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ASTM E2555-07

(Practice)

Standard Practice for Factors and Procedures for Applying the MIL-STD-105 Plans in Life and Reliability Inspection

Standard Practice for Factors and Procedures for Applying the MIL-STD-105 Plans in Life and Reliability Inspection

SCOPE
1.1 This practice presents a procedure and related tables of factors for adapting Practice E 2234 (equivalent to MIL-STD-105) sampling plans to acceptance sampling inspection when the item quality of interest is life length or reliability. Factors are provided for three alternative criteria for lot evaluation: mean life, hazard rate, and reliable life. Inspection of the sample is by attributes with testing truncated at the end of some prearranged period of time. The Weibull distribution, together with the exponential distribution as a special case, is used as the underlying statistical model.
1.2 A system of units is not specified by this practice.
1.3 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 and health practices and determine the applicability of regulatory limitations prior to use.

General Information

Status
Historical
Publication Date
28-Feb-2007
ICS
07.020 - Mathematics
Technical Committee
E11 - Quality and Statistics
Drafting Committee
E11.30 - Statistical Quality Control
Current Stage
Ref Project

Relations

Replaced By
ASTM E2555-07(2012) - Standard Practice for Factors and Procedures for Applying the MIL-STD-105 Plans in Life and Reliability Inspection
Effective Date
01-May-2012
Referred By
ASTM E3291-21 - Standard Guide for Reliability Demonstration Testing
Effective Date
01-Mar-2007
Referred By
ASTM E2696-21 - Standard Practice for Life and Reliability Testing Based on the Exponential Distribution
Effective Date
01-Mar-2007
Referred By
ASTM E3159-21 - Standard Guide for General Reliability
Effective Date
01-Mar-2007
Referred By
ASTM E456-13a(2022) - Standard Terminology Relating to Quality and Statistics
Effective Date
01-Mar-2007

