A hierarchical modelling approach for measuring reliability of and agreement between two types of magnetic field dosimeter

A hierarchical modelling approach for measuring reliability of and agreement between two types of magnetic field dosimeter

The paper describes how to use hierarchical models to assess the reliability of and agreement between two or more types of measurement device. The idea is illustrated by fitting a linear model with nested random effects to a set of data that was obtained from the calibration of two samples of extrem...

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Veröffentlicht in:Applied statistics 2004-04, Vol.53 (2), p.261-278
Hauptverfasser: Brazzale, Alessandra Rosalba, Salvan, Alberto, Roletti, Stefano
Format: Artikel
Sprache:eng
Schlagworte:
Agreements
Applications
Approximation
Calibration
Childhood
Density
Economic models
Electromagnetism
EMDEXTM meter
Exact sciences and technology
Extremely low frequency magnetic field
Flux density
Frequency
Hierarchical model
Hierarchy
Leukemia
Magnetic fields
Magnetic flux
Mathematics
Measurement
Measurement agreement
Method comparison
Methodology
Multilevel models
Nonparametric inference
Probability and statistics
Probability theory and stochastic processes
Reliability
Reliability, life testing, quality control
Sciences and techniques of general use
Special processes (renewal theory, markov renewal processes, semi-markov processes, statistical mechanics type models, applications)
Statistical methods
Statistical variance
Statistics
Studies
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Beschreibung
Zusammenfassung:The paper describes how to use hierarchical models to assess the reliability of and agreement between two or more types of measurement device. The idea is illustrated by fitting a linear model with nested random effects to a set of data that was obtained from the calibration of two samples of extremely low frequency magnetic field meters. The paper focuses on the formulation of a suitable model that accounts for the various aspects of the calibration protocol and the subsequent interpretation of the parameter estimates. The approach is very flexible and can easily be tuned to the various needs arising in the measurement agreement framework. It can be seen as an extension of the common practice of using a one-way random-effects model to retrieve a measure of agreement.
ISSN:0035-9254
1467-9876
DOI:10.1046/j.1467-9876.2003.05172.x