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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 135</font></td></tr></table><table border="0" cellspacing="0" cellpadding="0" width="100%"><tr><td rowspan="5"></td>
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  <td align="center"><font face="Times New Roman, Times, Serif" size="3"><img src="59fd68ea6500b6bc9bb20e636ca75e0c.gif" border="0" alt="0135-01.GIF" width="425" height="283" /></font></td>
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  <td align="center"><font face="Times New Roman, Times, Serif" size="2">Figure聽4.13<br />
Performance聽of聽steady-state聽filter聽(dashed-dotted聽curve)聽relative聽to聽the聽Kalman聽filter<br />
(solid聽curve).</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="2">represented by a dashed-dotted curve). The full Kalman filter makes a much larger correction initially because of the large initial error covariance. During the initial transient, the relative performance difference is large. Since both filters are stable and both filters use the same gains in steady state, the steady-state performance of the steady-state filter is identical to that of the full Kalman filter implementation.</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">Note that this approach will fail to apply directly if either the Kalman gains are zero in steady state or do not approach constant values as <i>t</i> </font><font face="Symbol" size="3">庐</font><font face="Times New Roman, Times, Serif" size="3"></font><font face="Symbol" size="3">楼</font><font face="Times New Roman, Times, Serif" size="3">.</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3"><i>4.7.5<br />
Nonlinear Filtering</i></font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">The previous sections have concentrated on the design and the analysis of optimal (and suboptimal) estimation algorithms for linear systems. In many navigation applications either the system dynamic equations or the measurement equations are not linear. For example, the GPS range measurement</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3"><img src="1ef747c0d5d557a43ad53e82eb6c20e5.gif" border="0" alt="0135-02.GIF" width="356" height="27" /></font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">is nonlinear in the receiver antenna position (<i>x</i></font><i><font face="Times New Roman, Times, Serif" size="1"><sub>r</sub></font><font face="Times New Roman, Times, Serif" size="3">, y</font><font face="Times New Roman, Times, Serif" size="1"><sub>r</sub></font><font face="Times New Roman, Times, Serif" size="3">, z</font><font face="Times New Roman, Times, Serif" size="1"><sub>r</sub></font></i><font face="Times New Roman, Times, Serif" size="1"><sub></sub></font><font face="Times New Roman, Times, Serif" size="3">). It is therefore necessary to consider extensions of the linear optimal estimation equations to nonlinear systems. This is the objective in this section. In this section continuous-time systems with discrete measurements are considered. The main references for the material of this section are Refs. 23, 53, 74, and 109. The presentation</font><font face="Times New Roman, Times, Serif" size="3" color="#FFFF00"></font></td>
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