The “Local Educational Laboratory on and results on...
Transcript of The “Local Educational Laboratory on and results on...
The “Local Educational Laboratory on Robotics”: methodology and results on
teaching with robots
Prof. Paolo DarioThe BioRobotics InstituteScuola Superiore Sant’Anna
Pisa, Italy
WorkshopA new generationof educational robotsInternational Conference on Robotics and AutomationShanghai International Convention CenterMay 13, 2011
Table of contentsTable of contents
Motivations for using robotics in school education
Four points of strengths for teaching with robots
A few Italian actors in the field of educational robotics
The past: robotic contests (from 1991) and previous experiences with schools
The present: the “Local Educational Laboratory on Robotics”
Conclusions
Table of contents
Motivations for using robotics in school education
Four points of strengths for teaching with robots
A few Italian actors in the field of educational robotics
The past: robotic contests (from 1991) and previous experiences with schools
The present: the “Local Educational Laboratory on Robotics”
Conclusions
Motivations: skill shortage
• Educational robotics for bridging the skill gap – Necessity of scientific and technological literacy
– To mould the educational system to the real needs of the job market and meet the demand for ICT competences
The Program for International Student Assessment (PISA)
• P.I.S.A. is a system of international assessments that focus on 15‐year‐olds' capabilities in reading literacy, mathematics literacy, and science literacy.
• PISA is organized by the Organization for Economic Cooperation and Development (OECD), an intergovernmental organization of industrialized countries
• PISA begun in 2000 and is administered every 3 years.
Mean score is 500
Data refer to 2006 (mandatory school) 15 years old. The average mean is inferior to that of other European countries in all areas of literacy. In the North‐East only reaches the mean score of other countries in science literacy. In 2006, fifty‐seven jurisdictions participated in PISA.
Evaluation of literacy in Italian schools PISA Results
Italy is here!
Science Competencies PISA 2006
Japan is here!
Table of contents
Motivations for using robotics in school education
Four points of strengths for teaching with robots
A few Italian actors in the field of educational robotics
The past: robotic contests (from 1991) and previous experiences with schools
The present: the “Local Educational Laboratory on Robotics”
Conclusions
4 Points of strength of Educational Robotics
• Attractive
• Learner‐centred learning
• Several knowledge and competences developed
• Group work
From Laurea thesisLA ROBOTICA EDUCATIVA NELLA SCUOLA PRIMARIA
(Educational robotics in primary schools)By SABRIA ROSSI
ANNO ACCADEMICO 2006 – 2007
1) Attractivity
• Robots are appealing: students’ attention should not be taken for granted!
• Game aspect: importance of anthropological function of games (play = no serious consequences)
• Learning by making mistakes (self‐confidence)
• Hands‐on
• Tangible objects
2 ) Learner‐centred learning
• The student, not the teacher, is a the centre of the educational activity
3 ) Knowledge and skills developed
• Science and technology– Scientific method: observation, hypothesis, verification, general rules
– Engineering and computer science– Biology– Physics– Mathematics– Logics– Language– Art: to draw what has been done
4 ) Group work
• At that age egocentrism is very strong and working in groups help to form a model of work
• To learn to listen, discuss negotiate
• Possibility to strengthen relationships within the group
A model of education and training at Graduate Level
Educating the Engineer of the 21st Century
able to manage new challenges and opportunities for Society and
Industry
A model of education and training at Graduate Level
Traditional Engineering Education
In many new areas, the identification of new possible products and services is strictly related to a deep understanding of the physical properties of materials.
At the same time, in such areas, scientific knowledge is the result of sophisticated engineering principles.
Engineering and Science are strictly interconnected
Modern engineering is more and more “science‐based”
Product specifications
Design
Factory, organization, management
Product
Mar
ket?
