In the thesis, I present the implementation of speed control on an induction machine. In the first chapter, I provide a general overview of electric machines and delve deeper into the physical operation of the utilized induction machine and its history. This is followed by a description of the set objectives: creating a mathematical model of the machine, carrying out control implementations, and utilizing the model for further development of control algorithms. The main part of the thesis can be divided into two sections from a content perspective. The first section involves creating a mathematical model using the Matlab extension Simulink. The second section focuses on control implementations, specifically the U/f control, on this machine model. In the second chapter, I outline the methodology for developing the induction machine model, presenting the theory and equations used to construct the model in Simulink. In the subsequent chapter, I review the obtained results from simulations of the mathematical machine model and assess the suitability of its operation. The fourth chapter centers on the speed control of the machine. I describe various approaches for adjusting the machine's speed and provide a more detailed presentation of scalar control (U/f), using equations and a block diagram. This is followed by a review of the results from the U/f control implementation, where I examine the output data from simulations and provide commentary on their alignment with expectations. In the sixth chapter, I summarize the findings from the obtained results and present plans for future work.