iTeh StandardsiTeh Standards
EURUSD
Your shopping cart is empty.
ASTM

ASTM E141-91(2003)e1

(Practice)

Standard Practice for Acceptance of Evidence Based on the Results of Probability Sampling

Standard Practice for Acceptance of Evidence Based on the Results of Probability Sampling

SIGNIFICANCE AND USE
This practice is designed to permit users of sample survey data to judge the trustworthiness of results from such surveys. Section 5 gives extended definitions of the concepts basic to survey sampling and the user should verify that such concepts were indeed used and understood by those who conducted the survey. What was the frame? How large (exactly) was the quantity N? How was the parameter θ estimated and its standard error calculated? If replicate subsamples were not used, why not?
Adequate answers should be given for all questions. There are many acceptable answers to the last question. If the sample design was relatively simple, such as simple random or stratified, then good estimates of sampling variance are easily available. If a more complex design was used then methods such as discussed in [1] may be acceptable. Replicate subsamples is the most straightforward way to estimate sampling variances when the survey design is complex.
Once the survey procedures that were used satisfy Section 5, consult Section 4 to see if any increase in sample size is needed. The calculations for making it are objectively described in Section 4.
Refer to Section 6 to guide in the interpretation of the uncertainty in the reported value of the parameter estimate, θ, i.e. the value of its standard error, se(θ). The quantity se(θ) should be reviewed to verify that the risks it entails are commensurate with the size of the sample.
SCOPE
1.1 This practice presents rules for accepting or rejecting evidence based on a sample. Statistical evidence for this practice is in the form of an estimate of a proportion, an average, a total, or other numerical characteristic of a finite population or lot. It is an estimate of the result which would have been obtained by investigating the entire lot or population under the same rules and with the same care as was used for the sample.
1.2 One purpose of this practice is to describe straightforward sample selection and data calculation procedures so that courts, commissions, etc. will be able to verify whether such procedures have been applied. The methods may not give least uncertainty at least cost, they should however furnish a reasonable estimate with calculable uncertainty.
1.3 This practice is primarily intended for one-of-a-kind studies. Repetitive surveys allow estimates of sampling uncertainties to be pooled; the emphasis of this practice is on estimation of sampling uncertainty from the sample itself. The parameter of interest for this practice is effectively a constant. Thus, the principal inference is a simple point estimate to be used as if it were the unknown constant, rather than, for example, a forecast or prediction interval or distribution devised to match a random quantity of interest.
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
14-Aug-2003
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

Replaces
ASTM E141-91(1997) - Standard Practice for Acceptance of Evidence Based on the Results of Probability Sampling
Effective Date
15-Aug-2003
Replaced By
ASTM E141-10 - Standard Practice for Acceptance of Evidence Based on the Results of Probability Sampling
Effective Date
15-May-2010
Referred By
ASTM E456-13a(2022) - Standard Terminology Relating to Quality and Statistics
Effective Date
15-Aug-2003
Referred By
ASTM E2334-09(2023) - 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
Effective Date
15-Aug-2003
Referred By
ASTM E1402-13(2018) - Standard Guide for Sampling Design
Effective Date
15-Aug-2003
Referred By
ASTM E2548-16 - Standard Guide for Sampling Seized Drugs for Qualitative and Quantitative Analysis
Effective Date
15-Aug-2003
Referred By
ASTM C50/C50M-13(2019) - Standard Practice for Sampling, Sample Preparation, Packaging, and Marking of Lime and Limestone Products
Effective Date
15-Aug-2003
Referred By
ASTM D75/D75M-19 - Standard Practice for Sampling Aggregates
Effective Date
15-Aug-2003
Referred By
ASTM E1367-03(2023) - Standard Test Method for Measuring the Toxicity of Sediment-Associated Contaminants with Estuarine and Marine Invertebrates
Effective Date
15-Aug-2003
Referred By
ASTM C823/C823M-12(2017) - Standard Practice for Examination and Sampling of Hardened<brk/> Concrete in Constructions
Effective Date
15-Aug-2003
Referred By
ASTM E105-21 - Standard Guide for Probability Sampling of Materials
Effective Date
15-Aug-2003
Referred By
ASTM D979/D979M-22 - Standard Practice for Sampling Asphalt Mixtures
Effective Date
15-Aug-2003
Referred By
ASTM F3260-18 - Standard Test Method for Determining the Flexural Stiffness of Medical Textiles
Effective Date
15-Aug-2003
Referred By
ASTM D3665-12(2017) - Standard Practice for Random Sampling of Construction Materials
Effective Date
15-Aug-2003

