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Date
Title
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01/09/2022
15:00 - 16:00
BSc
Arithmetic with Bounded Depth Threshold Circuits
Elena Küchle
[bachelor]Feed-forward neural networks (FNNs) have gained considerable attention in recent years due to their success in dealing with a number of machine learning problems. One way to model such networks is by means of threshold (LT) circuits. Threshold circuits are a well-studied extension of the traditional model of boolean circuits. However, little to no research has been conducted on the arithmetic of rational numbers using threshold circuits. First, we assess the state of the art knowledge of the basic arithmetic functions on integers with bounded depth LT circuits. In addition, we show that these results also hold for the arithmetic on rationals. Lastly, we approximate non-rational functions, such as the exponential and the natural logarithm functions, using LT circuits.
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01/09/2022
15:00 - 16:00
BSc
Arithmetic with Bounded Depth Threshold Circuits
Elena Küchle
[bachelor]Feed-forward neural networks (FNNs) have gained considerable attention in recent years due to their success in dealing with a number of machine learning problems. One way to model such networks is by means of threshold (LT) circuits. Threshold circuits are a well-studied extension of the traditional model of boolean circuits. However, little to no research has been conducted on the arithmetic of rational numbers using threshold circuits. First, we assess the state of the art knowledge of the basic arithmetic functions on integers with bounded depth LT circuits. In addition, we show that these results also hold for the arithmetic on rationals. Lastly, we approximate non-rational functions, such as the exponential and the natural logarithm functions, using LT circuits.
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24/08/2022
14:00 - 15:00
Ensemble Graph Neural Networks for Constraint Satisfaction Problems
Combinatorial optimization is a crucial research area in the field of operations research and computer science. Over the years, there has been a recent surge in solving combinatorial optimization tasks using machine learning and especially Graph Neural Networks (GNNs). Due to their scalability and inherent graph-based design, GNNs present an alternative platform to build large-scale combinatorial heuristics. A recent example of this is RUN-CSP, which is a highly scalable, heuristic solver for binary Maximum-Constraint Satisfaction Problems (Max-CSPs). This thesis aims to empirically evaluate the performance improvement on Max-CSPs like Max-k-COL using ensemble based learning techniques with RUN-CSP as their base architecture.
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15/08/2022
10:00 - 10:45
MSc
Pliability and the Approximability of Maximum Constraint Satisfaction Problems
Benedikt Mews
[master] The constraint satisfaction problem (CSP) generalizes several common NP-complete problems and is therefore computationally hard to solve. It gained interest in the computational complexity community for the many natural ways it can be restricted to achieve tractable problems. For each of these restrictions, the aim is to identify a dichotomy, a property that splits CSPs strictly into the complexity classes NP-hard and PTIME. Among these restrictions, this master thesis focuses on the structurally restricted optimization variant of CSP under polynomial time approximation scheme (PTAS)-approximation, for which a dichotomy has recently been conjectured.
This potential dichotomy is based on a property called pliability, which describes classes of graphs that are similar to tree-like graphs under consideration of valued constraints. Pliability has been found to have several interesting aspects that underline its importance: We can exchange the graph property treewidth in its definition with a few other graph properties and still achieve the exact same graph class, it unifies different graph classes for which previous PTAS-approaches were known and it has close connections to other relevant graph properties, namely fragility and hyperfiniteness.
In this talk, we give an overview over the complexity theoretical landscape that surrounds pliability, study the series of results that led up to pliability and put the relevant concepts into relation. Finally, we investigate the computational complexity of recognizing the graph properties that are related to pliability.
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13/07/2022
15:00 - 15:45
MSc
The Computational Power of Transformer Neural Networks
Lionel Damtew
The Transformer Neural Network Architecture, proposed by Vaswani et al. in 2017, proved to be very successful on machine translation tasks as well as other natural language processing tasks. Pérez, Marinković and Barceló studied the computational power of the transformer neural networks and proved them to be Turing complete under specific circumstances. This thesis presents this proof and studies the restrictions under which transformer neural networks are Turing complete and how their computational power depends on these restrictions, with a focus on the activation function and the precision of the numbers used. It shows how the computational power of the architecture is drastically reduced, when fixed precision numbers are used within the computation of the transformers, such that even some regular languages can not be recognized. Additionally, the computational power of a slightly modified architecture where the precision depends on the input length is analysed.
