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ISO/ASTM 51707:2002

(Main)

Guide for estimating uncertainties in dosimetry for radiation processing

Guide for estimating uncertainties in dosimetry for radiation processing

ISO/ASTM 51707 defines possible sources of error in dosimetry performed in gamma, X-ray (bremsstrahlung) and electron irradiation facilities and offers procedures for estimating the resulting magnitude of the uncertainties in the measurement results. Basic concepts of measurement, estimate of the measured value of a quantity, 'true' value, error and uncertainty are defined and discussed. Components of uncertainty are discussed and methods are given for evaluating and estimating their values. How these contribute to the standard uncertainty in the reported values of absorbed doses are considered and methods are given for calculating the combined standard uncertainty and an estimate of overall (expanded) uncertainty. The methodology for evaluating components of uncertainty follows ISO procedures. The traditional concepts of precision and bias are not used. Examples are given in five annexes. This International Standard assumes a working knowledge of statistics and several statistical texts are included in the references.

Guide pour l'estimation des incertitudes en dosimétrie pour le traitement par irradiation

General Information

Status
Withdrawn
Publication Date
17-Apr-2002
Withdrawal Date
17-Apr-2002
ICS
17.240 - Radiation measurements
Technical Committee
ISO/TC 85 - Nuclear energy, nuclear technologies, and radiological protection
Drafting Committee
ISO/TC 85 - Nuclear energy, nuclear technologies, and radiological protection
Current Stage
9599 - Withdrawal of International Standard
Completion Date
20-Jul-2005
Ref Project

Relations

Revised
ISO/ASTM 51707:2005 - Guide for estimating uncertainties in dosimetry for radiation processing
Effective Date
15-Apr-2008
Revises
ISO 15572:1998 - Guide for estimating uncertainties in dosimetry for radiation processing
Effective Date
15-Apr-2008

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ISO/ASTM 51707:2002 - Guide for estimating uncertainties in dosimetry for radiation processing
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INTERNATIONAL ISO/ASTM
STANDARD 51707
First edition
2002-03-15
Guide for estimating uncertainties in
dosimetry for radiation processing
Guide pour l’estimation des incertitudes en dosimétrie pour le
traitement par irradiation
Reference number
ISO/ASTM 51707:2002(E)
© ISO/ASTM International 2002

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ISO/ASTM 51707:2002(E)
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© ISO/ASTM International 2002
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ii © ISO/ASTM International 2002 – All rights reserved

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ISO/ASTM 51707:2002(E)
Contents Page
1 Scope . 1
2 Referenced documents . 1
3 Terminology . 1
4 Significance and use . 4
5 Basic concepts—components of uncertainty . 4
6 Evaluation of standard uncertainty . 6
7 Sources of uncertainty . 9
8 Combining uncertainties—statement of uncertainty . 10
9 Information provided by uncertainty . 10
10 Keywords . 11
Annexes . 11
Bibliography . 21
Figure 1 Graphical illustration of value, error, and uncertainty . 7
Figure 2 Graphical illustration of evaluating Type B standard uncertainty . 8
Figure A2.1 Measured specific absorbance versus wavelength for red perspex dosimetry
system . 14
Figure A3.1 Response curve for optichromic dosimetry system . 15
Figure A3.2 Response curve for thin film radiochromic dosimetry system . 16
Figure A3.3 Response curve for red perspex dosimetry system—logarithmic . 17
nd
Figure A3.4 Response curve for red perspex dosimetry system—2 order polynomial . 17
rd
Figure A3.5 Response curve for red perspex dosimetry system—3 order polynomial . 17
th
Figure A3.6 Response curve for red perspex dosimetry system—4 order polynomial . 18
nd
Figure A3.7 Residuals for red perspex dosimetry system—2 order polynomial . 19
rd
Figure A3.8 Residuals for red perspex dosimetry system—3 order polynomial . 18
Figure A4.1 Irradiation t emperature dependence . 19
Table 1 Examples of uncertainty in absorbed dose administered by a gamma ray calibration
facility . 9
Table 2 Examples of uncertainty in dosimeter readings . 9
Table 3 Examples of uncertainty in calibration curve . 9
Table 4 Examples of uncertainty due to routine use . 9
Table A1.1 Example of uncertainties in absorbed dose values for a pool type gamma facility . 11
Table A1.2 Example of uncertainties in absorbed dose values for electron beam facility . 11
Table A1.3 Example of uncertainties in absorbed dose values for irradiation of ceric-cerous
dosimeters in a gammacell 220 irradiator . 11
Table A1.4 Example of uncertainties in calibration of ceric-cerous transfer standard dosimetry
system . 12
Table A1.5 Example of uncertainties in absorbed dose values measured in a production irradiator
using sets of two ceric-cerous dosimeters . 12
Table A1.6 Example of uncertainties in calibration of harwell red 4034 perspex dosimeters in
production irradiator using ceric-cerous transfer standard dosimeters . 12
Table A1.7 Example of overall uncertainty for calibration and use of red perspex dosimeters . 12
Table A2.1 An example of Type A uncertainty in specific absorbance . 13
Table A2.2 Measured absorbance of radiochromic dosimeters irradiated under reproducible
conditions . 13
Table A2.3 Standard deviations from measurement of absorbance . 13
Table A3.1 Example of dosimeter response as a function of absorbed dose for a radiochromic
© ISO/ASTM International 2002 – All rights reserved iii

