Alan Blinder and Alan Kreuger's surveyAlternative Measures of Offshorability states the following:

Jobs that can be broken down into simple, routinizable tasks are easier to offshore than jobs requiring complex thinking, judgment, and human interaction. [Blinder/Krueger; 2009, 7]

Offshorability appears to be particularly prevalent in production work and in office and administrative jobs. By industry group, it is most common in manufacturing, finance and insurance, information services, and professional and technical services. More educated workers appear to hold somewhat more offshorable jobs. [Blinder/Krueger; 2009, 39]

So this begs the question, which part of my definition (see another post) of structural engineering is offshorable?  I would venture to say it is the applied science, mathematics, and code verification portion (about 20% of what we do).  Anything that can be done automatically from a computer is offshorable (analysis models, drafting, science, etc).  Everything else (design) is not.  That being said, I do not think analysis and drafting would be done well overseas without having an engineer or drafter within the locality of the project review the work.  The local experience is invaluable in our field.  For example, the outsourcing of steel drafting (called detailing) has become a major problem in the steel fabrication business.   They charge very little overseas (detailers overseas charge $5-$30/ton as opposed to $60-$80/ton locally) but there are so many mistakes that can arise by using overseas detailers.  The 20k savings of using an overseas detailer may end up costing the fabricator 40k in extra welding costs or mistakes in interpreting the AISC code.

Think about what a robot can do - that part of engineering is offfshorable.  Engineering is a complex task that involves high levels of judgment and experience.  It also involves human interactions (meeting with architects, site visits, working in collaborative teams, etc).   None of this is offshorable.  Our scientists and mathematicians may need to worry more about this issue than we do.  The applied science or code procedure portion of what we do may be considered offshorable, is only 20% maximum of what we do.   Our software will continue to do more and more code verification and analysis, but again that is still a small portion of our daily activities as an engineer.

As an example of why even the applied science portion cannot easily be done by a computer, see my article Twilight of the Idols.  It compares a terrible floor system solution from a computer to a good floor system solution from an experienced engineer.

Gordon Glegg's wonderful little book The Design of Design (1969) starts off with a bang.   The brilliant mechanical engineer and author begins his book with:

An engineer has almost limitless possibilities. He can, and frequently does, create dozens of original designs and has the satisfaction of seeing them become working realities. He is a creative artist in a sense never known by the pure scientist. An engineer can make something. He creates by arranging in patterns the discoveries of science past and present, patterns designed to fit the evermore intricate world of industry. His material is profuse, his problems fascinating, and everything hinges on his personal ability. His successes and failures become incarnate in metal. They grow up and confront him, sometimes with surprising results. A scientist can discover a new star but he cannot make one. He would have to ask an engineer to do it for him. [Glegg, 1969:1]

Well done Gordon!   Let's make a poster out of this.  If we added this to our classroom doors or our workplace walls, we replace the tired notion that science is the most rewarding profession.   Our high school students might embrace the engineering profession.    Our college students might stay in the engineering major (the reality is 50% drop out).   Our offices would surely benefit as well.   Hmm, I better add this poster idea to my manifesto.

Billy Vaughn Coen  states in "The Engineering Method" by (1984) that

Numerous studies show that the American Engineer is less well read, a better family member, more conservative politically, more oriented to the use of numbers than to general philosophical positions in making a decision, and goal oriented. [Coen, 1984]

My manifesto contained within this blog is partly a rebuke to this (except for the family part).  It doesn't challenge the perception of who we are, but who we are.   Presumptuous?   Yes, of course, after all, I did write a manifesto.   When writing it, I realize some things will come off as too simplistic and can be misleading.  It is meant to be read as a coherent whole, not piecemeal.   If I have offended anyone, I meant to, but not in the negative way.   I hope I have positively offended you!  Now please write back and offend me too at ean@structuresworkshop.com    My intent is not to provoke, but to seek truth, to be clear, to translate what I do as an engineer (when designing buildings), as an educator, and  as a citizen and human being.   It shouldn't be provocative.   In 20 years, this is all going to sound pretty straightforward and bland (this is not a goal, just a natural progression towards truth).   Also, most these ideas are not mine, I steal them.   Sometimes I don't always know where I steal them or from whom.   I am sorry about that.   I couldn't figure out where I got the idea that goals are unhealthy.   That came from within - I am really excited about that one.   The ideas about the design process were easy -  I just looked at my sent items email folder for one day.  I have read many  of these ideas before but they are scattered and not coherent.   That was why I decided to lay it all out.   It is a draft, and my manifesto will always be a work in progress… towards quality- just like engineering.

A quote taken from the "Historical Definition of Engineering" by Edwin Layton, Jr. (1984) contains the definition that engineering is the great creative science.   A prominent civil engineer, Thomas C. Clarke, held that

Science is the discovery and classification of the laws of nature. Engineering, in the broadest sense, is the practical application of such discovered laws...engineering is the great creative science. [Layton, 1984]

This is better than we are applied scientists but it still puts too much emphasis on science.      Edwin Layton agrees and states...

