design optimization

{{Main|Optimization problem}}

The formal mathematical (standard form) statement of the design optimization problem is {{Cite book|url=https://web.stanford.edu/~boyd/cvxbook/bv_cvxbook.pdf|title=Convex Optimization|last1=Boyd|first1=Stephen|last2=Boyd|first2=Stephen P.|last3=California)|first3=Stephen (Stanford University Boyd|last4=Vandenberghe|first4=Lieven|last5=Angeles)|first5=Lieven (University of California Vandenberghe, Los|date=2004-03-08|publisher=Cambridge University Press|isbn=9780521833783|language=en}}

$\backslash begin\{align\}$

&{\operatorname{minimize}}& & f(x) \\

&\operatorname{subject\;to}

& &h_i(x) = 0, \quad i = 1, \dots,m_1 \\

&&&g_j(x) \leq 0, \quad j = 1,\dots,m_2 \\

&\operatorname{and}

& &x \in X \subseteq R^n

\end{align}

where

• $x$ is a vector of n real-valued design variables $x\_1,\; x\_2,\; ...,\; x\_n$
• $f(x)$ is the objective function
• $h\_i(x)$ are $m\_1$equality constraints
• $g\_j(x)$ are $m\_2$ inequality constraints
• $X$ is a set constraint that includes additional restrictions on $x$ besides those implied by the equality and inequality constraints.

The problem formulation stated above is a convention called the negative null form, since all constraint function are expressed as equalities and negative inequalities with zero on the right-hand side. This convention is used so that numerical algorithms developed to solve design optimization problems can assume a standard expression of the mathematical problem.

We can introduce the vector-valued functions

$\backslash begin\{align\}$

&&&{h = (h_1,h_2,\dots,h_{m1})}\\

\operatorname{and}\\

&&&{g = (g_1, g_2,\dots, g_{m2})}

\end{align}

to rewrite the above statement in the compact expression

$\backslash begin\{align\}$

&{\operatorname{minimize}}& & f(x) \\

&\operatorname{subject\;to}

& &h(x) = 0,\quad g(x) \leq 0,\quad x \in X \subseteq R^n\\

\end{align}

We call $h,\; g$ the set or system of (functional) constraints and $X$ the set constraint.

Design optimization applies the methods of mathematical optimization to design problem formulations and it is sometimes used interchangeably with the term engineering optimization. When the objective function f is a vector rather than a scalar, the problem becomes a multi-objective optimization one. If the design optimization problem has more than one mathematical solutions the methods of global optimization are used to identified the global optimum.

Optimization Checklist

• Problem Identification
• Initial Problem Statement
• Analysis Models
• Optimal Design Model
• Model Transformation
• Local Iterative Techniques
• Global Verification
• Final Review

A detailed and rigorous description of the stages and practical applications with examples can be found in the book [http://www.cambridge.org/gh/academic/subjects/engineering/control-systems-and-optimization/principles-optimal-design-modeling-and-computation-3rd-edition?format=HB&isbn=9781107132672#C3r6r6aLRe2bUoef.97 Principles of Optimal Design].

Practical design optimization problems are typically solved numerically and many optimization software exist in academic and commercial forms.{{Cite book|url=https://books.google.com/books?id=wy5hBwAAQBAJ&q=design+optimization+with+matlab+achille+messac&pg=PR17|title=Optimization in Practice with MATLAB®: For Engineering Students and Professionals|last=Messac|first=Achille|author-link1=Achille Messac|date=2015-03-19|publisher=Cambridge University Press|isbn=9781316381373|language=en}} There are several domain-specific applications of design optimization posing their own specific challenges in formulating and solving the resulting problems; these include, shape optimization, wing-shape optimization, topology optimization, architectural design optimization, power optimization. Several books, articles and journal publications are listed below for reference.

