Engineering

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Synopsis: Technologies: Engineering: Engineering:

opportunities in wood material science and engineering. This consultation process involved eighteen funding organizations fromeight European countries

and promises about tissue engineering on a chip, stem cell analysis and possible production, 526 D. K. R. Robinson, T. Propp/Technological forecasting & Social Change 75

and engineering doctoral students coming from EU countries have firm plans to stay in the US upon the completion of their studies,

Paper Presented at the Portland International Conference on Management of Engineering and Technology, Portland, 2007.2 A. De Haan, K. Mulder, Sustainable air transport:

b Department Urban Water management Research at Eawag, Switzerland c Institute of environmental Engineering at ETH Zurich, Switzerland d Competence Center Sustainability and Infrastructure Systems

They consist of rules, standards, scientific knowledge, engineering practices, technologies and skills that determine a stable context in which highly complex system configurations can develop 12.

Instead of components, resilience engineering emphasises the meaning of practices, events and actions in the process 27.

As in resilience engineering, the dominant normative safety/risk management strategy is replaced by a natural or adaptive strategy in the new paradigm of risk management.

Resilience Engineering. Concepts and Precepts, Ashgate Publishing Ltd, Hampshire, 2006, pp. 9 17,2006. 28 T. Uusitalo, R. Koivisto and W. Schmit, Proactive risk assessment of critical infrastructures.

She graduated in environmental engineering (M. Sc. 1996) and in environmental policy (M. Sc. 1997, Lic.

Pellinen holds A m. Sc. in Engineering. 1186 T. Loikkanen et al.//Technological forecasting & Social Change 76 (2009) 1177 1186

b German Federal Ministry for Research and Education, BMBF, Germany c Fraunhofer Institute for Industrial Engineering, Germany d Fraunhofer Institute for Systems and Innovation research, Germany

was conducted by a consortium comprising the Fraunhofer Institute for Systems and Innovation research (Fraunhofer ISI) and the Fraunhofer Institute for Industrial Engineering (Fraunhofer IAO).

(automation, robotics, mechanical engineering, process engineering etc.)7. Health research and medicine 8. Infrastructure technology, urbanisation and environmental development 9. Environmental protection technology and sustainable development 10.

Walter Ganz is director and member of the Leading Circle of the Fraunhofer Institute for Industrial Engineering (IAO) in Stuttgart, Germany.

http://www. tandfonline. com/loi/ctas20 Foresight and strategy in national research councils and research programmes Per Dannemand Andersen a & Mads Borup a a Department of Management Engineering, Technical University

8 november 2009,917 932 Foresight and strategy in national research councils and research programmes Per Dannemand Andersen*and Mads Borup Department of Management Engineering

and Foresight section at thetechnical University of Denmark's Department for Management Engineering. His main areas of research are technology foresight, strategy in science and innovation, technological innovation, the interaction between industry and science,

and Foresight section at the Technical University of Denmark's Department for Management Engineering. His areas of work are systems of innovation and governance of research and innovation in the fields of eco-innovation and energy innovation.

environmental sciences, biomedical sciences, information and communication technologies, physical sciences and engineering, social sciences and humanities. 6. The single Social sciences and Humanities group of the first phase was replaced by two groups:

metal products and mechanical engineering; the forest cluster; health and well-being; and information and communication industry and services;

Synthetic biology the prospect of engineering cellular processes to operate as bioreactors, labs in a cell,

K. M. Patton/Technological forecasting & Social Change 72 (2005) 1082 1093 1089 backgrounds, from technology to specialties in consumer behavior, from engineering to anthropology,

it is interesting to note that one of the most successful has evolved now into an ERA NET‘‘Wood Wisdom''dealing with the integration of forestry and wood material science and engineering.

J. Cassingena Harper/Futures 43 (2011) 243 251 249 engineering major changes required in EU research and innovation policy in the coming years.

