Experiment station researchers have found that the spectral (wavelengths of light) information from natural colour imagery more accurately identifies individual tree crowns – the branches and leaves/needles extending from the trunk – than the traditional canopy height model when used in conjunction with unmanned aerial systems.
In a new study, University of New Hampshire researchers have concluded that when assessing forest imagery collected by unmanned aerial systems, an alternative method of delineating individual forest tree crowns within those images is more accurate than the most commonly used method, the canopy height model. The research is important to New Hampshire landowners and forest managers as mapping and monitoring forests is a key component of managing natural resources. According to the North East State Foresters Association, the annual value of sales of New Hampshire’s forest products industry totals nearly US$1.4 billion.
Researchers at the New Hampshire Agricultural Experiment Station have found that the spectral (wavelengths of light) information from natural colour imagery more accurately identifies individual tree crowns – the branches and leaves/needles extending from the trunk – than the traditional canopy height model when used in conjunction with unmanned aerial systems.
Additionally, the results for a mixed forest – one not dominated by either deciduous or coniferous trees – were not much different than either a conifer or deciduous forest alone. Most previous work in this area was done on conifer forests because the crown shape is easier to detect. However, much of the forested land area in New England and other parts of the United States contains both types of trees.
Improved accuracy in identifying and measuring tree crown size and shape can reveal much about the ecology and competition in the forest, according to Russ Congalton, professor of natural resources and the environment. Individual tree crowns also are an essential data product for precision forestry.
“Improvement in geospatial technologies, including the collection of remotely sensed imagery, has substantially increased our ability to generate effective and efficient information about our forests,” said Congalton. “Recently, the development of unmanned aerial systems has allowed for very cost-effective and high-resolution imagery. This imagery has the potential to provide information at a level of detail beyond what has historically been possible.”
This research is published in the journal Forests. Collaborators include postdoctoral research associate Jianyu Gu, and doctoral student Heather Grybas. This material is based upon work supported by the NH Agricultural Experiment Station, through joint funding of the National Institute of Food and Agriculture, U.S. Department of Agriculture, under award number 1015520, and the state of New Hampshire.