Abstract

The carrier-to-noise ratio (C/N0) is an important indicator of the signal quality of global navigation satellite system receivers. In a vector receiver, estimating C/N0 using a signal amplitude Kalman filter is a typical method. However, the classical Kalman filter (CKF) has a significant estimation delay if the signal power levels change suddenly. In a weak signal environment, it is difficult to estimate the measurement noise for CKF correctly. This article proposes the use of the adaptive strong tracking Kalman filter (ASTKF) to estimate C/N0. The estimator was evaluated via simulation experiments and a static field test. The results demonstrate that the ASTKF C/N0 estimator can track abrupt variations in C/N0 and the method can estimate the weak signal C/N0 correctly. When C/N0 jumps, the ASTKF estimation method shows a significant advantage over the adaptive Kalman filter (AKF) method in terms of the time delay. Compared with the popular C/N0 algorithms, the narrow-to-wideband power ratio (NWPR) method, and the variance summing method (VSM), the ASTKF C/N0 estimator can adopt a shorter averaging time, which reduces the hysteresis of the estimation results.

Highlights

  • Global navigation satellite system (GNSS) receivers use tracking loops to synchronize replicated signals with received signals to maintain a continuous lock on the received signals

  • Compared with the popular C/N0 algorithms, the narrow-to-wideband power ratio (NWPR) method, and the variance summing method (VSM), the adaptive strong tracking Kalman filter (ASTKF) C/N0 estimator can adopt a shorter averaging time, which reduces the hysteresis of the estimation results

  • Satellite 24 is selected for evaluation of the estimation performance of the ASTKF method when the signal condition in the environment is poor

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Summary

Introduction

Global navigation satellite system (GNSS) receivers use tracking loops to synchronize replicated signals with received signals to maintain a continuous lock on the received signals. The delay in the C/N0 estimation process may cause erroneous measurements to be passed to the navigation Kalman filter (KF), which would severely degrade the navigation performance For these reasons, the conventional C/N0 estimation algorithms that are discussed above can impair the performance of vector-tracking loops in harsh environments. In a weak signal environment, the amplitude Kalman filter has difficulty accurately determining the measurement noise. Based on this estimation method, an adaptive C/N0 estimation method is presented in [6]. The C/N0 estimation algorithm adaptively switches between the differential method and the strong tracking Kalman filter (STKF) estimator. Based on the software receiver, vector-tracking loops and an adaptive C/N0 estimation algorithm are implemented. The conclusions of this study are presented in the final section

Vector-Tracking
Covariance propagation
Computer Simulation Experiments
Evaluation
Algorithm Precision Analysis
Strong
Weak Signal Environment Evaluation
Conclusions
Results

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