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ISO/ASTM 51707:2002(E)
optical waveguide dosimetry system . 15
Table A3.2 Curve fit data for linear fit to radiochromic optical waveguide dosimetry system . 15
Table A3.3 Dosimeter response as a function of absorbed dose for a thin film radiochromic
dosimetry system . 16
Table A3.4 Logarithmic transformed linear curve fit data for thin film radiochromic system . 16
Table A3.5 Dosimeter response as a function of absorbed dose for red perspex system . 16
Table A3.6 Logarithmic curve fit data for red perspex system . 17
Table A3.7 Polynomial fit t est parameters . 17
iv © ISO/ASTM International 2002 – All rights reserved

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ISO/ASTM 51707:2002(E)
Foreword
ISO (the International Organization for Standardization) is a worldwide federation of national standards bodies
(ISO member bodies). The work of preparing International Standards is normally carried out through ISO
technical committees. Each member body interested in a subject for which a technical committee has been
established has the right to be represented on that committee. International organizations, governmental and
non-governmental, in liaison with ISO, also take part in the work. ISO collaborates closely with the
International Electrotechnical Commission (IEC) on all matters of electrotechnical standardization.
Draft International Standards adopted by the technical committees are circulated to the member bodies for
voting. Publication as an International Standard requires approval by at least 75% of the member bodies
casting a vote.
ASTM International is one of the world’s largest voluntary standards development organizations with global
participation from affected stakeholders. ASTM technical committees follow rigorous due process balloting
procedures.
A pilot project between ISO and ASTM International has been formed to develop and maintain a group of
ISO/ASTM radiation processing dosimetry standards. Under this pilot project, ASTM Subcommittee E10.01,
Dosimetry for Radiation Processing, is responsible for the development and maintenance of these dosimetry
standards with unrestricted participation and input from appropriate ISO member bodies.
Attention is drawn to the possibility that some of the elements of this International Standard may be the subject
of patent rights. Neither ISO nor ASTM International shall be held responsible for identifying any or all such
patent rights.
International Standard ISO/ASTM 51707 was developed by ASTM Committee E10, Nuclear Technology and
Applications, through Subcommittee E10.01, and by Technical Committee ISO/TC 85, Nuclear Energy.
Annexes A1, A2, A3, A4 and A5 of this International Standard are for information only.
© ISO/ASTM International 2002 – All rights reserved v

