website/static/~brozek/index.html?research%2FClusterAnalysis%2Fnotes%2Flec11-2.html

<!DOCTYPE html>
<html>
<head>
  <meta charset="utf-8" />
  <meta name="author" content="Brandon Rozek">
  <meta name="viewport" content="width=device-width, initial-scale=1.0">
  <meta name="robots" content="noindex" />
    <title>Brandon Rozek</title>
  <link rel="stylesheet" href="themes/bitsandpieces/styles/main.css" type="text/css" />
  <link rel="stylesheet" href="themes/bitsandpieces/styles/highlightjs-github.css" type="text/css" />
</head>
<body>

<aside class="main-nav">
<nav>
  <ul>
          <li class="menuitem ">
        <a href="index.html%3Findex.html" data-shortcut="">
          Home
                  </a>
      </li>
          <li class="menuitem ">
        <a href="index.html%3Fcourses.html" data-shortcut="">
          Courses
                  </a>
      </li>
          <li class="menuitem ">
        <a href="index.html%3Flabaide.html" data-shortcut="">
          Lab Aide
                  </a>
      </li>
          <li class="menuitem ">
        <a href="index.html%3Fpresentations.html" data-shortcut="">
          Presentations
                  </a>
      </li>
          <li class="menuitem ">
        <a href="index.html%3Fresearch.html" data-shortcut="">
          Research
                  </a>
      </li>
          <li class="menuitem ">
        <a href="index.html%3Ftranscript.html" data-shortcut="">
          Transcript
                  </a>
      </li>
      </ul>
</nav>
</aside>
<main class="main-content">
  <article class="article">
    <h1>K-Medoids</h1>
<p>A medoid can be defined as the object of a cluster whose average dissimilarity to all the objects in the cluster is minimal.</p>
<p>The K-medoids algorithm is related to k-means and the medoidshift algorithm. Both the k-means and k-medoids algorithms are partition and both attempt to minimize the distance between points in the cluster to it's center. In contrast to k-means, it chooses data points as centers and uses the Manhattan Norm to define the distance between data points instead of the Euclidean.</p>
<p>This method is known to be more robust to noise and outliers compared to k-means since it minimizes the sum of pairwise dissimilarities instead of the sum of squared Euclidean distances.</p>
<h2>Algorithms</h2>
<p>There are several algorithms that have been created as an optimization to an exhaustive search. In this section, we'll discuss PAM and Voronoi iteration method.</p>
<h3>Partitioning Around Medoids (PAM)</h3>
<ol>
<li>Select $k$ of the $n$ data points as medoids</li>
<li>Associate each data point to the closes medoid</li>
<li>While the cost of the configuration decreases:
<ol>
<li>For each medoid $m$, for each non-medoid data point $o$:
<ol>
<li>Swap $m$ and $o$, recompute the cost (sum of distances of points to their medoid)</li>
<li>If the total cost of the configuration increased in the previous step, undo the swap</li>
</ol></li>
</ol></li>
</ol>
<h3>Voronoi Iteration Method</h3>
<ol>
<li>Select $k$ of the $n$ data points as medoids</li>
<li>While the cost of the configuration decreases
<ol>
<li>In each cluster, make the point that minimizes the sum of distances within the cluster the medoid</li>
<li>Reassign each point to the cluster defined by the closest medoid determined in the previous step.</li>
</ol></li>
</ol>
<h3>Clustering Large Applications (CLARA</h3>
<p>This is a variant of the PAM algorithm that relies on the sampling approach to handle large datasets. The cost of a particular cluster configuration is the mean cost of all the dissimilarities.</p>
<h2>R Implementations</h2>
<p>Both PAM and CLARA are defined in the <code>cluster</code> package in R.</p>
<pre><code class="language-R">clara(x, k, metric = "euclidean", stand = FALSE, samples = 5, 
      sampsize = min(n, 40 + 2 * k), trace = 0, medoids.x = TRUE,
      keep.data = medoids.x, rngR = FALSE)</code></pre>
<pre><code class="language-R">pam(x, k, metric = "euclidean", stand = FALSE)</code></pre>
  </article>
</main>

<script src="themes/bitsandpieces/scripts/highlight.js"></script>
<script src="themes/bitsandpieces/scripts/mousetrap.min.js"></script>
<script type="text/x-mathjax-config">
  MathJax.Hub.Config({
    tex2jax: {
      inlineMath: [ ['$','$'], ["\\(","\\)"] ],
      processEscapes: true
    }
  });
</script>

<script type="text/javascript"
    src="http://cdn.mathjax.org/mathjax/latest/MathJax.js?config=TeX-AMS-MML_HTMLorMML">
</script>
<script>
  hljs.initHighlightingOnLoad();
  
  document.querySelectorAll('.menuitem a').forEach(function(el) {
    if (el.getAttribute('data-shortcut').length > 0) {
      Mousetrap.bind(el.getAttribute('data-shortcut'), function() {
        location.assign(el.getAttribute('href'));
      });       
    }
  });
</script>

</body>
</html>