TY - JOUR
T1 - Capturing Hidden Geochemical Anomalies in Scarce Data by Fractal Analysis and Stochastic Modeling
AU - Madani, Nasser
AU - Sadeghi, Behnam
N1 - Publisher Copyright:
© 2018, International Association for Mathematical Geosciences.
PY - 2019/7/1
Y1 - 2019/7/1
N2 - Fractal/multifractal modeling is a widely used geomathematical approach to capturing different populations in geochemical mapping. The rationale of this methodology is based on empirical frequency density functions attained from global or local distributions. This approach is quite popular because of its simplicity and versatility; it accounts for the frequency and spatial distribution of geochemical data considering self-similarity across a range of scales. Using this technique for detection of geochemical anomalies in scarce data, however, is problematic and can lead to systematic bias in the characterization of the underlying populations. In this paper, an innovative technique is presented that provides good results without a priori assumptions. A simulation approach is adopted for fractal analysis by generating different possible distribution scenarios for the variable under study to reveal the underlying populations that are frequently hidden due to lack of data. The proposed technique is called the global simulated size–number method, and it is validated in a case study with two synthetic datasets and another case study with real dataset from the Ushtagan gold deposit in northeast Kazakhstan.
AB - Fractal/multifractal modeling is a widely used geomathematical approach to capturing different populations in geochemical mapping. The rationale of this methodology is based on empirical frequency density functions attained from global or local distributions. This approach is quite popular because of its simplicity and versatility; it accounts for the frequency and spatial distribution of geochemical data considering self-similarity across a range of scales. Using this technique for detection of geochemical anomalies in scarce data, however, is problematic and can lead to systematic bias in the characterization of the underlying populations. In this paper, an innovative technique is presented that provides good results without a priori assumptions. A simulation approach is adopted for fractal analysis by generating different possible distribution scenarios for the variable under study to reveal the underlying populations that are frequently hidden due to lack of data. The proposed technique is called the global simulated size–number method, and it is validated in a case study with two synthetic datasets and another case study with real dataset from the Ushtagan gold deposit in northeast Kazakhstan.
KW - Fractal modeling
KW - Kernel density function
KW - Monte Carlo simulation
KW - Ushtagan gold deposit
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U2 - 10.1007/s11053-018-9421-4
DO - 10.1007/s11053-018-9421-4
M3 - Article
AN - SCOPUS:85055698064
SN - 1520-7439
VL - 28
SP - 833
EP - 847
JO - Natural Resources Research
JF - Natural Resources Research
IS - 3
ER -