Buy Standard

ASTM E141-91(2003)e1 - Standard Practice for Acceptance of Evidence Based on the Results of Probability SamplingASTM E141-91(2003)e1 - Standard Practice for Acceptance of Evidence Based on the Results of Probability Sampling
PreviousNext
Standard
ASTM E141-91(2003)e1 - Standard Practice for Acceptance of Evidence Based on the Results of Probability Sampling
English language
6 pages
sale 15% off
Preview
sale 15% off
Preview
REDLINE ASTM E141-91(2003)e1 - Standard Practice for Acceptance of Evidence Based on the Results of Probability SamplingREDLINE ASTM E141-91(2003)e1 - Standard Practice for Acceptance of Evidence Based on the Results of Probability Sampling
PreviousNext
Standard
REDLINE ASTM E141-91(2003)e1 - Standard Practice for Acceptance of Evidence Based on the Results of Probability Sampling
English language
6 pages
sale 15% off
Preview
sale 15% off
Preview

Standards Content (Sample)


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
´1
Designation:E141–91(Reapproved 2003)
Standard Practice for
Acceptance of Evidence Based on the Results of Probability
Sampling
This standard is issued under the fixed designation E141; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision.Anumber in parentheses indicates the year of last reapproval.A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
´ NOTE—Editorial changes were made throughout in November 2003.
1. Scope 2. Referenced Documents
1.1 This practice presents rules for accepting or rejecting 2.1 ASTM Standards:
,
evidence based on a sample. Statistical evidence for this E105 Practice for Probability Sampling of Materials
practice is in the form of an estimate of a proportion, an E122 Practice for Calculating Sample Size to Estimate,
average, a total, or other numerical characteristic of a finite With Specified Precision, the Average for a Characteristic
population or lot. It is an estimate of the result which would of a Lot or Process
havebeenobtainedbyinvestigatingtheentirelotorpopulation E178 Practice for Dealing With Outlying Observations
underthesamerulesandwiththesamecareaswasusedforthe E456 Terminology Relating to Quality and Statistics
sample.
NOTE 1—Practice E105 provides a statement of principles for guidance
1.2 One purpose of this practice is to describe straightfor-
ofASTMtechnicalcommitteesandothersinthepreparationofasampling
ward sample selection and data calculation procedures so that
planforaspecificmaterial.PracticeE122aidsindecidingontherequired
courts, commissions, etc. will be able to verify whether such
sample size. Practice E178 helps insure better behaved estimates. Termi-
nology E456 provides definitions of statistical terms used in this standard.
procedures have been applied.The methods may not give least
uncertainty at least cost, they should however furnish a
3. Terminology
reasonable estimate with calculable uncertainty.
3.1 Definitions:
1.3 This practice is primarily intended for one-of-a-kind
3.1.1 Equal Complete Coverage Result, n—the numerical
studies. Repetitive surveys allow estimates of sampling uncer-
characteristic(u)ofinterestcalculatedfromobservationsmade
tainties to be pooled; the emphasis of this practice is on
by drawing randomly from the frame, all of the sampling units
estimation of sampling uncertainty from the sample itself. The
covered by the frame.
parameter of interest for this practice is effectively a constant.
3.1.1.1 Discussion—Locatingtheunitsandevaluatingthem
Thus, the principal inference is a simple point estimate to be
are supposed to be done in exactly the same way and at the
used as if it were the unknown constant, rather than, for
same time as was done for the sample. The quantity itself is
example, a forecast or prediction interval or distribution
denoted u.Theequalcompletecoverageresultisneveractually
devised to match a random quantity of interest.
calculated. Its purpose is to serve as the objectively defined
1.4 This standard does not purport to address all of the
concrete goal of the investigation. The quantity u may be the
safety concerns, if any, associated with its use. It is the
¯
population mean,(Y), total (Y), median (M), the proportion
responsibility of the user of this standard to establish appro-
(P), or any other such quantity.
priate safety and health practices and determine the applica-
3.1.2 frame, n—a list, compiled for sampling purposes,
bility of regulatory limitations prior to use.
which designates all of the sampling units (items or groups) of
a population or universe to be considered in a specific study.
ThispracticeisunderthejurisdictionofASTMCommitteeE11onQualityand
Statistics and is the direct responsibility of Subcommittee E11.10 on Sampling /
Statistics. For referenced ASTM standards, visit the ASTM website, www.astm.org, or
Current edition approved Oct. 1, 2003. Published November 2003. Originally contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
approved in 1959. Last previous edition approved in 1991 as E141–91. DOI: Standards volume information, refer to the standard’s Document Summary page on
10.1520/E0141-91R03E01. the ASTM website.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959, United States.
