Multipath Mitigation Technology-integrated GNSS Direct Position Estimation Plug-in Module

TL;DR

This paper introduces a MATLAB-based direct position estimation (DPE) plug-in for GNSS receivers, enhanced with multipath mitigation technology to improve urban environment accuracy, and demonstrates its superior performance over traditional methods.

Contribution

It presents a practical, easily integrable DPE plug-in with multipath mitigation, advancing GNSS positioning robustness in urban environments.

Findings

MMT-DPE outperforms traditional DPE in NLOS conditions

The plug-in architecture facilitates easy integration with existing 2SP SDRs

MMT-DPE shows significant improvement in urban multipath scenarios

Abstract

Direct position estimation (DPE) is an effective solution to the MP issue at the signal processing level. Unlike two-step positioning (2SP) receivers, DPE directly solves for the receiver position, velocity, and time (PVT) in the navigation domain, without the estimation of intermediate measurements, thus allowing it to provide more robust and accurate PVT estimates in the presence of multipath (MP) and weak signals. But GNSS positioning with DPE is mostly left unapplied commercially, and continuing research into DPE has remained relatively stagnant over the past few years. To encourage further research on DPE by the GNSS community, we propose a DPE plug-in module that can be integrated into the conventional 2SP software-defined receivers (SDRs). Programmed in MATLAB, the proposed DPE plug-in module is aimed for better understanding and familiarity of a practical implementation of DPE. Its plug-in module architecture allows it to be incorporated with 2SP MATLAB SDRs, both vector tracking and scalar tracking with minimum changes, making it easy to use, and provides greater flexibility for researchers using various 2SP SDRs. We propose to further improve the performance of DPE against MP by incorporating Multipath Mitigation Technology (MMT) into DPE. Referred to as MMT-DPE, it is proposed as a variant of DPE that adds the MP components into DPE signal model by integrating MMT cost function into DPE, with the aim to better suit DPE for urban environment applications. Results show that while in MP-only conditions, an MMT-integrated 2SP (MMT-2SP) has similar performance with MMT-DPE, the proposed MMT-DPE manages to show great superiority against NLOS, making it the preferable option for applications in urban environments.