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01/07/2022
10:30 - 11:30
ATI
On the Parameterised Complexity of Learning First-Order LogicSteffen van BergeremWe analyse the complexity of learning first-order queries in a model-theoretic framework for supervised learning introduced by Grohe and Turán (TOCS 2004). Previous research on the complexity of learning in this framework focused on the question of when learning is possible in time sublinear in the background structure. Here we study the parameterised complexity of the learning problem. We have two main results. The first is a hardness result, showing that learning first-order queries is at least as hard as the corresponding model-checking problem, which implies that on general structures it is hard for the parameterised complexity class AW[*]. Our second main contribution is a fixed-parameter tractable agnostic PAC learning algorithm for first-order queries over sparse relational data (more precisely, over nowhere dense background structures).
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01/07/2022
10:30 - 11:30
ATI
On the Parameterised Complexity of Learning First-Order LogicSteffen van BergeremWe analyse the complexity of learning first-order queries in a model-theoretic framework for supervised learning introduced by Grohe and Turán (TOCS 2004). Previous research on the complexity of learning in this framework focused on the question of when learning is possible in time sublinear in the background structure. Here we study the parameterised complexity of the learning problem. We have two main results. The first is a hardness result, showing that learning first-order queries is at least as hard as the corresponding model-checking problem, which implies that on general structures it is hard for the parameterised complexity class AW[*]. Our second main contribution is a fixed-parameter tractable agnostic PAC learning algorithm for first-order queries over sparse relational data (more precisely, over nowhere dense background structures).
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24/06/2022
10:30 - 11:30
ATI
Width of Graph DecompositionsEva Fluck[ati][speaker=https://www.lics.rwth-aachen.de/cms/LICS/Der-Lehrstuhl/Team/Wissenschaftliche-Mitarbeiterinnen-und-M/~ryzs/Eva-Fluck/]
Tree and Path decompositions of graphs are an important and well studied topic
in theoretical computer science and discrete math, since at least the Graph
Minors project of Robertson and Seymour. Recently a generalization to graph
classes beyond paths and trees emerged. In this talk we will look at a possible
width measure for general graph decompositions, since considering the size of
the bag no longer suffices for a rich theory. Furthermore we try to find an
analog to Robertsons and Seymours Excluded Gird Theorem for tree width. That is
we try to find substructures that have to be present in graphs of large width.
We are able to proof a theorem for our width measure on path decompositions and
give a conjecture for all minor closed classes of graphs.
Joint work with Sandra Albrechtsen, Reinhard Diestel, Ann-Kathrin Elm, Raphael
W. Jacobs, Paul Knappe and Paul Wollan.
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23/06/2022
11:00 - 11:45
MSc
Hierarchical Message Passing for Constraint Satisfaction Problems
Moritz Rösgen
RUN-CSP is a graph neural network solving optimization problems modelled as constraint satisfaction problems (CSPs) by performing message passing on the graph representation of said problems. It is a generic architecture that can be trained unsupervised on any binary CSPs. We introduce an extension for RUN-CSP that additionally performs message passing on the tree decomposition of the input graph. Our goal is to use a tree decomposition that captures the global structure of the graph and allow messages to be passed through the graph in less steps. To this end we experiment with different algorithms for computing tree decompositions. In these experiments we compare our extension with the original architecture. It shows that we were not able to improve the results of RUN-CSP significantly. Neither on instances that were originally used to evaluate RUN-CSP nor on instances that we generated with a small treewidth.
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21/06/2022
11:00 - 11:30
BSc
The Complexity of Counting Small Patterns in Graphs and Relational Structures
Daniel Quirmbach
In der Präsentation wird die Komplexität des Zählens von Mustern auf Graphen und relationalen Strukturen untersucht. Hierzu wird das Konzept der Graphmotivparameter vorgestellt, um eine geschlossene Vorgehensweise für die Komplexitätsabschätzung der Zählprobleme #Hom, #Sub und #IndSub zu erhalten, die entweder die Anzahl an Homomorphismen oder an (induzierten) Teilgraphen eines Musters H zu beziehungsweise auf einem Graphen G zählen sollen. Ausgehend vom Dichotomiecharakters der Komplexität vom Problem #Hom untersuchen wir die Komplexität von Linearkombinationen von Problemen in #Hom. Durch eine Darstellung der Probleme #Sub und #IndSub als Linearkombinationen von Homomorphismenproblemen erhalten wir auch eine Dichotomie für diese Klassen. Wir erweitern die Idee der Graphmotivparameter auf relationale Strukturen und zeigen mithilfe einer Dichotomie des Problems $#Hom$ für relationale Strukturen, dass auch die Probleme #Sub und #IndSub durch ihre Darstellung als Linearkombination von Problemen in #Hom immer entweder in polynomieller Zeit lösbar oder #W[1]-schwer sind. Zudem identifizieren wir anhand der Baumweite ein Dichotomiekriterium, welches uns ermöglicht einzelne Probleminstanzen einer der beiden oben genannter Komplexitätsklassen zuzuordnen.
