blog.html

<!DOCTYPE html>
<html id="top" lang="en">
 <head>
  <!-- Required meta tags -->
  <meta charset="utf-8"/>
  <meta content="width=device-width, initial-scale=1.0" name="viewport"/>
  <title>
   Sebastian Mohr - Blog
  </title>
  <meta content="" name="description"/>
  <meta content="" name="keywords"/>
  <!-- Bootstrap CSS -->
  <link href="assets/css/bootstrap/bootstrap.min.css" rel="stylesheet"/>
  <!-- Google Fonts -->
  <link href="https://fonts.googleapis.com/css?family=Open+Sans:300,300i,400,400i,600,600i,700,700i|Raleway:300,300i,400,400i,500,500i,600,600i,700,700i|Poppins:300,300i,400,400i,500,500i,600,600i,700,700i" rel="stylesheet"/>
  <!-- Highlight JS -->
  <link href="https://unpkg.com/@highlightjs/cdn-assets@11.0.0/styles/default.min.css" rel="stylesheet"/>
  <!-- Master CSS -->
  <link href="assets/css/main.css" rel="stylesheet"/>
  <!-- Load mathjax -->
  <script src="https://cdnjs.cloudflare.com/ajax/libs/mathjax/2.7.7/latest.js?config=TeX-MML-AM_CHTML-full,Safe">
  </script>
  <!-- MathJax configuration -->
  <script type="text/x-mathjax-config">
   init_mathjax = function() {
      if (window.MathJax) {
      // MathJax loaded
          MathJax.Hub.Config({
              TeX: {
                  equationNumbers: {
                  autoNumber: "AMS",
                  useLabelIds: true
                  }
              },
              tex2jax: {
                  inlineMath: [ ['$','$'], ["\\(","\\)"] ],
                  displayMath: [ ['$$','$$'], ["\\[","\\]"] ],
                  processEscapes: true,
                  processEnvironments: true
              },
              displayAlign: 'center',
              CommonHTML: {
                  linebreaks: { 
                  automatic: true 
                  }
              },
              "HTML-CSS": {
                  linebreaks: { 
                  automatic: true 
                  }
              }
          });
      
