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ASTM E2586-07

(Practice)

Standard Practice for Calculating and Using Basic Statistics

Standard Practice for Calculating and Using Basic Statistics

SCOPE
1.1 This practice covers methods and formulas for computing and presenting basic descriptive statistics using a set of sample data containing a single variable. This practice includes simple descriptive statistics for variable data, tabular and graphical methods for variable data, and methods for summarizing simple attribute data. Some interpretation and guidance for use is also included.
1.2 The system of units for this Practice is not specified. Dimensional quantities in the Practice are presented only as illustrations of calculation methods. The examples are not binding on products or test methods treated.
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
30-Sep-2007
ICS
03.120.30 - Application of statistical methods
Technical Committee
E11 - Quality and Statistics
Drafting Committee
E11.10 - Sampling / Statistics
Current Stage
Ref Project

Relations

Replaced By
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Effective Date
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Effective Date
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Effective Date
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Effective Date
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ASTM E2586-07 - Standard Practice for Calculating and Using Basic StatisticsASTM E2586-07 - Standard Practice for Calculating and Using Basic Statistics
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ASTM E2586-07 - Standard Practice for Calculating and Using Basic Statistics
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NOTICE: This standard has either been superseded and replaced by a new version or withdrawn.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
Designation:E2586–07
Standard Practice for
Calculating and Using Basic Statistics
This standard is issued under the fixed designation E2586; 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 3.1.1 coeffıcient of variation,CV, n—foranonnegativechar-
acteristic, the ratio of the standard deviation to the mean for a
1.1 This practice covers methods and formulas for comput-
population or sample
ing and presenting basic descriptive statistics using a set of
3.1.1.1 Discussion—The coefficient of variation is often
sampledatacontainingasinglevariable.Thispracticeincludes
expressed as a percentage.
simple descriptive statistics for variable data, tabular and
3.1.1.2 Discussion—This statistic is also known as the
graphical methods for variable data, and methods for summa-
relative standard deviation, RSD.
rizing simple attribute data. Some interpretation and guidance
3.1.2 characteristic, n—a property of items in a sample or
for use is also included.
population which, when measured, counted, or otherwise
1.2 The system of units for this practice is not specified.
observed, helps to distinguish among the items. E2282
Dimensional quantities in the Practice are presented only as
3.1.3 empirical percentile, n—estimate of a population
illustrations of calculation methods. The examples are not
percentile using the sample data. This is a sample value such
binding on products or test methods treated.
that a percentage p of the sample is less than that value.
1.3 This standard does not purport to address all of the
3.1.4 histogram, n—graphical representation of the fre-
safety concerns, if any, associated with its use. It is the
quency distribution of a characteristic consisting of a set of
responsibility of the user of this standard to establish appro-
rectangles with area proportional to the frequency.
priate safety and health practices and determine the applica-
ISO 3534-1
bility of regulatory limitations prior to use.
3.1.4.1 Discussion—While not required, equal bar or class
2. Referenced Documents
widths are recommended for histograms.
th
3.1.5 interquartile range, IQR, n—the 75 percentile (0.75
2.1 ASTM Standards:
th
quantile) minus the 25 percentile (0.25 quantile), for a data
E178 Practice for Dealing With Outlying Observations
set.
E456 Terminology Relating to Quality and Statistics
3.1.6 kurtosis, g,g , n—for a population or a sample, a
E2282 Guide for Defining the Test Result of a Test Method 2 2
measure of the weight of the tails of a distribution relative to
2.2 ISO Standards
the center, calculated as the ratio of the fourth central moment
ISO 3534-1 Statistics—Vocabulary and Symbols, part 1:
(empiricalifasample,theoreticalifapopulationapplies)tothe
Probability and General Statistical Terms
standard deviation (sample, s, or population, s) raised to the
ISO 3534-2 Statistics—Vocabulary and Symbols, part 2:
fourth power, minus 3 (also referred to as excess kurtosis).
Applied Statistics
3.1.7 mean, n—of a population, µ, average or expected
3. Terminology
value of a characteristic in a population – of a sample, x, sum
of the observed values in the sample divided by the sample
3.1 Definitions: Unless otherwise noted, terms relating to
size.
quality and statistics are as defined in Terminology E456.
th
3.1.8 median, X, n—the 50 percentile in a population or
sample.
This practice is under the jurisdiction ofASTM Committee E11 on Quality and
3.1.8.1 Discussion—The sample median is the [(n+1)/2]
Statistics and is the direct responsibility of Subcommittee E11.10 on Sampling /
order statistic if the sample size n is odd and is the average of
Statistics.
the [n/2] and [n/2+1] order statistics if n is even.
Current edition approved Oct. 1, 2007. Published November 2007. DOI:
10.1520/E2586-07.
3.1.9 midrange, n—average of the minimum and maximum
For referenced ASTM standards, visit the ASTM website, www.astm.org, or
values in a sample.
contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
th
3.1.10 order statistic, x , n—value of the k observed
Standards volume information, refer to the standard’s Document Summary page on (k)
the ASTM website. value in a sample after sorting by order of magnitude.
Available fromAmerican National Standards Institute (ANSI), 25 W. 43rd St.,
4th Floor, New York, NY 10036, http://www.ansi.org.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959, United States.
E2586–07
3.1.10.1 Discussion—For a sample of size n, the first order dynamic, continuing to emerge and possibly change over time.
statistic x is the minimum value, x is the maximum value. Sample data serve as representatives of the population from
(1) (n)
3.1.11 population parameter, n—summary measure of the
which the sample originates. It is the population that is of
values of some characteristic of a population ISO 3534-2
primary interest in any particular study.
3.1.12 population, n—the totality of items or units of
4.2 The data (measurements and observations) may be of
material under consideration.
the variable type or the simple attribute type. In the case of
3.1.13 quantile,n—valuesuchthatafractionfofthesample
attributes, the data may be either binary trials or a count of a
or population is less than or equal to that value
defined event over some interval (time, space, volume, weight,
3.1.14 range, R, n—maximum value minus the minimum
or area). Binary trials consist of a sequence of 0s and 1s in
value in a sample.
which a “1” indicates that the inspected item exhibited the
3.1.15 sample, n—a group of observations or test results,
attribute being studied and a “0” indicates the item did not
taken from a larger collection of observations or test results,
exhibit the attribute. Each inspection item is assigned either a
whichservestoprovideinformationthatmaybeusedasabasis
“0” or a “1.” Such data are often governed by the binomial
for making a decision concerning the larger collection.
distribution. For a count of events over some interval, the
3.1.16 sample size, n, n—number of observed values in the
number of times the event is observed on the inspection
sample
interval is recorded for each of n inspection intervals. The
3.1.17 sample statistic, n—summary measure of the ob-
Poisson distribution often governs counting events over an
served values of a sample.
