Within the scope of the master's thesis, experimental research on the effectiveness of shear strengthening with FRP systems and analytical models for evaluating their effectiveness is presented. The selected experimental investigations focused on cyclic shear tests of individual stone and brick walls, taken from the experimental database of the Slovenian National Building and Civil Engineering Institute (ZAG), the Faculty of Civil and Geodetic Engineering at the University of Ljubljana, and the Institute for Research in Materials and Constructions (ZRMK). Results from various selected tests on strengthened walls are presented, illustrating the behavior of the walls under simulated in-plane seismic loading. The emphasis in selecting experimental research was on various types of masonry, including brick and stone walls, which were strengthened in different ways. Different levels of preloading and varying boundary conditions during shear tests allowed for the development of different failure mechanisms in the walls: flexural, shear, or mixed. The presentation of the experimental investigations includes all crucial data necessary for preparing the analytical model assessment, obtained from the selected experimental research, including tests on bricks, mortars used, and masonry investigations. It is important to highlight that the first phase of the research focused on cyclic shear testing of unstrengthen walls, followed by the repair of the same wall damages with appropriate injection mortars, and preceded with the second phase of testing, which involved cyclic shear testing of the strengthened walls. An overview of analytical models and guidelines is presented, considering the Italian CNR-DT 215/2018 and the American standard ACI 440.7-22. Calculations according to these standards were performed for the selected strengthening methods that were the subject of the experimental investigations. Additionally, analytical assessments were also conducted using models developed by various authors. To conduct a more comprehensive analysis, it was beneficial to include as many results and examples as possible to more accurately assess the validity and applicability of different models for various reinforcement configurations. The comparison between experimental results and analytical calculations was carried out to evaluate the adequacy of analytical models for determining the contribution to shear strength of unreinforced walls under seismic loading. The thesis also analyzed different reinforcement configurations, for which the same analytical models were used to assess the contribution of the reinforcements to shear capacity, revealing varying degrees of effectiveness. Each model is specifically suited to a particular reinforcement configuration, which is reflected in the discrepancies between the analytical assessments and the test results. The comparisons made in the thesis indicate that not every analytical model is suitable for every reinforcement configuration.