Opportunity for GNSS Reﬂectometry in Sensing the Regional Climate and Soil Moisture Instabilities in Myanmar

: The climate crisis is happening globally, and the consequent process has revealed soil evolution and meteorological interactions. The GNSS reﬂectometry (GNSS-R) technique recently encompassed sea surface monitoring, land changes, and snow sensing in addition to position, navigation, and timing. After the launch of NASA’s eight CYGNSS satellites, spaceborne soil moisture retrieval has become more opportune in a global and regional investigation. The research carried out by the CYGNSS DDM SNR with SMAP data to correlate diurnal mean soil moisture sensing was analyzed in the regional study of Myanmar, which is prone to climatic and weather conditions. The results showed that spaceborne GNSS-R soil moisture sensitivity was very useful during seasonal changes in regional observation. The DDM SNR surface reﬂectivity was strongly correlated with soil moisture according to surface temperature variations prepared from SMAP passive reﬂectometry. Sentinel SAR-1 data included the validation and veriﬁcation of ﬂood-prone areas affected by tropical storm surges or weather depressions in the monsoon season. The availability of surface reﬂectivity primarily relied on the surface roughness, surface temperature, and vegetation opacity for soil moisture retrieval. water availability, decreased river ﬂows, and inland ﬂooding and storm surges, which are signiﬁcant disaster impacts. In Myanmar, we observed the effects of climate change, which are increasingly in-consistent rainfall patterns, higher temperatures that reduce agricultural productivity in the central dry zone, sea-level rise, and soil salinization that erodes human settlements and infrastructure, driving many to seek alternative livelihoods, affecting the society and economy of Myanmar [21]. This research utilized spaceborne GNSS-R technology to analyze soil moisture sensitivity correlation between CYGNSS and SMAP in a regional study of Myanmar. Environmental impacts drive climate effect, and soil moisture changes were emphasized to study their correlations with the reﬂective signal, surface reﬂectivity, and soil moisture referenced data received by the SMAP passive reﬂectometry receiver. Figure 2 shows the different zonations according to the climatic condition of Myanmar.


Introduction
The GNSS technology's capability in positioning, navigation, and timing information is extracted from direct signals. In 1993, Martin Neira initiated the first bistatic radar remote sensing concept, the Passive Reflectometry and Interferometry System (PARIS) [1]. This system relies on the L-band of the Global Positioning System (GPS) signal for an ocean altimetry application. Ground, air, and spaceborne observations triggered by GNSS-R have progressed to detection of sea surface anomalies, snow, and land characteristics.
GNSS-R observatory satellites such as TDS-1 and the CYGNSS mission primarily serve sea surface observation purposes. By simultaneously receiving reflected signals, they can sense soil moisture, vegetation, snow, and environmental characteristics. After the launch of the eight CYGNSS satellites, the GNSS-R mission extended to retrieving soil moisture contents from the tropical regions. Despite the advances, spaceborne soil moisture sensing is still uncertain and preliminary because of the data limitation, collocation, and footprint heterogeneity [2]. A geophysical parameter such as surface roughness is challenging to define when dealing with coherent or incoherent surface, and it remains challenging to retrieve those uncertain parameters from spaceborne soil moisture observations [3].

Surface Roughness
Myanmar is bordered on the west and northwest by Bangla the northeast and east (the Golden Triangle region) by China, L principal drainage systems are the extensive Ayeyarwady-Chi which drains the west and north regions, and the Thanlwin Rive Tibet, drains the east part of the country. The topographic featur lower from north to south, from mountains and plateaus in th south. As shown in Figure 1, the main geographical features c highlands in the east, mountains and coastal areas in the west, a basin. Surface roughness, which is the h parameter, closely influen ability. SMAP radiometer sensors operate in the microwave Lsurface roughness is a key parameter compared to vegetation. In ness is less sensitive than vegetation biomass in microwave emis soil moisture variations. The vegetation canopy and seasonal wea significant factors in soil moisture sensing.
In the CYGNSS theoretical prediction of coherent reflectivity tion angle, rough topography contributed to reducing the spread taneously; surface roughness increases the spreading with mor because more specular reflection points contribute to the total sc GNSS bistatic radar receivers can quantify dielectric impacts more precisely, the spaceborne GNSS-R technique will be a pro soil moisture at relatively better spatial and temporal resolution. Surface roughness, which is the h parameter, closely influences soil moisture availability. SMAP radiometer sensors operate in the microwave L-band, and the effect of surface roughness is a key parameter compared to vegetation. In theory, surface roughness is less sensitive than vegetation biomass in microwave emission and backscatter to soil moisture variations. The vegetation canopy and seasonal weather conditions are also significant factors in soil moisture sensing.

Climatic Conditions
In the CYGNSS theoretical prediction of coherent reflectivity as a function of elevation angle, rough topography contributed to reducing the spreading of the DDM simultaneously; surface roughness increases the spreading with more significant roughness because more specular reflection points contribute to the total scattered field [10]. If the GNSS bistatic radar receivers can quantify dielectric impacts and surface roughness more precisely, the spaceborne GNSS-R technique will be a promising way to retrieve soil moisture at relatively better spatial and temporal resolution.

