Papers
Topics
Authors
Recent
Gemini 2.5 Flash
Gemini 2.5 Flash
129 tokens/sec
GPT-4o
28 tokens/sec
Gemini 2.5 Pro Pro
42 tokens/sec
o3 Pro
4 tokens/sec
GPT-4.1 Pro
38 tokens/sec
DeepSeek R1 via Azure Pro
28 tokens/sec
2000 character limit reached

Comparing remote sensing-based forest biomass mapping approaches using new forest inventory plots in contrasting forests in northeastern and southwestern China (2405.15438v1)

Published 24 May 2024 in cs.CV, cs.LG, and eess.IV

Abstract: Large-scale high spatial resolution aboveground biomass (AGB) maps play a crucial role in determining forest carbon stocks and how they are changing, which is instrumental in understanding the global carbon cycle, and implementing policy to mitigate climate change. The advent of the new space-borne LiDAR sensor, NASA's GEDI instrument, provides unparalleled possibilities for the accurate and unbiased estimation of forest AGB at high resolution, particularly in dense and tall forests, where Synthetic Aperture Radar (SAR) and passive optical data exhibit saturation. However, GEDI is a sampling instrument, collecting dispersed footprints, and its data must be combined with that from other continuous cover satellites to create high-resolution maps, using local machine learning methods. In this study, we developed local models to estimate forest AGB from GEDI L2A data, as the models used to create GEDI L4 AGB data incorporated minimal field data from China. We then applied LightGBM and random forest regression to generate wall-to-wall AGB maps at 25 m resolution, using extensive GEDI footprints as well as Sentinel-1 data, ALOS-2 PALSAR-2 and Sentinel-2 optical data. Through a 5-fold cross-validation, LightGBM demonstrated a slightly better performance than Random Forest across two contrasting regions. However, in both regions, the computation speed of LightGBM is substantially faster than that of the random forest model, requiring roughly one-third of the time to compute on the same hardware. Through the validation against field data, the 25 m resolution AGB maps generated using the local models developed in this study exhibited higher accuracy compared to the GEDI L4B AGB data. We found in both regions an increase in error as slope increased. The trained models were tested on nearby but different regions and exhibited good performance.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (66)
  1. Estimated carbon dioxide emissions from tropical deforestation improved by carbon-density maps. Nature climate change 2, 182–185.
  2. Forest canopy height and carbon estimation at monks wood national nature reserve, uk, using dual-wavelength sar interferometry. Remote Sensing of Environment 108, 224–239.
  3. Random forests. Machine learning 45, 5–32.
  4. Mapping forest aboveground biomass in the northeastern united states with alos palsar dual-polarization l-band. Remote Sensing of Environment 124, 466–478.
  5. New forest aboveground biomass maps of china integrating multiple datasets. Remote Sensing 13, 2892.
  6. Retrieving vegetation height of forests and woodlands over mountainous areas in the pacific coast region using satellite laser altimetry. Remote Sensing of Environment 114, 1610–1627.
  7. Major forest types and the evolution of sustainable forestry in china. Environmental Management 48, 1066–1078.
  8. A new circa 2007 biomass map for china differs significantly from existing maps. Scientific Data 11, 287.
  9. Forest fire risk zone mapping from satellite images and gis for baihe forestry bureau, jilin, china. Journal of forestry research 16, 169–174.
  10. Gedi launches a new era of biomass inference from space. Environmental Research Letters 17, 095001.
  11. The global ecosystem dynamics investigation: High-resolution laser ranging of the earth’s forests and topography. Science of remote sensing 1, 100002.
  12. Gedi l2a elevation and height metrics data global footprint level v002. nasa eosdis land processes daac.
  13. Aboveground biomass density models for nasa’s global ecosystem dynamics investigation (gedi) lidar mission. Remote Sensing of Environment 270, 112845.
  14. Biomass estimation from simulated gedi, icesat-2 and nisar across environmental gradients in sonoma county, california. Remote Sensing of Environment 242, 111779.
  15. Aboveground biomass retrieval in tropical forests—the potential of combined x-and l-band sar data use. Remote sensing of environment 115, 1260–1271.
  16. Sar handbook: Comprehensive methodologies for forest monitoring and biomass estimation. nasa.
  17. Processes underlying 50 years of local forest-cover change in yunnan, china. Forests 5, 3257–3273.
  18. Improved lstm model for boreal forest height mapping using sentinel-1 time series. Remote Sensing 14, 5560.
  19. Landsat time-series for estimating forest aboveground biomass and its dynamics across space and time: A review. Remote Sensing 12, 98.
  20. The gedi simulator: A large-footprint waveform lidar simulator for calibration and validation of spaceborne missions. Earth and Space Science 6, 294–310.
  21. High-resolution global maps of 21st-century forest cover change. science 342, 850–853.
  22. Aboveground biomass mapping using alos-2/palsar-2 time-series images for borneo’s forest. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing 12, 5167–5177.
  23. Importance of biomass in the global carbon cycle. Journal of Geophysical Research: Biogeosciences 114.
  24. Integration of multi-resource remotely sensed data and allometric models for forest aboveground biomass estimation in china. Remote Sensing of Environment 221, 225–234.
  25. Nasadem merged dem global 1 arc second v001 [data set]. nasa eosdis land processes daac. 2020 .
  26. Lightgbm: A highly efficient gradient boosting decision tree. Advances in neural information processing systems 30.
  27. First validation of gedi canopy heights in african savannas. Remote Sensing of Environment 285, 113402.
