TY - GEN
T1 - Finding prediction limits for a future number of failures in the prescribed time interval under parametric uncertainty
AU - Nechval, Nicholas
AU - Purgailis, Maris
AU - Rozevskis, Uldis
AU - Bruna, Inta
AU - Nechval, Konstantin
PY - 2012
Y1 - 2012
N2 - Computing prediction intervals is an important part of the forecasting process intended to indicate the likely uncertainty in point forecasts. Prediction intervals for future order statistics are widely used for reliability problems and other related problems. In this paper, we present an accurate procedure, called 'within-sample prediction of order statistics', to obtain prediction limits for the number of failures that will be observed in a future inspection of a sample of units, based only on the results of the first in-service inspection of the same sample. The failure-time of such units is modeled with a two-parameter Weibull distribution indexed by scale and shape parameters β and δ, respectively. It will be noted that in the literature only the case is considered when the scale parameter β is unknown, but the shape parameter δ is known. As a rule, in practice the Weibull shape parameter δ. is not known. Instead it is estimated subjectively or from relevant data. Thus its value is uncertain. This δ uncertainty may contribute greater uncertainty to the construction of prediction limits for a future number of failures. In this paper, we consider the case when both parameters β and δ are unknown. In literature, for this situation, usually a Bayesian approach is used. Bayesian methods are not considered here. We note, however, that although subjective Bayesian prediction has a clear personal probability interpretation, it is not generally clear how this should be applied to non-personal prediction or decisions. Objective Bayesian methods, on the other hand, do not have clear probability interpretations in finite samples. The technique proposed here for constructing prediction limits emphasizes pivotal quantities relevant for obtaining ancillary statistics and represents a special case of the method of invariant embedding of sample statistics into a performance index applicable whenever the statistical problem is invariant under a group of transformations, which acts transitively on the parameter space. This technique represents a simple and computationally attractive statistical method based on the constructive use of the invariance principle in mathematical statistics. Frequentist probability interpretation of the technique considered here is clear. Application to other distributions could follow directly. An example is given.
AB - Computing prediction intervals is an important part of the forecasting process intended to indicate the likely uncertainty in point forecasts. Prediction intervals for future order statistics are widely used for reliability problems and other related problems. In this paper, we present an accurate procedure, called 'within-sample prediction of order statistics', to obtain prediction limits for the number of failures that will be observed in a future inspection of a sample of units, based only on the results of the first in-service inspection of the same sample. The failure-time of such units is modeled with a two-parameter Weibull distribution indexed by scale and shape parameters β and δ, respectively. It will be noted that in the literature only the case is considered when the scale parameter β is unknown, but the shape parameter δ is known. As a rule, in practice the Weibull shape parameter δ. is not known. Instead it is estimated subjectively or from relevant data. Thus its value is uncertain. This δ uncertainty may contribute greater uncertainty to the construction of prediction limits for a future number of failures. In this paper, we consider the case when both parameters β and δ are unknown. In literature, for this situation, usually a Bayesian approach is used. Bayesian methods are not considered here. We note, however, that although subjective Bayesian prediction has a clear personal probability interpretation, it is not generally clear how this should be applied to non-personal prediction or decisions. Objective Bayesian methods, on the other hand, do not have clear probability interpretations in finite samples. The technique proposed here for constructing prediction limits emphasizes pivotal quantities relevant for obtaining ancillary statistics and represents a special case of the method of invariant embedding of sample statistics into a performance index applicable whenever the statistical problem is invariant under a group of transformations, which acts transitively on the parameter space. This technique represents a simple and computationally attractive statistical method based on the constructive use of the invariance principle in mathematical statistics. Frequentist probability interpretation of the technique considered here is clear. Application to other distributions could follow directly. An example is given.
KW - Number of failures
KW - prediction limits
KW - Weibull distribution
UR - https://www.scopus.com/pages/publications/84862210753
UR - https://link.springer.com/chapter/10.1007/978-3-642-30782-9_20
U2 - 10.1007/978-3-642-30782-9_20
DO - 10.1007/978-3-642-30782-9_20
M3 - Conference paper
AN - SCOPUS:84862210753
SN - 9783642307812
T3 - Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)
SP - 286
EP - 301
BT - Analytical and Stochastic Modeling Techniques and Applications - 19th International Conference, ASMTA 2012, Proceedings
T2 - 19th International Conference on Analytical and Stochastic Modelling and Applications, ASMTA 2012
Y2 - 4 June 2012 through 6 June 2012
ER -