Matlab simulation in New Hampshire:
Matlab simulation in New Hampshire However, whole-body models representing the body from head to toe, are desirable to study the influence of plane waves emitted by, for example, phone masts. The few works dedicated to model the entire hirepregnantwoman at different stages of pregnancy were based on hybrid modeling, which relies on the combination of mathematical, voxelized, and/or synthetic models. The hybrid model SILVY,
presented in combined a malformed fetus segmented from a MRI dataset, the voxelized pregnant woman trunk described in and the homogeneous whole-body envelope of a woman generated by laser scan imaging. Nonlinear scaling was used to hireadapt the whole-body envelope to the trunk model after removing the superficial fat and skin layers.
The brain and spinal cord of the model were also inserted and fitted into SILVY. In a set of mathematical models of the uterus and fetus were voxelized and embedded in the nonpregnant voxel model Voxel editing was required to translate and deform hireorgans away from the uterus. In nine pregnant female models at each month of gestation were generated, embedding a UFU into a computer graphics woman model.
The abdomen of the woman was only scaled for models at stages beyond 4 months and the UFUs were scaled to simulate the different gestational ages. In hybrid models using the UFU and maternal organs models from and computer graphics models were usedhire together to construct surface models of a pregnantwoman with detailed organs. Three models were built at months of pregnancy.
To insert the fetus, the maternal organs were manually translated and deformed to avoid overlaps using free-form deformation lattices. An angle of was hireapplied between the caudocephalic axis of the female body and the fetus for months models, and for the months model. Fetal soft tissues, brain, and skeleton were distinguished.