          MathJax.Hub.Queue(["Typeset", MathJax.Hub]);
      }
  }
  init_mathjax();
  </script>
 </head>
 <body>
  <!-- mobile navigator toggle button -->
  <button class="mobile-navigator-toggle d-xl-none" type="button">
   <i class="fas fa-bars">
   </i>
  </button>
  <header id="header">
   <div class="d-flex flex-column">
    <div class="me">
     <img class="img-fluid rounded-circle" src="assets/img/profile.png"/>
     <h1 class="text-light">
      <a href="index.html">
       Sebastian Mohr
      </a>
     </h1>
     <div class="social-links mt-3 text-center">
      <a href="https://github.com/semohr">
       <i class="fa fa-github">
       </i>
      </a>
      <a href="https://orcid.org/0000-0002-4721-0561">
       <i class="fab fa-orcid">
       </i>
      </a>
      <a href="mailto:sebastian@mohrenclan.de">
       <i class="far fa-envelope">
       </i>
      </a>
     </div>
    </div>
    <hr/>
    <nav class="navigator_ext">
     <ul>
      <li>
       <a href="index.html">
        <i class="fa fa-home">
        </i>
        <span>
         Home
        </span>
       </a>
      </li>
      <li>
       <a class="active" href="blog.html">
        <i class="fa fa-book">
        </i>
        <span>
         Blog
        </span>
       </a>
      </li>
     </ul>
    </nav>
    <hr/>
    <nav class="navigator" id="blog_nav">
     <ul>
      <li>
       <a href="#Spectral-graph-embedding">
        <span>
         Spectral graph embedding
        </span>
       </a>
      </li>
      <li class="sub-navigator">
       <a href="#Basics">
        <span>
         Basics
        </span>
       </a>
      </li>
      <li class="sub-navigator">
       <a href="#Main-objective">
        <span>
         Main objective
        </span>
       </a>
      </li>
      <li class="sub-navigator">
       <a href="#Solution">
        <span>
         Solution
        </span>
       </a>
      </li>
      <li class="sub-navigator">
       <a href="#Example">
        <span>
         Example
        </span>
       </a>
      </li>
     </ul>
     <ul>
     </ul>
    </nav>
   </div>
  </header>
  <main id="main">
   <div class="container" id="notebook-container">
    <div class="cell border-box-sizing text_cell rendered">
     <div class="inner_cell">
      <div class="text_cell_render border-box-sizing rendered_html">
       <h1 id="Spectral-graph-embedding">
        Spectral graph embedding
       </h1>
       <p>
        In the following I want to take a short look into how to perform laplacian spectral graph embedding. We will start with the mathematical basics on graphs. If you don't care about the math and just want to see the code you can jump right into the example.
       </p>
       <h2 id="Basics">
        Basics
       </h2>
       <p>
        We want to consider a directed graph $G = (V,E)$ with in total $|V|=N$ vertexes. Edges are defined by an adjacency matrix $A$, with the matrix values $a_{i,j}&gt;0$. In the most simple case the adjacency matrix only contains ones and zeros but you can also weight connections by increasing the corresponding matrix values.
       </p>
       <p>
        A usefull property for graphs is the degree matrix $D$ which contains information about the degree of each node. In our directed graph this corresponds to the incomming connections.
$$
D :=
\begin{cases}
    deg(v_{i}) &amp; \text{if }  i=j\\ 
    0 &amp; \text{else}
\end{cases}
$$
       </p>
       <p>
        Whereby the $deg(v_i)$ is the number of times a edge terminates at vertex $v_i$. In our directed graph that is the number of incomming connections.
       </p>
       <p>
        The Laplacian matrix is defined for directed graphs as
       </p>
       $$
L :=
\begin{cases}
    deg(v_{i}) &amp; \text{if }  i=j\\ 
    -1 &amp; \text{if } i \neq j \text{ and } v_i \text{ is adjacent to } v_j \\
    0 &amp; \text{else}
\end{cases}
$$
       <p>
        In most cases one would use the symmetric normalized Laplacian matrix. It is normalized using the degree matrix.
       </p>
       $$
L_{\text{sym}} = D^{-1/2}LD^{-1/2} = I- D^{-1/2}AD^{-1/2}
$$
       <h2 id="Main-objective">
        Main objective
       </h2>
       <p>
        Given a directed graph we want to compute a low dimensions representation of this graph. Thus we want want to create a set of vectors $ X := \{ x_1,...x_N\} \in \!R^2$ such that the larger the values of the adjacent vectors the smaller the distance $||x_i-x_j||^2$ between the resulting vertices. We consider the two dimensional case, but in theory the method should also work for a higher number of dimensions.
       </p>
       $$
\text{min}_{X \in \!R^2} \sum_{i,j}a_{i,j}||x_i-x_j||^2\\
=\text{min}_{X \in \!R^2} \text{ trace}(XLX^T)
$$
       <p>
        Trivially this is solved by $X=0$ but we are not searching for the singular solution, we avoid this by introducting further constrains to our problem. All solution vectors should be orthorgonal and the set should be normalized:
$$
XX^T = I \\
X\cdot\!1 = 0
$$
       </p>
       <h2 id="Solution">
        Solution
       </h2>
       <p>
        We can solve the above defined problem by the graph visualization spectral algorithm.
       </p>
       <ul>
        <li>
         Compute Laplacian matrix $L$
        </li>
        <li>
         Compute lowest three eigenpairs $(e_1,\lambda_1),(e_2,\lambda_2) ,(e_3,\lambda_3)$ i.e. $Le_k=\lambda_ke_k$
        </li>
        <li>
         Construct the embedding $X$ using the eigenvectors $e_2,e_3$
  $$
  X=\begin{bmatrix}e_2^T \\ e_3^T\end{bmatrix}
  $$
        </li>
       </ul>
       <p>
        I feel like deriving these formulas would be beyond the scope of this short blog entry. If you want to read up on the math I recommend this
        <a href="http://www.cs.yale.edu/homes/spielman/PAPERS/SGTChapter.pdf">
         book
