Difference between revisions of "Help Lite (Aleven, Roll)"

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(Hints during tutored problem solving – the effect of fewer hint levels with greater conceptual content)
(Glossary)
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=== Glossary ===
 
=== Glossary ===
  
* ''Help-seeking behavior'': Help-seeking related decisions students make (whether implicitly or explicitly) while learning. These decisions affect the type of actions taken by the student (ask for a hint, search the glossary, try to solve, ask the teacher or a friend), and the duration and effort dedicated to these actions (e.g., skip the hint, skim through it, or read it thoroughly).
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* [[help-seeking behavior]]
  
 
* ''Clicking through'': The most common type of Help Abuse. When 'clicking through' students ask for more hints repeatedly, without reading the hints themselves, until the most elaborated hint ('bottom out hint' is displayed.
 
* ''Clicking through'': The most common type of Help Abuse. When 'clicking through' students ask for more hints repeatedly, without reading the hints themselves, until the most elaborated hint ('bottom out hint' is displayed.
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* ''Cognitive Tutor'': A successful family of ITS to teach Geometry and Algebra.
 
* ''Cognitive Tutor'': A successful family of ITS to teach Geometry and Algebra.
 
  
 
=== Research question ===
 
=== Research question ===

Revision as of 16:25, 31 March 2007

Hints during tutored problem solving – the effect of fewer hint levels with greater conceptual content

Vincent Aleven, Ido Roll, Kenneth Koedinger

Meta-data

PI's: Vincent Aleven, Ido Roll

Other Contributers: Ron Salden (post-doc)

Study # Start Date End Date LearnLab Site # of Students Total Participant Hours DataShop?
1 5/2006 5/2006 Wilkinsburg (Geometry) 40 90 planned date: 5/2008


Abstract

This in vivo experiment compared the effectiveness of two styles of hint sequences during tutored problem solving. The study was carried out in the Geometry LearnLab. Two conditions were compared, each working with its own tutor version. The tutor versions differed only with respect to the content of the hint sequences. A key difference between the hint sequences was that the number of hint levels was reduced from about 7 in a typical hit sequence to 2 or 3. This was achieved by removing hints that merely reminded students of their current goal within the problem, by removing hints that encouraged students to try to address their question by using the Glossary, and by being more concise in explaining how a theorem or definition could be explained. At the same time, conceptual content was added, in the form of explanations of geometry terms.


Glossary

  • Clicking through: The most common type of Help Abuse. When 'clicking through' students ask for more hints repeatedly, without reading the hints themselves, until the most elaborated hint ('bottom out hint' is displayed.
  • Hint sequence: The sequence of hints which students can browse when attempting to solve a problem. This study compared a sequence with 7 levels to one with 2-3 levels.
  • Hint level: The index of the current hint viewed within the hint sequence.
  • Hint content: The content of the hint displayed to the student.
  • Help Avoidance: A type of help misuse, in which the student avoids help when should be asking for one (for example, after repeated errors).
  • Help Abuse: A type of help misuse, in which the students asks for more help than required (for example, by asking for hint before reading the problem).
  • Bottom out hint: The last hint level in a hint sequence. Usually conveys the answer to the relevant step.
  • Metacognition: A set of skills used by the student to manage and regulate the learning process. Help seeking skills are one type of metacognitive skills.
  • Gaming the system: A behavior in which the student attempts to make progress within the curriculum without thinking through the material. Most commonly, this can be done by guessing repeatedly or by clicking through hints.
  • Cognitive Tutor: A successful family of ITS to teach Geometry and Algebra.

Research question

How is robust learning affected by shorter hint sequences with richer conceptual content?

Background and Significance

Independent Variables

Type of hints:

  • Control: Standard Cognitive Tutor hints; Including 7 levels of hints of different types: containing either domain knowledge or learning recommendations (such as 'search the glossary for ...')
  • Experimental condition: Included only 2-3 levels of hints, each of which includes only domain knowledge.

Dependent variables

The study uses two levels of dependent measures:

Assessing Help Seeking behavior:

  • Analyzing log-files against a model of ideal help-seeking behavior

Assessing domain learning

  • Learning curves while using the tutor
  •  % correct on attempts following hint requests

Due to technical and administrative errors, some of the tests are lost, and others cannot be attributed to conditions. As a result, no pre- and post-test measures can be used.

Hypothesis

Students pay more attention to short hint sequences as they feel they are more helpful and easier to understand. Thus, the shorter hint sequences reduce hint abuse, such as students’ clicking through hints until they get the answer, without paying attention to why the answer is what it is. The richer conceptual content helps them to make sense out of the tutor’s hints, reducing implicit learning and also making students more likely to attend to the hints. Thus, there are two reasons why the new hints result in better sense making and less implicit learning.

Findings

None yet. Waiting for data to be available in DataShop.

Explanation

Having informative, relevant and on-time hints provides the student an effective learning trajectory when learning-by-doing becomes to difficult. The original help sequence require the learner for more responsibility - identify relevant hints, search the glossary, etc. These activities require cognitive load. However, the updated hint sequence offer relevant instruction when required, and low on extraneous cognitive load.


Descendents

Further Information

Plans for June-Dec 2007:

  • Analyze log files


Annotated bibliography

Aleven, V., & Koedinger, K.R. (2000) Limitations of student control: Do students know when they need help? in proceedings of 5th International Conference on Intelligent Tutoring Systems, 292-303. Berlin: Springer Verlag.

Aleven, V., McLaren, B.M., Roll, I., & Koedinger, K.R. (2004) Toward tutoring help seeking - Applying cognitive modeling to meta-cognitive skills . in proceedings of 7th Int C on Intelligent Tutoring Systems, 227-39. Berlin: Springer-Verlag.

Aleven, V., Roll, I., McLaren, B.M., Ryu, E.J., & Koedinger, K.R. (2005) An architecture to combine meta-cognitive and cognitive tutoring: Pilot testing the Help Tutor. in proceedings of 12th Int C on Artificial Intelligence in Education, Amsterdam, The Netherlands: IOS press.

Aleven, V., McLaren, B.M., Roll, I., & Koedinger, K.R. (2006). Toward meta-cognitive tutoring: A model of help seeking with a Cognitive Tutor. Int J of Artificial Intelligence in Education(16), 101-30

Roll, I., Aleven, V., & Koedinger, K.R. (2004) Promoting Effective Help-Seeking Behavior through Declarative Instruction. in proceedings of 7th Int C on Intelligent Tutoring Systems, 857-9. Berlin: Springer-Verlag.

Roll, I., Baker, R.S., Aleven, V., McLaren, B.M., & Koedinger, K.R. (2005) Modeling Students’ Metacognitive Errors in Two Intelligent Tutoring Systems. in L. Ardissono, (Eds.), in proceedings of User Modeling 2005, 379-88. Berlin: Springer-Verlag.

Roll, I., Ryu, E., Sewall, J., Leber, B., McLaren, B.M., Aleven, V., & Koedinger, K.R. (2006) Towards Teaching Metacognition: Supporting Spontaneous Self-Assessment. in proceedings of 8th Int C on Intelligent Tutoring Systems, 738-40. Berlin: Springer Verlag.

Roll, I., Aleven, V., McLaren, B.M., Ryu, E., Baker, R.S., & Koedinger, K.R. (2006) The Help Tutor: Does Metacognitive Feedback Improves Students' Help-Seeking Actions, Skills and Learning? in proceedings of 8th Int C on Intelligent Tutoring Systems, 360-9. Berlin: Springer Verlag.