Difference between revisions of "Graph Laplacian"

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Graph Laplacian, (aka Laplace Matrix, Admittance Matrix, Kirchhoff Matrix, Discrete Laplacian, Laplace-Beltrami operator), is simply a '''matrix representation of a graph.'''
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{{Nutshell|1=Laplacian = Degree Matrix - Adjacency Matrix|title=Graph Laplacian}}
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Graph Laplacian, (aka '''Laplace''' Matrix, '''Admittance''' Matrix, '''Kirchhoff''' Matrix, '''Discrete''' '''Laplacian''', '''Laplace'''-'''Beltrami''' operator), is simply a '''matrix representation of a graph.'''
  
 
Laplacian Matrix can be computed as:
 
Laplacian Matrix can be computed as:
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==Diagonalization of Laplacian==
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*The Laplacian of an undirected graph is symmetric as well as '''[[Matrix Properties|unitary]].'''
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*Using [[Eigenvalues and Eigenvectors|diagonalization]]: <math>L = U \Lambda U^{-1}</math> (where <math>U</math> is a set of eigenvectors and <math>\Lambda</math> is a diagonal matrix containing eigenvalues)
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*Then <math>U^T = U^{-1}</math> OR <math>UU^T = I</math>
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==Normalized Laplacian==
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<math>L_n = D^{-\frac{1}{2}}LD^{-\frac{1}{2}}</math>
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==Random-walk Laplacian==
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<math>L_{rw} = D^{-1}L</math>
  
 
==Keywords==
 
==Keywords==
 
Laplacian Matrix, GNN, Laplace Matrix, Degree Matrix
 
Laplacian Matrix, GNN, Laplace Matrix, Degree Matrix
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{{Box Note|boxtype=warning|Note text=For dynamical systems we consider <math> \lambda_1 </math> largest, but for Laplacian Matrix <math> \lambda_1 </math> is the smallest.}}

Latest revision as of 16:46, 17 June 2021


Graph Laplacian, (aka Laplace Matrix, Admittance Matrix, Kirchhoff Matrix, Discrete Laplacian, Laplace-Beltrami operator), is simply a matrix representation of a graph.

Laplacian Matrix can be computed as:

Where is Laplacian Matrix, is Degree Matrix and is Adjacency matrix.

Labelled graph Degree matrix Adjacency matrix Laplacian matrix
graph_example_small.PNG

Diagonalization of Laplacian

  • The Laplacian of an undirected graph is symmetric as well as unitary.
  • Using diagonalization: (where is a set of eigenvectors and is a diagonal matrix containing eigenvalues)
  • Then OR

Normalized Laplacian

Random-walk Laplacian

Keywords

Laplacian Matrix, GNN, Laplace Matrix, Degree Matrix

Warning: For dynamical systems we consider largest, but for Laplacian Matrix is the smallest.