        </a>
        by Daniel Spielman.
       </p>
      </div>
     </div>
    </div>
    <div class="cell border-box-sizing text_cell rendered">
     <div class="inner_cell">
      <div class="text_cell_render border-box-sizing rendered_html">
       <h2 id="Example">
        Example
       </h2>
       <p>
        Next let us code up an example using the proposed algorithm.
       </p>
      </div>
     </div>
    </div>
    <div class="cell border-box-sizing code_cell rendered">
     <div class="input">
      <div class="inner_cell">
       <div class="input_area">
        <div class="highlight hl-ipython3">
         <pre><code class="language-python"># Normally you would create this adjacency matrix from your data
import numpy as np
A = np.zeros((14,14))
for i in range(13):
    A[i,i+1] = 1
    A[i+1,i] = 1
A[13,0] = 1
A[0,13] = 1
print(f"{A=}")
</code></pre>
        </div>
       </div>
      </div>
     </div>
     <div class="output_wrapper">
      <div class="output">
       <div class="output_area">
        <div class="output_subarea output_stream output_stdout output_text">
         <pre><code class="language-python">A=array([[0., 1., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 1.],
       [1., 0., 1., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0.],
       [0., 1., 0., 1., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0.],
       [0., 0., 1., 0., 1., 0., 0., 0., 0., 0., 0., 0., 0., 0.],
       [0., 0., 0., 1., 0., 1., 0., 0., 0., 0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 1., 0., 1., 0., 0., 0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0., 1., 0., 1., 0., 0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0., 0., 1., 0., 1., 0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0., 0., 0., 1., 0., 1., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0., 0., 0., 0., 1., 0., 1., 0., 0., 0.],
       [0., 0., 0., 0., 0., 0., 0., 0., 0., 1., 0., 1., 0., 0.],
       [0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 1., 0., 1., 0.],
       [0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 1., 0., 1.],
       [1., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 1., 0.]])
</code></pre>
        </div>
       </div>
      </div>
     </div>
    </div>
    <div class="cell border-box-sizing code_cell rendered">
     <div class="input">
      <div class="inner_cell">
       <div class="input_area">
        <div class="highlight hl-ipython3">
         <pre><code class="language-python"># Compute the degree
deg = np.sum(A, axis=1)
D = np.diag(deg)
print(f"{D=}")
</code></pre>
        </div>
       </div>
      </div>
     </div>
     <div class="output_wrapper">
      <div class="output">
       <div class="output_area">
        <div class="output_subarea output_stream output_stdout output_text">
         <pre><code class="language-python">D=array([[2., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0.],
       [0., 2., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0.],
       [0., 0., 2., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0.],
       [0., 0., 0., 2., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 2., 0., 0., 0., 0., 0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0., 2., 0., 0., 0., 0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0., 0., 2., 0., 0., 0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0., 0., 0., 2., 0., 0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0., 0., 0., 0., 2., 0., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0., 0., 0., 0., 0., 2., 0., 0., 0., 0.],
       [0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 2., 0., 0., 0.],
       [0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 2., 0., 0.],
       [0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 2., 0.],
       [0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 2.]])
</code></pre>
        </div>
       </div>
      </div>
     </div>
    </div>
    <div class="cell border-box-sizing code_cell rendered">
     <div class="input">
      <div class="inner_cell">
       <div class="input_area">
        <div class="highlight hl-ipython3">
         <pre><code class="language-python"># Compute Laplacian matrix
L = D-A
print(f"L=array({np.round(L,1)})")
</code></pre>
        </div>
       </div>
      </div>
     </div>
     <div class="output_wrapper">
      <div class="output">
       <div class="output_area">
        <div class="output_subarea output_stream output_stdout output_text">
         <pre><code class="language-python">L=array([[ 2. -1.  0.  0.  0.  0.  0.  0.  0.  0.  0.  0.  0. -1.],
       [-1.  2. -1.  0.  0.  0.  0.  0.  0.  0.  0.  0.  0.  0.],
       [ 0. -1.  2. -1.  0.  0.  0.  0.  0.  0.  0.  0.  0.  0.],
       [ 0.  0. -1.  2. -1.  0.  0.  0.  0.  0.  0.  0.  0.  0.],
       [ 0.  0.  0. -1.  2. -1.  0.  0.  0.  0.  0.  0.  0.  0.],
       [ 0.  0.  0.  0. -1.  2. -1.  0.  0.  0.  0.  0.  0.  0.],
       [ 0.  0.  0.  0.  0. -1.  2. -1.  0.  0.  0.  0.  0.  0.],
       [ 0.  0.  0.  0.  0.  0. -1.  2. -1.  0.  0.  0.  0.  0.],
       [ 0.  0.  0.  0.  0.  0.  0. -1.  2. -1.  0.  0.  0.  0.],
       [ 0.  0.  0.  0.  0.  0.  0.  0. -1.  2. -1.  0.  0.  0.],
       [ 0.  0.  0.  0.  0.  0.  0.  0.  0. -1.  2. -1.  0.  0.],
       [ 0.  0.  0.  0.  0.  0.  0.  0.  0.  0. -1.  2. -1.  0.],
       [ 0.  0.  0.  0.  0.  0.  0.  0.  0.  0.  0. -1.  2. -1.],
       [-1.  0.  0.  0.  0.  0.  0.  0.  0.  0.  0.  0. -1.  2.]])
</code></pre>
        </div>
       </div>
      </div>
     </div>
    </div>
    <div class="cell border-box-sizing code_cell rendered">
     <div class="input">
      <div class="inner_cell">
       <div class="input_area">
        <div class="highlight hl-ipython3">
         <pre><code class="language-python"># Compute eigenpairs
eigenvals, eigenvectors = np.linalg.eigh(L)

