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Ph.D.,
Civil Engineering (Structural) Cornell University (1983), Doctor in
Aeronautical Engineering (Structural), University of Pisa, Italy (1977)
CURRENT PROJECTS Structural Design of Roman Concrete Domes at Hadrian's Villa Collaboration with C. F. Giuliani, Archaeology and Ancient Topography, La Sapienza, Roma and A. Becene, University of Rochester. The long term objective is to determine the structural behavior and the inherent structural design philosophy for pozzolanic concrete domes at Hadrian's Villa at Tivoli, Italy. These include the Vestibule of Piazza d'Oro, the octagonal room in the Small Baths, the semidome of the Canopo, and the Eliocamino. The investigation is based on systematic computational modeling and analysis involving detailed solid modeling reconstruction, linear static and dynamic FEM analysis, nonlinear FEM analysis including fracture mechanics and nonlinear material characterization. For each selected dome we have three specific aims: (1) Determine the static conditions of the structure as originally built (structure in its original service conditions.) (2) Determine the design process (or processes) that likely led to the particular structural-architectural solution. (3) Determine the process (or processes) of structural decay and partial collapse that transformed the structure from the original service conditions to the present degraded state. The preliminary study on the structural design of the Vestibule is nearly completed and is in the process of being published. For an introductory presentation with FEM results on the Vestibolo, see here Le Cupole Cementizie (in Italian.) The Grande Aula (Great Hall) of Trajan's Markets Collaboration with L. Ungaro and M. Vitti, Sovraintendenza ai Beni Culturali di Roma, and C. F. Giuliani, Archaeology and Ancient Topography, La Sapienza, Roma. The long term objective is to establish the role of the Great Hall in the evolution of monumental concrete vault design. Of particular interest is the structural function of the lateral supporting arches and kinematic behavior of the supportive travertine blocks. As for the study at Hadrian's Villa, the investigation is based on systematic computational modeling and analysis involving detailed solid modeling reconstruction, linear static and dynamic FEM analysis, nonlinear FEM analysis including contact analysis, fracture mechanics and nonlinear material characterization. To address structural issues that arise during construction and before concrete setting, we plan to develop a nonlinear material formulation for pozzolanic concrete with large aggregate, typical of Trajanic and Hadrianic construction. To date, 3D linear and nonlinear (contact only) FEM analyses has shown that the arches do not fulfill a structural function. We are in the process of publishing the initial results. graduate research assistant: Philip Brune, undergraduate research project Sarilyn Swayngim. For 3D linear results, see here Structural Analysis of the Grande Aula.
Collaboration with L. A. Taber, Washington U., St. Louis. Building on our prior work, we propose to write a general computational code that can be used to model the biomechanics of developing soft tissue structures. This project includes six specific aims. The first three aims deal with software development, and the last three aims test the utility of the code for representative applications. Work at Rochester is primarily on FEM code development. Aims: (1) Extend our FEM code to include remodeling of individual tissue constituents. (2) Extend the code to include mechanical feedback as a regulator of developmental processes. Feedback, which enables self assembly of tissues, will be implemented mathematically through user-specified tissue construction rules. (3) Develop an algorithm to automatically update the geometrical description and the mesh of finite element models undergoing geometrical transformations due to large deformations. Dynamic updating of the geometrical representation will allow, for example, regional addition or subtraction of tissue (e.g., added cell layers or cell death) and the fusion of epithelial sheets (e.g., wound healing). (4) Construct a finite element model for early brain development, including growth regulated by mechanical feedback. (5) Construct a finite element model for functional adaptation of arteries, including cell growth, matrix remodeling, and smooth muscle tone, all regulated by mechanical feedback. (6) Construct a finite element model for cardiac looping morphogenesis, including cell growth and cytoskeletal contraction regulated by mechanical feedback. Graduate research assistant: Jonathan Young.
Collaboration with L. A. Taber,
Washington U., St. Louis. In previous work, we have investigated
aspects of the looping problem. In particular, Taber has identified
some of the biomechanical forces that drive looping, an issue that has
confounded developmental biologists for decades. This project will
examine how these forces are integrated and regulated to create and
mold the heart. Specifically, we propose to: (1) Develop computational
models for formation and looping of the embryonic heart. (2) Determine
the role that mechanical stresses in the omphalomesenteric veins play
in left-right looping directionality. (3) Determine biomechanical
mechanisms involved in formation of the heart tube in the early embryo.
(4) Determine fundamental biomechanical principles that regulate
formation and c-looping of the embryonic heart. Completing these
specific aims should give us a more complete understanding of early
heart development, as well as provide a predictive model for future
studies in this field. Graduate research assistant: Christopher
Buttaccio.
1. R. Perucchio, "Self-adaptive FEM procedures based on Hierarchical Substructuring and Multigrid Analysis,” in S. Kodiyalam and M. Saxena, Editors, Geometry and Optimization Techniques for Structural Design, Southampton, UK: Computational Mechanics Publications & London, UK: Elsevier Publishing Company, pp. 141-175, 1994. 2. R. Srinivasan and R. Perucchio, "Finite element analysis of anisotropic nonlinear incompressible elastic solids by a mixed model,” International Journal for Numerical Methods in Engineering, vol.37, pp. 3075-3092, 1994. 3. [PDF] L. A. Taber and R. Perucchio, “Modeling heart development,” Journal of Elasticity, vol.61, pp. 165-197, 2000; reprinted in S. C. Cowin and J. D. Humphrey, Eds., Cardiovascular Soft Tissue Mechanics, Dordrecht, The Netherlands : Kluvier, pp. 165-197, 2002. 4. [PDF] Xie W. and R. Perucchio, “Multiscale finite element modeling of the trabeculated embryonic Heart: Numerical Evaluation of the Constitutive Relations for the Trabeculated Myocardium,” Computer Methods in Biomechanics and Biomedical Engineering, vol. 4, pp. 231-248, 2001. 5. [PDF] Xie W. , R. Thompson, and R. Perucchio, “A topology-preserving parallel 3D thinning algorithm for extracting the curve skeleton,” Pattern Recognition, vol. 36, pp. 1529-1544, 2003. 6. Xie W. and R. Perucchio, "Nonlinear 3D FE Biomechanical Analysis of the Trabeculated Embryonic Heart Under Cardiac Cycle Loading," ASME-BED Proceedings of the 2003 Summer Bioengineering Conference, pp. 425-426, Key Biscayne, FL, June 25-29, 2003. |
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