Publications – GNSS KAIST

last update: 2024-03-08

162 entries « ‹ 1 of 4 › »

2024

Sun, Andrew K., Morton, Y. Jade, Lee, Jiyun

Ionospheric Scintillation Effects across Multiple Carrier Frequency Bands Transmitted from LEO Satellites Conference

Proceedings of the 2024 International Technical Meeting of The Institute of Navigation, Long Beach, CA, 2024.

Abstract | Links

2023

Sun, Andrew K., Kil, Hyosub, Chang, Hyeyeon, Lee, Jiyun

Study of the Characteristics and Sources of Late-Night Equatorial Electron Density Irregularities Conference

AGU Annual Meeting 2023, San Francisco, CA, 2023.

Abstract

Chang, Hyeyeon, Liu, Lei, Morton, Y. Jade, Durgonics, Tibor, Wang, Jun, Fuller-Rowell, Dominic J., Hunt, Douglas, Braun, John, Weiss, Jan-Peter, Chang, Jaehee, Sun, Andrew K., Lee, Jiyun

Preliminary Assessment of Scintillation Data from the Spire Global and PlanetIQ Radio Occultation Constellation Conference

AGU Annual Meeting 2023, San Francisco, CA, 2023.

Abstract

@conference{nokey,

title = {Preliminary Assessment of Scintillation Data from the Spire Global and PlanetIQ Radio Occultation Constellation},

author = {Hyeyeon Chang and Lei Liu and Y. Jade Morton and Tibor Durgonics and Jun Wang and Dominic J. Fuller-Rowell and Douglas Hunt and John Braun and Jan-Peter Weiss and Jaehee Chang and Andrew K. Sun and Jiyun Lee},

year = {2023},

date = {2023-12-14},

urldate = {2023-12-14},

booktitle = {AGU Annual Meeting 2023},

address = {San Francisco, CA},

abstract = {Ionospheric scintillation, characterized by rapid fluctuations in amplitude and phase of signals as they propagate through ionospheric irregularities, is a space weather phenomenon that impacts satellite-based communication and navigation systems. Accurate identification of scintillation events is important to understand their impact on Earth systems. Numerous efforts have been dedicated to monitoring ionospheric scintillation using ground-based GNSS receiver networks. Fluctuations in the signals received by Low Earth Orbit (LEO) satellites that perform GNSS radio occultation (RO) measurements have also been utilized to monitor ionospheric scintillation.

Recently, low-cost CubeSats launched by commercial small satellite companies such as Spire Global, PlanetIQ, and GeoOptics are performing GNSS-RO measurements. These CubeSats collect high-rate data for scintillation observations. Both Spire Global and PlanetIQ have been awarded contracts by the National Oceanic and Atmospheric Administration (NOAA) for a GNSS-RO data pilot study. Before utilizing this data for scientific research, it is essential to evaluate the scintillation observations provided by the data to assess their reliability and potential.

This study presents a preliminary assessment of scintillation data from the Spire Global and PlanetIQ CubeSats. The assessment process employs a methodology to distinguish real ionospheric scintillation events from radio frequency interference and other anomalies. Events identified as ionospheric scintillation are then further evaluated in terms of rate of detection, scintillation indices magnitude distributions, irregularity heights and geographic areas where scintillations are detected, time of occurrence, and solar-geomagnetic conditions associated with the observed scintillations. Furthermore, this study compares the scintillation results obtained from Spire, PlanetIQ, and COSMIC-2 data, as well as available ground-based high rate GNSS receiver measurements.

The assessment results of this study will contribute to understanding of the performance of scintillation data from low-cost commercial RO missions. Filtering satellite data in this way to extract real scintillation phenomena can offer valuable insights into ionospheric responses to space weather events.},

keywords = {},

pubstate = {published},

tppubtype = {conference}

}

Ionospheric scintillation, characterized by rapid fluctuations in amplitude and phase of signals as they propagate through ionospheric irregularities, is a space weather phenomenon that impacts satellite-based communication and navigation systems. Accurate identification of scintillation events is important to understand their impact on Earth systems. Numerous efforts have been dedicated to monitoring ionospheric scintillation using ground-based GNSS receiver networks. Fluctuations in the signals received by Low Earth Orbit (LEO) satellites that perform GNSS radio occultation (RO) measurements have also been utilized to monitor ionospheric scintillation.
Recently, low-cost CubeSats launched by commercial small satellite companies such as Spire Global, PlanetIQ, and GeoOptics are performing GNSS-RO measurements. These CubeSats collect high-rate data for scintillation observations. Both Spire Global and PlanetIQ have been awarded contracts by the National Oceanic and Atmospheric Administration (NOAA) for a GNSS-RO data pilot study. Before utilizing this data for scientific research, it is essential to evaluate the scintillation observations provided by the data to assess their reliability and potential.

This study presents a preliminary assessment of scintillation data from the Spire Global and PlanetIQ CubeSats. The assessment process employs a methodology to distinguish real ionospheric scintillation events from radio frequency interference and other anomalies. Events identified as ionospheric scintillation are then further evaluated in terms of rate of detection, scintillation indices magnitude distributions, irregularity heights and geographic areas where scintillations are detected, time of occurrence, and solar-geomagnetic conditions associated with the observed scintillations. Furthermore, this study compares the scintillation results obtained from Spire, PlanetIQ, and COSMIC-2 data, as well as available ground-based high rate GNSS receiver measurements.

The assessment results of this study will contribute to understanding of the performance of scintillation data from low-cost commercial RO missions. Filtering satellite data in this way to extract real scintillation phenomena can offer valuable insights into ionospheric responses to space weather events.

Chang, Hyeyeon, Chang, Jaehee, Sun, Andrew K., Lee, Wookyoung, Kil, Hyosub, Lee, Jiyun

Performance Assessment of Ionospheric Electron Density Profiles retrieved from KOMPSAT-5 by Comparing with Ground-based and Space-based Observations Conference

AGU Annual Meeting 2023, San Francisco, CA, 2023.

Abstract

@conference{nokey,

title = {Performance Assessment of Ionospheric Electron Density Profiles retrieved from KOMPSAT-5 by Comparing with Ground-based and Space-based Observations},

author = {Hyeyeon Chang and Jaehee Chang and Andrew K. Sun and Wookyoung Lee and Hyosub Kil and Jiyun Lee},

year  = {2023},

date = {2023-12-13},

urldate = {2023-12-13},

booktitle = {AGU Annual Meeting 2023},

address = {San Francisco, CA},

abstract = {Korea Multi-Purpose Satellite (KOMPSAT)-5, launched in August 2013, is the first radio occultation (RO) mission in the Korean space program and carries the atmosphere occultation precision orbit determination (AOPOD) payload to provide data for precise orbit determination (POD) and GPS radio occultation (RO) measurements.

GPS RO data from KOMPSAT-5 is being processed and provided through a collaborative effort between KASI and the University Corporation for Atmospheric Research (UCAR). This data is then utilized by the National Oceanic and Atmospheric Administration (NOAA) for weather forecasting purposes. While the neutral atmospheric profiles from KOMPSAT-5 have been made available to the public via the COSMIC Data Analysis and Archive Center (CDAAC), the ionospheric electron density profiles have not yet been provided and validated.



In this study, the performance assessment of the ionospheric electron density retrieved from KOMPSAT-5 RO has been done. This study includes estimation of electron density profiles from KOMPSAT-5 by combining data from both the occultation antenna and POD antenna. To validate the electron density measurements from KOMPSAT-5 with reliable truth observations, digital ionosonde (digisonde) data, incoherent scatter radar (ISR), and COSMIC-2 RO data were used as the reference dataset. Furthermore, we aim to analyze the impact of horizontal ionospheric variations on the electron density retrieved by the RO technique by conducting performance evaluations based on different regions and local time periods.



The comparisons of F2 layer peak (NmF2) obtained from KOMPSAT-5 data to digisonde measurements reveal a high degree of correlation of 0.90. The comparisons with electron density profiles from ISR and COSMIC-2 RO data show that the profiles retrieved from KOMPSAT-5 RO data have good agreement with those from both ISR and COSMIC-2 RO data. The comparison results also show that the errors were more widely distributed in the lower latitude area and near the dusk/dawn terminators. This is believed to be due to the significant variations in the ionosphere in the horizontal direction at low latitudes and around dawn/dusk terminators, making it challenging to meet the spherical symmetry assumption, resulting in relatively large errors.},

keywords = {},

pubstate = {published},

tppubtype = {conference}

}

Korea Multi-Purpose Satellite (KOMPSAT)-5, launched in August 2013, is the first radio occultation (RO) mission in the Korean space program and carries the atmosphere occultation precision orbit determination (AOPOD) payload to provide data for precise orbit determination (POD) and GPS radio occultation (RO) measurements.
GPS RO data from KOMPSAT-5 is being processed and provided through a collaborative effort between KASI and the University Corporation for Atmospheric Research (UCAR). This data is then utilized by the National Oceanic and Atmospheric Administration (NOAA) for weather forecasting purposes. While the neutral atmospheric profiles from KOMPSAT-5 have been made available to the public via the COSMIC Data Analysis and Archive Center (CDAAC), the ionospheric electron density profiles have not yet been provided and validated.

In this study, the performance assessment of the ionospheric electron density retrieved from KOMPSAT-5 RO has been done. This study includes estimation of electron density profiles from KOMPSAT-5 by combining data from both the occultation antenna and POD antenna. To validate the electron density measurements from KOMPSAT-5 with reliable truth observations, digital ionosonde (digisonde) data, incoherent scatter radar (ISR), and COSMIC-2 RO data were used as the reference dataset. Furthermore, we aim to analyze the impact of horizontal ionospheric variations on the electron density retrieved by the RO technique by conducting performance evaluations based on different regions and local time periods.

The comparisons of F2 layer peak (NmF2) obtained from KOMPSAT-5 data to digisonde measurements reveal a high degree of correlation of 0.90. The comparisons with electron density profiles from ISR and COSMIC-2 RO data show that the profiles retrieved from KOMPSAT-5 RO data have good agreement with those from both ISR and COSMIC-2 RO data. The comparison results also show that the errors were more widely distributed in the lower latitude area and near the dusk/dawn terminators. This is believed to be due to the significant variations in the ionosphere in the horizontal direction at low latitudes and around dawn/dusk terminators, making it challenging to meet the spherical symmetry assumption, resulting in relatively large errors.

Chang, Jaehee, Sun, Andrew K., Chang, Hyeyeon, Wang, Yang, Liu, Lei, Hunt, Douglas, Morton, Y. Jade, Lee, Jiyun

Preliminary Assessment of the Residual Error due to Ionospheric Bending in the COSMIC-2 RO TEC by Comparing Results from Single- and Dual-frequency Methods Conference

AGU Annual Meeting 2023, San Francisco, CA, 2023.