Problem (curiosity and application driven)
Scientific knowledge (Discovery)
Going beyond traditional engineering education
Historical Milestones of Technology and Historical Milestones of Technology and Mathematics Leading to Cellular SystemsMathematics Leading to Cellular Systems
1844
TelegraphMorse
1870
ElectromagnetismMaxwell
1888
ElectromagneticwavesHertz
1896
WirelesstelegraphyMarconi
1904
Electron tube Fleming
1925
RadarAppletonBarnett
1948
TransistorBardeenBrattain
Shockley
1981
Analogcellular
SystemsNMT andAMPS arelaunched
The age ofDigital
CellularSystems isstarting, firstGSM call in
Helsinki
1876
TelephoneBell
1917
1947
CellularsystemconceptAT&T
1958
IntegratedcircuitsTexas
Instruments
1971
The firstmicro
processorIntel 4004
FourierAnalysisFourier
InformationTheory
ShannonSamplingTheoryNyquist
1928
SpectralAnalysisWiener
1930
Algorithms andcomputation
Turing
1936 1948
EstimationTheoryWiener
1942
1940
First concepts forspread spectrum
systems
1822
TeletrafficTheoryErlang
Digital signalprocessor
TexasInstruments
1983 1991
CodingTheory
Hamming
1950
FastFourier
TransformCooleyTukey
1965
MarkovChain
StochasticProcessMarkov
1900
PoissonProcessPoisson
1837
1933
FMmodulationArmstrong
GaloisField
Galois
1846
Courtesy of Nokia
The model of “science‐based engineering” requires creativity and problem‐solving capabilities.
We want to educate truly innovative engineers, able to invent and to solve “ill‐posed problems”, instead of well‐structured ones.
Product specifications
Design
Factory, organization, management
Product
Mar
ket?
Problem (curiosity and application driven)
Scientific knowledge (Discovery)
Invention
Prototypes, experiments
Specifications
The new engineer of the XXI Century: scientist, inventor, entrepreneur
Going beyond traditional engineering education
Table of contents
Motivations for using robotics in school education
Four points of strengths for teaching with robots
Some Italian actors in the field of educational robotics
The past: robotic contests (from 1991) and previous experiences with schools
The present: the “Local Educational Laboratory on Robotics”
Conclusions
Association: “La Scuola di Robotica”
Foundation “Mondo Digitale”
Institute for Educational Technologies
• Objective: to study educational innovation in relation to ICT
http://www.itd.cnr.it/
Italian team@RoboCup• Silver medal for the football competition!
• Among the first 10 teams in the dance competition (first time!)
• And no. 33 in the rescue competition (second time!)
RoboCup 2010 was held at the Suntec Singapore International Convention and Exhibition Centre, on 19‐25 June, 2010. http://www.robocup2010.org/
www.robotechsrl.com
Italy (2 launches, Aug. 2005 & Aug.
2006)
Poland (Mar. 2006)
Japan (Mar. 2006)
Spain (Sep. 2006) Netherlands (Jan. 2007) Portugal (Mar. 2007)
ITALY17%
JAPAN58%
POLAND5%
SPAIN5%
ITALY 27%
NETHERLAND8%
For more than 120.000 robots
RoboTech srlEdutainments robots and more…
Brasil (May 2008)
i‐Droid01Humanoid robot in kitDistributed by DeAgostini
I‐Droid funtionalities• I‐Droid01 is a commercial product
currently distributed worldwide as a collection in newspaper kiosks by De Agostini, an Italian publisher with branches in 30 countries.
• The collection includes 90 issues, each issue includes:– robot components, such as motors,
sensors, plastic parts, electronic components or software;
– a magazine with articles disseminating robotics, technical articles, didactics articles and instructions for assembling the robot.
A successful example of educational
robot (commercial product). The
robot is sold in pieces…you have to
assemble it!
RoboTech srlEdutainments robots and more…
• Scuola Superiore Sant’Annaspin‐off company
• Winner of the “The Fifth EURON/EUnited Robotics Technology Transfer Award” with “I‐Droid 01, a programmable humanoid robot for edutainment robotics” (Prague, March 28, 2008)
Table of contents Motivations for using robotics in
school education Four points of strengths for teaching
with robots A few Italian actors in the field of
educational robotics The past: robotic contests (from 1991)
and previous experiences with schools
The present: the “Local Educational Laboratory on Robotics”
Conclusions
• Participants: graduate and undergraduate students (mainly vocational studies or polytechnic secondary schools )
• Task: to find out sources of gas, light and other in a partially structured environment (shape and color of obstacles known)
• Main features:– No use of microprocessors– Custom electronics– Fully designed and developed
by students– Preparatory activities included:
• Theoretical as well as hands‐on meetings
A bit of history…
ICAR ‘91
Autonomous microrobots competition in Nagoya
Contest Ground
International Micro Robot Maze Contest, Nagoya, Japan(POLLICINO, Climbing Microrobot Category, 1995-2001)
Sponsored by: - Japan Society of Mechanical Engineers
- Nagoya University- IEEE Robotics and Automation Society
Results: 3 first prizes (1995, 96, 00)2 second prizes (1997,99)1 third prize (1998)
Pollicino
A'
B'C'
C
O
wheel rotorstator
coil
LEGENDA
outlet current in coil
inlet current in coil
verse of magnetic flux
star shaped stator
wheel rotorA
B
Contest in Nagoya
Autonomous microrobots competition in Nagoya
RoboCasa supported the travel of the accompanying researcher
In the framework of Expo 2005, a group of students participated in the Micro Robot Maze Contest in Nagoya (August 12, 2005), with an autonomous microrobot, one
cubic inch in size
The competition
Our team was finalist in the category “autonomous robots”
Autonomous microrobots competition in Nagoya
Preparing the final.
