Open AccessPosted Content
Ubiquity of synonymity: almost all large binary trees are not uniquely identified by their spectra or their immanantal polynomials
Reads0
Chats0
TLDR
The results show that a generic large binary tree is highly unlikely to be identified uniquely by common spectral invariants.Abstract:
There are several common ways to encode a tree as a matrix, such as the adjacency matrix, the Laplacian matrix (that is, the infinitesimal generator of the natural random walk), and the matrix of pairwise distances between leaves. Such representations involve a specific labeling of the vertices or at least the leaves, and so it is natural to attempt to identify trees by some feature of the associated matrices that is invariant under relabeling. An obvious candidate is the spectrum of eigenvalues (or, equivalently, the characteristic polynomial). We show for any of these choices of matrix that the fraction of binary trees with a unique spectrum goes to zero as the number of leaves goes to infinity. We investigate the rate of convergence of the above fraction to zero using numerical methods. For the adjacency and Laplacian matrices, we show that that the {\em a priori} more informative immanantal polynomials have no greater power to distinguish between trees.read more
Citations
More filters
Journal ArticleDOI
Characterizing and comparing phylogenies from their Laplacian spectrum
Eric Lewitus,Hélène Morlon +1 more
TL;DR: This work shows how to construct the spectral density profile of a phylogenetic tree from its Laplacian graph and demonstrates how the eigengap can identify modes of division within a given tree.
Journal ArticleDOI
A Geometric Approach to Tree Shape Statistics
TL;DR: In this paper, a new way to quantify the descriptive ability of tree shape statistics is presented, which is termed the geometric approach to differentiate it from the model-based approach previously explored.
Journal ArticleDOI
Spectra of Large Random Trees
TL;DR: In this article, the eigenvalues of the adjacency matrices of a wide variety of random trees were analyzed and it was shown that the empirical spectral distributions for many random tree models converge to a deterministic (model-dependent) limit as the number of vertices goes to infinity.
Posted ContentDOI
Network science inspires novel tree shape statistics
TL;DR: Leonardini et al. as discussed by the authors proposed tree shape summaries that are complementary to both asymmetry and the frequencies of small configurations, which can be computed in linear time and scale well to describe the shapes of large trees.
Posted ContentDOI
Polynomial Phylogenetic Analysis of Tree Shapes
TL;DR: This paper uses tree-defining polynomials to compare tree shapes randomly generated by simulations and tree shapes reconstructed from data and shows that the comparisons can be used to estimate parameters and to select the best-fit model that generates specific tree shapes.
References
More filters
Book
Spectral Graph Theory
TL;DR: Eigenvalues and the Laplacian of a graph Isoperimetric problems Diameters and eigenvalues Paths, flows, and routing Eigen values and quasi-randomness
MonographDOI
The representation theory of the symmetric group
Gordon James,Adalbert Kerber +1 more
TL;DR: In this paper, the authors propose a representation theory of symmetric groups and their young subgroups, which is based on the notion of irreducible matrix representations of groups.
BookDOI
Spectra of graphs
TL;DR: This book gives an elementary treatment of the basic material about graph Spectra, both for ordinary, and Laplace and Seidel spectra, by covering standard topics before presenting some new material on trees, strongly regular graphs, two-graphs, association schemes, p-ranks of configurations and similar topics.
Book
Spectra of graphs : theory and application
TL;DR: The Spectrum and the Group of Automorphisms as discussed by the authors have been used extensively in Graph Spectra Techniques in Graph Theory and Combinatory Applications in Chemistry an Physics. But they have not yet been applied to Graph Spectral Biblgraphy.