Kriging Interpolation in Modelling Tropospheric Wet Delay

Ma, Hongyang; Zhao, Qile; Verhagen, Sandra; Psychas, Dimitrios; Dun, Han

doi:10.3390/atmos11101125

Cited by 8 publications

(6 citation statements)

References 43 publications

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“…This is because the weights of the Kriging interpolation depend upon the distances and time variation between the unknown points and all available measurements, as well as the covariance reflected in the semivariogram. It is well known that a neutral atmosphere is stable over a small region, as supported by related studies [18,31]. Therefore, the Kriging interpolation is suitable for generating the tropospheric delay corrections because the neutral atmosphere exhibits a noticeable spatial autocorrelation.…”

Section: Ppp-rtk Model and Tropospheric Correctionsmentioning

confidence: 83%

External Tropospheric Corrections by Using Kriging Interpolation for Improving PPP-RTK Positioning Solutions

Song

Zhu

et al. 2022

Remote Sensing

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With the availability of satellite carrier-phase delay corrections provided by a reference network or the International GNSS Service (IGS), the integer ambiguity resolution for a single receiver can be successfully achieved, which is the so-called PPP-RTK concept. Although PPP-RTK can significantly shorten the convergence time, it is still worthwhile to further investigate fast and high-precision GNSS parameter estimation to improve efficiency and productivity. In order to fully exploit the potential of GNSS for positioning applications, we herein introduce external troposphere corrections as constrained pseudo observables to the undifferenced and uncombined PPP-RTK model. Since the uncertainties of the corrections are considered in the data processing, the PPP-RTK model with the weighted tropospheric corrections is referred to as the tropospheric-weighted model. Kriging interpolation is applied to generate the tropospheric corrections, as well as the corresponding variances. The quality of the tropospheric-weighted model is assessed by the positioning Root Mean Square (RMS) errors and the convergence time to reach a 10 cm accuracy. The 90% 3D convergence time of the kinematic positioning mode of the tropospheric-weighted model is 43.5 min with the ambiguity-float solution and 21.5 min with the ambiguity-fixed solution, which are shortened by 4.5 min and 5.5 min as compared to those of the standard PPP-RTK model, respectively. As for the static positioning mode, the 90% 3D convergence time of the tropospheric-weighted model for the ambiguity-float and -fixed solutions is 25.5 min and 15 min, while the 3D convergence time is 31.5 min and 18.5 min for the standard PPP-RTK model, respectively. The results also show that the tropospheric-weighted model can still work well in a 5 cm convergence threshold.

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Section: Ppp-rtk Model and Tropospheric Correctionsmentioning

confidence: 83%

External Tropospheric Corrections by Using Kriging Interpolation for Improving PPP-RTK Positioning Solutions

Song

Zhu

et al. 2022

Remote Sensing

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“…These estimations can then be interpolated to the position of a user station within the network, allowing for the correction of the user measurements. A large number of field tests in previous studies have well tested and demonstrated this network-RTK approach [ 25 , 58 ].…”

Section: Functional Modelmentioning

confidence: 99%

“…Moreover, accurate predictions of the rover’s ZTD outside the network are mainly determined by the distance to a nearby reference station and are thus unaffected by the number of reference stations. In conclusion, Kriging interpolation depends on the distances between unknown points, all available measurements, and the covariance shown in the semivariogram [ 25 ].…”

Section: Introductionmentioning

confidence: 99%

Multi-GNSS-Weighted Interpolated Tropospheric Delay to Improve Long-Baseline RTK Positioning

