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__________. Introduction Importance – Wildlife Habitat – Nutrient Cycling – Long-Term Carbon Storage – Key Indicator for Biodiversity Minimum Stocking.

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Presentation on theme: "__________. Introduction Importance – Wildlife Habitat – Nutrient Cycling – Long-Term Carbon Storage – Key Indicator for Biodiversity Minimum Stocking."— Presentation transcript:

1 __________

2 Introduction Importance – Wildlife Habitat – Nutrient Cycling – Long-Term Carbon Storage – Key Indicator for Biodiversity Minimum Stocking Standards – Common Snag Thresholds: DBH ≥ 25 or 38 cm Difficult to Quantify – Distribution Highly Variable – Requires Intensive Sampling – Expensive to Sample

3 Method Overview Collect Field Snag Stem Map Data – 805 m 2 Circular Plots (n= 206)(843 Snags) Extract Height Normalized Plot Lidar Point Cloud Apply Snag Filtering Algorithm Create Lidar Stem Map Compare Snag Stem Maps (Field vs. Lidar) – Detection & Error Rates

4 Study Locations

5 Blacks Mountain Experimental Forest (BMEF) 805 m 2 Circular Plots (n = 154) (LoD = 65; HiD = 79; RNA = 10)

6 Storrie Fire Restoration Area (SF) 805 m 2 Circular Plots (n = 52)

7 Field Data Summary (2009) Standing Trees (805 m 2 ) – DBH (cm) – Height (m) – Species – Risk Rating – Crown Width (m) – Ht. Live & Dead Crown – Condition Codes – Location

8 Lidar Data Summary (2009) Acquisition Survey Design – AGL: 900 m – Scan Angle: ± 14 o – Side Lap > 50% – Intensity Range: 1-255 – Variable Gain Setting – > 105,000 pulses sec -1 BMEF Lidar – Average Point Density: 6.9 m -2 (sd: 5.6) – Vertical Accuracy: < 10 cm – First & Single Returns: 90.2% SF Lidar – Average Point Density: 6.7 m -2 (sd: 5.9) – Vertical Accuracy: < 15 cm – First & Single Returns: 89.9% – Beam Diameter: ~24 cm (narrow) – Up to 4 returns pulse -1

9 Snag Filtering Algorithm Identifies Snag Points & Removes Live Tree Points Local-area 2D & 3D Filters Based on Location and Intensity Values Final Result: Point Cloud Containing Only Snag Points in the Overstory

10 Snag Filtering Algorithm Intensity – Returned Pulse Energy Energy Emitted Path Distance Intersected Object Surface Characteristics – Commonly Not Utilized Calibration Variability – Displayed Promise

11 Snag Filtering Algorithm Intensity Value Characteristics – Snags High Percentage (> 90%) Low Intensity Points (0 – 70 i) – Solid Woody Material (Bark, Bare, Charred) Some Snags had Small Percentage ( 125 i) – Solid Bare Seasoned Wood (Light Colored – Reflective) Some Snags had Very Small Percentage of (< 10%) of Mid-Range Intensity Points (70 – 125 i) – Dead Needles or Leaves, Fine Branches, Witches Broom – Live Trees Mix of Low- and Mid- Range Intensity Values (0 – 125 i) Small Number of Live Trees had High Intensity Points (> 125 i) – Trees with Sparse Crowns or Leader Growth

12 Snag Filtering Algorithm Two Stages with Multiple Filters – Elimination Stage Three 3D Filters to Remove Live Tree Points – Height Values Forced to Zero – Reinstitution Stage Coarse-Scale 2D & 3D Filter Fine-Scale 2D Filter

13 Snag Filtering Algorithm Two Stages with Multiple Filters – Elimination Stage Three 3D Filters to Remove Live Tree Points – Z-Values Forced to Zero – Reinstitution Stage Coarse-Scale 2D & 3D Filter Fine-Scale 2D Filter

14 Individual Snag Detection Create Surface Canopy Height Model – ‘CanopyModel’ Program in Fusion Software Package Locate & Measure Heights of Individual Snags – ‘CanopyMaxima’ Program in Fusion Software Package

15 Individual Snag Detection Detection Criteria – Within 2.5 m for Snags with Height < 9 m – Within 4 m for Snags with Height ≥ 9 m Three Possible Outcomes – Detected Successfully – Omission Error = Undetected Snag – Commission Error = Detected Snag when Live Tree or Other

16 BMEF Detection Rates ≥ 25 cm DBH Minimum Stocking Threshold 58% (± 4.3%) ≥ 38 cm DBH Minimum Stocking Threshold 62% (± 5.8%)

