global monitoring of riparian zones in arid lands using remote sensing methods in the colorado river...
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Global Monitoring ofRiparian Zonesin Arid Lands
Using Remote Sensing
Methods in the Colorado River Delta Hugo Rodriquez, Doug Rautenkranz, Pamela Nagler
OVERVIEW• Purpose and Background
– Applications
– The importance of measuring the extent and magnitude of riparian vegetation
– Usefulness of remote sensing in monitoring riparian vegetation
– Correlation of vegetation growth & water flows
• Data Collection
– aircraft flight (May 1999)
– satellite imagery
• Image processing & spectral analysis• Scaling from aerial images to satellite images
– field transects: validating imagery• Results: Satellite data is useful in determining
percent cover for habitat delineation.
• Future Work and Cooperation with Bureau of Reclamation– Helicopter Flight (January, 2000)– Future Aircraft Flight (May, 2000)
Applications
• Quantification of Riparian Vegetation in Arid Lands
• Protection of Biologically Diverse Natural Resources and Habitats for Endangered Species
• Warnings of Vegetation Stress and/or Habitat Reduction which help to facilitate bureaucratic decision-making.
• Provides Hydrologists, Modelers, Farmers, & Researchers with Image Products that aid in determining water availability.
Usefulness of Remote Sensing in Monitoring Riparian Vegetation
• Improved Methods:– Faster & Less tedious work– Larger area coverage & Inaccessible regions– More accurate (less human error)
• Spectral data (reflectances) are collected by sensors on different platforms:– satellite sensors: i.e., Landsat Thematic Mapper (TM)
or Terra MODIS– airborne sensors: i.e., DyCAM imaging camera,
Exotech Radiometer– ground sensors: i.e., Exotech Radiometer
• Spectral data is divided into Red and NIR bands and ratioed to give a vegetation index (VI) showing the presence of vegetation:– VI = 0 Soil– VI = 1 Green Vegetation
• VI is important in determining the magnitude and extent (percent cover (%C)) of vegetation.
Figure 1. Mean VIS-NIR reflectance (400 - 1000 nm) of four landscape components: live, green vegetation (n=88); dry deciduous litter (n=40); dry crop residues (n=21); and dry soils (n=20).
Ref
lect
ance
(%
)
Wavelength (nm)
400 500 600 700 800 900 1000
0
10
20
30
40
50
60
Deciduous Litter (DL) Crop Residue (CR) Soils (S)
Green Vegetation (GV)
CR
S
DL
GV
Spectral Data: Vegetation Indices (VI)
• A) NDVI = (NIR-Red) / (NIR+Red)
• B) SAVI = (1+L) x [(NIR - RED) / (NIR + Red + L)]
• C) EVI = 2(NIR-RED) / (NIR + 3.3Red - 4.5Blue + 0.6)
B G R NIR
The importance of measuring the extent and magnitude of
Riparian Vegetation
• Habitat• Endangered species, Biodiversity
• Land Corridors (Continuity of habitat)
• Water Resources, Wetlands
• Hydrology• Dependence of vegetation on water
availability
• Removal of invasive plants by floods
• Global Hydrologic Cycle
• Earth’s Energy Balance• Land Cover / Use, Vegetation Dynamics
• Surface Temperature and Energy Cycles
• Biology / Biogeochemistry of Ecosystems
• Global Carbon Cycle
• Climate Trends
Background
• After the construction of Glen Canyon Dam and the filling of Lake Powell, there was reduced flow and no water in the delta (“a dead delta”). There has been some regeneration of native vegetation in the absence of floods.
• Images were acquired before and after flooding to capture the state of vegetation and to bracket the flood periods. Bigger flows and their corresponding responses are shown in images before and after flooding.
• Large floods from 1983-86 produced trees which are now approximately 15 years old. Between 1986-93 there was no water, but trees which are in an age class ~10 years old germinated and grew although there were no floods. The 1997-99 flood period produced the greatest number of cottonwood and willow trees and which are 2-3 years old.