Mirmohammadian

Asgari

Verhagen

et al. 2022

Sensors

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Until now, RTK (real-time kinematic) and NRTK (Network-based RTK) have been the most popular cm-level accurate positioning approaches based on Global Navigation Satellite System (GNSS) signals in real-time. The tropospheric delay is a major source of RTK errors, especially for medium and long baselines. This source of error is difficult to quantify due to its reliance on highly variable atmospheric humidity. In this paper, we use the NRTK approach to estimate double-differenced zenith tropospheric delays alongside ambiguities and positions based on a complete set of multi-GNSS data in a sample 6-station network in Europe. The ZTD files published by IGS were used to validate the estimated ZTDs. The results confirmed a good agreement, with an average Root Mean Squares Error (RMSE) of about 12 mm. Although multiplying the unknowns makes the mathematical model less reliable in correctly fixing integer ambiguities, adding a priori interpolated ZTD as quasi-observations can improve positioning accuracy and Integer Ambiguity Resolution (IAR) performance. In this work, weighted least-squares (WLS) were performed using the interpolation of ZTD values of near reference stations of the IGS network. When using a well-known Kriging interpolation, the weights depend on the semivariogram, and a higher network density is required to obtain the correct covariance function. Hence, we used a simple interpolation strategy, which minimized the impact of altitude variability within the network. Compared to standard RTK where ZTD is assumed to be unknown, this technique improves the positioning accuracy by about 50%. It also increased the success rate for IAR by nearly 1.

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“…To this end, researchers have proposed many methods to deal with tropospheric delay, of which the following two are frequently applied in PPP: model correction method and parameter estimation method. The model correction method has been previously used to establish a mathematical model to correct tropospheric delay based on the physical characteristics of the troposphere and the functional relationship between meteorological parameters that affect its characteristics and tropospheric delay [10,11]. The model correction method can be divided into two types: one is the traditional tropospheric model based on early radio sounding observations, such as the Saastamoinen model, Hopfield model, and Black model, etc.…”

Section: Introductionmentioning

confidence: 99%

Tropospheric Delay Parameter Estimation Strategy in BDS Precise Point Positioning

Liu

et al. 2023

Remote Sensing

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Tropospheric delay (TD) parameter estimation is a critical issue underlying high-precision data processing for global navigation satellite systems (GNSSs). The most widely used TD parameter estimation methods are the random walk (RW) and piece-wise constant (PWC). The RW method can effectively track rapid variations of tropospheric delay, but it may introduce excessive noise. In contrast, the PWC method introduces less noise, but it is less adaptable to cases of large variations of tropospheric delay. To address the problem of how to choose the optimal TD parameter estimation method, this paper investigates the variation patterns of international GNSS service zenith tropospheric delay (IGS ZTD) products and proposes a combined strategy model for TD parameter estimation. Firstly, this paper avoids the day-boundary jumps problem of IGS ZTD products by grouping based on single-day data. Secondly, this paper introduces discrete point areas (DPAs) to measure the magnitude of the ZTD values and uses comprehensive indicators to reflect the variation of ZTD. Next, based on the Köppen-Geiger climate classification, this study selected five different climate classifications with a total of 20 IGS stations as experimental data. The data assessed span from day of year (DOY) 001 to DOY 365 in 2022. This paper then applied 26 different parameter estimation strategies for static precise point positioning (PPP) data processing, and the parameter estimation strategies that were used include the RW and PWC (with the piece-wise constant ranging from twenty minutes to five hundred minutes at twenty-minute intervals). Finally, ZTD and positioning results were obtained using various parameter estimation methods, and a combined strategy model was established. We selected five different climate classifications of IGS stations as validation data and designed three sets of comparative experiments: RW, PWC120, and the combined strategy model, to verify the effectiveness of the combined strategy model. The experimental results revealed that: RW and the combined strategy model have a comparable ZTD accuracy and both are superior to PWC120. The combined strategy model improves the positioning accuracy in the U direction compared to RW and PWC120. In arid (B) and polar (E) regions with a small variation of TD, the PWC120 strategy displayed a better positioning accuracy than the RW strategy; in equatorial (A) and warm-temperate (C) regions, where there are large variations of TD, the RW strategy exhibited a better positioning accuracy than the PWC120 strategy. The combined strategy model can flexibly select the optimal parameter estimation method according to the comprehensive indicator while ensuring ZTD estimation accuracy; it enhances positioning accuracy.

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Kriging Interpolation in Modelling Tropospheric Wet Delay

Cited by 8 publications

References 43 publications

External Tropospheric Corrections by Using Kriging Interpolation for Improving PPP-RTK Positioning Solutions

External Tropospheric Corrections by Using Kriging Interpolation for Improving PPP-RTK Positioning Solutions

Multi-GNSS-Weighted Interpolated Tropospheric Delay to Improve Long-Baseline RTK Positioning

Tropospheric Delay Parameter Estimation Strategy in BDS Precise Point Positioning

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