Climatic Conditions
Myanmar is the largest country in the Mekong region and the second-largest country in Southeast Asia. Myanmar has three seasons, with a tropical monsoon, hot, wet, and cold climate every four months. In recent decades, the weather and environmental crisis of Myanmar has increased remarkably, resulting in soil erosion and fertility loss, shortage in water availability, decreased river flows, and inland flooding and storm surges, which are significant disaster impacts.
In Myanmar, we observed the effects of climate change, which are increasingly inconsistent rainfall patterns, higher temperatures that reduce agricultural productivity in the central dry zone, sea-level rise, and soil salinization that erodes human settlements and infrastructure, driving many to seek alternative livelihoods, affecting the society and economy of Myanmar [21].
This research utilized spaceborne GNSS-R technology to analyze soil moisture sensitivity correlation between CYGNSS and SMAP in a regional study of Myanmar. Environmental impacts drive climate effect, and soil moisture changes were emphasized to study their correlations with the reflective signal, surface reflectivity, and soil moisture referenced data received by the SMAP passive reflectometry receiver. Figure 2 shows the different zonations according to the climatic condition of Myanmar.

REVIEW 4 of 1
In Myanmar, we observed the effects of climate change, which are increasingly in consistent rainfall patterns, higher temperatures that reduce agricultural productivity i the central dry zone, sea-level rise, and soil salinization that erodes human settlemen and infrastructure, driving many to seek alternative livelihoods, affecting the societ and economy of Myanmar [21].
This research utilized spaceborne GNSS-R technology to analyze soil moisture sen sitivity correlation between CYGNSS and SMAP in a regional study of Myanmar. Env ronmental impacts drive climate effect, and soil moisture changes were emphasized t study their correlations with the reflective signal, surface reflectivity, and soil moistur referenced data received by the SMAP passive reflectometry receiver. Figure 2 shows th different zonations according to the climatic condition of Myanmar.

CYGNSS L1 Data
The CYGNSS level 1 bistatic radar cross-section of the Earth's surface provided two-dimensional DDM grid of floating-point numbers. The CYGNSS satellite constella tion uses the onboard Delay Doppler Mapping Instrument (DDMI) and delay Dopple maps (DDMs) calibrated into received power and bistatic radar cross-sections (brcs Each of the CYGNSS satellites has a corresponding NetCDF (.nc format) data file pro vided each day. There are typically six-eight spacecrafts retrieving data under nomin conditions each day, but this can maximize to eight spacecrafts under particular circum stances. Higher than normal retrieval frequency is needed, for example, in tropical cy clone tracking cases. The Delay Doppler Map consists of the time delay function an Doppler frequency shift.
The GNSS-R-based soil moisture retrieval approach relies on an inversion of th DDM SNR bistatic radar equation to acquire the surface reflectivity. The surface refle tivity corrects the vegetation cover and surface roughness effects to obtain a Fresnel re flection coefficient. This coefficient is then related to soil moisture estimation by apply ing Fresnel reflection equations [22]:

CYGNSS L1 Data
The CYGNSS level 1 bistatic radar cross-section of the Earth's surface provided a two-dimensional DDM grid of floating-point numbers. The CYGNSS satellite constellation uses the onboard Delay Doppler Mapping Instrument (DDMI) and delay Doppler maps (DDMs) calibrated into received power and bistatic radar cross-sections (brcs). Each of the CYGNSS satellites has a corresponding NetCDF (.nc format) data file provided each day. There are typically six-eight spacecrafts retrieving data under nominal conditions each day, but this can maximize to eight spacecrafts under particular circumstances. Higher than normal retrieval frequency is needed, for example, in tropical cyclone tracking cases. The Delay Doppler Map consists of the time delay function and Doppler frequency shift.
The GNSS-R-based soil moisture retrieval approach relies on an inversion of the DDM SNR bistatic radar equation to acquire the surface reflectivity. The surface reflectivity corrects the vegetation cover and surface roughness effects to obtain a Fresnel reflection coefficient. This coefficient is then related to soil moisture estimation by applying Fresnel reflection equations [22]: where R lr is the Fresnel reflection coefficient and x(z) is the probability density function of the surface height z. The Fresnel reflection coefficient R lr can be expressed as linearly polarization modes: where R vv and R hh are Fresnel reflection coefficients for horizontal and vertical polarization. The bistatic received power is for the coherent component where specular reflections are thoroughly dominant and robust; the bistatic received power is for the coherent component according to the Z-V model [23].
where P coh RL. is the coherently received SNR power, R and L stand for the right-hand circularly polarized (RHCP) GNSS transmit antenna and the LHCP downward-looking GNSS-R antenna, λ is the free space wavelength, P t is the transmitted GNSS signals peak power, G t is the gain of the transmitter antenna, G r is the gain of the receiver antenna, r st is the distance between the GNSS transmitter and the specular reflection point, r sr is the distance between the GNSS-R receiver and the specular reflection point, and ΓRL(θ i ) denotes the specular reflectivity at a local incidence angle of θ i . λ is the GPS wavelength (19 cm) and Γ rl is the reflectivity of the surface. The reflectivity of the surface Γ rl is affected by near-surface soil moisture, as soil moisture affects the surface dielectric constant, which affects surface reflectivity. Surface reflectivity is affected by soil surface roughness, small surface height irregularities on the scale of λ. Since this analysis was only concerned with changes in surface reflectivity, we omitted the '4π' and 'λ 2 ' terms. Solving for reflectivity and making an additional correction for background noise (N), the surface reflectivity of P r,eff (in dB) [3] is then: P r,eff = 10 log Γ rl ∝ 10 log P c rl − 10 log N − 10 log G r − 10 logG t − 10 logP t r + 20 log(R ts + R sr ), The CYGNSS L1 DDM SNR was prepared for the data used. Data were collected in May, August, and October 2019 from the data product site, the Physical Oceanography Distributed Active Archive Centre (PODAAC), freely available at https://podaac.jpl.nasa. gov/dataset/CYGNSS_L1_V2.1, accessed on 9 April 2020 [24]. Figure 2a shows CYGNSS L1 data availability and Figure 2b shows the DDM SNR soil moisture contents prepared from the August 2019 monthly data. For Figure 3, we prepared DDM SNR and surface reflectivity P r,eff . We collected data for May, August, and October 2019 to illustrate seasonal changes in the soil moisture study. We used the Equal-Area Scalable Earth (EASE 2.0) 9 km × 9 km grid cell in a global cylindrical projection with the same projection of SMAP. The EASE-Grid is based on a philosophy of digital mapping and gridding definitions developed at the University of Colorado at Boulder. It was intended to be a versatile scheme for global-scale gridded data users, especially those who use remotely sensed data, although it has been gaining popularity as a common gridding format for data from other sources as well [25]. Surface reflectivity P r,eff was higher in the delta and lower part of Myanmar in August because the surface was almost wet. In August 2019, the region had flash floods and triggering land instabilities, owing to tropical cyclones and weather depressions, particularly in the lower part of the country [26]. Most parts of the country have moist soil, and the surface temperature decreased because of the increasing surface reflectivity. Myanmar has a tropical monsoon climate, where 75-90% of the annual rainfall occurs in the monsoon season from June to September [27]. While monsoonal rains are essential for agriculture, supplying water for irrigation and alluvial sediments, these events can frequently lead to severe flooding, significantly impacting people, homes, and ecosystems.

Soil Moisture
The SMAP L3 Passive Reflectometry product was a daily global composite containing gridded data from 6:00 a.m. (descending) and 6:00 p.m. (ascending). SMAP passive radiometer-based soil moisture retrieval, ancillary data, and quality assessment flags on the global 9 km Equal-Area Scalable Earth (EASE 2.0) grid designed by the National Snow and Ice Data Center (NSIDC) [28]. The data were also collected for May, August, and October Climate 2021, 9, 175 6 of 17 2019 in the Myanmar regional study. SMAP L3 data are available on the NSIDC site and can be freely downloaded at https://nsidc.org/data/SPL3SMP_E/versions/3, accessed on 9 April 2020 [29].
August 2019 monthly data. For Figure 3, we prepared DDM SNR and surface reflectivity P , . We collected data for May, August, and October 2019 to illustrate seasonal changes in the soil moisture study. We used the Equal-Area Scalable Earth (EASE 2.0) 9 km × 9 km grid cell in a global cylindrical projection with the same projection of SMAP. The EASE-Grid is based on a philosophy of digital mapping and gridding definitions developed at the University of Colorado at Boulder. It was intended to be a versatile scheme for global-scale gridded data users, especially those who use remotely sensed data, although it has been gaining popularity as a common gridding format for data from other sources as well [25]. Surface reflectivity P , was higher in the delta and lower part of Myanmar in August because the surface was almost wet. In August 2019, the region had flash floods and triggering land instabilities, owing to tropical cyclones and weather depressions, particularly in the lower part of the country [26]. Most parts of the country have moist soil, and the surface temperature decreased because of the increasing surface reflectivity. Myanmar has a tropical monsoon climate, where 75-90% of the annual rainfall occurs in the monsoon season from June to September [27]. While monsoonal rains are essential for agriculture, supplying water for irrigation and alluvial sediments, these events can frequently lead to severe flooding, significantly impacting people, homes, and ecosystems.

