@Article{CostaJrRosaMattRamo:2004:GrPaAn,
               author = "Costa Junior, R. A. and Rosa, Reinaldo Roberto and Mattedi, 
                         Adriana Prestes and Ramos, Fernando Manuel",
          affiliation = "{Nucleous for Simulation and Analysis of Complex Sustems (NUSASC)} 
                         and Instituto Nacional de Pesquisas Espaciais, Laborat{\'o}rio 
                         Associado de Computa{\c{c}}{\~a}o e Matem{\'a}tica Aplicada, 
                         (INPE.LAC) and Instituto Nacional de Pesquisas Espaciais, 
                         Laborat{\'o}rio Associado de Computa{\c{c}}{\~a}o e 
                         Matem{\'a}tica Aplicada, (INPE.LAC) and Instituto Nacional de 
                         Pesquisas Espaciais, Laborat{\'o}rio Associado de 
                         Computa{\c{c}}{\~a}o e Matem{\'a}tica Aplicada, (INPE.LAC)",
                title = "Gradient pattern analysis of extended convection-diffusion",
              journal = "Physica A: Statistical Mechanics and its Applications",
                 year = "2004",
               volume = "344",
               number = "3-4",
                pages = "447--455",
                month = "Dec.",
             keywords = "COMPUTER SCIENCE, Gradient pattern analysis, Burger's equation, 
                         Extended convection-diffusion, Generalized thermostatistics, 
                         Seismology, Dynamics, Systems, COMPUTA{\C{C}}{\~A}O APLICADA, 
                         An{\'a}lise de padr{\~a}o Gradiente, Equa{\c{c}}{\~a}o de 
                         Burguer, Convec{\c{c}}{\~a}o-difus{\~a}o extendida, 
                         Termost{\'a}tica geral, Seismologia.",
             abstract = "In this paper, we introduce a wave transport scenario useful for 
                         investigation of spatio-temporal energy transport related to 
                         earthquake phenomena. We perform gradient pattern analysis (GPA) 
                         of convection-diffusion patterns given by the solution of 2D 
                         Burger's equation. The GPA leads to characterize initial condition 
                         coherence and pattern equilibrium during its spatiotemporal 
                         evolution. This transport phenomenon is discussed in terms of its 
                         dependence to the initial condition pattern distribution. The 
                         initial condition variability is given by a set of symmetric 
                         energy distributions (Gaussian and non-Gaussian) obtained from 
                         variations of the Tsallis q-parameter. The results have shown that 
                         the GPA is able to characterize different spatio-temporal 
                         convective-diffusion patterns by means of its asymmetric phase 
                         diagram and this can be an useful tool for the study of energy 
                         loading and convective-diffusion drop patterns involved in the 
                         earthquake prediction.",
           copyholder = "SID/SCD",
                  doi = "10.1016/j.physa.2004.06.013",
                  url = "http://dx.doi.org/10.1016/j.physa.2004.06.013",
                 issn = "0378-4371",
             language = "en",
           targetfile = "gradient analysis.pdf",
        urlaccessdate = "15 jun. 2024"
}