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ISO/ASTM 51707:2002(E)
Standard Guide for
Estimating Uncertainties in Dosimetry for Radiation
1
Processing
This standard is issued under the fixed designation ISO/ASTM 51707; the number immediately following the designation indicates the
year of original adoption or, in the case of revision, the year of last revision.
1. Scope E 876 Practice for Use of Statistics In the Evaluation of
5
Spectrometric Data
1.1 This guide defines possible sources of error in dosimetry
E 1026 Practice for Using the Fricke Reference Standard
performed in gamma, x-ray (bremsstrahlung) and electron
3
Dosimetry System
irradiation facilities and offers procedures for estimating the
E 1249 Practice for Minimizing Dosimetry Errors in Radia-
resulting magnitude of the uncertainties in the measurement
tion Hardness Testing of Silicon Electronic Devices Using
results. Basic concepts of measurement, estimate of the mea-
3
Co-60 Sources
sured value of a quantity, “true” value, error and uncertainty
2.2 ISO/ASTM Standards:
are defined and discussed. Components of uncertainty are
51204 Practice for Dosimetry in Gamma Irradiation Facili-
discussed and methods are given for evaluating and estimating
3
ties for Food Processing
their values. How these contribute to the standard uncertainty
51205 Practice for Use of a Ceric-Cerous Sulfate Dosimetry
in the reported values of absorbed dose are considered and
3
System
methods are given for calculating the combined standard
51261 Guide for Selection and Calibration of Dosimetry
uncertainty and an estimate of overall (expanded) uncertainty.
3
Systems for Radiation Processing
The methodology for evaluating components of uncertainty
51275 Practice for Use of a Radiochromic Film Dosimetry
follows ISO procedures (see section 2.3). The traditional
3
System
concepts of precision and bias are not used. Examples are
51276 Practice for Use of a Polymethylmethacrylate Do-
given in five annexes.
3
simetry System
1.2 This guide assumes a working knowledge of statistics.
51310 Practice for the Use of a Radiochromic Optical
Several statistical texts are included in the references (1, 2, 3,
3
2 Waveguide Dosimetry System
4).
3
51401 Practice for Use of a Dichromate Dosimetry System
1.3 This standard does not purport to address all of the
51431 Practice for Dosimetry in Electron and Bremsstrahl-
safety concerns, if any, associated with its use. It is the
3
ung Irradiation Facilities for Food Processing
responsibility of the user of this standard to establish appro-
51607 Practice for Use of the Alanine-EPR Dosimetry
priate safety and health practices and determine the applica-
3
System
bility of regulatory limitations prior to use.
6
2.3 ICRU Reports:
2. Referenced Documents
ICRU Report 14 Radiation Dosimetry: X-Rays and Gamma
Rays with Maximum Photon Energies Between 0.6 and 50
2.1 ASTM Standards:
MeV
E 170 Terminology Relating to Radiation Measurements
3
ICRU Report 17 Radiation Dosimetry: X-Rays Generated at
and Dosimetry
Potentials of 5 to 150 kV
E 177 Practice for Use of the Terms Precision and Accuracy
4
ICRU Report 34 The Dosimetry of Pulsed Radiation
as Applied to Measurement of a Property of a Material
4
ICRU Report 35 Radiation Dosimetry: Electron Beams with
E 178 Practice for Dealing With Outlying Observations
4
Energies Between 1 and 50 MeV
E 456 Terminology Relating to Quality and Statistics
ICRU Report 37 Stopping Powers for Electrons and
E 666 Practice for Calculating Absorbed Dose from Gamma
3
Positrons
or X Radiation
ICRU Report 60 Radiation Quantities and Units
1
This guide is under the jurisdiction of ASTM Committee E10 on Nuclear
3. Terminology
Technology and Applications and is the direct responsibility of Subcommittee
3.1 Definitions:
E10.01 on Dosimetry for Radiation Processing, and is also under the jurisdiction of
ISO/TC 85/WG 3. 3.1.1 absorbed dose, D—quantity of radiation energy im-
Current edition approved Jan. 22, 2002. Published March 15, 2002. Originally
parted per unit mass of a specified material. The unit of
e1
published as ASTM E 1707–95. Last previous ASTM edition E 1707–95 . ASTM
absorbed dose is the gray (Gy) where 1 gray is equivalent to the
e1
E 1707–95 was adopted by ISO in 1998 with the intermediate designation ISO
15572:1998(E). The present International Standard ISO/ASTM 51707:2002(E) is a
revision of ISO 15572.
2
The boldface numbers in parentheses refer to the bibliography at the end of this
5
guide. Annual Book of ASTM Standards, Vol 03.06.
3 6
Annual Book of ASTM Standards, Vol 12.02. Available from International Commission on Radiation Units and Measure-
4
ments, 7910 Woodmont Ave., Suite 800 Bethesda, MD 20814, U.S.A.
Annual Book of ASTM Standards, Vol 14.02.
© ISO/ASTM International 2002 – All rights reserved
1

