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Rodrigo Weber dos Santos
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2020 – today
- 2024
- [j44]Noemi Zeraick Monteiro
, Rodrigo Weber dos Santos
Constructive fractional models through Mittag-Leffler functions. Comput. Appl. Math. 43(4): 177 (2024) - [j43]Noemi Zeraick Monteiro
A novel second-order ADI Scheme for solving epidemic models with cross-diffusion. J. Comput. Sci. 81: 102341 (2024) - [j42]Julià Camps
Digital twinning of the human ventricular activation sequence to Clinical 12-lead ECGs and magnetic resonance imaging using realistic Purkinje networks for in silico clinical trials. Medical Image Anal. 94: 103108 (2024) - [j41]Brodie A. J. Lawson
Perlin noise generation of physiologically realistic cardiac fibrosis. Medical Image Anal. 98: 103240 (2024) - [c78]Lucas Marins Ramalho de Lima
MonoWeb: Cardiac Electrophysiology Web Simulator. ICCS (4) 2024: 147-154 - 2023
- [j40]Brodie A. J. Lawson
Homogenisation for the monodomain model in the presence of microscopic fibrotic structures. Commun. Nonlinear Sci. Numer. Simul. 116: 106794 (2023) - [j39]João R. Alves, Lucas A. Berg
A Hybrid Model for Cardiac Perfusion: Coupling a Discrete Coronary Arterial Tree Model with a Continuous Porous-Media Flow Model of the Myocardium. Entropy 25(8): 1229 (2023) - [j38]Joventino Oliveira Campos, Rafael Moreira Guedes, Yan Barbosa Werneck, Luis Paulo S. Barra, Rodrigo Weber dos Santos, Bernardo M. Rocha
Polynomial chaos expansion surrogate modeling of passive cardiac mechanics using the Holzapfel-Ogden constitutive model. J. Comput. Sci. 71: 102039 (2023) - [c77]Yan Barbosa Werneck, Rodrigo Weber dos Santos
Replacing the FitzHugh-Nagumo Electrophysiology Model by Physics-Informed Neural Networks. ICCS (2) 2023: 699-713 - [c76]Thaís de Jesus Soares, João Pedro Banhato Pereira
Studying Arrhythmic Risk with In-Silico Programmed Ventricular Stimulation and Patient-Specific Computational Models. ICCSA (Workshops 9) 2023: 41-51 - [c75]Alexandre Bittencourt Pigozzo, Rodrigo Weber dos Santos
Sensitivity Analysis of a Cardiac Electrophysiology Model for the Occurrence of Electrical Alternans. ICCSA (Workshops 1) 2023: 44-58 - [c74]Guilherme Martins Couto
Accelerating the Simulations of Cardiac Arrhythmia with a Second-Order Numerical Method and High-Performance Computing. ICCSA (Workshops 9) 2023: 103-113 - 2022
- [j37]Megan E. Farquhar
Graph-based homogenisation for modelling cardiac fibrosis. J. Comput. Phys. 459: 111126 (2022) - [j36]Carolina Ribeiro Xavier
Timing the race of vaccination, new variants, and relaxing restrictions during COVID-19 pandemic. J. Comput. Sci. 61: 101660 (2022) - [j35]Nicolás A. Barnafi
Finite Element Methods for Large-Strain Poroelasticity/Chemotaxis Models Simulating the Formation of Myocardial Oedema. J. Sci. Comput. 92(3): 92 (2022) - [c73]Julià Camps, Zhinuo J. Wang, Rafael Sebastián, Xin Zhou, Brodie Lawson, Lucas Arantes Berg, Kevin Burrage, Vicente Grau, Rodrigo Weber dos Santos, Blanca Rodríguez:
Inference of Number and Location of Purkinje Root Nodes and Ventricular Conduction Properties from Clinical 12-Lead ECGs for Cardiac Digital Twinning. CinC 2022: 1-4 - [c72]Leto Luana Riebel
Modelling and Simulation Reveals Density-Dependent Re-Entry Risk in The Infarcted Ventricles After Stem Cell-Derived Cardiomyocyte Delivery. CinC 2022: 1-4 - [c71]Gabriel Brandão de Miranda
