1. INTRODUCTION
A Satellite Based Augmentation System (SBAS) is a system, which has been set as an international standard by the International Civilian Aviation Organization (ICAO). It is utilized for safe operation of aircrafts by providing an augmentation information in order to reduce Global Navigation Satellite System (GNSS)-related errors such as ionospheric delay and tropospheric delay, and satellite orbit and clock errors and calculate a protection level of the calculated location (ICAO 2006). The ICAO recommended the adoption of the SBAS, satellite-based next-generational navigation safety system, at the 10th General Meeting in 1991 and urged ICAO members to introduce the performance-based navigation in the 36th General Meeting in 2007 (Han et al. 2011). According to the recommendation, a number of nations including the USA, Europe, Japan, India, and Russia have been strive to construct, operate, and develop SBASs based on the L1 SBAS Minimum Operational Performance Standards (MOPS), which are SBAS-related international standards. Currently, the Wide Area Augmentation System (WAAS) in the USA (Bunce 2011), the European Geostationary Navigation Overlay Service (EGNOS) in Europe (Maufroid & Flament 2011), MTSAT Satellite Augmentation System (MSAS) in Japan (Manabe 2008), and GPS-Aided Geo Augmented Navigation (GAGAN) (Sin et al. 2014) are operated. The System for Differential Correction and Monitoring (SDCM) in Russia is currently under construction (Sin et al. 2014). The WAAS, EGNOS, and GAGAN provide services of Approach Procedures with Vertical Guidance (APV-I)-grade performance in all air spaces while the MSAS provides only services of Non Precision Approach of Required Navigation Performance (RNP) 0.3 grade because it lacks the number of reference stations and effects of the ionosphere are significant (Sin et al. 2014). Nations that own a SBAS have made an effort to improve SBAS-related performance and service level. As a part of the efforts, studies on Multi-Constellation SBAS that provides additional correction information about GNSS such as not only the GPS but also the GLObal NAvigation Satellite System (GLONASS) (Sakai et al. 2012). The L1 SBAS MOPS was designed to support Multi-Constellation such as GPS, GLONASS, and etc. originally (RTCA 2006) but all SBAS including the WAAS in the USA that are currently operated provide correction and integrity information about the GPS only (Lawrence 2011). In contrast, the SDCM in Russia, which has started SBAS test services in Russia, provides correction and integrity information about not only the GPS but also the GLONASS (Russian Space System 2012). Currently, LUCH-5A(PRN 140), LUCH-5B(PRN 125), and LUCH-5V(PRN 141) are assigned and used as geostationary satellites for the SDCM. Among them, PRN 140 satellite is now broadcasting SBAS test messages for SDCM test services. In particular, since the Korean Peninsula is covered by the service area of the PRN 140 satellite and messages broadcast by PRN 140 satellite are received in Korea as well, performance analysis on GPS/GLONASS Multi-Constellation SBAS using the SDCM can be possible. Thus, the present paper generated correction and integrity information about GPS and GLONASS using SDCM messages broadcast by the PRN 140 satellite, and performed analysis on GPS/GLONASS Multi-Constellation SBAS performance and APV-I availability by applying GPS and GLONASS observation data received from multiple reference stations, which were operated in the National Geographic Information Institute (NGII).
2. SBAS USER ALGORITHM FOR GLONASS
2.1 SBAS Message
SBAS geostationary satellites provide correction and integrity information generated in master stations using GPS-like L1 (1575.42 Mhz) ranging signal and broadcast the signal to a wide area of regions at a transmission rate of 250 bps. The SBAS message structure consists of 8 bits Preamble, 6 bits Message Type ID, 212 bits Data Field, and 24 bits CRC Parity as shown in Fig. 1. In particular, parameters required to generate correction and integrity information is included in the 212 data field (RTCA 2006).
Fig. 1. SBAS message structure.