---------------------- Page: 6 ----------------------
ISO/ASTM 51707:2002(E)
absorption of 1 joule per kilogram ( = 100 rad). The math- minus a true value of the measurand.
ematical relationship is the quotient of de¯ by dm, where de¯ is
3.1.14.1 Discussion—Since a true value cannot be deter-
the mean energy imparted by ionizing radiation to matter of mined, in practice a conventional true value is used. The
mass dm (see ICRU 60).
quantity is sometimes called“ absolute error of measurement”
when it is necessary to distinguish it from relative error. If the
D 5 de¯/dm (1)
result of a measurement depends on the values of quantities
3.1.2 accuracy of measurement—closeness of the agree-
other than the measurand, the errors of the measured values of
ment between the result of a measurement and the true value of
these quantities contribute to the error of the result of the
the measurand.
measurement.
3.1.3 calibration curve—graphical representation of the
3.1.15 expected value—sum of possible values of a variable
relationship between dosimeter response and absorbed dose for
weighted by the probability of the value occurring. It is found
a given dosimetry system. For a mathematical representation,
from the expression:
see response function.
E~v! 5 ( P V (3)
i i i
3.1.4 coeffıcient of variation—sample standard deviation
expressed as a percentage of sample mean value (see 3.1.38
where:
and 3.1.39). th
V = i value, and
i
th
~CV! 5 S /x¯ 3 100 % (2) P = probability of i value.
n21 i
3.1.16 influence quantity—quantity that is not included in
3.1.5 combined standard uncertainty—standard uncertainty
the specification of the measurand but that nonetheless affects
of the result of a measurement when that result is obtained
the result of the measurement.
from the values of a number of other quantities, equal to the
3.1.16.1 Discussion—This quantity is understood to include
positive square root of a sum of terms, the terms being the
values associated with measurement reference standards, ref-
variances or covariances of these other quantities weighted
erence materials, and reference data upon which the result of
according to how the measurement result varies with changes
the measurement may depend, as well as phenomena such as
in these quantities.
short-term instrument fluctuations and parameters such as
3.1.6 confidence interval—an interval estimate that contains
temperature, time, and humidity.
the mean value of a parameter with a given probability.
3.1.17 (measurable) quantity—attribute of a phenomenon,
3.1.7 confidence level—the probability that a confidence
body or substance that may be distinguished qualitatively and
interval estimate contains the value of a parameter.
determined quantitatively; for example, the specific quantity of
3.1.8 corrected result—result of a measurement after cor-
interest in this guide is absorbed dose.
rection for the best estimate of systematic error.
3.1.18 measurand—specific quantity subject to measure-
3.1.9 correction—value that, added algebraically to the
ment.
uncorrected result of a measurement, compensates for system-
3.1.18.1 Discussion—A specification of a measurand may
atic error.
include statements about other quantities such as time, humid-
3.1.9.1 Discussion—The correction is equal to the negative
ity, or temperature. For example, equilibrium absorbed dose in
of the systematic error. Some systematic errors may be
water at 25°C.
estimated and compensated by applying appropriate correc-
3.1.19 measurement—set of operations having the object of
tions. However, since the systematic error cannot be known
determining a value of a quantity.
perfectly, the compensation cannot be complete.
3.1.20 measurement procedure—set of operations, in spe-
3.1.10 correction factor—numerical factor by which the
cific terms, used in the performance of particular measure-
uncorrected result of a measurement is multiplied to compen-
ments according to a given method.
sate for a systematic error.
3.1.21 measurement system—system used for evaluating the
3.1.10.1 Discussion—Since the systematic error cannot be
known perfectly, the compensation cannot be complete. measurand.
3.1.11 coverage factor—numerical factor used as a multi- 3.1.22 measurement traceability—The ability to demon-
strate and document on a continuing basis that the measure-
plier of the combined standard uncertainty in order to obtain an
overall uncertainty. ment results from a particular measurement system are in
agreement with comparable measurement results obtained with
3.1.11.1 Discussion—A coverage factor, k, is typically in
a national standard (or some identifiable and accepted stan-
the range of 2 to 3 (see 8.3).
dard) to a specified uncertainty.
3.1.12 dosimeter batch—quantity of dosimeters made from
a specific mass of material with uniform composition, fabri- 3.1.23 method of measurement—logical sequence of opera-
tions used in the performance of measurements according to a
cated in a single production run under controlled, consistent
conditions and having a unique identification code. given principle.
3.1.13 dosimetry system—a system used for determining 3.1.23.1 Discussion—Methods of measurement may be
qualified in various ways such as: substitution method, differ-
absorbed dose, consisting of dosimeters, measurement instru-
ments and their associated reference standards, and procedures ential method, and null method.
for the system’s use.
3.1.24 outlier—a measurement result that deviates mark-
3.1.14 error (of measurement)—result of a measurement edly from others within a set of measurement results.
© ISO/ASTM International 2002 – All rights reserved
2