Characterization of Foam-Assisted Water-Gas Flow via Inverse Uncertainty Quantification Techniques. ICCS (4) 2022: 310-322 - [c70]Evandro Dias Gaio
Modeling Contrast Perfusion and Adsorption Phenomena in the Human Left Ventricle. ICCS (1) 2022: 455-468 - [c69]Berilo de Oliveira Santos
Forward Uncertainty Quantification and Sensitivity Analysis of the Holzapfel-Ogden Model for the Left Ventricular Passive Mechanics. ICCS (4) 2022: 749-761 - 2021
- [j34]Elnaz Pouranbarani
Calibration of single-cell model parameters based on membrane resistance improves the accuracy of cardiac tissue simulations. J. Comput. Sci. 53: 101375 (2021) - [c68]Maicom Peters Xavier, Lara Turetta Pompei, Ana Carolina G. de O. Vieira, Matheus Avila Moreira de Paula, Carla Rezende Barbosa Bonin, Ruy Freitas Reis
Modelling the Human Immune System Response to the ChAdOx1 nCoV-19 Vaccine. BIBM 2021: 3327-3333 - [c67]Rafael Sachetto Oliveira
How Fast Vaccination Can Control the COVID-19 Pandemic in Brazil? ICCS (2) 2021: 497-510 - [c66]Bruno Rocha Guedes, Marcelo Lobosco
Uncertainty Quantification of Tissue Damage Due to Blood Velocity in Hyperthermia Cancer Treatments. ICCS (2) 2021: 511-524 - [c65]Anna Luisa de Aguiar Bergo Coelho, Ricardo Silva Campos, João Gabriel Rocha Silva, Carolina Ribeiro Xavier, Rodrigo Weber dos Santos:
Modeling the Electromechanics of a Single Cardiac Myocyte. ICCS (2) 2021: 540-550 - [i2]Nicolás A. Barnafi, Bryan Gomez-Vargas, Wesley de Jesus Lourenço, Ruy Freitas Reis, Bernardo Martins Rocha, Marcelo Lobosco, Ricardo Ruiz-Baier, Rodrigo Weber dos Santos:
Mixed methods for large-strain poroelasticity/chemotaxis models simulating the formation of myocardial oedema. CoRR abs/2111.04206 (2021) - 2020
- [j33]Carla Rezende Barbosa Bonin, Guilherme Côrtes Fernandes, Reinaldo de Menezes Martins, Luiz Antonio Bastos Camacho, Andréa Teixeira-Carvalho, Lícia Maria Henrique da Mota, Sheila Maria Barbosa de Lima, Ana Carolina Campi-Azevedo, Olindo Assis Martins-Filho
Validation of a yellow fever vaccine model using data from primary vaccination in children and adults, re-vaccination and dose-response in adults and studies with immunocompromised individuals. BMC Bioinform. 21-S(17): 551 (2020) - [j32]Raffael Bechara Rameh, Elizabeth M. Cherry
Single-variable delay-differential equation approximations of the Fitzhugh-Nagumo and Hodgkin-Huxley models. Commun. Nonlinear Sci. Numer. Simul. 82: 105066 (2020) - [j31]Johnny Moreira Gomes, Rafael Sachetto Oliveira
Adaptive-step methods for Markov-based membrane models. Commun. Nonlinear Sci. Numer. Simul. 85: 105249 (2020) - [c64]Larissa de L. e Silva, Maicom Peters Xavier, Rodrigo Weber dos Santos, Marcelo Lobosco, Ruy Freitas Reis
Uncertain Quantification of Immunological Memory to Yellow Fever Virus. BIBM 2020: 1281-1288 - [c63]Maicom Peters Xavier, Ruy Freitas Reis
A simplified model of the Human Immune System response to the COVID-19. BIBM 2020: 1311-1317 - [c62]Elnaz Pouranbarani, Lucas A. Berg
Improved Accuracy of Cardiac Tissue-Level Simulations by Considering Membrane Resistance as a Cellular-Level Optimization Objective. EMBC 2020: 2487-2490 - [c61]João Gabriel Rocha Silva, Ricardo Silva Campos, Carolina Ribeiro Xavier
Simplified Models for Electromechanics of Cardiac Myocyte. ICCSA (1) 2020: 191-204 - [c60]Ricardo Silva Campos, João Gabriel Rocha Silva, Helio José Corrêa Barbosa, Rodrigo Weber dos Santos:
Electrotonic Effect on Action Potential Dispersion with Cellular Automata. ICCSA (1) 2020: 205-215 - [i1]Brodie A. J. Lawson, Rodrigo Weber dos Santos, Ian W. Turner, Alfonso Bueno-Orovio, Pamela M. Burrage, Kevin Burrage:
Homogenisation for the monodomain model in the presence of microscopic fibrotic structures. CoRR abs/2012.05527 (2020)
2010 – 2019
- 2019
- [j30]Ruy Freitas Reis
A personalized computational model of edema formation in myocarditis based on long-axis biventricular MRI images. BMC Bioinform. 20-S(6): 532 (2019) - [j29]Ruy Freitas Reis
On the mathematical modeling of inflammatory edema formation. Comput. Math. Appl. 78(9): 2994-3006 (2019) - [c59]Carla Rezende Barbosa Bonin, Marcelo Lobosco, Guilherme Côrtes Fernandes, Reinaldo de Menezes Martins, Luiz Antonio Bastos Camacho, Lícia Maria Henrique da Mota, Sheila Maria Barbosa de Lima, Ana Carolina Campi-Azevedo, Olindo Assis Martins-Filho
Quantitative Validation of a Yellow Fever Vaccine Model. BIBM 2019: 2113-2120 - [c58]Lara Turetta Pompei, Ruy Freitas Reis
Modeling the Increase of Interstitial Pressure During Viral Infections. BIBM 2019: 2176-2183 - [c57]Elvis H. Ribeiro, Alexandre Bittencourt Pigozzo, Carolina R. Xavier
Stochastic Petri Net Models for the Study of Macrophage Reprogramming. BIBM 2019: 2184-2191 - [c56]Lucas Arantes Berg
A Study of the Electrical Propagation in Purkinje Fibers. ICCS (3) 2019: 74-86 - [c55]Gustavo Montes Novaes
Combining Polynomial Chaos Expansions and Genetic Algorithm for the Coupling of Electrophysiological Models. ICCS (3) 2019: 116-129 - [c54]Cesar Augusto Conopoima, Bernardo Martins Rocha, Iury Igreja
Stabilized Variational Formulation for Solving Cell Response to Applied Electric Field. ICCS (5) 2019: 627-634 - 2018
- [j28]Thiago Marques Soares, Rodrigo Weber dos Santos
On the use of HCM to develop a resource allocation algorithm for heterogeneous clusters. Concurr. Comput. Pract. Exp. 30(24) (2018) - [j27]Jesuliana N. Ulysses
An Optimization-Based Algorithm for the Construction of Cardiac Purkinje Network Models. IEEE Trans. Biomed. Eng. 65(12): 2760-2768 (2018) - [c53]Ruy Freitas Reis
An Hydro-Mechanical Model of Edema Formation Applied to Bacterial Myocarditis. BIBM 2018: 1418-1424 - [c52]Fernando Otaviano Campos, João Filipe Fernandes, Yohannes Shiferaw, Titus Kühne, Rodrigo Weber dos Santos
A Multiscale Computational Model of Calcium-Mediated Ectopy in the Human Postinfarction Heart. CinC 2018: 1-4 - [c51]Marcelo Lobosco
Design and Analysis of an Undergraduate Computational Engineering Degree at Federal University of Juiz de Fora. ICCS (3) 2018: 293-303 - [c50]Vinícius Clemente Varella, Aline Mota Freitas Matos, Henrique Couto Teixeira, Angélica da Conceição Oliveira Coelho, Rodrigo Weber dos Santos
A Stochastic Model to Simulate the Spread of Leprosy in Juiz de Fora. ICCS (3) 2018: 559-566 - [c49]Tiago Marques do Nascimento, Rodrigo Weber dos Santos
Performance Evaluation of Two Load Balancing Algorithms for Hybrid Clusters. VECPAR 2018: 119-131 - 2017
- [j26]Ricardo Silva Campos, Bernardo Martins Rocha, Marcelo Lobosco
Multilevel parallelism scheme in a genetic algorithm applied to cardiac models with mass-spring systems. J. Supercomput. 73(2): 609-623 (2017) - [c48]Carla Rezende Barbosa Bonin, Guilherme Côrtes Fernandes, Rodrigo Weber dos Santos
A simplified mathematical-computational model of the immune response to the yellow fever vaccine. BIBM 2017: 1425-1432 - [c47]Micael P. Xavier, Carla Rezende Barbosa Bonin, Rodrigo Weber dos Santos