17 Storrie Fire Detection Rates ≥ 25 cm DBH Minimum Stocking Threshold 76% (± 3.5%) ≥ 38 cm DBH Minimum Stocking Threshold 79% (± 4.6%)

18 Commission Error Rates

19 Products Snag Spatial Distribution – Never Been Available w/out Intensive Sampling – Forest Management & Assessment Applications Spatial Arrangement Assessments Wildlife Interactions Changes Over Time Snag Density Estimates – Improve Stocking Standard Assessment

20 Take Aways Promising Semi-Automated Method Less Variable Snag Density Estimates Clarity to Snag Stocking Standards (Assessment & Creation) Stem Map Larger Snags Across Landscape Filtering Point Clouds Using Intensity and Location Information Provides Enhanced Lidar Analysis Framework Useful Compliment Product: “Live Tree” Points

21 Future Improvements Calibrated Intensity Information New Filtering Methods Incorporation of Other Remote Sensing Products Snag Decay Stage Classification

22

23 Results Snag Height Estimation

24 Detection Rate Trends

25 Applications Focus: Individual Snag Detection – Traditionally Difficult to Quantify Irregular & Sparse Distribution – Filtering Algorithm Identifies Snag Pts. – Overall Detection Rate of 70.6% (± 2.9) Snags w/ DBH ≥ 38 cm Live Above-Ground Biomass – Filtered Point Cloud Increased Explanatory Power (R 2 0.86 to 0.94) Understory Vegetation Cover – Traditionally Difficult to Estimate & Predict (R 2 < 0.4) – Filtered Lidar Metric Increases Explanatory Power (R 2 > 0.7) – Cover Prediction RMSE ± 22%

26 Discussion Detection Rates Influenced by Controllable and Uncontrollable Factors – Controllable Factors: Lidar Data Quality (Acquisition Specifications) Individual Snag Detection Methods (Filtering & Location Identification) – Uncontrollable Factors: Forest Stand Characteristics Individual Snag Characteristics Room for Improvement – Filtering Algorithm – Incorporate Additional Remote Sensing Products

27

28 Airborne Discrete-Return Lidar Small-Footprint – Beam Diameter: 10-100 cm Multiple Returns per Pulse – Typically 2-3 returns max. Accuracy – Vertical < 30 cm – Horizontal < 30 cm Products – X, Y, Z Points – Intensity

29 Airborne Discrete-Return Lidar Small-Footprint – Beam Diameter: 10-100 cm Multiple Returns per Pulse – Typically 2-3 returns max. Accuracy – Vertical < 30 cm – Horizontal < 30 cm Products – X, Y, Z Points – Intensity

30 Applications Individual Snag Detection – Traditionally Difficult to Quantify Irregular & Sparse Distribution – Filtering Algorithm Identifies Snag Pts. – Overall Detection Rate of 70.6% (± 2.9) Snags w/ DBH ≥ 38 cm Live Above-Ground Biomass – Filtered Point Cloud Improves Prediction Understory Vegetation Cover – Traditionally Difficult to Estimate & Predict (R 2 < 0.4) – Filtered Lidar Metric Increases Explanatory Power (R 2 > 0.7) – Cover Prediction RMSE ± 22%

31 Results Reduced Prediction RMSE by 4.6 Mg ha -1

32 Applications Individual Snag Detection – Traditionally Difficult to Quantify Irregular & Sparse Distribution – Filtering Algorithm Identifies Snag Pts. – Overall Detection Rate of 70.6% (± 2.9) Snags w/ DBH ≥ 38 cm Live Above-Ground Biomass – Filtered Point Cloud Improves Prediction Understory Vegetation Cover – Traditionally Difficult to Estimate & Predict (R 2 < 0.4) – Filtered Lidar Metric Increases Explanatory Power (R 2 > 0.7) – Cover Prediction RMSE ± 22%

33 Results Models Cross Validation Overall Prediction Accuracy: ± 22%

34 Applications Summary Demonstrates the Ability of Airborne Discrete-Return Lidar to Identify & Predict Unique Forest Attributes Filtering Point Clouds Using Intensity and Location Information Provides Enhanced Framework – Useful in All Three Applications Possible Improvements: – Calibrated Intensity Information – New Filtering Methods – Small-Footprint Full-Waveform Lidar

35 Soap Box & Future Work Lidar Successfully Predicts Numerous Forest Attributes – More Applications Developing Rapidly Time to Incorporate into Forest Management Planning & Assessments – Provides Foundation to Optimize Forest Planning While Meeting Multiple Goals

36 Snag Filtering Algorithm Lower & Upper Intensity Thresholds – Likely Snag or Live-Tree Point Cut-Offs – Helps Account for Lidar Acquisition Intensity Variation

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