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ISO/ASTM 51707:2002(E)
3.1.25 overall uncertainty—quantity defining the interval measurements of the same measurand carried out subject to all
about the result of a measurement within which the values that of the following conditions: the same measurement procedure,
could reasonably be attributed to the measurand may be the same observer, the same measuring instrument, used under
expected to lie with a high level of confidence. the same conditions, the same location, and repetition over a
3.1.25.1 Discussion—Overall uncertainty is referred to as short period of time.
“expanded uncertainty” (see Guide to the Expression of 3.1.33.1 Discussion—These conditions are called “repeat-
7
Uncertainty in Measurement) (5). To associate a specific level ability conditions.” Repeatability may be expressed quantita-
of confidence with the interval defined by the overall uncer- tively in terms of the dispersion characteristics of the results.
tainty requires explicit or implicit assumptions regarding the
3.1.34 reproducibility (of results of measurements)—
probability distribution characterized by the measurement closeness of agreement between the results of measurements of
result and its combined standard uncertainty. The level of
the same measurand, where the measurements are carried out
confidence that may be attributed to this interval can be known under changed conditions such as differing: principle or
only to the extent to which such assumptions may be justified.
method of measurement, observer, measuring instrument, lo-
3.1.26 primary–standard dosimeter—a dosimeter of the cation, conditions of use, and time.
highest metrological quality, established and maintained as an
3.1.34.1 Discussion—A valid statement of reproducibility
absorbed dose standard by a national or international standards requires specification of the conditions changed. Reproducibil-
organization.
ity may be expressed quantitatively in terms of the dispersion
3.1.27 principle of measurement—scientific basis of a characteristics of the results. In this context, results of mea-
method of measurement.
surement are understood to be corrected results.
3.1.28 quadrature—a method of estimating overall uncer-
3.1.35 response function—mathematical representation of
tainty from independent sources by taking the square root of
the relationship between dosimeter response and absorbed dose
the sum of the squares of individual components of uncertainty
for a given dosimetry system.
(for example, coefficient of variation).
3.1.36 result of a measurement—value attributed to a mea-
3.1.29 random error—result of a measurement minus the
surand, obtained by measurement.
mean result of a large number of measurements of the same
3.1.36.1 Discussion—When the term “result of a measure-
measurand that are made under repeatable or reproducible
ment” is used, it should be made clear whether it refers to: the
conditions (see 3.1.33 and 3.1.34).
indication, the uncorrected result, the corrected result, and
3.1.29.1 Discussion—In these definitions (and that for sys-
whether several values are averaged. A complete statement of
tematic error), the term“ mean result of a large number of
the result of the measurement includes information about the
measurements of the same measurand” is understood to mean
uncertainty of the measurement.
“the expected value or mean of all possible measured values of
3.1.37 routine dosimeter—dosimeter calibrated against a
the measurand obtained under conditions of repeatability or
primary-, reference-, or transfer-standard dosimeter and used
reproducibility.” This ensures that the definition cannot be
for routine dosimetry measurement.
misinterpreted to imply that for a series of observations, the
3.1.38 sample mean—a measure of the average value of a
random error of an individual observation is known and can be
data set which is representative of the population. It is
eliminated by applying a correction. The view of this guide is
determined by summing all the values in the data set and
that error is an idealized concept and that errors cannot be
dividing by the number of items (n) in the data set. It is found
known exactly.
from the expression:
3.1.30 reference–standard dosimeter—a dosimeter of high
1
metrological quality, used as a standard to provide measure- x¯ 5 x , i 5 1, 2, 3 . n (4)
( i
n
i
ments traceable to and consistent with measurements made
3.1.39 sample standard deviation, S —measure of disper-
using primary–standard dosimeters. n−1
sion of values expressed as the positive square root of the
3.1.31 reference value (of a quantity)—value attributed to a
sample variance.
specific quantity and accepted, sometimes by convention, as
3.1.40 sample variance—the sum of the squared deviations
having an uncertainty appropriate for a given purpose; for
from the sample mean divided by (n−1), given by the expres-
example, the value assigned to the quantity realized by a
sion:
reference standard.
2
3.1.31.1 Discussion—This is sometimes called “assigned
( ~x 2 x¯!
2 i
S 5 (5)
value,” or “assigned reference value.” n21
~n 2 1!
3.1.32 relative error (of measurement)—error of measure-
where:
ment divided by a true value of the measurand.
x = individual value of parameter with i = 1, 2.n, and
3.1.32.1 Discussion—Since a true value cannot be deter- i
x¯ = mean of n values of parameter (see 3.1.38).
mined, in practice a reference value is used.
3.1.41 standard uncertainty—uncertainty of the results of a
3.1.33 repeatability (of results of measurements)—
measurement expressed as a standard deviation.
closeness of the agreement between the results of successive
3.1.42 systematic error—mean result of a large number of
7 repeated measurements of the same measurand minus a true
Available from International Organization for Standardization, Case Postal 56,
value of the measurand.
CH-1211 Geneva 20 Switzerland.
© ISO/ASTM International 2002 – All rights reserved
3

---------------------- Page: 8 ----------------------
ISO/ASTM 51707:2002(E)
3.1.42.1 Discussion—The repeated measurements are car- Accurate dosimetry is essential in process control (see ISO/
ried out under the conditions of the term “repeatability”. Like ASTM Guide 51261). For absorbed dose measurements to be
true value, systematic error and its causes cannot be completely meaningful, the overall uncertainty associated with these
known. The error of the result of a measurement may often be measurements must be estimated and its magnitude quantified.
considered as arising from a number of random and systematic
NOTE 1—For a comprehensive discussion of various dosimetry meth-
effects that contribute individual components of error to the
ods applicable to the radiation types and energies discussed in this guide,
error of the result (see Terminologies E 170 and E 456, and
see ICRU Reports 14, 17, 34, 35 and Reference (9).
ASTM Practice E 177).
4.2 This guide uses the methodology adopted by the Inter-
3.1.43 traceability—see measurement traceability.
national Organization for Standardization for estimating uncer-
3.1.44 transfer–standard dosimeter—a dosimeter, often a
tainties in dosimetry for radiation processing (see section 2.3).
reference–standard dosimeter, suitable for transport between
ASTM traditionally expresses uncertainty in terms of precision
different locations for use as an intermediary to compare
and bias where precision is a measure of the extent to which
absorbed dose measurements.
replicate measurements made under specified conditions are in
3.1.45 true value—value of measurand that would be ob-
agreement and bias is a systematic error (see ASTM Termi-
tained by a perfect measurement.
nologies E 170 and E 456, and Practice E 177). As seen from
3.1.45.1 Discussion—True values are by nature indetermi-
this standard, sources of uncertainty are evaluated as either
nate and only an idealized concept. In this guide the terms “true
Type A or Type B rather than in terms of precision and bias.
value of a measurand” and“ value of a measurand” are viewed
Both random and systematic error clearly are differentiated
as equivalent (see 5.1.1).
from components of uncertainty. The methodology for treat-
3.1.46 Type A evaluation (of standard uncertainty)—
ment of uncertainties is in conformance with current interna-
method of evaluation of a standard uncertainty by the statistical
tionally accepted practice. (See Guide to the Expression of
analysis of a series of observations.
Uncertainty in Measurement (5).)
3.1.47 Type B evaluation (of standard uncertainty)—
4.3 Although this guide provides a framework
...

