This paper presents a probabilistic approach to the characterization of dynamical models of induction machine clusters. The authors' method derives bounds on eigenvalue variations for linearized models expressed in terms of stochastic norms. In their examples of the modeling of power system loads, this characterization tends to be less conservative than alternative deterministic approaches. They consider examples of induction machines with different ratings (classes), and allow for wide variations of electrical and mechanical parameters. They describe a stochastic norm approach to: (1) efficiently describe the dynamical model variations for a cluster of similar machines without having to perform repeated eigenvalue calculations, e.g. in a wind farm application; and (2) suggest the order of the reduced model in power system load modeling where the tightness of the bounds of eigenvalue variations is used for guidance in decisions regarding the number of different classes that would efficiently represent a given composite load.
[1]
Aleksandar M. Stankovic,et al.
A probabilistic approach to aggregate induction machine modeling
,
1996
.
[2]
M. David Kankam,et al.
Aggregation of Induction Motors for Transient Stability Load Modeling
,
1987,
IEEE Transactions on Power Systems.
[3]
G. W. Stewart,et al.
Stochastic Perturbation Theory
,
1990,
SIAM Rev..
[4]
A. Morelato,et al.
Improving dynamic aggregation of induction motor models
,
1994
.
[5]
S. Ahmed-Zaid,et al.
Structural modeling of small and large induction machines using integral manifolds
,
1991
.
[6]
A.M. Stankovic,et al.
Parametric variations of induction machine models: a statistical characterization
,
1995,
Proceedings of International Conference on Control Applications.