interval.
3.1.18 skewness, g,g , n—for population or sample, a
1 1
4.3 For sample data to be used to draw conclusions about
measure of symmetry of a distribution, calculated as the ratio
the population, the process of sampling and data collection
of the third central moment (empirical if a sample, and
must be considered, at least potentially, repeatable. Descriptive
theoretical if a population applies) to the standard deviation
statistics are calculated using real sample data that will vary in
(sample, s, or population, s) raised to the third power.
repeating the sampling process.As such, a statistic is a random
3.1.19 standard deviation—of a population, s, the square
variable subject to variation in its own right. The sample
root of the average or expected value of the squared deviation
statistic usually has a corresponding parameter in the popula-
of a variable from its mean – of a sample s , the square root of
tion that is unknown (see Section 5). The point of using a
the sum of the squared deviations of the observed values in the
sample divided by the sample size minus 1. statisticistosummarizethedatasetandestimateacorrespond-
2 2
ing population characteristic or parameter.
3.1.20 variance, s,s , n—square of the standard deviation
of the population or sample.
4.4 Descriptive statistics consider numerical, tabular, and
3.1.20.1 Discussion—For a finite population, s is calcu-
graphical methods for summarizing a set of data. The methods
latedasthesumofsquareddeviationsofvaluesfromthemean,
considered in this practice are used for summarizing the
divided by n. For a continuous population, s is calculated by
observations from a single variable.
integrating (x-µ) with respect to the density function. For a
4.5 The descriptive statistics described in this practice are:
sample, s is calculated as the sum of the squared deviations of
4.5.1 Mean, median, min, max, range, mid range, order
observedvaluesfromtheiraveragedividedbyonelessthanthe
statistic, quartile, empirical percentile, quantile, interquartile
sample size.
range, variance, standard deviation, Z-score, coefficient of
3.1.21 Z-score, n—observed value minus the sample mean
variation, skewness and kurtosis, and standard error.
divided by the sample standard deviation.
4.6 Tabular methods described in this practice are:
4. Significance and Use
4.6.1 Frequency distribution, relative frequency distribu-
4.1 This practice provides approaches for characterizing a
tion, cumulative frequency distribution, and cumulative rela-
sample of n observations that arrive in the form of a data set.
tive frequency distribution.
Large data sets from organizations, businesses, and govern-
4.7 Graphical methods described in this practice are:
mental agencies exist in the form of records and other
4.7.1 Histogram,ogive,boxplot,dotplot,normalprobability
empirical observations. Research institutions and laboratories
plot, and q-q plot.
at universities, government agencies, and the private sector
4.8 While the methods described in this practice may be
also generate considerable amounts of empirical data.
used to summarize any set of observations, the results obtained
4.1.1 Adata set containing a single variable usually consists
by using them may be of little value from the standpoint of
of a column of numbers. Each row is a separate observation or
interpretation unless the data quality is acceptable and satisfies
instance of measurement of the variable. The numbers them-
certain requirements.To be useful for inductive generalization,
selvesaretheresultofapplyingthemeasurementprocesstothe
any sample of observations that is treated as a single group for
variable being studied or observed. We may refer to each
presentationpurposesmustrepresentaseriesofmeasurements,
observation of a variable as an item in the data set. In many
all made under essentially the same test conditions, on a
situations, there may be several variables defined for study.
material or product, all of which have been produced under
4.1.2 The sample is selected from a larger set called the
population. The population can be a finite set of items, a very essentially the same conditions. When these criteria are met,
we are minimizing the danger of mixing two or more distinctly
large or essentially unlimited set of items, or a process. In a
process, the items originate over time and the population is different sets of data.
E2586–07
4.8.1 If a given collection of data consists of two or more 5.1.2 Agreat variety of distribution shapes are theoretically
samples collected under different test conditions or represent- possible. When the curve is symmetric, we say that the
ing material produced under different conditions (that is, distribution is symmetric; otherwise, it is asymmetric. A
different populations), it should be considered as two or more distribution having a longer tail on the right side is called right
separate subgroups of observations, each to be treated inde- skewed; a distribution having a longer tail on the left is called
pendently in a data analysis program. Merging of such sub- left skewed.
groups, representing significantly different conditions, may 5.1.3 For a given density function, f (x), the relationship to
lead to a presentation that will be of little practical value. cumulative area under the curve may be graphically shown in
Briefly, any sample of observations to which these methods are the form of a cumulative distribution function, F (x). The
applied should be homogeneous or, in the case of a process, function F (x) plots the cumulative area under f (x) as x moves
have originated from a process in a state of statistical control. to the right. Fig. 2 shows a symmetric distribution with its
4.9 The methods developed in Sections 6, 7, and 8 apply to density function, f (x), plotted on the left-hand axis and
the sample data. There will be no misunderstanding when, for distribution function, F (x), plotted on the right-hand axis.
example, the term “mean” is indicated, that the meaning is 5.1.4 Referring to the F (x) axis in Fig. 2, observe that F
samplemean,notpopulationmean,unlessindicatedotherwise. (30) = 0.5. The point x = 30 divides the distribution into two
It is understood that there is a data set containing n observa- equal halves with respect to probability (50 % on each side of
tions. The data set may be denoted as: x). In general, where F (x) = 0.5, we call the point x the median
th
or 50 percentile of the distribution. In like manner, we may
x ,x ,x .x (1)
1 2 3 n
th th
define any percentile, for example, the 25 or the 90
4.9.1 There is no order of magnitude implied by the
percentiles. In general, for 0 < p < 1, a 100p % percentile is a
subscript notation unless subscripts are contained in parenthe-
location point, Q , that divides the distribution into two parts,
p
sis (see 6.7).
with 100p % lying to the left and (1-p)100 % lying to the right.
5.2 A density function is often given as a formula with one
5. Characteristics of Populations
ormoreparameters,which,whengivenvalues,allowthecurve
5.1 A population is the totality of a set of items under
to be drawn. For many distributions, two parameters are
consideration. Populations may be finite or unlimited in size
sufficient (some have one parameter and others have more than
and may be existing or continuing to emerge as, for example,
two). The parameters may also have meaning with respect to
in a process. For continuous variables, X, representing an
the shape of the curve, the scale used, or some other property
essentially unlimited population or a process, the population is
of the curve.
mathematicallycharacterizedbyaprobabilitydensityfunction,
5.2.1 The mean or “expected value” of a distribution,
f (x). The density function visually describes the shape of the
denoted by the symbol µ, is a parameter that defines the central
distribution as for example in Fig. 1. Mathematically, the only
location of a distribution. The mean can be thought of as a
requirements of a density function are that its ordinates be all
“centerofgravity”forthedistribution.Whenthedistributionis
positive and that the total area under the
...