´1
E141–91 (2003)
3.1.2.1 Discussion—The list may cover a specific shipment size is needed. The calculations for making it are objectively
or lot, all households in a county, a state, or country; for described in Section 4.
example,anypopulationofinterest.Everysamplingunitinthe
4.4 Refer to Section 6 to guide in the interpretation of the
frame (1) has a unique serial number, which may be preas- uncertainty in the reported value of the parameter estimate, u,
signed or determined by some definite rule, (2) has an
i.e. the value of its standard error, se(u). The quantity se(u)
address—a complete and clear instruction (or rules for its should be reviewed to verify that the risks it entails are
formulation) as to where and when to make the observation or
commensurate with the size of the sample.
evaluation, (3) is based on physically concrete clerical mate-
rials such as directories, dials of clocks or of meters, ledgers,
5. Descriptive Terms and Procedures
maps, aerial photographs, etc., referred to in the addresses.
5.1 Probability Sampling Plans—include instructions for
3.1.3 sample, n—agroupofitems,observations,testresults,
using either:
or portions of material, taken from a larger collection of such
5.1.1 carefully prepared tables of random number,
items; it provides information for decisions concerning the
5.1.2 computer algorithms, carefully programmed and run
larger collection.
on a large computer, to generate pseudo-random numbers or,
3.1.3.1 Discussion—Aparticular sample is identified by the
5.1.3 certifiably honest physical devices, such as coin flips,
setofserialnumbersfromtherandomizationdeviceandbythe
toselectthesampleunitssothatinferencesmaybedrawnfrom
addresses on the frame generated by those serial numbers.
the test results and decisions may be made with risks correctly
3.1.4 sampling unit, n—an item, test specimen or portion of
calculated by probability theory.
material that is to be subjected to evaluation as part of the
5.1.4 Such plans are defined and their relative advantages
sampling plan.
discussed in Refs. (1), (2), and (3).
3.1.4.1 Discussion—If it is not feasible to select test speci-
5.2 Replicate Subsamples—a number of disjoint samples,
mens or laboratory samples individually, the sampling unit
each one separately drawn from the frame in accord with the
may be a group of items, for example, a row, an entire case of
same probability sampling plan. When appropriate, separate
items,oraprescribedarea(asintheexaminationofafinishing
laboratoriesshouldeachworkonseparatereplicatesubsamples
process).
and teams of investigators should be assigned to separate
3.1.4.2 By a more expensive method of measurement (fu-
replicate subsamples.This approach insures that the calculated
ture time, more elaborate frame) it may be possible to define a
standard error will not be a systematic underestimate. Such
quantity, u8, as a target parameter or ideal goal of an investi-
subsamples were called interpenetrating in Ref. (4) where
gation. Criticism that holds u to be an inappropriate goal
many of their basic properties were described. See Ref. (2) for
should demonstrate that the numerical difference between u
further theory and applications.
and u8 is substantial. Measurements may be imprecise but so
5.2.1 Discussion—For some types of material a sample
long as measurement errors are not too biased, a large size of
selected with uniform spacing along the frame (systematic
the lot or population, N, insures that u and u8 are essentially
sample) has increased precision over a selection made with
equal.
randomlyvaryingspacings(simplerandomsample).Examples
4. Significance and Use include sampling mineral ore or grain from a conveyor belt or
sampling from a list of households along a street. If the
4.1 This practice is designed to permit users of sample
systematicsampleisobtainedbyasinglerandomstarttheplan
survey data to judge the trustworthiness of results from such
is then a probability sampling plan, but it does not permit
surveys. Section 5 gives extended definitions of the concepts
calculatingthestandarderrorasrequiredbythispractice.After
basic to survey sampling and the user should verify that such
dividing the sample size by an integer k (such as k =4or k
concepts were indeed used and understood by those who
=10) and using a random start for each of k replicate
conducted the survey. What was the frame? How large (ex-
subsamples, some of the increased precision of systematic
actly) was the quantity N? How was the parameter u estimated
sampling (and a standard error on k−1 degrees of freedom)
and its standard error calculated? If replicate subsamples were
can be achieved.
not used, why not?
5.2.2 Audit Subsample—a small subsample of the survey
4.2 Adequate answers should be given for all questions.
sample(asfewas10observationsmaybeadequate)forreview
There are many acceptable answers to the last question. If the
of all procedures from use of the random numbers through
sampledesignwasrelativelysimple,suchassimplerandomor
locating and measurement, to editing, coding, data entry and
stratified, then good estimates of sampling variance are easily