On the use of Gillespie stochastic simulation algorithm in a model of the human immune system response to the Yellow Fever vaccine. BIBM 2017: 1476-1482 - [c46]Tiago Marques do Nascimento, Rodrigo Weber dos Santos
Performance Evaluation of Two Load Balancing Algorithms on a Hybrid Parallel Architecture. PaCT 2017: 58-69 - [c45]Thiago Marques Soares, Rodrigo Weber dos Santos
Evaluation of HCM: A New Model to Predict the Execution Time of Regular Parallel Applications on a Heterogeneous Cluster. PPAM (2) 2017: 58-67 - [c44]Tiago Marques do Nascimento, Rodrigo Weber dos Santos
Dynamic Load Balancing Algorithm for Heterogeneous Clusters. PPAM (2) 2017: 166-175 - 2016
- [j25]João R. Alves, Rafael A. B. de Queiroz
Simulation of cardiac perfusion by contrast in the myocardium using a formulation of flow in porous media. J. Comput. Appl. Math. 295: 13-24 (2016) - [j24]Joventino Oliveira Campos, Rafael Sachetto Oliveira
Lattice Boltzmann method for parallel simulations of cardiac electrophysiology using GPUs. J. Comput. Appl. Math. 295: 70-82 (2016) - [j23]Carla Rezende Barbosa Bonin, Rodrigo Weber dos Santos
Computational modeling of the immune response to yellow fever. J. Comput. Appl. Math. 295: 127-138 (2016) - [j22]Caroline Mendonça Costa
Mind the Gap: A Semicontinuum Model for Discrete Electrical Propagation in Cardiac Tissue. IEEE Trans. Biomed. Eng. 63(4): 765-774 (2016) - [c43]Tales L. Fonseca
Machine Learning Approaches to Estimate Simulated Cardiac Ejection Fraction from Electrical Impedance Tomography. IBERAMIA 2016: 235-246 - [c42]Thiago Marques Soares, Rodrigo Weber dos Santos
A Parallel Model for Heterogeneous Cluster. ICA3PP Workshops 2016: 76-90 - [c41]Raphael Pereira Cordeiro, Rafael Sachetto Oliveira
Improving the Performance of Cardiac Simulations in a Multi-GPU Architecture Using a Coalesced Data and Kernel Scheme. ICA3PP 2016: 546-553 - [c40]Rafael Sachetto Oliveira
Simulations of Cardiac Electrophysiology Combining GPU and Adaptive Mesh Refinement Algorithms. IWBBIO 2016: 322-334 - [c39]Ruy Freitas Reis
A Plasma Flow Model in the Interstitial Tissue Due to Bacterial Infection. IWBBIO 2016: 335-345 - [c38]Rafael Sachetto Oliveira
Reactive Interstitial and Reparative Fibrosis as Substrates for Cardiac Ectopic Pacemakers and Reentries. IWBBIO 2016: 346-357 - 2015
- [j21]T. M. do Nascimento, J. M. de Oliveira, Micael P. Xavier, Alexandre Bittencourt Pigozzo, Rodrigo Weber dos Santos
On the use of multiple heterogeneous devices to speedup the execution of a computational model of the Human Immune System. Appl. Math. Comput. 267: 304-313 (2015) - [j20]Johnny Moreira Gomes, Adriele Alvarenga, Ricardo Silva Campos, Bernardo Martins Rocha, Ana Paula Couto da Silva
Uniformization Method for Solving Cardiac Electrophysiology Models Based on the Markov-Chain Formulation. IEEE Trans. Biomed. Eng. 62(2): 600-608 (2015) - [c37]Tiago Marques do Nascimento, Rodrigo Weber dos Santos
On a Dynamic Scheduling Approach to Execute OpenCL Jobs on APUs. CARLA 2015: 118-128 - [c36]Ricardo Silva Campos, Bernardo Martins Rocha, Luis Paulo da Silva Barra, Marcelo Lobosco
A Parallel Genetic Algorithm to Adjust a Cardiac Model Based on Cellular Automaton and Mass-Spring Systems. PaCT 2015: 149-163 - [c35]Thiago M. Soares, Micael P. Xavier, Alexandre Bittencourt Pigozzo, Ricardo Silva Campos, Rodrigo Weber dos Santos