Other teams were from Japan, Thailand and Korea.
The competition
Our team was finalist in the category “autonomous robots”
Autonomous microrobots competition in Nagoya
Preparing the final.
Other teams were from Japan, Thailand and Korea.
Educating young researchers through BIG CHALLENGES
Learning by doingLunar robotics challenge organised by the European Space Agency
Opening regularly our labs to schoolchildren and teachers (since 2002)
Annual PSV opening to citizenship
Annual PSV opening to schools of the Valdera area
PSV opening to best students of the Valdera area
Old and New Crafts Day ‐ in Perignano di Lari (LI)
November 30, 2008
Educational program with schoolRobotic services in DOMOCASA (Nov.2009 ‐May 2010)
“Alternating Studying and working” Project
LICEO SCIENTIFICO LICEO SCIENTIFICO ““FEDERIGO ENRIQUESFEDERIGO ENRIQUES””
2 stages of 4 working days each, with 2 students (age 16‐17) and 2 students (age 17‐18)
• 31/03/2009‐03/04/2009 + 21/04/2009‐24/04/2009
• Programming a microcontroller
• Measuring force in an octopus tentacle
• Electronics: basic principles and component fabrication
“Scientific Coffee or aperitif”meetings
Istituto Tecnico Commerciale Pacinotti Pisa. Visit @PSV , January, 21, 2009
Liceo Scientifico XXV Aprile PontederaVisits @PSV , November 17, 2009
Established collaborations
Robotic competitionECCE ROBOT ‘09 :National Certification (Ministero dell’Istruzione) as National competition for improving excellences (D.m. 17/06/09)
Italian activities• Torino, March 2010
• National meeting for analysing how to bring robotics to schools
• Robotics for improving:– Scientific and mathematic competences
– Logic and linguistic competences
– Didactics skills such as: team working, problem‐solving, peer‐to‐peer education.
C:\Users\Francesca\Desktop\ludoteca\locandina_jrobot.jpg
Official document from Italian Ministry of Education and University (2009)
Robotics has been acknowledged by the Ministry of Education and University as a new technology that can support educational activities in mandatory schools, especially for improving technological and scientific
literacy
SSSA and National Project on Educational Robotics
September 2010National project for promoting robotics as educational tool for schools. Funded by MIUR and private entities (l’Unione industriali Camera di Commercio)
Direttiva 30 novembre 2009, n. 93
ESOF Torino, 3 luglio 2010
Table of contents
Motivations for using robotics in school education
Four points of strengths for teaching with robots
A few Italian actors in the field of educational robotics
The past: robotic contests (from 1991) and previous experiences with schools
The present: the “Local Educational Laboratory on Robotics”
Conclusions
The local area: Valdera
• Unione Valdera is a consortium of 15 municipalities in the Pisa province, which provides social and educational services for citizens, families and schools and promotes cultural and artistic activities.
Tuscany
Valdera
Peccioli
Robotics for a new Era of Economic and Social Development in Valdera : the “Robot‐Era Project”
• Industrial and service robotics for promoting economic and social development of the Valdera Area in the following fields:– Industrial (Piaggio,…)
– Manufacturing (Furniture,…)
– Agriculture (Olive oil, Wine,…)
– Social (Healthcare, public services,…)
• Educating young and adult people in deploying and using robotic technologies to promote the development of Valdera.
• Collaborations and synergies between municipalities, university, schools, enterprises, banks, citizens, investors, stakeholders,…
Why the Valdera area?
