Abstract
The concepts of structural behavior analysis and optimization have started to be combined in the latest decades with an increasing trend also due to the need of often meeting performance targets, high structural complexity and costs. Nonetheless, existing approaches tackled this issue mainly in the domain of static calculations or referring to a specific type of optimization (e.g., size, topology or geometry). A new methodology is proposed to systematically perform different types of analysis (e.g., linear and nonlinear), by exploiting the Autodesk Robot Structural Analysis API through MATLAB. This approach involves the adoption of ActiveX technologies for the manipulation of COM (Component Object Model) objects in the MATLAB environment. A real-world example of linear dynamic modal analysis is also presented and a synthetic diagnostic of the structure is conducted based on the displacements resulting from the calculation.
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References
Cerѐ, G., Rezgui, Y., Zhao, W.: Critical review of existing built environment resilience frameworks: Directions for future research. Int. J. Disaster Risk Reduct. 25, 173–189 (2017)
Fisher, A., Sharma, S.: Exploiting Autodesk Robot Structural Analysis Professional API for Structural Optimization, http://bimandbeam.typepad.com/. Last accessed 26 Apr. 2018
The European Union Per Regulation 305/2011, EN 1998-1:2004+A1:2003: Eurocode 8: Design of structures for earthquake resistance, Brussels (2004)
FEMA: 2015 NEHRP. Recommended Seismic Provisions: Design Examples, Washington D.C. (2016)
Adaptsoft, ADAPT Structural Concrete Software (2017)
Tekla, Tekla Structures. Administrator’s Release Notes (2015)
Computers & Structures Inc, SAP 2000 User Manual, Version 19 (2016)
Autodesk, Autodesk Robot Structural Analysis Professional 2010 Training Manual (2009)
Autodesk, Autodesk Robot Structural Analysis. Metric Getting Started Guide (2010)
Collette, Y., Siarry, P.: Multiobjective optimization: principles and case studies, 1st edn. Springer, Berlin (2003)
MathWorks, MATLAB Optimization Toolbox, https://uk.mathworks.com/products/optimization.html. Last accessed 18 Apr. 2018
Dolsek, M.: Development of computing environment for the seismic performance assessment of reinforced concrete frames by using simplified nonlinear models. Bull. Earthq. Eng. 8, 1309–1329 (2010)
Autodesk, Autodesk Robot Structural Analysis Professional 2018. Robot Object Model (2017)
Baldock, R.: Structural optimisation in building design practice: case-studies in topology optimisation of bracing systems. University of Cambridge (2007)
Balling, R.J., Briggs, R.R., Gillman, K.: Multiple optimum size/shape/topology designs for skeletal structures using a genetic algorithm. J. Struct. Eng. 132(7), 1158–1165 (2006)
Sigmund, O.: A 99 line topology optimization code written in Matlab. Struct. Multi. Optim. 21(2), 120–127 (2001)
Rajan, S.D.: Sizing, shape, and topology design optimization of trusses using genetic algorithm. J. Struct. Eng. 121(10), 1480–1487 (1995)
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Cerè, G., Zhao, W., Rezgui, Y. (2019). Structural Behavior Analysis and Optimization, Integrating MATLAB with Autodesk Robot. In: Mutis, I., Hartmann, T. (eds) Advances in Informatics and Computing in Civil and Construction Engineering. Springer, Cham. https://doi.org/10.1007/978-3-030-00220-6_45
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DOI: https://doi.org/10.1007/978-3-030-00220-6_45
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