Events

Upcoming events

Bridging the Practicality Gaps in Responsible AI

Ayan Majumdar Max Planck Institute for Software Systems
13 Jul 2026, 11:00 am - 12:00 pm
Saarbrücken building E1 5, room 029
SWS Student Defense Talks - Thesis Proposal
AI-driven systems increasingly shape consequential decisions in domains such as lending, university admissions, and content moderation. Yet making these systems trustworthy in practice requires more than principled algorithms: it requires methods that scale, account for bias throughout the decision-making process, and can be evaluated against deployed real-world systems. This thesis addresses these challenges through three lines of work: scalable causal algorithmic recourse, fairness across the decision-making pipeline, and content policy enforcement on digital platforms.

First, ...
AI-driven systems increasingly shape consequential decisions in domains such as lending, university admissions, and content moderation. Yet making these systems trustworthy in practice requires more than principled algorithms: it requires methods that scale, account for bias throughout the decision-making process, and can be evaluated against deployed real-world systems. This thesis addresses these challenges through three lines of work: scalable causal algorithmic recourse, fairness across the decision-making pipeline, and content policy enforcement on digital platforms.

First, it introduces CARMA, a neural-network-based approach that amortizes causal recourse generation, producing near-real-time recommendations while preserving causal validity and effort optimality. Second, it addresses fairness across the decision-making pipeline by developing a causal framework for measuring and mitigating bias in post-selection treatment decisions, alongside an online learning framework, FairAll, that learns fair and temporally consistent selection policies without sacrificing utility. Third, it studies instruction-driven moderation with foundation models and introduces ModerationBench, a benchmark of multimodal, in-the-wild social media content grounded in Bluesky’s deployed moderation guidelines.

Together, these contributions push Responsible AI beyond idealized settings and toward practical deployment. They provide scalable mechanisms for recourse, broader tools for fairness across the full decision-making pipeline, and grounded methods for evaluating adaptable content-safety enforcement in real-world digital platforms.
Read more

Recent events

Verification of Concurrent Pushdown Systems with Dynamic Creation of Threads

Pascal Baumann Max Planck Institute for Software Systems
25 Jun 2026, 11:00 am - 12:00 pm
Saarbrücken building G26, room 111
SWS Student Defense Talks - Thesis Proposal
Multi-pushdown automata (MPDA) are a classic computational model that can be used to capture the behavior of multithreaded recursive programs. Here, each parallel thread is simply modeled by a single stack, and there is a fixed number of them. Due to the well known fact that most verification problems are undecidable for MPDA, even with just two stacks, the literature contains many different ways to restrict the runs of this model, in such a manner as to recover decidability. ...
Multi-pushdown automata (MPDA) are a classic computational model that can be used to capture the behavior of multithreaded recursive programs. Here, each parallel thread is simply modeled by a single stack, and there is a fixed number of them. Due to the well known fact that most verification problems are undecidable for MPDA, even with just two stacks, the literature contains many different ways to restrict the runs of this model, in such a manner as to recover decidability. A popular restriction of this kind is known as bounded context-switching: For a fixed bound k, every parallel thread (or stack) may only be interrupted by another thread up to k times.

We consider an extended setting, where the number of parallel threads is not fixed, and more of them can be spawned dynamically during execution. This gives rise to the model of dynamic networks of concurrent pushdown systems (DCPS), which we still restrict with bounded context-switching. In this setting, we consider various verification questions, that have been asked for similar models in the past. These include state reachability, non-termination (with and without assumptions on fairness), and boundedness of the thread buffer. Moreover we consider the novel verification problem of Dyck inclusion: Given a model with action sequences over some alphabet of bracket pairs, are all its executions well-bracketed? Our results close a preexisting complexity gap for state reachability, and settle the complexity of several other verification problems, where in many cases even decidability was unknown before
Read more

Quantum Internet: From Hardware to Application

Prof. Stephanie Wehner TUDelft
(hosted by Krishna Gummadi)
01 Jun 2026, 10:00 am - 11:00 am
Saarbrücken building E1 5, room 029
SWS Distinguished Lecture Series
Software is what turns quantum hardware into technology everyone can use. In this talk we focus on the quantum communication networks, with the first metropolitan scale quantum networks being built and the technologies to connect them over long distances advancing. We begin with the first operating system for quantum networks (QNodeOS), allowing applications to be programmed and executed on arbitrary quantum processors connected to a quantum network. Demonstrated on two different types of quantum hardware, QNodeOS now provides a framework for experimenting with software systems for quantum networks. ...
Software is what turns quantum hardware into technology everyone can use. In this talk we focus on the quantum communication networks, with the first metropolitan scale quantum networks being built and the technologies to connect them over long distances advancing. We begin with the first operating system for quantum networks (QNodeOS), allowing applications to be programmed and executed on arbitrary quantum processors connected to a quantum network. Demonstrated on two different types of quantum hardware, QNodeOS now provides a framework for experimenting with software systems for quantum networks. We then turn to a specific kind of quantum network application, in which entanglement is harnessed for coordination between distant parties. We explore this through a recent example in radio spectrum allocation, opening the door to a new domain of quantum network applications.
Read more

Modern Fine-Grained Complexity

Nick Fischer MPI-INF - D1
06 May 2026, 12:15 pm - 1:15 pm
Saarbrücken building E1 5, room 002
Joint Lecture Series
Put yourself in the shoes of an algorithm designer working on some computational problem. You have found an algorithm running in time O(n^2), say, but after months of effort no faster algorithm is in sight. Perhaps your algorithm is already optimal – but how could you show this? This is the central challenge of fine-grained complexity theory. In the spirit of classical NP-hardness, this theory starts from the assumption that certain canonical problems are hard, and then uses so-called fine-grained reductions to show that many other problems are conditionally hard as well. ...
Put yourself in the shoes of an algorithm designer working on some computational problem. You have found an algorithm running in time O(n^2), say, but after months of effort no faster algorithm is in sight. Perhaps your algorithm is already optimal – but how could you show this? This is the central challenge of fine-grained complexity theory. In the spirit of classical NP-hardness, this theory starts from the assumption that certain canonical problems are hard, and then uses so-called fine-grained reductions to show that many other problems are conditionally hard as well.

In this talk, I will first describe the basic concepts of fine-grained complexity along with some illustrative examples, before turning to more recent developments, including some of my own work. I will discuss some questions that resisted the basic theory for a long time, and how progress on them has required a more sophisticated method – the celebrated structure-versus-randomness paradigm.
Read more

Archive