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+<html>
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+    <meta name="Author" content="C. L. Davis">
+    <title>Magnetism - Mutual Induction - Physics 299</title>
+    <meta content="C. L. Davis" name="author">
+  </head>
+  <body style="color: rgb(0, 0, 0); background-color: rgb(255, 255,
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+    <center>
+      <h1> <img src="ULPhys1.gif" height="50" width="189"
+          align="texttop"></h1>
+    </center>
+    <center>
+      <h1>Mutual Induction<br>
+      </h1>
+    </center>
+    <center><img src="celticbar.gif" height="22" width="576"><br>
+      <br>
+      <font color="#ff0000"><i>
+          <meta http-equiv="content-type" content="text/html;
+            charset=windows-1252">
+        </i></font><font color="#ff0000"><i>
+          <meta http-equiv="content-type" content="text/html;
+            charset=windows-1252">
+        </i></font>
+      <div class="copy-paste-block"><font color="#ff0000"><i><span
+              class="bqQuoteLink">"A</span></i></font><font
+          color="#ff0000"><i><span class="bqQuoteLink"> fact is a simple
+              statement that everyone believes.&nbsp; It is innocent,
+              unless found guilty.&nbsp; A hypothesis is a novel
+              suggestion that no one wants to believe.&nbsp; It is
+              guilty, until found effective</span></i><span></span>"</font><br>
+      </div>
+      <font color="#ff0000"><i> </i><font color="#000000">Edward Teller</font></font><br>
+    </center>
+    <img src="netbar.gif" height="40" width="100%" align="middle">
+    <blockquote> </blockquote>
+    <ul>
+      <li> As we have seen, Faraday's Law of Induction tells us that a
+        changing magnetic flux through a circuit will induce an emf and
+        therefore an "induced current".&nbsp; Consider the situation of
+        two nearby circuits (below) where the flux through circuit 2
+        changes due to the changing current in circuit 1.</li>
+    </ul>
+    <div align="center"><img alt="magmutualindfig1"
+        src="mag_mutualind_fig1.jpg" height="261" width="411"><br>
+      <div align="left">
+        <ul>
+          <li>With N<sub>2</sub> turns in circuit 2 the emf is given by</li>
+        </ul>
+        <div align="center"><img alt="magmutualindeqn1"
+            src="mag_mutualind_eqn1.jpg" height="60" width="122"><br>
+          <blockquote>
+            <div align="left">but the total flux through circuit 2 is
+              proportional to the current in circuit 1, where the
+              proportionality constant is called the mutual inductance
+              of the coils, M<sub>21</sub>,<br>
+              <br>
+              <div align="center"><img alt="magmutualindeqn2"
+                  src="mag_mutualind_eqn2.jpg" height="38" width="162"><br>
+                <div align="left">Combining these two equations gives<br>
+                  <br>
+                </div>
+              </div>
+              <div align="center"><img alt="magmutualindeqn3"
+                  src="mag_mutualind_eqn3.jpg" height="81" width="159"><br>
+                <div align="left">In other words the emf in circuit 2 is
+                  proportional to the rate of change of current in
+                  circuit 1.&nbsp; As we will see shortly, the mutual
+                  inductance M<sub>21</sub> depends only on the
+                  geometric configuration of the two circuits.<br>
+                </div>
+              </div>
+            </div>
+          </blockquote>
+          <div align="left">
+            <div align="center">
+              <div align="left">
+                <ul>
+                  <li>If the roles of the two circuits are reversed -
+                    that is a changing current in circuit 2 induces a
+                    current in circuit 1 - then</li>
+                </ul>
+                <div align="center"><img alt="magmutualindeqn4"
+                    src="mag_mutualind_eqn4.jpg" height="81" width="423"><br>
+                  <div align="left">
+                    <ul>
+                      <li>It is "easy" to show that&nbsp; M<sub>21</sub>
+                        = M<sub>12</sub> .&nbsp; In other words given
+                        two circuits in a particular configuration it
+                        doesn't matter in which circuit the current is
+                        induced the mutual inductance is the same.</li>
+                    </ul>
+                    <ul>
+                      <li><b>UNITS: </b>Inductance is measured in
+                        Henrys <img alt="Henry" src="Henry.jpg"
+                          height="135" width="105" align="middle"><br>
+                      </li>
+                    </ul>
+                    <div align="center"><img alt="magmutualindeqn5"
+                        src="mag_mutualind_eqn5.jpg" height="39"
+                        width="308"><br>
+                      <blockquote>
+                        <div align="left"><img alt="exclamation"
+                            src="exclamation-icon.gif" height="30"
+                            width="31"> The concept of inductance is
+                          related to the magnetic field in a similar way
+                          that capacitance is related to the electric
+                          field.<br>
+                        </div>
+                      </blockquote>
+                      <div align="left">
+                        <ul>
+                          <li>In order to calculate mutual inductance
+                            you will typically follow the steps below:</li>
+                        </ul>
+                        <blockquote>
+                          <ol>
+                            <li>Determine <b>B</b> due to one circuit
+                              at the location of the other using
+                              Ampere's Law or the Biot-Savart Law.</li>
+                            <li>Using this <b>B</b> calculate the
+                              magnetic flux through the 'other' circuit.</li>
+                            <li>Then use the equation N<sub>2</sub>&#934;<sub>2</sub>
+                              = MI<sub>1</sub> to obtain M.</li>
+                          </ol>
+                          You will always find that <i><b>M depends
+                              only on the geometric parameters of the
+                              two circuits and the number of turns in
+                              each circuit.</b></i><br>
+                          <ol>
+                          </ol>
+                        </blockquote>
+                      </div>
+                    </div>
+                  </div>
+                </div>
+              </div>
+            </div>
+          </div>
+        </div>
+      </div>
+    </div>
+    <blockquote>
+      <div align="left"> </div>
+    </blockquote>
+    <div align="center">
+      <div align="left">
+        <div align="center">
+          <div align="left">
+            <div align="center">
+              <div align="left">
+                <div align="center">
+                  <div align="left">
+                    <div align="center">
+                      <div align="center">
+                        <div>
+                          <div align="left">
+                            <div align="center">
+                              <div align="left"> </div>
+                            </div>
+                          </div>
+                        </div>
+                      </div>
+                    </div>
+                  </div>
+                </div>
+              </div>
+            </div>
+          </div>
+          <blockquote>
+            <div align="left"> </div>
+          </blockquote>
+        </div>
+      </div>
+      <blockquote> </blockquote>
+    </div>
+    <div align="center"><img src="netbar.gif" height="40" width="100%"></div>
+    <div align="center">
+      <div align="center"> </div>
+      <center>
+        <p style="color: rgb(255, 0, 0); font-style: italic;"
+          class="MsoNormal">
+          <meta http-equiv="content-type" content="text/html;
+            charset=windows-1252">
+        </p>
+        <font color="#ff0000"><i>This girl said she recognized me from
+            the vegetarian club, but I'd never met herbivore. </i></font><br>
+        <br>
+        &nbsp;<img src="celticbar.gif" height="22" width="576"> <br>
+        &nbsp;
+        <p><i>Dr. C. L. Davis</i> <br>
+          <i>Physics Department</i> <br>
+          <i>University of Louisville</i> <br>
+          <i>email</i>: <a href="mailto:c.l.davis@louisville.edu">c.l.davis@louisville.edu</a>
+          <br>
+          &nbsp; </p>
+        <p><img src="header-index.gif" height="51" width="92"> </p>
+      </center>
+      <p><br>
+      </p>
+      <blockquote> </blockquote>
+    </div>
+  </body>
+</html>