Abstract

@conference{nokey,

title = {Preliminary Assessment of the Residual Error due to Ionospheric Bending in the COSMIC-2 RO TEC by Comparing Results from Single- and Dual-frequency Methods},

author = {Jaehee Chang and Andrew K. Sun and Hyeyeon Chang and Yang Wang and Lei Liu and Douglas Hunt and Y. Jade Morton and Jiyun Lee },

year  = {2023},

date = {2023-12-12},

urldate = {2023-12-12},

booktitle = {AGU Annual Meeting 2023},

address = {San Francisco, CA},

abstract = {The total electron content (TEC) derived from Global Positioning System (GPS) radio occultation (RO) measurements has proven to be one of the most essential observables in ionospheric studies. There are two approaches for calculating the TEC, one of which is the single-frequency method that requires the ionospheric excess phase obtained through the removal of the orbit and clock errors in the L1 or L2 phase measurements. The other is the dual-frequency method that uses the combination of L1 and L2 phase measurements, which is more efficient as it automatically cancels out the orbit and clock errors. Because of this advantage, the dual-frequency method has been the more conventional approach for TEC estimation, and is currently being implemented in the TEC processing algorithm at COSMIC Data Analysis and Archive Center (CDAAC). However, when using the assumption of straight-line propagation, there exists a residual error in both TEC estimates relative to the true straight-line TEC which arises from the bending and dispersion of the GPS signal ray paths in the ionosphere. The dual-frequency TEC is known to have a larger residual error compared to the single-frequency TEC, which has been demonstrated in previous studies through theoretical derivations and simulations. However, this theoretical representation of residual errors due to ionospheric bending has not been thoroughly investigated and validated using real RO measurements.

In this research, real RO observations from the Constellation Observing System for Meteorology, Ionosphere, and Climate-2 (COSMIC-2) mission were used to quantify the residual error in the relative TEC obtained by the dual-frequency method compared to the single-frequency method. The single-differencing with simultaneously tracked reference and occulting GPS satellite observations was used for the precise removal of the receiver clock bias in order to obtain the ionospheric excess phase for the single-frequency TEC. The results verified that the difference between the dual-frequency and single-frequency TEC at common straight-line tangent altitudes was larger at regions of high vertical TEC gradients causing larger ray separations. It was found that the residual error in the dual-frequency TEC derived from the COSMIC-2 precise orbit determination (POD) antenna observations on January 3rd, 2023 can be up to 5.3 TECU larger than that in the single-frequency TEC in the case of an occultation event with the vertical TEC gradient reaching 4.8 TECU/km. This presentation will discuss detailed approaches in the single-frequency excess phase-based TEC estimation and the dependence of dual-frequency residual error on background ionospheric TEC values.},

keywords = {},

pubstate = {published},

tppubtype = {conference}

}

The total electron content (TEC) derived from Global Positioning System (GPS) radio occultation (RO) measurements has proven to be one of the most essential observables in ionospheric studies. There are two approaches for calculating the TEC, one of which is the single-frequency method that requires the ionospheric excess phase obtained through the removal of the orbit and clock errors in the L1 or L2 phase measurements. The other is the dual-frequency method that uses the combination of L1 and L2 phase measurements, which is more efficient as it automatically cancels out the orbit and clock errors. Because of this advantage, the dual-frequency method has been the more conventional approach for TEC estimation, and is currently being implemented in the TEC processing algorithm at COSMIC Data Analysis and Archive Center (CDAAC). However, when using the assumption of straight-line propagation, there exists a residual error in both TEC estimates relative to the true straight-line TEC which arises from the bending and dispersion of the GPS signal ray paths in the ionosphere. The dual-frequency TEC is known to have a larger residual error compared to the single-frequency TEC, which has been demonstrated in previous studies through theoretical derivations and simulations. However, this theoretical representation of residual errors due to ionospheric bending has not been thoroughly investigated and validated using real RO measurements.
In this research, real RO observations from the Constellation Observing System for Meteorology, Ionosphere, and Climate-2 (COSMIC-2) mission were used to quantify the residual error in the relative TEC obtained by the dual-frequency method compared to the single-frequency method. The single-differencing with simultaneously tracked reference and occulting GPS satellite observations was used for the precise removal of the receiver clock bias in order to obtain the ionospheric excess phase for the single-frequency TEC. The results verified that the difference between the dual-frequency and single-frequency TEC at common straight-line tangent altitudes was larger at regions of high vertical TEC gradients causing larger ray separations. It was found that the residual error in the dual-frequency TEC derived from the COSMIC-2 precise orbit determination (POD) antenna observations on January 3rd, 2023 can be up to 5.3 TECU larger than that in the single-frequency TEC in the case of an occultation event with the vertical TEC gradient reaching 4.8 TECU/km. This presentation will discuss detailed approaches in the single-frequency excess phase-based TEC estimation and the dependence of dual-frequency residual error on background ionospheric TEC values.

Kim, Junsoo, Nam, Gihun, Min, Dongchan, Kim, Noah Minchan, Lee, Jiyun

Safety Risk Assessment Based Minimum Separation Boundary Conference

2023 IEEE/AIAA 42nd Digital Avionics Systems Conference (DASC), Barcelona, Spain, 2023.

Abstract | Links

@conference{nokey,

title = {Safety Risk Assessment Based Minimum Separation Boundary},

author = {Junsoo Kim and Gihun Nam and Dongchan Min and Noah Minchan Kim and Jiyun Lee},

doi = {10.1109/DASC58513.2023.10311141},

year  = {2023},

date = {2023-10-01},

urldate = {2023-10-01},

booktitle = {2023 IEEE/AIAA 42nd Digital Avionics Systems Conference (DASC)},

pages = {1-8},

address = {Barcelona, Spain},

abstract = {Urban Air Mobility (UAM) is a promising next-generation mobility solution, leveraging airspace and state-of-the-art technologies for efficient and prompt transportation in urban areas. In UAM operations, constrained urban airspace and a high safety requirement level have presented new challenges in determining the separation boundary between aircraft; increasing airspace efficiency while maintaining safety is crucial. In general aviation and Unmanned Aerial Systems (UAS), separation boundaries are set to large values to readily meet a target level of safety (TLS). These large boundaries, however, can severely lower the traffic capacity of UAM airspace if applied directly. To address this issue, in this paper we propose a methodology for determining the safety-assured minimum separation boundary for UAM operations. Our methodology identifies system safety requirements, conducts safety risk assessments (SRA), and analyzes system integrity for a comprehensive systemic approach, which reduces the reliance on extensive flight data without compromising conservatism. We applied the proposed methodology to a Global Navigation Satellite System (GNSS)/Inertial Navigation System (INS) integrated navigation system as a case study for analysis. The results indicate that a significant reduction in separation boundaries is possible while still satisfying the safety requirements compared to existing separation boundaries for general aviation and UAS. Furthermore, this paper applies the proposed method to various navigation technologies such as multi-GNSS constellation, GNSS augmentation systems, and INS sensor with different grades with the goal of further reducing the separation boundary to satisfy the stringent vertical requirements of future UAM airspace.},

keywords = {},

pubstate = {published},

tppubtype = {conference}

}

Sun, Andrew K., Chang, Jaehee, Lee, Jiyun, Breitsch, Brian, Morton, Y. Jade, Pullen, Sam

Mid-Latitude Ionospheric Scintillation Impact on Availability of Dual-frequency GNSS Augmentation Systems Conference

Proceedings of the 36th International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS+ 2023), Denver, Colorado, 2023.

Abstract

@conference{nokey,

title = {Mid-Latitude Ionospheric Scintillation Impact on Availability of Dual-frequency GNSS Augmentation Systems},

author = {Andrew K. Sun and Jaehee Chang and Jiyun Lee and Brian Breitsch and Y. Jade Morton and Sam Pullen},

year = {2023},

date = {2023-09-13},

urldate = {2023-09-13},

booktitle = {Proceedings of the 36th International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS+ 2023)},

address = {Denver, Colorado},

abstract = {Dual-frequency service of GNSS augmentation systems can effectively mitigate most ionospheric threats to system users. However, ionospheric scintillation remains a significant concern for GNSS augmentation systems, even with the benefits of dual-frequency operation. Ionospheric scintillation is characterized by rapid amplitude and phase fluctuations caused by electron density irregularities in the ionosphere. These fluctuations can lead to phase transitions and signal fading, resulting in the degradation of system performance. The occurrence of scintillation is most severe in low-latitude regions, driven by factors such as equatorial plasma bubbles (EPBs). While scintillation is relatively rare in mid-latitudes, EPBs can extend toward higher latitudes during extreme geomagnetic storms, potentially causing scintillations in mid-latitude regions. Our recent work assessed the impact of low-latitude scintillation on dual-frequency GNSS augmentation systems. However, this approach might not fully apply to mid-latitudes due to different ranges of scintillation properties and conditions. In response, our study investigates potential scintillation effects in mid-latitude regions using high-rate GNSS scintillation data to define the threat space based on physics-based modeling parameters. To characterize the scintillation effects, we conduct simulations for all combinations of parameters within the threat space. This allows us to identify the worst-case parameters corresponding to the most severe scintillation effects and incorporate them into the protection level calculations. Finally, we assess the availability of a dual-frequency SBAS-like system under extreme mid-latitude scintillation impact scenarios. Our results indicate that scintillation impacts on availability are much less severe in mid-latitudes compared to low-latitudes. However, potential scintillation impacts still exist in mid-latitudes under extreme scintillation conditions. Our approach can be applied to various GNSS augmentation systems to assess the impact of scintillation on system performance. This contribution can support the development of performance standards for operations under scintillation and mitigation strategies to address its impact on system performance.},

keywords = {},

pubstate = {published},

tppubtype = {conference}

}

Dual-frequency service of GNSS augmentation systems can effectively mitigate most ionospheric threats to system users. However, ionospheric scintillation remains a significant concern for GNSS augmentation systems, even with the benefits of dual-frequency operation. Ionospheric scintillation is characterized by rapid amplitude and phase fluctuations caused by electron density irregularities in the ionosphere. These fluctuations can lead to phase transitions and signal fading, resulting in the degradation of system performance. The occurrence of scintillation is most severe in low-latitude regions, driven by factors such as equatorial plasma bubbles (EPBs). While scintillation is relatively rare in mid-latitudes, EPBs can extend toward higher latitudes during extreme geomagnetic storms, potentially causing scintillations in mid-latitude regions. Our recent work assessed the impact of low-latitude scintillation on dual-frequency GNSS augmentation systems. However, this approach might not fully apply to mid-latitudes due to different ranges of scintillation properties and conditions. In response, our study investigates potential scintillation effects in mid-latitude regions using high-rate GNSS scintillation data to define the threat space based on physics-based modeling parameters. To characterize the scintillation effects, we conduct simulations for all combinations of parameters within the threat space. This allows us to identify the worst-case parameters corresponding to the most severe scintillation effects and incorporate them into the protection level calculations. Finally, we assess the availability of a dual-frequency SBAS-like system under extreme mid-latitude scintillation impact scenarios. Our results indicate that scintillation impacts on availability are much less severe in mid-latitudes compared to low-latitudes. However, potential scintillation impacts still exist in mid-latitudes under extreme scintillation conditions. Our approach can be applied to various GNSS augmentation systems to assess the impact of scintillation on system performance. This contribution can support the development of performance standards for operations under scintillation and mitigation strategies to address its impact on system performance.