tabulation. Selection of the audit subsample may be done by
available. If a more complex design was used then methods
puttingthensampleobservationsinorderastheyarecollected,
such as discussed in Ref. (1) may be acceptable. Replicate
calculating the nearest integer to n , or some other conve-
=
subsamples is the most straightforward way to estimate sam-
nient integer, and taking this number to be the spacing for
pling variances when the survey design is complex.
systematicselectionoftheauditsubsample.Thereviewshould
4.3 Once the survey procedures that were used satisfy
uncover any gross departures from prescribed practices or any
Section 5, consult Section 4 to see if any increase in sample
conceptual misunderstandings in the definitions. If the audit
subsample is large enough (say 30 observations or more) the
regression of audited values on initial observations may be
The boldface numbers in parentheses refer to a list of references at the end of
this standard. used to calibrate the estimate. This technique is the method of
´1
E141–91 (2003)
two-phase sampling as discussed in Ref. (1). Helpful discus-
se~p!5 p~1 2 p!/~n 21! (4)
=
sion of an audit appears in Ref. (2).
5.2.3 Estimate—a quantity calculated on the n sample
(b) when u=the population total (u=Y) then
observations in the same way as the equal complete coverage
u5 Ny¯ and se ~u! 5 Nse ~y¯! (5)
result u would have been calculated from the entire set of N
possible observations of the population; the symbol u denotes
If a simple random sample of size n=200 has a=25 items
the estimate. (In calculating u, replicate subsample member-
with the attribute then the conclusion is u=0.125 and se
ship is ignored.)
(u)=0.023 on 199 degrees of freedom.
5.2.3.1 Discussion—An estimate has a sampling distribu-
5.2.4.4 Example 4—If uisaparameterotherthanameanor
tion induced from the randomness in sample selection. The
if the sample design is complex, then replicate subsamples
equal complete coverage result is effectively a constant while
should be used in the sample design. Denote the k separate
any estimate is only the value from one particular sample.
estimatesas u,i=1,2,., kanddenoteby utheestimatebased
i
Thus, there is a mean value of the sampling distribution and
onthewholesample.Theaverageofthe u willbecloseto,but
i
there is also a standard deviation of the sampling distribution.
in general not equal to u. The standard error of u is calculated
5.2.4 Standard Error—the quantity computed from the
as:
observations as an estimate of the sampling standard deviation
k
of the estimate; se (u) denotes the standard error. 2
se u 5 u 2u /k k 21 (6)
~ ! ~ ! ~ !
Π( i
i 51
5.2.4.1 Example1—When uisthepopulationaverageofthe
N quantities and a simple random sample of size n was drawn,
where u is the average of the u . The standard error is
then the sample average y becomes the usual estimate u, i
based on k−1 degrees of freedom.
where
The following estimates of percent “drug-in-suit” sales of
n
prescriptiondrugswerebasedon20replicatesubsamples;each
u5 y¯ 5 y /n. (1)
( i
i 51
followed a stratified cluster sampling design. The separate
The quantities y , y , ., y denote the observations. The estimateswere:6.8,7.1,8.4,9.5,8.6,4.1,3.7,3.2,3.8,5.8,8.8,
1 2 n
standard error is calculated as: 5.0, 7.9, 8.8, 8.4, 8.1, 6.0, 6.3, 4.5, 5.8. The value of u was
6.74% and se(u)=0.43% on 19 degrees of freedom. Notice
n
se u! 5 se y¯! 5 y 2 y¯! /n~n 21!. (2) that u =6.58 does not equal u=6.74. This is because u is a
~ ~ ~
Π( i
i 51
ratio of two overall averages while u is the average of 20
1 3
There are n −1 degrees of freedom in this standard error.
ratios. For an example with k=2, average ⁄3 and ⁄5 and
When the observations are: compare to (1+3)/(3+5).
81.6, 78.7, 79.7, 78.3, 80.9, 79.5, 79.8, 80.3, 79.5, 80.7
5.2.5 Procedures—must be described in written form and
should cover the following matters; (1) parties interested in
then y=79.90and se(y¯)=0.32.Asthisexampleillustrates,
collecting data should agree on the importance of knowing u
formula (2) is correct when k replaces n and subsample
and its definition including measurement methods, (2) the
estimates are used in place of observations.
frame shall be carefully and explicitly constructed; N shall be
5.2.4.2 Example 2 on the Finite Population Correction
well established, (3) random numbers (or a certifiably honest
(fpc)—Multiplying se (y¯) by 1 2 n/N is always correct
=
physical random device) shall dictate selection of the sample.
when the goal of the survey is to estimate the finite population
There will be no substitution of one sampling unit for another.
mean (u= Y). Using the previous data and if N=50, then
The method of sample selection shall permit calculation of a
se(y¯) becomes se(y¯)=0.28 after applying the fpc. If random
standard error of the estimate (4) the use of replicate sub-
measurement error exists in the observations, then u8 based on
samples is recommended (see 5.2); an audit subsample should
a reference measurement method may be a more appropriate
be selected and processed and any departures from prescribed
survey goal than u (see section 4.1.4.1). If so, then se(y¯) would
...


