Automated Techniques to Map Headwaters Stream Networks in the Piedmont Ecoregion of North
Carolina
Valerie GarciaForestry Department, North Carolina State University
Office of Research and Development, Environmental Protection AgencyAugust 4, 2004
Why is the research important?
A large percentage of non-point source pollution is suspected to occur through headwaters streams
Current available USGS 1:24,000 Topographic maps lack accuracy in depicting the presence and location of headwaters streams
The lack of accurate maps for headwaters streams places an inordinate burden on both the regulatory agencies and the regulated communities in planning and implementing policy
Why is the research important?
Recent availability of LIDAR data for portions of North Carolina provide new opportunities for developing more accurate stream maps
This study focuses on the mapping of headwaters stream networks using Geographical Information System (GIS) approaches and LIDAR data
Study results limited to the Piedmont Ecoregion of North Carolina
Layout of Study
Phase I: Extensive literature search to investigate state-of-science Geographical Information System (GIS) approaches relevant for using LIDAR data to map headwaters streams
Phase II: Compare and evaluate approaches identified through the literature search by applying the techniques to a study site in the Piedmont Ecoregion of North Carolina
Phase I: Literature Search
Some Definitions…
Triangulated Irregular Network (TIN)
Digital Elevation Model (DEM)
Hydro-enforcement
Triangulated Irregular Network (TIN):
Formulation of non-overlapping triangles from irregularly spaced x, y, and z points (vector-based)
Digital Elevation Model (DEM):
As used in this study…uniformly spaced, 3-dimensional cartographic representation (x, y, z) in a grid or raster format
Both TINs and DEMs result in artifacts—artificial disruptions of the natural drainage of water
Incorporation of known stream center-lines (breaklines) into the modeled terrain ensure the downstream drainage of water
Hydro-Enforcement
Summary of Literature Search Findings fell into two major categories
Production of accurate topographic maps Extraction of stream networks
TINs produce more precise topographic maps maintains LIDAR elevation points as triangle vertices better retains linear structures (breaklines)
DEMs are better for automatically extracting headwaters streams can automatically correct drainage problems and
determine stream origin
Summary of Literature Search
The interpolation method and the resolution used to generate the topographic map can impact the accuracy of the map more complex interpolation methods (e.g., Spline,
Kriging) require more knowledge and are computationally demanding, but are expected to perform better in modeling terrain
resolution drives computation demands of the interpolation method and can impact the selection of which interpolation method can be used
Summary of Literature Search
Hydro-enforcement of the DEM enhances the accuracy of the extracted stream networks derived from orthophotos (can be expensive) typically not available for headwaters streams
Physical processes relevant at headwaters stream scales are different than watershed scales typically modeled stream origin and hillslope (diffuse) flow are critical at
headwaters stream scales
Phase II: Application of Stream Mapping Techniques to Study Site in
Falls Lake, North Carolina
Research Questions
What is the accuracy of the LIDAR surface elevation points?
When using densely spaced LIDAR data, does the interpolation method used to create a DEM make a difference in the accuracy of the DEM?
At what resolution do you begin to lose channel definition of headwaters streams, thereby affecting the production of headwaters stream maps?
Does using breakline data to hydro-enforce TINs and DEMs make a difference in the production of headwaters stream maps?
Do more complex stream flow algorithms and stream origin approaches produce better results than simpler methods in mapping headwaters streams? [not covered in this presentation]
Method Steps
Step 1: Evaluate the accuracy of LIDAR surface elevation points
Step 2: Compare the accuracy of topographic maps generated using various interpolation methods
Step 3: Evaluate the effect of scaling on topographic and stream map accuracy
Step 4: Assess the impact of using hydro-enforcement to extract stream networks
Study Site
Forested headwater stream catchment near Falls Lake in the Piedmont Ecoregion of North Carolina was selected as the study site Collected surveyed elevation points and mapping grade
Global Positioning System (GPS) along headwater stream
All modeling techniques were run for the study site and compared against survey data and available ancillary data
GIS Applications Used in Study
ArcGIS used to generate topographic maps
Four interpolation methods compared: Natural Neighbor, Inverse Distance Weighting (IDW), Spline and Kriging
Four resolutions compared: 10 ft., 20 ft., 60 ft., 90 ft.