Min, Dongchan, Kim, Noah Minchan, Kim, Junsoo, Lee, Jiyun, Pullen, Sam

SS-RAIM based Integrity Architecture for CDGNSS Systems against Satellite Measurement Faults Conference

Proceedings of the 36th International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS+ 2023), Denver, Colorado, 2023.

Abstract | Links

Kim, Noah Minchan, Min, Dongchan, Lee, Jiyun

Integrity Assurance of LIRTK Using SS-RAIM Against Sensor Faults for UAV Applications Conference

Proceedings of the 36th International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS+ 2023), Denver, Colorado, 2023.

Abstract | Links

Lee, Jinsil, Kim, Minchan, Min, Dongchan, Pullen, Sam, Lee, Jiyun

Navigation Safety Assurance of a KF-Based GNSS/IMU System: Protection Levels Against IMU Failure Journal Article

In: NAVIGATION: Journal of the Institute of Navigation, vol. 70, iss. 4, 2023.

Abstract | Links

Lee, Jiyun, Nam, Gihun, Min, Dongchan, Sun, Andrew K., Pullen, Sam

Network-Based Augmentation System (NBAS) Architectures Optimized to Support Urban Air Mobility (UAM) Conference

2023 International Technical Meeting of The Institute of Navigation, Long Beach, CA, 2023.

Abstract | Links

Sun, Andrew K., Chang, Jaehee, Lee, Jiyun, Breitsch, Brian, Morton, Y. Jade

Availability Assessment of Dual-Frequency GNSS-Based Augmentation Systems Under Equatorial Ionospheric Scintillations Conference

2023 International Technical Meeting of The Institute of Navigation, Long Beach, CA, 2023.

Abstract | Links

2022

Kil, Hyosub, Sun, Andrew K., Chang, Hyeyeon, Paxton, Larry J., Nikoukar, Romina, Lee, Jiyun

Characteristics and Sources of Electron Density Irregularities in the Low Latitude F Region Conference

AGU Fall Meeting 2022, Chicago, IL, 2022.

Kil, Hyosub, Chang, Hyeyeon, Sun, Andrew K., Lee, Jiyun

Study of the drivers of the equatorial ionization anomaly using ICON and COSMIC2 data Conference

AGU Fall Meeting 2022, Chicago, IL, 2022.

Chang, Hyeyeon, Chang, Jaehee, Sun, Andrew K., Lee, Woo Kyoung, Lee, Jiyun

Preliminary results of electron density profiles retrieved from KOMPSAT-5 Radio Occultation Data Conference

AGU Fall Meeting 2022, Chicago, IL, 2022.

Chang, Jaehee, Chang, Hyeyeon, Lee, Jiyun

Cycle Slip Mitigation for Total Electron Content Retrieval using GeoOptics Radio Occultation Data Conference

AGU Fall Meeting 2022, Chicago, IL, 2022.

Min, Dongchan, Kim, Minchan, Lee, Jinsil, Circiu, Mihaela-Simona, Meurer, Michael, Lee, Jiyun

DNN-Based Approach to Mitigate Multipath Errors of Differential GNSS Reference Stations Journal Article

In: IEEE Transactions on Intelligent Transportation Systems, pp. 1-7, 2022.

Abstract | Links

Nam, Gihun, Sun, Andrew K., Lee, Jiyun, Pullen, Sam

Networked UAV Detection and Alerting of Ionospheric Anomalies within LADGNSS Navigation Framework Conference

Proceedings of the 35th International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS+ 2022), Denver, Colorado, 2022.

Abstract | Links

@conference{nokey,

title = {Networked UAV Detection and Alerting of Ionospheric Anomalies within LADGNSS Navigation Framework},

author = {Gihun Nam and Andrew K. Sun and Jiyun Lee and Sam Pullen },

doi = {https://doi.org/10.33012/2022.18424},

year  = {2022},

date = {2022-09-01},

booktitle = {Proceedings of the 35th International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS+ 2022)},

pages = {1529-1536},

address = {Denver, Colorado},

abstract = {Local Area Differential GNSS (LADGNSS) is a simplification of the Ground-based Augmentation System (GBAS) architecture to provide navigation and guidance for nearby UAVs. Recent research has evaluated the impacts of severe ionospheric anomalies on Dual-Frequency, Multiple-Constellation (DFDC) LADGNSS and its monitors. To protect against all possible ionospheric anomalies, the system assumes that the worst-case undetected ionosphere-induced differential errors might affect users. The hypothetical impact of ionospheric anomalies can be lowered by improving monitoring capability, and one possible improvement not studied previously is to utilize two-way transmissions from the multiple networked UAVs supported by LADGNSS at any given time. Two-way datalinks are already part of the LADGNSS architecture to support UAV status reports and cooperative guidance, and they can be exploited to allow all UAVs connected to LADGNSS ground stations to share the threat information collected by any of them. This paper examines the benefit of networked UAVs for LADGNSS under anomalous ionospheric conditions by proposing a monitor strategy that leverages observations from networked UAVs to enhance ionospheric monitor capability. The strategy utilizes UAVs within the network which have superior ionospheric gradient monitor (IGM) detection capability to reduce the maximum undetected gradient of a specific user UAV, leading to reduced maximum undetected ionosphere-induced differential errors (MIEV) at that user. Simulation results show a significant reduction in the worst ionosphere-induced differential error by utilizing multiple monitor capability of networked UAVs, where the benefit increases with a larger number of UAVs that are more widely distributed.},

keywords = {},

pubstate = {published},

tppubtype = {conference}

}

Bang, Eugene, Lee, Jiyun

Undersampled Ionospheric Irregularity Threat Parameterization Using a Three-Dimensional Model for Satellite-Based Augmentation Systems Journal Article

In: IEEE Transactions on Aerospace and Electronic Systems, pp. 1-24, 2022.

Abstract | Links

Chang, Hyeyeon, Lee, Jiyun, Yoon, Hyosang, Morton, Y. Jade, Saltman, Alex

Performance assessment of radio occultation data from GeoOptics by comparing with COSMIC data Journal Article

In: Earth, Planets and Space, vol. 74, no. 108, 2022.

Abstract | Links

@article{nokey,

title = {Performance assessment of radio occultation data from GeoOptics by comparing with COSMIC data},

author = {Hyeyeon Chang and Jiyun Lee and Hyosang Yoon and Y. Jade Morton and Alex Saltman},

doi = {10.1186/s40623-022-01667-6},

year  = {2022},

date = {2022-07-11},

urldate = {2022-07-11},

journal = {Earth, Planets and Space},

volume = {74},

number = {108},

abstract = {Responding to the ever-growing demand for environmental information, the National Oceanic and Atmospheric Administration (NOAA) seeks to enter into contracts to purchase Global Navigation Satellite System (GNSS) radio occultation (RO) observations produced by commercial vendors at a low-cost. GeoOptics is one commercial vendor awarded a contract with NOAA. GeoOptics operates the Community Initiative for Cellular Earth Remote Observation (CICERO) constellation of low-earth-orbiting (LEO) 6U CubeSats. The 6U-sized CICERO will enable the deployment of GNSS array consisting of RO satellites in the Earth’s atmosphere to obtain many atmospheric observations which can improve weather forecasting. Applying GeoOptics RO data to reliable weather forecasting requires an assessment of its performance. This study analyzes the performance of GeoOptics CubeSats measurements by comparing it with the Constellation Observing System for Meteorology, Ionosphere, and Climate (COSMIC) missions (COSMIC-1 and COSMIC-2). The performance analysis was carried on data coverage capabilities and measurement quality. The analysis of data coverage confirmed that GeoOptics can acquire global observational coverage with adequate low-altitude penetration capability, while there should be updated in local time coverage. The analysis of RO measurement quality showed that GeoOptics RO measurements are comparable to those of COSMIC-2, even though GeoOptics exhibited a lower signal-to-noise ratio (SNR). The potential of GeoOptics allows for the development of a GNSS array in the Earth’s atmosphere and a large amount of effective RO measurements to be obtained for reliable weather forecasting.},

keywords = {},

pubstate = {published},

tppubtype = {article}

}

Park, Haerhee, Lee, Jinsil, Lee, Jiyun

Error modelling method of extended Kalman filter-based terrain referenced navigation system for integrity assurance under nominal conditions Journal Article

In: IET Radar, Sonar & Navigation, vol. 16, no. 9, pp. 1516-1529, 2022.

Abstract | Links

Kil, Hyosub, Chang, Hyeyeon, Lee, Woo Kyoung, Paxton, Larry J., Sun, Andrew K., Lee, Jiyun

The Origin of Multitude Plasma Depletions Detected During the 12 February 2000 and 29 October 2003 Geomagnetic Storms Journal Article

In: Journal of Geophysical Research: Space Physics, vol. 127, no. 3, 2022.

Abstract | Links

@article{nokey,

title = {The Origin of Multitude Plasma Depletions Detected During the 12 February 2000 and 29 October 2003 Geomagnetic Storms},

author = {Hyosub Kil and Hyeyeon Chang and Woo Kyoung Lee and Larry J. Paxton and Andrew K. Sun and Jiyun Lee},

doi = {10.1029/2021JA030169},

year  = {2022},

date = {2022-03-21},

urldate = {2022-03-21},

journal = {Journal of Geophysical Research: Space Physics},

volume = {127},

number = {3},

abstract = {Large amplitude plasma density irregularities have occasionally been detected at night in the midlatitude F region during geomagnetic storms. They are often interpreted in terms of equatorial plasma bubbles (EPBs) because midlatitude irregularities have the morphology of EPBs. This study assesses whether morphology can be a determining factor in ascribing the origin of such midlatitude ionospheric irregularities. We address this question by analyzing the observations of the First Republic of China satellite (ROCSAT-1) and Defense Meteorological Satellite Program (DMSP)-F14 and -F15 satellites during the geomagnetic storms on 12 February 2000 and 29 October 2003. On both days, ROCSAT-1 detects plasma depletions at midlatitudes in broad longitude regions and DMSP satellites detect isolated severe plasma depletions whose widths and depths are much wider and deeper than those of typical EPBs. The distinguishing characteristics during the storms are the detection of midlatitude depletions only in the Southern Hemisphere and the occurrence of some of these depletions before 19 hr local time and at the longitudes where EPBs are absent in the equatorial region. These characteristics are not explained satisfactorily by the characteristics of EPBs. Considering the detection of some of the midlatitude depletions at the equatorward edge of ionospheric perturbations in midlatitudes, midlatitude depletions are likely ionospheric perturbations that originated from higher latitudes. Because midlatitude depletions can originate from different sources, the morphology alone is not a determining factor of their origin.},

keywords = {},

pubstate = {published},

tppubtype = {article}

}

Lee, Halim, Pullen, Sam, Lee, Jiyun, Park, Byungwoon, Yoon, Moonseok, Seo, Jiwon

Optimal Parameter Inflation to Enhance the Availability of Single-Frequency GBAS for Intelligent Air Transportation Journal Article

In: IEEE Transactions on Intelligent Transportation Systems, pp. 1-8, 2022.

