Florian Frantzen scite author profile

We systematically evaluate the (in-)stability of state-of-the-art node embedding algorithms due to randomness, i.e., the random variation of their outcomes given identical algorithms and graphs. We apply five node embeddings algorithms-HOPE, LINE, node2vec, SDNE, and GraphSAGE-to synthetic and empirical graphs and assess their stability under randomness with respect to (i) the geometry of embedding spaces as well as (ii) their performance in downstream tasks. We find significant instabilities in the geometry of embedding spaces independent of the centrality of a node. In the evaluation of downstream tasks, we find that the accuracy of node classification seems to be unaffected by random seeding while the actual classification of nodes can vary significantly. This suggests that instability effects need to be taken into account when working with node embeddings. Our work is relevant for researchers and engineers interested in the effectiveness, reliability, and reproducibility of node embedding approaches.

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Signal processing on simplicial complexes

Seby¹,

Frantzen²,

Roddenberry³

et al. 2021

Preprint

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Higher-order networks have so far been considered primarily in the context of studying the structure of complex systems, i.e., the higher-order or multi-way relations connecting the constituent entities. More recently, a number of studies have considered dynamical processes that explicitly account for such higher-order dependencies, e.g., in the context of epidemic spreading processes or opinion formation. In this chapter, we focus on a closely related, but distinct third perspective: how can we use higher-order relationships to process signals and data supported on higher-order network structures. In particular, we survey how ideas from signal processing of data supported on regular domains, such as time series or images, can be extended to graphs and simplicial complexes. We discuss Fourier analysis, signal denoising, signal interpolation, and nonlinear processing through neural networks based on simplicial complexes. Key to our developments is the Hodge Laplacian matrix, a multi-relational operator that leverages the special structure of simplicial complexes and generalizes desirable properties of the Laplacian matrix in graph signal processing.This chapter is built on the exposition of [46], in particular with respect to the example applications considered. Our discussion here is however more geared towards a reader with a network science background who is less familiar with signal processing. In particular, we provide additional discussion on the relations between filtering and linear dynamical processes on networks.

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Florian Frantzen

Hodgelets: Localized Spectral Representations of Flows On Simplicial Complexes

Signal Processing on Simplicial Complexes

The Effects of Randomness on the Stability of Node Embeddings

The Effects of Randomness on the Stability of Node Embeddings

Signal processing on simplicial complexes

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