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ASTM E2555-07 - Standard Practice for Factors and Procedures for Applying the MIL-STD-105 Plans in Life and Reliability InspectionASTM E2555-07 - Standard Practice for Factors and Procedures for Applying the MIL-STD-105 Plans in Life and Reliability Inspection
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ASTM E2555-07 - Standard Practice for Factors and Procedures for Applying the MIL-STD-105 Plans in Life and Reliability Inspection
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NOTICE: This standard has either been superseded and replaced by a new version or withdrawn.
Contact ASTM International (www.astm.org) for the latest information
An American National Standard
Designation:E2555–07
Standard Practice for
Factors and Procedures for Applying the MIL-STD-105 Plans
in Life and Reliability Inspection
This standard is issued under the fixed designation E2555; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope 3.1.2.2 Discussion—Thisdefinitionsupersedesthatgivenin
MEL-STD-105E.
1.1 This practice presents a procedure and related tables of
3.1.2.3 Discussion—A sampling plan and an AQL are
factors for adapting Practice E2234 (equivalent to MIL-STD-
chosen in accordance with the risk assumed. Use of a value of
105) sampling plans to acceptance sampling inspection when
AQL for a certain defect or group of defects indicates that the
the item quality of interest is life length or reliability. Factors
sampling plan will accept the great majority of the lots or
are provided for three alternative criteria for lot evaluation:
batches provided the process average level of percent defective
mean life, hazard rate, and reliable life. Inspection of the
(or defects per hundred units) in these lots or batches are no
sampleisbyattributeswithtestingtruncatedattheendofsome
greater than the designated value of AQL. Thus, the AQL is a
prearranged period of time. The Weibull distribution, together
designated value of percent defective (or defects per hundred
with the exponential distribution as a special case, is used as
units) for which lots will be accepted most of the time by the
the underlying statistical model.
sampling procedure being used. The sampling plans provided
1.2 A system of units is not specified by this practice.
herein are so arranged that the probability of acceptance at the
1.3 This standard does not purport to address all of the
designated AQL value depends upon the sample size, being
safety concerns, if any, associated with its use. It is the
generally higher for large samples than for small ones, for a
responsibility of the user of this standard to establish appro-
given AQL. The AQL alone does not identify the chances of
priate safety and health practices and determine the applica-
accepting or rejecting individual lots or batches but more
bility of regulatory limitations prior to use.
directly relates to what might be expected from a series of lots
2. Referenced Documents
or batches, provided the steps indicated in this refer to the
operating characteristic curve of the plan to determine the
2.1 ASTM Standards:
relative risks.
E456 Terminology Relating to Quality and Statistics
3.1.3 consumer’s risk, n—probability that a lot having
E2234 Practice for Sampling a Stream of Product by
specified rejectable quality level will be accepted under a
Attributes Indexed by AQL
defined sampling plan.
3. Terminology
3.1.4 double sampling plan, n—a multiple sampling plan in
which up to two samplings can be taken and evaluated to
3.1 Definitions:
accept or reject a lot.
3.1.1 The terminology defined inTerminology E456 applies
3.1.5 limiting quality level (LQL), n—quality level having a
to this practice unless modified herein.
specified consumer’s risk for a given sampling plan.
3.1.2 acceptance quality level (AQL), n—quality limit that
3.1.6 lot, n—a definite quantity of a product or material
is the worst tolerable process average when a continuing series
accumulated under conditions that are considered uniform for
of lots is submitted for acceptance sampling. E2234
sampling purposes.
3.1.2.1 Discussion—This term is often referred to as the
3.1.6.1 Discussion—The lot for sampling may differ from a
“acceptance quality limit.”
collection of units designated as a batch for other purposes, for
example, production, shipment, and so forth.
This practice is under the jurisdiction ofASTM Committee E11 on Quality and
3.1.7 multiple sampling plan, n—a sampling plan in which
Statistics and is the direct responsibility of Subcommittee E11.30 on Statistical
successive samples from a lot are drawn and after each sample
Quality Control.
Current edition approved March 1, 2007. Published April 2007. DOI: 10.1520/ is inspected a decision is made to accept the lot, reject the lot,
E2555-07.
or to take another sample, based on quality level of the
For referenced ASTM standards, visit the ASTM website, www.astm.org, or
combined samples.
contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
Standards volume information, refer to the standard’s Document Summary page on
the ASTM website.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959, United States.
E2555–07
3.1.7.1 Discussion—When the quality is much less or much 3.2.7 Weibull distribution, n—probability distribution hav-
more than the AQL, the decision can be made on the first ing cumulative distribution:
sample, which is smaller than that of a single sampling plan
b
t – g
function F~t! 5 1 – exp – , t.g and probability density
S S D D
with equivalent acceptance quality level. For samples that are
h
closetotheAQLinquality,additionalsamplesarerequiredand
b21 b
b t – g t – g
the total sample size will be larger than the corresponding function f~t! 5 exp –
S D S S D D
h h h
single sampling plan.
3.2.7.1 Discussion—TheWeibulldistributioniswidelyused
3.1.8 sample, n—group of items, observations, test results,
for modeling product life. It can take a wide variety of shapes
or portions of material taken from a large collection of items,
andalsothecharacteristicsofothertypesofdistributionsbased
observations,testresults,orquantitiesofmaterialthatservesto
on the value of its parameters. g is called the location,
provide information that may be used as a basis for making a
minimum life, or threshold parameter and defines the lower
decision concerning the larger collection. E2234
limit of the distribution (Fig. 1). h is called the scale or
3.2 Definitions of Terms Specific to This Standard:
characteristic life parameter and is equal to the 63.2 percentile
3.2.1 acceptance number, n—the maximum number of
of the distribution, minus g (Fig. 2). b is the shape parameter
failed items allowed in the sample for the lot to be accepted
(Fig. 3). The exponential distribution is the special case where
using a single or multiple sampling plan.
g = 0 and b=l.
3.2.2 hazard rate, n—differential fraction of items failing at
time t among those surviving up to time t, symbolized by h(t).
4. Significance and Use
3.2.2.1 Discussion—h(t) is also referred to as the instanta-
4.1 The procedure and tables presented in this practice are
neous failure rate at time t. It is related to the probability
based on the use of the Weibull distribution in acceptance
density and cumulative distribution functions by h(t) = f(t)/
sampling inspection. Details of this work, together with tables
(l – F(t)).
of sampling plans of other forms, have been published previ-
3.2.3 mean life, n—average time that items in the lot or
