Designing a two-rank acceptance sampling plan for quality inspection of geospatial data products

To address the disadvantages of classical sampling plans designed for traditional industrial products, we originally propose a two-rank acceptance sampling plan (TRASP) for the inspection of geospatial data outputs based on the acceptance quality level (AQL). The first rank sampling plan is to inspe...

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Veröffentlicht in:	Computers & geosciences 2011-10, Vol.37 (10), p.1570-1583
Hauptverfasser:	Tong, Xiaohua, Wang, Zhenhua, Xie, Huan, Liang, Dan, Jiang, Zuoqin, Li, Jinchao, Li, Jun
Format:	Artikel
Sprache:	eng
Schlagworte:	Acceptable quality limit (AQL) Acceptance Areal geology Areal geology. Maps case studies computers Design engineering Earth sciences Earth, ocean, space Exact sciences and technology Geologic maps, cartography Hypergeometric distribution Inspection Mathematical analysis Mathematical models Optimization Poisson distribution Quality assurance Sampling spatial data system optimization Two-rank acceptance sampling plan
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container_title	Computers & geosciences
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creator	Tong, Xiaohua Wang, Zhenhua Xie, Huan Liang, Dan Jiang, Zuoqin Li, Jinchao Li, Jun
description	To address the disadvantages of classical sampling plans designed for traditional industrial products, we originally propose a two-rank acceptance sampling plan (TRASP) for the inspection of geospatial data outputs based on the acceptance quality level (AQL). The first rank sampling plan is to inspect the lot consisting of map sheets, and the second is to inspect the lot consisting of features in an individual map sheet. The TRASP design is formulated as an optimization problem with respect to sample size and acceptance number, which covers two lot size cases. The first case is for a small lot size with nonconformities being modeled by a hypergeometric distribution function, and the second is for a larger lot size with nonconformities being modeled by a Poisson distribution function. The proposed TRASP is illustrated through two empirical case studies. Our analysis demonstrates that: (1) the proposed TRASP provides a general approach for quality inspection of geospatial data outputs consisting of non-uniform items and (2) the proposed acceptance sampling plan based on TRASP performs better than other classical sampling plans. It overcomes the drawbacks of percent sampling, i.e., “strictness for large lot size, toleration for small lot size,” and those of a national standard used specifically for industrial outputs, i.e., “lots with different sizes corresponding to the same sampling plan.”
doi_str_mv	10.1016/j.cageo.2011.02.006
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subjects	Acceptable quality limit (AQL) Acceptance Areal geology Areal geology. Maps case studies computers Design engineering Earth sciences Earth, ocean, space Exact sciences and technology Geologic maps, cartography Hypergeometric distribution Inspection Mathematical analysis Mathematical models Optimization Poisson distribution Quality assurance Sampling spatial data system optimization Two-rank acceptance sampling plan
title	Designing a two-rank acceptance sampling plan for quality inspection of geospatial data products
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