One is need the to avoid alienating the scientific and engineering professions, whose numbers and organisation have grown,

People can gain knowledge from the act of interpreting, reading, reverse engineering texts and other artefacts;

and Royal Academy of Engineering launched a major consultation exercise exploring risks as well as opportunities. These bodies set up an independent working group,

involving nanoscience and engineering, social science, ethics, consumer protection and environmental interests. The working group issued a call for written evidence,

the main report was Royal Society and Royal Academy of Engineering 27; the dissemination and follow-up to this is described (ands updated) at http://www. nanotec. org. uk/whathappen. htm (accessed 29/07/09;

IPTS-ISTAG, European commission, Luxembourg, 2001.27 Royal Society and Royal Academy of Engineering, Nanoscience and Nanotechnologies:

''Nanotechnologies and the royal society and royal academy of engineering's inquiry, Public Understanding of Science 16 (3)( 2007) 345 364.40 S. J. Wood, R. Jones

and consensus-building for engineering major processes of transformation. Therefore sound approaches of futures thinking will help to better address the grand challenges.

and consensus-building for engineering major processes of transformation. Therefore sound approaches of futures thinking will help to better address the grand challenges.

First, the Royal Society and the Royal Academy of Engineering in the UK have incorporated these issues into their study (commissioned by the UK government,

A Technical, Political and Institutional Map of Emerging technologies, Greenpeace Environmental Trust, London, 2003, July 14 Royal Society, Royal Academy of Engineering, Nanoscience and nanotechnologies:

even the engineering and economic feasibility has not yet been clarified. What does that mean for the technology assessment of nanotechnology?

and institutes (representing basic research on nanotechnology related phenomena, material researchers and developers, systems engineering, toxicology of nanoscopic structures,

bin engineering, the roadmapping process has influenced so positively public and industry officials that their questioning of support for fundamental technology support is muted...

vision-building and consensus-building for engineering major processes of transformation; shaping and defining research and innovation agendas (2011 FTA Conference Scientific Committee.

Notes 1. These are referred to often in project engineering as‘unk-unks 'and are similar to the ecological‘safe-fail'principle,

matching environmental uncertainty Riccardo Vecchiato a a Department of Management, Economics and Industrial Engineering, Politecnico di Milano, Milan, Italy Published online:

matching environmental uncertainty Riccardo Vecchiato*Department of Management, Economics and Industrial Engineering, Politecnico di Milano, Milan, Italy This paper explores how strategic decision-makers select

Downloaded by University of Bucharest at 05:03 03 december 2014 Strategic foresight 795 Notes on contributor Riccardo Vecchiato is Assistant professor at the Department of Management, Economics and Industrial Engineering of Politecnico di Milano

Engineering Management Journal 11, no. 1: 7 14. Entovation International. 2004. The characteristics of 5th generation management. http://www. entovation. com/assessment/fifthgen. htm (accessed December 2004.

Journal of Management in Engineering, 18, no. 3: 150 5. Larsen, A. H. 2003. Finding and re-finding transparency at Aarstiderne.

which was about building an explicit service-oriented R&d trajectory in an engineering-oriented RTO,

3. 2. The case of DSSCS Nanotechnology entails engineering matter at molecular scale, seeking novel applications of new materials and devices.

Tingting Ma is a Phd candidate in Management Science and Engineering, Beijing Institute of technology of China.

GA. He is also Professor Emeritus of Industrial & Systems Engineering, and of Public policy, at Georgia Tech, where he continues as the co-director of the Technology policy and Assessment Center.

International Journal of Applied Engineering Education 1, no. 5: 321 8. Scapolo, F.,A l. Porter,

value-adding and market creation 10-G Unpopularity of science and engineering, human resource problem,

Although there was understandably a strong focus on‘‘hard''research in science, engineering and technology, within several challenges there was also a clear role for social sciences and humanities.

and engineering and science skills PAGE 36 jforesight jvol. 15 NO. 1 2013 The project undertaken provided a national view on grand challenges that had been discussed in other settings.

B Power Engineering and Energy Saving; B Manufacturing Systems; and B Safety. The thematic area‘‘Rational Use of Natural resources''covers the following five technology areas:

Furniture, games 34 Other consumer goods 35 Civil engineering Source: Schmoch (2008) VOL. 15 NO. 1 2013 jforesight jpage 59 code C08g covering‘‘polymer electrolyte''is identified,

), 27 (Engines, pumps, turbines), 30 (Thermal processes and apparatus), 31 (Mechanical elements) and 35 (Civil engineering.

