Matching-Capacitance-Calculation on KnightLi Blog https://knightli.com/en/tags/matching-capacitance-calculation/ Recent content in Matching-Capacitance-Calculation on KnightLi Blog Hugo -- gohugo.io en Fri, 29 Nov 2024 00:00:00 +0000 Crystal Oscillator Capacitance Basics (Matching Capacitance, Load Capacitance, and Parasitic Capacitance) https://knightli.com/en/2024/11/29/crystal-load-capacitance-calculation/ Fri, 29 Nov 2024 00:00:00 +0000 https://knightli.com/en/2024/11/29/crystal-load-capacitance-calculation/ <h2 id="typical-crystal-oscillator-circuit">Typical Crystal Oscillator Circuit </h2><p>A typical crystal oscillator uses two external capacitors with equal values (<code>C1</code>, <code>C2</code>). They are often called matching capacitors (or load capacitors in common usage).</p> <p><img src="https://knightli.com/2024/11/29/%E6%99%B6%E6%8C%AF-%E5%8C%B9%E9%85%8D%E7%94%B5%E5%AE%B9-%E8%B4%9F%E8%BD%BD%E7%94%B5%E5%AE%B9-%E5%A4%96%E6%8E%A5%E7%94%B5%E5%AE%B9/x.png" width="1426" height="889" srcset="https://knightli.com/2024/11/29/%E6%99%B6%E6%8C%AF-%E5%8C%B9%E9%85%8D%E7%94%B5%E5%AE%B9-%E8%B4%9F%E8%BD%BD%E7%94%B5%E5%AE%B9-%E5%A4%96%E6%8E%A5%E7%94%B5%E5%AE%B9/x_hu_eb078a5544216e2a.png 480w, https://knightli.com/2024/11/29/%E6%99%B6%E6%8C%AF-%E5%8C%B9%E9%85%8D%E7%94%B5%E5%AE%B9-%E8%B4%9F%E8%BD%BD%E7%94%B5%E5%AE%B9-%E5%A4%96%E6%8E%A5%E7%94%B5%E5%AE%B9/x_hu_f1cb6b8d3b9fe8b1.png 1024w" loading="lazy" alt="Typical Crystal Oscillator Circuit" class="gallery-image" data-flex-grow="160" data-flex-basis="384px" ></p> <p>Datasheets usually specify a required load capacitance <code>CL</code> (Load Capacitance), which is the effective capacitance seen by the crystal.</p> <p>If load capacitance is too large, oscillation frequency tends to shift lower. If too small, frequency tends to shift higher.</p> <h2 id="parasitic-capacitance-and-calculation">Parasitic Capacitance and Calculation </h2><p>Goal: choose matching capacitors (<code>C1</code>, <code>C2</code>) so the crystal sees its required <code>CL</code>.</p> <p>Formula:</p> <p><code>${C_L}={C_S}+\frac{C_D \times C_G}{C_D + C_G}$</code></p> <p>Where:</p> <ul> <li><code>CS</code>: shunt/parasitic capacitance (often around 1 pF in rough estimation)</li> <li><code>CD</code>: total capacitance at one crystal pin</li> <li><code>CG</code>: total capacitance at the other crystal pin</li> </ul> <p>Common expansion:</p> <ul> <li><code>${C_D} = C_{PCB} + C_O + C_2</code></li> <li><code>${C_G} = C_{PCB} + C_I + C_1</code></li> </ul> <p><code>CPCB</code> is PCB stray capacitance, <code>CI/CO</code> are MCU internal pin capacitances.</p> <h3 id="example">Example </h3><p>Given:</p> <ul> <li><code>${C_S}=1pF</code></li> <li><code>${C_I}={C_O}=5pF</code></li> <li><code>${C_{PCB}}=4pF</code></li> <li><code>${C_1=C_2}</code></li> <li>crystal requires <code>${C_L}=10pF</code></li> </ul> <p>Then solve to get approximately:</p> <ul> <li><code>${C_D=C_G=18pF}</code></li> <li><code>${C_1=C_2=9pF}</code></li> </ul> <p>Under symmetric assumptions (<code>CI=CO</code>, <code>CD=CG</code>, <code>C1=C2</code>), a simplified form can be used.</p> <p><img src="https://knightli.com/2024/11/29/%E6%99%B6%E6%8C%AF-%E5%8C%B9%E9%85%8D%E7%94%B5%E5%AE%B9-%E8%B4%9F%E8%BD%BD%E7%94%B5%E5%AE%B9-%E5%A4%96%E6%8E%A5%E7%94%B5%E5%AE%B9/o.png" width="1142" height="395" srcset="https://knightli.com/2024/11/29/%E6%99%B6%E6%8C%AF-%E5%8C%B9%E9%85%8D%E7%94%B5%E5%AE%B9-%E8%B4%9F%E8%BD%BD%E7%94%B5%E5%AE%B9-%E5%A4%96%E6%8E%A5%E7%94%B5%E5%AE%B9/o_hu_53b6e53a6ba0087c.png 480w, https://knightli.com/2024/11/29/%E6%99%B6%E6%8C%AF-%E5%8C%B9%E9%85%8D%E7%94%B5%E5%AE%B9-%E8%B4%9F%E8%BD%BD%E7%94%B5%E5%AE%B9-%E5%A4%96%E6%8E%A5%E7%94%B5%E5%AE%B9/o_hu_f3ae74580b1e888a.png 1024w" loading="lazy" class="gallery-image" data-flex-grow="289" data-flex-basis="693px" ></p>