1. Engineering Challenge for Sustainable World
Lecture at the National Cheng Kung University
Engineering Challenge for Sustainable World
Jung Uck Seo
October 7, 2010
Tainan, Taiwan

2. What is Engineering? The profession in which a knowledge of the
mathematical and natural sciences gained by study,
experience, and practice is applied with judgment to
develop ways to utilize, economically, the materials and
forces of nature for the benefit of mankind.
Engineering is a profession like medicine, law, etc. that
aspires to high standards of conduct and recognizes its
responsibility to the general public.

3. What is an engineer?
Engineers use their imagination and analytical skills to invent, design, and build things that matter.
They are team players with independent minds who ask, “How can we develop a better recycling system to protect the environment, design a school that can withstand an earthquake, or create cutting-edge special effects for the movies?”
By dreaming up creative and practical solutions, engineers are changing the world all the time.

4. Science, Engineering, and Technology
Scientist - Like an engineer, but a primary goal is the expansion of knowledge and understanding physical processes.
Engineer - Applies knowledge of math and the physical sciences to the efficient design and construction of usable devices, structures and processes.
Technologist - Technologists focus on direct application of established engineering principles and processes. Math, the physical sciences, and underlying engineering theory receive limited coverage. More interested in hardware and processes.
Technician - Completes a 2-year degree in a narrow technical area such as electronics, drafting, or machining.
Artisans - Training may be a combination of schooling and work experience. Examples include, welders, machinists, electricians, carpenters, painters, steel workers, and artists.

5. Engineering Disciplines
Aerospace Engineering
Agricultural Engineering
Biomedical Engineering
Chemical Engineering
Civil - Environmental, Ocean Engineering
Computer Science and Computer Engineering
Electrical and Computer Engineering
Engineering Technology and Industrial Distribution
Industrial Engineering
Mechanical Engineering
Nuclear and Radiological Health Safety Engineering
Petroleum Engineering…..

6. Engineering Functions
Research - explore, discover and apply new principles
Development - transform ideas or concepts into production processes
Design - link the generation of ideas and the production
Production and testing - manufacture and assemble components or products
Sales - market engineering products
Operations - maintain equipment and facilities
Construction - organizes bids, supervises certain components of process
Management - optimize the use of resources (equipment, labor, finances)
Education and training - teach engineering principles in university and industrial settings
Consulting - provide engineering services by alone or with other engineers.

7. Employers and Career Paths for Engineers
Industry, Self, Education, NGO, Govt., Military, Others
Career Paths:
1) Corporate ladder
2) Independent entrepreneur
3) Military or government
4) Engineering and social service aboard
5) Professor/engineer
6) Graduate work outside engineering
7) A mix of above
Industry, Self. Education, Non-profit, Fed. Govt., Military, Other Govt. Others

8. Engineering as a Profession
Engineering possesses those attributes that typically
characterize a profession:
Satisfies an indispensable and beneficial need.
Requires the exercise of discretion and judgment and is not subject to standardization.
Involves activities that require knowledge and skill not commonly possessed by the general public.
Has group consciousness for the promotion of knowledge and professional ideas and for rendering social services.
Has a legal status and requires well-formulated standards of admission.

9. Systems Engineering
An interdisciplinary field of engineering focused on how complex engineering projects should be designed and managed.
Issues such as logistics, the coordination of different teams, and automatic control of machinery become more difficult when dealing with large, complex projects.
Systems engineering deals with work-processes and tools to handle such projects, and it overlaps with both technical and human-centered disciplines such as control engineering, industrial engineering, organizational studies, and project management.

10. Electrification, Automobile, Airplane, Water Supply and Distribution, Electronics, Radio and Television, Agricultural Mechanization, Computers, Telephone, Air Conditioning and Refrigeration, Highways, Spacecraft, Internet, Imaging, Household Appliances, Health Technologies, Petroleum and Petrochemical Technologies, Laser and Fiber Optics, Nuclear Technologies, High-performance Materials
Electrification, Automobile, Airplane, Water Supply and Distribution, Electronics, Radio and Television, Agricultural Mechanization, Computers, Telephone, Air Conditioning and Refrigeration, Highways, Spacecraft, Internet, Imaging, Household Appliances, Health Technologies, Petroleum and Petrochemical Technologies, Laser and Fiber Optics, Nuclear Technologies, High-performance Materials

11. Grand Challenges for Engineering

12. What we do mean by Global Problematique?
The interconnected and interacting issues of all types which affect the becoming
of life in the global ecosystem
The uncontrollable and interacting circumstances of all types, which constrain
the timely and effective resolution of these issues.
The Club of Rome introduced the phrase “World Problematique” in 1960s. It has been
used by many persons who deal with the set of issues combining into a threat to our
common future. It is the entire framework of life on Earth and its contents as such:
(1) What we, humans, traditionally call Nature, or the environment, considered as
everything alive or not (air, land water and minerals), and see commonly as external to
human society.
(2) Contrary to the most common attitude, the global ecosystem includes our species.
Homo sapiens is not external to its natural context but definitely inside of it and utterly
depends on it for its existence. We are now the form of life that impacts most severely on
the rest of the ecosystem. It is therefore logically incorrect, when addressing the
problematique, mentally to isolate our species from its natural context.