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SIGNIFICANCE AND USE
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ASTM E3080-23(Practice)
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ABSTRACT
This practice covers regression analysis of a set of data to define the statistical relationship between two numerical variables for use in predicting one variable from the other. This practice is restricted in scope to consider only a single numerical response variable and a single numerical predictor variable. The objective is to obtain a regression model for use in predicting the value of the response variable Y for given values of the predictor variable X.
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ABSTRACT
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Note 1: Tables in Annex A1 – Annex A4 and parts of the text are reproduced by permission of John R. Wiley and Sons. More extensive tables and discussion of the methods will be found in that text.  
4.2 The sampling tables based on lot quality protection (LTPD) (the tables in Annex A1 and Annex A2) are perhaps best adapted to conditions where interest centers on each lot separately, for example, where the individual lot tends to retain its identity either from a shipment or a service standpoint. These tables have been found particularly useful in inspections made by the ultimate consumer or a purchasing agent for lots or shipments purchased more or less intermittently.  
4.3 The sampling tables based on average quality protection (AOQL) (the tables in Annex A3 and Annex A4) are especially adapted for use where interest centers on the average quality of product after inspection rather than on the quality of each individual lot and where inspection is, therefore, intended to serve, if necessary, as a partial screen for defective pieces. The latter point of view has been found particularly helpful, for example, in consumer inspections of continuing purchases of large quantities of a product and in manufacturing process inspections of parts where the inspection lots tend to lose their identity by merger in a common storeroom from which quantities are withdraw...
SCOPE
1.1 This practice is primarily a statement of principals for the guidance of ASTM technical committees and others in the use of average outgoing quality limit, AOQL, and lot tolerance percent defective, LTPD, sampling plans for determining acceptable of lots of product.  
1.2 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 E2334-09(2023)(Practice)
Standard Practice for Setting an Upper Confidence Bound for a Fraction or Number of Non-Conforming items, or a Rate of Occurrence for Non-Conformities, Using Attribute Data, When There is a Zero Response in the Sample