ously. See Refs (1-3). Since the basic computations required
population are expected to operate before failure.
havealreadybeenmade,ithasbeenquiteeasytoprovidethese
3.2.3.1 Discussion—Thismetricisoftenreferredtoasmean
new factors. No changes in method or details of application
time to failure (MTTF) or mean time before failure (MTBF).
have been made over those described in the publications
3.2.4 rejection number, n—the minimum number of failed
referencedabove.Forthisreason,thetextportionofthisreport
items in the sample that will cause the lot to be rejected under
has been briefly written. Readers interested in further details
a given sampling plan.
3.2.5 reliable life (r ), n—life beyond which some specified
r
proportion, r, of the items in the lot or population will survive.
3.2.6 test truncation time (t), n—amount of time sampled 3
The boldface numbers in parentheses refer to the list of references at the end of
items are allowed to be tested. this standard.
FIG. 1 Effect of the Parameter g on the Weibull Probability
Density Function, f(t)
E2555–07
FIG. 2 Effect of the Parameter h on the Weibull Probability
Density Function, f(t)
FIG. 3 Effect of the Parameter b on the Weibull Probability
Density Function, f(t)
are referred to these previous publications. Other sources of 4.2.4 Determine the number of sample items that failed
material on the underlying theory and approach are also during the test period.
available (4-7). 4.2.5 Compare the number of items that failed with the
4.2 The procedure to be used is essentially the same as the number allowed under the selected Practice E2234 plan.
one normally used for attribute sampling inspection. The only 4.2.6 If the number that failed is equal to or less than the
difference is that sample items are tested for life or survival acceptable number, accept the lot; if the number failing
instead of for some other property. For single sampling, the exceeds the acceptable number, reject the lot.
following are the required steps: 4.3 Both the sample sizes and the acceptance numbers used
4.2.1 Using the tables of factors provided in Annex A1, are those specified by Practice E2234 plans. It will be assumed
select a suitable sampling inspection plan from those tabulated in the section on examples that single sampling plans will be
in Practice E2234. used. However, the matching double sampling and multiple
4.2.2 Drawatrandomasampleofitemsofthesizespecified sampling plans provided in MIL-STD-105 can be used if
by the selected Practice E2234 plan. desired. The corresponding sample sizes and acceptance and
4.2.3 Place the sample of items on life test for the specified rejection numbers are used in the usual way. The specified test
period of time, t. truncation time, t, must be used for all samples.
E2555–07
4.4 The probability of acceptance for a lot under this terms of these ratios, the probability of acceptance will be high
procedure depends only on the probability of a sample item for lots whose mean life meets the specified requirement. The
failing before the end of the test truncation time, t. For this actualprobabilityofacceptancewillvaryfromplantoplanand
reason, the actual life at failure need not be determined; only maybereadfromtheassociatedoperatingcharacteristiccurves
thenumberofitemsfailingisofinterest.Liferequirementsand supplied in MDL-STD-105. The curves are entered by using
test time specifications need not necessarily be measured in the corresponding p’(%) value. Annex Table 1B lists 100t/µ
chronologicaltermssuchasminutesorhours.Forexample,the ratios at the LQLfor the quality level at which the consumer’s
life measure may be cycles of operation, revolutions, or miles risk is 0.10. Annex Table 1C lists corresponding 100t/µ ratios
of travel. for a consumer’s risk of 0.05.
4.5 Theunderlyinglifedistributionassumedinthisstandard 4.8.1 These ratios are to be used directly for the usual case
is the Weibull distribution (note that the exponential distribu- for which the value for the Weibull location or threshold
tion is a special case of the Weibull). The Weibull model has parameter (g) can be assumed as zero. If g is not zero but has
three parameters. One parameter is a scale or characteristic life someotherknownvalue,allthatshallbedoneistosubtractthe
parameter. For these plans and procedures, the value for this value for g from t to get t and from m to get m . These
0 0
parameter need not be known; the techniques used are inde- transformed values, t and m , are then employed in the use of
0 0
pendent of its magnitude. A second parameter is a location or the tables and for all other computations.Asolution in terms of
“guaranteedlife”parameter.Intheseplansandprocedures,itis m and t can then be converted back to actual or absolute
0 0
assumed that this parameter has a value of zero and that there values by adding the value for g to each.
is some risk of item failure right from the start of life. If this is
5. Examples, Mean Life Ratio
not the case for some applications, a simple modification in
5.1 A Practice E2234 acceptance sampling inspection plan
procedure is available. The third parameter, and the one of
is to be applied to incoming lots of product for which the mean
importance, is the shape parameter, b. The magnitude of the
item life is the property of interest.An acceptable mean life of
conversion factors used in the procedures described in this
2000 h has been specified, and under the plan, used lots with a
report depends directly on the value for this parameter. For this
mean life of this value or greater shall have a high probability
reason, the magnitude of the parameter shall be known through
of acceptance. A testing truncation time of t = 250 h has been
experience with the product or shall be estimated from past
specified. From past experience it has been determined that the
research, engineering, or inspection data. Estimation proce-
Weibull distribution can be used as a life-length model and a
dures are available and are outlined in Ref (1).
shape parameter value of 2.5 and a location or threshold
4.6 Forthecommoncaseofrandomchancefailureswiththe
parameter value of 0 can be assumed. Single sampling is to be
failurerateconstantovertime,ratherthanfailuresasaresultof
used. A sample of as many as 300 items or so can be tested at
“infant mortality” or wearout, a value of 1 for the shape
one time. An appropriate sampling inspection plan shall be
parameter shall be assumed. With this parameter value, the
selected. Also, the consumer’s risk under use of the selected
Weibull distribution reduces to the exponential. Tables of
plan shall be determined.
conversion factors are provided in Annex A1 for 15 selected
5.1.1 Computation of the 100t/µ ratio at the AQL gives
shape parameter values ranging from ⁄2 to 10, the range
100t/µ = 100 3 250/2000 = 12.5. Examination of the ratios in
commonly encountered in industrial and technical practice.
the column for a shape parameter of 2.5 in Annex Table 1A
The value 1, used for the exponential case, is included. Factors
discloses a value of 12.4 for anAQLof 0.40 in p’(%) terms.A
for other required shape parameter values within this range
plan with this AQL is accordingly to be used. Reference now
may be obtained approximately by interpolation. A more
to Practice E2234 indicates for Sample Size Code Letter M the
complete discussion of the relationship between failure pat-
sample size is 315; this value will accordingly be used.
terns and the Weibull parameters can be found in Refs (1-3).
ExaminationoftheMasterTableforNormalInsp
...