A total of 64 message types (MTs) are assigned as presented in Table 1 to provide parameters required to generate SBAS correction and integrity information (RTCA 2006). Although the number of messages used in the current operating SBAS systems including the WAAS in the USA, the EGNOS in Europe, and the MSAS in Japan is different system by system, around 19 messages are employed in general (Seok 2016). MT 1 among currently broadcast messages includes PRN Mask information to identify satellites supported by SBAS systems, which are utilized to calculate fast correction and long-term correction, which are satellite-related correction information in relation to MT 2~7, MT 10, MT 12, MT 24~25, and MT 28, and \(\sigma_{flt}^2\) that is the variance of estimate errors with regard to fast correction and long-term correction. MT 18 includes IGP mask information to identify ionospheric grid point (IGPs) for which ionospheric vertical delay and integrity information inside each of the SBAS system coverage, which is utilized to calculate ionospheric correction, which is ionospheric correction information in relation to MT 10 and MT 26, and , which is the variance of estimate error with regard to ionospheric correction.
Table 1. SBAS message types and information.
Type | Contents | Type | Contents |
0 1 2 to 5 6 7 8 9 10 11 12 13 to 16 |
SBAS test mode PRN mask assignments Fast correction & UDRE Integrity information (UDRE) Fast correction degradation factor Reserved GEO navigation message Degradation parameters Reserved SBAS network time / UTC offset Reserved |
17 18 19 to 23 24 25 26 27 28 29 to 61 62 63 |
GEO Satellite almanacs Ionospheric grid point mask Reserved Mixed fast & long-term correction Long-term correction Ionospheric correction & GIVE SBAS service message Clk-Eph Cov. matrix message Reserved Internal test message Null message |
2.2 GLONASS Time and GLONASS Coordinate System
GLONASS is operated based on the reference clock generated in the GLONASS control segment, in which GLONASS time is adjusted to be synchronized with coordinated universal time (UTC) through the leap second correction in contrast with the GPS.
When user positioning is calculated by combining measurements via GPS and GLONASS, a difference in reference clock between GPS and GLONASS systems must be taken into consideration (ICAO 2006). There are a variety of methods that take a difference in reference clock into consideration. In an SBAS, a method that provides a time offset between two systems to users directly is used. The advantage of this method improves interoperability by fixing the number of unknown variables in the navigation solution equation to four even if user positioning is determined by combining measurements of GPS and GLONASS since GLONASS satellite clock errors calculated in consideration of time offset can be regarded as a measurement from the same constellation rather than different constellations (Sakai et al. 2012) Since the current operating SBAS systems including the WAAS in the USA, the EGNOS in Europe, and the MSAS in Japan support the GPS only, a difference in reference clock between two systems is not considered. Nonetheless, the SDCM in Russia that supports not only the GPS but also GLONASS considers a difference in reference clock between two systems and a time offset between two systems is included in MT 12 (Russian Space System 2012).
In contrast with the GPS that uses the WGS-84 coordinate, GLONASS employs the PZ-90 coordinate made in Russia. According to the GLONASS modernization plan, the PZ-90.02 coordinate, which is nearly equivalent to the ITRF2000 coordinate, has been used since September 2007. Similar to the case of using the reference clock, positions of the GPS and GLONASS satellites in the same coordinate system should be considered when user positioning is calculated using measurements obtained via two systems. The most general method for this is to convert the PZ-90.02 coordinate into the WGS-84 coordinate, and an equation of conversion between two coordinate systems is presented in Eq. (1).
\(\left[\begin{matrix}x\\y\\z\\\end{matrix}\right]_{WGS-84}=\left[\begin{matrix}x\\y\\z\\\end{matrix}\right]_{PZ-90.02}+\left[\begin{matrix}-0.36\\0.08\\0.18\\\end{matrix}\right]\) (1)
2.3 Limitation of PRN Mask
The PRN mask with regard to GNSS and GEO is assigned in the L1 SBAS MOPS, which is the international SBAS standard as presented in Table 2. The PRN mask included in MT 1 consists of a total of 210 slots whose value is 0 or 1. If a slot value is 0, it means that correction information of a corresponding satellite is not provided. If a slot value is 1, it means that correction information of a corresponding satellite is provided (RTCA 2006).
Table 2. PRN mask assignment for SBAS.
PRN | Assignment |
1 to 37 38 to 61 62 to 119 120 to 138 139 to 210 |
GPS GLONASS Future GNSS GEO/SBAS PRN Future GNSS/GEO/SBAS |
The most significant shortcoming of the L1 SBAS MOPS is that only up to 51 satellites can be corrected. Since PRN masks with regard to 32 GPS satellites and one to three GEO satellites are assigned and used in existing SBASs, the above limitation is not valid. On the other hand, the SDCM that supports even the GLONASS should assign PRN masks with regard to 24 GLONASS satellites additionally, it is affected by the above limitation.