Abstract | Links

Kim, Dongwoo, Lee, Jiyun

Kalman-filter-based Integrity Evaluation Considering Fault Duration: Application to GNSS-based Attitude Determination Journal Article

In: GPS Solutions, vol. 26, no. 51, 2022.

Abstract | Links

Chang, Hyeyeon, Kil, Hyosub, Sun, Andrew K., Zhang, Shunrong, Lee, Jiyun

Ionospheric disturbances in low- and midlatitudes during the geomagnetic storm on 26 August 2018 Journal Article

In: Journal of Geophysical Research: Space Physics, vol. 127, no. 2, 2022.

Abstract | Links

@article{nokey,

title = {Ionospheric disturbances in low- and midlatitudes during the geomagnetic storm on 26 August 2018},

author = {Hyeyeon Chang and Hyosub Kil and Andrew K. Sun and Shunrong Zhang and Jiyun Lee},

doi = {10.1029/2021JA029879},

year  = {2022},

date = {2022-01-24},

urldate = {2022-01-24},

journal = {Journal of Geophysical Research: Space Physics},

volume = {127},

number = {2},

abstract = {Plasma density depletions at midlatitudes during geomagnetic storms are often understood in terms of equatorial plasma bubbles (EPBs) due to their morphological similarity. However, our study reports the observations that reveal the generation of plasma depletions at midlatitudes by local sources. During the geomagnetic storm on 26 August 2018, the Defense Meteorological Satellite Program and Swarm satellites detected plasma depletions at midlatitudes in the Asian sector in the absence of EPBs in the equatorial region. This observation and the total electron content (TEC) maps over Japan demonstrate that traveling ionospheric disturbances (TIDs) are the sources of midlatitude plasma depletions in the Asian sector. Near the west coast of the United States, the development of a narrow TEC depletion band was identified from TEC maps. The TEC depletion band, which is elongated in the northwest–southeast direction, moves toward the west with a velocity of approximately 240 m/s. The TEC at the TEC depletion band is about 5 TEC units (1016 m−2) smaller than the ambient TEC. As this band is confined to the midlatitudes, this phenomenon is not associated with an EPB. The characteristics of the TEC depletion band are consistent with those of medium-scale TIDs. Observations in the Asian sector and the TEC depletion band over the United States demonstrate that plasma depletions can develop at midlatitudes by local sources. Therefore, the morphological similarity between midlatitude irregularities and EPBs or their coincident occurrence does not provide corroborating evidence of their connection.},

keywords = {},

pubstate = {published},

tppubtype = {article}

}

Nam, Gihun, Min, Dongchan, Kim, Noah Minchan, Lee, Jiyun, Pullen, Sam

Optimal Smoothing and Monitor Strategies for DFDC Local-Area DGNSS under Anomalous Ionospheric Conditions Conference

Proceedings of the 2022 International Technical Meeting of The Institute of Navigation, Long Beach, California, 2022.

Abstract | Links

@conference{nokey,

title = {Optimal Smoothing and Monitor Strategies for DFDC Local-Area DGNSS under Anomalous Ionospheric Conditions},

author = {Gihun Nam and Dongchan Min and Noah Minchan Kim and Jiyun Lee and Sam Pullen},

doi = {10.33012/2022.18166},

year  = {2022},

date = {2022-01-01},

urldate = {2022-01-01},

booktitle = {Proceedings of the 2022 International Technical Meeting of The Institute of Navigation},

pages = {1156 - 1174},

address = {Long Beach, California},

abstract = {Dual-Frequency, Dual-Constellation Local-Area DGNSS (DFDC LADGNSS) modernizes and expands upon L1-based LADGPS to support autonomous vehicles with improved system availability and robustness against ionospheric disturbances. Recent research has evaluated several different LADGNSS smoothing strategies using measurements on GPS L1/L5 and Galileo E1/E5a frequencies to determine the optimal approach under nominal conditions. However, under anomalous ionospheric conditions, the optimal smoothing procedure may be different from the one preferred under nominal conditions. In addition, and system performance greatly depends on the ionospheric monitoring algorithm when a Single Frequency (SF) or Divergence-Free (DF) smoothing process is used. To examine this problem, the performance of SF and DF smoothing processes is evaluated by simulation in terms of Maximum Ionosphere-Induced Vertical Errors (MIEVs), which quantify the anomalous ionospheric impact on DFDC LADGNSS. IonosphereFree (IF) smoothing, which removes almost all ionospheric delay impacts, is evaluated based on its nominal (H0) Vertical Protection Level (VPL). A dual frequency ionospheric gradient monitor is also introduced to fully take advantage of multiple-frequency measurements. MIEVs and VPLs are generated for 27-satellite GPS and Galileo constellations to determine which smoothing and monitor strategies give the best performance (lowest MIEVs or VPLs) under anomalous ionospheric conditions.},

keywords = {},

pubstate = {published},

tppubtype = {conference}

}

Kim, Noah Minchan, Min, Dongchan, Lee, Jiyun

Correct Fix Probability Improvement Method via INS Aiding to Single Epoch RTK System Conference

Proceedings of the 2022 International Technical Meeting of The Institute of Navigation, Long Beach, California, 2022.

Abstract | Links

@conference{nokey,

title = {Correct Fix Probability Improvement Method via INS Aiding to Single Epoch RTK System},

author = {Noah Minchan Kim and Dongchan Min and Jiyun Lee},

doi = {10.33012/2022.18167},

year  = {2022},

date = {2022-01-01},

urldate = {2022-01-01},

booktitle = {Proceedings of the 2022 International Technical Meeting of The Institute of Navigation},

pages = {1304 - 1319},

address = {Long Beach, California},

abstract = {This paper introduces a method that utilizes an Inertial Navigation System (INS) to improve the Probability of Correct Fix (PCF) in a single-epoch Real-Time Kinematic (RTK) system. In the proposed system, only single-epoch GNSS measurements are used to avoid problems caused by cycle slips, and a time-propagated relative vector in the INS is used as a pseudo measurement in addition to the GNSS measurements to obtain an RTK solution with an improved PCF. We mathematically prove that the covariance matrix of an ambiguity float solution is always improved by the addition of prior information of an INS-aided relative vector compared to that of the existing single-epoch RTK. However, the PCF simulation results obtained by using the improved covariance matrix after applying the proposed method show that counter examples with a worse PCF of INS-aided solution than that of a GNSS-only solution may occur due to the characteristics of Z-transformation in the Least-squares AMBiguity Decorrelation Adjustment (LAMBDA) method. This study also mathematically proves that the PCF is always improved without a counter example when the original Z matrix calculated from the existing single-epoch RTK is applied. Thus, we propose a new algorithm that does not generate any counter examples, while increasing the PCF significantly based on the proof. Availability simulations were performed for different GNSS measurement noise levels and Inertial Measurement Unit (IMU) sensor grades. The results show that the system availability can be improved after applying the proposed method to the existing single-epoch RTK.},

keywords = {},

pubstate = {published},

tppubtype = {conference}

}

2021

Chang, Hyeyeon, Kil, Hyosub, Sun, Andrew K., Zhang, Shunrong, Lee, Jiyun

Bubble-like Ionospheric Irregularities observed in the United States during the 26 August 2018 Geomagnetic Storm Conference

AGU Fall Meeting 2021, New Orleans, LA, 2021.

Links

Nam, Gihun, Kim, Dongwoo, Kim, Noah Minchan, Lee, Jiyun, Pullen, Sam

Enhanced Local-Area DGNSS for Autonomous Vehicle Navigation: Optimal Smoothing Strategy Conference

Proceedings of the 34th International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS+ 2021), St. Louis, Missouri, 2021.

Abstract | Links

@conference{nokey,

title = {Enhanced Local-Area DGNSS for Autonomous Vehicle Navigation:  Optimal Smoothing Strategy},

author = {Gihun Nam and Dongwoo Kim and Noah Minchan Kim and Jiyun Lee and Sam Pullen },

doi = {10.33012/2021.18066},

year  = {2021},

date = {2021-09-01},

urldate = {2021-09-01},

booktitle = {Proceedings of the 34th International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS+ 2021), St. Louis, Missouri},

pages = {4080 - 4096},

abstract = {Local Area Differential GNSS (LADGNSS) is one means of providing navigation and guidance to autonomous vehicles with very high accuracy and integrity. In previous work, the authors have developed a low-cost, portable LADGNSS system prototype based on the single-frequency (L1-only) Ground-based Augmentation System (GBAS) architecture developed for civil aviation. This work expands that system to use multiple frequencies (L5/E5 in addition to L1) and Galileo satellites in addition to GPS, creating a Dual-Frequency Dual-Constellation (DFDC) system. This creates additional options for the carrier smoothing of code phase that is critical to reducing code-phase (pseudorange) errors and provides additional means to detect and exclude signals affected by anomalous ionospheric behavior. This paper develops new models of nominal errors for DFDC LADGNSS to represent error correlation across time and among ground reference receivers. These models support detailed comparisons of different smoothing algorithms and time constants in the presence of multiple nominal error sources. Vertical Protection Levels (VPLs) for a set of candidate smoothing processes and time constants are generated for 27-satellite GPS and Galileo constellations to determine which give the best performance (lowest VPLs, and thus highest availability) under different operational scenarios, different user distances from the LADGNSS reference station, and different levels of nominal ionospheric activity (in mid-latitudes and in equatorial regions).},

keywords = {},

pubstate = {published},

tppubtype = {conference}

}

Sun, Andrew K., Lee, Jiyun, Pi, Xiaoqing, Kriegel, Martin, Berdermann, Jens

GNSS Carrier Frequency Dependence of Ionospheric Scintillation Index in Equatorial Regions Conference

Proceedings of the XXXIVth URSI General Assembly and Scientific Symposium, Rome, Italy, 2021.

Kim, Dongwoo, Yoon, Moonseok, Pullen, Sam, Lee, Jiyun

Closed-form analysis of undetected range errors due to ionospheric impacts for GBAS category I operations Journal Article

In: NAVIGATION, vol. 68, no. 3, pp. 507-519, 2021.

