The thermal deformation of spindle is one of the important factors that affect the machining accuracy of machine tools. The friction of the bearings of spindle during high-speed machining causes the temperature rising and thermal deformation of spindle and thereby affects the machining accuracy. To improve the machining accuracy, the thermal compensation technology is a useful method to correct the machining error induced by the thermal deformation of spindle. The author firstly establishes a simplified theoretical model of the spindle based on physical principles and the empirical formula proposed by literatures and then adopts the method of grey-box system identification to establish the thermal network model of the spindle. The thermal network model can estimate the temperatures of 7 feature points within the spindle and its amount and time of numerical calculation are much lower than the finite element method. After that, by means of the method of black-box system identification, the temperatures of the 7 feature points estimated by the aforesaid thermal network model are used as the input data to training the thermal deformation model of the spindle. The resulting thermal deformation model is expressed in terms of state space and can estimate the axial deformation of the spindle. Finally, the author further simplifies the thermal deformation model of the spindle by means of the correlation coefficient method in statistics. The simplified thermal deformation model requires only the input temperature data of 3 feature points within the spindle. The simplified thermal deformation model further reduces the amount and time of numerical calculation while remaining the accuracy. The integration of the aforesaid thermal network model and thermal deformation model, one can estimate the thermal deformation of the spindle from its rotational speed. Comparing with the experimental measurement, the error of the estimated thermal deformation is less 2 μm. The proposed method of thermal deformation estimation is applicable to the thermal compensation of machine tool.