for a description of the two treatment groups in this study. | |
− | To summarize, the experiment | + | To summarize, the experiment had the following progression: |
− | (1) Survey of student interests administered in Austin ISD and Learnlab site | + | (1) Survey (paper & online) of student interests administered in Austin ISD and Learnlab site |
− | (2) Based on survey data, structured interviews | + | (2) Based on survey data, structured interviews on students' out-o9f-school interests were conducted |
− | (3) | + | (3) Based on interest interview, 24 students participated in think-alouds where they each solved 5 problems with different degrees of relevancy. |
− | + | (4) Relevant problem scenarios for Section 5 were written by Candace Walkington & Milan Sherman and reviewed by 2 master algebra teachers | |
− | (5) One [[cognitive tutor|Cognitive Tutor]] Algebra unit replaced at a Learnlab site with | + | (5) One [[cognitive tutor|Cognitive Tutor]] Algebra unit replaced at a Learnlab site with randomized control (in-sequence) setup |
=== Explanation === | === Explanation === |
Revision as of 19:36, 26 July 2010
Contents
Robust Learning in Culturally and Personally Relevant Algebra Problem Scenarios
Candace Walkington (DiBiano), Anthony Petrosino, Jim Greeno, and Milan Sherman
Summary Tables
PIs | Candace Walkington & Anthony Petrosino |
Other Contributers |
|
Pre Study
Study Start Date | 09/01/08 |
Study End Date | 4/15/10 |
Study Site | Austin, Texas & Pittsburgh, PA |
Number of Students | N = 125 |
Average # of hours per participant | 3 hrs. |
Full Study
Study Start Date | 9/1/08 |
Study End Date | 4/15/10 |
LearnLab Site | Hopewell High |
LearnLab Course | Algebra |
Number of Students | N = 125 |
Average # of hours per participant | 3 hr |
Data in DataShop | Yes - Personalization Hopewell 2010 |
Abstract
In the original development of the PUMP Algebra Tutor (PAT), teachers had designed the algebra problem scenarios to be "culturally and personally relevant to students" (Koedinger, 2001). However, observations and discussions with teachers in Austin ISD suggest that the problem scenarios are disconnected from the lives of typical urban students. This study will examine whether and the mechanisms by which familiarity with problem scenario context affect comprehension and robust learning. We will use the medium of Cognitive Tutor Algebra for the in-vivo portion of this study, but our aim is not to improve the quality of the software’s problem scenarios. It is instead to study how student diversity affects cognition, motivation, and learning, by using the power of a computer system that has the ability to do what classroom teachers cannot – personalize each problem to the background and interests of each individual student.
The research began in Fall of 2008 with a study of the personal interests of urban students at an "Academically Unacceptable" school in Austin, TX (75% free/reduced lunch). Freshman algebra students were surveyed and interviewed over their interests, such as sports, music, movies, etc., as well as how they use mathematics in their everyday lives. Students were also asked to solve a number of cognitive tutor problems, rewritten to have varying levels of "relevancy," while thinking aloud. Results of this study were used to rewrite the algebra problem scenarios in one section of the Cognitive Tutor software, Section 5, "Linear Models and Independent Variables." In Fall of 2009 at the Pittsburgh Learnlab site the Cognitive Tutor software was programmed to give students an initial interests survey, and then select problem scenarios that match user interests. The resulting robust learning, measured by delayed post-test, curriculum progress and mastery of knowledge components, will be analyzed with a 2-group design (experimental vs. control) to measure the effects of the personalization.
Background and Significance
This research direction was initiated by the observation of classrooms in Austin, Texas using the Cognitive Tutor Algebra I software, as well as discussions with teachers that had implemented this software at some point in their teaching career. Teacher complaints were consistently centered not around the interface, the feedback, or the cognitive model of the software, but on the problem scenarios. Teachers explained that their urban students found problems about harvesting wheat “silly,” “dry,” and irrelevant. Teachers also complained that some of the vocabulary words in the Cognitive Tutor problem scenarios (one example was the word "greenhouse") confused their students because urban freshman do not typically discuss these topics in their everyday speech. It’s important to note that as part of the development of the PUMP Algebra Tutor (PAT), teachers had designed problems to be "culturally and personally relevant to students" (Koedinger, 2001). This research is designed to empirically test the claim that the cultural and personal relevance of problem scenarios affects robust learning.
Research Questions
- How will performance and time on task be affected when personalization through relevant problem scenarios is implemented instead of the current problem scenarios in the Cognitive Tutor Algebra I software?
- How will robust learning be affected when personalization through relevant problem scenarios is implemented instead of the current problem scenarios in the Cognitive Tutor Algebra I software?
