The Accuracy of Ground-Cover Measurements

Booth, Arthur L.; Cox, Samuel E.; Meikle, Tim; Fitzgerald, C. P.

doi:10.2458/azu_jrm_v59i2_booth

Cited by 22 publications

(45 citation statements)

References 16 publications

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“…Such artificial plots have many limitations: constancy of shape and color, restriction of no overlap, and non-random distribution at the edges, as suggested by Schultz et al (1961) andbooth et al (2006b). But even though artificial plots do not accurately reflect the real world, they do serve the purpose of demonstrating the influence of changing sampling density on accuracy when using the DGo and the PDPC methods.…”

Section: Technical Considerations For Using the Plot Digital Photogramentioning

confidence: 99%

Digital Photograph Analysis for Measuring Percent Plant Cover in the Arctic

Chen¹,

Chen²,

Leblanc³

et al. 2010

ARCTIC

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AbStrACt. long-term satellite remote sensing data, when properly calibrated and validated against ground monitoring, could provide valuable data sets for assessing climate change impacts on ecosystems, wildlife, and other important aspects of life in the Arctic. Percent plant cover is ideal for seasonal and long-term ground monitoring because it can be observed non-destructively and is closely related to other key ecosystem variables, such as biomass and leaf area index (lAi). Accurately measuring percent plant cover in the Arctic, however, has been a challenge. Advances in digital photography and imageprocessing techniques have provided the potential to measure vegetation cover accurately. in this paper we report an adapted method for quantifying percent plant cover based on plot digital photograph classification (PDPC). In this digital image analysis, the red, green, and blue image channels and the intensity, hue, and saturation image channels were used together to ensure more accurate cover measurement and labeling of plant species. We evaluated the accuracy of the PDPC method and two other techniques, visual estimate and digital grid overlay, by testing against artificial plots with known percent cover, by comparing with destructively measured lAi, and by comparing results of the three methods. our evaluation indicates that the PDPC method is the most accurate. In addition, PDPC has the advantages of being objective, quick in the field, and suitable for measuring percent plant cover in the Arctic at the level of functional types or species groups.Key words: percent plant cover, Arctic, visual estimate, digital photograph, image classification, LAI rÉSuMÉ. lorsqu'elles sont bien calibrées et qu'elles sont validées contre le dépistage terrestre, les données résultant de la télédétection satellitaire à long terme pourraient fournir d'importants ensembles de données en vue de l'évaluation des incidences du changement climatique sur les écosystèmes, la faune et d'autres aspects-clés de la vie dans l'Arctique. le pourcentage de couverture végétale est idéal pour le dépistage saisonnier et le dépistage terrestre à long terme parce qu'il peut être observé sans qu'il n'y ait de destruction et parce qu'il est étroitement lié à d'autres variables-clés se rapportant aux écosystèmes, comme la biomasse et l'indice de surface foliaire (iSF). toutefois, dans l'Arctique, la mesure exacte du pourcentage de couverture végétale représente un défi. Les progrès réalisés dans les domaines de la photographie numérique et des techniques de traitement d'images fournissent la possibilité de mesurer la couverture végétale avec précision. Dans cette communication, nous faisons état d'une méthode adaptée permettant de quantifier le pourcentage de couverture végétale en fonction de la classification de photographies numériques de parcelles. Dans le cadre de l'analyse d'images numériques, les canaux rouges, verts et bleus des images ainsi que les canaux d'intensité, de tonalité et de saturation des images ont été utilisés pour donner lieu ...

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Section: Technical Considerations For Using the Plot Digital Photogramentioning

confidence: 99%

Digital Photograph Analysis for Measuring Percent Plant Cover in the Arctic

Chen¹,

Chen²,

Leblanc³

et al. 2010

ARCTIC

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“…Another approach is to select points within the image and have the operator manually classify sample points, analogous to pointintercept methods in the field (Booth et al 2006a). Studies comparing cover estimates derived from digital images to traditional methods have generally found good agreement (Booth et al 2005(Booth et al , 2006b). Because these methods are largely untested for wetland determination and delineation purposes, they do not provide a suitable alternative to traditional sampling approaches.…”

Section: Defining and Locating Sampling Units In The Fieldmentioning

confidence: 99%

Vegetation Sampling for Wetland Delineation: A Review and Synthesis of Methods and Sampling Issues

Gage¹,

Cooper²

2010

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This document reviews sampling issues and methods for characterizing vegetation, with an emphasis on delineating wetland boundaries in accordance with Section 404 of the Clean Water Act. Numerous vegetation sampling methods have been developed, but no single approach is optimal for all sampling objectives, vegetation types, and ecological settings. Methods vary in relative precision, accuracy, and efficiency, although selection of methods should also explicitly consider sampling objectives, resources, and data requirements. Key considerations include the choice of metric(s), selection of sampling units, and logistical issues such as time required for sample collection. Common metrics include frequency, cover, and biomass,

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“…Additionally, they may require the user to have knowledge of image processing techniques. Most importantly, current techniques generally lack sufficient accuracy to be useful [16,26].…”

Section: Introductionmentioning

confidence: 99%

Increasing the Accuracy and Automation of Fractional Vegetation Cover Estimation from Digital Photographs

et al. 2016

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Abstract:The use of automated methods to estimate fractional vegetation cover (FVC) from digital photographs has increased in recent years given its potential to produce accurate, fast and inexpensive FVC measurements. Wide acceptance has been delayed because of the limitations in accuracy, speed, automation and generalization of these methods. This work introduces a novel technique, the Automated Canopy Estimator (ACE) that overcomes many of these challenges to produce accurate estimates of fractional vegetation cover using an unsupervised segmentation process. ACE is shown to outperform nine other segmentation algorithms, consisting of both threshold-based and machine learning approaches, in the segmentation of photographs of four different crops (oat, corn, rapeseed and flax) with an overall accuracy of 89.6%. ACE is similarly accurate (88.7%) when applied to remotely sensed corn, producing FVC estimates that are strongly correlated with ground truth values.

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The Accuracy of Ground-Cover Measurements

Cited by 22 publications

References 16 publications

Digital Photograph Analysis for Measuring Percent Plant Cover in the Arctic

Digital Photograph Analysis for Measuring Percent Plant Cover in the Arctic

Vegetation Sampling for Wetland Delineation: A Review and Synthesis of Methods and Sampling Issues

Increasing the Accuracy and Automation of Fractional Vegetation Cover Estimation from Digital Photographs

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