# sort by eigenvalues
i = eigenvals.argsort()[::-1]
eigenvals = eigenvals[i]
eigenvectors = eigenvectors[i]
</code></pre>
        </div>
       </div>
      </div>
     </div>
    </div>
    <div class="cell border-box-sizing code_cell rendered">
     <div class="input">
      <div class="inner_cell">
       <div class="input_area">
        <div class="highlight hl-ipython3">
         <pre><code class="language-python"># Plotting
import matplotlib.pyplot as plt

def plot(x,y,A):
    # Remove axis and set figuresize
    plt.subplots(figsize=(10, 10))
    plt.axis('off')
    
    # Plot edges
    for i, b in enumerate(A):
        for j, a in enumerate(b):
            if a &gt; 0:
                x_s = [x[i],x[j]]
                y_s = [y[i],y[j]]
                plt.plot(x_s,y_s,color="tab:gray")
                
    # Plot points
    plt.scatter(x,y,marker="o",s=150,zorder=10,color="tab:green")
                    
# Plot the coordinates for each point        
plot(eigenvectors[:,1],eigenvectors[:,2],A)
</code></pre>
        </div>
       </div>
      </div>
     </div>
     <div class="output_wrapper">
      <div class="output">
       <div class="output_area">
        <div class="output_png output_subarea">
         <img src="data:image/png;base64,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
"/>
        </div>
       </div>
      </div>
     </div>
    </div>
   </div>
  </main>
  <footer id="footer">
   <div class="container">
    <div>
     © Sebastian Mohr
    </div>
    <p>
     Blog last updated 19. Jul 2021
    </p>
   </div>
  </footer>
  <a class="to-top" href="#top">
   <i class="fas fa-chevron-up">
   </i>
  </a>
  <!-- Bootstrap JS -->
  <script src="assets/js/bootstrap/bootstrap.bundle.min.js">
  </script>
  <!-- Font Awesome -->
  <script crossorigin="anonymous" src="https://kit.fontawesome.com/1d156e89e1.js">
  </script>
  <!-- Highlight JS -->
  <script src="https://unpkg.com/@highlightjs/cdn-assets@11.0.0/highlight.min.js">
  </script>
  <script src="https://unpkg.com/highlightjs-badge/highlightjs/highlight.pack.js">
  </script>
  <!-- Highlight-Badge JS -->
  <script src="https://unpkg.com/highlightjs-badge/highlightjs-badge.min.js">
  </script>
  <script>
   setTimeout(function () {
      var pres = document.querySelectorAll(".highlight>pre>code");
      for (var i = 0; i < pres.length; i++) {
          hljs.highlightBlock(pres[i]);
      }
      var options = {
          contentSelector: ".highlight",
          // Delay in ms used for `setTimeout` before badging is applied
          // Use if you need to time highlighting and badge application
          // since the badges need to be applied afterwards.
          // 0 - direct execution (ie. you handle timing
          loadDelay:0,

          // CSS class(es) used to render the copy icon.
          copyIconClass: "fa fa-copy",
          // CSS class(es) used to render the done icon.
          checkIconClass: "fa fa-check text-success",
        
          // hook to allow modifying the text before it's pasted
          onBeforeTextCopied: function(text, codeElement) {
            console.log(text)
            return text;   //  you can fix up the text here
          }
      };
      window.highlightJsBadge(options);
  },10);
  </script>
  <!-- Master JS -->
  <script src="assets/js/main.js">
  </script>
  <script type="text/javascript">
   var $sections = document.querySelectorAll('h1, h2')

    //$sections = Array.prototype.slice.call($sections);
    var ids_ex = ["Spectral-graph-embedding","Example","Basics","Main-objective","Solution"];
    // map each section id to their corresponding navigation link
    var sectionIdTonavigationLink = {};
    for (var i = $sections.length-1; i >= 0; i--) {
      var id = $sections[i].id;
      if (id != ""){
        sectionIdTonavigationLink[id] = document.querySelectorAll('nav > ul > li > a[href=\\#' + id + ']') || null;
      }
    }
  </script>
 </body>
</html>