Performance Evaluation of a Human Immune System Simulator on a GPU Cluster. PaCT 2015: 458-468 - 2014
- [j19]Caroline Mendonça Costa
An Efficient Finite Element Approach for Modeling Fibrotic Clefts in the Heart. IEEE Trans. Biomed. Eng. 61(3): 900-910 (2014) - [j18]Ricardo Silva Campos, Marcelo Lobosco
A GPU-based heart simulator with mass-spring systems and cellular automaton. J. Supercomput. 69(1): 1-8 (2014) - [c34]Rogerio G. N. Santos Filho, Luciana Conceição Dias Campos, Rodrigo Weber dos Santos
Artificial Neural Networks Ensemble Applied to the Electrical Impedance Tomography Problem to Determine the Cardiac Ejection Fraction. IBERAMIA 2014: 734-741 - 2013
- [j17]Alexandre Bittencourt Pigozzo, Gilson Costa Macedo
On the computational modeling of the innate immune system. BMC Bioinform. 14(S-6): S7 (2013) - [j16]Ricardo Silva Campos, Fernando Otaviano Campos, Johnny Moreira Gomes, Ciro de Barros Barbosa, Marcelo Lobosco
Comparing high performance techniques for the automatic generation of efficient solvers of cardiac cell models. Computing 95(S1): 639-660 (2013) - [j15]Ronan Mendonça Amorim, Rodrigo Weber dos Santos
Solving the cardiac bidomain equations using graphics processing units. J. Comput. Sci. 4(5): 370-376 (2013) - [j14]Fernando Otaviano Campos, Thomas Wiener, Anton J. Prassl
Electroanatomical Characterization of Atrial Microfibrosis in a Histologically Detailed Computer Model. IEEE Trans. Biomed. Eng. 60(8): 2339-2349 (2013) - [c33]Carolina Ribeiro Xavier
Genetic Algorithm for the History Matching Problem. ICCS 2013: 946-955 - [c32]Rogerio G. N. Santos Filho, Luciana Conceição Dias Campos, Rodrigo Weber dos Santos
Determination of Cardiac Ejection Fraction by Electrical Impedance Tomography Using an Artificial Neural Network. MICAI (2) 2013: 130-138 - [c31]Ricardo Silva Campos, Ronan Mendonça Amorim, Bernardo Lino de Oliveira, Bernardo Martins Rocha, Joakim Sundnes, Luis Paulo da Silva Barra, Marcelo Lobosco, Rodrigo Weber dos Santos:
3D Heart Modeling with Cellular Automata, Mass-Spring System and CUDA. PaCT 2013: 296-309 - 2012
- [j13]Alexandre Bittencourt Pigozzo, Gilson Costa Macedo
Computational Modeling of Microabscess Formation. Comput. Math. Methods Medicine 2012: 736394:1-736394:16 (2012) - [j12]Bruno Gouvêa de Barros, Rafael Sachetto Oliveira
Simulations of Complex and Microscopic Models of Cardiac Electrophysiology Powered by Multi-GPU Platforms. Comput. Math. Methods Medicine 2012: 824569:1-824569:13 (2012) - [j11]Rafael Sachetto Oliveira
A parallel accelerated adaptive mesh algorithm for the solution of electrical models of the heart. Int. J. High Perform. Syst. Archit. 4(2): 89-100 (2012) - [j10]Mario Cannataro
Advanced computing solutions for health care and medicine. J. Comput. Sci. 3(5): 250-253 (2012) - [j9]Fernando Otaviano Campos, Anton J. Prassl
Influence of ischemic core muscle fibers on surface depolarization potentials in superfused cardiac tissue preparations: a simulation study. Medical Biol. Eng. Comput. 50(5): 461-472 (2012) - [c30]Ronan Mendonça Amorim, Ricardo Silva Campos, Marcelo Lobosco, Christian Jacob, Rodrigo Weber dos Santos:
An Electro-Mechanical Cardiac Simulator Based on Cellular Automata and Mass-Spring Models. ACRI 2012: 434-443 - [c29]Elisa Portes dos Santos Amorim, Carolina Ribeiro Xavier
Comparison between Genetic Algorithms and Differential Evolution for Solving the History Matching Problem. ICCSA (1) 2012: 635-648 - [c28]Rafael Sachetto Oliveira