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ISO
ISO/ASTM 51940:2022(Main)
Guidance for dosimetry for sterile insects release programs

1.1 This document outlines dosimetric procedures to be followed for the radiation-induced reproductive sterilization of live insects for use in pest management programs. The primary use of such insects is in the Sterile Insect Technique, where large numbers of reproductively sterile insects are released into the field to mate with and thus control pest populations of the same species. A secondary use of sterile insects is as benign hosts for rearing insect parasitoids. A third use is for testing detection traps for fruit flies and moths, and testing mating disruption products for moths. The procedures outlined in this document will help ensure that insects processed with ionizing radiation from gamma, electron, or X-ray sources receive absorbed doses within a predetermined range. Information on effective dose ranges for specific applications of insect sterilization, or on methodology for determining effective dose ranges, is not within the scope of this document. NOTE 1—Dosimetry is only one component of a total quality assurance program to ensure that irradiated insects are adequately sterilized and fully competitive or otherwise suitable for their intended purpose. 1.2 This document provides information on dosimetry for the irradiation of insects for these types of irradiators: selfcontained dry-storage 137Cs or 60Co irradiators, self-contained low-energy X-ray irradiators (maximum processing energies from 150 keV to 300 keV), large-scale gamma irradiators, and electron accelerators (electron and X-ray modes). NOTE 2—Additional, detailed information on dosimetric procedures to be followed in installation qualification, operational qualification, performance qualification, and routine product processing can be found in ISO/ASTM Practices 51608 (X-ray [bremsstrahlung] facilities processing at energies over 300 keV), 51649 (electron beam facilities), 51702 (large-scale gamma facilities), and 52116 (self-contained dry-storage gamma facilities), and in Ref (1)2 (self-contained X-ray facilities). 1.3 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard except for the non-SI units of minute (min) hour (h) and day (d). These non-SI units are accepted for use within the SI system. 1.4 This document is one of a set of standards that provides recommendations for properly implementing and utilizing radiation processing. It is intended to be read in conjunction with ISO/ASTM Practice 52628. 1.5 The absorbed dose for insect sterilization is typically within the range of 20 Gy to 600 Gy. 1.6 This document refers, throughout the text, specifically to reproductive sterilization of insects. It is equally applicable to radiation sterilization of invertebrates from other taxa (for example, Acarina, Gastropoda) and to irradiation of live insects or other invertebrates for other purposes (for example, inducing mutations), provided the absorbed dose is within the range specified in 1.5. 1.7 This document also covers the use of radiation-sensitive indicators for the visual and qualitative indication that the insects have been irradiated (see ISO/ASTM Guide 51539). 1.8 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. 1.9 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ISO
ISO/ASTM 51310:2022(Main)
Practice for use of a radiochromic optical waveguide dosimetry system

1.1 This is a practice for using a radiochromic optical waveguide dosimetry system to measure absorbed dose in materials irradiated by photons and high energy electrons in terms of absorbed dose to water. The radiochromic optical waveguide dosimetry system is generally used as a routine dosimetry system. 1.2 The optical waveguide dosimeter is classified as a Type II dosimeter on the basis of the complex effect of influence quantities (see ISO/ASTM Practice 52628). 1.3 This document is one of a set of standards that provides recommendations for properly implementing dosimetry in radiation processing, and describes a means of achieving compliance with the requirements of ISO/ASTM 52628 for an optical waveguide dosimetry system. It is intended to be read in conjunction with ISO/ASTM Practice 52628. 1.4 This practice applies to radiochromic optical waveguide dosimeters that can be used within part or all of the specified ranges as follows: 1.4.1 The absorbed dose range is from 1 Gy to 20 000 Gy. 1.4.2 The absorbed dose rate is from 0.001 Gy/s to 1000 Gy/s. 1.4.3 The radiation photon energy range is from 1 MeV to 10 MeV. 1.4.4 The radiation electron energy range is from 3 MeV to 25 MeV. 1.4.5 The irradiation temperature range is from –78 °C to +60 °C. 1.5 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard. 1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. 1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ISO
ISO/ASTM 51818:2020(Main)
Practice for dosimetry in an electron beam facility for radiation processing at energies between 80 and 300 keV

