Baranyi and Yam proposed the concept of M-mode SVD/HOSVD-based canonical form of TP functions and quasi-LPV system models. Szeidl et al. proved that the TP model transformation is capable of numerically reconstructing this canonical form.
Baranyi and Yam employed the ideas described by De Lathauwer etal and the algorithm developed by Vasilescu and Terzopoulos under the name M-mode SVD. The M-mode SVD is referred in the literature as either the Tucker or the HOSVD. The Tucker algorithm and the DeLathauwer etal. companion algorithm are sequential algorithm that employ gradient descent or the power method, respectively.
Related definitions (on TP functions, finite element TP functions, and TP models) can be found here. Details on the control theoretical background (i.e., the TP type polytopic Linear Parameter-Varying state-space model) can be found here.
A free MATLAB implementation of the TP model transformation can be downloaded at https://web.archive.org/web/20120229061018/http://tptool.sztaki.hu/ or at MATLAB Central http://www.mathworks.com/matlabcentral/fileexchange/25514-tp-tool.
Assume a given finite element TP function:
where . Assume that, the weighting functions in are othonormal (or we transform to) for . Then, the execution of the HOSVD on the core tensor leads to:
Then,
that is:
where weighting functions of are orthonormed (as both the and where orthonormed) and core tensor contains the higher-order singular values.
&* ordering: for all possible values of .