Real-Time Coseismic Displacement Retrieval Based on Temporal Point Positioning with IGS RTS Correction Products

Zhang, Tracy; Nie, Zhixi; Wang, Zhenjie; Wu, Huisheng; Xu, Xiaofei

doi:10.3390/s21020334

Cited by 5 publications

(7 citation statements)

References 56 publications

(66 reference statements)

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“…Subcm land deformations in the mining areas are detectable [14]. Coseismic displacement waveforms are retrieved with horizontal and vertical accuracy of 1.2 cm and 2.4 cm, respectively [15]. Time transfer uncertainty with real-time PPP is better than 0.3 ns [16].…”

Section: Introductionmentioning

confidence: 99%

Galileo High Accuracy Service in Real-Time PNT, Geoscience and Monitoring Applications

Hadas,

Kazmierski,

Kudłacik

et al. 2024

IEEE Geosci. Remote Sensing Lett.

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Satellite transmission of orbit and clock corrections is critical for real-time positioning, navigation and timing (PNT), geoscience applications, safety and liability critical services based on Global Navigation Satellite Systems (GNSS) precise positioning. In response to such a demand, Galileo has established a High Accuracy Service (HAS) of almost global coverage for GPS and Galileo. We validate the quality of HAS corrections and investigate service performance in a variety of applications. Decimeter-level accuracy of HAS corrections leads to static and kinematic positioning with precision of a few centimeters and subdecimeter, respectively, and timing precision of a single nanosecond. Other GNSS-derived products meet the requirements of real-time GNSS meteorology and allow for monitoring coseismic vibrations. Although other Internet correction streams offer superior results, HAS provides better performance than nominal and nearly global coverage.

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Section: Introductionmentioning

confidence: 99%

Galileo High Accuracy Service in Real-Time PNT, Geoscience and Monitoring Applications

Hadas,

Kazmierski,

Kudłacik

et al. 2024

IEEE Geosci. Remote Sensing Lett.

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“…Ayrıca GNSS alıcılarının veri işleme ve depolama kapasitesindeki gelişmeler, kullanılan yöntemlere dayalı geliştirilen algoritmalar ve gerçek zamanlı uydu yörünge ve saat düzeltme bilgisi veri akışının sağlanması sonucu anlık oluşan dinamik yer değiştirmeleri gerçek zamanlı Hassas Nokta Konumlama (RT-PPP) yöntemiyle de değerlendirilmiştir (Hadas and Bosy 2015, Elsobeiey and Al Harbi 2016, Krzan and Przestrzelski 2016, El-Mowafy et al 2016, Alcay and Turgut 2017, 2019, Alcay 2019, Alkan ve Mutlu 2022. Bu yöntem deprem, tsunami, rüzgâr ve volkanik patlama gibi doğal olayların oluşturmuş olduğu şiddetli yüksek dinamik hareketlerin anlık olarak izlenilmesi ve değerlendirilmesini sağlamıştır (Martin et al 2015, Zhang et al 2021. Bununla birlikte bağıl konum belirleme yönteminin sabit noktaya bağlı olması, sonradan değerlendirme (PP)-PPP tekniğinde kullanılan uydu yörünge ve saat düzeltme ürünlerinin belirli bir zaman gecikmesiyle yayınlanması ve RT-PPP yönteminde anlık internet servisine dayalı kesintiler, gerçek zamanlı ürünlerin Gerçek Zamanlı Servis (RTS) kaynaklı gecikmeleri, bu yöntemlerin gerçek zamanlı dinamik hareketleri izlemede kullanılabilirliğini sınırlandırmaktadır.…”

Section: Introductionunclassified

Investigation of Real-Time GNSS VADASE Approach Capability of Capturing Vertical Dynamic Movements

Karadeniz

Bezcioğlu

Yiğit

et al. 2022

Afyon Kocatepe University Journal of Sciences and Engineering

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Yeryüzünde meydana gelen dinamik hareketlerin tespit edilmesinde GNSS (Global Navigation Satellite System) sensörüne dayalı birçok konum belirleme yöntemi (Bağıl Kinematik, Gerçek Zamanlı Kinematik (RTK), Hassas Nokta Konumlama (PPP), Gerçek Zamanlı (RT)-PPP vb.) kullanılmıştır. Kullanılan bu yöntemler ikinci bir GNSS alıcısı, internet bağlantısı, uydu yörünge ve saat düzeltme bilgisi gibi harici parametreler gerektirir. Bu çalışmada herhangi bir harici parametreye ihtiyaç duymadan gerçek zamanlı (Real-Time) dinamik hareketleri doğrudan yakalayabilen VADASE (Variometric Approach for Displacement Analysis Stand-Alone Engine) yaklaşımının düşey yönlü dinamik davranışları belirleyebilme yeteneği incelenmiştir. Çoklu-GNSS gözlemlerine dayalı bu yöntem, zaman ve frekans alanında bağıl konum belirleme (RP) yöntemi referans alınarak PPP yöntemi ile karşılaştırılmıştır. Sonuçlara bakıldığında düşey dinamik hareketlerin baskın frekans değerlerinin üç yöntem için de aynı olduğu görülmüştür. Baskın frekansa karşılık gelen genlik değerlerinde ise deneylerde referans alınan RP yöntemine göre RT-VADASE yönteminde 1.6 mm ila 3.2 mm arasında değişmekteyken PPP yönteminde bu farklılık 1.1 mm ila 1.6 mm arasında değişmektedir. Ayrıca zaman alanında tüm deney durumlarına incelendiğinde RT-VADASE yönteminin PP-PPP yöntemine göre KOH değerleri arasında milimetre düzeyinde (1-2mm) küçük farklılık bulunmaktadır. Sonuçlar, RT-VADASE yaklaşımının anlık olarak düşey dinamik hareketleri doğru ve güvenilir bir şekilde tespit edebileceğini göstermektedir. Bununla birlikte, RT-VADASE yöntemi deprem, rüzgâr, trafik yükü gibi dinamik yüklerin, yapıda meydana getirebileceği etkiyi anlık olarak tespit etmek ve yapı sağlığını tehdit edebilecek durumlarda yapının hızlı tehlike değerlendirilmesi yapılarak insan hayatını tehlikeye düşürecek durumlarda erken uyarı sistemine entegre bir sensör olarak kullanılabileceği gösterilmiştir.