Soil Moisture
The SMAP L3 Passive Reflectometry product was a daily global composite containing gridded data from 6:00 a.m. (descending) and 6:00 p.m. (ascending). SMAP passive radiometer-based soil moisture retrieval, ancillary data, and quality assessment flags on the global 9 km Equal-Area Scalable Earth (EASE 2.0) grid designed by the National Snow and Ice Data Center (NSIDC) [28]. The data were also collected for May, August, and October 2019 in the Myanmar regional study. SMAP L3 data are available on the NSIDC site and can be freely downloaded at https://nsidc.org/data/SPL3SMP_E/versions/3 [29].
SMAP used the L-band radiometer as a highly sensitive indicator of surface soil moisture. The radiometric brightness temperature represents emission determined SMAP used the L-band radiometer as a highly sensitive indicator of surface soil moisture. The radiometric brightness temperature represents emission determined mainly by the physical temperature and dielectric constant of the existing scene (soil moisture in the top~5 cm). The sensitivity to soil moisture decreased significantly for surfaces with a vegetation water content (VWC) above~5 kg m -2 . The SMAP radiometer instrument provided brightness temperature measurements with better than 1.3 K uncertainty (1-sigma), given that the brightness temperature difference across the dynamic range of surface soil moisture can be many tens of K (up to~70 K and higher) [30]. Table 1 shows the SMAP Enhanced L3 Radiometer system overview of global daily 9 km EASE gridded soil moisture L3 data. SMAP-R received GPS L2 C-band (frequency = 1227.45 MHz, wavelength = 24.42 cm). The bistatic radar cross-section, which was the same equation used in CYGNSS calibrations but slightly modified to the SMAP-R characteristics, for the coherent assumptions [10] is as follows: where σ 0coh is the bistatic radar cross-section of coherence surface, P incoh , P coh is the power received from the incoherence and coherence surfaces, P tx is the GPS transmitted power, G tx is the GPS transmitter antenna gain, λ is the GPS signal wavelength (at GPS-L2C is 24.42 cm), R rx sp is the distance from the receiver to a particular surface pixel, R tx sp is distance from the transmitter to a particular surface pixel, T i is the integration time, and B (τ, f d ) denotes the filtered scattering surfaces. Coherent scattering is a surface dominated by any area containing mirror-like surfaces such as rivers, lakes, wetlands, flooded surfaces, or sea ice surfaces [10]. The Irrawaddy River begins in the upper highland area of Myanmar and flows to the lower parts of the delta area, then to the Adman Sea. Thus, both Myanmar and other parts of the Mekong region have the same experiences with flash water extending, flooding caused by storm surges, and other meteorological problems [31]. The following imagery was prepared with the enhanced soil moisture data from the SMAP L3 radiometer.
In Figure 4, the area is almost dry and has less soil moisture owing to the evapotranspiration process in May. In August, the regions were almost wet, and the soil was saturated in the monsoon season, then returned to a decrease at the beginning of the winter season in October.
SMAP-R received GPS L2 C-band (frequency = 1227.45 MHz, wavelength = 24.42 cm). The bistatic radar cross-section, which was the same equation used in CYGNSS calibrations but slightly modified to the SMAP-R characteristics, for the coherent assumptions [10] is as follows: where σ is the bistatic radar cross-section of coherence surface, P , P is the power received from the incoherence and coherence surfaces, P is the GPS transmitted power, G is the GPS transmitter antenna gain, λ is the GPS signal wavelength (at GPS-L2C is 24.42 cm), R is the distance from the receiver to a particular surface pixel, R is distance from the transmitter to a particular surface pixel, T is the integration time, and B (τ, f ) denotes the filtered scattering surfaces.
Coherent scattering is a surface dominated by any area containing mirror-like surfaces such as rivers, lakes, wetlands, flooded surfaces, or sea ice surfaces [10]. The Irrawaddy River begins in the upper highland area of Myanmar and flows to the lower parts of the delta area, then to the Adman Sea. Thus, both Myanmar and other parts of the Mekong region have the same experiences with flash water extending, flooding caused by storm surges, and other meteorological problems [31]. The following imagery was prepared with the enhanced soil moisture data from the SMAP L3 radiometer.
In Figure 4, the area is almost dry and has less soil moisture owing to the evapotranspiration process in May. In August, the regions were almost wet, and the soil was saturated in the monsoon season, then returned to a decrease at the beginning of the winter season in October.

Surface Temperature
SMAP L3 surface temperature was obtained from L2 SM_P algorithms with ancillary datasets of AVHRR NDVI. The sufficient soil surface temperature was at 9 km grid

Surface Temperature
SMAP L3 surface temperature was obtained from L2 SM_P algorithms with ancillary datasets of AVHRR NDVI. The sufficient soil surface temperature was at 9 km grid spacing for the global daily composite data. According to surface temperature, the algorithms based on SMAP identified emissivity of the soil surface from brightness temperature (TB). This emissivity was used to sense soil moisture content. Figure 5 shows surface temperature monthly data prepared for May, August, and October 2019 in the Myanmar region. May was the hot and dry season in this region. The surface temperature was high owing to increased surface emissivity and brightness temperature (TB). The surface temperature dropped in the wet season of August and rose slightly again in October, turning into the winter (cold). In August, the country had moist soil and the surface temperature decreased rithms based on SMAP identified emissivity of the soil surface from brightness temperature (TB). This emissivity was used to sense soil moisture content. Figure 5 shows surface temperature monthly data prepared for May, August, and October 2019 in the Myanmar region. May was the hot and dry season in this region. The surface temperature was high owing to increased surface emissivity and brightness temperature (TB). The surface temperature dropped in the wet season of August and rose slightly again in October, turning into the winter (cold). In August, the country had moist soil and the surface temperature decreased because of the surface reflectivity. The surface emissivity decreased, and the brightness temperature (TB) dropped.