13. Is World Sustainable? The Club of Rome Brundtland Report UNEP MDG
One Planet Many People
Role of Engineering
Role of Systems Engineering
A New Path for World Development

14. New Challenges for Engineering
Complexity…through adopting a systems approach
Uncertainty…when decision-making in the absence of complete information;
Change…by challenging orthodoxy and envisioning the future;
People…through consultation processes and negotiation to meet society’s and individual’s needs;
Limits to growth…through seeking efficient resource use, ensuring pollution control and maintaining ecosystem services;
Whole-life costs…by considering environmental and social externalities and embracing life-cycle management;
Tradeoffs…by providing optimization around a single variable to create solutions acceptable for all; and
New leadership…through building multidisciplinary / multiculture teams like symphonies.

15. Systems World
The world around us can be looked at in a variety of ways. One way is to see the world as made up from many interacting systems: weather, societal, economic, ecological, floral, faun-al, tectonic plate, oceanic, and so on. This is very much a connected view of the world: nothing is isolated and totally independent; everything is part of something bigger, and everything comprises many interacting parts – subsystems.

16. Global Crisis Crisis = Threat + Opportunity
危脅 : Threat  Global Community
機會 : Opportunity  Engineering
Crisis = Threat + Opportunity
Global Crisis
Crisis (危機) =危脅+機會
危脅 : Threat to Global Community
機會 : Opportunity for Systems Engineering
Crisis = Threat + Opportunity

17. Crisis  危機 危機=危脅( Threat)+機會(Opportunity)
Global Crisis
Crisis  危機 危機=危脅( Threat)+機會(Opportunity)

18. Global Issues
The present path of world development is generating imbalances, vulnerabilities, inequities, exclusion and polarization which constitute clear threats to the prospects of both present and future generations. The Program draws on the independent, multicultural and interdisciplinary membership of the Club to clarify the key elements of a new path for world development. It will propose new lines of thinking and action which are urgently needed to: avert the risks and consequences of catastrophic climate change; reduce the devastating impacts of human activities on ecosystems and environment and the overuse of the biological and physical resources of the planet; achieve more fairness in the distribution of vital resources and opportunities and of the costs and benefits of globalization;
Avert=

19. Global Issues - cont
Accelerate global efforts to eradicate poverty and deprivation of a growing world population; Adapt and reform the structure of international institutions to address the integrated problems of a world in rapid transformation; and broadly, to achieve equitable and sustainable world development and thus preserve international security and world peace. In order to manage the complexity of such an extensive “problematique”, the program strategy focuses successively on five clusters of interconnected issues while recognizing the linkages between the clusters. In each case, a small expert conference develops proposals for action and identifies issues for in-depth analysis through internet-based, international research networks. The five clusters are:

20. The Five Clusters
1. Environment and Resources: Climate Change, Energy Security, Ecosystems and Water.
2. Globalization: Distribution of Wealth and Income, Employment, Economic Restructuring, Trade and Finance.
3. International Development: Demographic Growth, Environmental Stress, Poverty, Food Production,
4. Social Transformation: Health and Employment, Social Change, Values, Culture, Identity and Behavior.
5. Peace and Security: Justice, Democracy, Governance, Solidarity, Security and Peace.

21. Reminding Points
Systems engineering denotes different things to different people
Social & Human factors are critical to the birth of visionary systems engineering and engineers
Systems engineering and engineers are critical to mission and programmatic success
Continuously Improving systems engineering capability is a challenging and important task for the Military services, Government agencies, and Industries

22. Systems Engineering on Global Citizenship
Systems Engineering fosters key interdisciplinary research and development on corporate citizenship and provides a framework for further academic debate on corporate responsibility in a global society.
This provides a unique forum to discuss the consequences of the social and political mandate of business firms and examines the implications of these consequences for the theory of the firm.
Systems Engineering should collaborate with various disciplines such as management studies, economics, sociology, legal studies and political science to evaluate the concept of corporate citizenship and to analyze the role of private business in global governance and the production of global goods.

