Extensions to the Theory of Sampling 1. The extended Gy's formula, the segregation paradox and the fundamental sampling uncertainty (FSU)

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Extensions to the Theory of Sampling 1. The extended Gy's formula, the segregation paradox and the fundamental sampling uncertainty (FSU). / Svensmark, Bo.

In: Analytica Chimica Acta, Vol. 1187, 339127, 2021.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Svensmark, B 2021, 'Extensions to the Theory of Sampling 1. The extended Gy's formula, the segregation paradox and the fundamental sampling uncertainty (FSU)', Analytica Chimica Acta, vol. 1187, 339127. https://doi.org/10.1016/j.aca.2021.339127

APA

Svensmark, B. (2021). Extensions to the Theory of Sampling 1. The extended Gy's formula, the segregation paradox and the fundamental sampling uncertainty (FSU). Analytica Chimica Acta, 1187, [339127]. https://doi.org/10.1016/j.aca.2021.339127

Vancouver

Svensmark B. Extensions to the Theory of Sampling 1. The extended Gy's formula, the segregation paradox and the fundamental sampling uncertainty (FSU). Analytica Chimica Acta. 2021;1187. 339127. https://doi.org/10.1016/j.aca.2021.339127

Author

Svensmark, Bo. / Extensions to the Theory of Sampling 1. The extended Gy's formula, the segregation paradox and the fundamental sampling uncertainty (FSU). In: Analytica Chimica Acta. 2021 ; Vol. 1187.

Bibtex

@article{bb3f34b87e314cf98a08212cce3f3a54,
title = "Extensions to the Theory of Sampling 1. The extended Gy's formula, the segregation paradox and the fundamental sampling uncertainty (FSU)",
abstract = "The Theory of Sampling as developed by Pierre Gy is a complete theory that describes sampling errors and how to obtain a representative sample. Unfortunately Gy's formula for prediction of the Fundamental Sampling Error (FSE) can be difficult to use in practice, as it is only valid for binary materials with same size distribution of analyte containing fragments and matrix fragments. An extended Gy's formula for estimation of FSE is derived from Gy's definition of constitutional heterogeneity. This formula is exact with no assumptions and allows prediction of FSE for any particulate material with any number of particle classes in contrast to Gy's formula. The difference is that the only assumption made is that the sampled material can be divided into classes with similar properties for the fragments within each class. The extended Gy's formula is validated by model experiments sampling mixtures of 3–7 components with a riffle splitter with 18 chutes. In most cases the observed sampling error was well predicted by the newly derived, extended Gy's formula. However, in some experiments the observed sampling errors were lower than FSE. This can be explained by the sampling paradox, and the effect is calculated by a new function, the Fundamental Sampling Uncertainty, FSU. The observed results are typically in excellent agreement with the predictions (the predicted uncertainties were on average 0.5% points lower than the observed values). The extended Gy's formula described here is ideal for use in teaching of sampling methods because the experiments can be set up using materials with accurately known properties. The proposed new formula allows accurate prediction of FSE and FSU for complex materials that contain more than two types of particles.",
keywords = "Fundamental sampling error, Gy's formula, Prediction sampling uncertainty, Riffle splitter, Soil sampling, Theory of sampling",
author = "Bo Svensmark",
note = "Publisher Copyright: {\textcopyright} 2021 The Author(s)",
year = "2021",
doi = "10.1016/j.aca.2021.339127",
language = "English",
volume = "1187",
journal = "Analytica Chimica Acta",
issn = "0003-2670",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Extensions to the Theory of Sampling 1. The extended Gy's formula, the segregation paradox and the fundamental sampling uncertainty (FSU)

AU - Svensmark, Bo

N1 - Publisher Copyright: © 2021 The Author(s)

PY - 2021

Y1 - 2021

N2 - The Theory of Sampling as developed by Pierre Gy is a complete theory that describes sampling errors and how to obtain a representative sample. Unfortunately Gy's formula for prediction of the Fundamental Sampling Error (FSE) can be difficult to use in practice, as it is only valid for binary materials with same size distribution of analyte containing fragments and matrix fragments. An extended Gy's formula for estimation of FSE is derived from Gy's definition of constitutional heterogeneity. This formula is exact with no assumptions and allows prediction of FSE for any particulate material with any number of particle classes in contrast to Gy's formula. The difference is that the only assumption made is that the sampled material can be divided into classes with similar properties for the fragments within each class. The extended Gy's formula is validated by model experiments sampling mixtures of 3–7 components with a riffle splitter with 18 chutes. In most cases the observed sampling error was well predicted by the newly derived, extended Gy's formula. However, in some experiments the observed sampling errors were lower than FSE. This can be explained by the sampling paradox, and the effect is calculated by a new function, the Fundamental Sampling Uncertainty, FSU. The observed results are typically in excellent agreement with the predictions (the predicted uncertainties were on average 0.5% points lower than the observed values). The extended Gy's formula described here is ideal for use in teaching of sampling methods because the experiments can be set up using materials with accurately known properties. The proposed new formula allows accurate prediction of FSE and FSU for complex materials that contain more than two types of particles.

AB - The Theory of Sampling as developed by Pierre Gy is a complete theory that describes sampling errors and how to obtain a representative sample. Unfortunately Gy's formula for prediction of the Fundamental Sampling Error (FSE) can be difficult to use in practice, as it is only valid for binary materials with same size distribution of analyte containing fragments and matrix fragments. An extended Gy's formula for estimation of FSE is derived from Gy's definition of constitutional heterogeneity. This formula is exact with no assumptions and allows prediction of FSE for any particulate material with any number of particle classes in contrast to Gy's formula. The difference is that the only assumption made is that the sampled material can be divided into classes with similar properties for the fragments within each class. The extended Gy's formula is validated by model experiments sampling mixtures of 3–7 components with a riffle splitter with 18 chutes. In most cases the observed sampling error was well predicted by the newly derived, extended Gy's formula. However, in some experiments the observed sampling errors were lower than FSE. This can be explained by the sampling paradox, and the effect is calculated by a new function, the Fundamental Sampling Uncertainty, FSU. The observed results are typically in excellent agreement with the predictions (the predicted uncertainties were on average 0.5% points lower than the observed values). The extended Gy's formula described here is ideal for use in teaching of sampling methods because the experiments can be set up using materials with accurately known properties. The proposed new formula allows accurate prediction of FSE and FSU for complex materials that contain more than two types of particles.

KW - Fundamental sampling error

KW - Gy's formula

KW - Prediction sampling uncertainty

KW - Riffle splitter

KW - Soil sampling

KW - Theory of sampling

U2 - 10.1016/j.aca.2021.339127

DO - 10.1016/j.aca.2021.339127

M3 - Journal article

C2 - 34753570

AN - SCOPUS:85117146359

VL - 1187

JO - Analytica Chimica Acta

JF - Analytica Chimica Acta

SN - 0003-2670

M1 - 339127

ER -

ID: 287071965