Abstract | Links

Chang, Jaehee, Chang, Hyeyeon, Lee, Jiyun

Preliminary Assessment of GeoOptics and Spire CubeSat RO Performance by Comparing with COSMIC-2 Conference

BIEN 2021, Daejeon, 2021.

Sun, Andrew K., Chang, Hyeyeon, Pullen, Sam, Kil, Hyosub, Seo, Jiwon, Morton, Y. Jade, Lee, Jiyun

Markov Chain-based Stochastic Modeling of Deep Signal Fading: Availability Assessment of Dual-frequency GNSS-based Aviation under Ionospheric Scintillation Journal Article

In: Space Weather, vol. 19, no. 9, pp. e2020SW002655, 2021.

Abstract | Links

@article{Sun2021,

title = {Markov Chain-based Stochastic Modeling of Deep Signal Fading: Availability Assessment of Dual-frequency GNSS-based Aviation under Ionospheric Scintillation},

author = {Andrew K. Sun and Hyeyeon Chang and Sam Pullen and Hyosub Kil and Jiwon Seo and Y. Jade Morton and Jiyun Lee},

doi = {10.1029/2020SW002655},

year  = {2021},

date = {2021-06-24},

journal = {Space Weather},

volume = {19},

number = {9},

pages = {e2020SW002655},

abstract = {Deep signal fading due to ionospheric scintillation severely impacts global navigation satellite system (GNSS)-based applications. GNSS receivers run the risk of signal loss under deep fading, which directly leads to a significant decrease in navigation availability. The impact of scintillation on GNSS-based applications can be mitigated via dual-frequency signals which provide a backup channel. However, the benefit of dual-frequency diversity highly depends on the correlation of fading processes between signals at different frequencies. This paper proposes a Markov chain-based model that simulates the actual behavior of correlated fading processes in dual-frequency channels. A set of recorded scintillation data was used to capture transitions among all fading states based on the fading and recovery of each signal frequency. A statistical study of deep fading characteristics in this data revealed that the Markov chain-based model accurately generates realistic correlated fading processes. Using the proposed model, aviation availability of localizer performance with vertical guidance down to a 200-foot decision height (“LPV-200”) under a strong scintillation scenario is analyzed by considering the effects of signal outages due to deep fading. A parametric analysis of the availability resulting from variations in mean time to loss of lock, mean time to reacquisition, and ionospheric delay uncertainty was conducted to investigate the performance standards on GNSS-based aviation under scintillation. The analysis results demonstrate a significant benefit of frequency diversity on aviation availability during scintillation. This model will further enable the assessment of GNSS-based availability for aviation and other applications under a full range of scintillation conditions.},

keywords = {},

pubstate = {published},

tppubtype = {article}

}

Chang, Hyeyeon, Yoon, Moonseok, Pullen, Sam, Marini-Pereira, Lenoardo, Lee, Jiyun

Ionospheric spatial decorrelation assessment for GBAS daytime operations in Brazil Journal Article

In: Navigation, vol. 68, no. 2, pp. 391-404, 2021.

Abstract | Links

2020

Chang, Hyeyeon, Lee, Jiyun, Wang, Yang, Breitsch, Brian, Morton, Y. Jade

Effects of CICERO Receiver Characteristics on the Quality of Radio Occultation Data Conference

AGU Fall Meeting 2020, 2020.

Chang, Hyeyeon, Lee, Jiyun, Wang, Yang, Breitsch, Brian, Morton, Y. Jade

Preliminary Assessment of CICERO Radio Occultation Performance by Comparing with COSMIC I Data Conference

Proceedings of the 33rd International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS+ 2020), 2020.

Abstract | Links

Yoon, Moonseok, Kim, Dongwoo, Lee, Jiyun

Extreme ionospheric spatial decorrelation observed during the March 1, 2014, equatorial plasma bubble event Journal Article

In: GPS Solutions, vol. 24, no. 47, 2020.

Abstract | Links

@article{Yoon2020,

title = {Extreme ionospheric spatial decorrelation observed during the March 1, 2014, equatorial plasma bubble event},

author = {Moonseok Yoon and Dongwoo Kim and Jiyun Lee},

doi = {10.1007/s10291-020-0960-x},

year  = {2020},

date = {2020-02-17},

journal = {GPS Solutions},

volume = {24},

number = {47},

abstract = {The ground-based augmentation system must make provisions to being sufficiently robustness to ionospheric anomalies through the development of an ionospheric anomaly threat model. For developing the threat model in Brazil, earlier work found that ionospheric spatial decorrelations larger than those in the midlatitude regions were frequently observed during the peak of Solar Cycle #24 (current cycle). We provide details of a study of the extreme ionospheric spatial decorrelation observed over Brazil during the March 1, 2014, equatorial plasma bubble (EPB) event. As viewed by two Brazilian GNSS reference stations in São José dos Campos, PRN 03 descended to an elevation angle of about 19° in the northern sky. A spatial decorrelation of 850.7 mm/km at the GPS L1 signal at 01:04:00 UT between the two stations SJCU (23.21° S, 45.96° W) and SSJC (23.20° S, 45.86° W) over a baseline of 9.72 km was discovered, when the line of sight of PRN 03 passed through the transition zone of the EPB. Since the EPB-induced ionospheric scintillation can corrupt the ionospheric gradient estimates, multiple gradient observations were made from multiple stations and satellites to verify the largest gradient observation. Severe gradients discovered at other station–satellite pairs support that the event of PRN 03 is a real anomaly as opposed to a receiver fault or the result of post-processing errors. Since the availability loss was estimated to be 41.7% with the Brazilian threat model, remedies to reduce over-estimated ionospheric impact when evaluating and mitigating ionospheric integrity risk are presented.},

keywords = {},

pubstate = {published},

tppubtype = {article}

}

Sun, Kiyoung, Chang, Hyeyeon, Lee, Jiyun, Seo, Jiwon, Morton, Y. T. Jade, Pullen, Sam

Performance Benefit from Dual-Frequency GNSS-based Aviation Applications under Ionospheric Scintillation: A New Approach to Fading Process Modeling Conference

Proceedings of the 2020 International Technical Meeting of The Institute of Navigation, San Diego, California, 2020.

Abstract | Links

@conference{Sun2020,

title = {Performance Benefit from Dual-Frequency GNSS-based Aviation Applications under Ionospheric Scintillation: A New Approach to Fading Process Modeling},

author = {Kiyoung Sun and Hyeyeon Chang and Jiyun Lee and Jiwon Seo and Y.T. Jade Morton and Sam Pullen},

doi = {10.33012/2020.17184},

year  = {2020},

date = {2020-02-14},

booktitle = {Proceedings of the 2020 International Technical Meeting of The Institute of Navigation},

pages = {889 - 899},

address = {San Diego, California},

abstract = {Deep signal fading due to ionospheric scintillation may cause loss-of-lock on one or more satellites in GNSS receiver tracking loops, which can degrade the navigation availability of GNSS-based aviation applications. Scintillation impact can be mitigated via the frequency diversity, which decreases the chance of satellite loss in the presence of deep and frequent signal fades. This study presents an improved fading process model that generates correlated fading processes of dual-frequency signals and simulates the resulting scintillation impact to evaluate the availability benefit of utilizing dual-frequency GNSS in aviation applications under scintillation. The correlated fading process was described by combining single-frequency only and dual-frequency concurrent fading processes under the assumption that each fading process can be modeled as a Poisson process. Times between deep fading onsets and fading durations observed from GPS L1/L5 dual-frequency measurements collected at Hong Kong in March 2nd, 2014 were used to model the GPS L1 only, L5 only, and L1/L5 concurrent fading processes. Availability simulations for SBAS service supporting the LPV200 phase of flight were conducted by considering the effects of satellite geometry degradation and shortened carrier smoothing time, which are caused by signal losses from deep fades generated by the newly proposed fading process model. A parametric analysis of availability resulting from variations in both the probability of loss-of-lock (under deep fading) and the receiver reacquisition time (following loss-of-lock) was conducted to provide receiver requirement standards for SBAS-based aviation under severe scintillation. The results show noticeable availability improvement from dual-frequency SBAS-based aviation applications over existing single-frequency SBAS.},

keywords = {},

pubstate = {published},

tppubtype = {conference}

}

Lee, Jinsil, Kim, Dongwoo, Min, Dongchan, Nam, Gihun, Lee, Jiyun

Optimal Continuity Allocation for a Tightly-coupled KF-based GNSS/IMU Navigation System with Redundant IMUs Conference

Proceedings of the 2020 International Technical Meeting of The Institute of Navigation, San Diego, California, 2020.

Abstract | Links

@conference{Lee2020,

title = {Optimal Continuity Allocation for a Tightly-coupled KF-based GNSS/IMU Navigation System with Redundant IMUs},

author = {Jinsil Lee and Dongwoo Kim and Dongchan Min and Gihun Nam and Jiyun Lee},

doi = {10.33012/2020.17201},

year  = {2020},

date = {2020-02-14},

booktitle = {Proceedings of the 2020 International Technical Meeting of The Institute of Navigation},

pages = {1101 - 1116},

address = {San Diego, California},

abstract = {This paper introduces an optimal continuity allocation algorithm for a tightly-coupled Kalman-filter (KF)-based Global Navigation Satellite System (GNSS) and multiple Inertial Measurement Units (IMUs) integrated navigation system. Beyond our recent work on the integrity and continuity algorithm of a KF-based GNSS and a single IMU navigation system, the method proposed in this paper enables IMU sensor exclusion while assuring total continuity and integrity requirements under redundant IMU sensor configuration. Two filtering scenarios in the presence of redundant IMU sensors are considered: 1) individual filters that utilize state estimates from a single set of filters at a time, and uses other filters as backup solutions, and 2) a decentralized filter where all the parallel local filters process each IMU sensor measurement and local estimates are subsequently fused in a master filter to achieve the global estimations. First, an analytical equation that can evaluate the continuity risk probability under each filter scenario is derived. Second, based on the fact that sub-filters within the decentralized filter share the same GNSS measurements with different IMU sensors, an inter-filter correlation between test statistics of the decentralized filter is considered to tightly allocate continuity to each monitor. Inter-filter correlation is quantified recursively by the KF, and the monitor thresholds are determined from the formulated joint distributions by the inter-filter correlation. Lastly, a minimum bounding protection level (PL) is determined by optimally allocating continuity risk to each monitor. Continuity allocation considering the correlation significantly improves the overall availability by lowering the continuity burden of each monitor. Simulation results show the benefits of utilizing redundant IMU in terms of system availability and the benefits of taking into account the exact inter-filter correlation for the case of a decentralized filter when allocating continuity requirements for each monitor.},

keywords = {},

pubstate = {published},

tppubtype = {conference}

}

This paper introduces an optimal continuity allocation algorithm for a tightly-coupled Kalman-filter (KF)-based Global Navigation Satellite System (GNSS) and multiple Inertial Measurement Units (IMUs) integrated navigation system. Beyond our recent work on the integrity and continuity algorithm of a KF-based GNSS and a single IMU navigation system, the method proposed in this paper enables IMU sensor exclusion while assuring total continuity and integrity requirements under redundant IMU sensor configuration. Two filtering scenarios in the presence of redundant IMU sensors are considered: 1) individual filters that utilize state estimates from a single set of filters at a time, and uses other filters as backup solutions, and 2) a decentralized filter where all the parallel local filters process each IMU sensor measurement and local estimates are subsequently fused in a master filter to achieve the global estimations. First, an analytical equation that can evaluate the continuity risk probability under each filter scenario is derived. Second, based on the fact that sub-filters within the decentralized filter share the same GNSS measurements with different IMU sensors, an inter-filter correlation between test statistics of the decentralized filter is considered to tightly allocate continuity to each monitor. Inter-filter correlation is quantified recursively by the KF, and the monitor thresholds are determined from the formulated joint distributions by the inter-filter correlation. Lastly, a minimum bounding protection level (PL) is determined by optimally allocating continuity risk to each monitor. Continuity allocation considering the correlation significantly improves the overall availability by lowering the continuity burden of each monitor. Simulation results show the benefits of utilizing redundant IMU in terms of system availability and the benefits of taking into account the exact inter-filter correlation for the case of a decentralized filter when allocating continuity requirements for each monitor.