ArcHydro used to extract stream networks
Networks extracted with and without hydro-enforcement
Networks extracted at four resolutions: 10 ft., 20 ft., 60 ft., 90 ft.
Data Used in Study
Existing data used in modeling
LIDAR mass elevation points (NC State Floodplain Mapping Program, 2003)
Breakline data (stream centerlines and shorelines) (NC State Floodplain Mapping Program, 2003)
Data used for comparisons
Field-collected data (survey, mapping-grade GPS) Medium and high resolution National Hydrography Dataset (NHD) (2000) USGS 1:24,000 Topographic Digital Raster Graph (DRG) (1994) Wake County Hydrography Lines (2000) derived from 1:12,000 aerial
photography 1999 Wake County Color Digital Orthophotography
Step 1: Evaluation of LIDAR Surface Elevation Points
Collection of high-accuracy ground truth data
Control Benchmarks established along ridge of study catchments (vertical +/- 2cm)
Transect surveyed across study catchment (vertical +/- 8cm)
GPS measurements taken along headwater stream (horizontal 1-2m)
Compared LIDAR data to field-collected survey points
TIN generated from LIDAR data (without breaklines) and used for comparison with survey data
Step 1: Evaluation of LIDAR Surface Elevation Points
RMSE was 1.32’ or 40.1 cm (no points removed) Recalculated using the “95 percentile” methodology with adjusted RMSE of 28.7 cm Published accuracy of LIDAR data is 25 cm (95 percentile) -- but study did not limit
survey to uniform slope and used only one landcover type
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104.4 9.7 23.4 36.6 28.0 28.8 28.0 24.8 30.3 27.4 35.8 26.5 15.3 4.8 4.0 51.3 2.0 1.9 2.1 33.9 41.7 34.4 25.0 21.7
C ontr ol P oi nts Sur vey P oints T IN-no br eaks
Step 2: Comparison of Topographic Maps
Generated DEMs from LIDAR data using four different interpolation techniques and compared to ground-truth data 20 ft. resolution used as LIDAR data averaged at least
one point every 20 sq. ft.
Four interpolation methods compared (Natural Neighbor, IDW, Spline and Kriging)
Results compared to survey data
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C ontr ol P oi nts
Sur vey P oints IDW Kr ig
Step 2: Comparison of Topographic Maps
Method vs. Survey Points
RMSE
LIDAR 1.3'
Spline 1.4'
Natural Neighbor 1.6'
IDW 2.2'
Kriging 2.3'
IDW(brick), Kriging (majenta) vs. Survey Points (blue)
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104.4 9.7 23.4 36.6 28.0 28.8 28.0 24.8 30.3 27.4 35.8 26.5 15.3 4.8 4.0 51.3 2.0 1.9 2.1 33.9 41.7 34.4 25.0 21.7
C ontr ol P oi nts
Sur vey P oints Spl ine Natur al Neighbor
Method vs. Survey Points
RMSE
LIDAR 1.3'
Spline 1.4'
Natural Neighbor 1.6'
IDW 2.2'
Kriging 2.3'
Spline (red), Natural Neighbor (green) vs. Survey Points (blue)
Step 2: Comparison of Topographic Maps
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104.4 9.7 23.4 36.6 28.0 28.8 28.0 24.8 30.3 27.4 35.8 26.5 15.3 4.8 4.0 51.3 2.0 1.9 2.1 33.9 41.7 34.4 25.0 21.7
C ontr ol P oi nts
Sur vey P oints IDW Spl ine Natur al Neighbor Kr ig
Method vs. Survey Points
RMSE
LIDAR 1.3'
Spline 1.4'
Natural Neighbor 1.6'
IDW 2.2'
Kriging 2.3'
Step 2: Comparison of Topographic Maps
Step 3: Evaluate Impact of Scaling to Various Resolutions
Evaluate impact of scaling on accuracy of topographic map
Natural Neighbor, IDW, and Regularized Spline used to generate 10 ft., 20 ft., 60 ft. and 90 ft. resolution DEMs
Results compared to survey data
Step 3: Evaluate Impact of Scaling to Various Resolutions
Evaluate impact of scaling on stream extraction
ArcHydro used to extract stream networks at various resolutions (10 ft., 20 ft., 60 ft. 90 ft.)
