Presentation is loading. Please wait.

Presentation is loading. Please wait.

Developing a Total Uncertainty Program for the JAF Environmental Laboratory- Lessons Learned James Furfaro James Furfaro Entergy NNE Entergy NNE White.

Published byEmmeline McGee Modified over 9 years ago

Similar presentations

Presentation on theme: "Developing a Total Uncertainty Program for the JAF Environmental Laboratory- Lessons Learned James Furfaro James Furfaro Entergy NNE Entergy NNE White."— Presentation transcript:

1 Developing a Total Uncertainty Program for the JAF Environmental Laboratory- Lessons Learned James Furfaro James Furfaro Entergy NNE Entergy NNE White Plains, NY White Plains, NY

2 The James A. FitzPatrick (JAF) Environmental Laboratory

3 James A. FitzPatrick Environmental Laboratory The JAF Environmental Laboratory does environmental analysis for: -Indian Point Units 2 &3 -James A. FitzPatrick Plant -Nine Mile Point Units 1 &2 -Ginna

4 Self-Assessment of the JAF Environmental Laboratory n Compare the JAF E-lab to an industry standard of excellence, ANSI N42.23. n ANSI N42.23 presents 11 elements for a laboratory QA program. n The JAF E-lab does not calculate total uncertainties for their analytical values.

5 Approach for Calculating Total Uncertainty (TU) n Use NIST Technical Note 1297 and the GUM. n Calculate TUs for each type of analysis. n Look at the major error components of each analysis. n Break the components down into counting errors and systematic errors.

6 “Guide To The Expression of Uncertainty in Measurement” (GUM) n The NIST policy includes the approach given in the “Guide To The Expression of Uncertainty in Measurement.” n The GUM was prepared by individuals from many international organizations. (ISO 1995)

7 “Creating A Level of Confidence for the Measurement” y ± k  c (y) where :  c (y) = the combined standard uncertainty of y. k = coverage factor: 1, 2 or 3. y = the estimate of the quantity you are trying to measure.

8 Root-Sum-Of-The-Squares Methodology

9 Estimate Error Terms - Sample Receipt

10 Sample Preparation

11 Sample Counting and Analysis

12 Data Analysis

13 Another Pair of Hands n In April 2001, hired a contractor to help finish the estimate of the error terms for each individual analysis. n NIST and/or GUM methodology would be used.

14 Problems/Confusion n We were planning on issuing this work as a formal calculation, December 2001. n Our contractor presented us with the calculation. He used a methodology based on Bruckner, LANL. We were told that we couldn’t use the root-sum-of-the squares methodology. n Confusion-NIST uses the root-sum- of-the-squares methodology?

15 A Lesson Learned “When systematic errors are small relative to random errors, the root-sum-of-the-squares methodology provides reasonable estimates of the uncertainty.” Bruckner,1993 (Bruckner,1993)

16 A Lesson Learned (Continued) “When systematic errors are large relative to random errors, the root-sum-of-the-squares methodology leads to uncertainty estimates that are too small.” Bruckner,1993 “When systematic errors are large relative to random errors, the root-sum-of-the-squares methodology leads to uncertainty estimates that are too small.” (Bruckner,1993)

17 Bruckner’s Approach n Empirical formula n It gives realistic estimates when the systematic error is larger than the random error. n Very difficult to use when you have several random and systematic error terms.

18 Four Important Parameters in the GUM n Sensitivity Factors n Avoid/minimize correlating effects n Realistically Estimate Degrees of Freedom n Estimate the type of distribution for Type B evaluation.

19 GUM Method for Estimating TU Estimated standard deviations are summed using the root- sum-of-squares methodology to obtain the total standard deviation (uncertainty) for the measurement.

20 Law of Propagation of Uncertainty (GUM) [  c (y)] = y{ [c 1 x  (x 1 )/x 1 ] 2 + [c 2 x  (x 2 )/x 2 ] 2 + … [c N x  (x N )/x N ] 2 } 1/2 where:  c (y) = the combined standard unc. of the estimate y.  (x i ) = the standard unc. of x i. c i = the sensitivity factor.

21 Confidence Interval (GUM) y ± t  /2, eff x  c (y) where : t  /2, eff = t statistic with a level of significance of . eff = the effective degrees of freedom.

22  2 total =  1 2 +  2 2 +  3 2 + …. Normal Distributions y ± k  total

23 Other Distributions u total 2 = u 1 2 + u 2 2 + u 3 2 + …. u = estimated standard deviation of a component.

24 Effective Degrees of Freedom (GUM) eff = the effective degrees of freedom.

25 Summary of Individual Components-Gamma Spec.* *Uncertainty components reported at 1 standard deviation.

26 Efficiency Versus Energy log-log plot

27 Summary of Individual Components- Beta Analysis *Uncertainty components reported at 1 standard deviation.

28 Summary of Lessons Learned n Estimating error terms is a very time consuming process. n Try to identify the major random and systematic error terms for each analysis. If you overlook an error term, you can always go back and “sharpen the pencil.”