This document is not anASTM standard and is intended only to provide the user of anASTM standard an indication of what changes have been made to the previous version. Because
it may not be technically possible to adequately depict all changes accurately, ASTM recommends that users consult prior editions as appropriate. In all cases only the current version
of the standard as published by ASTM is to be considered the official document.
An American National Standard
e1
Designation:E141–91(Reapproved 1997) Designation:E141–91(Reapproved 2003)
Standard Practice for
Acceptance of Evidence Based on the Results of Probability
Sampling
This standard is issued under the fixed designation E141; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision.Anumber in parentheses indicates the year of last reapproval.A
superscript epsilon (e) indicates an editorial change since the last revision or reapproval.
e NOTE—Editorial changes were made throughout in November 2003.
1. Scope
1.1 This practice presents rules for accepting or rejecting evidence based on a sample. Statistical evidence for this practice is
in the form of an estimate of a proportion, an average, a total, or other numerical characteristic of a finite population or lot. It is
an estimate of the result which would have been obtained by investigating the entire lot or population under the same rules and
with the same care as was used for the sample.
1.2 One purpose of this practice is to describe straightforward sample selection and data calculation procedures so that courts,
commissions, etc. will be able to verify whether such procedures have been applied. The methods may not give least uncertainty
at least cost, they should however furnish a reasonable estimate with calculable uncertainty.
1.3 This practice is primarily intended for one-of-a-kind studies. Repetitive surveys allow estimates of sampling uncertainties
tobepooled;theemphasisofthispracticeisonestimationofsamplinguncertaintyfromthesampleitself.Theparameterofinterest
for this practice is effectively a constant. Thus, the principal inference is a simple point estimate to be used as if it were the
unknown constant, rather than, for example, a forecast or prediction interval or distribution devised to match a random quantity
of interest.
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 and health practices and determine the applicability of regulatory
limitations prior to use.
2. Referenced Documents
2.1 ASTM Standards:
E105 Practice for Probability Sampling of Materials
E122 Practice for Choice of Sample Size to Estimate a Measure of Quality for a Lot or Process
E178 Practice for Dealing with Outlying Observations
E456 Terminology for Statistical Methods
NOTE 1—Practice E105 provides a statement of principles for guidance of ASTM technical committees and others in the preparation of a sampling
planforaspecificmaterial.PracticeE122aidsindecidingontherequiredsamplesize.PracticeE178helpsinsurebetterbehavedestimates.Terminology
E456 provides definitions of statistical terms used in this standard.
3. Terminology
3.1 Definitions:
3.1.1 Equal Complete Coverage Result, n— the numerical characteristic (u) of interest calculated from observations made by
drawing randomly from the frame, all of the sampling units covered by the frame.
3.1.1.1 Discussion—Locating the units and evaluating them are supposed to be done in exactly the same way and at the same
time as was done for the sample.The quantity itself is denoted u.The equal complete coverage result is never actually calculated.
Its purpose is to serve as the objectively defined concrete goal of the investigation. The quantity u may be the population mean,
¯
(Y), total (Y), median (M), the proportion (P), or any other such quantity.
3.1.2 frame, n—a list, compiled for sampling purposes, which designates all of the sampling units (items or groups) of a
population or universe to be considered in a specific study.
3.1.2.1 Discussion—The list may cover a specific shipment or lot, all households in a county, a state, or country; for example,
This practice is under the jurisdiction of ASTM Committee E-11E11 on Quality and Statistical Methods and is the direct responsibility of Subcommittee E11.10 on
Sampling and Data Analysis. Sampling.
Current edition approved August 15, 1991. Published November 1991. Originally published as E141–59 T. Last previous edition E141–69 (1975).
Annual Book of ASTM Standards, Vol 14.02.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959, United States.
e1
E141–91 (2003)
any population of interest. Every sampling unit in the frame (1) has a unique serial number, which may be preassigned or
determined by some definite rule, (2) has an address—a complete and clear instruction (or rules for its formulation) as to where