Yoon, Moonseok, Lee, Jiyun, Pullen, Sam

Integrity Risk Evaluation of Impact of Ionospheric Anomalies on GAST D GBAS Journal Article

In: Navigation, vol. 1, no. 12, 2020.

Abstract | Links

2019

Jeong, Seongkyun, Kim, Minchan, Lee, Jiyun

GNSS Spoofing Detection for Moving Receiver using GNSS Augmentation System Journal Article

In: International Journal of Aeronautical and Space Sciences, vol. Accepted, 2019.

Lee, Jinsil, Kim, Minchan, Min, Dongchan, Lee, Jiyun

Integrity Algorithm to Protect against Sensor Faults in Tightly-coupled KF State Prediction Conference

Proceedings of the 32nd International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS+ 2019), Miami, Florida, 2019.

Abstract | Links

@conference{Lee2019c,

title = {Integrity Algorithm to Protect against Sensor Faults in Tightly-coupled KF State Prediction},

author = {Jinsil Lee and Minchan Kim and Dongchan Min and Jiyun Lee},

doi = {10.33012/2019.16867},

year = {2019},

date = {2019-09-23},

booktitle = {Proceedings of the 32nd International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS+ 2019)},

pages = {594 - 627},

address = {Miami, Florida},

abstract = {Recently, autonomous vehicles including self-driving cars, or autonomous drones are getting a great deal of attention with the expectation that they can partially replace or augment human performance while improving operational efficiency and increase the range of applications. There are many technical issues to solve for realizing the mission including mechanical and electrical problem, control and path planning, and navigation. Among the required technologies, navigation is one of the essential components for the development of autonomous vehicles because vehicles conduct control and path following operations autonomously by trusting the given navigation information. In this response, multi-sensor navigation systems have been actively developed to improve navigation accuracy as well as continuity under various operational conditions. Currently, various sensors including Global Navigation Satellite System (GNSS), Inertial Measurement Unit (IMU), vision sensor, barometer, magnetometer, and LIDAR (for cars) are integrated to provide the navigation solution. Many studies developed the integration algorithms of these sensors, and the accuracy and continuity are significantly improved. As the many inputs from various sensors are integrated, navigation solutions are more often exposed to potential sensor faults. For the practical use of the autonomous vehicle in a ‘real world’ environment, navigation safety in addition to the navigation accuracy and continuity is critical to ensure the safe operation of the autonomous vehicles. This raises the most obvious and important question which is “How can we prove that the solution from the multi-sensor navigation system is safe to use?”. This study leverages the concept of navigation integrity which is carried out in civil aviation navigation. Integrity is a measure of trust in navigation solutions, and integrity algorithm detects navigation sensor faults causing unacceptably large positioning error and computes position error bound (protection level, PL) against undetected sensor faults. In civil aviation, integrity algorithms have been developed for different types of GNSS standalone and augmentation systems including Receiver Autonomous Integrity Monitoring (RAIM), and Satellite or Ground Based Augmentation Systems (SBAS or GBAS) to ensure navigation integrity to the extremely high level of integrity (of the order of from 10-7 to 10-9). In an integrity algorithm, the PL is computed by quantifying the impact of undetected sensor faults which propagates through a filter estimation algorithm. Thus, a PL derivation algorithm should be designed depending on estimation filters. The developed integrity algorithms for civil aviation (reviewed in the previous paragraph) is designed based on the weighted least square (WLS) filter algorithm which is a snapshot estimator in accordance with the positioning algorithm. In contrast, the multi-sensor navigation systems mostly use a Kalman filter (KF), which is a ‘recursive’ filter, for estimating navigation solutions. The recursive filter utilizes all previous sensor information in addition to the current time sensor input to determine the state estimates. This means sensor faults occurred in the previous measurements affect the position estimates as well as sensor faults in the current time measurements. This fault propagation characteristic in a recursive KF should be carefully considered when designing a KF based integrity algorithm. This raises the need for the new integrity algorithm for multi-sensor navigation systems which utilizes KF for sensor integration. The KF based integrity algorithms that quantify the fault impact on state estimates are actively being discussed in recent publications [1]-[3]. One assumption made in the previous studies is that faults occur in the GNSS measurement sequence which is used for the KF measurement update. Studies in [1] and [2] quantified the worst-case integrity risk of KF estimates by determining the worst-case fault vector in an analytical approach based on the relationship between state error and range residual based monitor test statistics. [2] specifically applied the KF based integrity algorithm to evaluate the integrity risk against a GNSS spoofing within a GNSS/IMU integrated system with an assumption that the IMU is a fault-free sensor. As another approach, [3] proposed to compute a real-time PL equation for KF estimates. To improve real-time capability, it applied an external snapshot based WLS RAIM monitor for fault monitoring and computed PL by simulating the impact of remaining fault on KF estimates through the KF algorithm that users are utilizing for their positioning. Based on the fact that there are two main filtering steps which are a state prediction and measurement update, the integrity algorithm for the sensor faults occurring in the state prediction step is also required in multi-sensor navigation systems to fully assure the system safety. In the state prediction step, an estimated state in a previous epoch is propagated to the next epoch based on a given static model or using sensor measurements which provide information for the state prediction. In multi-sensor navigation systems, sensors which provide the information for vehicle motions are used for the state prediction step. There are sensors generally applied in state prediction step including IMU, and vision sensor. Those sensors are also vulnerable to faults [4]-[5], and integrity against those sensors should be considered within the system integrity algorithms. In [6], we illustrated how an unexpected step type IMU faults (potentially due to fracture, stiction, or delamination) affect the KF estimates when it is used for the state prediction in a GNSS/IMU integrated navigation system. It was also shown that the impact of fault on position solutions due to the IMU sensor faults could be expressed using the KF innovation vector in real-time. A PL was determined for the IMU sensor fault hypothesis using the KF innovation vector and additional noise bounding terms. In this paper, we extend the concept of integrity assurance against faults occurring in sensors used for state prediction, proposed in [6], to KF-based multi-sensor navigation systems. We analyze the key difference in the impact of faults occurring in the prediction step and the measurement update step on state estimates. Under the assumption that no simultaneous fault occurs on two integrated sensors (one for the state prediction, and the other for the measurement update), the most fundamental parameter we can utilize from a KF is a KF innovation vector. If the innovation can fully capture the recursive impact of faults on state estimates in real-time, the user PL can be formulated utilizing the innovation vector with additional uncertainty terms for noise bounding. Based on the analytical formulation of the recursive fault impact on user position under each fault condition, it is shown that the innovation vector can express the fault impact on user position only when the fault occurs in sensors used for the state prediction. In case of a fault occurring in sensors used for the measurement update step, additional information on the fault vector is required to fully express the magnitude of the resulting position error caused by the fault. In other words, the innovation vector cannot be used to compute user PL in real-time when there is a fault on sensors used for the measurement update. Table 1 summarizes the content in this paragraph. Based on the finding, this study proposes a generalized integrity architecture which can be used for a KF based multi-sensor navigation system to assure navigation integrity. In the integrity architecture, three fault hypotheses are defined which are a nominal hypothesis (H0), a fault hypothesis occurred in a sensor for the measurement update step (H1), and a fault hypothesis occurred in a sensor for the prediction step (H2). For the H0 hypothesis, nominal covariance from the KF is used for PL computation. Under the H1 fault hypothesis, an additional fault monitoring algorithm is required to detect faults and quantify the undetected fault magnitude after fault monitoring in order to compute the real-time protection level. The algorithms which use RAIM proposed by the previous study [3] can be utilized for computing a real-time PL for this fault hypothesis. Lastly, the KF innovation vector is used to detect the fault and to compute a PL for the H2 fault hypothesis. For the H2 fault hypothesis, fault detection is conducted on the user position domain by comparing the fault impact determined using the KF innovation vector in real-time with a pre-defined threshold without employing additional fault monitoring algorithms. The proposed integrity algorithm can be applied to various types of multi-sensor navigation systems to compute PL against the sensor faults occurring in the state prediction step. In this study, we verified and showed the applicability of the developed integrity algorithm using two types of KF based multi-sensor systems which are a GNSS/IMU integrated navigation system and a GNSS/vision integrated navigation system. IMU and Vision sensors were used to predict the filter state, and GNSS was used to update the filter. Three PLs are computed for each fault hypothesis. We employed the algorithm proposed in [3] for computing a real-time PL against GNSS faults within the KF. New PLs both for the IMU and vision sensor were determined using the KF innovation sequence based on the proposed integrity algorithm. The computed PLs for IMU and vision sensors well bounded the KF estimates both under no-fault condition and fault-injected condition. The proposed integrity algorithm for KF-based multi-sensor navigation systems against sensor faults in the KF prediction step can be broadly used to fully assure the safety of autonomous vehicles. References [1] M. Joerger, and B. Pervan (2013). "Kalman Filter-Based Integrity Monitoring Against Sensor Faults." Journal of Guidance, Control, and Dynamics 36(2): 349-361. [2] C. Tanil et al. (2017). "An INS monitor to detect GNSS spoofers capable of tracking vehicle position." IEEE Transactions on Aerospace and Electronic Systems. [3] Bhattacharyya, S. and D. Gebre-Egziabher (2015). "Kalman filter based RAIM for GNSS receivers." IEEE Transactions on Aerospace and Electronic Systems 51(3): 2444-2459. [4] Bhatti, Umar Iqbal, and Washington Yotto Ochieng. "Failure modes and models for integrated GPS/INS systems." The Journal of Navigation 60.2 (2007): 327-348. [5] Fu, Li et al. “Vision-Aided RAIM: A New Method for GPS Integrity Monitoring in Approach and Landing Phase” Sensors (Basel, Switzerland) vol. 15,9 22854-73. 10 Sep. 2015, doi:10.3390/s150922854 [6] J. Lee, et al., “Integrity assurance of Kalman-filter based GNSS/IMU integrated systems against IMU faults for UAV applications,” ION GNSS 2018, Miami, Florida, pp. 2484-2500.},

