The thesis presents complete solution for control and management of permanent magnet synchronous machine at elevated operating temperatures with torque estimation and field weakening mode. The solution is made as an expansion of basic FOC scheme and does not need any hardware modifications. As a result it can be considered a cost-effective and relatively simple upgrade to existing control system. Introduction of the thesis provides the overview of different areas considered in this research, from torque estimation, drive protection measures and demagnetization modelling followed by a problem definition of controlling the electric drive at elevated temperatures. After the definition of general model equations of permanent magnet synchronous machine and presentation of field oriented control in field weakening mode, the thesis focuses on non-salient pole type of machine. The main reason for this is the simplification of the problem approach. Decreased performance of machine at elevated temperatures and the corresponding machine torque estimation are the initial guidelines of the present work, following from permanent magnet material properties. Demagnetization mechanism, together with demagnetization modelling represent a great part of the thesis. Central and longest chapter deals with modeling of demagnetization with finite element method, through which an appropriate magnetic structure for simplified magnetic circuit is derived. The results from both the magnetic circuit and finite element method are compared to justify the accuracy of proposed magnetic circuit. The stator reverse field estimation, which directly affects the permanent magnets, is determined using the magnetic circuit approach. The permanent magnet temperature is determined with simple modified flux observer. Using both the permanent magnets temperature and magnetic circuit, the permanent magnets operating point on B(H) curve is obtained. Followed by calculation of safe operating area, which is defined as the distance between current operating point of permanent magnets and the knee point of B(H) curve, the stator field weakening current is limited to prevent their demagnetization. The results chapter presents the operation of proposed system in both simulations and in practical laboratory model. Results are obtained in two regimes, namely at constant field weakening operation and a rising temperature of permanent magnets and at constant temperature and progressive field weakening. The efficiency of proposed torque and temperature estimation method along with the permanent magnet demagnetization protection mechanism are presented. It is also shown that the accuracy of torque estimation enables the compensation of the decreased torque generation due to thermal effects. For a clearer illustration of position of the operating point of permanent magnets according to B(H) characteristics, 3D graphs in both regimes are also shown at the end of the chapter. The results of both the simulation and laboratory model are gathered together on the same graph to better present their correspondence. It can be seen how the operating point stays within reversible demagnetization area in case of active demagnetization protection and how in the absence of protection the operating point shifts below the knee of B(H) characteristics into the irreversible demagnetization. The final chapter briefly summarizes the work and definition of its main features and indicates the possibility of further work development of the proposed system. Particularly, the salient pole permanent magnet synchronous machines are to be considered in the future work in this field.