From time series to linear system-Part II. Exact modelling
Automatica (Journal of IFAC)
SIAM Journal on Control and Optimization
Brief paper: An approach to closed-loop subspace identification by orthogonal decomposition
Automatica (Journal of IFAC)
Survey paper: Structured low-rank approximation and its applications
Automatica (Journal of IFAC)
Model selection approaches for non-linear system identification: a review
International Journal of Systems Science
High-performance numerical algorithms and software for structured total least squares
Journal of Computational and Applied Mathematics
Hi-index | 22.15 |
New algorithms for identification of a balanced state space representation are proposed. They are based on a procedure for the estimation of impulse response and sequential zero input responses directly from data. The proposed algorithms are more efficient than the existing alternatives that compute the whole Hankel matrix of Markov parameters. It is shown that the computations can be performed on Hankel matrices of the input-output data of various dimensions. By choosing wider matrices, we need persistency of excitation of smaller order. Moreover, this leads to computational savings and improved statistical accuracy when the data is noisy. Using a finite amount of input-output data, the existing algorithms compute finite time balanced representation and the identified models have a lower bound on the distance to an exact balanced representation. The proposed algorithm can approximate arbitrarily closely an exact balanced representation. Moreover, the finite time balancing parameter can be selected automatically by monitoring the decay of the impulse response. We show what is the optimal in terms of minimal identifiability condition partition of the data into ''past'' and ''future''.