seasonal polarimetric measurements of soil moisture using ... · prn#30 bao tower prn#18...
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21-25 July 2003IGARSS’03 Toulouse, France
Seasonal Polarimetric Measurements of Soil Moisture
Using Tower-Based GPS Bistatic Radar
V. Zavorotny1, D. Masters2, A. Gasiewski1, B. Bartram1, S. Katzberg3, P. Axelrad2, and R. Zamora1
1NOAA Environmental Technology Laboratory, Boulder CO, 803052CCAR/University of Colorado at Boulder, CB431, Boulder CO, 80309
3NASA Langley Research Center, Code 328, Hampton VA, 23681
21-25 July 2003IGARSS’03 Toulouse, France
Outline
• The results of GPS surface reflection measurements observed from the 300-m tall ETL Boulder Atmospheric Observatory (BAO) tower are described.
• In this experiment the first seasonal measurements of bare soil moisture from a stationary location using bistatic reflection were performed. Several receiving antennas offering various gain and polarization sensitivities were used.
• By observing from a fixed tower over low grass the roughness of the reflecting area remains constant, hence variations in the signal are uniquely related to changes in the dielectric permittivity, and therefore, to soil moisture.
• Seasonal retrievals of soil-moisture content from multi-polarization GPS reflection data is presented and compared with in situ soil moisture measurements.
21-25 July 2003IGARSS’03 Toulouse, France
Introduction
• Knowledge of soil moisture (SM) over wide areas is essential formany applications, e.g., crop yield expectation, prediction of potential flood hazards, air quality, and local weather forecasts.
• Remote sensing methods such as passive radiometers and active radar sensors are considered suitable for SM mapping because conventional in situ soil moisture measurement techniques are both localized and expensive.
• Attributes of using GPS signals of opportunity as a means of active airborne bistatic sensing of SM include:
The omnipresence of GPS signals during all weather conditions,The low cost of GPS receiver technology compared to alternative remote sensing systems,The civilian signal frequency of 1.575 GHz is also nearly optimal for SM sensing.
21-25 July 2003IGARSS’03 Toulouse, France
Geometry of the BAO Tower GPS Reflection Experiment
One mile
BAO Tower
21-25 July 2003IGARSS’03 Toulouse, France
Boulder Atmospheric Observatory Tower
C A modified GPS navigation receiver was mounted on top of the 300-meter NOAA ETL Boulder Atmospheric Observatory (BAO) tower near Erie, CO (40E03N00.1ON, 105E00N13.8OW).
• The stationary tower observation geometry facilitated seasonal measurements of GPS reflections from the same area of land, thus excluding signal variability due to changing roughness and vegetation cover scenes.
21-25 July 2003IGARSS’03 Toulouse, France
Instrumentation
Low-Gain Hemispherical Antenna
Delay-Mapping ReceiverThe receiver, provided by the NASA Langley Research Center, tracked the direct line of sight satellites using a low-gain zenith-oriented right hand circularly polarized (RHCP) antenna and recorded the cross correlation function of the reflected signals using an alternating series of surface-oriented antennas.
21-25 July 2003IGARSS’03 Toulouse, France
Instrumentation (cont’d)The surface-oriented antennas consist of: (a) a low-gain hemispherical left hand circularly polarized (LHCP) antenna;(b) four endfire high gain (~ 12 dB) V, H, LHCP, and RHCP antennas
High gain antennas:RHCPLHCPVertical Pol.Horizontal Pol.
21-25 July 2003IGARSS’03 Toulouse, France
Instrumentation (cont’d)
The orientation of all surface-oriented antennas was 35Efrom nadir for the incident angle, and 245E for the azimuthal angle.
Low-gain zenith-oriented antenna (RHCP)
Low-gain surface-oriented antenna (LHCP)
High-gain surface-oriented antennas
21-25 July 2003IGARSS’03 Toulouse, France
Instrumentation (cont’d)
RHCPH-pol
V-polLHCP
Weatherproof receiver enclosure
21-25 July 2003IGARSS’03 Toulouse, France
Measurement Technique
• Each GPS satellite signal is coded with a unique pseudorandom noise (PRN) code designed to produce an autocorrelation functionconfined within "1 code bit transition, or code “chip.”
