For better predictability and management of hydrocarbon reservoirs it is necessary to establish adequate constitutive models to represent the mechanical and hydraulic behavior of these materials. During the production of hydrocarbons, an increase in effective stresses occur due to the reduction of pore pressure. This can lead to a reduction in the pore space of the reservoir and may lead to pore collapse. The compaction of the reservoirs is a consequence of the alteration of the state of stress, which produce elastic and plastic deformations, eventually leading to failure of the rock. It is known that the resistance of the carbonates is related to the porosity, mineralogy and arrangement of the grains. Since this type of rock usually has an elastoplastic behavior with anisotropic characteristics. The use of advanced constitutive models is necessary to reproduce the complex stress-strainpermeability behavior of sedimentary rocks. The Lade-Kim and Modified Cam Clay with Cohesion (CCMC) isotropic models are used in this work to try to represent the geomechanical behavior of travertine; a rock analogous to one of the Brazilian Pre-Salt facies. Parameters of these models for these type of rocks are seldom found in the literature, and their determination depends on carefully performed laboratory tests. The present work aims to contribute with the establishment of adequate models to represent the geomechanical behavior of travertine carbonate as a function of porosity. As a part of the present work an anisotropic model called CALK was developed, based on the isotropic model of Lade-Kim. In addition, triaxial compression, hydrostatic and uniaxial compression tests were performed on travertine carbonate samples with different orientations of the layers in relation to the axial axis of the samples ( parallel, Beta = 90 degrees , orthogonal, Beta = 0 degrees and inclined, Beta = 45 degrees) The results of the tests were used to establish parameters of the constitutive models Lade-Kim and CCMC. The retro-analysis process was used, incorporating the Lade-Kim algorithm, developed in MATLAB 2017 and FORTRAN 90, to the DREAM and MINPACK algorithms, respectively. The results indicate that the proposed methodology and the CALK model are able to adequately represent the mechanical behavior of the travertine observed in the laboratory.