Fault detection and fault tolerance concerning electric drives are important research fields that ensure robustness and increased safety of vehicles and other drive systems. One of key components inside the permanent magnet synchronous motor electric drive, for mobile systems, is it’s battery power supply. Fault inside the drive’s power supply can cause a sudden interruption of the energy flow. In an event of an improper response of the control system this interruption can result in a loss of control over the electrical quantities of the drive, damage of the electronic components, as a result of overvoltage condition, or an abrupt loss of supply feeding the control systems. The first step towards establishing operation in the presence of a fault is a robust real-time detection of the power supply open circuit fault. This thesis proposes a model-based approach of fault detection based on the lumped electric circuit model of the power supply system. Using the power supply model, it is possible to determine the DC-link voltage of the electric drive based on the calculated inverter current and open circuit battery voltage. Since the open circuit battery voltage cannot be measured directly, a sliding mode observer is proposed. The deviation between the estimated and measured DC-link voltage is then used as a fault indicator. Value of a diagnostic threshold, which enables elimination of false positive detection, is based on the analytic calculation of measurement error and system parameter variability. Operation during the fault relies on the rotational energy of the electric drive, which could provide the energy necessary for maintaining the level of a DC-link voltage. Control over DC-link voltage enables operation in field weakening region, prevents secondary damage due to failure of electric components and, in case of drives supplied with single power source, provides the energy source for control systems. A DC-link voltage regulator is proposed, with its internal control loop based on the well-known field oriented control of the permanent magnet synchronous motor. Parameters of the cascade control loop are crucial for the stability and rapid transition to fault operation during an active open circuit fault. An analytic approach based on the model of the system was developed for determining the parameters of the DC-link voltage PI controller, using the method of reducing the order of system transfer function. System modelling and numerical calculations inside MATLAB/Simulink environment were used for verification of the key approaches stated in the thesis. Results comprise of comparisons between established lithium battery models and that proposed in the thesis, impact analysis of the change in machine’s magnetic field energy during the fault, and numerical results of error transformations that affect successful fault detection. Experimental results that confirm the possibility of deploying the proposed principles on a real electric drive are performed by coupling two electric drives with its respective battery power supplies. Firstly, the immunity to a false positive fault detection in case of sudden changes of the drives operating point is verified, followed by a successful presentation of fault detection in case of power supply circuit interruption. The response of the DC-link voltage regulator in combination with detection algorithm is verified for various operating conditions defined prior to the occurrence of open circuit power supply fault. Conclusion of the thesis contains an overview of novel contributions to the related research fields, prospects for future research, and the possibilities of applying proposed principles to the broader research field of electric drive systems.