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      <h1 class="post-title">Comparison and classification of high-precision actuators based on stiffness influencing vibration isolation</h1>
    </header>

    <div class="post-toc" id="post-toc">
  <h2 class="post-toc-title">Contents</h2>
  <div class="post-toc-content">
    <nav id="TableOfContents">
  <ul>
    <li><a href="#classification-of-high-precision-actuators">Classification of high-precision actuators</a></li>
    <li><a href="#time-delay-of-piezoelectric-electronics">Time Delay of Piezoelectric Electronics</a></li>
    <li><a href="#definition-of-low-stiffness-and-high-stiffness-actuator">Definition of low-stiffness and high-stiffness actuator</a></li>
    <li><a href="#low-stiffness-high-stiffness-characteristics">Low-Stiffness / High-Stiffness characteristics</a></li>
    <li><a href="#controller-design">Controller Design</a></li>
    <li><a href="#discussion">Discussion</a></li>
  </ul>

  <ul>
    <li><a href="#backlinks">Backlinks</a></li>
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    <div class="post-content">
      <dl>
<dt>Tags</dt>
<dd><a href="/zettels/vibration_isolation/">Vibration Isolation</a>, <a href="/zettels/actuators/">Actuators</a></dd>
<dt>Reference</dt>
<dd><sup id="aad53368e29e8a519e2f63857044fa46"><a href="#ito16_compar_class_high_precis_actuat" title="Shingo Ito \&amp; Georg Schitter, Comparison and Classification of High-Precision Actuators  Based on Stiffness Influencing Vibration Isolation, {IEEE/ASME Transactions on Mechatronics}, v(2), 1169-1178 (2016).">(Shingo Ito &amp; Georg Schitter, 2016)</a></sup></dd>
<dt>Author(s)</dt>
<dd>Ito, S., &amp; Schitter, G.</dd>
<dt>Year</dt>
<dd>2016</dd>
</dl>
<h2 id="classification-of-high-precision-actuators">Classification of high-precision actuators</h2>
<div class="table-caption">
  <span class="table-number">Table 1</span>:
  Zero/Low and High stiffness actuators
</div>
<table>
<thead>
<tr>
<th><strong>Categories</strong></th>
<th><strong>Pros</strong></th>
<th><strong>Cons</strong></th>
</tr>
</thead>
<tbody>
<tr>
<td>Zero stiffness</td>
<td>No vibration transmission</td>
<td>Large and Heavy</td>
</tr>
<tr>
<td>Low stiffness</td>
<td>High vibration isolation</td>
<td>Typically for low load</td>
</tr>
<tr>
<td>High Stiffness</td>
<td>High control bandwidth</td>
<td>High vibration transmission</td>
</tr>
</tbody>
</table>
<h2 id="time-delay-of-piezoelectric-electronics">Time Delay of Piezoelectric Electronics</h2>
<p>In this paper, the piezoelectric actuator/electronics adds a time delay which is much higher than the time delay added by the voice coil/electronics.</p>
<h2 id="definition-of-low-stiffness-and-high-stiffness-actuator">Definition of low-stiffness and high-stiffness actuator</h2>
<ul>
<li><strong>Low Stiffness</strong> actuator is defined as the ones where the transmissibility stays below 0dB at all frequency</li>
<li><strong>High Stiffness</strong> actuator is defined as the ones where the transmissibility goes above 0dB at some frequency</li>
</ul>
<p><a id="org6e18c94"></a></p>
<figure>
    <img src="/ox-hugo/ito16_low_high_stiffness_actuators.png"
         alt="Figure 1: Definition of low-stiffness and high-stiffness actuator"/> <figcaption>
            <p>Figure 1: Definition of low-stiffness and high-stiffness actuator</p>
        </figcaption>
</figure>

<h2 id="low-stiffness-high-stiffness-characteristics">Low-Stiffness / High-Stiffness characteristics</h2>
<ul>
<li>The low stiffness actuators achieve smooth transition from active isolation to passive isolation.</li>
<li>The high stiffness actuators can have a gap between the passive and active isolation vibration where the vibrations are amplified in a certain frequency band.</li>
</ul>
<h2 id="controller-design">Controller Design</h2>
<p><a id="orgc911fbe"></a></p>
<figure>
    <img src="/ox-hugo/ito16_transmissibility.png"
         alt="Figure 2: Obtained transmissibility"/> <figcaption>
            <p>Figure 2: Obtained transmissibility</p>
        </figcaption>
</figure>

<h2 id="discussion">Discussion</h2>
<p>The stiffness requirement for low-stiffness actuators can be rephrased in the frequency domain as: &ldquo;the cross-over frequency of the sensitivity function of the feedback system must be larger than \(\sqrt{2} \omega_r\) with \(\omega_r\) is the resonant frequency of the uncontrolled system&rdquo;.</p>
<p>In practice, this is difficult to achieve with piezoelectric actuators as their first resonant frequency \(\omega_r\) is <strong>too close to other resonant frequencies to ensure close-loop stability</strong>.
In contrast, the frequency band between the first and the other resonances of Lorentz actuators can be broad by design making them more suitable to construct a low-stiffness actuators.</p>
<h1 id="bibliography">Bibliography</h1>
<p><a id="ito16_compar_class_high_precis_actuat"></a>Ito, S., &amp; Schitter, G., <em>Comparison and classification of high-precision actuators based on stiffness influencing vibration isolation</em>, IEEE/ASME Transactions on Mechatronics, <em>21(2)</em>, 1169–1178 (2016).  <a href="http://dx.doi.org/10.1109/tmech.2015.2478658">http://dx.doi.org/10.1109/tmech.2015.2478658</a> <a href="#aad53368e29e8a519e2f63857044fa46">↩</a></p>
<h2 id="backlinks">Backlinks</h2>
<ul>
<li><a href="/zettels/actuators/">Actuators</a></li>
</ul>

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