• Smallest peak (250,000 acre/ft) in 1997 still has enough water to stimulate/regenerate vegetation growth. In conclusion, the big peak flows exist, however even the smaller flows provide for a riparian growth.
Annual Flows
Glen CanyonDam Completed
Lake Powell
fills
Determining Vegetation Stress
• Vegetation Indices (VI) – Fraction of Absorbed Photosynthetically Active
Radiation (fAPAR) – Leaf Area Index (LAI)
• EvapoTranspiration (ET)– Surface resistance– Latent heat of vaporization– Thermal Data: Canopy and Air Temperatures
• Peak Vegetation (VI & ET) data are correlated with these hydrologic variables:– Surface flows– Storage of water in the riparian aquifer– Depth to water and salinity of water– Precipitation, outflows, net radiation, potential
evaporation, soil holding capacity
• Validation: – ground – aircraft– satellite, with different resolutions
Data Collection• Maps
– Roads, urban areas, landmarks – Canals, drainage system, wetlands, soils– Vegetation/Landcover classes (GIS)
– Species identification (ground-truthing)
• Field Instrumentation– Hydrological Gaging Stations:
• surface flows, salinity, aquifer storage
– IRT (temperature), Ground Exotech (Refl. & VI)– LAI2000 (LAI), AccuPAR (fAPAR), Sap Flow (ET)– Manual Estimations:
• Height, Widths, Percent Cover, Vegetation Class/Species
• Meteorological Data (for 2000 flight)– net radiation, wind speed– vapor pressure deficit– field and air temperature
• Airborne Instrumentation– Digital VIS-NIR Camera– Exotech with simulated MODIS bands (VI)– Infrared Thermal (IRT) instrument (temperature)– Albedometers– Video Tape
Colorado River Delta Project Area
Ciénega
Altar Desert
Water &Mud Flats
S E A W i F S (1 km resolution) 1998 Image
Data Collection: AerialMay 24, 1999
4
89
DigitalPhotos
10:47
10:53
10:55
10:55
10:56
10:56
10:56
10:56
10:56
Area = 67m x 100m Alt. = 150mRes. = 1.7m
Length= 1.5 kmwith 10 kmspacing
Swath = 600mAlt. = 1000mRes. = 17.5m
Thematic Mapper (30m Resolution) 1998 Image
Image histograms:3 Bands and 3 VIs
501
502
503
504
505
506
507
Snaps-zone.shpFlight -line.shpSnaps.shp
0 0.8 Kilometers
N
EW
S
Layers
Hugo Rodriguez-gallegosPamela Nagler
5-01 5-02 5-03 5-04 5-05 5-06 5-07
Colorado River Delta MQUALS Flight May 24, 1999
Series 5-01 to 5-07
TM satellite Image, 1997TM satellite Image, 1997
SaviNdviNirRedBlueSzaDycam_timeSeries
5-01 11.03 24.02 71.08 87.33 148.70 0.30 0.14
5-02 11.03 24.01 40.36 59.60 78.10 0.09 0.05
5-03 11.03 24.00 44.39 65.31 112.21 0.24 0.12
5-04 11.03 23.99 46.48 68.45 143.94 0.38 0.18
5-05 11.03 23.98 57.01 85.03 141.45 0.28 0.13
5-06 11.03 23.97 62.10 89.97 150.73 0.30 0.14
5-07 11.03 23.96 54.62 102.90 141.50 0.18 0.09
MQUALS Flight
GIS Components
• Flight Line • Coordinates of Dycam Images• Solar Zenith Angle of Dycams• TM image (July 1997)• Video Time for Dycam image
location• Percent plant cover
• Visual assessments• Spectral analysis
• Dycam Reflectances • Dycam Average VI• TM Average VI
DyCAM (fov: 100m)overlayed with
Video Still (fov: 30m)
Vegetation Indices (VI) / Image
• A) NDVI = (NIR-Red) / (NIR+Red)
• B) SAVI = (1+L) x [(NIR - RED) / (NIR + Red + L)]
• C) EVI = 2(NIR-RED) / (NIR + 3.3Red - 4.5Blue + 0.6)
Determining Percent Cover