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23/05/2022
11:00 - 11:45
MSc
Approximate Probabilistic Query Evaluation
Oliver Feith
[master]Probabilistic databases model uncertain data as a probability space
over traditional relational databases. Evaluating queries in probabilistic
databases hence requires computing confidences for the answers,
which is #P-hard even for (some) conjunctive queries. Therefore, new
methods are needed to obtain practical solutions.
We survey the computational complexity of approximately evaluat-
ing queries. In particular, we study the data complexity of queries
with regard to additive and multiplicative approximation. We adapt
algorithms and techniques for proving hardness-of-approximation re-
sults from related fields to show that these approximation paradigms
give rise to a strict hierarchy under common complexity-theoretic
assumptions: While exact evaluation is tractable for only select con-
junctive queries, the class of (unions of) conjunctive queries admits a
multiplicative FPRAS. However, we identify other seemingly simple
queries which resist multiplicatively approximate evaluation entirely.
By contrast, all queries can be evaluated using an additive FPRAS.
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20/05/2022
10:30 - 11:30
ATI
The solidarity cover problemEran RosenbluthVarious real-world problems consist of partitioning a set of locations into disjoint subsets such that each subset covers the whole set with a certain radius. Given a finite set S, a metric d, and a radius r, define a subset S' ⊆ S to be an *r-cover* if and only if ∀s ∈ S ∃s' ∈ S' : d(s, s') ≤ r. We examine the problem of determining whether there exist m disjoint r-covers, naming it the Solidarity Cover Problem (SCP). We consider as well the related optimization problems of maximizing the number of r-covers, referred to as the partition size, and minimizing the radius. We analyze the relation between the SCP and a graph problem known as the Domatic Number Problem (DNP), both hard problems in the general case. We show that the SCP is hard already in the Euclidean 2D setting, implying hardness of the DNP already in the unit disc graph setting. As far as we know, the latter is a result yet to be shown. We use the tight approximation bound of (1 + o(1))ln(n) for the DNP’s general case, shown by U. Feige, M. Halldórsson, G. Kortsarz, and A. Srinivasan (SIAM 15 Journal on computing, 2002), to deduce the same bound for partition-size approximation of the SCP in the Euclidean space setting. We show an upper bound of 3 and lower bounds of 2 and √2 for approximating the minimal radius in different settings of the SCP. Lastly, in the Euclidean 2D setting we provide a bicriteria-approximation of ( 1/16, 2) for the partition size and radius respectively. Joint work with Britta Peis and Laura Vargas Koch.
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13/05/2022
10:30 - 11:30
ATI
Solving AC Power Flow with Graph Neural Networks under Realistic ConstraintsHinrikus WolfWe propose a graph neural network architecture solving the AC power flow problem under realistic constraints. While the energy transition is changing the energy industry to a digitalized and decentralized energy system, the challenges are increasingly shifting to the distribution grid level to integrate new loads and generation technologies. To ensure a save and resilient operation of distribution grids, AC power flow calculations are the means of choice to determine grid operating limits or analyze grid asset utilization in planning procedures. In our approach we demonstrate the development of a framework which makes use of graph neural networks to learn the physical constraints of the power flow. We present our model architecture on which we perform unsupervised training to learn a general solution of the AC power flow formulation that is independent of the specific topologies and supply tasks used for training. Finally, we demonstrate, validate and discuss our results on medium voltage benchmark grids.
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06/05/2022
10:30 - 11:30
ATI
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14/04/2022
13:00 - 13:45
BSc
Integer Factorization Using Graph Neural Networks
Raman Daoud
In this thesis, an efficient algorithm was implemented that encodes integer factorisation instances as CSPs and SAT instances. In addition, experiments were performed to test the performance of GNN-based CSP and SAT solvers for the factorisation problem.
