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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 243</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"><i>7.1.2<br />
Stationary Receiver</i></font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">In the case in which the receiver is known to be stationary, an adequate model would include only receiver position and clock bias states. With the clock bias model of Sec. 5.4.1 and the assumption that the receiver is stationary, the differential equation for the (total) state is</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3"><img src="0c16fd7b4e1080feeb6736898d960fd2.gif" border="0" alt="0243-01.GIF" width="387" height="86" /></font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">Even though the receiver is assumed stationary, the spectral densities of the position-variable process-noise terms are not usually assumed to be zero. This prevents the filter gains from asymptotically approaching zero, which may lead to numerical difficulties and cause the filter to essentially ignore new information as <i>k</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">. Therefore the filter position estimate will not converge to a constant, but will wander around within the vicinity of the true position. This model is also applicable, by appropriate selection of the driving-noise spectral densities, to situations in which a nominally stationary receiver is undergoing small random motion, e.g., when a receiver mounted on a structure that vibrates because of wind or other disturbances.</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3"><i>7.1.3<br />
Low Dynamic Receiver</i></font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">When the receiver is in uniform motion (i.e., near constant velocity), performance is improved by the inclusion of velocity states in the model. In this case, velocity is modeled as a random-walk process, positions are modeled as the integral of velocity, and clock errors are modeled the same as in the previous section:</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3"><img src="8c28afd9dc8e9717f6687de965b5a53e.gif" border="0" alt="0243-02.GIF" width="413" height="132" /></font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">where the </font><font face="Symbol" size="3"><i>w</i></font><font face="Symbol" size="1"><sub>u</sub></font><font face="Times New Roman, Times, Serif" size="3"> terms would be selected to model the random variations in the velocity. Specification of the value of var(</font><font face="Symbol" size="3"><i>w</i></font><font face="Symbol" size="1"><sub>u</sub></font><font face="Times New Roman, Times, Serif" size="3">) is a tuning process for a specific application. Since a stochastic model is being fit to a deterministic process, a rigorous specification approach cannot be expected.</font><font face="Times New Roman, Times, Serif" size="3" color="#FFFF00"></font></td>
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