An Adaptive Mesh Algorithm for the Numerical Solution of Electrical Models of the Heart. ICCSA (1) 2012: 649-664 - [c27]Pedro Augusto F. Rocha, Micael P. Xavier, Alexandre Bittencourt Pigozzo, Bárbara de Melo Quintela, Gilson Costa Macedo, Rodrigo Weber dos Santos
A Three-Dimensional Computational Model of the Innate Immune System. ICCSA (1) 2012: 691-706 - [c26]Igor Knop
System Dynamics Metamodels Supporting the Development of Computational Models of the Human Innate Immune System. ICCSA (1) 2012: 707-722 - 2011
- [j8]Bernardo M. Rocha, Fernando Otaviano Campos, Ronan Mendonça Amorim, Gernot Plank
Accelerating cardiac excitation spread simulations using graphics processing units. Concurr. Comput. Pract. Exp. 23(7): 708-720 (2011) - [j7]Bernardo M. Rocha, Ferdinand Kickinger, Anton J. Prassl
A Macro Finite-Element Formulation for Cardiac Electrophysiology Simulations Using Hybrid Unstructured Grids. IEEE Trans. Biomed. Eng. 58(4): 1055-1065 (2011) - [c25]Caroline Mendonça Costa
A finite element approach for modeling micro-structural discontinuities in the heart. EMBC 2011: 437-440 - [c24]Alexandre Bittencourt Pigozzo, Gilson Costa Macedo, Rodrigo Weber dos Santos
Implementation of a Computational Model of the Innate Immune System. ICARIS 2011: 95-107 - [c23]Rafael Sachetto Oliveira
Comparing CUDA, OpenCL and OpenGL Implementations of the Cardiac Monodomain Equations. PPAM (2) 2011: 111-120 - [c22]Mario Cannataro
Biomedical and Bioinformatics Challenges to Computer Science: Bioinformatics, Modeling of Biomedical Systems and Clinical Applications. ICCS 2011: 1058-1061 - [c21]Ricardo Silva Campos, Marcelo Lobosco
Adaptive Time Step for Cardiac Myocyte Models. ICCS 2011: 1092-1100 - 2010
- [j6]Mario Cannataro
Special section: Biomedical and bioinformatics challenges to computer science. Future Gener. Comput. Syst. 26(3): 421-423 (2010) - [j5]Ricardo Silva Campos, Ronan Mendonça Amorim, Caroline Mendonça Costa, Bernardo Lino de Oliveira, Ciro de Barros Barbosa, Joakim Sundnes, Rodrigo Weber dos Santos
Approaching cardiac modeling challenges to computer science with CellML-based web tools. Future Gener. Comput. Syst. 26(3): 462-470 (2010) - [c20]Alexandre Bittencourt Pigozzo, Marcelo Lobosco
Parallel Implementation of a Computational Model of the Human Immune System. Euro-Par Workshops 2010: 217-224 - [c19]Carolina Ribeiro Xavier, Elisa Portes dos Santos Amorim, Ronan M. Amorim, Marcelo Lobosco, Paulo Goldfeld, Flavio Dickstein, Rodrigo Weber dos Santos:
Performance Evaluation of a Reservoir Simulator on a Multi-core Cluster. ICCSA (4) 2010: 395-408 - [c18]Elisa Portes dos Santos Amorim, Paulo Goldfeld, Flavio Dickstein, Rodrigo Weber dos Santos, Carolina Ribeiro Xavier:
Automatic History Matching in Petroleum Reservoirs Using the TSVD Method. ICCSA (2) 2010: 475-487 - [c17]Alexandre Bittencourt Pigozzo, Marcelo Lobosco
Parallel Implementation of a Computational Model of the HIS Using OpenMP and MPI. SBAC-PAD (Workshops) 2010: 67-72 - [c16]Mario Cannataro
Biomedical and bioinformatics challenges to computer science. ICCS 2010: 931-933
2000 – 2009
- 2009
- [j4]Carolina Ribeiro Xavier
Multi-Level Parallelism for the Cardiac Bidomain Equations. Int. J. Parallel Program. 37(6): 572-592 (2009) - [c15]Mario Cannataro
GridSnake: A Grid-based implementation of the Snake segmentation algorithm. CBMS 2009: 1-6 - [c14]Ely Edison Matos, Fernanda Campos, Regina Braga
