In this thesis, we analyzed the SIR model in detail and based on the data from the beginning of the epidemic formed a model for the first and second wave of the epidemic. From the obtained results we can conclude that the model does not describe well the actual data, which means that at the beginning of the epidemic we will have very poor predictions about the development of the epidemic. Probable reason for this is introduction of epidemic measures. After that, we focused on modeling based on all previous data related to the stringency coeffcient. This way of interpreting the epidemic provides more accurate data, so we decided to apply this interpretation to other models in this paper. We then performed a detailed analysis for the ASIR model, based on the stringency coeffcient. Using the ASIR model, we obtained data that are closer to the actual data than in the SIR model. After that, we dedicated ourselves to the SIRS, SIRW and SIR models with constant vaccination. We did not analyze these models in detail, but presented them as models that describe the epidemic in an interesting way. In the SIRS and SIRW model, we can see that the population of infected, recovered and susceptible to infections occurs in waves, which is interesting because the epidemic of the viral disease COVID-19 in the Republic of Croatia also occurred in waves. In these models, the infection is still circulating in the population, which, in addition to vaccination, is possibly to happen in reality. In the end, we can conclude that none of the above models will approximate the actual situation completely accurately. The reason for this may be in the imprecise determination of the model parameters, and the introduction of measures that change the parameters. In each of the models, we can understand how the epidemic will behave if the characteristics of the virus change (virus mutations that affect the duration of immunity) or if our attitude towards the epidemic changes (introduction or abolition of measures)..