Recent wide-ranging usage of Global Positioning System devices and wireless communication devices, together with enhancements of supportive technology, induced the expansion of the research on moving objects. By modelling and analyzing moving objects data, we learn about the moving objects behaviour and even become able to predict their future locations. The most common objects of research are humans and vehicles. The less studied class of moving objects are wild animals which are moving freely in space, whose movement is complex and conditioned by various external and internal factors. The movement analysis and prediction models applied for humans and vehicles are not appropriate for animals, therefore new models should be proposed. In most of the related work, contextual and additional information is not considered into the process of movement analysis and prediction. In the thesis introduction is given an overview of research area of moving objects, with emphasis on wildlife. Wild animals are placed in area of moving objects research with its specificities in order to justify the need of setting up a new approach to movement analysis and prediction for this type of moving objects. The existing systems and algorithms that support some part of the analysis and prediction process are also presented. Later on, we propose a generic model for knowledge representation, analysis and prediction of moving objects movement adapted to the wild animals. The model consists of knowledge base and set of algorithms for the analysis and prediction of animal movement. The proposed solution includes expert knowledge, contextual information, historical movement of animal and animal characteristics in analysis and prediction. The model is based on the automatic process of integration of the identified properties of the movement. Movement prediction process is suggested and described taking into account the expert knowledge and contextual information. The procedure involves determining the geographical area in which animals can reside for some period of time, as well as the prediction of the next movement in real time, when it is necessary to observe or to catch the animal. Supporting algorithms necessary for successful performance of prediction procedure such as significant location identification are presented as well. The prediction process meets the requirement for the possibility of prediction in areas where the animal has not been previously, or where there is no historical data on movement in this area. In order to support the process of movement prediction and to evaluate algorithms for the analysis and prediction of movement of wild animals, we have built a prototype. The results of algorithms have been validated by comparison with field data of the movement of wolves and bears in Croatia. The research of moving objects, especially those moving freely in space, is challenging research area still in development. The results of this study will be useful to community members engaged in studies of wildlife, whether they need to analyse complex spatio-temporal data offline or predict the movement of animal at the terrain research in real time. We believe the same generic model could be applied to different kind of animals but also to other classes of moving objects.