Fig. 2 shows MT 1 PRN masks of SDCM message received at the Navigation System Laboratory in Sejong University from 00:00 to 24:00 in September 24, 2016, which verified that the current SDCM assigned and employed PRN masks with regard to a total of 51 satellites (26 GPS satellites, 24 GLONASS satellites, and 1 SDCM GEO satellite) except for GPS PRN 1, 5, 6, 24, 26, and 32.
Fig. 2. PRN mask for MT 1 transmitted by SDCM.
2.4 IOD (Issue of Data)
In MT 25 that is broadcast by the SBAS, the issue of data (IOD) is included along with satellite orbit and clock error corrections, which are required to calculate a long-term correction. Users must take the IOD into consideration in the calculation of long-term correction. For the GPS, the IOD is used to check whether GPS broadcast ephemeris used to generate long-term correction in the master stations and GPS broadcast ephemeris used to determine satellite positioning by users are matched. Satellite position and clock errors using a corresponding broadcast ephemeris can be corrected by long-term correction only when IOD ephemeris (IODE), IOD clock (IODC) that are included in GPS broadcast ephemeris of users and IOD are matched. For GLONASS, the IOD refers to a valid time that can apply long-term correction to a satellite position calculated using GLONASS broadcast ephemeris. It consists of operation time (V) and delay time (L) as presented in Table 3. Users can apply long-term correction only to satellite position and clock errors calculated using GLONASS broadcast ephemeris that satisfies Eq. (2). (Russian Space System 2012).
\(t_{LT}-L-V\le t_r\le t_{LT}-L\) (2)
In Eq. (2), \(t_{LT}\) refers to a time that long-term correction is broadcast at the geostationary satellite and \(t_r\) refers to a time that a user receives the GLONASS broadcast ephemeris.
Table 3. PRN mask assignment for SBAS.
Data | Bits | Range [s] | Resolution [s] |
Operation time Delay time |
5 3 |
30 to 960 0 to 120 |
30 30 |
2.5 Long-term Correction for GLONASS Satellite
As mentioned in the above, a process of calculation of long-term correction can vary slightly since the reference clock and coordination system used by each of the GPS and GLONASS systems are different.
For correction information of satellite clock errors, satellite clock error correction (\(\delta\Delta t_{SV}\)) for GPS satellites can be calculated using Eq. (3) while satellite clock error correction for GLONASS satellites can be calculated via Eq. (4) by considering a time offset (\(\delta a_{fG0}\)) that is a difference in reference clock between GPS time and GLONASS time, which is included in MT 12 (RTCA 2006, Russian Space System 2012).
\(\delta\Delta t_{SV}=\delta a_{f0}+\delta a_{f1}(t-t_0)\) (3)
\(\delta\Delta t_{SV}=\delta a_{f0}+\delta a_{f1}\left(t-t_0\right)+\delta a_{fG0}\) (4)
In Eqs. (3) and (4), \(\delta a_{f0}\) and \(\delta a_{f1}\) refer to clock offset error correction and clock drift error correction, and \(t\) and \(t_0\) refer to a current time and applicable time of long-term correction.
For correction information of satellite orbit errors, satellite orbit error correction (\(\delta x_k,\delta y_k,\delta z_k\)) for both of GPS and GLONASS satellites can be calculated using Eq. (5). However, since correction information of GPS satellites is based on the WGS-84 coordinate system and correction information of GNONASS satellite is based on the PZ-90.02 coordinate system, correction information of GLONASS satellite orbit error shall be converted to the WGS-84 coordinate system using Eq. (1).
\(\left[\begin{matrix}\delta x_k\\\delta y_k\\\delta z_k\\\end{matrix}\right]=\left[\begin{matrix}\delta x\\\delta y\\\delta z\\\end{matrix}\right]+\left[\begin{matrix}\delta\dot{x}\\\delta\dot{y}\\\delta\dot{z}\\\end{matrix}\right]\left(t-t_0\right)\) (5)
In Eq. (5), \(\delta x\), \( \delta y\), and \( \delta z\) refer to correction information of satellite orbit errors, and \(\delta\dot{x}\), \(\delta\dot{y}\), and \(\delta\dot{z}\) refer to correction information of satellite velocity errors. \(t\) and \(t_0\) are the same as in Eqs. (3) and (4).