Engineering is a community of people who are practitioners of a creative form of cognition, engineering design, akin to that practiced by artists.   [Layton, 1984]

Our method, the engineering method, is closer to how an artist goes about their work than it is to the scientific method.   For more definitions of engineering that characterize it as an art, see Jon A. Schmidt's excellent article "Philosophy and Engineering" in Structure September 2008 issue.

In "The Engineering Method" by Billy Vaughn Coen (1984), Coen states correctly that everything in engineering is heuristic.   A heuristic is something that helps the engineer make a design choice.  

The rule of engineering is: do what you think represents best practice at the time you must decide...the definition of the engineering method depends on the heuristic; the rule of the method and the rule of judgment are heuristics...all engineering is heuristic.   [Coen, 1984]

Coen lists some sample heuristics such as:

"Engineering is trial and error" or

"Work at the margin of solvable problems" or

"The yield strength of a material is equal to a 0.02 percent offset on the stress-strain curve"   

 This is what the engineer does, this is the engineering method.   Engineering is the use of engineering heuristics.   It is as simple (or complicated) as that.   My problem with this definition is only the word "heuristic", it is too complicated.    I think it should be called "design aids" or "engineering guides" to reveal a solution to an ill-defined problem (as opposed to well defined problems of applied science).    So in this sense, engineering is a decision making process by an engineer who applies know-how and personal values (similar to my definition).

This is what I came up with…         Structural Engineering is the design of BIG things.

The know-how required to do this is immense and requires lifelong learning.  Engineers are 1% to 10% of each of the following:

• Scientists 
• Mathematicians
• Computer Scientists
• Information Seekers (State of the Art)
• Specialists in Structural Systems
• Experts in Construction
• Citizens of a Locality of Construction Practices and Material Availability
• Cost Estimators or Knowledgeable of Best Practices to Reduce Cost
• Experts of Local Fabrication and Construction Technologies
• Experts of  Building Codes, Specifications, Standards, Guides, and Regulations
• Risk Evaluators and Code Interpreters
• Experts in Structural Calculations
• Experts in three dimensional representation in the mind
• Experts in Synthesizing Complex/Unsolvable things to Simple/Solvable things.
• Experts in Analysis Modeling using Software
• Skeptics of Structural Engineering Software
• Debaters of Efficiency and Economy and Elegance
• Artists, Philosophers, Poets, Dreamers with Unconstrained Self Expression
• Drafters or BIM Specialists
• Collaborators working with Design teams
• Listeners of Vision and Needs of Project/Client/Architect
• Knowledgeable of Collaborator’s field
• Users of Rules of Thumb (Heuristics)
• Experts in the ability to make decisions under great amounts of uncertainty

Civil (Structural) Engineering is the design of big things.  Mechanical Engineering is the design of dynamic things.  Chemical Engineering the design of strange things.  Electrical Engineering is the design of invisible things.   My definition suggests Engineering is design of Big, Dynamic, Strange and Invisible things.  You might ask, well Architects design big things too don’t they?  This is correct, but they are not hired precisely because the thing is big.  We are.  This definition may contribute to a positive “rebranding” of the profession and I believe it will  improve “career appeal”, and reduce our “brain drain” if we simply and succinctly told the truth.   Why is the retention rate in engineering schools around 50%?  That is a real problem but I think it is a marketing problem.   Our educators are not good engineering mentors and they likely mislead our students into believing we engineers merely complete calculation procedures.   Engineering is so much greater than that!

This is the most common definition…

Engineers are applied scientists

No!   Scientists are applied scientists.   Our educators are applied scientists.  Scientists make sense of what exists in nature.  They test and examine nature.   Scientists discover.    Engineers take nature and make what exists outside of it.   Engineers invent, create, and make.  Engineers are makers.  Engineers are designers.  Engineers design real things.

In Alan Harris famously said in his essay Architectural Misconceptions of Engineering:

Engineering is no more applied science, than painting is applied chemestry [Harris, 1975:17]

The applied science portion of what we do is actually the easiest and most straight forward.  It is objective and has its’ own linear, step wise methodology.  That is why the young engineers are doing the calculations and the modeling, while more experienced engineers are not.   Yes, it needs to be right, so there is a lot of responsibility in this phase but that doesn’t make it difficult.   The experienced ones are doing the other 90% of what we do, the more difficult tasks, tasks that require much more than a calculation.  Design is the other 90% of engineering that is only achieved after one graduates from being a mere applied scientist (or technician) to being an engineer!

Borrowing from Donald Rumsfeld, scientific application or procedural design is about the known knowns.   Design is much more about the known unknowns.   So why do we align ourselves so closely with science?    Because it is “hard”?   Nope.  It is because we have allowed the educators of our profession to define it for us.   Our educators are not engineers, they are scientists.   That is okay, but let’s be honest about it.   Please understand, I love science, but I am as much an artist as a scientist and I suspect so are you.   They only differ from scientists in the fact that they absorb themselves in practical problems.   They are great educators and researchers and I am incredibly impressed by our educators – but they are rarely engineers.     They are really “practical” scientists.  They rarely  design big things.   Is there any other professional major where the person who is teaching the thing, does not perform the thing?  Law?  Architecture?  Medicine?  Engineering may be the only one.  Research is very different than practice but we have a system in place that rewards science and research over the richness of engineering practice.   Research is science, not engineering.   I am not saying we replace the incredible faculty we have with engineers, nor am I suggesting that the curriculum should change.   Design is learned in practice, and applied science is learned in school.   That is all fine.   I am merely describing who are educators are.  I do think our educators have the responsibility to know who we are, so this blog is for them too.