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01/04/2022
10:30 - 11:15
MSc
The Iteration Number of the Weisfeiler-Leman Algorithm
Athena Riazsadri
The Weisfeiler-Leman (WL) algorithm is a simple combinatorial algorithm with widespread applications, most prominently as a subroutine for competitive graph isomorphism solvers. The number of iterations until it reaches termination is crucial for the parallelized running time of the algorithm. For each integer k, there is a k-dimensional version of the algorithm. While Lichter et al. (LICS 2019) provided an upper bound of O(n*log n) on the iteration number of 2-WL on input graphs of order n, there have been no improvements over the trivial upper bound of O(n^k) on the iteration number of the k-dimensional version of the algorithm for k>2 and input graphs of order n. We will present the proof to the currently best known upper bound of O(n*log n) on the iteration number of 2-WL and provide a parameterized upper bound on the iteration number of k-WL for k>2.
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01/04/2022
10:30 - 11:15
MSc
The Iteration Number of the Weisfeiler-Leman Algorithm
Athena Riazsadri
The Weisfeiler-Leman (WL) algorithm is a simple combinatorial algorithm with widespread applications, most prominently as a subroutine for competitive graph isomorphism solvers. The number of iterations until it reaches termination is crucial for the parallelized running time of the algorithm. For each integer k, there is a k-dimensional version of the algorithm. While Lichter et al. (LICS 2019) provided an upper bound of O(n*log n) on the iteration number of 2-WL on input graphs of order n, there have been no improvements over the trivial upper bound of O(n^k) on the iteration number of the k-dimensional version of the algorithm for k>2 and input graphs of order n. We will present the proof to the currently best known upper bound of O(n*log n) on the iteration number of 2-WL and provide a parameterized upper bound on the iteration number of k-WL for k>2.
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31/03/2022
15:00 - 15:30
BSc
Characterising Fragments of First-Order Logic by Counting Homomorphisms
Gian Luca Spitzer
Two graphs G, G' are homomorphism-indistinguishable over a class S of graphs if for each F in S, the number of homomorphisms from F to G equals the number of homomorphisms from F to G'. Results by Dvořák (2010) and Grohe (2020) show that homomorphism-indistinguishability over the class of graphs of tree-width at most k coincides with logical equivalence in the (k+1)-variable fragment of first-order logic with counting, while homomorphism-indistinguishability over the class of graphs of tree-depth at most q coincides with equivalence in the quantifier-rank-q fragment. We introduce the graph parameter of elimination-order and prove that two graphs are equivalent in the k-variable, quantifier-rank-q fragment of counting first-order logic if and only if they are homomorphism-indistinguishable over the class of graphs of elimination-order (k,q).
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31/03/2022
15:45 - 16:30
MSc
Variants of the Weisfeiler-Leman Algorithm
Sebastian Issel
[master]The expressiveness of different variants of the k-dimensional Weisfeiler-Leman algorithm and related concepts is compared. The relation of the classical coloring, the bijective pebble game and counting logics will be generalized to these variants with similar results.The variants are obtained by relaxing the coloring of tuples to sets or multisets ofvertices. This reduces the needed memory to calculate the coloring. Some upper and lower bounds of their expressiveness, compared to the classical version, are shown. As an additional viewpoint, a linear equation system will be defined which turns out to be solvable precisely if the algorithm cannot differentiate the graphs. This system stems from an adaptation of the Sherali-Adams relaxation for integer linear programming.
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31/03/2022
15:00 - 15:30
BSc
Characterising Fragments of First-Order Logic by Counting Homomorphisms
Gian Luca Spitzer
Two graphs G, G' are homomorphism-indistinguishable over a class S of graphs if for each F in S, the number of homomorphisms from F to G equals the number of homomorphisms from F to G'. Results by Dvořák (2010) and Grohe (2020) show that homomorphism-indistinguishability over the class of graphs of tree-width at most k coincides with logical equivalence in the (k+1)-variable fragment of first-order logic with counting, while homomorphism-indistinguishability over the class of graphs of tree-depth at most q coincides with equivalence in the quantifier-rank-q fragment. We introduce the graph parameter of elimination-order and prove that two graphs are equivalent in the k-variable, quantifier-rank-q fragment of counting first-order logic if and only if they are homomorphism-indistinguishable over the class of graphs of elimination-order (k,q).
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31/03/2022
15:45 - 16:30
MSc
Variants of the Weisfeiler-Leman Algorithm
Sebastian Issel
[master]The expressiveness of different variants of the k-dimensional Weisfeiler-Leman algorithm and related concepts is compared. The relation of the classical coloring, the bijective pebble game and counting logics will be generalized to these variants with similar results.The variants are obtained by relaxing the coloring of tuples to sets or multisets ofvertices. This reduces the needed memory to calculate the coloring. Some upper and lower bounds of their expressiveness, compared to the classical version, are shown. As an additional viewpoint, a linear equation system will be defined which turns out to be solvable precisely if the algorithm cannot differentiate the graphs. This system stems from an adaptation of the Sherali-Adams relaxation for integer linear programming.