Vegetation Opacity
According to scattering related the Wang's "tau omega" model (where is the optical thickness and the single scattering albedo of the vegetation canopy) [32], a daily global composite of the estimated vegetation opacity in the 9 km grid used the same "tau" parameter normalized by the cosine of the incidence angle: where b is a landcover-based parameter described in the SMAP Level 2/3 Passive Soil Moisture Product ATBD, VWC is vegetation water content in kg/m 2 derived from NDVI climatology, and θ is the incidence angle (= 40°) for SMAP. According to the tau omega model, accounting for vegetation effects is essential for soil moisture retrieval. The presence of vegetation attenuates the soil emission. In addition, SMAP L3 reflectometry received soil moisture information influenced by brightness temperature and vegetation opacity [8].
If soil moisture content increased, surface brightness temperature increased accordingly. Surface roughness (h) was high, so soil moisture decreased because of the combined and incoherent scattering effect. Vegetation opacity was directly related to its water content, and it became higher in the monsoon season (wet) than in the dry and cold season [33]. Figure 6 shows that SMAP Radiometer vegetation opacity maps were prepared in May, August, and October 2019.

Vegetation Opacity
According to scattering related the Wang's "tau omega" model (where τ is the optical thickness and ω the single scattering albedo of the vegetation canopy) [32], a daily global composite of the estimated vegetation opacity in the 9 km grid used the same "tau" parameter normalized by the cosine of the incidence angle: where b is a landcover-based parameter described in the SMAP Level 2/3 Passive Soil Moisture Product ATBD, VWC is vegetation water content in kg/m 2 derived from NDVI climatology, and θ is the incidence angle (= 40 • ) for SMAP. According to the tau omega model, accounting for vegetation effects is essential for soil moisture retrieval. The presence of vegetation attenuates the soil emission. In addition, SMAP L3 reflectometry received soil moisture information influenced by brightness temperature and vegetation opacity [8].
If soil moisture content increased, surface brightness temperature increased accordingly. Surface roughness (h) was high, so soil moisture decreased because of the combined and incoherent scattering effect. Vegetation opacity was directly related to its water content, and it became higher in the monsoon season (wet) than in the dry and cold season [33]. Figure 6 shows that SMAP Radiometer vegetation opacity maps were prepared in May, August, and October 2019.

Processing Flows
In this research, we applied a GNSS-R bistatic radar cross-section technique based on the Z-V Model with the Cyclone Global Navigation Satellite System (CYGNSS) and SMAP observation dataset based on the tau omega (τ − ω) scattering model. Instead of a single instrument, CYGNSS comprises eight GNSS-R satellites in low Earth orbit around the tropical region. For this reason, we used the proposed technique with CYGNSS data because it provided more observation data and had a significant opportunity for soil moisture observation in the regional study.

Processing Flows
In this research, we applied a GNSS-R bistatic radar cross-section technique based on the Z-V Model with the Cyclone Global Navigation Satellite System (CYGNSS) and SMAP observation dataset based on the tau omega (τ − ω) scattering model. Instead of a single instrument, CYGNSS comprises eight GNSS-R satellites in low Earth orbit around the tropical region. For this reason, we used the proposed technique with CYGNSS data because it provided more observation data and had a significant opportunity for soil moisture observation in the regional study.
The theoretical footprint of a reflected CYGNSS signal is ~0.5 × 0.5 km (spatial resolution) in the case of a smooth surface (coherence) and a receiver at the altitude of CYGNSS, with slight dependence on the incidence angle [34]. The mean temporal resolution of CYGNSS is less than 12 h. SMAP reflectometry data were received at 36 km × 36 km (spatial) every day (temporal). In this research, we used the EASE 2.0 grid on the global 9 km × 9 km both for space and time collocation reference. For each grid cell, we calculated the daily average of the surface reflectivity ΔP , concerning the mean value for that grid cell for the entire period of interest (May, August, and October 2019). We calculated average mean soil moisture ΔSM in the same way: differences from the mean SM value for each grid cell in the seasonal observation period. We then compared the surface reflectivity ΔP , to the mean soil moisture ΔSM for each grid cell and calculated the correlation coefficient. Figure 7 data processing flows diagram shows that spaceborne CYGNSS L1 initially received monthly data from May, August, and October 2019. Reflected received SNR power was extracted from the L1 radar cross-section of the Earth's surface products from all eight satellites of the CYGNSS mission. The received signal power was delivered as a function of the time delay (sampled according to the GNSS signal bandwidth) and Doppler frequency owing to platform and Earth motion (sampled according to the coherent integration time); the resulting Delay Doppler Map (DDM) represents the main observable.
Then, DDM SNR converted to the surface reflectivity according to the bistatic scattering Z-V model. In the second step, we prepared soil moisture data and surface temperature, surface roughness, and vegetation opacity, which influenced the received signals of SMAP L3-enhanced radiometric data. Thirdly, the soil moisture retrieval process was carried out by CYGNSS DDM SNR and surface reflectivity was correlated with SMAP SM data. Finally, Sentinel SAR-1 data were validated to the land instability sens- The theoretical footprint of a reflected CYGNSS signal is~0.5 × 0.5 km (spatial resolution) in the case of a smooth surface (coherence) and a receiver at the altitude of CYGNSS, with slight dependence on the incidence angle [34]. The mean temporal resolution of CYGNSS is less than 12 h. SMAP reflectometry data were received at 36 km × 36 km (spatial) every day (temporal). In this research, we used the EASE 2.0 grid on the global 9 km × 9 km both for space and time collocation reference. For each grid cell, we calculated the daily average of the surface reflectivity ∆P r,eff concerning the mean value for that grid cell for the entire period of interest (May, August, and October 2019). We calculated average mean soil moisture ∆SM in the same way: differences from the mean SM value for each grid cell in the seasonal observation period. We then compared the surface reflectivity ∆P r,eff to the mean soil moisture ∆SM for each grid cell and calculated the correlation coefficient. Figure 7 data processing flows diagram shows that spaceborne CYGNSS L1 initially received monthly data from May, August, and October 2019. Reflected received SNR power was extracted from the L1 radar cross-section of the Earth's surface products from all eight satellites of the CYGNSS mission. The received signal power was delivered as a function of the time delay (sampled according to the GNSS signal bandwidth) and Doppler frequency owing to platform and Earth motion (sampled according to the coherent integration time); the resulting Delay Doppler Map (DDM) represents the main observable.