ABSTRACT
This practice presents methodology for the setting of an upper confidence bound regarding an unknown fraction or quantity non-conforming, or a rate of occurrence for nonconformities, in cases where the method of attributes is used and there is a zero response in a sample. Three cases are considered. In Case 1, the sample is selected from a process or a very large population of interest. In Case 2, a sample of n items is selected at random from a finite lot of N items. In Case 3, there is a process, but the output is a continuum, such as area (for example, a roll of paper or other material, a field of crop), volume (for example, a volume of liquid or gas), or time (for example, hours, days, quarterly, etc.) The sample size is defined as that portion of the �continuum� sampled, and the defined attribute may occur any number of times over the sampled portion.
SIGNIFICANCE AND USE
4.1 In Case 1, the sample is selected from a process or a very large population of interest. The population is essentially unlimited, and each item either has or has not the defined attribute. The population (process) has an unknown fraction of items p (long run average process non-conforming) having the attribute. The sample is a group of n discrete items selected at random from the process or population under consideration, and the attribute is not exhibited in the sample. The objective is to determine an upper confidence bound, pu, for the unknown fraction p whereby one can claim that p ≤ pu with some confidence coefficient (probability) C. The binomial distribution is the sampling distribution in this case.  
4.2 In Case 2, a sample of n items is selected at random from a finite lot of N items. Like Case 1, each item either has or has not the defined attribute, and the population has an unknown number, D, of items having the attribute. The sample does not exhibit the attribute. The objective is to determine an upper confidence bound, Du, for the unknown number D, whereby one can claim that D ≤ Du with some confidence coefficient (probability) C. The hypergeometric distribution is the sampling distribution in this case.  
4.3 In Case 3, there is a process, but the output is a continuum, such as area (for example, a roll of paper or other material, a field of crop), volume (for example, a volume of liquid or gas), or time (for example, hours, days, quarterly, etc.) The sample size is defined as that portion of the “continuum” sampled, and the defined attribute may occur any number of times over the sampled portion. There is an unknown average rate of occurrence, λ, for the defined attribute over the sampled interval of the continuum that is of interest. The sample does not exhibit the attribute. For a roll of paper, this might be blemishes per 100 ft2; for a volume of liquid, microbes per cubic litre; for a field of crop, spores per acre; for a time interval, ca...
SCOPE
1.1 This practice presents methodology for the setting of an upper confidence bound regarding a unknown fraction or quantity non-conforming, or a rate of occurrence for nonconformities, in cases where the method of attributes is used and there is a zero response in a sample. Three cases are considered.  
1.1.1 The sample is selected from a process or a very large population of discrete items, and the number of non-conforming items in the sample is zero.  
1.1.2 A sample of items is selected at random from a finite lot of discrete items, and the number of non-conforming items in the sample is zero.  
1.1.3 The sample is a portion of a continuum (time, space, volume, area, etc.) and the number of non-conformities in the sample is zero.  
1.2 Allowance is made for misclassification error in this practice, but only when misclassification rates are well understood or known and can be approximated numerically.  
1.3 The values stated in inch-pound units are to be regarded as standard. No other units of measurement are included in this standard.  
1.4 This ...

