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this book can help you to get a better performance in the gps development

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<p></p><table border="0" cellspacing="0" cellpadding="0" width="100%"><tr><td align="right"><font face="Times New Roman, Times, Serif" size="2" color="#FF0000">Page 44</font></td></tr></table><table border="0" cellspacing="0" cellpadding="0"><tr><td rowspan="5"></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">velocity of the point relative to the <i>b</i> frame due to the relative rotation of the <i>a</i> frame. The last term is the transformation of the instantaneous <i>a</i>-frame relative velocity into <i>b</i>-frame coordinates.</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">Equations (2.55) can be considered as a special case of the following theorem.</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">Theorem of Coriolis If two frames of reference experience relative angular rotation <img src="b1c16ddb355385f627cc1e74f75c37f8.gif" border="0" alt="C0044-01.GIF" width="36" height="18" /> with v</font><font face="Times New Roman, Times, Serif" size="2"><sup><i>b</i></sup></font><font face="Times New Roman, Times, Serif" size="3">(<i>t</i>) = R</font><font face="Times New Roman, Times, Serif" size="1"><sub><i>a2b</i></sub></font><font face="Times New Roman, Times, Serif" size="3">(<i>t</i>)v</font><font face="Times New Roman, Times, Serif" size="2"><sup><i>a</i></sup></font><font face="Times New Roman, Times, Serif" size="3">(<i>t</i>) and <img src="b1b2f2893baa10b57113df24c6cd1cc6.gif" border="0" alt="C0044-02.GIF" width="124" height="17" />2, then the time rates of change of the vector in the two coordinate systems are related by</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3"><img src="b750814cb17ca24c43ee584f875d835a.gif" border="0" alt="0044-01.GIF" width="333" height="23" /></font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">Taking a second derivative of Eq. (2.55) gives</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3"><img src="6b269c84fa272b8de18a137bbab5f3a0.gif" border="0" alt="0044-02.GIF" width="457" height="61" /></font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3"><img src="142668288e976d0bc121c0e4928cc6d9.gif" border="0" alt="0044-03.GIF" width="456" height="42" /></font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">Note the following points regarding the derivation of Eq. (2.58): the equation is exact, the equation is applicable between any two coordinate systems, and the equation is linear in the position and the velocity vectors [111]. This equation is the foundation on which INSs are built.</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3"><i>2.5.3<br />
Calculation of the Direction Cosine</i></font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">The previous sections have motivated the necessity of maintaining accurate direction-cosine matrices. In this section three methods for maintaining the direction-cosine matrix as the two coordinate systems experience arbitrary relative angular motion are considered. All three techniques discussed rely on measuring the relative angular rate and integrating it (by means of different methods). Initial conditions for the resulting differential equations are discussed in Chap. 6. Before integration, the angular rates should be properly compensated for biases and navigation-frame rotation, as discussed in Chap. 6.</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">The measurement of angular rates followed by integration to determine angle is preferred over direct measurement of the Euler angles for the following reasons. Angular rates are measurable by means of inertial measurements. Inertial measurements do not rely on reception of any signal exterior to the sensor itself. Therefore the accuracy of the processes described will be limited only by the accuracy inherent to the instrument and of the integration process. Alternatively, level sensors and compass-type instruments could be used to measure the Euler angles directly. However, level (gravity vector) sensors are sensitive to acceleration as well as Euler angle changes, and heading sensors are sensitive to local magnetic fields. The resulting errors are difficult to quantify <i>a priori</i> to determine worst-case system performance.</font><font face="Times New Roman, Times, Serif" size="3" color="#FFFF00"></font></td>
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