(Transport) and 35 (Civil engineering). The third hot application technology before the year 2020 is technology 32 (Transport),

20 (Materials, metallurgy), 27 (Engines, pumps, turbines) and 35 (Civil engineering. From the source technology side, technology 27 (Engines, pumps, turbines) is the hottest source technology for application to other technologies before 2020,

metallurgy), 23 (Chemical engineering), 30 (Thermal processes and apparatus), 32 (Transport) and 35 (Civil engineering). Technology 1 (Electrical machinery, apparatus, energy) is prospected also as a hot source technology, especially by South korea,

(Transport), 34 (Other consumer goods) and 35 (Civil engineering). Also, technology 23 (Chemical engineering) is prospected as a source technology for other seven technologies,

the prospected application technologies will be technologies 1 (Electrical machinery, apparatus, energy), 19 (Basic materials chemistry), 20 (Materials, metallurgy), 27 (Engines, pumps, turbines) and 35 (Civil engineering).

, apparatus, energy), technology 27 (Engines, pumps, turbines) to technology 1 (Electrical machinery, apparatus, energy), technology 35 (Civil engineering) to technology 1 (Electrical machinery, apparatus, energy),

ocean energy/seawater desalination China Integrated gasification combined cycle 35 (Civil engineering) 1 (Electrical machinery, apparatus, energy) Japan Large-area thin-film solar cells;

technology), 27 (Engines, pumps, turbines) and 35 (Civil engineering. The most intensive linkage of the interaction is source technology 27 (Engines, pumps, turbines) to application technology 1 (Electrical machinery, apparatus, energy.

) and 35 (Civil engineering), especially technologies 23 (Chemical engineering) and 27 (Engines, pumps, turbines) show higher linkage with technology 1 (Electrical machinery, apparatus, energy.

interactions across WIPO technologies for Delphi topics from Japan PAGE 64 jforesight jvol. 15 NO. 1 2013 (Civil engineering).

), 34 (Other consumer goods) and 35 (Civil engineering. Technologies 32 (Transport) and 35 (Civil engineering) especially show higher linkages with technology 1 (Electrical machinery, apparatus, energy.

Technology 27 (Engines, pumps, turbines) is also a hot source technology; the application technologies comprise of technologies 1 (Electrical machinery, apparatus, energy), 3 (Telecommunications), 8 (Semiconductors), 10 (Measurement), 13 (Medical technology), 20 (Materials, metallurgy

Figure 4 Technology interactions across WIPO technologies for Delphi topics from South korea VOL. 15 NO. 1 2013 jforesight jpage 65 engineering;

and 12 (Control) and 35 (Civil engineering) show especially higher linkages with technology 1 (Electrical machinery, apparatus, energy.

Another hot application technology is technology 35 (Civil engineering. The possible source technologies comprise technologies 12 (Control), 15 (Biotechnology), 25 (Handling) and 27 (Engines, pumps, turbines;

The possible application technologies comprise technologies 1 (Electrical machinery, apparatus, energy), 30 (Thermal processes and apparatus), 32 (Transport) and 35 (Civil engineering),

The important source technologies comprise technologies 15 (Biotechnology), 17 (Macromolecular chemistry, polymers), 19 (Basic materials chemistry), 24 (Environmental technology) and 35 (Civil engineering.

energy) comprise source technologies 12 (Control), 23 (Chemical engineering), 27 (Engines, pumps, turbines) and 35 (Civil engineering),

consumer goods) and 35 (Civil engineering. Higher linkages are demonstrated in technology 1 (Electrical machinery, apparatus, energy) to application technology 32 (Transport),

The possible cross-interacted source technologies come from source technology 12 (Control), 19 (Basic materials chemistry), and 35 (Civil engineering.

and technologies 12 (Control) and 25 (Handling) to technology 35 (Civil engineering. The content of these topics comprises‘‘Circulating fluidized bed flue gas desulfurization'',Coal gasification-based poly-generation technology'',Energy consumption analysis for construction and building environmental systems and energy saving optimization technology,

For example, The Inspec Database, produced by the Institution of Engineering and Technology (IET), contains records from the world's technical

hclin@stpi. narl. org. tw Dr Te-Yi Chan received BS, MS and Phd degrees in Computer Engineering from Chung Yuan Christian University

He received his engineering degree at Ecole Centrale (Paris). His key qualifications are Sustainability Policy analysis and impact assessment, and foresight studies.