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25/03/2022
10:30 - 11:15
The Expressiveness of Convolutions and Random Walks in Graph Learning//Fabian Bender
In the field of graphlearning, the well-known Weisfeiler-Leman algorithm imposes a hierarchy that theoreticallybinds the expressive powers of a wide group of modern learning architectures.This establishes impossibility constraints hindering these architectures to useimportant insights into graphs for real-world predictions.
Provably not subject to this hierarchy, the work of [Toenshoff et al., 2021]introduces a new approach called CRAWL, which leverages 1D convolutions andrandom walks to capture the underlying structure of graphs. However, thetheoretical promises raise no guarantee in practical performance. In thisthesis, the abilities of the design to detect cycles and count various smallerstructures called graphlets in graphs are investigated. The expressiveness ofCRAWL and the influence of its hyperparameters is evaluated and compared to standardmessage-passing architectures as well as higherlevel approaches.
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18/03/2022
10:30 - 11:15
BSc
Query Evaluation in Symmetric Probabilistic Databases
Adrian Voß
[bachelor]
In 2011 van den Broeck et al. proposed an algorithm which is able to compute the symmetric weighted model count of a first-order sentence in CNF, which is effectively a probabilistic inference problem. In their subsequent research, van den Broeck et al. showed that their method is guaranteed to solve the problem in polynomial time for sentences with a most 2 logical variables. The algorithm can be applied to arbitrary first-order sentences using a novel Skolemization algorithm, which retains the model count of a first-order sentence. The naturally arising question about sentences with at least 3 variables has been answered negatively by Suciu et al. 2015. In 2014 van den Broeck et al. also claimed that their algorithm is applicable to symmetric probabilistic databases, for which it solves the query evaluation problem in polynomial time. In this thesis we expand on the latter and construct the relation between first-order models and probabilistic databases. We build a cohesive algorithm from the various sources, expand the descriptions from the original papers to detailed proofs and give examples which illustrate the application of the method, such that the algorithm can be used in probabilistic database applications directly.
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11/03/2022
10:30 - 11:15
BSc
The Real Complexity of Query Evaluation in Probabilistic Databases
János Arpasi
[bachelor]Abstract:
Probabilistic databases constitute probability distributions over relational databases. Of great interest for research have been the tuple independent probabilistic databases, where it was proven that for every UCQ that the evaluation problem is either computable in polynomial time or #P hard, but until now this always assumed all occurring probabilities are rational, so the case for arbitrary real numbers was not sorted out yet. We will therefore give an introduction into computable real numbers and functions, review some complexity theory for continuous data and show that the dichotomy holds true also for real numbers.
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11/02/2022
10:30 - 11:30
ATI
Separating Rank Logic from Polynomial TimeMoritz LichterIn the search for a logic capturing polynomial time the most promising candidates are Choiceless Polynomial Time (CPT) and rank logic. Rank logic extends fixed-point logic with counting by a rank operator over prime fields. In this talk I will discuss a recent construction that is a variant of the so called CFI graphs that defines them over Z_{2^i} rather than Z_2. The isomorphism problem of these CFI graphs over Z_{2^i} cannot be defined in rank logic, even if the base graph is totally ordered. However, CPT can define this isomorphism problem. The argument therefore separates rank logic from CPT and in particular from polynomial time. The key idea to argue that rank logic does not define the isomorphism problem of CFI graphs over Z_{2^i} constructs matrices over CFI graphs. These show that certain sequences of other matrices are simultaneously similar. I will also discuss arising challenges and hint at their solutions providing overall overview of the arguments, in particular of the construction of said matrices.
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28/01/2022
10:00 - 11:00
ATI
Blind Extraction of Equitable Partitions From Graph Signals
Michael Scholkemper
Finding equitable partitions is closely related to the extraction of graph symmetries and of interest in a variety of applications such as node role detection, cluster synchronization, consensus dynamics, and network control problems. In this work we study a blind identification problem in which we aim to recover an equitable partition of a network without the knowledge of the network's edges but based solely on the observations of the outputs of an unknown graph filter. Specifically, we consider two settings. First, we consider a scenario in which we can control the input to the graph filter and present a method to extract the partition inspired by the well-known Weisfeiler-Lehman (color refinement) algorithm. Second, we generalize this idea to a setting where we only observe the outputs to random, low-rank excitations of the graph filter, and present a simple spectral algorithm to extract the relevant equitable partitions.