• Reflection of this incident signal from a rough dielectric surface will produce multiple delayed signals having amplitudes proportional to the power reflection coefficient at each specular point.
• The output of a typical GPS reflection receiver is a cross correlation between a receiver-generated replica of the PRN code and the PRN code of the reflected signal.
• The cross correlation function is generally both wider and lowerthan the autocorrelation of the direct signal, and carries information about the roughness and dielectric properties of the soil at thespecular points.
21-25 July 2003IGARSS’03 Toulouse, France
Measurement Technique(cont’d)
• Cross correlation waveforms for single GPS satellites were continuously recorded in 21 quarter-chip bins for one satellite at a time.
• Accumulation of signals was performed in hardware for fundamental sampling intervals of 1 ms. Batches of length 0.1 s of the sum-square of the in-phase and quadrature waveform components were averaged prior to archival.
• Signals from the surface-looking antennas were sequentially selected using a microwave PIN switch which provided an 8 s total integration period for the low-gain LHCP antenna and a 2 s total integration period for the other antennas.
• To suppress high-frequency Rayleigh fading due to rough surface scattering an additional averaging of the reflected waveforms (after subtracting the noise floor) was performed over a 100-s moving window.
21-25 July 2003IGARSS’03 Toulouse, France
Zone of Reflection
Feb. 4, 2002
Variations in the signal are uniquely related to changes in the dielectric permittivity, and therefore, to soil moisture because roughness of the area with low grass remains constant.
Reflected signals were recorded only for satellites with reflection ground tracks passing through the high-gain antenna footprint of size ~ 400 m x 350 m.
The gravimetric wetness of the soil was estimated at 6.0 cm depth using a Campbell Scientific CS-615 time-domain reflectometer. The soil in the uppermost 1.0 m layer at the BAO is heavy clay.
21-25 July 2003IGARSS’03 Toulouse, France
GPS Signal Reflection and Antenna Footprint Geometry
10 dB 3 dB
45o
35o
25o
15o
BAO towerPRN#30
PRN#1855o
-1000
-800
-600
-400
-200
0
200
y (m
)
-1000 -800 -600 -400 -200 0 200
x (m)
The specularlyreflecting points on the land surface provided a set of diurnally repeatable ground tracks.
PRN#18 and PRN#30 were selected for analysis because their tracks passing through the center of the high-gain antenna footprint (3-db and 10-dB contours shown).
Their reflection tracks are shown for June 5, 2002.
21-25 July 2003IGARSS’03 Toulouse, France
Example of Raw Time Series for Reflected and Direct Signals
0
50
100
150
200
250
0 10 20 30 40 50 60 Time (min)
Reflected Signal
SNR
Direct Signal
235 240 245 250 255 260 265 270Azimuth (deg)230
35 40 45 50 55 60 65 Elevation (deg)
Signals (all channels) from GPS satellite PRN#18 on June 5, 2002,18:00/19:00 UTC
21-25 July 2003IGARSS’03 Toulouse, France
0 8 32 4024 48 56Time (s)
SNR
High GainAntennas
16
Reflected Signal
RHCP
0
50
100
150
Direct Signal
LHCP
LHCPLow Gain
V-pol
H-pol
Fragment From the Previous Signal Time Series
21-25 July 2003IGARSS’03 Toulouse, France
Intercomparison Between Reflected Signals Obtained with All Antennas
GPS PRN#18 July 10, 2002
LHCPH-polV-polRHCPLHCP (Low-Gain)
220 230 240 250 260 270Azimuth (degree)
2800
5
10
15
20
25SN
R
21-25 July 2003IGARSS’03 Toulouse, France
Data Analysis• The reflected signals were analyzed for several days preceding four
local rain events and immediately afterwards.
• An expected rise of the reflected signal power was observed after rain events and subsequent decreases during following dry periods.
• Analogous correlation with rain events was found for other polarization channels. The highest levels of reflected power were the result of a very wet top layer saturated with water or, in some instances, standing water.
