Model Predictive Control (M. Kvasnica, M. Fikar, M. Klaučo, J. Oravec, J. Holaza, P. Bakaráč, M. Furka, M. Horváthová, K. Fedorová, R. Kohút, L. Galčíková, J. Vargan)

Model Predictive control (MPC) has been successful not only in academia but in industrial process applications as well. Its main drawbacks are the stability problems. We focus on broad aspects of new methods in explicit and implicit model predictive control.

Dynamic Optimisation (M. Fikar, R. Paulen)

Increased quality requirements in chemical and petrochemical industries call for more complicated and sophisticated control strategies. Moreover, there is a need to know the achievable limits of performance and speed of transient behaviour of processes. Optimal control theory is able to provide responses to these questions. In this research, changeover problems in multicomponent distillation, waste-water treatment are studied.

Modelling and Control of Chemical Reactors, Biochemical Reactors, Distillation Columns and Heat Exchangers (Ľ. Čirka, M. Fikar, A. Mészáros, J. Vargan, M. Arici)

The research of all research groups is focused on modelling and control of various types of chemical and biochemical processes.

Control Engineering Education (M. Fikar, Ľ. Čirka, M. Kalúz, J. Oravec, P. Bakaráč)

Research in this domain focuses on application of information technologies in control education. This covers interactive on-line blocks and automatic generation of testing problems. The current research involves personification of students problems.

Information Technologies (M. Fikar, Ľ. Čirka, M. Kvasnica, M. Kalúz)

Research in this domain is oriented to:

• application of information technologies for data treatment and visualisation
• development of static and dynamic web pages not olny for purposes of measurement and control but for general information treatment
• automatic data acquisition from various internet sources
  

Open Source solutions are applied:: web, mail, smb servers, databases (MySQL), programming tools (PHP, JavaScript) on operating systems GNU/Linux, FreeBSD, Solaris.

Distributed and Decentralized Optimization (M. Kvasnica, J. Oravec, K. Fedorová, R. Kohút, E. Pavlovičová, K. Kiš)

Research is focused on the control of the system in distributed and decentralized way, in order to decrease computational burden per calculation unit or increase privacy of each node in network. This approach can be also helpful to find the global optimum of non-convex optimization problems.

Guaranteed Parameter Estimation (R. Paulen, M. Mojto)

The quality of the results of model-based optimization and control strongly depends on the accuracy of the models employed. It is essential that the predictions of variables that are considered in the optimization problem, e.g. product quality parameters, are accurate. The quality of the models can be improved by online adaptation of crucial parameters via robust state and parameter estimation schemes. In this respect, we pursue a guaranteed parameter estimation approach to obtain robust estimates of uncertain parameters while avoiding unreliable approximations that are associated with classical estimation approaches.

Machine Learning in Process Control (M. Kvasnica, M. Klaučo, M. Kalúz, K. Kiš)

Machine learning is attracting huge interest not only in academia but also in the industry. The primary aim of this research is to study the application of machine learning approaches to enhance and design controllers of various nature and structure.

Spectral graph theory (S. Pavlíková, N. Krivoňáková)

Spectral graph theory constitutes an important sub-discipline of algebraic graph theory. Its significance consists in pulling together methods of advanced linear algebra, group theory and combinatorics to the study of properties of graphs and discrete structures in general. In addition to this, it turns out that spectral graph theory has found numerous applications, most notably in chemistry where spectra of graphs representing molecules carry information about their energy and hence stability. Numerous methods have been developed for investigation of graph spectra; a recent one consists in graph inversion, an area the members of the team have been active in recent years.

Uncertainty modeling (A. Kolesárová, Z. Takáč, Ľ. Horanská, P. Viceník)

Research in this domain focuses on fuzzy sets and interval-valued fuzzy sets, theory of aggregation operators, measure and integral theory, copulas, triangular norms and conorms. Theoretical results are applied in multi-criteria decision making, image processing, and artificial intelligence.

Number Theory (V. Baláž, T. Visnyai)

Basic research in number theory is immensely important not only for the theory itself but also for every area of mathematics. The results of this theory bring applications to different areas of scientific and social life. It is useful to deal with the special properties of individual types of numbers (divisibility, different expansion of real numbers, etc.), each numerical theoretical result being a potential contribution to solving basic problems and hypotheses such as problems with Fermat numbers, Mersen numbers, the existence of prime numbers of different shapes (e.g. n!+1), perfect numbers, the existence of sequences consisting of prime numbers, express rational numbers by prime numbers, etc., Catalan's, Goldbach's and Waring's hypothesis, and others.

Probabilistic Number Theory (V. Baláž, T. Visnyai)

Probabilistic number theory also includes the theory of distribution of sequences, which is a key area of mathematical analysis. Specially, the theory of distribution of modulo 1, it is an important part of number theory with many applications in mathematics and also in other disciplines. The most important case is the theory of uniform distribution of modulo 1, which is the theoretical basis of the Quasi-Monte Carlo method known as an effective tool for solving the whole spectrum of difficult problems in different areas of human knowledge. For small dimensions, the estimation of quasi-Monte Carlo integration error by using Koksma-Hawka's theorem is better than the estimation of error for Monte Carlo method. The aim is to find an error estimation that could be used for large dimensions (for example, in the insurance exist integrals for dimension m = 360).

Special convergences (V. Baláž, A. Maťašovský, T. Visnyai)

Below the density on the set of natural numbers, we mean every non-negative measure. The basic densities are asymptotic density, Buck density, uniform density, logarithmic density, weight density, densities assigned to summation methods, especially densities to matrix summation methods are known. Using density we can define special types of convergence, so called convergence according to the ideal containing null-sets for a given density. To asymptotic density, we receive statistical convergence, even density, even convergence, For the general ideal of subsets of the set of natural numbers, we receive so called I-convergence introduced by P. Kostyrko, T. Šalát and W. Wilczinski (2000-2001), that is equivalent to convergence according dual filter. Another type of convergence is almost convergence, strong - Ceasaro convergence and so on. Special convergences have been shown to have various applications in Number Theory and Mathematical Analysis. Inclusions, their metric and topological properties are studied among sets of such converging sequences.

Generalized types of continuity (V. Baláž, A. Maťašovský, T. Visnyai)

The notion of continuity is a nondetachable part of our life, there is no scientific area in which the term would not appear. The notion continuity and its various generalized types, as quasi-continuity, somewhat continuity, almost continuity, almost quasi-continuity, and others have a number of applications in mathematics itself, whether we consider it for the functions of one or more variables (finitely or infinitely many variables). It is known that if we consider the functions of several variables then the separate quasi-continuity at each variable gives the quasi-continuity, the same statement does not apply to continuity. Although each continuous function is quasi-continuous (the opposite does not apply). There is a natural question, whether there is a stronger type of continuity for functions of several variables, such that its separate continuity would guarantee the continuity of a given function. It is necessary to find a given type of continuity and to examine its properties and to compare it with the notion of a strong separate connection. In the final dimension, the strong separate continuity implies the continuity of the function of several variables.