keywords = {},

pubstate = {published},

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}

Recently, autonomous vehicles including self-driving cars, or autonomous drones are getting a great deal of attention with the expectation that they can partially replace or augment human performance while improving operational efficiency and increase the range of applications. There are many technical issues to solve for realizing the mission including mechanical and electrical problem, control and path planning, and navigation. Among the required technologies, navigation is one of the essential components for the development of autonomous vehicles because vehicles conduct control and path following operations autonomously by trusting the given navigation information. In this response, multi-sensor navigation systems have been actively developed to improve navigation accuracy as well as continuity under various operational conditions. Currently, various sensors including Global Navigation Satellite System (GNSS), Inertial Measurement Unit (IMU), vision sensor, barometer, magnetometer, and LIDAR (for cars) are integrated to provide the navigation solution. Many studies developed the integration algorithms of these sensors, and the accuracy and continuity are significantly improved. As the many inputs from various sensors are integrated, navigation solutions are more often exposed to potential sensor faults. For the practical use of the autonomous vehicle in a ‘real world’ environment, navigation safety in addition to the navigation accuracy and continuity is critical to ensure the safe operation of the autonomous vehicles. This raises the most obvious and important question which is “How can we prove that the solution from the multi-sensor navigation system is safe to use?”. This study leverages the concept of navigation integrity which is carried out in civil aviation navigation. Integrity is a measure of trust in navigation solutions, and integrity algorithm detects navigation sensor faults causing unacceptably large positioning error and computes position error bound (protection level, PL) against undetected sensor faults. In civil aviation, integrity algorithms have been developed for different types of GNSS standalone and augmentation systems including Receiver Autonomous Integrity Monitoring (RAIM), and Satellite or Ground Based Augmentation Systems (SBAS or GBAS) to ensure navigation integrity to the extremely high level of integrity (of the order of from 10-7 to 10-9). In an integrity algorithm, the PL is computed by quantifying the impact of undetected sensor faults which propagates through a filter estimation algorithm. Thus, a PL derivation algorithm should be designed depending on estimation filters. The developed integrity algorithms for civil aviation (reviewed in the previous paragraph) is designed based on the weighted least square (WLS) filter algorithm which is a snapshot estimator in accordance with the positioning algorithm. In contrast, the multi-sensor navigation systems mostly use a Kalman filter (KF), which is a ‘recursive’ filter, for estimating navigation solutions. The recursive filter utilizes all previous sensor information in addition to the current time sensor input to determine the state estimates. This means sensor faults occurred in the previous measurements affect the position estimates as well as sensor faults in the current time measurements. This fault propagation characteristic in a recursive KF should be carefully considered when designing a KF based integrity algorithm. This raises the need for the new integrity algorithm for multi-sensor navigation systems which utilizes KF for sensor integration. The KF based integrity algorithms that quantify the fault impact on state estimates are actively being discussed in recent publications [1]-[3]. One assumption made in the previous studies is that faults occur in the GNSS measurement sequence which is used for the KF measurement update. Studies in [1] and [2] quantified the worst-case integrity risk of KF estimates by determining the worst-case fault vector in an analytical approach based on the relationship between state error and range residual based monitor test statistics. [2] specifically applied the KF based integrity algorithm to evaluate the integrity risk against a GNSS spoofing within a GNSS/IMU integrated system with an assumption that the IMU is a fault-free sensor. As another approach, [3] proposed to compute a real-time PL equation for KF estimates. To improve real-time capability, it applied an external snapshot based WLS RAIM monitor for fault monitoring and computed PL by simulating the impact of remaining fault on KF estimates through the KF algorithm that users are utilizing for their positioning. Based on the fact that there are two main filtering steps which are a state prediction and measurement update, the integrity algorithm for the sensor faults occurring in the state prediction step is also required in multi-sensor navigation systems to fully assure the system safety. In the state prediction step, an estimated state in a previous epoch is propagated to the next epoch based on a given static model or using sensor measurements which provide information for the state prediction. In multi-sensor navigation systems, sensors which provide the information for vehicle motions are used for the state prediction step. There are sensors generally applied in state prediction step including IMU, and vision sensor. Those sensors are also vulnerable to faults [4]-[5], and integrity against those sensors should be considered within the system integrity algorithms. In [6], we illustrated how an unexpected step type IMU faults (potentially due to fracture, stiction, or delamination) affect the KF estimates when it is used for the state prediction in a GNSS/IMU integrated navigation system. It was also shown that the impact of fault on position solutions due to the IMU sensor faults could be expressed using the KF innovation vector in real-time. A PL was determined for the IMU sensor fault hypothesis using the KF innovation vector and additional noise bounding terms. In this paper, we extend the concept of integrity assurance against faults occurring in sensors used for state prediction, proposed in [6], to KF-based multi-sensor navigation systems. We analyze the key difference in the impact of faults occurring in the prediction step and the measurement update step on state estimates. Under the assumption that no simultaneous fault occurs on two integrated sensors (one for the state prediction, and the other for the measurement update), the most fundamental parameter we can utilize from a KF is a KF innovation vector. If the innovation can fully capture the recursive impact of faults on state estimates in real-time, the user PL can be formulated utilizing the innovation vector with additional uncertainty terms for noise bounding. Based on the analytical formulation of the recursive fault impact on user position under each fault condition, it is shown that the innovation vector can express the fault impact on user position only when the fault occurs in sensors used for the state prediction. In case of a fault occurring in sensors used for the measurement update step, additional information on the fault vector is required to fully express the magnitude of the resulting position error caused by the fault. In other words, the innovation vector cannot be used to compute user PL in real-time when there is a fault on sensors used for the measurement update. Table 1 summarizes the content in this paragraph. Based on the finding, this study proposes a generalized integrity architecture which can be used for a KF based multi-sensor navigation system to assure navigation integrity. In the integrity architecture, three fault hypotheses are defined which are a nominal hypothesis (H0), a fault hypothesis occurred in a sensor for the measurement update step (H1), and a fault hypothesis occurred in a sensor for the prediction step (H2). For the H0 hypothesis, nominal covariance from the KF is used for PL computation. Under the H1 fault hypothesis, an additional fault monitoring algorithm is required to detect faults and quantify the undetected fault magnitude after fault monitoring in order to compute the real-time protection level. The algorithms which use RAIM proposed by the previous study [3] can be utilized for computing a real-time PL for this fault hypothesis. Lastly, the KF innovation vector is used to detect the fault and to compute a PL for the H2 fault hypothesis. For the H2 fault hypothesis, fault detection is conducted on the user position domain by comparing the fault impact determined using the KF innovation vector in real-time with a pre-defined threshold without employing additional fault monitoring algorithms. The proposed integrity algorithm can be applied to various types of multi-sensor navigation systems to compute PL against the sensor faults occurring in the state prediction step. In this study, we verified and showed the applicability of the developed integrity algorithm using two types of KF based multi-sensor systems which are a GNSS/IMU integrated navigation system and a GNSS/vision integrated navigation system. IMU and Vision sensors were used to predict the filter state, and GNSS was used to update the filter. Three PLs are computed for each fault hypothesis. We employed the algorithm proposed in [3] for computing a real-time PL against GNSS faults within the KF. New PLs both for the IMU and vision sensor were determined using the KF innovation sequence based on the proposed integrity algorithm. The computed PLs for IMU and vision sensors well bounded the KF estimates both under no-fault condition and fault-injected condition. The proposed integrity algorithm for KF-based multi-sensor navigation systems against sensor faults in the KF prediction step can be broadly used to fully assure the safety of autonomous vehicles. References [1] M. Joerger, and B. Pervan (2013). "Kalman Filter-Based Integrity Monitoring Against Sensor Faults." Journal of Guidance, Control, and Dynamics 36(2): 349-361. [2] C. Tanil et al. (2017). "An INS monitor to detect GNSS spoofers capable of tracking vehicle position." IEEE Transactions on Aerospace and Electronic Systems. [3] Bhattacharyya, S. and D. Gebre-Egziabher (2015). "Kalman filter based RAIM for GNSS receivers." IEEE Transactions on Aerospace and Electronic Systems 51(3): 2444-2459. [4] Bhatti, Umar Iqbal, and Washington Yotto Ochieng. "Failure modes and models for integrated GPS/INS systems." The Journal of Navigation 60.2 (2007): 327-348. [5] Fu, Li et al. “Vision-Aided RAIM: A New Method for GPS Integrity Monitoring in Approach and Landing Phase” Sensors (Basel, Switzerland) vol. 15,9 22854-73. 10 Sep. 2015, doi:10.3390/s150922854 [6] J. Lee, et al., “Integrity assurance of Kalman-filter based GNSS/IMU integrated systems against IMU faults for UAV applications,” ION GNSS 2018, Miami, Florida, pp. 2484-2500.

Yoon, Moonseok, Kim, Dongwoo, Pullen, Sam, Lee, Jiyun

Assessment and Mitigation of EPB Impacts on Category-I GBAS operations in the Brazilian Region Journal Article

In: Navigation, vol. 66, no. 3, pp. 643-659, 2019.

Abstract | Links

Jeong, Seongkyun, Lee, Jiyun

Synthesis Algorithm for Effective Detection of GNSS Spoofing Attacks Journal Article

In: International Journal of Aeronautical and Space Sciences, 2019.

Abstract | Links

Kim, Dongwoo, Kim, Minchan, Lee, Jinsil, Lee, Jiyun

Use of Local-area Differential GNSS System for Polar Exploration Conference

The 13th International Symposium on Antarctic Earth Sciences, Incheon, Republic of Korea, 2019.

Lee, Jinsil, Lee, Jiyun

Correlation between Ionospheric Spatial Decorrelation and Space Weather Intensity for Safety-Critical Differential GNSS Systems Journal Article

In: Sensors, vol. 19, no. 9, pp. 2127, 2019.