Agreement for an
educating community25 Nov. 2010
Agreement for an
educating community25 Nov. 2010
Union of the municiaplities of: 1.BIENTINA, 2.BUTI, 3.CALCINAIA, 4.CAPANNOLI, 5.CASCIANA TERME, 6.CHIANNI,7.CRESPINA, 8.LAJATICO, 9.LARI, 10.PALAIA, 11.PECCIOLI, 12.PONSACCO, 13.PONTEDERA, 14.SANTA MARIA A MONTE 15.TERRICCIOLA
Union of the municiaplities of: 1.BIENTINA, 2.BUTI, 3.CALCINAIA, 4.CAPANNOLI, 5.CASCIANA TERME, 6.CHIANNI,7.CRESPINA, 8.LAJATICO, 9.LARI, 10.PALAIA, 11.PECCIOLI, 12.PONSACCO, 13.PONTEDERA, 14.SANTA MARIA A MONTE 15.TERRICCIOLA
Our Proposal to the Valdera Community
School Network “Costellazioni”
Scuola Superiore Sant’Anna
Polo Sant’Anna Valdera
November 25, 2010 November 25, 2010
“Agreement for Community Education”: • to define a common educational plan to follow
the trajectories of the scientific territorial development.
• Signed by – Unione Valdera; – Scuola Superiore Sant’Anna, – “Rete Costellazioni”‐ a territorial net of schools ‐, – Pont‐Tech– the Administration of Pisa
• Objective: to encourage the creation of an integrated training system based on Territorial Educational Laboratories with a shared planning in order to distinguish further the public school.
Pilot Schools
• 2 upper secondary institutes in Pontedera– Pedagogical– Industrial and technical institute
• 2 secondary schools– Pontedera– Capannoli
• 2 elementary schools– Lari – Fauglia
Local Laboratory on Robotics: Educational Offer
Integrated Institutes
Upper secondary Institutes
Involvement of children/teenagers form 3 to 19 years oldInvolvement of children/teenagers form 3 to 19 years old
Prelimnary Meetings
between robotic researchers and
teachers/ organisational
activities
Prelimnary Meetings
between robotic researchers and
teachers/ organisational
activities
Sept. 201
0
Feb. 201
1
Feb.20
12
Sept. 201
1
LELR starts with few selected schools
LELR starts with few selected schools
LELR: full start (all schools)
LELR: full start (all schools)
Feb. 201
3
Sept. 201
2
Sept 201
3
RevisionRevisionRevisionRevision RevisionRevision
Teachers Training Courses: ‐Refresher courses
‐Stage periods @ SSSA
Teachers Training Courses: ‐Refresher courses
‐Stage periods @ SSSA
teachers
teachers
studentsstudents
LELR: full start (all schools)
LELR: full start (all schools)
Teachers Training Courses: ‐Refresher courses
‐Stage periods @ SSSA
Teachers Training Courses: ‐Refresher courses
‐Stage periods @ SSSA
2013‐1014 School Year start:
LELR fully defined and structured
2013‐1014 School Year start:
LELR fully defined and structured
Direct involvement of SSSA Teachers trained and autonomous
A possible scheme of action
SSSA toy‐robots for ELRName Main features Cost Availability
Pleovery Pleo is autonomous.
ifferent kinds of sensors
on programmable
€300 1 owned by SSSA
Available on the market
AIBOntertaining Robot
rogrammable
ifferent kinds of sensors
nternet wireless communication
€2000
(non in commercio)
3 owned by SSSA
No more available on the market
I‐Droidrogrammable Robot
pen platform,
ifferent kinds of sensors
oice recognition
€ 800 3 owned by SSSA Distributed in Europe by De Agostini
Robo designer
evelopmental kit
kinds of sensors
€130 Distribuited in Europe by SSSA spin‐of Robotech Srl
Nao
igh level platform
5 DOF
ighly sensorized
€ 12000 1 owned by SSSA
Available on the market
LELR results on teaching with robots, so far…
1. Robotics for learning nature
Primary schoolPrimary school
Teaching Science with robots
Number of students 15‐20
Age7‐11 years old (transversal laboratorial group where the cooperative learning is implemented)
Number of hours 20
Description
• This project was developed in 2011, and it based on the concept that robotics could be useful for learning on nature.• Starting from the study of living being, new scientific theories are developed and then implemented on a robotic platform.
