. . . "\u010Cl\u00E1nek se zab\u00FDv\u00E1 tvorbou matematick\u00FDch model\u016F lidsk\u00E1 lebky pro numerickou anal\u00FDzu pomoc\u00ED metody kone\u010Dn\u00FDch prvk\u016F na z\u00E1klad\u011B dat z\u00EDskan\u00FDch z po\u010D\u00EDta\u010Dov\u00E9 tomografie"@cs . "With increasing power of computers and accordingly developing variational methods, especially Finite Element Method (FEM), computer simulation is nowadays one of the most popular methods in engineering practice. The major advantage of computer simulations compared to experiments is that they are cheaper and always non-destructive. For needs of biomechanics, we can consider analyzes of parts of skeleton or simulations of blood flow etc. For numerical analysis using FEM development of accurate geometry of organs of different tissues is necessary. An example of use in biomechanics is stress analysis of bones, in our case human skull. The problem is divided into two parts: image analysis and tissue segmentation followed by reconstruction of the model geometry. The latter can be achieved by two different approaches with the same goal (FE model): volume generation using NURBS (Non-Uniform Rational B-Splines) used for reconstruction of organs of relatively simple shape (e.g. femur) and direc" . "RIV/68407700:21260/04:06102875" . . . "564464" . . "Jirou\u0161ek, Ond\u0159ej" . . "With increasing power of computers and accordingly developing variational methods, especially Finite Element Method (FEM), computer simulation is nowadays one of the most popular methods in engineering practice. The major advantage of computer simulations compared to experiments is that they are cheaper and always non-destructive. For needs of biomechanics, we can consider analyzes of parts of skeleton or simulations of blood flow etc. For numerical analysis using FEM development of accurate geometry of organs of different tissues is necessary. An example of use in biomechanics is stress analysis of bones, in our case human skull. The problem is divided into two parts: image analysis and tissue segmentation followed by reconstruction of the model geometry. The latter can be achieved by two different approaches with the same goal (FE model): volume generation using NURBS (Non-Uniform Rational B-Splines) used for reconstruction of organs of relatively simple shape (e.g. femur) and direc"@en . "[D81C97191DE9]" . "Wroclaw" . . . "Finite Element Model of Human Skullconstructed from Data Obtained from Computed Thomography" . "Kone\u010Dneprvkov\u00FD model lidsk\u00E9 lebky vytvo\u0159en\u00FD na z\u00E1klad\u011B dat z CT anotace"@cs . "FE model; Mesh generation; Skull"@en . . "21260" . "Finite Element Model of Human Skullconstructed from Data Obtained from Computed Thomography"@en . "Kuneck\u00FD, Ji\u0159\u00ED" . "Finite Element Model of Human Skullconstructed from Data Obtained from Computed Thomography" . "1"^^ . "1st Students' Scientific Conference of Biomechanics" . "2"^^ . . . . "Szklarska Poreba" . . "Oficyna Wydawnicza Politechniki Wroc\u0142awskiej" . "RIV/68407700:21260/04:06102875!RIV/2005/MSM/212605/N" . "105 ; 106" . . "Finite Element Model of Human Skullconstructed from Data Obtained from Computed Thomography"@en . "2"^^ . . . "Z(AV0Z2071913), Z(MSM 212600025)" . "Kone\u010Dneprvkov\u00FD model lidsk\u00E9 lebky vytvo\u0159en\u00FD na z\u00E1klad\u011B dat z CT anotace"@cs . "2004-05-27+02:00"^^ . "1732-0240" .