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National Mission on ICT in EducationIIT Bombay
What is Project OSCAR? Project OSCAR (Open Source Courseware Animations Repository)
aims:
So far been working on creating school level animations(Classes 8-12)
We had however also created some animations of Under-graduate levels in Mechanical Engineering and Computer Science
Example: Six-bar Linkage: http://oscar.iitb.ac.in/availableProposalsAction.do?type=av&id=167&language=english
Create a large repository of web-based, interactive animations for teaching various concepts and technologies.
This could be useful not only for classroom teaching but also for enabling independent-learning and distance education.
Current goal of Project OSCAR
Focus on developing animations on concepts at Under-Graduate and Post-Graduate levels.
Attempting to create animations across all domains in Science and Engineering by following an NPTEL-like hierarchy.
National Mission on ICT in Education
Launched by the Ministry of Human Resources Development (MHRD), Government of India
Goal is to raise the levels of education in India
Indians can avail of free of cost e-knowledge contents
Spread of digital literacy to create teacher empowerment
Are animations really useful?
No formal study has been conducted yet.
Opportunity for education researchers!
Anecdotal evidence of usefulness
Enthused response from faculties & students. Case in point:
A professor had hired an
animation company to make animations for his lectures. He was
surprised to get an animation for free and that too with payment
for his TA.
Google Analytics
Google Analytics
Current OSCAR statistics
4325588-12Physics
207518UG/PGNetworking
7965UGMechanicalsimulations
2018308-12, UGMaths
8111-12Data structures and algorithms
24518-10Chemistry
485211-12Biology
Download countNo. of animationsLevelArea
Total no. of animations currently in OSCAR repository = 114
Aren't animations already available? Yes, lots of animations/videos available on the web.
You may be using them in your courses already.
Most animations are proprietary and/or have some licensing issues.Can only be viewed online.
Cannot be downloaded.
Cannot be distributed to remote colleges.
Most efforts are in bits and pieces; typically a group working in a particular discipline creates animations for their courses.
So, why yet another effort?
So...
What is different about this work?
Creative Commons license – can be freely distributed.
Open Source code – can be reviewed/extended etc.
Supported by MHRD's National Mission.
This is perhaps the first effort to create supporting material for courses on such a large scale.
Current Target – All of NPTEL and CDEEP courses.
MHRD's goal – All of higher education courses.
How do we plan to do this? Creating animations is manpower intensive:
Requires domain expertise (knowledge of subject)
Requires design expertise (visual communication)
Requires programming expertise (Java/Flash/Blender)
So far:
We trained programmers to also become subject experts and designers!
Going forward:
We need to scale (and replicate) the animation creation process.
Can be done ... with your participation!
Process overviewOSCAR PROCESS MODEL
Concept proposal Submission
Storyboard Development
Animation Design Development
Animation AppletCoding
Reviewer
Animation Inducted In OSCAR
Repository
ApprovedAnimation
1
2
3
4
5
6
Faculty: How can you participate?
Propose idea
Review Instructional Design Document
Review the animation
Faculty: why should you participate?
You will have an animation to use in your class the next time you teach the course!
These animations will be open source and will be available for free download from http://oscar.iitb.ac.in
The animations would be useful not only for classroom teaching but also for independent-learning.
Faculty who have already participated as Concept Proposers/Reviewers
1. Prof. C. Amarnath 8. Prof. K. Chebrolu
2. Prof. P.S.Gandhi 9. Prof. S. Chakrabarty
3. Prof. U.Gaitonde 10. Prof. P. Bhattacharya
4. Prof. S. Kedare 11.Prof. S. Mahajani
5. Prof. M.Atrey
6. Prof. U.Bhandarkar
7. Prof. A.Agrawal
Faculty who have expressed interest to participate
1. Prof. Pradeep P.I. 8. Prof. N.N.Viswanathan
2. Prof. A. Contractor 9. Prof. K. Ramasubramanian
3. Prof. H. Pillai 10. Prof. R. Banerjee
4. Prof. P.Sunthar 11. Prof. K. Narayanan
5. Prof. A.Dutta 12. Prof. A.K. Pani
6. Prof. R. Sunoj 13. Prof. I.N.N.Nambothiri
7. Prof. B. Tembe
Students: How can you participate? Research Scholars / Teaching Assistants /Research Assistants
Propose a concept to animate
Fill up the Instructional Design Document (IDD)
Your IDD should contain instructions of how the concept will be explained to novice viewers
Your IDD should also contain instructions of what to show for animators for e.g. Color coding, boundary conditions etc.