• A correlation was found between reflected GPS signal power and in situ SM measurements made on days without rain events as water was absorbed by the soil.
• Examples of such data obtained from GPS satellites PRN#18 and PRN#30 using various antennas are presented in the following plots
21-25 July 2003IGARSS’03 Toulouse, France
Effect of Rainfall on the Reflected Signal
After rainfall
Before rainfall
0
50
100
150
SNR
230 240 250 260 270 280Satellite Azimuth Angle (deg)
Comparison between two reflected signals for GPS PRN#18 obtained with the LHCP high-gain antenna on July 10, 2002 before rainfall, and on July 11, 2002 after rainfall.
21-25 July 2003IGARSS’03 Toulouse, France
Comparison Between Reflected Signal and in situ Measured Soil Wetness (SW)
0
10
20
30
40
50SN
R
0.10 0.15 0.20 0.25 0.30 0.35Soil Wetness
PRN#18 High-Gain LHCP Antenna
21-25 July 2003IGARSS’03 Toulouse, France
Comparison Between Reflected Signal and in situ Measured SW (cont’d)
0.10 0.15 0.20 0.25 0.30 0.35Soil Wetness
0
20
40
60
80
100SN
R
PRN#30 High-Gain LHCP Antenna
21-25 July 2003IGARSS’03 Toulouse, France
Comparison Between Reflected Signal and in situ Measured SW (cont’d)
0
2
4
6
8
10SN
R
0.10 0.15 0.20 0.25 0.30 0.35
Soil Wetness
PRN#18 High-Gain RHCP Antenna
21-25 July 2003IGARSS’03 Toulouse, France
Comparison Between Reflected Signal and in situ Measured SW (cont’d)
PRN#18 High-Gain H-pol. Antenna
0
5
10
15
20
25SN
R
0.10 0.15 0.20 0.25 0.30 0.35Soil Wetness
21-25 July 2003IGARSS’03 Toulouse, France
Comparison Between Reflected Signal and in situ Measured SW (cont’d)
0
5
10
15
20SN
R
0.10 0.15 0.20 0.25 0.30 0.35Soil Wetness
PRN#18 High-Gain V-pol. Antenna
21-25 July 2003IGARSS’03 Toulouse, France
Comparison Between Reflected Signal and in situ Measured SW (cont’d)
0.10 0.15 0.20 0.25 0.30 0.35Soil Wetness
0
2
4
6
8
10
12SN
R
PRN#18 Low-Gain LHCP Antenna
21-25 July 2003IGARSS’03 Toulouse, France
Comparison Between Reflected Signal and in situ Measured SW (cont’d)
0
2
4
6
8
10
12SN
R
0.10 0.15 0.20 0.25 0.30 0.35Soil Wetness
PRN#30 Low-Gain LHCP Antenna
21-25 July 2003IGARSS’03 Toulouse, France
Data Analysis: Summary
• The highest waveform SNR are for the high-gain LHCP antenna with the SNR reaching 50 for 0.33 soil wetness and leveling at 10-13 dB.
• A similar behavior is found for other polarization channels, however, at lower SNR levels.
• An encouraging result is obtained even the low-gain LHCP antenna despite the low gain and possible complications due to multipath.
• The SNR data do not show significant sensitivity to the measuredwetness at lower levels of moisture.
• A possible explanation: The L-band waves can penetrate through the relatively thin and dry layer to deeper soil with larger reflectivity. It is thus suggested that the probe SM measurements at 6 cm are not representative for depths important for L-band radio wave propagation.
21-25 July 2003IGARSS’03 Toulouse, France
Conclusions
• An expected correlation between strong reflected signals and rain events has been observed.
• The high-gain antennas increased the receiver dynamic range and reduced surface multipath radio wave interference.
• A high level of correlation has been found between reflected signal power and in situ soil moisture measurements for high levels of moisture when the top layer of soil of about 6 cm of thickness was moist enough.
• For drier top layers the correlation between top-layer moisture and the reflected power is diminished due to deeper penetration of the L-band radio waves toward the more moist layers of soil.