The cell membrane is an incredibly complex system, which is hard to analyse. This is not only due to its complexity and the many proteins, tensions, and forces to take into account, but also because of the cell’s incredibly small size. As such, simulations will be used to predict the membranes’ shapes. This behaviour is dictated by the properties of the lipids, out of which a majority of the membrane is made[2]. To analyse this phenomenon, we used the trisurf simulation software. In the analysis, we accounted for external forces by inducing a pressure difference within and without the cell. The most important mechanism was the minimization of free energy, which causes the cell to deform into the most energy-efficient shape possible under any pressure. We disregarded the nucleus due to the fact that erythrocytes are the most interesting cell when it comes to abnormal shapes[13], and human erythrocytes have no nucleus. We started by making 3 sweeps of the rigidity-pressure phase space, after which we determined which sub-space we will analyse next, based on our results. After 3 sweeps, we found an area with sufficiently realistic and interesting results. We analysed all of the points (membrane shapes) in this sub-space by their reduced volume and membrane free energy. We also compared them with experimental results and came to the conclusion that for most cells, minimization of free membrane energy is an important process and can alone determine the final cell shape. This is not true for cells whose membranes are significantly non-homogeneous in certain areas, as locally the proteins will win out and affect the shape, making our model insufficient.