3-D (DEM) Representation of Vegetation Indices
Digital Elevation Model Image of DyCAM VI
DyCAM VI Classification of Ground Features
Percent Cover Comparison
ComputerVisual
DyCAM %C Results
Vegetation Indices (DyCAM) as a predictor of Percent Cover
Percent Cover
0 20 40 60 80 100
Veg
etat
ion
Ind
ices
0.0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
NDVI: y = 0.0308 + 0.0042x n = 63; SEE = 0.0582 R = 0.87029358 R² = 0.75741091 Adj R² = 0.75349818
SAVI: y = 0.0450 + 0.0014x n = 61; SEE = 0.0293 R = 0.75323017 R2 = 0.56735568 Adj R2 = 0.56014494
EVI: y = 0.0829 + 0.0023x n = 63; SEE = 0.0395 R = 0.81822894 R2 = 0.66949859 Adj R2 = 0.66416792
Global LAI
0.0 0.5 1.0 1.5 2.0 2.5
Veg
etat
ion
Ind
ices
0.0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
NDVI: y = 0.0863 + 0.1873x n = 56; SE = 0.079 R = 0.73588081 Rsqr = 0.54152057 Adj Rsqr = 0.53318458
EVI: y = 0.1128 + 0.1041x n = 56; SE = 0.0462 R = 0.71819221 Rsqr = 0.51580006 Adj Rsqr = 0.50699642
SAVI: y = 0.0698 + 0.0564x n = 54; SE = .0344 R = 0.60117607 Rsqr = 0.36141267 Adj Rsqr = 0.34936385
Vegetation Indices (DyCAM) as a predictor of Leaf Area Index (LAI)
Data Collection: FIELD
Ground Cover (%) vs. Geographic Sampling of the Aerial Images
Tree Characteristics
A B
C D
For three transect sites (Cinco de Mayo, Benito Juarez and Jesus Gonzales), 268 trees (cottonwood and willow only) were evaluated for Height (A), Diameter (B), No.Rings as a function of Diameter (C), and Age (D).
Diameter (cm)
WillowsCottonwoods
Cottonwood-Willow Zone: Cover Classes Estimates 3 Ways
n = 9
n = 63
n = 9
Equal samples
Accounts for different
transect lengths
Percent Cover by Species in Understory, Midstory, Overstory,
% of Total Land Cover & Area (ha)
Anderson-Ohmart Cover Classes
Cottonwood-Willow Structural Classes:
A comparison of US and Mexico Riparian Area
TM Nº (Scaled NDVI) and NDVI from DyCAM to TM (1999)
Scaled NDVI (Nº ): TM Nº = 0.956 * DyCAM Nº + 0.004
r2 = 0.82
TM NDVI: = 0.911 * DyCAM Nº - 0.177r2 = 0.79
Percent Cover determined using TM NDVI
Conclusions
• Vegetation Indices (VI) were determined using aerial remote sensing equipment and were well correlated with percent cover (%C).
• Vegetation mapping methods derived from aerial images were scaled up to the satellite level to show changes in percent cover in the ecosystem.
• Field surveys validated inferences from aerial and satellite imagery:– Changes in total vegetation cover over time– Regeneration of native tree species– The volume of flow
• Satellite images can be used to assess habitat extent, water availability, and land use change.
• Peak vegetation can be correlated with surface flows to gauge water stress & water requirements to support the ecosystem.
• Annual qualitative assessments of variables such as Vegetation Indices (VI) and percent cover (%C) can be used to monitor the status of riparian vegetation in the Delta.
Future Work
• Land Cover Class Delineation based on VI
• Species Classification based on Spectral Discrimination
• Processing of TM Images (1992-99)
• Comparison of riparian areas:– Colorado River
• Mexico• United States
– Bill Williams River
– Virgin River
– Gila River
Helicopter Flight and Future Aerial Data Collection