One modern application of design optimization is structural design optimization (SDO) is in building and construction sector. SDO emphasizes automating and optimizing structural designs and dimensions to satisfy a variety of performance objectives. These advancements aim to optimize the configuration and dimensions of structures to optimize augmenting strength, minimize material usage, reduce costs, enhance energy efficiency, improve sustainability, and optimize several other performance criteria. Concurrently, structural design automation endeavors to streamline the design process, mitigate human errors, and enhance productivity through computer-based tools and optimization algorithms. Prominent practices and technologies in this domain include the parametric design, generative design, building information modelling (BIM) technology, machine learning (ML), and artificial intelligence (AI), as well as integrating finite element analysis (FEA) with simulation tools.Towards BIM-Based Sustainable Structural Design Optimization: A Systematic Review and Industry Perspective. Sustainability 2023, 15, 15117. https://doi.org/10.3390/su152015117

• [http://manufacturingscience.asmedigitalcollection.asme.org/issue.aspx?journalid=125&issueid=27495 Journal of Engineering for Industry]
• [http://mechanicaldesign.asmedigitalcollection.asme.org/journal.aspx Journal of Mechanical Design]
• [http://mechanicaldesign.asmedigitalcollection.asme.org/issue.aspx?journalid=126&issueid=28068 Journal of Mechanisms, Transmissions, and Automation in Design]
• [https://www.cambridge.org/core/journals/design-science Design Science]
• [https://www.tandfonline.com/toc/geno20/current Engineering Optimization]
• [https://www.tandfonline.com/toc/cjen20/current Journal of Engineering Design]
• [https://www.journals.elsevier.com/computer-aided-design/ Computer-Aided Design]
• [https://www.springer.com/mathematics/journal/10957 Journal of Optimization Theory and Applications]
• Structural and Multidisciplinary Optimization
• Journal of Product Innovation Management
• International Journal of Research in Marketing

• [https://wiki.ece.cmu.edu/ddl/index.php/Main_Page Design Decisions Wiki (DDWiki)] : Established by the Design Decisions Laboratory at Carnegie Mellon University in 2006 as a central resource for sharing information and tools to analyze and support decision-making