This practice covers dosimetric procedures to be followed in installation qualification, operational qualification and performance qualification (IQ, OQ, PQ), and routine processing at electron beam facilities to ensure that the product has been treated with an acceptable range of absorbed doses. Other procedures related to IQ, OQ, PQ, and routine product processing that may influence absorbed dose in the product are also discussed. The electron beam energy range covered in this practice is between 80 and 300 keV, generally referred to as low energy. Dosimetry is only one component of a total quality assurance program for an irradiation facility. Other measures may be required for specific applications such as medical device sterilization and food preservation. Other specific ISO and ASTM standards exist for the irradiation of food and the radiation sterilization of health care products. For the radiation sterilization of health care products, see ISO 11137-1. In those areas covered by ISO 11137-1, that standard takes precedence. For food irradiation, see ISO 14470. Information about effective or regulatory dose limits for food products is not within the scope of this practice (see ASTM F1355 and F1356). This document is one of a set of standards that provides recommendations for properly implementing dosimetry in radiation processing, and describes a means of achieving compliance with the requirements of ISO/ASTM 52628. It is intended to be read in conjunction with ISO/ASTM 52628. This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ISO
ISO/ASTM 52628:2020(Main)
Standard practice for dosimetry in radiation processing

This practice describes the basic requirements that apply when making absorbed dose measurements in accordance with the ASTM E61 series of dosimetry standards. In addition, it provides guidance on the selection of dosimetry systems and directs the user to other standards that provide specific information on individual dosimetry systems, calibration methods, uncertainty estimation and radiation processing applications. This practice applies to dosimetry for radiation processing applications using electrons or photons (gamma- or X-radiation). This practice addresses the minimum requirements of a measurement management system, but does not include general quality system requirements. This practice does not address personnel dosimetry or medical dosimetry. This practice does not apply to primary standard dosimetry systems. This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.

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ISO
ISO/ASTM 51631:2020(Main)
Practice for use of calorimetric dosimetry systems for dose measurements and dosimetry system calibration in electron beams

This practice covers the preparation and use of semiadiabatic calorimetric dosimetry systems for measurement of absorbed dose and for calibration of routine dosimetry systems when irradiated with electrons for radiation processing applications. The calorimeters are either transported by a conveyor past a scanned electron beam or are stationary in a broadened beam. This document is one of a set of standards that provides recommendations for properly implementing dosimetry in radiation processing, and describes a means of achieving compliance with the requirements of ISO/ASTM Practice 52628 for a calorimetric dosimetry system. It is intended to be read in conjunction with ISO/ASTM Practice 52628. The calorimeters described in this practice are classified as Type II dosimeters on the basis of the complex effect of influence quantities. See ISO/ASTM Practice 52628. This practice applies to electron beams in the energy range from 1.5 to 12 MeV. The absorbed dose range depends on the calorimetric absorbing material and the irradiation and measurement conditions. Minimum dose is approximately 100 Gy and maximum dose is approximately 50 kGy. The average absorbed-dose rate range shall generally be greater than 10 Gy·s-1. The temperature range for use of these calorimetric dosimetry systems depends on the thermal resistance of the calorimetric materials, on the calibration range of the temperature sensor, and on the sensitivity of the measurement device. This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ISO
ISO/ASTM 51276:2019(Main)
Practice for use of a polymethylmethacrylate dosimetry system

1.1 This is a practice for using polymethylmethacrylate (PMMA) dosimetry systems to measure absorbed dose in materials irradiated by photons or electrons in terms of absorbed dose to water. The PMMA dosimetry system is generally used as a routine dosimetry system. 1.2 The PMMA dosimeter is classified as a Type II dosim-eter on the basis of the complex effect of influence quantities (see ISO/ASTM Practice 52628). 1.3 This document is one of a set of standards that provides recommendations for properly implementing dosimetry in radiation processing, and describes a means of achieving compliance with the requirements of ISO/ASTM 52628 "Prac-tice for Dosimetry in Radiation Processing" for a PMMA dosimetry system. It is intended to be read in conjunction with ISO/ASTM Practice 52628. 1.4 This practice covers the use of PMMA dosimetry systems under the following conditions: 1.4.1 the absorbed dose range is 0.1 kGy to 150 kGy. 1.4.2 the absorbed dose rate is1×10−2 to1×107 Gy·s−1. 1.4.3 the photon energy range is 0.1 to 25 MeV. 1.4.4 the electron energy range is 3 to 25 MeV. 1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appro-priate safety, health, and environmental practices and deter-mine the applicability of regulatory limitations prior to use. 1.6 This international standard was developed in accor-dance with internationally recognized principles on standard-ization established in the Decision on Principles for the Development of International Standards, Guides and Recom-mendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ISO
ISO/ASTM 51538:2017(Main)
Practice for use of the ethanol-chlorobenzene dosimetry system

