Scratch for Science. Computational Thinking Jeanette Wing, 2006 Core theme in CS education, more and more in other subjects Abstraction Automation eScience.

Slides:

Advertisements

Similar presentations

A new kind of science Education Lessons Learned from StarLogo and Perspectives on NKS Bakhtiar Mikhak – MIT Media Lab Bakhtiar Mikhak – MIT Media Lab Brian.

Advertisements

“TRANS”FORMATIVE ASSESSMENT 10 Key Points

Educational Technology

Dave Tucker Edinboro University of Pennsylvania. What will be covered  Are Serious games useful?  Examples.

Information and Communication Technology for Inquiry Based Science Education.

WP6K: INTERACTIVE COMPUTER ANIMATIONS M. Fatih Taşar Betül Timur Gazi Üniversitesi.

“The Scientific Ability of Young Children and the Role of the Teacher in Inquiry-based Learning Karen Worth

Thinklets and TI; Technology for Learning and Doing Mathematics Martin van Reeuwijk Freudenthal Institute Utrecht University, Netherlands.

The Beautiful Story of Logo Papert (1980) Mindstorms: Children, computers, and powerful ideas.

Programming Revisited - The Educational Value of Computer Programming Andrea diSessa (UC Berkeley) Boxer Eric Klopfer (MIT) Andrew Begel (UC Berkeley)

Powerful Ideas Constructivist Educational Techniques in Computer Programming Instruction Using MswLOGO © Copyright 2002, Tony Gauvin, UMFK.

July 2001Mara Alagic: Teaching for Effective Learning 1 Teaching for Effective Learning: Teaching for Understanding.

Summer 2001Mara Alagic: Technology in Teaching andLearning 1 Technology in Teaching and Learning Mara Alagic.

Science PCK Workshop March 24, 2013 Dr. Martina Nieswandt UMass Amherst

Theme Numeracy, Scientific Reasoning and Inquiry.

VaNTH and The Legacy Cycle: Bioengineering and Problem Based Instruction Cherie McCollough Graduate Research Assistant – VaNTH ERC University of Texas.

Using the Internet in the Math Classroom Internet Workshops, Internet Projects, Internet Inquires, & Webquests Allison Duncan Canyons School District.

By: Kayla Ford, Jessica Hogue, and Shelby Spalding TEACHING AND LEARNING WITH TECHNOLOGY IN MATHEMATICS AND SCIENCE.

Freedoms Foundation at Valley Forge American Revolution North Tour Boston, MA to West Point, NY June 26 – July 2, 2013.

Course Goal: You will learn why and how to use robotics and related technologies in your classroom. w What does this have to do with education? w What.

1 Exploring Teachers ’ Informal Formative Assessment Practices and Students ’ Understanding in the Context of Scientific Inquiry Source: Journal Of Research.

French Technology Education Curriculum Analysis & Description. UPDATE – 2008 Présenté par Marjolaine Chatoney.

Technology in Science and Mathematics Instruction Session Five EDT 612.

Chapter 11 Technology in Mathematics and Science Instruction © 2010 Pearson Education, Inc. All rights reserved.

Lawrie Hunter Kochi University of Technology Concept mapping: styles, techniques and language tasks JALTCALL June.

METAFORA Learning Approach Processes Contributing To Students’ Meaning Generation In Science Learning Roula Smyrnaiou, Foteini Moustaki, Chronis Kynigos.

Modeling Applied Mindtool Experiences with Hyperlinked Presentation Software Stephenie Schroth Jonassen, D.H. (2006). Modeling with Technology: Mindtools.

Science Writing for Learning Greg Kelly Pennsylvania State University EarthEd Workshop Aug 8-10, 2006.

Setting the Focus of TAL.  We are learning to… ◦ Develop a common understanding of the word intervention.  We will be successful when we… ◦ Make connections.

Recent Publications: Guzdial, M., Ludovice, P., Realff, M., Morley, T., Carroll, K., & Ladak, A. (2001). The challenge of collaborative learning in engineering.

