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A Computer Tutorial System for Introductory Physics Courses

A Computer Tutorial System for Introductory Physics Courses. Joel A. Shapiro Instructional Seminar November 15, 2001. Intelligent Tutoring Systems. Interactively helps students while they try to solve physics problems Not a homework grader Not just right or wrong

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A Computer Tutorial System for Introductory Physics Courses

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  1. A Computer Tutorial System for Introductory Physics Courses Joel A. Shapiro Instructional Seminar November 15, 2001

  2. Intelligent Tutoring Systems • Interactively helps students while they try to solve physics problems • Not a homework grader • Not just right or wrong • Models student understanding

  3. Learning by Solving Problems • Learning physics without trying to solve problems will not produce deep understanding. Independent problem solving teaches the student to • Analyze a situation • Decompose into semi-independent pieces • Examine which fundamental principles apply • Utilize these principles to find appropriate equations • Construct from these a solution to the problem • Unfortunately, these are hard to learn!

  4. What not to learn • Problem analysis is hard – students try to use a primitive problem solving method: find the right equation to plug into. • On problems too hard for that technique, without help students may give up. • Do we give in by assigning only one-step problems? This only reinforces their poor attack strategy, and is not what we want!

  5. Andes II, an ITS for Intro Physics

  6. Andes Developers • Prof. Kurt VanLehn of the Learning Research and Development Center, Univ. of Pittsburgh, and his group. This currently consists of Anders Weinstein, Collin Lynch, and Linwood Taylor, but has included Abigail Gertner and Christina Conati and others. Including me. • Members of the Physics and Computer Science Departments of the U. S. Naval Academy, including Bob Shelby, Don Treacy, Mary Wintersgill and Kay Schulze.

  7. Andes • Used in a general introductory physics course at the US Naval Academy • Currently covers mechanics through angular momentum (rotation in a plane only) • Has 115 problems of varying complexity • Problem specification requires only a small amount of programmer-style entry --- the system itself solves the problems and generates the help.

  8. Andes topics (currently) • Topics covered • Vectors • Statics (no torques) • Translational Kinematics • Translational Dynamics • Linear momentum • Rotational Kinematics • Circular motion • Torque • Angular Momentum • Work • Energy

  9. Select problem within topic

  10. Problem choosing (blowup)

  11. Opening problem presentation

  12. An example problem An inclined plane making an angle of 25.0 degrees with the horizontal has a pulley at its top. A 30.0 kg block on the plane is connected to a freely hanging 20.0 kg block by means of a cord passing over the pulley. Compute the distance that the 20.0 kg block will fall in 2.00 seconds starting from rest. Neglect friction.

  13. Problem decomposition • Draw the free body diagram for the block on the slope • Apply Newton’s second law to that block • Draw the free body diagram for the hanging block • Apply Newton II to the hanging block • Recognize that the tensions are the same, and that the accelerations are correlated • Use all the above to find the acceleration • Use the kinematics of constant acceleration to find the distance the hanging mass falls.

  14. Selecting a body

  15. Selecting body (blowups)

  16. Defining a force, part 1

  17. Specifying force’s agent

  18. Specify type Note wrong angle

  19. Finishing up force Note angle adjusted Note variable name changed Note hint to draw axes

  20. Defining axes (blowup) Axes tool New axes

  21. Defining axes

  22. Mistaken force

  23. Normal straight up?

  24. Asking what’s wrong

  25. What’s wrong (blowup)

  26. Hints on normal forces

  27. Hints (blowup)

  28. Defining an acceleration

  29. Acceleration dialog

  30. Entering equations

  31. Equations for block on incline Stricter scaffolding would require writing the first equation in terms of components, and then giving the components in terms of magnitudes and directions. The scaffolding should fade as a student demonstrates competence. Fta_x+Fw_x+Fn_x=ma*aa_x Fta_x=Fta Fw_x=-Fw*sin 25 deg Fn_x=0 aa_x = aa

  32. The second body

  33. Dialog

  34. Andes solves equations

  35. Solving for the acceleration

  36. Undefined variable

  37. Answers need correct units

  38. Right answer

  39. Problem Closed

  40. Send log of session

  41. To do next? To do next? • Describe what it takes to specify a problem in Andes. • Switch to Andes itself, and watch • one of you • all of you collectively • try one of the other problems.

  42. Andes structure • Andes contains: • a physics knowledge database, which contains basic physical principles such as Newton’s Laws, and also rules about when various constraints apply. • a database of problem specifications • A workbench for interacting with the student • A problem solver, for finding all solutions to a specified problem. • An algebra subsystem, for analyzing and solving equations. • A help system, for organizing dialog with the student.

  43. Problem Description(just comments) (defproblem exdt2a "with the horizontal has a pulley at its top." "A 30 kg block on the plane is connected to a freely hanging 20 kg block" "by means of a cord passing over the pulley." "Compute the distance that the 20 kg block will fall in 2.00 seconds" "starting from rest. Neglect friction.") :features (working Andes2 dynamics) :comments ( "Should return 60 states: 2 axes for blk30 (0 degrees & 25 degrees)" "and 2 orders for the x and y axes if the 0 degree axis is used." "crossed with resolving forces on blk30 first or blk20 first" "crossed with 10 ways to solve the kinematics sub-problem")

  44. ProblemDescription, cont. :soughts ((answer(at (mag (displacement block2)) (during 1 2)))) :givens ( (time 1) (time 2) (time (during 1 2)) (given (duration (during 1 2)) (dnum 2 |s|)) Dt = 2 s (object block1) (given (mass block1) (dnum 30 |kg|)) m1 = 30 kg (supports plane block1 (during 1 2) (dnum 25 |deg|)) (tied-to string block1 (during 1 2) (dnum 25 |deg|)) (motion block1 (during 1 2) (straight speed-up (dnum 25 |deg|))) ; for now, just tell that accel is constant so LK applies (constant (accel block1) (during 1 2)) (near-planet earth) (object block2) (given (mass block2) (dnum 20 |kg|)) m2 = 20 kg (tied-to string block2 (during 1 2) (dnum 90 |deg|)) (motion block2 1 momentarily-at-rest) (motion block2 (during 1 2) (straight speed-up (dnum 270 |deg|))) ; for now, just tell that accel is constant so LK applies (constant (accel block2) (during 1 2)) (motion block2 2 (straight NIL (dnum 270 |deg|))) )) Answer: magnitude of displacement Time points and intervals Objects need declaring Block is on plane at 25 deg tied to string at 25 deg and moves straight at 25 Acceleration is constant. Need to consider gravity String is vertical on block 2 Block starts from rest, then it moves downward

  45. PowerPoint Instructions

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