and when to make the observation or evaluation, (3) is based on physically concrete clerical materials such as directories, dials
of clocks or of meters, ledgers, maps, aerial photographs, etc., referred to in the addresses.
3.1.3 sample,n—agroupofitems,observations,testresults,orportionsofmaterial,takenfromalargercollectionofsuchitems;
it provides information for decisions concerning the larger collection.
3.1.3.1 Discussion—A particular sample is identified by the set of serial numbers from the randomization device and by the
addresses on the frame generated by those serial numbers.
3.1.4 sampling unit, n—anitem,testspecimenorportionofmaterialthatistobesubjectedtoevaluationaspartofthesampling
plan.
3.1.4.1 Discussion—If it is not feasible to select test specimens or laboratory samples individually, the sampling unit may be
a group of items, for example, a row, an entire case of items, or a prescribed area (as in the examination of a finishing process).
3.1.4.2 Byamoreexpensivemethodofmeasurement(futuretime,moreelaborateframe)itmaybepossibletodefineaquantity,
u8, as a target parameter or ideal goal of an investigation. Criticism that holds u to be an inappropriate goal should demonstrate
that the numerical difference between u and u8 is substantial. Measurements may be imprecise but so long as measurement errors
are not too biased, a large size of the lot or population, N, insures that u and u8 are essentially equal.
4. Significance and Use
4.1 This practice is designed to permit users of sample survey data to judge the trustworthiness of results from such surveys.
Section 5 gives extended definitions of the concepts basic to survey sampling and the user should verify that such concepts were
indeed used and understood by those who conducted the survey. What was the frame? How large (exactly) was the quantity N?
How was the parameter u estimated and its standard error calculated? If replicate subsamples were not used, why not?
4.2 Adequate answers should be given for all questions. There are many acceptable answers to the last question. If the sample
design was relatively simple, such as simple random or stratified, then good estimates of sampling variance are easily available.
If a more complex design was used then methods such as discussed in [1] may be acceptable. Replicate subsamples is the most
straightforward way to estimate sampling variances when the survey design is complex.
4.3 Once the survey procedures that were used satisfy Section 5, consult Section 4 to see if any increase in sample size is
needed. The calculations for making it are objectively described in Section 4.
4.4 Refer to Section 6 to guide in the interpretation of the uncertainty in the reported value of the parameter estimate, u, i.e.
thevalueofitsstandarderror,se(u).Thequantityse(u)shouldbereviewedtoverifythattherisksitentailsarecommensuratewith
the size of the sample.
5. Descriptive Terms and Procedures
5.1 Probability Sampling Plans—include instructions for using either:
5.1.1 carefully prepared tables of random number,
5.1.2 computer algorithms, carefully programmed and run on a large computer, to generate pseudo-random numbers or,
5.1.3 certifiably honest physical devices, such as coin flips, to select the sample units so that inferences may be drawn from the
test results and decisions may be made with risks correctly calculated by probability theory.
5.1.4 Such plans are defined and their relative advantages discussed in [1], [2] and [6].
5.2 Replicate Subsamples—a number of disjoint samples, each one separately drawn from the frame in accord with the same
probability sampling plan. When appropriate, separate laboratories should each work on separate replicate subsamples and teams
of investigators should be assigned to separate replicate subsamples. This approach insures that the calculated standard error will
not be a systematic underestimate. Such subsamples were called interpenetrating in [5] where many of their basic properties were
described. See [2] for further theory and applications.
5.2.1 Discussion—For some types of material a sample selected with uniform spacing along the frame (systematic sample) has
increased precision over a selection made with randomly varying spacings (simple random sample). Examples include sampling
mineraloreorgrainfromaconveyorbeltorsamplingfromalistofhouseholdsalongastreet.Ifthesystematicsampleisobtained
byasinglerandomstarttheplanisthenaprobabilitysamplingplan,butitdoesnotpermitcalculatingthestandarderrorasrequired
by this practice. After dividing the sample size by an integer k (such as k =4or k =10) and using a random start for each of k
replicate subsamples, some of the increased precision of systematic sampling (and a standard error on k−1 degrees of freedom)
can be achieved.
5.2.2 Audit Subsample—a small subsample of the survey sample (as few as 10 observations may be adequate) for review of all
