Transcript hum08.ppt

Teaching
“Technology and Society”
to Undergraduate Learners
Erol Inelmen
Assistant Professor
OUTLINE
Introduction
Background
Survey
Model
Implementation
Discussion
Conclusion
Introduction
premise
claim
evidence
Introduction
premise
Technology
should
Satisfy needs (food, shelter)
Use means (energy, robot)
Introduction
claim
Society
must
Create assets (green, culture)
Inculcate values (solidarity, respect)
Introduction
evidence
Education
can
Suggest goals (development, wellbeing)
Protect resources (soil, water)
Background : the problem
significance
consequence
control
significance
Chant (1989) points at the importance of
the “artefacts” as they reveal the “social
significance” in contexts where they have
been introduced.
Higgs et. al. (2000) claims that we need to
evolve “theories that guide us toward a
critical rather than a passive engagement
with technology and its effects in our lives
consequences
Feenberg (2002) poses the dilemma of
technology and development,
Nye (2006) discussed the idea that we
have developed
“technologies to increase our physical
power, to perform all kind of work, to
protect ourselves, to produce surpluses, to
enhance memory and extend perception ...
we have also excelled in finding new uses
for inventions, and this has had many
unexpected and not always welcome
consequences
control
Collingridge (1980) argues for the need to
understand the “diffusion” of technologies
in order to control them.
Agassi, (1985) suggest the need to
“develop the technology of controls”
Survey : the solution
integration
universality
systemics
integration
Plato, –from his Republic, VII 537warns us that “the sciences which they
learned without any order in their early
education will be brought together and
they will be able to see the natural
relationship of sciences to one another and
to true being”.
universality
Comenius -while advocating for “universal
education”- suggests the need for a)
constant practice with minimum of theory
and b) experience and observation in a
sufficiently varied form as to “prevent
boredom” (Sadler, 1966).
systemics
Following Flyvbjerg (2001) we must all take
part in the decision making of
environmental problems and learn the
“rules of the game”.
In the future “system dynamics” must be
part of any natural or social curriculum.
Nature can survive without humans, but
humans cannot without nature.
Implementation
solidarity
clarity
continuity
solidarity
Every citizen should feel the need to
develop a “social responsibility”
approach (Inelmen, 1999).
such as promoted by FAO, UNDEP, WTO,
WWF, WorldWatch. This context must be
encouraged.
clarity
“System thinking” (Buckeridge and
Inelmen, 2002) –some prefer “critical
thinking” approach to knowledge
generation.
In order to facilitate the discussion –
among participant of different
backgrounds- in class “visual thinking” is
adopted (Inelmen, 2001a).
Another tool – which is extensively
covered in another work of the author- that
helps developing new ideas and
applications, is “case based reasoning”
(Inelmen, 2001b).
continuity
Integration of all courses is a requirement
for a life-long-learning approach in
education.
Using the classification of the Library of
Congress is possible to integrate all areas
of studies basically under natural and
social sciences. (Inelmen, et al , 2003)
Model
traditional
outcome
novel
traditional
Week
Syllabus for the “Technology and Society” course
1 Time line of human needs (from shelter to communication)
2 Time line of technical achievements (from stone to silicon)
3 Technology and science (the double spiral of engagement)
4 Technology and urbanism (development of cities, the GAP project))
5 Technology and the environment (air, soil and water protection)
6 The history of ideas on technology (from Aristotle to Heidegger)
7 Technology applications (innovations in medicine and arts)
8 Philosophical discussions on technology (human wellbeing at stake?)
9 System approach to technology (the technology palette) click to see the slides
10 Controversial issues (biotechnology, nanotechnology, magnetic waves, etc)
11 Appropriate technologies (a sustainable approach to development)
12 Waste recovery and recycling technology ( the 0-waste as a target)
outcome
Pre-fixed outline may cause dissatisfaction in
both the participants and the instructor.
“There can be no excellent teaching or learning
unless teachers and learners delight in what
they are doing” (Ramsden, 1992).
novel
Model for the “Technology and Society” course
(SCIENCE)
facts
enhance
develop
(TECHNOLOGY)
means
(SOCIETY)
transform
support
(ENVIRONMENT)
resources
needs
Discussion
conservation
innovation
regulation
conservation
Our cultural heritage
(due to construction work)
and
Our physical health
(due to excessive cultivation) is
endangered
innovation
Development must be under control.
There are too many risks that affect the
health of the planet: a dialogue between all
stakeholders trying to understand the
dynamics between technology, science,
society and environment
regulation
there is a need to teach “technology
management”
The subject of “appropriate technology”
and “sustainable development” be at the
top of the program.
Conclusion
summary
caveat
legacy
Conclusion
summary
Education can raise the awareness
about the benefits/losses
caused by “technology” on “society”
Conclusion
caveat
Technology has not adressed all the aspirations
Postmodernism surged from this discontent
Conclusion
legacy
We owe next generations the right to use the same
resources of the planet
we have used
The threats originating from the excessive use of technology (Heidegger ,1977) need full consideration.
Acknowledgement
We acknowledge the guidance of
Prof. Günhan Danışman
from the History Department.
His support crystallized in a “techno-palette” framework
available on the web.
References
Meadows, D.H., et al. (1992)
“Beyond the limits: confronting global
collapse, envisioning a sustainable future”.
Post Mills, Vt.: Chelsea Green Pub.Co