2.6 SBAS Positioning Algorithm
Fig. 3 shows the SBAS positioning algorithm using the augmentation information which is provided by the SDCM. For input data of the algorithm, RINEX Observation Data, Navigation Data, and SBAS Broadcast Message are used. A process of the user positioning calculation is as follows: First, GLONASS L1 code measurement, satellite signal reception time, and GLONASS broadcast ephemeris are received as input data and GLONASS satellite position and clock errors are calculated as of the time of the satellite signal transmission. Second, GLONASS L1 code measurement, satellite signal receive time, and GLONASS broadcast ephemeris are received as input data and user position and clock errors are calculated in the stand-alone mode. Third, decoded SDCM message, GLONASS satellite position, and clock errors are received as input data and fast correction and long-term correction, which are GLONASS satellite-related correction information, and ionospheric correction and tropospheric correction, which are atmosphere-related errors, are calculated. Finally, SDCM correction is applied to GLONASS L1 code measurements to calculate user position and clock errors at the SBAS mode.
Fig. 3. SBAS positioning algorithm using SDCM corrections.
3. EXPERIMENTAL RESULTS
3.1 GPS/GLONASS Observations Data and SBAS Message
In order to consider various user positions from low to high latitudes in South Korea, the following 17 GNSS reference stations that are operated by the National Geographic Information Institute are selected as shown in Fig. 4: Cheorwon Reference Station (CHUL), Inje Reference Station (INJE), Ganghwa Reference Station (GANH), Hongcheon Reference Station (HONC), Seoul Reference Station (SOUL), Donghae Reference Station (DONH), Incheon Reference Station (INCH), Suwon Reference Station (SUWN), Boeun Reference Station (BOEN), Gunsan Reference Station (KUSN), Muju Reference Station (MUJU), Ulsan Reference Station (WOLS), Busan Reference Station (PUSN), Suncheon Reference Station (SONC), Geoje Reference Station (GOJE), Jangheung Reference Station (JAHG), Jeju Reference Station (CHJU). Table 4 summarizes latitude, longitude, height, and GNSS receiver used in each reference station. For performance analysis, GPS and GNONASS observation data received at each reference station for 24 hours from 00:00 in September 24 2016 to 24:00 in September 24 2016 were used as GNSS observation data. For SBAS messages, SDCM messages from PRN 140 satellite received at the Navigation System Laboratory in Sejong University at the same time period were used.
Fig. 4. Location of NGII GNSS reference stations used for the analysis.
Table 4. Information of 17 GNSS reference stations.
Site name | GNSS receiver | Lat. [°N] | Lon. [°E] | Hgt. [m] |
CHUL INJE GANH HONC SOUL DONH INCH SUWN BOEN KUSN MUJU WOLS PUSN SONC GOJE JAHG CHJU |
Trimble NetR9 Trimble NetR5 Trimble NetR9 Trimble NetR5 Trimble NetR9 Trimble NetR9 Trimble NetR5 Trimble NetR9 Trimble NetR5 Leica GR10 Trimble NetR8 Trimble NetR5 Trimble NetR5 Trimble NetR5 Leica GR10 Trimble NetR5 Trimble NetR9 |
38.273 38.070 37.719 37.709 37.630 37.507 37.420 37.276 36.488 36.005 36.003 35.504 35.234 34.958 34.722 34.675 33.514 |
127.145 128.171 126.390 128.194 127.080 129.124 126.686 127.054 127.730 126.762 127.661 129.416 129.075 127.486 128.591 126.899 126.530 |
289.032 257.483 43.501 372.184 59.113 69.941 88.464 83.819 212.238 49.082 230.189 99.935 158.645 43.617 61.720 116.773 50.337 |
3.2 Position Accuracy
Fig. 5 shows a result that projects the Root Mean Squares (RMS) of horizontal and vertical errors of user's position calculated by applying SDCM differential correction and integrity information to the observation data in the reference stations to the Korean Peninsula map in order to verify the correction performance of user positioning error in the GPS/GLONASS Multi-Constellation SBAS according user's position in the Korean Peninsula. Table 5 summarizes standard deviation, RMS, and maximum values of horizontal and vertical errors of user position for each reference station. As presented in Fig. 5 and Table 5, RMSs of horizontal and vertical errors were increased as a latitude is moved from higher latitude to lower latitude in South Korea. In particular, RMSs of horizontal and vertical errors in CHUL Reference Station, which was located in the northernmost part among the selected reference stations, were 0.8857 m and 1.0276 m, respectively, while those in CHJU Reference Station, which was located in the southernmost part, were 1.9322 m and 2.1862 m, verifying that a user positioning error of the GPS/GLONASS Multi-Constellation SBAS was twice that in the high latitude approximately, resulting in a significant decrease in performance.