procedures from use of the random numbers through locating and measurement, to editing, coding, data entry and tabulation.
Selection of the audit subsample may be done by putting the n sample observations in order as they are collected, calculating the
nearest integer to n , or some other convenient integer, and taking this number to be the spacing for systematic selection of the
=
audit subsample. The review should uncover any gross departures from prescribed practices or any conceptual misunderstandings
in the definitions. If the audit subsample is large enough (say 30 observations or more) the regression of audited values on initial
observationsmaybeusedtocalibratetheestimate.Thistechniqueisthemethodoftwo-phasesamplingasdiscussedin[1].Helpful
discussion of an audit appears in [2].
e1
E141–91 (2003)
5.2.3 Estimate—a quantity calculated on the n sample observations in the same way as the equal complete coverage result u
would have been calculated from the entire set of N possible observations of the population; the symbol u denotes the estimate.
(In calculating u, replicate subsample membership is ignored.)
5.2.3.1 Discussion—An estimate has a sampling distribution induced from the randomness in sample selection. The equal
complete coverage result is effectively a constant while any estimate is only the value from one particular sample. Thus, there is
a mean value of the sampling distribution and there is also a standard deviation of the sampling distribution.
5.2.4 Standard Error—the quantity computed from the observations as an estimate of the sampling standard deviation of the
estimate; se (u) denotes the standard error.
5.2.4.1 Example 1—When u is the population average of the N quantities and a simple random sample of size n was drawn,
then the sample average y becomes the usual estimate u, where
n
u5 y¯ 5 y /n. (1)
(
i
i51
n
u5 y¯ 5 y /n. (1)
( i
i 51
The quantities y , y , ., y denote the observations. The standard error is calculated as:
1 2 n
n
se ~u!5se ~y¯! 5 ~y 2 y¯! /n~n 21!. (2)
Œ(
i
i51
n
se ~ u! 5 se ~y¯! 5 ~y 2 y¯! /n~n 21!. (2)
Π(
i
i 51
There are n −1 degrees of freedom in this standard error. When the observations are:
81.6, 78.7, 79.7, 78.3, 80.9, 79.5, 79.8, 80.3, 79.5, 80.7
then y=79.90 and se(y¯)=0.32.As this example illustrates, formula (2) is correct when k replaces n and subsample estimates
are used in place of observations.
5.2.4.2 Example 2 on the Finite Population Correction (fpc)—Multiplyingse(y¯)by 1 2 n/Nisalwayscorrectwhenthegoal
=
of the survey is to estimate the finite population mean (u= Y). Using the previous data and if N=50, then se(y¯) becomes
se(y¯)=0.28 after applying the fpc. If random measurement error exists in the observations, then u8 based on a reference
measurementmethodmaybeamoreappropriatesurveygoalthan u(seesection4.1.4.1).Ifso,then se(y¯)wouldbefurtheradjusted
upward by an amount somewhat less than the downward adjustment of the fpc. Both of these adjustments are often numerically
so small that these adjustments may be omitted—leaving se(y¯) of (2) as a slight overestimate.
5.2.4.3 Example 3—If the quantity of interest is (a) a proportion or (b) a total and the sample is simple random then the above
formulas are still applicable. A proportion is the mean of zeroes and ones, while the total is a constant times the mean. Thus:
(a) when u is taken to be the population proportion (u= P) then;
u5 p 5 (y/n 5 a/n (3)
i
where:
a is the number of units in the sample with the attribute, and
se~p!5 =p~1 2 p!/~n 21! (4)
(b) when u=the population total (u=Y) then
u5 Ny¯ and se ~u! 5 Nse ~y¯! (5)
Ifasimplerandomsampleofsize n=200has a=25itemswiththeattributethentheconclusionis u=0.125and se(u)=0.023
on 199 degrees of freedom.
5.2.4.4 Example 4.If u is a parameter other than a mean or if the sample design is complex, then replicate subsamples should
be used in the sample design. Denote the k separate estimates as u,i=1, 2, ., k and denote by u the estimate based on the whole
i
sample. The average of the uwill be close to, but in general not equal to u. The standard error of u is calculated as:
i
k
se ~u! 5 ~u 2u! /k~k 21! (6)
Π(
i
i 51
k
se ~u! 5 ~u 2u! /k~k 21! (6)
Π(
i
i 51
where u is the average of the u. The standard error is based on k−1 degrees of freedom.
i
The following estimates of percent “drug-in-suit” sales of prescription drugs were based on 20 replicate subsamples; each
followed a stratified cluster sampling design. The separate estimates were: 6.8, 7.1, 8.4, 9.5, 8.6, 4.1, 3.7, 3.2, 3.8, 5.8, 8.8, 5.0,
e1
E141–91 (2003)
7.9,8.8,8.4,8.1,6.0,6.3,4.5,5.8.Thevalueof uwas6.74%andse(u)=0.43%on19degreesoffreedom.Noticethat u =6.58
does not equal u=6.74. This is because u is a ratio of two overall averages while u is the average of 20 ratios. For an example
1 3
with k=2, average ⁄3 and ⁄5 and compare to
...