1.1 This practice covers the preparation, handling, testing, and procedure for using the ethanol-chlorobenzene (ECB) dosimetry system to measure absorbed dose to water when exposed to ionizing radiation. The system consists of a dosimeter and appropriate analytical instrumentation. For simplicity, the system will be referred to as the ECB system. The ECB dosimeter is classified as a type I dosimeter on the basis of the effect of influence quantities. The ECB dosimetry system may be used as a reference standard dosimetry system or as a routine dosimetry system. 1.2 ISO/ASTM 51538 is one of a set of standards that provides recommendations for properly implementing dosimetry in radiation processing, and describes a means of achieving compliance with the requirements of ISO/ASTM Practice 52628 for the ECB system. It is intended to be read in conjunction with ISO/ASTM Practice 52628. 1.3 This practice describes the mercurimetric titration analysis as a standard readout procedure for the ECB dosimeter when used as a reference standard dosimetry system. Other readout methods (spectrophotometric, oscillometric) that are applicable when the ECB system is used as a routine dosimetry system are described in Annex A1 and Annex A2. 1.4 This practice applies only to gamma radiation, X-radiation/bremsstrahlung, and high energy electrons. 1.5 This practice applies provided the following conditions are satisfied: 1.5.1 The absorbed dose range is between 10 Gy and 2 MGy for gamma radiation and between 10 Gy and 200 kGy for high current electron accelerators (1, 2) (Warning?the boiling point of ethanol chlorobenzene solutions is approximately 80 °C. Ampoules may explode if the temperature during irradiation exceeds the boiling point. This boiling point may be exceeded if an absorbed dose greater than 200 kGy is given in a short period of time.) 1.5.2 The absorbed-dose rate is less than 106 Gy s−1(2). 1.5.3 For radionuclide gamma-ray sources, the initial pho-ton energy is greater than 0.6 MeV. For bremsstrahlung photons, the energy of the electrons used to produce the bremsstrahlung photons is equal to or greater than 2 MeV. For electron beams, the initial electron energy is greater than 8 MeV (3). NOTE 1 The same response relative to 60Co gamma radiation was obtained in high-power bremsstrahlung irradiation produced bya5MeV electron accelerator (4). NOTE 2 The lower energy limits are appropriate for a cylindrical dosimeter ampoule of 12-mm diameter. Corrections for dose gradients across the ampoule may be required for electron beams. The ECB system may be used at lower energies by employing thinner (in the beam direction) dosimeters (see ICRU Report 35). The ECB system may also be used at X-ray energies as low as 120 kVp (5). However, in this range of photon energies the effect caused by the ampoule wall is considerable. NOTE 3 The effects of size and shape of the dosimeter on the response of the dosimeter can adequately be taken into account by performing the appropriate calculations using cavity theory (6). 1.5.4 The irradiation temperature of the dosimeter is within the range from −30 °C to 80 °C. NOTE 4 The temperature dependence of dosimeter response is known only in this range (see 5.2). For use outside this range, the dosimetry system should be calibrated for the required range of irradiation tempera-tures. 1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appro-priate safety and health practices and determine the applica-bility of regulatory limitations prior to use. Specific warnings are given in 1.5.1, 9.2 and 10.2. 1.7 This international standard was developed in accor-dance with internationally recognized principles on standard-ization established in the Decision on Principles for the Development of International Standards, Guides and Recom-mendations issued by the World Trade Organization Technical

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ISO
ISO/ASTM 51205:2017(Main)
Practice for use of a ceric-cerous sulfate dosimetry system

1.1 This practice covers the preparation, testing, and procedure for using the ceric-cerous sulfate dosimetry system to measure absorbed dose to water when exposed to ionizing radiation. The system consists of a dosimeter and appropriate analytical instrumentation. For simplicity, the system will be referred to as the ceric-cerous system. The ceric-cerous dosimeter is classified as a type 1 dosimeter on the basis of the effect of influence quantities. The ceric-cerous system may be used as a reference standard dosimetry system or as a routine dosimetry system. 1.2 ISO/ASTM 51205:2017 is one of a set of standards that provides recommendations for properly implementing dosimetry in radiation processing, and describes a means of achieving compliance with the requirements of ISO/ASTM Practice 52628 for the ceric-cerous system. It is intended to be read in conjunction with ISO/ASTM Practice 52628. 1.3 This practice describes both the spectrophotometric and the potentiometric readout procedures for the ceric-cerous system. 1.4 This practice applies only to gamma radiation, X-radiation/bremsstrahlung, and high energy electrons.

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