Fig. 5. SDCM position accuracy map.
Table 5. Horizontal and vertical error statistics at each GNSS reference stations (2697 epochs / 2880 epochs).
Site name |
Horizontal | Vertical | ||||
Std. [m] | RMS [m] | Max [m] | Std. [m] | RMS [m] | Max [m] | |
CHUL INJE GANH HONC SOUL DONH INCH SUWN BOEN KUSN MUJU WOLS PUSN SONC GOJE JAHG CHJU |
0.4202 0.4287 0.4686 0.4045 0.3746 0.3715 0.5296 0.4597 0.4357 0.6095 0.5831 1.2822 0.8174 0.5416 0.9942 0.5858 1.4705 |
0.8857 0.8636 0.9317 0.8197 0.7810 0.7515 0.9765 0.9104 0.9037 1.0475 0.9558 1.5802 1.1744 1.0039 1.4422 1.0592 1.9322 |
3.8435 5.7658 4.6816 3.1462 3.6495 2.8306 4.5056 3.3952 2.8168 6.7553 13.1663 28.6218 14.5710 5.9983 12.6941 5.5296 18.9978 |
1.0219 1.1269 1.2085 1.0177 0.9918 0.8838 1.6357 1.1867 1.1417 1.2960 1.6848 2.0497 1.6076 1.7611 1.6713 1.3260 2.1544 |
1.0276 1.1317 1.2147 1.0239 1.0958 0.9107 1.6809 1.2582 1.2222 1.4595 1.6846 2.0533 1.6112 1.7759 1.7427 1.4009 2.1862 |
3.9754 10.0602 6.1514 4.6160 5.3753 3.2120 13.7194 7.4170 6.2282 8.6851 23.4755 43.7879 29.2361 20.1039 11.2583 8.7716 21.2794 |
3.3 APV-I Availability
The ICAO specifies the RNP with regard to accuracy, integrity, continuity, and availability according to a navigation mode in safety facility including the SBAS. The SBAS which is a system for aviation has been developed to meet the performance requirements of the APV-I level or higher where airplanes can take off and land. It is also necessary for the SBAS to perform performance evaluation and monitoring continuously whether accuracy, integrity, continuity, and availability required before and after system operation are satisfied (ICAO 2006, Kim et al. 2016). Availability, which is one of the SBAS system performance requirements, refers to a requirement of time ratio that meets the performance requirements in relation to accuracy, integrity, and continuity. It is also expressed conventionally as a ratio of time that the protection level (PL) is less than the alert limit (AL). In this paper, we investigated a possibility whether performance of APV-I level is satisfied from viewpoints of AL and horizontal and vertical PL calculated using data collected in 24 hours assuming that accuracy, integrity, and continuity in the SDCM system in South Korea satisfy the performance requirements of APV-I level.
In order to analyze availability of APV-I in the GPS/GLONASS Multi-Constellation SBAS according to user position in South Korea, mean values of Horizontal Protection Level (HPL) and vertical protection level calculated by applying SDCM differential correction and integrity information to observation data in the reference stations are indicated in Fig. 6 and summarized in Table 6 for each reference station. Fig. 7 shows a projection of availability with regard to integrity requirements (Horizontal 40 m / Vertical 50 m) of precision approach (PA) of APV-I airplane required by the ICAO to the Korean Peninsula map. Table 7 summarizes detailed results for each reference station. As the same as the analysis result on position errors, horizontal and vertical PLs were increased as a latitude moved from higher to lower latitude in South Korea, and APV-I availability was decreased accordingly. In particular, mean values of horizontal and vertical PLs at CHJU Reference Station were 42.5063 m and 59.0544 m, respectively, which were 2.5 to 2.7 times higher than 15.6189 m and 22.9821 m, which were values at CHUL Reference Station, verifying that the PL was rapidly increased as a latitude moved from higher to lower latitude. Furthermore, APV-I availabilities at CHUL and DONH Reference Stations in the horizontal and vertical directions showed 99.5139% / 99.3750% and 99.4444% / 99.6875%, respectively, which satisfied the required standards (99% ~ 99.999%) of the ICAO, indicating that services of APV-I level can be available to users located in reference stations of high latitude region. However, reference stations located in mid-to-low latitude regions satisfied the ICAO required standards only at the horizontal or vertical direction but not satisfied in both of the horizontal and vertical directions, which indicated that users in low-to-mid latitude regions may not use services of the APV-I level.