Robotic platforms Lamprey robot and cricket robot developed by SSSA
Teaching SCIENCE with RoboticsTeaching SCIENCE with Robotics
Nature-Science
Robotics Scuola Superiore Sant’Anna
Schools and teachers
Stefano OrofinoGabriella Bonsignori
Tutors
Different steps with subsequent discussion/activities in class:
• Why learning from the Nature?•Why SSSA fabricated a cricket and a lamprey robot?•Robots presentation: how lamprey and cricket robots work?•Which animal do you would like to replicate? Why?
Istituto comprensivo Mariti FaugliaProf. Silvia Coppedè - TeacherDott. Gabriella Bonsignori – BiologistEng. Stefano Orofino - Roboticist
Teaching SCIENCE with RoboticsTeaching SCIENCE with Robotics
2. Introduction to robotics
Primary schoolPrimary school
Introduction to robotics
Number of students 18
Age 7 years old
Number of hours 20
Description
• This project will be developed in 2011• Build old toys and study differences between old and new toys• Introduction to robotics• Laboratory hours with Bee‐Bot
Robotic platform
RoboDesigner
Phase 1: old and new toysPhase 1: old and new toys
• Objective: to discover our grandparents’ toys
http://errecomerobot.blogspot.com/
Francesca CecchiTutor
Phase 2: What is a robot?Phase 2: What is a robot?
Objective:
• to learn what is a robot and what are its main components
• Speaking about Artificial Intelligence by Eliza
http://errecomerobot.blogspot.com/
Phase 3: First robotic platform, BeeBotPhase 3: First robotic platform, BeeBot
• Objective: learn first steps about programming a robot
http://errecomerobot.blogspot.com/
Phase 4: Second robotic platform, RobodesignerPhase 4: Second robotic platform, Robodesigner
• Objective: to learn about hardware and software components
http://errecomerobot.blogspot.com/
Secondary schoolSecondary schoolRobotics: an interdisciplinary approach, from da Vinci machines to sci‐fi
Number of students ≈60
Age 11‐13 years old
Number of hours 40
Description
1. Comenius project (European project): “Home sweet home”, the house of the Future
2. Physical education: Study of human movement
3. Technology: introduction to robotics and on mechanical transmissions
Additional Subjects:• Italian Literature: reading of fables/legends (e.g. The Golem),
sci‐fi short stories and/or novels (i.e. Asimov, Philip Dick, Frederic Brown); vision of excerpt from the following movies: Blade Runner, Frankenstein, Edward scissors hands); creative writing (tales with robots as characters)
• Art: imagining and depict bad/good robots.
• The 2 C in the “Scuola Media” in Capannoli worked on the house in the future, in detail on the use of domotics in modern houses.
• Visits:– the Sant’Anna laboratories (easy and intuitional lessons on robotics)
– the domotic house at Peccioli
• At the end of this project they built a small house robot
1. Comenius project: Home Sweet home1. Comenius project: Home Sweet home
http://www.comenius.tv
Filippo CavalloFrancesca Cecchi
Tutors
• Final meeting in Bocholt, May 10‐15
• Nao robot will be the actor of a monolog of I Robot by A. Binder
• Three students have registered the monolog and will give the voice to the robot
1. Comenius project: Home Sweet home1. Comenius project: Home Sweet home
http://www.comenius.tv
2. Study of human movement Physical Education and Science Activity
2. Study of human movement Physical Education and Science Activity
(1) From the idea of Leonardo da Vinci (1452‐1519), “Studio di articolazioni del braccio”
Skeleton arm actuation by using springs and wires.
(2) Theoretical and practical study of the upper and lower limb dofs.
Martina CosciaMarco D’AlonzoDario Martelli
Tutors
(3) Motion analysis in medicine and sport.Practical application: kinematic and electromyographic analysis of an athletic gesture carried out by children in our lab.
2. Study of human movement Physical Education and Science Activity
2. Study of human movement Physical Education and Science Activity
Bassi Luciani LorenzoGhionzoli Alessio Monaco Vito
Tutors
3. Introduction to Robotics and mechanical transmissions Technical Education and Science Activity
3. Introduction to Robotics and mechanical transmissions Technical Education and Science Activity
OBJECTIVES:
• To develop an understanding about science and technology as related to robotics:- state of the art on Robotics- explore the question of what the robot is
• To introduce various technical components related to the developement of robots- sensors- power source - mechanical transmissions (gears, belts, chains,…)- actuators- computer programming
• To allow the students to have practical experience with basics components: what beyond black box?
