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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 25</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">the misalignment matrices to transform between the instrument and platform frames is a primary objective of the IMU alignment process.</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3"><i>2.1.9<br />
Summary</i></font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">A natural question at the beginning of this section is, why are the various coordinate systems required? The answer is that each sensor provides measurements with respect to a given coordinate system. The fact that the sensor-relevant coordinate frames are typically distinct from the navigation frame can now be made more concrete.</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">The GPS system (described in Chap. 5) provides estimates of antenna position in the ECEF coordinate system, vision and radar provide distance measures in a local vehicle-relative coordinate system, and accelerometers and gyros provide inertial measurements expressed relative to the instrument axes. Given that different sensors provide measurements relative to different frames, the measurements in different frames are comparable only if there are convenient means to transfer the measurements between the coordinate systems. For example, a strap-down GPS-aided INS performing navigation relative to a fixed tangent-plane frame of reference will typically</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">1. transform acceleration and angular rate measurements to platform coordinates</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">2. compensate the platform angular rate measurement for navigation-frame rotation</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">3. integrate the compensated platform-frame angular rates to maintain an accurate vector transformation from platform to navigation coordinates</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">4. transform platform-frame accelerations to tangent plane by using the transformation from step 3</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">5. integrate the (compensated) tangent-plane accelerations to calculate tangent-plane velocity and position</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">6. make GPS measurements, transformed from ECEF to tangent-plane coordinates, to estimate and correct errors in the sensed and the calculated INS quantities.</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">The necessary coordinate system transformations and the algorithms for their on-line calculation are derived in the following sections.</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">2.2<br />
ECEF Coordinate Systems</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">Two different coordinate systems are common for describing the location of a point in the ECEF frame. These rectangular and geodetic coordinate systems are defined in the following two subsections. In Sec. 2.2.3 the transformation between the two sets of coordinates is discussed.</font><font face="Times New Roman, Times, Serif" size="3" color="#FFFF00"></font></td>
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