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“…In the studies, the performance of the Real Time (RT)-PPP method and the correction products used were tested by monitoring the displacements that occur in natural events such as earthquakes and tsunamis. (Hadas and Bosy, 2015;Krzan and Przestrzelski, 2016;Elsobeiey and Al Harbi, 2016;El-Mowafy et al, 2016;Alcay and Turgut, 2017;Alcay, 2019;Takahaski et al, 2014, Tu et al, 2017, El-Mowafy and Deo, 2017Li et al, 2019;Li et al, 2014;Zheng et al, 2019;Zhang et al, 2021). This method, which is also used in deformation monitoring of engineering structures, has been emphasized as an alternative method to the RP method (Martin et al, 2015;Tang et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

“…However, the use of these products has been tested for near real-time rapid hazard assessment in order to detect the oscillations caused by the motions of the earth's crust in the structures and the damage to the structure. It has been tested that under real-time conditions, correction products produced from IGC01 can be detected at the centimeter or even millimeter level in the detection of earthquake-induced surface wave motions (Li et al, 2019;Li et al, 2014;Zheng et al, 2019;Zhang et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

High-rate real-time PPP for dynamic motion detection in vertical direction

Karadeniz

Bezcioğlu

Yiğit

et al. 2022

Proceedings of the 5th Joint International Symposium on Deformation Monitoring - JISDM 2022

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Nowadays, with the developments in GNSS (Global Navigation Satellite System) technology, the data storage and data processing capacity of GPS (Global Positioning System) receivers has been gradually increased. This situation is widely used in the detection and monitoring of horizontal and vertical vibrations that occur in the structure when high temporal resolution geodetic GPS receivers are under the influence of dynamic loads such as earth crust motions, wind load, traffic load, which affect man-made engineering structures. In the study, RT DF-PPP (Real Time Dual Frequency-Precise Point Positioning) method was applied together with a GPS sensor with a sampling interval of 20 Hz, using a steel bar mounted on a steel tree model designed as a structure model, and a steel bar on which different sensors can be integrated and can provide simulation of vertical motions in detecting vertical motions occurring in structures. To evaluate the performance of the method used and to test the performance of capturing vertical displacements, the DF-RP (Dual Frequency-Relative Positioning) method was taken as reference and the results were compared with the PP-PPP (Post Process-PPP) method using the IGS-Final (International GNSS Service-Final) product. When the results are compared with the RP and PP-PPP solutions in the frequency domain of vertical motions as a result of harmonic oscillations of the high-rate RT-PPP method, it has been seen that the amplitudes and frequencies are compatible with each other. Therefore, dynamic motions that occur as a result of natural events such as earthquakes, tsunamis, landslides and volcanic eruptions can be instantly and reliably monitored and detected by the high-rate RT-PPP method. When the results were evaluated in the time domain, an improvement was observed in the RMSE (Root Mean Square Error) and maximum values of RT-PPP and PP-PPP methods according to RP after filtering. When the statistical results are examined, vertical harmonic motions of the solutions made by using both RT-PPP and PP-PPP methods can be detected with accuracy below centimeters. These results clearly show that it can detect vertical dynamic motions in engineering structures such as bridges, skyscrapers and viaducts with RT-PPP method to evaluate. Thus, by detecting the effects of dynamic motions occurring in the structure on the health of the structure, a safe environment will be provided by making a rapid hazard assessment for life safety.

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Real-Time Coseismic Displacement Retrieval Based on Temporal Point Positioning with IGS RTS Correction Products

Cited by 5 publications

References 56 publications

Galileo High Accuracy Service in Real-Time PNT, Geoscience and Monitoring Applications

Galileo High Accuracy Service in Real-Time PNT, Geoscience and Monitoring Applications

Investigation of Real-Time GNSS VADASE Approach Capability of Capturing Vertical Dynamic Movements

High-rate real-time PPP for dynamic motion detection in vertical direction

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