Performance Enhancement of GNSS/MEMS-IMU Tightly Integration Navigation System using Multiple Receivers

Global Navigation Satellite System (GNSS) and Inertial Navigation System (INS) are the most commonly used navigation systems. They both have unique advantages and disadvantages. GNSS is capable of generating precise navigation solutions while enough satellites are in view. However, the GNSS signals...

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Veröffentlicht in:	IEEE access 2020-01, Vol.8, p.1-1
Hauptverfasser:	Zhu, Zhenshu, Jiang, Changhui, Bo, Yuming
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Sprache:	eng
Schlagworte:	Computation Digital signal processing Digital signal processors Field programmable gate arrays Field tests Global navigation satellite system GNSS Inertial navigation Inertial platforms INS Microprocessors Multiple Receivers Navigation systems Performance enhancement Performance evaluation Receivers Satellites State vectors Statistical analysis System effectiveness Tight Integration
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description	Global Navigation Satellite System (GNSS) and Inertial Navigation System (INS) are the most commonly used navigation systems. They both have unique advantages and disadvantages. GNSS is capable of generating precise navigation solutions while enough satellites are in view. However, the GNSS signals are sensitive to the environment. While the signals is attenuated, the GNSS receiver will fail to provide reliable navigation solutions. INS is an advanced navigation system built based on Newton's law. Due to the random noises contained in the Inertial Measurement Unit (IMU), the INS navigation solutions errors diverge over time. Therefore, effective integration of the two common systems can obtain better navigation results than any individual system. In this paper, for enhancing the GNSS/INS tightly integration system with low cost, multiple receivers were employed in the tight integration. Pseudo-range and Pseudo-range rates from the multiple receivers were employed to compose the measurement vector of the integration filter. In order to reduce the computation load, a measurement difference method was proposed. The state vector dimension could be reduced with the measurement difference scheme. Both simulation and field test were carried out for evaluating the performance of the proposed method. Since it was hard to obtain GNSS raw measurements from commercial receivers, self-developed DSP+FPGA (Digital Signal Processor, DSP; Field Programmable Gate Array, FPGA) based GNSS receivers were employed in the field test. The statistical analysis of the results showed that the positioning errors decreased with the receiver's amount increasing. In addition, a measurement difference method was proposed to reduce the state vector dimension for saving the computation load with the identical navigation solutions accuracy.
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The state vector dimension could be reduced with the measurement difference scheme. Both simulation and field test were carried out for evaluating the performance of the proposed method. Since it was hard to obtain GNSS raw measurements from commercial receivers, self-developed DSP+FPGA (Digital Signal Processor, DSP; Field Programmable Gate Array, FPGA) based GNSS receivers were employed in the field test. The statistical analysis of the results showed that the positioning errors decreased with the receiver's amount increasing. 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subjects	Computation Digital signal processing Digital signal processors Field programmable gate arrays Field tests Global navigation satellite system GNSS Inertial navigation Inertial platforms INS Microprocessors Multiple Receivers Navigation systems Performance enhancement Performance evaluation Receivers Satellites State vectors Statistical analysis System effectiveness Tight Integration
title	Performance Enhancement of GNSS/MEMS-IMU Tightly Integration Navigation System using Multiple Receivers
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