In her Master's thesis, Kathrin Seßler addresses the issue of the multimodal data generation using self-attention-based models, such as Transformers. The Master's thesis is supervised by Gjergji Kasneci and supported by Vadim Borisov in an advisory capacity.

In his Master's thesis, Felix Sieghörtner addressed the issue of the black-box model explainability. The Master's thesis was supervised by Gjergji Kasneci and supported by Vadim Borisov in an advisory capacity.

The abstract: 
Machine learning algorithms and deep neural networks see a significant rise in popularity for all kinds of problem-solving. Whether it is auto-correction in our cell phones or route-finding in our navigation systems, machine learning plays a key role in our daily lives. Some of them may have a heavy impact on human life, such as assisting doctors in selecting the appropriate treatment for patients. For this reason, the Explainability of Artificial Intelligence (XAI) is becoming an increasingly important field of study. Being able to explain decisions made by an AI, helps humans to understand its choices and is crucial for ensuring a wide acceptance among the public.
This thesis presents a Python framework for explainable AI. The key elements of it are two novel algorithms for generating and evaluating feature attributions for computer vision tasks. The developed perturbation- and permutation-based feature attribution generation method is model-agnostic and without the need to train any surrogate machine learning model. The evaluation method replaces superpixels with other superpixels and reevaluates the image afterward. In addition to a visual and empirical evaluation, these methods are compared to the current state-of-the-art feature attribution approaches, resulting in the novel methods performing on par or, in some cases, even better than existing ones.

Manuel Weiß beschäftigte sich in seiner Bachelorarbeit mit der Erweiterung des lokalen Erklärmodells LICON. Ziel der Arbeit war, LICON für die Verwendung in Bayesschen Neuronalen Netzwerken zu adaptieren. Durch diesen Schritt wird eine Quantifizierung der Unsicherheit in Bezug auf die generierten Feature Attributionen möglich, wodurch die Erklärungen an Robustheit und Aussagekraft gewinnen. Die Bachelorarbeit wurde von Gjergji Kasneci betreut und von Johannes Haug beratend unterstützt.

David Hildner is working on master's thesis, project entitled "amorf - A Multi-Output Regression Framework".

Multi-output regression is the problem of learning a mapping from a multi-dimensional real-valued input space to a multi-dimensional real-valued output space. So far no framework specifically designed for multi-output regression has been developed in Python. In this thesis a number of different multi-output regression methods are presented, evaluated and implemented into to the Python framework amorf. A novel approach, the autoencoder assisted multi-target regression, is introduced.