CelOWS: A Service Oriented Architecture to Define, Query and Reuse Biological Models. ICCS (1) 2009: 73-83 - [c13]Elisa Portes dos Santos, Carolina Ribeiro Xavier
Comparing Genetic Algorithms and Newton-Like Methods for the Solution of the History Matching Problem. ICCS (1) 2009: 377-386 - [c12]Mario Cannataro
Bioinformatics' Challenges to Computer Science: Bioinformatics Tools and Biomedical Modeling. ICCS (1) 2009: 807-809 - [c11]Franciane C. Peters, Luis Paulo S. Barra, Rodrigo Weber dos Santos
Determination of Cardiac Ejection Fraction by Electrical Impedance Tomography - Numerical Experiments and Viability Analysis. ICCS (1) 2009: 819-828 - [c10]Ronan M. Amorim, Gundolf Haase
Comparing CUDA and OpenGL implementations for a Jacobi iteration. HPCS 2009: 22-32 - [c9]Bernardo M. Rocha, Fernando Otaviano Campos, Gernot Plank
Simulations of the Electrical Activity in the Heart with Graphic Processing Units. PPAM (1) 2009: 439-448 - 2008
- [c8]Mario Cannataro
Bioinformatics' Challenges to Computer Science. ICCS (3) 2008: 67-69 - [c7]Caroline Mendonça Costa, Ricardo Silva Campos, Fernando Otaviano Campos, Rodrigo Weber dos Santos
Web Applications Supporting the Development of Models of Chagas' Disease for Left Ventricular Myocytes of Adult Rats. ICCS (3) 2008: 120-129 - [c6]Gustavo Miranda Teixeira, Igor Ramalho Pommeranzembaum, Bernardo Lino de Oliveira, Marcelo Lobosco
Automatic Segmentation of Cardiac MRI Using Snakes and Genetic Algorithms. ICCS (3) 2008: 168-177 - 2007
- [j3]Gernot Plank
Algebraic Multigrid Preconditioner for the Cardiac Bidomain Model. IEEE Trans. Biomed. Eng. 54(4): 585-596 (2007) - [c5]Carolina Ribeiro Xavier
Multi-level Parallelism in the Computational Modeling of the Heart. SBAC-PAD 2007: 3-10 - 2006
- [c4]Ciro de Barros Barbosa, Rodrigo Weber dos Santos
A Transformation Tool for ODE Based Models. International Conference on Computational Science (1) 2006: 68-75 - [c3]Fernando Otaviano Campos, Rafael Sachetto Oliveira
Performance Comparison of Parallel Geometric and Algebraic Multigrid Preconditioners for the Bidomain Equations. International Conference on Computational Science (1) 2006: 76-83 - [c2]D. M. S. Martins, Fernando Otaviano Campos, Leandro Neumann Ciuffo, Rafael Sachetto Oliveira
A Computational Framework for Cardiac Modeling Based on Distributed Computing and Web Applications. VECPAR 2006: 544-555 - 2004
- [j2]Rodrigo Weber dos Santos
Parallel multigrid preconditioner for the cardiac bidomain model. IEEE Trans. Biomed. Eng. 51(11): 1960-1968 (2004) - 2003
- [c1]Rodrigo Weber dos Santos, Flavio Dickstein:
On the Influence of a Volume Conductor on the Orientation of Currents in a Thin Cardiac Tissue. FIMH 2003: 111-121
1990 – 1999
- 1999
- [j1]Rodrigo Weber dos Santos, Ricardo Bianchini, Claudio Luis de Amorim:
A Survey of Messaging Software Issues and Systems for Myrinet-Based. Parallel Distributed Comput. Pract. 2(2) (1999)
Coauthor Index
[j36] [j35] [c68] [c67] [c66] [i2] [j33] [j31] [c64] [c63] [j30] [j29] [c59] [c58] [c57] [j28] [c53] [c51] [c50] [c49] [j26] [c48] [c47] [c46] [c45] [c44] [j23] [c42] [c41] [c39] [c38] [j21] [c37] [c36] [c35] [j18] [j17] [j16] [c31] [j13] [j12] [c30] [c27] [c26] [c24] [c21] [c20] [c19] [c17] [c15] [c6]
Bernardo M. Rocha
aka: Bernardo Martins Rocha
aka: Bernardo Martins Rocha
Carolina Ribeiro Xavier
aka: Carolina R. Xavier
aka: Carolina R. Xavier
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