Fig. 6. Average protection level map of SDCM.
Fig. 7. APV-I availability map of SDCM.
Table 6. Mean value of horizontal and vertical protection level at each GNSS reference stations (2697 epochs / 2880 epochs).
Site name | Horizontal mean [m] | Vertical mean [m] |
CHUL INJE GANH HONC SOUL DONH INCH SUWN BOEN KUSN MUJU WOLS PUSN SONC GOJE JAHG CHUJ |
15.9329 16.1806 17.9175 16.2265 16.9967 15.6189 18.1438 18.1456 18.8148 21.7896 20.0387 22.7957 23.6311 24.3014 24.2641 27.1596 42.5063 |
23.5342 26.0831 26.9844 25.2107 26.3453 22.9821 28.0394 29.2376 28.1794 34.9991 29.8996 31.3524 30.9322 36.7476 32.6797 37.0806 59.0554 |
Table 7. Horizontal and vertical APV-I availability at each GNSS reference stations (2697 epochs / 2880 epochs).
Site name | Horizontal availability [%] | Vertical availability [%] |
CHUL INJE GANH HONC SOUL DONH INCH SUWN BOEN KUSN MUJU WOLS PUSN SONC GOJE JAHG CHUJ |
99.5139 99.6528 96.6319 99.5139 99.0278 99.4444 96.5278 96.7361 95.1736 89.7222 92.3264 90.1389 89.6528 87.7431 87.3611 82.7083 69.4097 |
99.3750 98.4375 95.6597 98.3333 98.1597 99.6875 95.1389 92.8472 93.8194 80.2083 89.9653 88.6806 89.5139 79.2708 86.4263 75.9375 58.5764 |
3.4 Differential Correction Analysis
In order to determine the reason for significant performance degradation of GPS/GLONASS Multi-Constellation SBAS as a latitude moved from higher to lower latitude in South Korea, performance was analyzed in terms of fast correction, long-term correction, and ionospheric correction.
Fig. 8 shows comparison of the number of tracked satellites at CHUL and CHJU reference stations and the number of satellites used in user positioning calculation. The mean numbers of tracked satellites at two reference stations were approximately 17 and 16 satellites, which showed no significant difference. However, the mean numbers of satellites used in position calculation were approximately 13 and 9 satellites, which showed a significant difference. In particular, the numbers of satellites used in position calculation showed the most difference between two reference stations as 16 and 6 satellites in 18:07 in September 24 2016. As presented in Table 8, the numbers of satellites that can generate fast correction and long-term correction had no significant difference between two reference stations but the numbers of satellites that can generate ionospheric correction were 17 and 6 satellites, which have a significant effect on determination of the number of satellites (16 and 6 satellites) used in position calculation in each reference station.
Fig. 8. Number of tracked and used satellites at CHUL and CHJU reference stations.
Table 8. Number of fast/long-term/ionospheric corrections at 2016/09/24 18:07.
Site name | Fast | Long-term | Ionospheric |
CHUL CHJU |
26 24 |
26 26 |
17 6 |
Table 9. Predefined world-wide IGP spacing – Band 0-8 (RTCA 2006).
Latitude degrees | Latitude spacing degrees | Longitude spacing degrees |
N85 N75 to N65 S55 to N55 S75 to S65 S85 |
10 10 5 10 10 |
90 10 5 10 90 (offset 40° East) |
Table 10. Predefined world-wide IGP spacing – Band 9-10 (RTCA 2006).