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ASTM E122-17(2022)(Practice)
Standard Practice for Calculating Sample Size to Estimate, With Specified Precision, the Average for a Characteristic of a Lot or Process

ABSTRACT
This practice covers simple methods for calculating how many units to include in a random sample in order to estimate with a specified precision, a measure of quality for all the units of a lot of material or produced by a process. It also treats the common situation where the sampling units can be considered to exhibit a single source of variability; it does not treat multi-level sources of variability.
SIGNIFICANCE AND USE
4.1 This practice is intended for use in determining the sample size required to estimate, with specified precision, a measure of quality of a lot or process. The practice applies when quality is expressed as either the lot average for a given property, or as the lot fraction not conforming to prescribed standards. The level of a characteristic may often be taken as an indication of the quality of a material. If so, an estimate of the average value of that characteristic or of the fraction of the observed values that do not conform to a specification for that characteristic becomes a measure of quality with respect to that characteristic. This practice is intended for use in determining the sample size required to estimate, with specified precision, such a measure of the quality of a lot or process either as an average value or as a fraction not conforming to a specified value.
SCOPE
1.1 This practice covers simple methods for calculating how many units to include in a random sample in order to estimate with a specified precision, a measure of quality for all the units of a lot of material, or produced by a process. This practice will clearly indicate the sample size required to estimate the average value of some property or the fraction of nonconforming items produced by a production process during the time interval covered by the random sample. If the process is not in a state of statistical control, the result will not have predictive value for immediate (future) production. The practice treats the common situation where the sampling units can be considered to exhibit a single (overall) source of variability; it does not treat multi-level sources of variability.  
1.2 The system of units for this standard is not specified. Dimensional quantities in the standard are presented only as illustrations of calculation methods. The examples are not binding on products or test methods treated.  
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 E2587-16(2021)e1(Practice)
Standard Practice for Use of Control Charts in Statistical Process Control