Author Indicator Robert J Watts, Alan L Porter 14 Number of items in databases such as Science Citation Index number of items in databases such as Engineering

, NDIA Systems Engineering Conference online at, http://lincoln. gsfc. nasa. gov/trl/Nolte2003. pdf 2003.8 NASA, HRST Technology assessments.

Alan Porter is a Professor Emeritus of Industrial & Systems Engineering, and of Public policy, at Georgia Tech, where he remains Co-director of the Technology policy and Assessment Center.

and are considered today a relatively mature computational tool for solving complex engineering problems, for which the term Modern Heuristics 36 was coined.

He obtained an MSC degree in Industrial Engineering from Sabanci University. His research interests are exploration and analysis of dynamically complex systems under deep uncertainty.

He obtained a master's degree in Commercial Engineering and a Phd degree from the Faculty of economics, Social and Political sciences & Solvay Business school of the Free University of Brussels. His research focuses mainly on the multidimensional dynamics of complex systems,

He obtained his master's degree in Commercial Engineering and Phd degree from the Faculty of economics, Social and Political sciences & Solvay Business school of the Free University of Brussels. His research focuses mainly on the multidimensional dynamics of complex uncertain systems,

Kristian Borch b, Ted Fuller c a SVR, Research centre of the Flemish Government, Boudewijnlaan 30, B-1000 Brussels, Belgium b Department of Management Engineering

Currently Kristian is Head of Section in the Department of Management Engineering (DTU Man) at the Technical University of Denmark.

Nearly all of the experts from academia came from the natural sciences and engineering. Only one expert was from toxicology

engineering and technology research and development from the approximately $255 million it spent in fiscal year 1999.1.

the Nanoscale Science, Engineering and Technology (NSET) Subcommittee of the NSTC Committee on Technology (which succeeded the IWGN) called for the involvement of social scientists across the board 38

and presented a vision for progress in nanotechnology from 2010 to 2020 3. Besides redefining the R&d goals for nanoscale science and engineering integration,

from NGOS, from the physical and biological sciences, engineering, medicine, social sciences, economics, and philosophy. The report included insights from US experts in the field, examinations of lessons learned,

and engineering investigations with social science and policy research from the outset 44. This concept also stems from the NNI6

and engineering and the mass use of nanotechnology. The related future governance will be oriented on a user-centric ecosystem

and engineering brought together under the broader umbrella definition of nanotechnology. FTA ACTIVITIES were used in this early stage to facilitate a common understanding,

The US Interagency Working group on Nanoscience, Engineering and Technology (IWGN) published a worldwide study on Nanostructure Science and Technology in 1999.

and engineering under a broad definition of nanotechnology and served as the foundation in developing long-term R&d visions and strategies.

Transf. 34 (2009) 320 342.9 M. C. Roco, Nanoscale science and engineering: unifying and transforming tools, AICHE J. 50 (2004) 890 897.10 M. Roco, Possibilities for global governance of converging technologies, J. Nanopart.

Chang. 76 (2009) 1187 1197.35 C. Milburn, Nanotechnology in the age of posthuman engineering: science fiction as science, Configurations 10 (2002) 261 296.36 S. Kaplan, J. Radin, Bounding an emerging technology:

Soc. 24 (2002) 93 109.45 NSTC, National science and Technology Council, Committee on Technology, Subcommittee on Nanoscale Science Engineering and Technology, The National Nanotechnology Initiative:

inscribing and describing publics in public engagement, Minerva 48 (2010) 219 238.61 K. Braun, S. Schultz, a certain amount of engineering involved:

She holds a Phd in sociology of technology from Darmstadt Technical University and a diploma in mechanical engineering.