Latitude degrees | Latitude spacing degrees | Longitude spacing degrees |
N85 N75 to N65 N60 S60 S75 to S65 S85 |
10 5 5 5 5 10 |
30 10 5 5 10 30 (offset 10° East) |
Whether the ionospheric correction information is generated or not is determined by whether the IGPs around the ionospheric pierce point (IPP) provide a sufficient number of vertical ionospheric delay or not. Tables 9 and 10 present IGP latitude and longitude spacing for each band, which are specified in L1 SBAS MOPS. The SDCM employs seven bands (0, 4, 5, 6, 7, 8, and 9) out of a total of 11 bands and the Korean Peninsula is included in Band 7 which provide IGP ionospheric correction information in every . Fig. 9 shows the IGP where the SDCM provides ionospheric correction information at the time of 2016/9/24 18:07 and the IPP of visible satellites at CHUL and CHJU reference stations. The IPP of visible satellites at CHUL reference station was distributed mostly at latitude or higher whereas the IPP of visible satellites in CHJU reference station was distributed mostly over or lower. In addition, the SDCM did not provide ionospheric correction information to regions whose latitude was or lower in the Korean Peninsula. Due to this characteristic, only 17 satellites were able to be used in user positioning calculation because ionospheric correction information about three satellites out of 20 visible satellites cannot be generated at CHUL reference station, and ionospheric correction information about 12 satellites out of 18 visible satellites cannot be generated at CHJU reference station so only six satellites were used in user positioning calculation. From these results, the decrease in the number of satellites that can generate ionospheric correction in low latitude regions was verified as a main reason for performance degradation in the GPS/GLOMASS Multi-Constellation SBAS using SDCM.
Fig. 9. IGPs and IPPs distribution at 2016/9/24 18:07.
4. CONCLUSIONS
In this paper, we generated differential correction and integrity information with regard to GPS and GLONASS by receiving PRN 140 messages from the SDCM satellite of Russia, which has started a test service of SBAS in Russia, and analyzed performance in Multi-Constellation SBAS in the Korean Peninsula utilizing the above information. To do this, 17 reference stations running by the National Geographic Information Institute were selected, and characteristics of messages and accuracy and integrity characteristics received from 2016/9/24 00:00 and 2016/9/24 24:00 were verified thereby performing performance analysis.
The analysis result on correction performance of user positioning showed that horizontal and vertical errors tended to increase as users in South Korea were located in lower latitude. For example, errors calculated in the southernmost reference station amounted to twice of that in the northernmost reference station approximately. The PL also showed the same tendency. For example, the PL in the southernmost reference station amounted to 2.5 times of that in the northernmost reference station approximately. Accordingly, only CHUL and DONH reference stations, which were the northernmost reference stations out of 17 stations, satisfied APV-I availability in terms of PL and AL.
In order to determine the reason for performance degradation in Multi-Constellation SBAS in the SDCM as a latitude moved from higher to lower latitude, fast correction, long-term correction, and ionospheric correction were analyzed. The analysis result showed that the mean numbers of visible satellites were approximately 17 satellites in higher latitude and 16 satellites in lower latitude, which showed no significant difference. However, the mean numbers of satellites used in user positioning calculation were approximately 13 satellites in higher latitude and 9 satellites in lower latitude, which verified the decrease in the number of satellites used in user positioning calculation in lower latitude. To determine the reason for the decrease in the number of satellites, the number of satellites that can generate ionospheric correction with regard to 2016/9/24 18:07 where the number of satellites was the most different between the northernmost CHUL and the southernmost CHJU reference stations were analyzed. The analysis result showed that the number of satellites that can generate ionospheric correction was 17 satellites in CHUL reference station and 6 satellites in CHJU reference station due to the characteristics of the SDCM that did not provide ionospheric correction information with regard to IGP below latitude over the Korean Peninsula. Because most SDCM reference stations were distributed over higher latitudes than that of South Korea so that a distribution of IPPs that can be generated was concentrated in higher latitudes as well, which made difficult to generate vertical ionospheric delay of available IPP in South Korea. As such, a difference in the number of satellites that can generate ionospheric correction was verified as the main reason for the regional difference in performance of GPS/GLONASS Multi-Constellation SBAS using the SDCM. For future study, it is necessary to investigate possibility of improvements on performance degradation through interlink with other systems.
ACKNOWLEDGMENTS
This research was supported by Basic Science Research Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Science, ICT & Future Planning (No. 2015R1C1A1A02037779).
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