23. Good Engineers are like Maestros
Instruments 1. First Violins 2. Second Violins 3. Violas 4. Cellos 5. Double Basses 6. Flutes 7. Oboes 8. Clarinets 9. Bassoons 10. Horns 11. Trumpets 12. Trombones 12. Tuba 13. Timpani 13. Other Percussion Instruments 14. Harp …..
Aerospace Bio / Biomedical Chemical Civil Computer Electrical / Electronic Environmental Industrial / Manufac. Materials Mechanical, .…. Systems ….. Others
Good Engineers are like Maestros
Aerospace Engineering, Bioengineering / Biomedical Engineering, Chemical Engineering, Civil Engineering, Computer Science and Engineering, Electrical and Electronic Engineering, Environmental Engineering, Industrial and Manufacturing Engineering, Materials Engineering, Mechanical Engineering,…. Systems Engineering

24. The Conductor
The most important person in an orchestra is conductor. He, or she does not play an instrument at all. The conductor's job, at its most basic level, is to indicate the beat of the music. Most conductors use a long stick, called a baton, to make the beat as clear as possible.
The conductor moves the baton towards several imaginary 'points' which indicate which beat in the bar the orchestra is currently
playing.
The conductor is also responsible for the preparation and rehearsal of the orchestra, and for making interpretative decisions - such as whether a certain passage should be slow, fast, soft, loud, smooth, aggressive, and so on. A conductor communicates these decisions both verbally (in rehearsal) and during the performance using
different movements, gestures, and facial expressions.

25. Interdisciplinary Engineering Fields
Are you an artist, musician, or athlete? Wouldn’t it be great to
be able to combine your talent and passion with a career? 
There are plenty of traditional, nontraditional, and
interdisciplinary fields of engineering. They might just match
up with your interests, whether they involve design,
architecture, law, business, geography, psychology, or
education.
As an acoustical engineer, you might develop a state-of-the
art sound studio, or as a sports engineer you might create
equipment that tests the performance of athletes. 
You might also work in “human factors engineering,” a
fascinating field that takes human behavior and psychology
into account in developing products and systems.

26. Systems Engineering: an Art and a Science
We can compare systems engineering to an orchestra
and its ability to perform a symphony. Most people
understand what music is, but not everyone can play an
instrument. Each instrument requires a different level of
expertise and skill. Some musicians spend their entire careers
mastering a single instrument, which is good because each
one needs to be played well. But sophisticated music involves
many different instruments played in unison. Depending on
how well they come together, they may produce beautiful
music or a terrible cacophony.

27. A Symphony is a System
Musicians practice the science of music, and follow the process of translating notes on a page to play their instruments. The maestro, lead them to connect the process of playing to the art of creating great music. Maestros do a lot more than just keep time. They: • are born with the insight into musical instruments and musicians beyond pitch, rhythm, dynamics, etc. • are necessary when the orchestra reaches a certain size and complexity • have typically mastered one or more musical instruments • may be composers • select and shape the music that an orchestra plays • interpret a composer’s music in light of the audience • strive to maintain the integrity of the composer’s intentions • organize and lead the musicians • are responsible for the success of the performance

28. Maestros and Systems Engineers
They know what the music should sound like (the look and function of a design), and lead a team in achieving the desired sound (the system requirements). Systems engineers know the fundamentals of mathematics, physics, and other pertinent sciences, as well as the capabilities of various people and disciplines: • master a technical discipline and practice multiple disciplines • understand the end game and overall objectives of the endeavor • create a vision and approach for attaining the objectives • are architects or designers • select / shape the technical issues to be addressed by multidisciplinary teams • interpret / communicate objectives, requirements, system architecture, and design • responsible for the design’s technical integrity • organize / lead multicultural/multidisciplinary teams • responsible for the successful delivery of a complex product or service The similarities between maestros and systems engineers describe the latter’s desired behavioral characteristics and capabilities.
end game=[éndɡèim] [명사] (체스·경기의) 최종회, 막판; ((일반적으로)) 최종 단계; [군사] 엔드 게임 ((적의 탄도 미사일 방어 시스템을 기만하는 수단의 일종))

29. Test like you fly, fly like you test !
Systems Engineers pay particular attention to verification and validation
Verification answers the question: “Did we build our system right?” If yes, it proves our product meets the requirements. Practice the hard-earned lesson, Validation answers the question: “Did we build the right system?” If yes, it is supposed to do, which often goes well beyond just meeting requirements.
Test like you fly, fly like you test !

30. Global Ecosystem
The global ecosystem is the entire framework of life on Earth and its
contents.
First, it contains what we, humans, traditionally call Nature, or
the environment, considered as everything alive or not
(air, land water and minerals), and see commonly as external to
human society.
Second, and contrary to the most common attitude, the global ecosystem
includes our species: Homo sapiens is not external to its natural context,
but definitely inside of it and utterly depends on it for its existence. We
are now the form of life that impacts most severely on the rest of the
ecosystem. It is therefore logically incorrect, when addressing the
global problematique, mentally to isolate our species from its
natural context.

31. Moving towards Sustainable Development
ECO-CENTRIC CONCERNS: Natural resources and ecological capacity
TECHNO-CENTRIC CONCERNS: Techno-economic systems
SOCIO-CENTRIC CONCERNS: Human capitial and social expectations
ECO-CENTRIC CONCERNS: Natural resources and ecological capacity
TECHNO-CENTRIC CONCERNS: Techno-economic systems
SOCIO-CENTRIC CONCERNS: Human capital and social expectations