Computers as Mindtools by David Jonassen Summary by David Jonassen Computers can most effectively support meaningful learning and knowledge construction.

Disciplinary Literacy for Deeper Learning Dr. Hiller A. Spires, North Carolina State University August 13, 2015.

What OLPC is good for & Not good for?. Explicit Educational purposes in mind?

Teaching and Learning with Technology in Mathematics and Science Instruction Chapter 11.

Measuring What Matters: Technology & the Assessment of all Students Jim Pellegrino.

Workshop on Teaching Introductory Statistics Session 1: Planning A Conceptual Course Using Common Threads And Big Ideas, Part I: GAISE Recommendations.

By: Tyler Wade & Troy Parrish. Prezi  individual learners construct mental models to understand the world around them  LOGO  connected with experimental.

The Evolution of ICT-Based Learning Environments: Which Perspectives for School of the Future? Reporter: Lee Chun-Yi Advisor: Chen Ming-Puu Bottino, R.

Elementary Education In a Technology Age Gregory Gates Period 5.

Open Education Resources “Open educational resources provide a learner- centered platform that authentically marries technology with education and provides.

IT’S ALIVE: DYNAMIC VISUALIZATION IN MATHEMATICS AND SCIENCE Scott A. Sinex & Barbara A. Gage Department of Physical Sciences Prince George’s Community.

USING DIGITAL OPEN-SOURCE EDUCATION RESOURCES IN THE SECONDARY MATHEMATICS CLASSROOM Presented by Dr. Paul Gray Chief Curriculum Officer Cosenza & Associates,

Learning Through Programming Kevin Joseph Staszowski Shani Bryant Alice Mello Cavallo February 19, 2004.

11.1 Chapter 11 Technology in Mathematics and Science Instruction M. D. Roblyer Integrating Educational Technology into Teaching, 4/E Copyright © 2006.

Interactive Excel Spreadsheets: A Computational and Conceptual Learning Tool for Mathematics and Science Scott A. Sinex Department of Physical Sciences.

Conclusions theory building, Emphasis on theory building, specific focus on teacher mediation: reframing socio-cultural theory was recontextualised, integrated.

The Impact of Technology on the Contemporary Classroom Shaun Rosell Kansas State University EDCI 803 Curriculum Development.

Technology Integration for the New 21st Century Learner Scratch Projects.

Chapter 7 Learning by Exploring Microworlds and Virtual Realities 報告者：楊美菁.

Technology Integration Strategies for Science Instruction Integrating Educational Technology into Teaching Roblyer & Doering.

Hablando de la Formación de Profesores de Ciencias New Trends in the Formation of Physics Teachers C ARL J. W ENNING, D IRECTOR P HYSICS T EACHER E DUCATION.

21 st Century Skills Workshop C&I Carol Brown Visiting faculty from MSITE

San Antonio Technology in Education Coalition Technology Training Model.

DESIGNING A BLENDED COURSE CMA E-Learning Day 2015 Workshop Stephen McConnachie.

Teaching & Learning with Scratch Miguel Figueiredo Department of Sciences and Technologies School of Education - Polytechnic Institute of Setúbal.

Commercialization Development Research Need Introduction.

Exploring Philosophy During a Time of Reform in Mathematics Education Dr. Kimberly White-Fredette Gordon State College Barnesville, GA.

CAT Presentation  Foss is a self-contained curriculum which focuses not only on the content of science, but also the processes as well; including.

Implementing more Spanish Language Arts Presented to School #33 Dual Language Council Presented by Adrializ Serrano.

Mansureh Kebritchi, Atsusi ‘‘2c” Hirumi Computers & Education 51 (2008) 1729–

First Due: A Tactical- Decision Game By Richard Llewellyn.