Mail us your filled up IDD at: [email protected]
On final approval you will earn decent honorarium
Students: How can you participate? Programmers
Register yourself as Developer at http://oscar.iitb.ac.in/OSCARPPsignupdescription.do
You are to choose an approved 'Instructional Design Document' from the list shown online
Submit the Animation Design and your source code for review.
On final approval , you will paid a decent honorarium
Your approved animation will be uploaded at OSCAR site with developer attribution going to you
Students: why should you participate? Research Scholars / Teaching Assistants /Research Assistants:
Contribute to MHRD's National Mission of ICT in Education Earn decent honorarium for each of your approved IDDs Get attribution as concept proposer in OSCAR website
Contribute to MHRD's National Mission of ICT in Education Earn decent honorarium for each of your approved animation designs In addition, win decent honorariums for each of your approved animation coding Get attribution as developer in OSCAR website
Programmers:
Details and Examples
Stage 1: Proposal Stage
OSCAR Process Stages
Stage 2: Storyboard Stage
Stage 3.1: Implementation Stage
Stage 3.2: Implementation Stage
Stage 2
IDD template and example
This is a template to create an Instructional Design Document of the concept you have selected for creating animation.
This will take you through a 5 section process to provide the necessary
details to the animator before starting the animation.
The legend on the left will indicate the current status of the document.
The Black coloured number will denote the current section, the
Turquoise color would denote the completed sections, and the Sky
blue color would denote the remaining sections.
The slides having 'Instructions' would have a Yellow box, as shown on
the top of this slide.
Instruction Slide
Write the Title of the concept here
Add Instructor/Instructors name here
Definitions and Keywords
Add the keywords with definitions which are used in this concept
Add more slides if required5
3
2
4
1
Concept details: In this section, provide the stepwise detailed explanation of
the concept.
Please fill in the steps of the explanation of the concepts in
the table format available in the slides to follow (see the
sample below).
Resize the table dimensions as per your requirements.
1
5
3
2
4
Step Details of the step
Image / Diagram Text to be displayed
Action / Motion in the step
1 The Thermoacoustic refrigerator employs high pressure waves for the required heat transfer.
The Thermoacoustic refrigerator employs high pressure waves for the required heat transfer.
Blue arrows are animated from the speaker, and white hollow arrows would move vertically. - Blue arrows should disappear by the time they reach the end of box (system)
Concept detailsStep
numberDetails of the step Image / Diagram Text to be
displayedAction / Motion in
the step
1
5
3
4
2
Interactivity and Boundary limits expected in the animation In this section provide, interactivity options for all the
parameters/components of the concept.
For example:
Numerical values to change the state of the component: By providing
input boxes
Drag and drop of components: To test the comprehension of the users
Movement of objects: To explain the action of the components
Provide the boundary limits of the parameters, which will
enable correctness of the results of the experiment.
1
5
3
2
4Interactivity option
numberDetails of
interactivityImage /
DiagramText to be displayed
Boundary limit
1 The user can move the ‘balloon’ of gas in the resonator
When the balloon is placed in high pressure region, it would shrink and its temperature will rise (it will become red). When moved to low pressure region, it expands becoming cold (blue)
....
gas
Interactivity and Boundary limitsInteractivity
option numberDetails of
interactivityImage / Diagram
Text to be displayed
Boundary limit
1
2
3
1
5
2
4
3
Questionnaire to test the user A small, (5 questions) questionnaire can be created in the
next slide, to test the user's comprehension.
This can be an objective type questionnaire.
It can also be an exercise, based on the concept taught in
this animation.
1
5
2
4
3
QuestionnaireAnswers: a) b) c)
d)
2.
Answers: a) b) c)
d)
3.
Answers: a) b) c)
d)
4.
Answers: a) b) c)
d)
5.
Answers: a) b) c)
d)
1
5
2
4
3
Links for further reading In the subsequent slide, you can provide links, which can be
relevant for the user to understand the concept further.
