Abstract
This paper evaluates the performance of an integrity monitoring algorithm of global navigation satellite systems (GNSS) for the Kalman filter (KF), termed KF receiver autonomous integrity monitoring (RAIM). The algorithm checks measurement inconsistencies in the range domain and requires Schmidt KF (SKF) as the navigation processor. First, realistic carrier-smoothed pseudorange measurement error models of GNSS are integrated into KF RAIM, overcoming an important limitation of prior work. More precisely, the error covariance matrix for fault detection is modified to capture the temporal variations of individual errors with different time constants. Uncertainties of the model parameters are also taken into account. Performance of the modified KF RAIM is then analyzed with the simulated signals of the global positioning system and navigation with Indian constellation for different phases of aircraft flight. Weighted least squares (WLS) RAIM used for comparison purposes is shown to have lower protection levels. This work, however, is important because KF-based integrity monitors are required to ensure the reliability of advanced navigation methods, such as multi-sensor integration and vector receivers. A key finding of the performance analyses is as follows. Innovation-based tests with an extended KF navigation processor confuse slow ramp faults with residual measurement errors that the filter estimates, leading to missed detection. RAIM with SKF, on the other hand, can successfully detect such faults. Thus, it offers a promising solution to developing KF integrity monitoring algorithms in the range domain. The modified KF RAIM completes processing in time on a low-end computer. Some salient features are also studied to gain insights into its working principles.
Highlights
Accepted: 13 December 2021Since its inception, satellite navigation has become a critical infrastructure that supports a significant part of everyday life today
Having modeled Ψ with underlying parameters residing within a range, results of extensive simulations are shown to justify that Ψmax can be used in place of Ψ to determine max test statistics and protection levels (PL)
For the simulation results of this section, lower limits of the scale factors used to account for uncertain parameters are: $tr, min = 0.5; $ura, min = 0.5; Ktr, min = 0.25; Kura, min = 0.25; and Kml-n, min = 0.25
Summary
Satellite navigation has become a critical infrastructure that supports a significant part of everyday life today. Reference [9] reviews different sensor integration architectures for intelligent transportation systems and state-of-the-art methods for fault detection and exclusion (FDE) and PL calculations In this context, all KF-based methods up to the time of writing are discussed. Designs a computationally efficient KF RAIM algorithm for GNSS receivers It checks measurement inconsistencies in the range domain, models time correlated errors, and requires Schmidt KF (SKF) as the navigation processor. This paper attempts to explore range domain methods further for their relatively low architectural complexity To this end, it extends the work in [16], which uses an SKF [24] navigation processor and carrier-smoothed pseudoranges for absolute positioning. The paper concludes with a summary of the key findings and future work
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