- To think about an application concerning principles of Robotic
• Developement of a gear system (season clock)- to introduce a basic understanding on mechanical transmissions - materials and methods
3. Introduction to Robotics and mechanical transmissions Technical Education and Science Activity
3. Introduction to Robotics and mechanical transmissions Technical Education and Science Activity
Number of class: 2, each composed by 20 studentNumber of lessons: 4, each one of 4 hours
Season Clock• Activity 1) We lerned about gears
- to recognize gears in terms of topology and size.
• Activity 2) We lerned about direction of motion- to understand the direction of rotation of two or more gears.
• Activity 3) We lerned about gear ratio- to determine the gear ratio with simples mathematical calculations.
• Activity 4) Application of learned “know how”- to define n° of gears, n° of thets, morfology and dimension of gears to develop a
Season Clock.
• Activity 5) Laboratory activity- to learn by hand-work: use of wood board, hammer & nail, screwdriver & screw.
3. Introduction to Robotics and mechanical transmissions Technical Education and Science Activity
3. Introduction to Robotics and mechanical transmissions Technical Education and Science Activity
3. Introduction to Robotics and mechanical transmissions Technical Education and Science Activity
3. Introduction to Robotics and mechanical transmissions Technical Education and Science Activity
Upper secondary school: Industrial and technical instituteUpper secondary school: Industrial and technical institute
1. development of subsystems with nutchip microcontroller.• A small group of students (fourth and fifth year) started working on the Nutchip. • The Nutchip is a microcontroller by Atmel, programmable through a software that works on state tables and with the possibility to manage four input and four output. • New subsystems will be developed for the remote control of a robot and successively a device will be designed able to optimize the elaboration resources of the Sumo‐Bot by means of a parallel control of the motors.
1. Robotic hand• The objective is to develop a robotic hand thanks to the machines owned by the institute: lathe, milling machine, numerical control machine.• Make the hand moving through pistons, springs, …
3. assembly, programming and development of simple robots. 4 commercial Robot Kits: SumoBots, Sumovore MiniSumo Robot Kit and
Mark IIIActivities:
• Assembling the kits • Programming competitions among different robots• Programming some functions on them like light or trajectory tracking • Improving robots performances in terms of their motor programs
The school attended the national robotic competition ROBOFESTA in Pisa, January 15, 2011 with 4 robots
• Third price in group robotic competition• First price for best software implementation (single
student)
The school attended the national robotic competition ROBOFESTA in Pisa, January 15, 2011 with 4 robots
• Third price in group robotic competition• First price for best software implementation (single
student)
• Activities on Robo‐ethics • Transversal group (17‐19 years old)
Upper secondary school: Industrial and technical instituteUpper secondary school: Industrial and technical institute
Activities on RoboEthicsIntroductory seminars and workshps in schoolsApprox. 800 students participatedSupervision of indipendent activities carried out by professorsTopics that rised more interests among students:Robotics and workplacesMilitary roboticsNeurorobotics
High school specializing in education (2 classes of students attending the final year: leaving examination).
Topic: Robotics as a paradigm of interdisciplinary approach
Upper secondary school: pedagogical
Upper secondary school: pedagogical
Didactic laboratory development
Main topics
Upper secondary school: pedagogical
Final numbers of 2010‐2011
Numbers of teachers involved 13
Number of classes involved 15
Number of students involved ≈220
Number of SSSA tutors involved 15
Number of hours 60
Table of contents
Motivations for using robotics in school education
Four points of strengths for teaching with robots
A few Italian actors in the field of educational robotics
The past: robotic contests (from 1991) and previous experiences with schools
The present: the “Local Educational Laboratory on Robotics”
Conclusions
In conclusion….1. To promote an interdisciplinary approach in
educational robotics– To overcome rigid divisions between subjects, fostering a trans‐disciplinary approach
• E.g. especially to overcame division between humanistic and techo‐scientific cultures
– To foster:• “systemic vision” of reality (i.e. interacting systems, feed‐back)
• critical thinking• curiosity• management of complexity
In conclusion….
2. To include ethics in educational robotic projects allows:– To build “critical instruments” fitted to an increasing complex and ever changing world
– To foster critical reflection on techno‐scientific developments
• E.g. implications on the natural environment, weak living beings (animals and plants) and on human beings
Thank you for your attention!