  28. Performance evaluation of gedi and icesat-2 laser altimeter data for terrain and canopy height retrievals. Remote Sensing of Environment 264, 112571.
  29. Spatial and temporal distribution of forest fire frequency and forest area burnt in jilin province, northeast china. Journal of Forestry Research 29, 1233–1239.
  30. Relationships between forest stand parameters and landsat tm spectral responses in the brazilian amazon basin. Forest ecology and management 198, 149–167.
  31. A china’s normalized tree biomass equation dataset.
  32. Carbon losses from deforestation and widespread degradation offset by extensive growth in african woodlands. Nature communications 9, 3045.
  33. Spaceborne synthetic aperture radar: Principles, data access, and basic processing techniques. Synthetic Aperture Radar (SAR) Handbook: Comprehensive Methodologies for Forest Monitoring and Biomass Estimation , 21–64.
  34. The tropical forest carbon cycle and climate change. Nature 559, 527–534.
  35. Mapping tropical forest biomass with radar and spaceborne lidar in lopé national park, gabon: overcoming problems of high biomass and persistent cloud. Biogeosciences 9, 179–191.
  36. Using satellite radar backscatter to predict above-ground woody biomass: A consistent relationship across four different african landscapes. Geophysical Research Letters 36.
  37. Using icesat-2 to estimate and map forest aboveground biomass: A first example. Remote Sensing 12, 1824.
  38. Mapping global forest canopy height through integration of gedi and landsat data. Remote Sensing of Environment 253, 112165.
  39. Evaluation of p-band sar tomography for mapping tropical forest vertical backscatter and tree height. Remote Sensing 13, 1485.
  40. The impact of geolocation uncertainty on gedi tropical forest canopy height estimation and change monitoring. Science of Remote Sensing 4, 100024.
  41. Benchmark map of forest carbon stocks in tropical regions across three continents. Proceedings of the national academy of sciences 108, 9899–9904.
  42. Mapping sar geometric distortions and their stability along time: A new tool in google earth engine based on sentinel-1 image time series. International Journal of Remote Sensing 42, 9135–9154.
  43. The potential of multifrequency sar images for estimating forest biomass in mediterranean areas. Remote Sensing of Environment 200, 63–73.
  44. Potential of texture measurements of two-date dual polarization palsar data for the improvement of forest biomass estimation. ISPRS Journal of Photogrammetry and Remote Sensing 69, 146–166.
  45. Towards mapping the diversity of canopy structure from space with gedi. Environmental Research Letters 15, 115006.
  46. Fusing gedi with earth observation data for large area aboveground biomass mapping. International Journal of Applied Earth Observation and Geoinformation 115, 103108.
  47. Effects on rhizospheric and heterotrophic respiration of conversion from primary forest to secondary forest and plantations in northeast china. European journal of soil biology 66, 11–18.
  48. Characteristics of climate change and its relationship with land use/cover change in yunnan province, china. International journal of climatology 38, 2520–2537.
  49. Generation of 10m resolution palsar and jers-sar mosaic and forest/non-forest maps for forest carbon tracking, in: 2011 IEEE International Geoscience and Remote Sensing Symposium, IEEE. pp. 3510–3513.
  50. Palsar radiometric and geometric calibration. IEEE Transactions on Geoscience and Remote Sensing 47, 3915–3932.
  51. A review of radar remote sensing for biomass estimation. International Journal of Environmental Science and Technology 12, 1779–1792.
  52. Spatial distribution of forest aboveground biomass in china: Estimation through combination of spaceborne lidar, optical imagery, and forest inventory data. Remote Sensing of Environment 173, 187–199.
  53. Sub-continental-scale carbon stocks of individual trees in african drylands. Nature 615, 80–86.
  54. Understanding the temporal behavior of crops using sentinel-1 and sentinel-2-like data for agricultural applications. Remote sensing of environment 199, 415–426.
  55. Sensitivity of sentinel-1 backscatter to vegetation dynamics: An austrian case study. Remote Sensing 10, 1396.
  56. Biomass allometric equations for 10 co-occurring tree species in chinese temperate forests. Forest Ecology and Management 222, 9–16.
  57. The exceptional value of intact forest ecosystems. Nature ecology & evolution 2, 599–610.
  58. Radar backscatter is not a’direct measure’of forest biomass. Nature climate change 2, 556–557.
  59. Lidar sampling for large-area forest characterization: A review. Remote sensing of environment 121, 196–209.
  60. Changes in global terrestrial live biomass over the 21st century. Science Advances 7, eabe9829.
  61. Lightgbm: accelerated genomically designed crop breeding through ensemble learning. Genome Biology 22, 1–24.
  62. Forest management in northeast china: history, problems, and challenges. Environmental Management 48, 1122–1135.
  63. Forest fire susceptibility modeling using a convolutional neural network for yunnan province of china. International Journal of Disaster Risk Science 10, 386–403.
  64. Estimating aboveground biomass using landsat 7 etm+ data across a managed landscape in northern wisconsin, usa. Remote sensing of environment 93, 402–411.
  65. Improving forest aboveground biomass estimation using seasonal landsat ndvi time-series. ISPRS Journal of Photogrammetry and Remote Sensing 102, 222–231.
  66. How environmental factors affect forest fire occurrence in yunnan forest region. Forests 13, 1392.
Citations (1)
View on Semantic Scholar

Summary

We haven't generated a summary for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Summarize Now
X Twitter Logo Streamline Icon: https://streamlinehq.com

Tweets