The development of energy-efficient electrical machines requires an accurate knowledge of the soft- and hard-magnetic material behavior already in the design stage. Accurate numerical models are required which offer the ability of better understanding and modelling in an appropriate accuracy. With such model properties on the one hand accurate simulations can be performed and on the other hand the best possible material choice for a particular application, i.e. for an electrical machine, can be done. The soft-magnetic material constitutes the magnetic core of an electrical machine and its properties. On that account, the accurate prediction of iron losses of soft-magnetic materials for various frequencies and magnetic flux densities, i.e., arbitrary magnetic field waveforms, is eminent for the design of electrical machines [1]. For this purpose different phenomenological iron-loss models were proposed, which describe the loss-generating effects, i.e., hysteresis, non-local eddy currents and anomalous eddy currents. Most of these suffer from poor accuracy for not considering the effect of high frequencies and high material utilization as well as the material degradation due to the magneto-elastic coupling [2, 3, 5]. This paper presents a comparison of common iron-loss models. The IEM-formula used, resolves the limitation by introducing a high-order term of the magnetic flux density and considers the alteration of material-dependent loss-parameters due to the magneto-elastic coupling [3]. The knowledge of the magnetic property deterioration due to induced residual stress occurring during the manufacturing or operation of the electrical machine is indispensable for the contemporary design. It has been widely ascertained that processing of electrical steel laminations significantly alters the magnetic properties of the electrical steel [2–6]. Cutting induces plastic deformation and residual stress in the laminations. Due to their strong sensitivity to mechanical stress,...