Abstract | Links

@article{Lee2019,

title = {Correlation between Ionospheric Spatial Decorrelation and Space Weather Intensity for Safety-Critical Differential GNSS Systems},

author = {Jinsil Lee and Jiyun Lee},

doi = {10.3390/s19092127},

year  = {2019},

date = {2019-05-08},

journal = {Sensors},

volume = {19},

number = {9},

pages = {2127},

abstract = {An ionospheric spatial decorrelation is one of the most dominant error factors that affects the availability of safety-critical differential global navigation satellite systems (DGNSS). This is because systems apply significant conservatism on the error source when ensuring navigation safety due to its unpredictable error characteristic. This paper investigates a correlation between GNSS-derived ionospheric spatial decorrelation and space weather intensity. The understanding of the correlation has significant advantages when modeling residual ionospheric errors without being overly pessimistic by exploiting external sources of space weather information. An ionospheric spatial decorrelation is quantified with a parameter of spatial gradient, which is an ionosphere total electron content (TEC) difference per unit distance of ionospheric pierce point (IPP). We used all pairs of stations from dense GNSS networks in the conterminous United States (CONUS) that provide an IPP separation distance of less than 100 km to obtain spatial gradient measurements under both ionospherically quiet and active conditions. Since the correlation results would be applied to safety-critical navigation applications, special attention was paid by taking into consideration all non-Gaussian tails of a spatial gradient distribution when determining spatial gradient statistics. The statistics were compared with space weather indices which are disturbance storm time (Dst) index and interplanetary magnetic field (IMF) Bz index. As a result, the ionospheric spatial decorrelation showed a significant positive correlation with both indices, especially under active ionospheric conditions. Under quiet conditions, it showed positive correlation slightly weaker than those under active conditions, and the IMF Bz showed preceding response to the spatial gradient statistics revealing the potential applicability for predicting the spatial decorrelation conditions.},

keywords = {},

pubstate = {published},

tppubtype = {article}

}

Min, Dongchan, Kim, Minchan, Lee, Jinsil, Lee, Jiyun

Deep Neural Network Based Multipath Mitigation Method for Carrier Based Differential GNSS Systems Conference

Proceedings of the ION 2019 Pacific PNT Meeting (2019 ION PNT), Honolulu, Hawaii, 2019.

Abstract | Links

@conference{Min2019,

title = {Deep Neural Network Based Multipath Mitigation Method for Carrier Based Differential GNSS Systems},

author = {Dongchan Min and Minchan Kim and Jinsil Lee and Jiyun Lee},

doi = {10.33012/2019.16856},

year  = {2019},

date = {2019-04-15},

booktitle = {Proceedings of the ION 2019 Pacific PNT Meeting (2019 ION PNT)},

pages = {451-466},

address = {Honolulu, Hawaii},

abstract = {Carrier based Differential Global Navigation Satellite System (CD-GNSS) is getting lots of attention as a promising technology for drones since it can provide centimeter-level accuracy. Unlike widely used CD-GNSS applications such as geodetic survey, CD- GNSS systems to be used for drone applications should provide a certain level of integrity along with accuracy. However, there is a critical challenge in guaranteeing the integrity of CD-GNSS systems for drone applications due to a long filter duration which is the time necessary to resolve cycle ambiguity correctly. One of the most dominant factors that limits reducing the filter duration is the code multipath error. In this response, this paper proposes a code multipath mitigation method using Deep Neural Network (DNN) for drone systems. It is well known that DNN is a powerful for nonlinear regression problems toward which multipath estimation is applicable and can be trained using a large quantity of data. The target scenario of this study is chosen as a drone flying at a sufficiently high altitude (where no multipath reflections exist from surrounding obstacles) before lowering its altitude for other phases of operation. Therefore, the dominant factor of multipath errors of the drone is the signal reflection from its body frame. Considering the fact, the input parameters were chosen for developing the DNN model as elevation, azimuth and tilt angle of antenna which characterize signals reflected by the frame and Signal to Noise Ratio (SVR) which characterizes the slight change of signals. The validity of the proposed model was investigated and its multipath mitigation performance was evaluated under the target scenario using real data. The results show that the multipath error is mitigated by about 30% in terms of the standard deviation of multipath error and the filter duration is reduced by about 66%.},

keywords = {},

pubstate = {published},

tppubtype = {conference}

}

Lee, Jiyun

Assessment and Mitigation of Ionospheric Spatial Decorrelation on GBAS: Lessons Learned Conference

Proceedings of the ION 2019 Pacific PNT Meeting (2019 ION PNT), Honolulu, Hawaii, 2019.

Links

Chang, Hyeyeon, Yoon, Moonseok, Lee, Jiyun, Pullen, Sam, Pereira, Leonardo Marini

Assessment of Ionospheric Spatial Decorrelation for Daytime Operations of GBAS in the Brazilian Region Conference

Proceedings of the 2019 International Technical Meeting of The Institute of Navigation (ION ITM 2019), Reston, Virginia, 2019.

Abstract | Links

@conference{Chang2019,

title = {Assessment of Ionospheric Spatial Decorrelation for Daytime Operations of GBAS in the Brazilian Region},

author = {Hyeyeon Chang and Moonseok Yoon and Jiyun Lee and Sam Pullen and Leonardo Marini Pereira},

doi = {10.33012/2019.16673},

year  = {2019},

date = {2019-02-04},

booktitle = {Proceedings of the 2019 International Technical Meeting of The Institute of Navigation (ION ITM 2019)},

pages = {618-631},

address = {Reston, Virginia},

abstract = {	Extensive ionospheric studies were conducted to support the initial phase of system design approval (SDA) for the existing SLS-4000 GBAS installed at Galeão Airport (GIG) in Rio de Janeiro, Brazil. This paper focuses on determining the broadcast value of the standard deviation of vertical ionospheric gradients (or sigma_vig) that is required to bound ionospheric spatial gradients at the Brazilian region under nominal conditions during daytime hours. The days for the analysis were selected by a combination of high levels of daytime or nighttime scintillation and/or severe values of the geomagnetic storm index. The time-step method, which is useful for gaining sufficient samples at distances less than the physical separation distance of ground stations, was utilized to estimate ionospheric spatial gradients. The results show that the bounding sigma_vig values are in the range of 8-13 mm/km, when daytime was defined to exist between 6 AM and 6 PM local time. Because the time-step method estimates gradients over a time interval instead of at a single time, the results include temporal as well as spatial gradients, meaning that they overestimate the spatial gradients that are the desired results. Thus, a new method called “geometric modeling” was proposed to estimate ionospheric temporal gradients and evaluate the temporal effect added to the bounding sigma_vig values. As a result, a sigma_vig of 13 mm/km including an approximately 2 mm/km temporal gradient contribution, is conservative enough to bound ionospheric spatial decorrelation for daytime GBAS operations in the Brazilian region.},

keywords = {},

pubstate = {published},

tppubtype = {conference}

}

Yoon, Moonseok, Lee, Jiyun, Pullen, Sam

Integrity Risk Evaluation of Impact of Ionospheric Anomalies on GAST D GBAS Conference

Proceedings of the 2019 International Technical Meeting of The Institute of Navigation (ION ITM 2019), Reston, Virginia, 2019.

Abstract | Links

@conference{Yoon2019c,

title = {Integrity Risk Evaluation of Impact of Ionospheric Anomalies on GAST D GBAS},

author = {Moonseok Yoon and Jiyun Lee and Sam Pullen},

doi = {10.33012/2019.16685},

year  = {2019},

date = {2019-02-04},

booktitle = {Proceedings of the 2019 International Technical Meeting of The Institute of Navigation (ION ITM 2019)},

pages = {100-112},

address = {Reston, Virginia},

abstract = {To insure safe approach and landing operations of GAST D GBAS, this study develops a three-step worst-case parameter search and integrity risk evaluation method to identify the worst-case sets of ionospheric threat parameters and evaluate the worstpossible integrity risk. Parameters of the ionospheric gradient impact simulation are first classified into two groups, “Worst-Case (WC)” and “average,” based on the underlying “specific risk” integrity requirements. “WC” parameters are those for which a clear basis for averaging could not be established because the probabilistic distribution of these parameters cannot be established with confidence due to the lack of sufficient independent observation data. These “WC” parameters must use the worst-case value of that parameter in calculating integrity risk, meaning the value of the parameter that maximizes the integrity risk. Parameters chosen to be “average” are those which are known to be essentially random from the point of view of a GBAS precision approach impacted by an ionospheric front. The parameters treated as “average” can apply values from a sampled distribution (usually from a Uniform distribution) between the minimum and maximum values of that parameter as the basis for calculating integrity risk. The first step of this method performs a randomized search over all of the parameters with a very large total number of samples to identify one or more regions of the ionospheric threat space where the worst-case result (maximum integrity risk) is likely to lie. In the second step, the search for the worst-case set of threat parameters is more refined so that a single worst-case set of parameters can be selected for each region. Once each identified region has a single set of worst-case threat-model parameters, separate “Step 3” simulations can be conducted for each region to estimate integrity risk values, and these final results are what is compared to the SARPs anomalous ionosphere integrity requirements. This paper also evaluates the maximum integrity risk probabilities based on this three-step method using the SARPs ionospheric anomaly threat model and geometric parameters. The resulting integrity risk values for all regions are well below 10-9 , showing that the GAST D SARPs integrity requirement is met based on this combined worst-case/average definition of the anomalous ionospheric threat.},

keywords = {},

pubstate = {published},

tppubtype = {conference}

}

To insure safe approach and landing operations of GAST D GBAS, this study develops a three-step worst-case parameter search and integrity risk evaluation method to identify the worst-case sets of ionospheric threat parameters and evaluate the worstpossible integrity risk. Parameters of the ionospheric gradient impact simulation are first classified into two groups, “Worst-Case (WC)” and “average,” based on the underlying “specific risk” integrity requirements. “WC” parameters are those for which a clear basis for averaging could not be established because the probabilistic distribution of these parameters cannot be established with confidence due to the lack of sufficient independent observation data. These “WC” parameters must use the worst-case value of that parameter in calculating integrity risk, meaning the value of the parameter that maximizes the integrity risk. Parameters chosen to be “average” are those which are known to be essentially random from the point of view of a GBAS precision approach impacted by an ionospheric front. The parameters treated as “average” can apply values from a sampled distribution (usually from a Uniform distribution) between the minimum and maximum values of that parameter as the basis for calculating integrity risk. The first step of this method performs a randomized search over all of the parameters with a very large total number of samples to identify one or more regions of the ionospheric threat space where the worst-case result (maximum integrity risk) is likely to lie. In the second step, the search for the worst-case set of threat parameters is more refined so that a single worst-case set of parameters can be selected for each region. Once each identified region has a single set of worst-case threat-model parameters, separate “Step 3” simulations can be conducted for each region to estimate integrity risk values, and these final results are what is compared to the SARPs anomalous ionosphere integrity requirements. This paper also evaluates the maximum integrity risk probabilities based on this three-step method using the SARPs ionospheric anomaly threat model and geometric parameters. The resulting integrity risk values for all regions are well below 10-9 , showing that the GAST D SARPs integrity requirement is met based on this combined worst-case/average definition of the anomalous ionospheric threat.

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