The Urgency of Engineering Education Reform by William Wulf presses this point further:

Engineering faculty are, for the most part, judged by criteria similar to the science faculty, and the practice of engineering is not one of those criteria. The faculty reward system recognizes teaching, research, and service to the profession, but it does not give the same status to delivering a marketable product or process, or designing an enduring piece of the nation's infrastructure. [Wulf, 1998]

Am I the only person who finds this strange?   Our Architecture schools are completely different.   They encourage their faculty to have their own practices.   When I interviewed for a position at an Architecture School, they asked me questions about the buildings that I designed.  The tenured faculty of architecture schools are often well known architects.   Why is it so different for us?

Here is more of the same from the National Society of Professional Engineers (NSPE)…

Engineering is the creative application of scientific principles used to plan, build, direct, guide, manage, or work on systems to maintain and improve our daily lives.

This "application of science" notion is so pervasive that it sounds like it is pretty much all that we do and suggests that our creativity is not employed for artistry, self-expression, costs, or constructability, but solely for science.   That is just plain weird – and wrong.  This is pretty disappointing and the fact that the word "design" is missing again.  Design is the defining characteristic of engineering.

The American Society of Civil Engineers unfortunately defines civil engineering (of which we structural engineers are a subset) as…  “The profession in which a knowledge of the mathematical and physical 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 progressive well-being of humanity in creating, improving and protecting the environment, in providing facilities for community living, industry and transportation, and in providing structures for the use of humankind."   

How could a definition of engineering omit the most important word – design!  This again sounds like we are merely applied scientists, which is not the case.   It is lengthy, dull, and fails to describe what we do, instead focusing on the end product, what we make.  Saying that a cook makes cake does not describe cooking very well.   

ASCE also states:

“Civil engineers make civilization possible.”

Again, this weak definition fails to describe what we do, just the end product of our work.

Another good but flawed definition from the British Institution of Structural Engineers, is…

Structural engineering is the science and art of designing and making, with economy and elegance, buildings, bridges, frameworks and other similar structures so that they can safely resist the forces to which they may be subjected.

This sounds pretty good, right?   Unfortunately, it fails completely in describing how one goes about designing.    Like all other definitions, it puts too great an emphasis on force resistance.    Yes, we proportion members based largely on forces, but that is only one of many design considerations – we also have to take construction practices, architectural constraints, client needs, and many other factors into account.  As Hardy Cross put it, "Strength is essential, but otherwise unimportant."

A popular but limited definition of structural engineering is…

Structural Engineering is the Art of molding materials we do not wholly understand into shapes we cannot precisely analyze, so as to withstand forces we cannot really assess, in such a way that the community at large has no reason to suspect the extent of our ignorance.  

This is from Dr. Brown in 1967 or Dr. Dykes in 1978 (For its history, see Jon Schmidt's "InFocus" column in the January 2009 issue of STRUCTURE, "The Definition of Structural Engineering.")  This is clever and fun but only addresses uncertainty of forces and materials.   What a limited understanding of what we do!   This applied science portion of engineering is what they teach in school, so it is a popular definition in the classroom.   Yes, we are experts in the ability to make decisions under great amounts of uncertainty, but that is only one aspect of our work.   Stress and strain are necessary calculations but represent only a small fraction of all that we do; otherwise, we could be completely replaced by a computer.  Those of us who do genuine engineering are never concerned about this.

Engineering is synthesis (evaluation of design options).   One particular framing system is chosen not because it is the truth, but because it is as close as the designer can get.   That is enough to discover that one system is better than another. You see, structural design is really not objective, not close. There really isn’t one answer; there never has been. The problem is that design is perceived that way and has an objective truth assigned to it.  Once you abolish this misconception, the creative possibilities are limitless.   See my article "Twilight of the Idols" in Modern Steel Construction Magazine for more on synthesis and an example design problem.

It could be constrained by forces of nature or analytical techniques to describe nature.   It could be controlled by local construction methods, material availability, or an engineer's own ingenuity.   A design can be borne by art and uncertainty as much as it can be borne by science and certainty.   Anyone who doesn't know this is not an engineer.  Isler created the thin concrete shell, a pillowcase shape, when he viewed burlap hanging over rebar.  The artist Kenneth Snelson developed the tensegrity by playing with sticks and strings.   The artist, Ai WeiWei created the bird's nest form used for the Beijing National Stadium for the 2008 Olympics by looking at one.  Bucky Fuller created the geodesic dome through sculpture and play.   He fooled around with stuff like triangles made out of spaghetti, not math.   The inventor Theo Jansen is the master of amazingly lifelike kinetic sculptures without math or science.  Math and science rarely contribute to the creation of the design (there are very few exceptions).    So why are we engineers not making stuff in school?   Who knows!