ABSTRACT
This guide covers fundamental concepts, applications, and mathematical relationships associated with reliability as used in industrial areas and as applied to simple components, processes, and systems or complex final products. This guide summarizes selected concepts, terminology, formulas, and methods associated with reliability and its application to products and processes.
SIGNIFICANCE AND USE
4.1 This practice describes the use of control charts as a tool for use in statistical process control (SPC). Control charts were developed by Shewhart (2)3 in the 1920s and are still in wide use today. SPC is a branch of statistical quality control (3, 4), which also encompasses process capability analysis and acceptance sampling inspection. Process capability analysis, as described in Practice E2281, requires the use of SPC in some of its procedures. Acceptance sampling inspection, described in Practices E1994, E2234, and E2762, requires the use of SPC to minimize rejection of product.  
4.2 Principles of SPC—A process may be defined as a set of interrelated activities that convert inputs into outputs. SPC uses various statistical methodologies to improve the quality of a process by reducing the variability of one or more of its outputs, for example, a quality characteristic of a product or service.  
4.2.1 A certain amount of variability will exist in all process outputs regardless of how well the process is designed or maintained. A process operating with only this inherent variability is said to be in a state of statistical control, with its output variability subject only to chance, or common, causes.  
4.2.2 Process upsets, said to be due to assignable, or special causes, are manifested by changes in the output level, such as a spike, shift, trend, or by changes in the variability of an output. The control chart is the basic analytical tool in SPC and is used to detect the occurrence of special causes operating on the process.  
4.2.3 When the control chart signals the presence of a special cause, other SPC tools, such as flow charts, brainstorming, cause-and-effect diagrams, or Pareto analysis, described in various references (4-8), are used to identify the special cause. Special causes, when identified, are either eliminated or controlled. When special cause variation is eliminated, process variability is reduced to its inherent variability, and control...
SCOPE
1.1 This practice provides guidance for the use of control charts in statistical process control programs, which improve process quality through reducing variation by identifying and eliminating the effect of special causes of variation.  
1.2 Control charts are used to continually monitor product or process characteristics to determine whether or not a process is in a state of statistical control. When this state is attained, the process characteristic will, at least approximately, vary within certain limits at a given probability.  
1.3 This practice applies to variables data (characteristics measured on a continuous numerical scale) and to attributes data (characteristics measured as percentages, fractions, or counts of occurrences in a defined interval of time or space).  
1.4 The system of units for this practice is not specified. Dimensional quantities in the practice are presented only as illustrations of calculation methods. The examples are not binding on products or test methods treated.  
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 appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
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...

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ASTM E2819-11(2021)(Practice)
Standard Practice for Single- and Multi-Level Continuous Sampling of a Stream of Product by Attributes Indexed by AQL

ABSTRACT
This practice establishes tables and procedures for applying five different types of continuous sampling plans for inspection by attributes using MIL-STD-1235B as a basis for sampling a steady stream of lots indexed by AQL. This practice represents a conversion of MIL-STD1235B to an ASTM-supported standard.
SIGNIFICANCE AND USE
4.1 The reason for preserving military sampling standards is that many organizations throughout the world still use these standards in their current form. MIL-STD-1235B is no longer supported by the U.S. Department of Defense as of the mid-1990s and is out of print, but does exist in the public domain. This practice represents a conversion of MIL-STD-1235B to an ASTM-supported standard.  
4.2 This practice provides the tables and procedures for applying five different types of continuous sampling plans for inspection by attributes. These continuous sampling plans are discussed in Sections 6 – 10 of this practice and each section includes information on:
(1) Initiation of 100 % inspection in use.
(2) Requirements on when to switch to sampling inspection.
(3) Conditions warranting a return to 100 % inspection.
(4) When a change in Code Letter, if desired, can be made.
(5) What to do when the checking inspector finds a defect that was originally found conforming by the screening inspector(s), that is, ineffective screening.
(6) Situations where a defect is found before the switch to 100 % inspection causing excessive periods of 100 % inspection so action must be taken, that is, long periods of screening.  
4.2.1 Section 6 (Section 2 in MIL-STD-1235B) describes specific procedures and applications of the CSP-1 sampling plans – a single-level continuous sampling procedure which provides for alternating between sequences of 100 % inspection and sampling inspection.  
4.2.2 Section 7 (Section 3 in MIL-STD-1235B) describes specific procedures and applications of the CSP-F sampling plans – a variation of the CSP-1 plans in that CSP-F plans are applied to a relatively short run of product, thereby permitting smaller clearance numbers to be used.  
4.2.3 Section 8 (Section 4 in MIL-STD-1235B) describes specific procedures and applications of the CSP-2 sampling plans – a modification of CSP-1 in that 100 % inspection resumes only after a prescribed number of def...
SCOPE
1.1 This practice establishes tables and procedures for applying five different types of continuous sampling plans for inspection by attributes using MIL-STD-1235B as a basis for sampling a steady stream of lots indexed by AQL.  
1.2 This practice provides the sampling plans of MIL-STD-1235B in ASTM format for use by ASTM committees and others. It recognizes the continuing usage of MIL-STD-1235B in industries supported by ASTM. Most of the original text in MIL-STD-1235B is preserved in Sections 6 – 10 of 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, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
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 E178-21(Practice)
Standard Practice for Dealing With Outlying Observations

