Welcome to the page of the Chair of Mathematics - Scientific Computing

The Scientific Computing group works on the development and analysis of methods in data science, in particular those based on applied harmonic analysis and functional analysis. Focus topics include signal processing, information theory, sampling theory, time-frequency analysis, quantization and machine learning.

For example, our group develops efficient methods to assemble (synthesize) from or decompose (analyse) functions or operators into well-understood basic building blocks. Analysis relies on the understanding of appropriately chosen basic components and on determining the weight of each component in a given signal. For example, a picture can be decomposed into patches of red, green, and blue of varying intensities. The dual operation is signal synthesis. Using the same building blocks as in the analysis step, we can assemble or reassemble (after transmitting and/or modifying coefficients) signals and transformations to our liking. Returning to our example, we could, starting from scratch, draw a picture by choosing patches of red, green, and blue and intensities freely.

In digital communications, synthesis and analysis are applied in succession. To transmit digital data through a medium, an analog signal is formed using a synthesis step. Here, the digital information is embedded in the weights. The receiver then performs an analysis of the obtained signal to extract the weights and with it the digital data. The principal objective is to design building blocks that are robust against disturbances present in transmission channels.

Within the past decade, mathematical contributions to these objectives had an tremendous impact on signal processing and communications engineering: wavelet bases were designed to analyze images (jpeg2000), and Gabor systems are currently used to transmit data through wired or wireless channels (OFDM). A wavelet basis consists of functions, which are all equal in shape but which are translated (shifted in time or space) or stretched copies of each other. The building blocks in Gabor theory on the other hand are functions, which are modulated (frequency-shifted) and translated (shifted in time or space) copies of each other.
In recent years, our research within the framework described above focused on time--frequency analysis of operators and Gabor analysis, and their applications in communications engineering. (For educational material, visit the website of the Summer Academy of the Jacobs University Bremen: Progress in Mathematics for Communication Systems.)

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Math News

06-04-2025

Dr. Hidde Schönberger receives award from Sparkasse Ingolstadt Eichstätt for the best dissertation

As part of this year's Dies Academicus, Dr. Hidde Schönberger received the award for the best dissertation for his work titled "Nonlocal gradients within variational models: Existence theories and asymptotic analysis." The dissertation, written under the supervision of Prof. Dr. Carolin Kreisbeck at the Chair of Mathematics – Analysis, consists of 6 research articles and was previously honored with the prestigious Klaus-Körper Prize of the Society for Applied Mathematics and Mechanics (GAMM).

In his dissertation, Dr. Schönberger investigates mathematical models involving nonlocal gradients — a highly topical subject in variational calculus, particularly relevant in the modeling of material behavior. As opposed to classical models in the literature based on local quantities like the derivative, the nonlocal analogues allow for discontinuities to emerge, which is of relevance for studying when materials fracture. His work establishes that solutions of these nonlocal variational problems exist and identifies their dependence on crucial parameters in the model. Since these solutions cannot be computed explicitly, proving that they exist is important not only from a theoretical point, but also from an applied point of view where they need to be approximated with the computer. Furthermore, the asymptotic analysis shows, in particular, that the nonlocal models are consistent with their local counterparts that have already been used for many decades. The concepts introduced in the thesis represent a significant contribution to the understanding and advancement of nonlocal variational principles. A crucial tool that is introduced allows the analysis of the more intractable nonlocal gradients to be reduced to their simpler local versions, and this provides a methodology that can help solve many other problems in the nonlocal setting as well.

Dr. Hidde Schönberger completed his BSc and MSc in mathematics cum laude at Utrecht University, after which he continued as/became a doctoral researcher at KU in 2021 During that time, he presented his work at various conferences and completed a research visit to Universidad Autonoma de Madrid in Spain. Since September 2024, he is a postdoc at the Institute for Analysis and Scientific Computing at TU Wien, where he continues his research on nonlocal problems in the calculus of variations.

We sincerely congratulate Dr. Schönberger on this well-deserved award and wish him continued success in his future career!

MIDS seminar

Mathematical Institute for Machine Learning and Data Science

The Chair of Scientific Computing is part of the new founded Mathematical Institute for Machine Learning and Data Science, MIDS.
Learn more about MIDS here.