2019
DOI: 10.3390/rs11243009
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Validating a Landsat Time-Series of Fractional Component Cover Across Western U.S. Rangelands

Abstract: Western U.S. rangelands have been quantified as six fractional cover (0%-100%) components over the Landsat archive at a 30 m resolution, termed the "Back-in-Time" (BIT) dataset. Robust validation through space and time is needed to quantify product accuracy. Here, we used field data collected concurrently with high-resolution satellite (HRS) images over multiple locations (n = 42) and years. Field observations were used to train regression tree models, predicting the component cover across each HRS image. Our… Show more

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Cited by 14 publications
(8 citation statements)
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“…The BIT data have been robustly validated by Rigge et al (2019b) who compared BIT data to a series of predictions made on high-resolution satellite imagery finding strong temporal relationships with a mean coefficient of determinations (R 2 ) of 0.63 and root-mean-square error (RMSE) of 5.47% and strong spatiotemporal correlations with a mean R 2 of 0.52 and RMSE of 7.89% across components. Data collected at longterm monitoring plots (n = 126) over a 10-yr period of 2006-2018 in southwestern Wyoming were compared to BIT data, again showing robust temporal and spatiotemporal correlations, with a mean R 2 of 0.46 across components (Shi et al 2020).…”
Section: Dependent Variablesmentioning
confidence: 99%
“…The BIT data have been robustly validated by Rigge et al (2019b) who compared BIT data to a series of predictions made on high-resolution satellite imagery finding strong temporal relationships with a mean coefficient of determinations (R 2 ) of 0.63 and root-mean-square error (RMSE) of 5.47% and strong spatiotemporal correlations with a mean R 2 of 0.52 and RMSE of 7.89% across components. Data collected at longterm monitoring plots (n = 126) over a 10-yr period of 2006-2018 in southwestern Wyoming were compared to BIT data, again showing robust temporal and spatiotemporal correlations, with a mean R 2 of 0.46 across components (Shi et al 2020).…”
Section: Dependent Variablesmentioning
confidence: 99%
“…Pixels were flagged as changed if thresholds were exceeded in both summer and fall images in a given year. Training data from the circa 2014 base were selected within the unchanged pixels in each year [28,34,35]. The training points were pooled across time to develop Cubist regression tree (RuleQuest Research 2008) models which used two seasons (summer and fall) of Landsat imagery, topographic data, and spectral indices as inputs [28,34].…”
Section: Input Datamentioning
confidence: 99%
“…A series of post-processing models were applied to ensure accurate post-burn trajectories and to eliminate noise and illogical change. For more details on the process, see Rigge et al [35].…”
Section: Input Datamentioning
confidence: 99%
“…First, we excluded well pads with <100% overlap with sagebrush remote sensing data. Second, we excluded well pads if mean sagebrush cover among reference pixels was ≤5.9% in any year following apparent reclamation, corresponding with the root mean square error for sagebrush estimates when compared with independent high resolution data (Rigge et al, 2019) and therefore potentially lacking sagebrush. Third, we used a LANDFIRE dataset for Existing Vegetation Type (LF 2.0.0; Rollins, 2009) with a crosswalk to Society of American Foresters‐Society for Range Management cover types to retain pads if at least one reference pixel was classified as “Mountain Big Sagebrush,” “Wyoming Big Sagebrush,” “Sagebrush‐Grass,” or “Big Sagebrush‐Bluebunch Wheatgrass.”…”
Section: Methodsmentioning
confidence: 99%