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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 15</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">A weakness of this approach is that the analysis is only as accurate as the truth model. As an extreme example, consider the case in which the truth model is identically the same as the ideal model. Linearizing and forming the error equations shows that there are no errors other than those due to initialization. This is obviously not true, but rather is an artifact of an inaccurate truth model. Alternatively, the truth model can never be absolutely accurate. Specification of the truth model requires the application of engineering judgement to determine which error effects are necessary to model and which may be neglected. Tradeoffs must be made judiciously at this step, since an inappropriately neglected form of model error at this step could seriously affect the ultimate navigation performance.</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">As already alluded to, it is desirable for the navigation system to be self-correcting, in the sense that the system can estimate and correct calibration, alignment, and navigation-state errors. This is the primary motivation for aiding sensors.</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">1.4<br />
Types of Inertial Systems</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">As described above, two distinct implementation approaches for inertial systems are possible: <i>mechanized-platform systems and strap-down systems</i>.</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">In <i>mechanized-platform</i> systems, the inertial sensors are mounted on an actuated platform. The gimbal angles are commanded to maintain the platform-frame alignment with a specified navigation coordinate system. This is achieved by attempting to maintain the gyro outputs at the rotational rates computed for the navigation frame. If this is achieved, then the platform does not experience any rotation relative to the navigation frame, in spite of vehicle motion. In this approach, accelerometers aligned with the platform measure the specific force along the navigation coordinate system axes. Scaling and integration of this measured acceleration yield the desired navigation-frame position and velocity vectors. Vehicle attitude is determined by measurement of the relative angles between the vehicle and the platform axes.</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3"><i>Strap-down</i> systems attach the inertial sensors directly to the vehicle frame. In this approach, the sensors experience the full dynamic motion of the vehicle. Therefore higher bandwidth (possibly noisier) rate gyros with a higher dynamic range are required. Because of the increased dynamic range, gyro scale-factor error and nonlinearity become increasingly important. In addition, the relationship among vehicle, navigation, and inertial coordinate frames must be maintained computationally. This increases the on-board computational load relative to that of a mechanized system. In the early days of navigation, the feasibility of strap-down systems was debated because of the required gyro dynamic response specifications and the computational requirements, especially in applications in which inertial-only (unaided) position accuracy was required for long durations.</font></td>
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  <td><font face="Times New Roman, Times, Serif" size="3">Actuated systems have smaller computational burdens and expose the inertial sensors to a more benign inertial environment, but are typically larger</font><font face="Times New Roman, Times, Serif" size="3" color="#FFFF00"></font></td>
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