• Rutherford., Aris, ([2016], ©1961). The optimal design of chemical reactors : a study in dynamic programming. Saint Louis: Academic Press/Elsevier Science. {{ISBN|9781483221434}}. OCLC 952932441
• Jerome., Bracken, ([1968]). Selected applications of nonlinear programming. McCormick, Garth P.,. New York,: Wiley. {{ISBN|0471094404}}. OCLC 174465
• L., Fox, Richard ([1971]). Optimization methods for engineering design. Reading, Mass.,: Addison-Wesley Pub. Co. {{ISBN|0201020785}}. OCLC 150744
• Johnson, Ray C. Mechanical Design Synthesis With Optimization Applications. New York: Van Nostrand Reinhold Co, 1971.
• 1905-, Zener, Clarence, ([1971]). Engineering design by geometric programming. New York,: Wiley-Interscience. {{ISBN|0471982008}}. OCLC 197022
• H., Mickle, Marlin ([1972]). Optimization in systems engineering. Sze, T. W., 1921-2017,. Scranton,: Intext Educational Publishers. {{ISBN|0700224076}}. OCLC 340906.
• Optimization and design; [papers]. Avriel, M.,, Rijckaert, M. J.,, Wilde, Douglass J.,, NATO Science Committee., Katholieke Universiteit te Leuven (1970- ). Englewood Cliffs, N.J.,: Prentice-Hall. [1973]. {{ISBN|0136380158}}. OCLC 618414.
• J., Wilde, Douglass (1978). Globally optimal design. New York: Wiley. {{ISBN|0471038989}}. OCLC 3707693.
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• Uri., Kirsch, (1981). Optimum structural design : concepts, methods, and applications. New York: McGraw-Hill. {{ISBN|0070348448}}. OCLC 6735289.
• Uri., Kirsch, (1993). Structural optimization : fundamentals and applications. Berlin: Springer-Verlag. {{ISBN|3540559191}}. OCLC 27676129.
• Structural optimization : recent developments and applications. Lev, Ovadia E., American Society of Civil Engineers. Structural Division., American Society of Civil Engineers. Structural Division. Committee on Electronic Computation. Committee on Optimization. New York, N.Y.: ASCE. 1981. {{ISBN|0872622819}}. OCLC 8182361.
• Foundations of structural optimization : a unified approach. Morris, A. J. Chichester [West Sussex]: Wiley. 1982. {{ISBN|0471102008}}. OCLC 8031383.
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• 1944-, Ravindran, A., (2006). Engineering optimization : methods and applications. Reklaitis, G. V., 1942-, Ragsdell, K. M. (2nd ed.). Hoboken, N.J.: John Wiley & Sons. {{ISBN|0471558141}}. OCLC 61463772.
• N.,, Vanderplaats, Garret (1984). Numerical optimization techniques for engineering design : with applications. New York: McGraw-Hill. {{ISBN|0070669643}}. OCLC 9785595.
• T., Haftka, Raphael (1990). Elements of Structural Optimization. Gürdal, Zafer., Kamat, Manohar P. (Second rev. edition ed.). Dordrecht: Springer Netherlands. {{ISBN|9789401578622}}. OCLC 851381183.
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• Hans., Eschenauer, (1997). Applied structural mechanics : fundamentals of elasticity, load-bearing structures, structural optimization : including exercises. Olhoff, Niels., Schnell, W. Berlin: Springer. {{ISBN|3540612327}}. OCLC 35184040.
• 1956-, Belegundu, Ashok D., (2011). Optimization concepts and applications in engineering. Chandrupatla, Tirupathi R., 1944- (2nd ed.). New York: Cambridge University Press. {{ISBN|9781139037808}}. OCLC 746750296.
• Okechi., Onwubiko, Chinyere (2000). Introduction to engineering design optimization. Upper Saddle River, NJ: Prentice-Hall. {{ISBN|0201476738}}. OCLC 41368373.
• Optimization in action : proceedings of the Conference on Optimization in Action held at the University of Bristol in January 1975. Dixon, L. C. W. (Laurence Charles Ward), 1935-, Institute of Mathematics and Its Applications. London: Academic Press. 1976. {{ISBN|0122185501}}. OCLC 2715969.
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• Integrated design of multiscale, multifunctional materials and products. McDowell, David L., 1956-. Oxford: Butterworth-Heinemann. 2010. {{ISBN|9781856176620}}. OCLC 610001448.
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{{refbegin}}

• {{cite journal |title=Generating optimal topologies in structural design using a homogenization method |journal=Computer Methods in Applied Mechanics and Engineering |volume=71 |issue=2 |pages=197–224 |date=1988-11-01 |doi=10.1016/0045-7825(88)90086-2 |issn=0045-7825 |url= | last1 = Bendsøe | first1 = Martin Philip | last2 = Kikuchi | first2 = Noboru|hdl=2027.42/27079 |hdl-access=free }}
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• {{cite book |last1=Bendsøe |first1=Martin P. |last2=Sigmund |first2=O. |title=Topology optimization : theory, methods, and applications |publisher=Springer |edition=2nd |date=2013 |isbn=9783662050866 |oclc=50448149 |url=https://books.google.com/books?id=ZCjsCAAAQBAJ&pg=PR1}}
• {{cite book |editor-last=Rozvany |editor-first=G.I.N. |editor-last2=Lewiński |editor-first2=T. |title=Topology optimization in structural and continuum mechanics |publisher=Springer |date=2014 |isbn=9783709116432 |oclc=859524179 |url=https://books.google.com/books?id=B8HHBAAAQBAJ&pg=PP1}}

{{refend}}

{{Design}}

Category:Design