Results
This section discusses the correlation between CYGNSS DDM SNR and SMAP SM regarding the surface reflectivity response to soil moisture for diurnal changes in three Then, DDM SNR converted to the surface reflectivity according to the bistatic scattering Z-V model. In the second step, we prepared soil moisture data and surface temperature, surface roughness, and vegetation opacity, which influenced the received signals of SMAP L3-enhanced radiometric data. Thirdly, the soil moisture retrieval process was carried out by CYGNSS DDM SNR and surface reflectivity was correlated with SMAP SM data. Finally, Sentinel SAR-1 data were validated to the land instability sensing for flood extended into monsoon season.

Results
This section discusses the correlation between CYGNSS DDM SNR and SMAP SM regarding the surface reflectivity response to soil moisture for diurnal changes in three different seasons of Myanmar.

Soil Moisture Correlation of CYGNSS DDM SNR and SMAP SM
In orbit, CYGNSS microsatellite observatories receive direct and reflected signals from GPS (Global Positioning System) satellites. The direct signal pinpoints CYGNSS observatory positions, velocity, and timing information, while the reflected signals respond to terrain characteristics [35]. Figure 8 shows that the CYGNSS receiver received reflected peak DDM SNR signal monthly in May, August, and October for seasonal changes (hot, wet, and cold) analysis. SMAP passive radiometer received monthly soil moisture data in the same collocation and time referenced. In Figure 9, Myanmar has three different seasonal changes, and the hot season e  The DDM SNR received signal was sensitive to change according to correlation values. Soil moisture coefficient values were r = 0.2260 for May, r = 0.534 for August, and r = 0.418 for October. Significant changes and soil moisture retrieval were high in August 2019 owing to several weather conditions, i.e., flash floods from heavy rain and storm surges triggered in lower parts of Myanmar [36,37]. DDM SNR changed very significantly from dry to wet season. In the following Figure 8, the monthly mean soil moisture graph reflects that the obtained DDM SNR, and SMAP correlation was high and consistent in August. The surface was wet and greatly depended on other geophysical parameters such as vegetation canopy, brightness temperature, the dielectric constant of medium and terrain conditions, and scattering conditions for the coherent and incoherent phenomenon [11].
In Figure 9, Myanmar has three different seasonal changes, and the hot season ended in May. August was a wet (rainy) season. In October, the weather condition was temperate almost everywhere in the country. Thus, CYGNSS DDM SNR and SMAP were very sensitive to soil moisture over 3 months of different daily changes. the GNSS-R DDM SNR and soil moisture correlation was lower in the dry season, was higher in the wet season and saw a slight drop in the winter season. In August, the mean soil moisture value was highest at 0.40 cm 3 /cm 3 , which was a consistent and good agreement between CYGNSS and SMAP for spaceborne soil moisture sensing. In Figure 9, Myanmar has three different sea ed in May. August was a wet (rainy) season. I temperate almost everywhere in the country. T were very sensitive to soil moisture over 3 month R DDM SNR and soil moisture correlation was the wet season and saw a slight drop in the w moisture value was highest at 0.40 cm 3 /cm 3 , whic between CYGNSS and SMAP for spaceborne soil  Figure 10 shows CYGNSS surface reflectivi ture data received by the SMAP L3 passive senso  Figure 10 shows CYGNSS surface reflectivity and correlates it with the soil moisture data received by the SMAP L3 passive sensor. In the delta and lower part of Myanmar, severe flood conditions occurred from July to October owing to weather depression, causing a disaster crisis [38].

