Electromagnetic transient simulation for large-scale power system is a time-consuming problem. A new frequency-dependent equivalence method is presented in the paper, which might significantly accelerate power system electromagnetic transient simulation. In the method, an effective algorithm is designed to directly transfer the port admittance determinant of external system's mixing matrix into admittance rational function; and the step-by-step strategy for the equivalence of actual large system is put forward, which further reduces the calculation quantities needed. Moreover, the study of multiple real root pole characteristics of admittance transfer function of two-port network is performed and a proposition is achieved. Based on the proposition and residue theorem, the equivalence system for external system corresponding to the admittance rational function is obtained. The computation complexity of the step-by-step equivalence method is about o(aOE < n/n (p) aOE parts per thousand xt)(aOE < aOE parts per thousand is upper integral operation, n is the total buses number of external system, N (P) is the total buses number of single step equivalence network, T is single step equivalence time), which indicates that the computation complexity of the method proposed has nearly linear relationship with the buses number of external system, and the method proposed has satisfactory computation speed. Since the mixing matrix of external system includes all the information of external system, therefore, port admittance rational function derived from it can reflect its full frequency characteristic and the equivalence network achieved has high equivalence precision. Moreover, since the port rational function is gained at the condition of the external system without source, which equals stable passive network, it could not show any unstable pole and need not extra measure to make the equivalence system stable. The test results of the samples and comparison with other methods demonstrate that the new method proposed is valid and effective.

• 出版日期2012-7
• 单位天津大学; 中国电力科学研究院