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This practice establishes lot or batch sampling plans and procedures for inspection by attributes using MIL-STD-105E as a basis for sampling a steady stream of lots indexed by acceptance quality limit (AQL). It provides the sampling plans of MIL-STD-105E in ASTM format for use by ASTM committees and others and recognizes the continuing usage of MIL-STD-105E in industries supported by ASTM. This practice also establishes lot or batch sampling plans and procedures for inspection by attributes.
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ABSTRACT
This practice presents a procedure and related tables of factors for adapting Practice E2234 (equivalent to MIL-STD105) sampling plans to acceptance sampling inspection when the item quality of interest is life length or reliability. Factors are provided for three alternative criteria for lot evaluation: mean life, hazard rate, and reliable life. Inspection of the sample is by attributes with testing truncated at the end of some prearranged period of time. The Weibull distribution, together with the exponential distribution as a special case, is used as the underlying statistical model. The procedure and tables presented in this practice are based on the use of the Weibull distribution in acceptance sampling inspection.
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SIGNIFICANCE AND USE
4.1 The creation of a standardized test method generally follows a series of steps from inception to approval and ongoing use. In all such stages there are questions of how well the test method performs.  
4.1.1 Assessments of a new or existing test method generally involve statistical planning and analysis. This standard recommends what approaches may be taken and indicates which standards may be used to perform such assessments.  
4.2 This standard introduces a series of phases which are recommended to be considered during the life cycle of a test method as depicted in Fig. 1. These begin with a design phase where the standard is initially prepared. A development phase involves a variety of experiments that allow further refinement and understanding of how the test method performs within a laboratory. In an evaluation phase the test method is then examined by way of interlaboratory studies resulting in precision and bias statistics which are published in the standard. Finally, the test method is subject to a monitoring phase.
FIG. 1 Sequence of Steps  
4.3 All ASTM test methods are required to include statements on precision and bias.3  
4.4 Since ASTM began to require all test methods to have precision and bias statements that are based on interlaboratory studies, there has been increased concern regarding what statistical experiments and procedures to use during the development of the test methods. Although there exists a wide range of statistical procedures, there is a small group of generally accepted techniques that are beneficial to follow. This guide is designed to provide a brief overview of these procedures and to suggest an appropriate sequence of conducting these procedures.  
4.5 Statistical procedures often result in interpretations that are not absolutes. Sometimes the information obtained may be inadequate or incomplete, which may lead to additional questions and the need for further experimentation. Information outside the data is also impo...
SCOPE
1.1 This guide identifies statistical procedures for use in developing new test methods or revising or evaluating existing test methods, or both.  
1.2 This guide also cites statistical procedures especially useful in the application of test methods.  
1.3 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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ASTM
ASTM E2234-09(2023)(Practice)
Standard Practice for Sampling a Stream of Product by Attributes Indexed by AQL