Independent variables
This experiment will manipulate level of personalization through two treatment groups:
- Students recieve current Cognitive Tutor Algebra problems
- Students receive matched culturally relevant Cognitive Tutor Algebra problems personalized according to student interest survey
Treatment | Example Problem | Received By |
Normal Cognitive Tutor Algebra problem scenarios | A skier noticed that she can complete a run in about 30 minutes. A run consists of riding the ski lift up the hill, and skiing back down. If she skiis for 3 hours, how many runs will she have completed? | 25-30 randomly-assigned Algebra I students at Learnlab site |
Relevant personalized problem scenarios | (student selects personal interest in T.V. shows, cultural survey/interview shows strong interest among urban youth in reality shows)
You noticed that the reality shows you watch on T.V. are all 30 minutes long. If you’ve been watching reality shows for 3 hours, how many have you watched? |
110 randomly-assigned Algebra I students at Learnlab site |
Hypothesis
Students in the treatment with personally relevant problem scenarios will show improved performance in terms of some measures of robust learning as a result of two factors:
- Increased intrinsic motivation (such as with the REAP Tutor study)
- Formation of a more detailed and meaningful situation model (Nathan, Kintsh, & Young, 1992).
Dependent variables
Robust learning will be measured through:
- Normal Post-test measuring transfer of learning to different problem contexts (including abstract problems).
- Delayed Post-test measuring long-term retention
- Curriculum progress and Mastery of knowledge components in the Cognitive Tutor software, including in subsequent units:
- The students’ progress through the knowledge components in the curriculum will measure accelerated future learning by reflecting the latency in mastering knowledge components and curriculum sections that build on the knowledge components and curriculum sections affected by the culturally relevant problem scenarios.
Intrinsic Motivation will be measured through:
- Hint-seeking and reading behavior in Cognitive Tutor software
- Time on task in Cognitive Tutor software
Method
This experiment began in the Fall of 2008 with a study of student interests. An interests survey was administered to high school classes in Austin ISD that contain a high proportion of diverse students, as well as at a Pittsburgh Learnlab. Structured in-depth interviews relating to student interests were conducted with around 29 of the surveyed students. Based on the results of the survey and interviews, culturally relevant problem scenarios that correspond to current problem scenarios in Cognitive Tutor Algebra I were formulated for Section 5, Linear Models and Independent Variables. Approximately 27 problem scenarios from the selected section will be replaced, with 4 variations on each problem scenario that correspond to different student interests, in order to obtain personalization. I wrote these problem scenarios while consulting with Jim Greeno and Milan Sherman; they will have the same underlying mathematics as the original Cognitive Tutor problems, with changes to the objects or nouns (what the problem is about) and the pronouns (who the problem is about). See the table above for an example of how these two changes might occur.
The culturally relevant problem scenarios were reviewed by two master Algebra I teachers. In a pilot study, 24 Algebra I students participated in think-aloud protocols where they solved five story problems with varying degrees of relevancy, that were based on Cognitive Tutor problems. Problem scenarios that students have difficulties or issues with will be reworked.
The new problem scenarios were integrated into the Cognitive Tutor Algebra software in Summer 2009 with the cooperation of Carnegie Learning. Once the new problem scenarios were placed into the software, they were used in an in vivo experiment at a Learnlab school site in Pittsburgh by approximately 50-55 randomly-assigned students during the 09-10 school year. An additional 50-55 randomly-assigned students received the regular problem scenarios. See table above for a description of the two treatment groups in this study.
To summarize, the experiment had the following progression: (1) Survey (paper & online) of student interests administered in Austin ISD and Learnlab site (2) Based on survey data, structured interviews on students' out-o9f-school interests were conducted (3) Based on interest interview, 24 students participated in think-alouds where they each solved 5 problems with different degrees of relevancy. (4) Relevant problem scenarios for Section 5 were written by Candace Walkington & Milan Sherman and reviewed by 2 master algebra teachers (5) One Cognitive Tutor Algebra unit replaced at a Learnlab site with randomized control (in-sequence) setup
Explanation
This study is situated in the new “Motivation and Metacogntion’ thrust. The foundation of this study is that relevance of problem scenarios affects robust learning during the formation situation models, defined as mental representation of relationships, actions, and events in a problem (Nathan, Kintsch, & Young, 1992), as well through intrinsic motivation (Cordova & Lepper, 1996). Our hypothesis is that personalized problems would cause students to create more detailed and meaningful situation models through enhanced problem comprehension ad implicit problem knowledge. This would in turn affect the topology of the learning event space and/or path choices, causing students to use different strategies or paths (“blue-line” vs. “red-line”) as relevant problems are more likely to help students to encode deep, relevant features and/or avoid encoding shallow, irrelevant features. Another facet of this hypothesis is that personalized problems would enhance intrinsic motivation, which would increase focus of attention on the problem, contributing both to the formation of detailed situation models as well as more general enhancement of engagement and time on task (relating to "path effects").
References
Clark, R. C. & Mayer, R. E. (2003). E-Learning and the Science of Instruction. Jossey-Bass/Pfeiffer.
Cordova, D. I. & Lepper, M. R. (1996). Intrinsic Motivation and the Process of Learning: Beneficial Effects of Contextualization, Personalization, and Choice. Journal of Educational Psychology, 88(4), 715-730.
Koedinger, K. R. (2001). Cognitive tutors as modeling tool and instructional model. In Forbus, K. D. & Feltovich, P. J. (Eds.) Smart Machines in Education: The Coming Revolution in Educational Technology. Menlo Park, CA: AAAI/MIT Press.
Nathan, M., Kintsch, W., & Young, E. (1992). A theory of algebra-word-problem comprehension and its implications for the design of learning environments. Cognition and Instruction, 9(4), 329-389.