Abstract: Considering the instability and distortion of power hardware-in-the-loop simulation（PHILs）system caused by the sampling delay and discretization error,a unified discrete-domain model for PHIL system and a D-segmentation-based stable boundary calculation method are proposed in this paper. Compared with the traditional continuous-domain model,a high-frequency instability of PHILs caused by delay and discretization is discovered by this proposed model and a reduced impedance range of hardware under test（HUT）in PHILs is indicated by the presented stable boundary. The PHILs experiments verify the correctness of the proposed modeling method and the stability boundary and demonstrate the influence of simulation step and impedance matching on the stability of PHILs.The results show that the FPGA-based small-step PHILs is an effective tool to simulate the interaction between weak grid and inverter because of an increasing stable boundary and enlarged the impedance range of HUT.