ABSTRACT
This practice establishes lot or batch sampling plans and procedures for inspection by attributes using MIL-STD-105E as a basis for sampling a steady stream of lots indexed by acceptance quality limit (AQL). It provides the sampling plans of MIL-STD-105E in ASTM format for use by ASTM committees and others and recognizes the continuing usage of MIL-STD-105E in industries supported by ASTM. This practice also establishes lot or batch sampling plans and procedures for inspection by attributes.
SIGNIFICANCE AND USE
4.1 Purpose—This publication establishes lot or batch sampling plans and procedures for inspection by attributes. This publication shall not be interpreted to supersede or conflict with any contractual requirements. The words “accept,” “acceptance,” “acceptable,” etc, refer only to the contractor’s use of the sampling plans contained in this standard and do not imply an agreement by the customer (formerly “Government” in original text) to accept any product. Determination of acceptability by the customer shall be as described in contractual documents. The sampling plans described in this standard are applicable to AQL’s of 0.01 % or higher and are therefore not suitable for applications where quality levels in the range of parts per million levels can be realized.  
4.2 Application—Sampling plans designated in this publication are applicable, but not limited, to inspection of the following: (1) end items, (2) components and raw materials, (3) operations or services, (4) materials in process, (5) supplies in storage, (6) maintenance operations, (7) data or records, (8) administrative procedures. These plans are intended primarily to be used for a continuing series of lots or batches. The plans may also be used for the inspection of isolated lots or batches, but, in this latter case, the user is cautioned to consult the operating characteristic curves to find a plan which will yield the desired protection (see 6.11).
SCOPE
1.1 This practice establishes lot or batch sampling plans and procedures for inspection by attributes using MIL-STD-105E as a basis for sampling a steady stream of lots indexed by acceptance quality limit (AQL).  
1.2 This practice provides the sampling plans of MIL-STD-105E in ASTM format for use by ASTM committees and others. It recognizes the continuing usage of MIL-STD-105E in industries supported by ASTM. Most of the original text in MIL-STD-105E is preserved in Sections 4 – 6 of this practice.  
1.3 No system of units is specified in this standard.  
1.4 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.  
1.5 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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ASTM E456-13a(2022)e1(Terminology)
Standard Terminology Relating to Quality and Statistics

