Thermally induced error is one of the main limitations of the sensitivity of fiber-optic gyroscopes (FOGs). The analysis of thermal sensitivity of FOG is based on the study of the Shupe effect and the elastic-optical effect in the fiber circuit. The main requirement in this case is to preserve the principle of reciprocity for rays propagating in opposite directions of the fiber circuit. It was determined that the thermally induced phase difference of these rays should not exceed ∆φ(t) ≈ 10-7 rad. To reduce the thermal sensitivity of FOG, various methods are used, including quadrupole methods of winding the fiber circuit, using frameless coils, as well as coils made of special materials. Considerable attention is paid to improving the properties of fiber and adhesive compounds to minimize the effect of temperature on the optical-physical characteristics of these components of the fiber circuit. The article examines the advantages and disadvantages of each of the methods of compensating the thermally induced error of FOG. Analytical relations characterizing the effect of temperature gradients on the sensitivity of measuring angular velocity and Sagnac phase when using FOG are given. Part of the methods for solving this problem are discussed in this article. However, the elemental base and FOG signal processing tools are constantly being improved, the transition to integrated optical technologies is being carried out, which opens up new ways to increase the sensitivity of the FOG with minimal costs. On the basis of the conducted research, practical recommendations are given to reduce the influence of temperature gradients on the sensitivity of FOG. The work can be useful for specialists working in the field of FOG design.