Soil Moisture Correlation of CYGNSS Surface Reflectivity and SMAP SM
Correlation coefficient values of DDM SNR and its surface reflectivity were higher in August. CYGNSS surface reflectivity and SMAP SM correlation values were r = 0.2262 for May, r = 0.560 for August, and r = 0.461 for October. Myanmar had several disaster crises, such as flash floods due to weather depression. Flash floods caused landslides in some parts, and land instability occurred in the lower parts of Myanmar [39]. Monthly mean soil moisture was higher in August because the surface was almost always wet.
Climate 2021, 9, x FOR PEER REVIEW mar, severe flood conditions occurred from July to October owing to weather sion, causing a disaster crisis [38]. Correlation coefficient values of DDM SNR and its surface reflectivity were in August. CYGNSS surface reflectivity and SMAP SM correlation values were r for May, r = 0.560 for August, and r = 0.461 for October. Myanmar had several crises, such as flash floods due to weather depression. Flash floods caused lands some parts, and land instability occurred in the lower parts of Myanmar [39]. M mean soil moisture was higher in August because the surface was almost always The correlation calculation was completed using EASE 2.0 gridded to a 9 km scale for CYGNSS and SMAP for the regional SM analysis. The correlation res very different during the seasonal changes of May and August 2019. This meant correlation (r = 0.560) between surface reflectivity Pr,eff and SMAP SM in May a gust. Figure 11 shows daily mean soil moisture changes from May, August, and 2019. As stated, earlier, the correlation coefficient value was higher in August meant daily soil moisture was significantly increased compared to other mont anmar had frequent meteorological depressions and tropical cyclones in the m season until October. As a result, the surface area was more saturated, which inf soil moisture content. The correlation calculation was completed using EASE 2.0 gridded to a 9 km × 9 km scale for CYGNSS and SMAP for the regional SM analysis. The correlation result was very different during the seasonal changes of May and August 2019. This meant a strong correlation (r = 0.560) between surface reflectivity P r,eff and SMAP SM in May and August. Figure 11 shows daily mean soil moisture changes from May, August, and October 2019. As stated, earlier, the correlation coefficient value was higher in August, which meant daily soil moisture was significantly increased compared to other months. Myanmar had frequent meteorological depressions and tropical cyclones in the monsoon season until October. As a result, the surface area was more saturated, which influenced soil moisture content.
The research compared Chew et al.'s (2018) prediction for regional soil moisture observation on the medium vegetated area. However, they counted soil moisture variation from the surface reflectivity of CYGNSS DDM SNR data and SMAP; the soil moisture retrieving value was still low and not high enough to provide for heavily vegetated and rough terrain [3]. This research added the diurnal study with seasonal changes in soil moisture correlation to the regional analysis from NASA spaceborne observations of the CYGNSS and SMAP missions. There were consistent and linear relationships between CYGNSS observations and SMAP SM retrievals, which were most easily quantified in the range where SM was highest.
9, x FOR PEER REVIEW Figure 11. CYGNSS surface reflectivity and SMAP me The research compared Chew et al.'s (2018) servation on the medium vegetated area. Howev from the surface reflectivity of CYGNSS DDM SN trieving value was still low and not high enoug rough terrain [3]. This research added the diur moisture correlation to the regional analysis from CYGNSS and SMAP missions. There were con CYGNSS observations and SMAP SM retrieval the range where SM was highest.

Data Validation and Verification with SENTINE
ESA, the Copernicus program, is being dev lation of two polar-orbiting satellites. Sentinelband synthetic aperture radar imaging, enablin the weather, day and night. Sentinel-1, a constel band SAR, provides backscatter (σ∘) observation

Data Validation and Verification with SENTINEL SAR-1
ESA, the Copernicus program, is being developed to launch the Sentinel-1 constellation of two polar-orbiting satellites. Sentinel-1 satellites operate all the time with C-band synthetic aperture radar imaging, enabling them to receive imagery regardless of the weather, day and night. Sentinel-1, a constellation of two (A and B) satellites with C-band SAR, provides backscatter (σ•) observations at 5 × 20 m 2 resolution. Synthetic Aperture Radar (SAR) can penetrate clouds, regardless of weather conditions, and has day and night capability; many studies have focused on monitoring efficient and high-quality methods for surface water mapping.
Depending on the region, the SAR-based flood detection algorithms can detect floods with an accuracy ranging from 80 to 95%. Uddin et al. (2019) determined that Sentinel-1 SAR observation data have great potential in producing flood information with high accuracy and high spatial resolution over a 6-day interval, despite the predominance of severe weather conditions during flooding time in Bangladesh [40].
The Sentinel SAR-1 (A and B) constellation offers a 6-day exact repeat cycle. However, a single SENTINEL-1 satellite can trap the entire world once every 12 days. Accordingly, Sentinel SAR data cannot provide high temporal resolution for continuous flood detection purposes. Because of the dynamic nature of floods or flash floods, SAR images are not used operationally during floods [41]. Thus, no single standard dataset can satisfy all the conditions that fulfill the temporal evolution of flood inundation extent with reasonable accuracy [42].
In Sentinel SAR-1 imagery, each pixel value is directly related to the backscatter energy from the surface and terrain conditions. The Copernicus Sentinel SAR-1 images in Figure 12 were obtained after correcting the radiometric and geometric calibrations. In Figure 12b