The impact of national traditions and cultures on national foresight processes Per Dannemand Andersen*,Lauge Baungaard Rasmussen Department for Management Engineering, Technical University of Denmark, Produktionstorvet 424,2800 Lyngby

.,Norcross, GA, United states c Industrial & Systems Engineering, Georgia Tech, Atlanta, GA, USA d Public policy, Georgia Tech, Atlanta, GA, USA e

and sector (i e. the European forest sector) that aimed to create an international research agenda, based on the recognition of long-termchallenges of this sector and the identification of gaps and opportunities in wood material science and engineering.

GA. He is also Professor Emeritus of Industrial & Systems Engineering, and of Public policy at Georgia Tech, where he co-directs the Technology policy and Assessment Center.

Challenges of user involvement in future technology analysis, Science and Public policy 37 (2010) 51 61.20 C. Lettl, User involvement competence for radical innovation, Journal of Engineering and Technology management

Proceedings of the Third international conference on Human-centred software engineering (HCSE'10), Springer-verlag, Berlin Heidelberg, 2010, pp. 111 118.29 W. Gaver, A. Boucher, S

, B. Van Wielinga, Knowledge Engineering and Management: The Commonkads Methodology, MIT Press, Cambridge, 2002.36 B. J. Witcher, R. Butterworth, Hoshin kanri at Hewlett-packard, Journal of General Management 25 (2000) 70

Proceedings of the World Congress on Engineering, 2008. S v. Marinho, C. Cagnin/Futures 59 (2014) 50 61 61

system NBIC Educational system Nanotech and science Agri-food supply ICT mathematics Infrastructures Mathematics Armed forces ICT Geology Engineering Economics Chemistry Biology

and knowledge systems that enable each other in pursuit of a common goal Nares Damrongchai obtained his MPHIL degree from the University of Cambridge, UK and a doctorate in engineering from Tokyo Institute of technology.

‘key fields'and‘priority themes'(zhongdian lingyu jiqi youxian zhuti),‘mega-engineering projects'(zhongda zhuanxiang),‘frontier technologies,

So-called mega-engineering and mega-science projects are aimed at‘leapfrogging'in key areas, while key technology programs play the role of supporting economic development,

and diffusiio of agricultural technologies 11th Five-Year Plan Mega-science Program 2006 Promote four top scientific areas Mega-engineering Projects 2006 Promote technology

and engineering projects with highly strategic national goals Date of creation unknown International S&t Cooperation Plan 2001?

provide a platform for international cooperation State Engineering Technology research Centers Provide technologies and equipment to firms Soft Science Research program Provide reliable scientific advice to national and local policy-makers Source:

The Mega-engineering Projects is missing due to lack of data. Table 3. Allocations for S&t by Central Government in main S&t programs (in million RMB) Item 2001 2002 2003 2004 2005 2006 2007 2008

One principal program, the Mega-engineering Projects is missing due to lack of data. However, though we do not know their exact size,

The 16 Mega-engineering Projects identified in the last MLP are selected clearly missionorieented to address major economic and societal needs,

973 Projects) with programs for industrial development (Mega-engineering Projects) and sectoral technology programs on a more modest scale (Key technologies Programs, 863 Projects).

whose knowleedg base is across electronic engineering and biotechnollog (Dr. Chip 2010). However, since biochips are very minor in the sector,

vision-building and consensus-building for engineering major processes of transformation and efforts to define the research agenda, setting research priorities and specialisation focus.

By 2031 global science (natural sciences, social sciences, engineering and humanities) has played a significant role in helping to build a more sustainable world by working with society to address the major challenges associated with sustainable development.

The science base of ICSU has been expanded to include strong representation of health, engineering, humanities and social sciences.

Kostoff, R. N. and Schaller, R. R. 2001)‘ Science and technoloog roadmaps',IEEE Transactions on Engineering Management, 48: 132 43.

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