The growth of the electric motor industry requires cheaper and more efficient solutions, so one of these solutions in the future could be switched-reluctance motors. It is a type of electric motor with salient poles that uses a change in reluctance (magnetic resistance) to create torque and what sets them apart from other motors is its simple build and low cost. In switched reluctance motors, the stator windings are powered, and the rotor has no windings and can consist of one piece of ferromagnetic material. This greatly simplifies the mechanical design but complicates the electrical design because it is necessary to make a certain system to change the supply of voltage to the different stator windings. In industry, transport, commercial and residential applications, permanent magnet motors and induction motors dominate, but switched reluctance motors are more suitable for operation at high speeds and temperatures compared to other motor types due to a robust rotor core that can withstand high speeds, centrifugal forces and high temperatures. Disadvantages of switched reluctance motors are torque ripple, acoustic noise and vibrations, and low power factor when working with light loads. Torque ripple and noise can be reduced by changing various parameters such as stator and rotor geometry, pole combination, material, shaft and current control. The description of the energy conversion during rotor rotation explains why the switched reluctance motor has a low power factor when operating at light loads and why the power factor is higher in saturation. Switched reluctance motors are identified by the number of stator and rotor poles, so for example a switched reluctance motor with 6 stator poles and 4 rotor poles is called a 6/4 PRM. The choice of the number of stator and rotor poles has a significant impact on the operation and performance of the motor, affects torque ripple and the choice of the number of phases. The modelling of a switched reluctance motor in the Motor-CAD software package is described. Motor-CAD is used for electromagnetic and thermal analysis and design of electric motors and is used here on the example of three motors: 12/8 SRM, 24/16 SRM and 6/14 SRM. The parameters of the switched reluctance motors at different operating points are observed and the results of the calculation are displayed. The operation of switched reluctance motors can be optimized by changing current, voltage and on and off angles.