Look for complete geospatial metadata in this layer's associated xml document available from the download link * Metric Name: SNV – Index of Large Tree Presence * Tier: 2 * Data Vintage: 06/2020 * Unit Of Measure: Floating point; number of the nine 10-meter pixels within a 30 meter pixel that contains at least one tree of this size Floating point; values represent the percent of nine 10-meter pixels within a 30 meter pixel that contains at least one tree within each dbh class. * Metric Definition and Relevance: Large trees are important to forest managers for multiple reasons: they have a greater likelihood of survival from fire; they are an important source of seed stock; they provide vitally important wildlife habitat; and they contribute to other critical processes like carbon storage and nutrient cycling. Management and protection of large trees are often the focus of silvicultural prescriptions in order to protect existing ones and to foster recruitment of future ones. In consultation with National Forests, “large trees” for the Sierra Nevada region have been designated in two categories, 24”-30” dbh (diameter at breast height) and greater than 30” dbh. Trees larger than 24” dbh are considered “large” within the California Wildlife Habitat Relationships model and thus we have specifically identified areas that have these features. The data provided are an estimate of the frequency of trees (in each dbh class) within a 30 meter pixel expressed as a percentage. * Creation Method: To determine the presence and proportion of large tree in a 30 meter pixel, we used the 10 meter data from the California Forest Observatory (CFO) that contains the height (in meters) of the largest tree in that 10 meter pixel. After converting meters to feet, we then developed an allometric equation to predict tree diameter as a function of tree height in feet. We selected data for plots located in the Sierra Nevada region from the USDA Forest Inventory and Analysis program (FIA) for California (FIA DataMart 2023; California 2022 database; ver. 9.0.1). We included trees that met the following criteria: alive; crown class code of open-grown, dominant, or co-dominant; diameter at breast height (DBH, breast height = 4.5 ft) at least 1 inch; and height (HT) at least 5 feet. To minimize the impact of outliers, we trimmed the maximum tree height to the 0.995th percentile. These selection criteria yielded 82,444 trees. We used an information-theoretic approach to select the best allometric model (Burnham and Anderson 2002). We evaluated three alternative functions: : linear, power, and saturating. The criteria for model selection were based on the Akaike Information Criterion (AIC). For this set of 3 potential models, we calculated the difference in AIC between every model and the model with the lowest AIC (ΔAIC). The best allometric model was a saturating function where: DIA = (187.2*HT)/(588.5+HT) The root mean square error on the DBH prediction was 6.02 in and the pseudoR2 = 0.71. Predicted diameters from heights are summarized here: Block statistics were run to compute the frequency of California Forest Observatory (CFO) 10-meter pixels within a 3x3 window of the number of pixels containing at least one tree larger than the minimum diameter sized tree. The resulting frequency within a 30m pixel (values 0 through 9) is expressed as a percentage. Two metrics have been developed for the Sierra Nevada region: 1. 1) frequency within pixel of 24” – 30” dbh in trees 2. 2) frequency within pixel of greater than 30” dbh in trees References Burnham, K.P., and D.R. Anderson. 2002. Model selection and multimodel inference: a practical information-theoretic approach. 2nd ed. New York, Springer-Verlag. FIA DataMart. 2023. USDA Forest Inventory and Analysis DataMart. https://experience.arcgis.com/experience/3641cea45d614ab88791aef54f3a1849/ * Credits: California Forest Observatory (Salo Sciences), 2020