29 Summary of Lessons Learned (Continued) n The GUM allows you to use the Root- Sum-of-the-Squares Methodology. n When the systematic error component is relatively large compared to the random component, the GUM methodology leads to reasonable estimates of the uncertainty. n It does this through the use of four parameters.

30 Dr. Kenneth Inn says: “Always sharpen the pencil...,

31 …but Don’t Sharpen the Marshmallow.”

32 References n ANSI N42.23. “American National Standard Measurement and Associated Instrumentation Quality Assurance for Radioassay Laboratories, IEEE, NY 1997. n Bruckner, L.A. “Propagation of Variance Uncertainty Calculation for an Autopsy Tissue Analysis” Health Physics, 67 (1):24-33, July 1994 (Appendix C). n Bruckner, L.A. “Including Random and Systematic Errors in Measurement Uncertainty” LA-UR-93-932, Los Alamos National Laboratory, NM, 1993 n “Guidelines for Evaluating and Expressing the Uncertainty of NIST Measurement Results” NiST Technical Note 1297, 1994. n “Guide to the Expression of Uncertainty in Measurement” ISO, 1995.

Download ppt "Developing a Total Uncertainty Program for the JAF Environmental Laboratory- Lessons Learned James Furfaro James Furfaro Entergy NNE Entergy NNE White."

Similar presentations

Design of Experiments Lecture I

Design of Experiments Lecture I
Welcome to PHYS 225a Lab Introduction, class rules, error analysis Julia Velkovska.

Welcome to PHYS 225a Lab Introduction, class rules, error analysis Julia Velkovska.
Simple Linear Regression

Simple Linear Regression
1 Introduction to the GUM ( International Guidelines for calculating and expressing uncertainty in measurement) Prepared by Les Kirkup and Bob Frenkel.

1 Introduction to the GUM ( International Guidelines for calculating and expressing uncertainty in measurement) Prepared by Les Kirkup and Bob Frenkel.
EVALUATING BIOASSAY UNCERTANITY USING GUM WORKBENCH ® HPS TECHNICAL SEMINAR April 15, 2011 Brian K. Culligan Fellow Scientist Bioassay Laboratory Savannah.

EVALUATING BIOASSAY UNCERTANITY USING GUM WORKBENCH ® HPS TECHNICAL SEMINAR April 15, 2011 Brian K. Culligan Fellow Scientist Bioassay Laboratory Savannah.
MARLAP Measurement Uncertainty

MARLAP Measurement Uncertainty
Classical Regression III

Classical Regression III
© 2010 Pearson Prentice Hall. All rights reserved Least Squares Regression Models.

© 2010 Pearson Prentice Hall. All rights reserved Least Squares Regression Models.
Chapter 10 Simple Regression.

Chapter 10 Simple Regression.
DATA ANALYSIS I MKT525. Plan of analysis What decision must be made? What are research objectives? What do you have to know to reach those objectives?

DATA ANALYSIS I MKT525. Plan of analysis What decision must be made? What are research objectives? What do you have to know to reach those objectives?
Types of Errors Difference between measured result and true value. u Illegitimate errors u Blunders resulting from mistakes in procedure. You must be careful.

Types of Errors Difference between measured result and true value. u Illegitimate errors u Blunders resulting from mistakes in procedure. You must be careful.
Simple Linear Regression Analysis

Simple Linear Regression Analysis
Uncertainties of measurement in EXCEL

Uncertainties of measurement in EXCEL
CE 428 LAB IV Error Analysis (Analysis of Uncertainty) Almost no scientific quantities are known exactly –there is almost always some degree of uncertainty.

CE 428 LAB IV Error Analysis (Analysis of Uncertainty) Almost no scientific quantities are known exactly –there is almost always some degree of uncertainty.
Understanding sample survey data

Understanding sample survey data
Standard error of estimate & Confidence interval.

Standard error of estimate & Confidence interval.
Confidence Intervals. Estimating the difference due to error that we can expect between sample statistics and the population parameter.

Confidence Intervals. Estimating the difference due to error that we can expect between sample statistics and the population parameter.
HAWKES LEARNING SYSTEMS math courseware specialists Copyright © 2010 by Hawkes Learning Systems/Quant Systems, Inc. All rights reserved. Chapter 14 Analysis.

HAWKES LEARNING SYSTEMS math courseware specialists Copyright © 2010 by Hawkes Learning Systems/Quant Systems, Inc. All rights reserved. Chapter 14 Analysis.
Copyright 2008 © Silliker, All Rights Reserved Interpretation of Lab Results What am I buying? What does it mean? What do I do with it?

Copyright 2008 © Silliker, All Rights Reserved Interpretation of Lab Results What am I buying? What does it mean? What do I do with it?
Fundamentals of Data Analysis Lecture 7 ANOVA. Program for today F Analysis of variance; F One factor design; F Many factors design; F Latin square scheme.

Fundamentals of Data Analysis Lecture 7 ANOVA. Program for today F Analysis of variance; F One factor design; F Many factors design; F Latin square scheme.

Similar presentations

Ads by Google