Extracted stream networks compared to each other, GPS points and Wake County hydrography lines
Step 3: Evaluate Impact of Scaling to Various Resolutions - DEM
Comparison of DEMs at different resolutions Very little difference exists between the 10 ft. and 20 ft. resolution DEMs
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Sur vey P oi nts
Sur vey P oints Spl ine - 10' Spl ine - 20'
Step 3: Evaluate Impact of Scaling to Various Resolutions – Stream Extraction
Comparison of DEMs at different resolutions At 60 ft. resolution, 2 ft. headwater stream channel becomes a 120 ft. depression At 90 ft. resolution, the entire drainage is lost
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Sur vey P oi nts
Sur vey P oints Spl ine - 60' Spl ine - 90'
Impact of Scaling to Various Resolutions
Comparison of drainages extracted at different resolutions
Similar to the topographic map results, very little difference exists between the extracted stream drainages generated from the 10 ft. and 20 ft. resolution DEMs
Impact of Scaling to Various Resolutions
Comparison of drainages extracted at different resolutions
At 60 ft. resolution, drainage lines become much more unnaturally linear and have more occurrences of drainage interruptions
At 90 ft. resolution, this problem is more extreme
Step 4: Assess the effect of Hydro-enforcement on the Extraction of Stream Networks
Accuracy of source breakline data Overlain on NHD, Wake County hydrography lines, Wake County
digital orthophotography and USGS 1:24,000 Topographic DRG Evaluate the impact of hydro-enforcement on extracting headwaters
stream networks ArcHydro used to extract stream networks for each DEM, with and
without hydro-enforcement Extracted networks compared to stream GPS points, NHD, Wake
County hydrography lines, Wake County digital orthophotography and USGS 1:24,000 Topographic DRG
NC Floodplain Program breakline data aligns well with the 1999 Wake County digital orthophotography
Step 4: Impact of Hydro-enforcement – Accuracy of Breakline Data
Step 4: Impact of Hydro-enforcement – Accuracy of Breakline Data
NHD (high resolution (blue) and medium resolution (red)) aligns well with USGS 1:24,000 Topographic DRG
Step 4: Impact of Hydro-enforcement – Accuracy of Breakline Data
NHD (high resolution) does NOT align with 1999 orthophotography (beige polygons emphasize alignment problems)
Step 4: Impact of Hydro-Enforcement
Most of the differences were in the higher-order streams
The headwaters stream network was substantially the same regardless of whether the grid was hydro-enforced or not
Hydro-enforced Natural Neighbor DEM produced the cleanest drainage lines in the breakline areas
Drainage created from hydro-enforced TIN (converted to grid) produces a confused drainage in the lake area
Step 4: Impact of Hydro-Enforcement
“Best” drainage generated from Natural Neighbor DEM with hydro-enforcement (blue) overlain on Wake County hydrological lines
(green)
Conclusions
Simpler interpolation methods (e.g., Nearest Neighbor, IDW) did as well or better than the more complex interpolation methods (e.g., Kriging) for generating the base DEMs that are used for extracting headwaters stream networks
Hydro-enforcement did not improve the results in extracting the headwaters stream networks
Hydro-enforcement did generate more direct drainages in the lake area, indicating that flatter areas or any area prone to flooding, will be aided by breakline data
Conclusions
Breakline data available through the NC State Floodplain Program are better aligned than currently available NHD or USGS 1:24,000 Topographic Map
Because misalignments are carried throughout the stream network, only the highest quality breakline data should be used for hydro-enforcement; alternatively, no hydro-enforcement should be used
“Zooming in” shows that the model does better than the Wake County hydrography lines as compared to the GPS stream points
Bottomline…
For the study catchment—LIDAR data and GIS modeling approaches did a better job than the best stream data currently available for the area
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