ABSTRACT
This practice covers outlying observations in samples and how to test the statistical significance of outliers. The procedures in this practice were developed primarily to apply to the simplest kind of experimental data, that is, replicate measurements of some property of a given material or observations in a supposedly random sample.
SCOPE
1.1 This practice covers outlying observations in samples and how to test the statistical significance of outliers.  
1.2 The system of units for this standard is not specified. Dimensional quantities in the standard are presented only as illustrations of calculation methods. The examples are not binding on products or test methods treated.  
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, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
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 E2935-21(Practice)
Standard Practice for Evaluating Equivalence of Two Testing Processes

ABSTRACT
This practice provides statistical methodology for conducting equivalence testing on numerical data from two sources to determine if their true means or variances differ by no more than predetermined limits. This standard provides guidance on experiments and statistical methods needed to demonstrate that the test results from a modified testing process are equivalent to those from the current testing process, where equivalence is defined as agreement within a prescribed limit, termed an equivalence limit.
SIGNIFICANCE AND USE
4.1 Laboratories conducting routine testing have a continuing need to make improvements in their testing processes. In these situations it must be demonstrated that any changes will neither cause an undesirable shift in the test results from the current testing process nor substantially affect a performance characteristic of the test method. This standard provides guidance on experiments and statistical methods needed to demonstrate that the test results from a modified testing process are equivalent to those from the current testing process, where equivalence is defined as agreement within a prescribed limit, termed an equivalence limit.  
4.1.1 The equivalence limit, which represents a worst-case difference or ratio, is determined prior to the equivalence test and its value is usually set by consensus among subject-matter experts.  
4.1.2 Examples of modifications to the testing process include, but are not limited, to the following:  
(1) Changes to operating levels in the steps of the test method procedure,
(2) Installation of new instruments, apparatus, or sources of reagents and test materials,
(3) Evaluation of new personnel performing the testing, and
(4) Transfer of testing to a new location.  
4.1.3 Examples of performance characteristics directly applicable to the test method include bias, precision, sensitivity, specificity, linearity, and range. Additional characteristics are test cost and elapsed time needed to conduct the test procedure.  
4.2 Equivalence studies are performed by a designed experiment that generates test results from the modified and current testing procedures on the same types of materials that are routinely tested. The design of the experiment depends on the type of equivalence needed as discussed below. Experiment design and execution for various objectives is discussed in Section 5.  
4.2.1 Means equivalence is concerned with a potential shift in the mean test result in either direction due to a modification in the te...
SCOPE
1.1 This practice provides statistical methodology for conducting equivalence studies on numerical data from two sources of test results to determine if their true means, variances, or other parameters differ by no more than predetermined limits.  
1.2 Applications include (1) equivalence studies for bias against an accepted reference value, (2) determining means equivalence of two test methods, test apparatus, instruments, reagent sources, or operators within a laboratory or equivalence of two laboratories in a method transfer, and (3) determining non-inferiority of a modified test procedure versus a current test procedure with respect to a performance characteristic.  
1.3 The guidance in this standard applies to experiments conducted either on a single material at a given level of the test result or on multiple materials covering a selected range of test results.  
1.4 Guidance is given for determining the amount of data required for an equivalence study. The control of risks associated with the equivalence decision is discussed.  
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 t...

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