Tapio Heimo scite author profile

We address the problem of multiresolution module detection in dense weighted networks, where the modular structure is encoded in the weights rather than topology. We discuss a weighted version of the q-state Potts method, which was originally introduced by Reichardt and Bornholdt. This weighted method can be directly applied to dense networks. We discuss the dependence of the resolution of the method on its tuning parameter and network properties, using sparse and dense weighted networks with built-in modules as example cases. Finally, we apply the method to stock price correlation data, and show that the resulting modules correspond well to known structural properties of this correlation network.

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Maximal spanning trees, asset graphs and random matrix denoising in the analysis of dynamics of financial networks

Heimo

Kaski²,

Saramäki³

2009

Physica A: Statistical Mechanics and its Applications

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Spectral and network methods in the analysis of correlation matrices of stock returns

Heimo¹,

Saramäki²,

Onnela

et al. 2007

Physica A: Statistical Mechanics and its Applications

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Spectral methods and cluster structure in correlation-based networks

Heimo¹,

Tibély

Saramäki³

et al. 2008

Physica A: Statistical Mechanics and its Applications

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We investigate how in complex systems the eigenpairs of the matrices derived from the correlations of multichannel observations reflect the cluster structure of the underlying networks. For this we use daily return data from the NYSE and focus specifically on the spectral properties of weight W_{ij} = |C|_{ij} - \delta_{ij} and diffusion matrices D_{ij} = W_{ij}/s_j- \delta_{ij}, where C_{ij} is the correlation matrix and s_i = \sum_j W_{ij} the strength of node j. The eigenvalues (and corresponding eigenvectors) of the weight matrix are ranked in descending order. In accord with the earlier observations the first eigenvector stands for a measure of the market correlations. Its components are to first approximation equal to the strengths of the nodes and there is a second order, roughly linear, correction. The high ranking eigenvectors, excluding the highest ranking one, are usually assigned to market sectors and industrial branches. Our study shows that both for weight and diffusion matrices the eigenpair analysis is not capable of easily deducing the cluster structure of the network without a priori knowledge. In addition we have studied the clustering of stocks using the asset graph approach with and without spectrum based noise filtering. It turns out that asset graphs are quite insensitive to noise and there is no sharp percolation transition as a function of the ratio of bonds included, thus no natural threshold value for that ratio seems to exist. We suggest that these observations can be of use for other correlation based networks as well.Comment: 26 pages, 14 figure

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Tapio Heimo

Detecting modules in dense weighted networks with the Potts method

Maximal spanning trees, asset graphs and random matrix denoising in the analysis of dynamics of financial networks

Spectral and network methods in the analysis of correlation matrices of stock returns

Spectral methods and cluster structure in correlation-based networks

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