Add more slides in necessary
1
2
5
3
4
Links for further reading1
2
5
3
4
ADD LINKS HERE
Title of the concept, subject. Name of the author
5
ROBOT DYNAMICS & CONTROLSUBJECT : MECHANICAL ENGINEERING
NAME: PROF P S GANDHI
Mention what will be your animation medium: 2D or 3D Mention the software to be used for animation development: JAVA, Flash, Blender, Shikav, Maya..etc
Animation Medium : 2D
Software : JAVA
4
Definitions of the keywords used in the animation 6
1.PID Controller Simulation
2. Regulation
3. Tracking
PID Controller : Combining all three modes of control(proportional, integral and derivative) enables a controller to be produced which has no offset error and reduces the tendency for oscillations.
Regulation : User selects two points (if non interactive: point is already specified) and robot takes end effector from one point to another in two or three different ways without bothering about path to go from A to B
Tracking : User selects two points and robot takes end effector from one point to another in a straight line (specified) fashion. Or one point is considered centre and another on the circle that the end effector draws.
PID Controller
Let us consider the Close Loop System
Where,
Plant: A system to be controlled
Controller: Provides the excitation for the plant; Designed to control the overall system behavior
Controller Plant+
-
R e u Y
7
- The transfer function of the PID controller looks like the following:
Kp = Proportional gain KI = Integral gain Kd = Derivative gain
- The variable (e) represents the tracking error, the difference between the desired input value (R) and the actual output (Y). This error signal (e) will be sent to the PID controller, and the controller computes both the derivative and the integral of this error signal. The signal (u) just past the controller is now equal to the proportional gain (Kp) times the magnitude of the error plus the integral gain (Ki) times the integral of the error plus the derivative gain (Kd) times the derivative of the error.
- This signal (u) will be sent to the plant, and the new output (Y) will be obtained. This new output (Y) will be sent back to the sensor again to find the new error signal (e). The controller takes this new error signal and computes its derivative and its integral again. This process goes on and on.
8
s
KKsKsK
s
KK IPD
DI
P
2
dt
deKedtKeKu DIP
The Close Loop System with PID Control
Where, KP : Proportional GainKD: Derivative GainKI: Integral Gain
9
Describe the concept chosen and clearly illustrate how you want to explain the concept in the animation.
10
1. To explain how PID Controller controls manipulator ( Slides 11 to 15)
- As gain is varied animation can display how the robot links along with end effector will behave. Graph on the simulation window can be generated as the robot motion evolves in time. Interactive version: Users can change the PID gains, robot parameters interactively and observe the variation in the behavior.
2. Regulation : End effector can reach target through different paths (Slide 18)
- User selects two points (if non interactive: point is already specified) and robot takes end effector from one point to another in two/ three different ways without bothering about path to go from A to B
3. Tracking : End Effector can follow specified path (Slide 19)
- User selects two points and robot takes end effector from one point to another in a straight line (specified) fashion. Or one point is considered centre and another on the circle that the end effector draws.
Let 2DOF manipulator shown below are required to be moved from position 1 to position 2.
In this case if we use different gains we will get different outputs, which we want to demonstrate.
1
2
X
Y
Manipulator
11
For example, if we give only proportional gain, then manipulator will not reach its desired position. It will start vibrating there as shown below
2
1
2
X
Y
Manipulator
X
Y
Fig: Manipulator at initial position, Position 2 => desired output
Fig: Output due to proportional gain alone 12
When the input is proportional and derivative gain, then it will stop vibrating but there will be some offset between position of end effector & desired position 2.
2
X
Y
Fig.: PD Output ( Steady State offset)
Steady State Error
time
13
If we use PID controller then it will not vibrate ,not even if there is any offset in position. It will reach its desired position.
2
X
Y
14
-(a) => given Position of manipulator-(b) => if press P (vibration)-(c ) => if press PD (no vibration but offset)-(d) => if press PID (no vibration & offset)
Brief:
(a)
(b) (c) (d) 15
Plots If PD Controller used, there will always be some offset. Here for different derivative gains we can show its output
16
The variation with integral gain can also be plotted.
Here user will specified specific value.