Discussions
In this analysis, CYGNSS reflectometry SNR data correlated with SMAP reflectometry soil moisture data. Moreover, CYGNSS reflectivity was compared to SMAP SM for monthly and daily observations in the study area. Image interpretation presented surface temperature, vegetation opacity, and surface roughness prepared from SMAP. Flood and land information analysis extracted data for validation and verification processes from Microwave Sentinel SAR-1. In the following Table 2, we compared correlation coefficient results of CYGNSS and SMAP SM. A good agreement was observed between CYGNSS reflectometry and referenced soil moisture measurements from SMAP. The table shows the soil moisture correlation coefficient values for DDM SNR, and the surface reflectivity ΔP , was the highest in August (r = 0.534 and r = 0.560) and lowest in May (r = 0.2260 and r = 0.2262). It was expected that the region would be almost wet in August. The wet surface produced a stronger reflection than dry surfaces. The surface reflectivity ΔP , was mainly influenced by topography, surface water, and land cover, not only SM [6,43]. Moist surfaces have higher dielectric constants, which results in higher reflectivity than drier surfaces [13,44].
The soil moisture correlation results were generally consistent based on ancillary data interpreted from geophysical key parameters. CYGNSS received DDM SNR soil moisture sensitivity data on seasonal weather changes, land instabilities from flood intrusion, and tropical storm surge in the study area. The study demonstrated soil moisture from the CYGNSS mission on a regional scale for Myanmar, along with ancillary information about the overlying vegetation opacity and the surface roughness from SMAP passive reflectometry data. These results showed that the influences of other geophysical parameters, such as vegetation opacity, surface temperature, and surface roughness, were potential key issues for spaceborne GNSS-R sensing over land.

Discussions
In this analysis, CYGNSS reflectometry SNR data correlated with SMAP reflectometry soil moisture data. Moreover, CYGNSS reflectivity was compared to SMAP SM for monthly and daily observations in the study area. Image interpretation presented surface temperature, vegetation opacity, and surface roughness prepared from SMAP. Flood and land information analysis extracted data for validation and verification processes from Microwave Sentinel SAR-1. In the following Table 2, we compared correlation coefficient results of CYGNSS and SMAP SM. A good agreement was observed between CYGNSS reflectometry and referenced soil moisture measurements from SMAP. The table shows the soil moisture correlation coefficient values for DDM SNR, and the surface reflectivity ∆P r,eff was the highest in August (r = 0.534 and r = 0.560) and lowest in May (r = 0.2260 and r = 0.2262). It was expected that the region would be almost wet in August. The wet surface produced a stronger reflection than dry surfaces. The surface reflectivity ∆P r,eff was mainly influenced by topography, surface water, and land cover, not only SM [6,43]. Moist surfaces have higher dielectric constants, which results in higher reflectivity than drier surfaces [13,44].
The soil moisture correlation results were generally consistent based on ancillary data interpreted from geophysical key parameters. CYGNSS received DDM SNR soil moisture sensitivity data on seasonal weather changes, land instabilities from flood intrusion, and tropical storm surge in the study area. The study demonstrated soil moisture from the CYGNSS mission on a regional scale for Myanmar, along with ancillary information about the overlying vegetation opacity and the surface roughness from SMAP passive reflectometry data. These results showed that the influences of other geophysical parameters, such as vegetation opacity, surface temperature, and surface roughness, were potential key issues for spaceborne GNSS-R sensing over land.

Conclusions
Satellite Navigation Technology principally pioneered its services to detect position, navigation, and time. After enhancement with GNSS reflectometry, it now helps the public in disaster mitigation, climate, hydro-meteorology forecasting, land information, and sea surface anomalies observation. Remote sensing reflectometry has emerged to detect abrupt changes in sea surface conditions, wind speed, and direction due to cyclone intrusions. GNSS reflectometry can also aid by using sea and ocean data and contemporarily apply them to land applications such as soil moisture, snow, time-series weather forecasting, and climatic observation. Up to the present, spaceborne observation for soil moisture sensing has been an uncertain process. The system, parameters, retrieving model, and algorithms remain a challenge to better understanding soil moisture observation. In addition, other geophysical parameters, such as surface roughness, vegetation biomass, and dielectric, are very complex issues.
The spaceborne NASA CYGNSS mission was initially intended to track tropical cyclones and well-observed land-based sensing. For this analysis, GNSS-R techniques retrieved several models such as the Z-V model of the bistatic cross-section, the tau omega (τω) scattering model, and the surface reflectivity model geophysical parameters. Although GNSS-R technology still has technical challenges, the eight CYGNSS satellites have improved system capabilities, and spatial and temporal resolution.
This research included a comprehensive analysis, including geophysical parameters such as reflectivity and surface roughness upon different incidence angles, vegetation optical depth (VOD), brightness temperature variations with coherent and incoherent scattering, and accurate information to deliver regional climatic and environmental concerns. A dielectric constant and soil moisture observation proved the data from CYGNSS and SMAP.
Finally, our research goal was to investigate spaceborne GNSS-R soil moisture observation and its influence by geophysical parameters. For a better understanding, soil-moistureretrieving algorithms and all-inclusive models will need to guide uncertain spaceborne soil moisture sensing presenting challenging technical issues. New GNSS-R spaceborne missions will also be comparatively challenging to an existing system. As a result, multidisciplinary science can meet human needs in one way or another to sustain the planet inhabited by human beings.