ABSTRACT
This standard is the general terminology standard for terms defined in the standards of Committee E11 on Quality and Statistics. A term in this standard which lists an attribution to an E11 technical standard indicates that the standard is normative for that term. Term definitions that are similar to ISO 3534 will be noted in this standard, but ISO 3534 will not be considered normative for any E11 terms.
SCOPE
1.1 This standard is the general terminology standard for terms defined in the standards of Committee E11 on Quality and Statistics.  
1.2 A term in this standard which lists an attribution to an E11 technical standard indicates that the standard is normative for that term. Any changes in the term definition in the normative standard will be editorially changed in this standard. Any terms added to an E11 standard will be editorially added to this standard with an attribution to that standard.  
1.3 Term definitions that are similar to ISO 3534 will be noted in this standard, but ISO 3534 will not be considered normative for any E11 terms.  
1.4 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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ASTM
ASTM D6026-21(Practice)
Standard Practice for Using Significant Digits and Data Records in Geotechnical Data

SIGNIFICANCE AND USE
5.1 The guidelines presented in this practice for retaining significant digits and rounding numbers may be adopted by the using agency or user. Their adoption should generally be used to calculate and record data when specified requirements are not included in a standard.  
5.2 While this practice originated when most geotechnical data were manually collected and recorded on data forms, tables, or into computers, the use of digital acquisition, calculations, and reporting of data has become more common. When calculators and computers are used for data collection, the significant digits may not meet the requirements specified in this standard. Nevertheless, their use shall not be regarded as nonconforming with this practice.  
5.3 The guidelines presented herein should not be interpreted as absolute rules but as guides to calculate and report observed or test data without exaggerating or degrading the precision of the values.  
5.3.1 The guidelines presented emphasize recording data to enough significant digits or the number of decimal places to allow sensitivity and variability analyses to be performed.
SCOPE
1.1 Using significant digits in geotechnical data involves the processes of collecting, calculating, and recording either measured values or calculated values (results) or both. This practice is intended to promote uniformity in recording significant digits for measured and calculated values involving geotechnical data.  
1.2 The guidelines presented are industry standard and are representative of the significant digits that should be retained in general. The guidelines do not consider material variation, the purpose for obtaining the data, special purpose studies, or any considerations for the user's objectives, and it is common practice to increase or reduce significant digits of reported data to be commensurate with these considerations.  
1.3 It is beyond the scope of this practice to consider significant digits used in analysis methods for engineering design.  
1.4 This practice accepts a variation of the traditional rounding method that recognizes the algorithm common to most hand-held calculators and computers, see 6.2.3. The traditional rounding method (see 6.2) is in accordance with Practice E29, ASTM Manual 7, or IEEE/ASTM SI 10.
Note 1: Calculators and computers often present and use many digits in their output and calculations, which may not all be significant. It is the responsibility of the programmer and user to make sure that the measured and calculated values are handled, interpreted and reported properly using these guidelines.  
1.5 This practice offers a set of instructions for performing one or more specific operations. This document cannot replace education or experience and should be used in conjunction with professional judgment. Not all aspects of this practice may be applicable in all circumstances. This ASTM standard is not intended to represent or replace the standard of care by which the adequacy of a given professional service must be judged, nor should this document be applied without consideration of a project’s many unique aspects. The word “Standard” in the title means only that the document has been approved through the ASTM consensus process.  
1.6 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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ASTM
ASTM E2232-21(Guide)
Standard Guide for Selection and Use of Mathematical Methods for Calculating Absorbed Dose in Radiation Processing Applications

SIGNIFICANCE AND USE
4.1 Use as an Analytical Tool—Mathematical methods provide an analytical tool to be employed for many applications related to absorbed dose determinations in radiation processing. Mathematical calculations may not be used as a substitute for routine dosimetry in some applications (for example, medical device sterilization, food irradiation).  
4.2 Dose Calculation—Absorbed-dose calculations may be performed for a variety of photon/electron environments and irradiator geometries.  
4.3 Evaluate Process Effectiveness—Mathematical models may be used to evaluate the impact of changes in product composition, loading configuration, and irradiator design on dose distribution.  
4.4 Complement or Supplement to Dosimetry—Dose calculations may be used to establish a detailed understanding of dose distribution, providing a spatial resolution not obtainable through measurement. Calculations may be used to reduce the number of dosimeters required to characterize a procedure or process (for example, dose mapping).  
4.5 Alternative to Dosimetry—Dose calculations may be used when dosimetry is impractical (for example, granular materials, materials with complex geometries, material contained in a package where dosimetry is not practical or possible).  
4.6 Facility Design—Dose calculations are often used in the design of a new irradiator and can be used to help optimize dose distribution in an existing facility or radiation process. The use of modeling in irradiator design can be found in Refs (2-7).  
4.7 Validation—The validation of the model should be done through comparison with reliable and traceable dosimetric measurements. The purpose of validation is to demonstrate that the mathematical method makes reliable predictions of dose and other transport quantities. Validation compares predictions or theory to the results of an appropriate experiment. The degree of validation is commensurate with the application. Guidance is given in the documents referenced in Annex A2.  
...
SCOPE
1.1 This guide describes different mathematical methods that may be used to calculate absorbed dose and criteria for their selection. Absorbed-dose calculations can determine the effectiveness of the radiation process, estimate the absorbed-dose distribution in product, or supplement or complement, or both, the measurement of absorbed dose.  
1.2 Radiation processing is an evolving field and annotated examples are provided in Annex A6 to illustrate the applications where mathematical methods have been successfully applied. While not limited by the applications cited in these examples, applications specific to neutron transport, radiation therapy and shielding design are not addressed in this document.  
1.3 This guide covers the calculation of radiation transport of electrons and photons with energies up to 25 MeV.  
1.4 The mathematical methods described include Monte Carlo, point kernel, discrete ordinate, semi-empirical and empirical methods.  
1.5 This guide is limited to the use of general purpose software packages for the calculation of the transport of charged or uncharged particles and photons, or both, from various types of sources of ionizing radiation. This standard is limited to the use of these software packages or other mathematical methods for the determination of spatial dose distributions for photons emitted following the decay of 137Cs or 60Co, for energetic electrons from particle accelerators, or for X-rays generated by electron accelerators.  
1.6 This guide assists the user in determining if mathematical methods are a useful tool. This guide may assist the user in selecting an appropriate method for calculating absorbed dose. The user must determine whether any of these mathematical methods are appropriate for the solution to their specific application and what, if any, software to apply.
Note 1: The user is urged to apply these predictive techniques while being aware of the need for experien...

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