Throughout the project, we carried out the work defined in the three objectives and translated our mathematical insights into practical tools for researchers and engineers. The overview below provides somewhat more technical detail than the previous summary.
OBJECTIVE 1: UNDERSTANDING THE MATHEMATICS BEHIND DATA-DRIVEN MODELS
We revealed how the four fundamental subspaces of (block-)Macaulay matrices provide a unified framework for solving the core tasks in our modeling approach—multivariate polynomial equations and multiparameter eigenvalue problems (MEPs). The right null space shows that the solutions can be computed as the eigenvalues of an associated matrix; the left null space describes how the equations interact; the row space delivers the difference equations that define multi dimensional (mD) systems and enables numerical elimination in both polynomial equations and polynomial dynamic models; the properties of the column space can be used to speed up calculations.
OBJECTIVE 2: OPTIMAL MODELS FROM NON-MODEL-COMPLIANT DATA
We proved that globally optimal models can be obtained by formulating the optimization problem as a rectangular MEP. The same approach yields a globally optimal model reduction method. Working with the associated MEPs also enabled us, for the first time, to count the exact number of solutions.
OBJECTIVE 3: EFFICIENT ALGORITHMS FOR OPTIMAL MODELS
We developed efficient numerical algorithms exploiting the special structure and properties of the underlying matrices. A key outcome is MacaulayLab (
http://macaulaylab.net(öffnet in neuem Fenster)) a publicly available MATLAB toolbox for solving multivariate polynomial equations and MEPs, including a database of test problems.
Furthermore, we introduced two elimination methods based on tools from numerical linear algebra, such as the well-known singular value decomposition (SVD) and the less well known cosine–sine decomposition (CSD). We also developed an SVD‑based state elimination technique for polynomial dynamic models.
EXPLOITATION AND DISSEMINATION
We disseminated our results through peer reviewed publications, conferences, seminars and invited talks, listed at
https://homes.esat.kuleuven.be/~sistawww/bdm/backtotheroots/(öffnet in neuem Fenster).
MacaulayLab makes our algorithms widely accessible to researchers and practitioners.
The freely available draft of our didactic book “Back to the Roots” presents the framework to a broad mathematical‑engineering audience and supports adoption in research and teaching.