17
RegulationRegulation : User selects two points (if non interactive: point is already specified) and robot takes end effector from one point to another in two /three different ways without bothering about path to go from A to B
2
1
X
Y
1 2 & => User Defined Positions
A => manipulator end effector moves from 1 to 2 through path A
B => same manipulator end effector moves from 1 to 2 through path B
One manipulator can take number of paths to reached desired target.
AB
=> Path B
=> Path A
Note: It is single manipulator following different paths to reach same targets
Figure =>
18
TrackingTracking: User selects two points and robot takes end effector from one point to another in a straight line (specified) fashion. Or one point is considered centre and another on the circle that the end effector draws.
2
1
X
Y
θ1
θ1' θ2
θ2'
X
Y
θ1
θ2
CASE I CASE II
Case I => User defines any two points (let 1 & 2), then manipulator end effector will move from 1 to 2 through straight line by adjusting angles θ1 & θ2
Case II=> manipulator end effector will move along circumference of circle by adjusting angles θ1 & θ2
Note: Points and circle are within reachable workplace
19
List out user interactions that will be there to enhance the understanding of the concept in the animation.
20
User should be able to see how different gains have different outputs. If we combine all gains like proportional, derivative and integral ,then how the
system performs? In slide 15, as mentioned the three press buttons indicates the activation of
required gain. User will simply press it with the mouse click and then be able to see its output through animation.
Regulation: Case 1: manipulator should be showed on desktop with given link and joint parameters. User can select any two points on desktop. If points are within reachable workspace then manipulator will work as explained in slides.
Case 2: If points are not within workspace then there should be certain option to ask for changing link parameters to bring points within workspace.
Tracking: User will select two points or required path. Manipulator will follow that path as explained in slide i.e. either straight line or circular etc.
A small questionnaire with answers based on the concept. 21
After going through this animation, the viewer should be able to answer simple questions like:
1) What is PID controller?A) Proportional Integral Derivative (Slide 7 to 9)
2) What will be the output if only proportional controller implements?A) Vibration (slide 12)
3) What will be the output if only proportional & Derivative controller implements?
A) Steady state offset (Slide 13)
4) What is Regulation?A) Slide No. : 18
5) What is Tracking?A) Slide No. : 19
Links for further reading/references 22
http://nptel.iitm.ac.in/ - link : - NPTEL courses>>Mechanical Engg.>>
Robotics(web)>>course content>> Robot Dynamics and control (Lecture 33)
1. http://decibel.ni.com/content/docs/DOC-2781
1. http://www.engin.umich.edu/group/ctm/PID/PID.html
Further User Specification23
1. Audio support required.2. Colour changes to be shown.4. Clear Demonstration of PID Controller output on manipulator5. Plots for different gains.6. Theory will come in the left panel of the animation or in response to pressing a 'Theory' button.7. Keywords should come in 'Glossary' section.8. 'Help' button should give stepwise instruction of how to operate the animation. (User Friendly Desktop)
Stage 3Programming process
Select from the list of approved “Instruction Design Documents”
Fill up & submit the Applet Design Document online
On approval, create the animation source code following coding
guidelines given online.
Submit the source code & class diagrams for review
On approval, animation inducted in Project OSCAR repository
Examples of animation created by Java
Examples of animation created by Flash
Examples of animation created by Blender
Examples of animation created by Shikav
Examples of animation created by Shikav
Facets of Project OSCAR
1. Contribution to Open Source
3. Curriculum and Teacher Support
2. Training Students
4. Adaptation of content
to local needs
5. Research Offshoots
What to do next?For Faculties:
a. If you have a concept in mind right now, please fill out the “Concept Definition Form”
b. Also please give contact details of your TA/RA/RS
c. In case, you want to send the concepts to animate later, please email them to : [email protected]
d. We will contact you and your TA/RA/RS to get the animation made
What to do next?
If you have a concept in mind, fill up the “Instruction Design Document Form”
If approved by your faculty, you will then have to mail us at : [email protected] the filled “Instruction Design Document”(IDD) ppt we have already mailed you by September 20,2009 to avail of the prizes.
In case, you want to send the concepts later, email the “Instruction Design Document” ppt, already mailed to you, directly to : [email protected] by September 20,2009 to avail of the prizes.
Reviewers' decision will be final and binding.
For TA/RA/RS:
This presentation is licensed under ...