Perfect Pedagogy Developmental Psychology of a Middle School student:

Authenticity, Simulation and Metacognitive Learning

Comparison of Abstraction in Computer Coding and Critical Thinking

CAST Workshop 2007 Sinex Venturing into Computation Science and Dynamic Visualization with Excelets “Excel with a New Twist” Scott A. Sinex Department.

CAST Workshop 2006 Interactive Excel Spreadsheets: A Computational and Conceptual Learning Tool for Mathematics and Science Scott A. Sinex Department.

CS160: Lecture 6 John Canny Fall /9/2018.

Learning to Teach and Teaching to Learn via Visualization

Copyright 2002, Tony Gauvin, UMFK

Presentation transcript:

Scratch for Science

Computational Thinking Jeanette Wing, 2006 Core theme in CS education, more and more in other subjects Abstraction Automation eScience Institute, SECANT, Matter & Interactions eScience InstituteSECANTMatter & Interactions

Data Collection and Analysis Excel (Excelets, also mathematical models)Excelets Lab probes, software Commodity hardware (phones, Arduino) for data collection

Scratch for Science Limited need to teach the tool – Students pick it up faster than we do! Power of a versatile programming language Teacher-created resources Peer-created resources Assessments Simulations

Interactive Tutorials Similar to HyperCard stacks of the past More dynamic than PowerPoint Students can tweak, contribute Could take place of paper, poster

Learning Games Motivating for students – More likely to practice on own time Can be tailored to your classes' needs Students can take a part in shaping them

Modeling and Simulation "In these dynamic Turtle Microworlds, [students] come to a different kind of understanding – a feel for why the world works as it does." – Seymour Papert, 1979 Constructionism – learning through building and testing Explore unapproachable phenomena Can be made into games (motivation)

Students Creating Games They want to learn realistic physics The math can be very serious They show their friends

Potential for Data Collection, Analysis PicoBoards Arduino Scratch 2.0 Learning with Data project, Lifelong Kindergarten Learning with Data project

Clement J. (2000) Model based learning as a key research area for science education. International Journal of Science Education, 22(9), pp Colella, V. S., Klopfer, E., & Resnick, M. (2001). Adventures in Modeling: Exploring Complex, Dynamic Systems with StarLogo. Teachers College Press. De Jong, T., & Van Joolingen, W. R. (1998). Scientific Discovery Learning with Computer Simulations of Conceptual Domains. Review of Educational Research, 68(2), diSessa, Andrea (2000) Changing Minds: Computers, Learning, and Literacy, MIT Press, Boston MA Foley, B. (1999), “How Visualizations Alter the Conceptual Ecology” presented at the AERA annual meeting 1999, Montreal, Canada Foley, B. & Kawasaki, J (April, 2009) “Building Models from Scratch” Paper presented at the American Educational Research Association meeting, San Diego CA Gobert, J.D. & Pallant, A. (2004) Fostering Students’ Epistemologies of Models via Authentic Model-Based Tasks Journal of Science Education and Technology, Vol. 13, No. 1, National Research Council (2011). Report of a Workshop of Pedagogical Aspects of Computational Thinking. National Academies Press. Papert, S. (1980) Mindstorms: children, computers, and powerful ideas. Basic Books, Inc. New York, NY, US Schwarz, C. and White, B. (2005) Meta-modeling knowledge: Developing students' understanding of scientific modeling. Cognition and Instruction 23:2, pp Sherin, B., diSessa, A. & Hammer, D. (1993). Dynaturtle Revisited: Learning Physics Through Collaborative Design of a Computer Model. Interactive Learning Environments, 3 (2), Stewart, J., Passmore, C., Cartier, J., Rudolph, J. and Donovan, (2005) Modeling for understanding in science education in S. Romberg, T., Carpenter, T. and Dremock, F. (eds) Understanding mathematics and science matters pp Lawrence Erlbaum Associates, Mahwah, NJ White, B. and Fredericksen, J. (1998) Inquiry, modeling, and metacognition: Making science accessible to all students. Cognition and Instruction 16:1, pp