Questions, Comments and Discussion

Ask us and Technical Secretary will try to provide an answer. You can facilitate discussion about the standard in here.

This May Also Interest You

ASTM
ASTM E3080-23(Practice)
Standard Practice for Regression Analysis with a Single Predictor Variable

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.
SIGNIFICANCE AND USE
4.1 Regression analysis is a procedure that uses data to study the statistical relationships between two or more variables (1, 2).3 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.  
4.2 A regression model consists of: (1) a regression function that relates the mean values of the response variable distribution to fixed values of the predictor variable, and (2) a statistical distribution that describes the variability in the response variable values at a fixed value of the predictor variable.  
4.2.1 The regression analysis utilizes either experimental or observational data to estimate the parameters defining a regression model and their precision. Diagnostic procedures are utilized to assess the resulting model fit and can suggest other models for improved prediction performance.  
4.3 The information in this practice is arranged as follows.  
4.3.1 Section 5 gives a general outline of the steps in the regression analysis procedure. The subsequent sections cover procedures for estimation of specific regression models.  
4.3.2 Section 6 assumes a straight line relationship between the two variables. This is also known as the simple linear regression model or a first order model. This model should be used as a starting point for understanding the XY relationship and ultimately defining the best fitting model to the data.  
4.3.3 Section 7 considers a proportional relationship between the variables, where the ratio of one variable to the other is constant. The intercept is constrained to be zero. This model is useful for single point calibration, where a reference material is run periodically as a standard during routine testing to correct for drift in instrument performance over a given range of test results.  
4.3.4 Section 8 di...
SCOPE
1.1 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.  
1.2 The regression analysis provides graphical and calculational procedures for selecting the best statistical model that describes the relationship and for evaluation of the fit of the data to the selected model.  
1.3 The resulting regression model can be useful for developing process knowledge through description of the variable relationship, in making predictions of future values, in relating the precision of a test method to the value of the characteristic being measured, and in developing control methods for the process generating values of the variables.  
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 ...

  • Standard
    23 pages
    English language
    sale 15% off
  • Standard
    23 pages
    English language
    sale 15% off
ASTM
ASTM E141-10(2023)(Practice)
Standard Practice for Acceptance of Evidence Based on the Results of Probability Sampling

ABSTRACT
This practice presents rules for accepting or rejecting evidence based on a sample. Statistical evidence for this practice is in the form of an estimate of a proportion, an average, a total, or other numerical characteristic of a finite population or lot. This practice is an estimate of the result which would have been obtained by investigating the entire lot or population under the same rules and with the same care as was used for the sample. One purpose of this practice is to describe straightforward sample selection and data calculation procedures so that courts, commissions, etc. will be able to verify whether such procedures have been applied.
SIGNIFICANCE AND USE
4.1 This practice is designed to permit users of sample survey data to judge the trustworthiness of results from such surveys. Practice E105 provides a statement of principles for guidance of ASTM technical committees and others in the preparation of a sampling plan for a specific material. Guide E1402 describes the principal types of sampling designs. Practice E122 aids in deciding on the required sample size.  
4.2 Section 5 gives extended definitions of the concepts basic to survey sampling and the user should verify that such concepts were indeed used and understood by those who conducted the survey. What was the frame? How large (exactly) was the quantity N? How was the parameter θ estimated and its standard error calculated? If replicate subsamples were not used, why not? Adequate answers should be given for all questions. There are many acceptable answers to the last question.  
4.3 If the sample design was relatively simple, such as simple random or stratified, then fully valid estimates of sampling variance are easily available. If a more complex design was used then methods such as discussed in Ref (1)3 or in Guide E1402 may be acceptable. Use of replicate subsamples is the most straightforward way to estimate sampling variances when the survey design is complex.  
4.4 Once the survey procedures that were used satisfy Section 5, see if any increase in sample size is needed. The calculations for making it objectively are described in Section 6.  
4.5 Refer to Section 7 to guide in the interpretation of the uncertainty in the reported value of the parameter estimate, θ^, that is, the value of its standard error, se(θ^). The quantity se(θ^) should be reviewed to verify that the risks it entails are commensurate with the size of the sample.  
4.6 When the audit subsample shows that there was reasonable conformity with prescribed procedures and when the known instances of departures from the survey plan can be shown to have no appreciable effect on the est...
SCOPE
1.1 This practice presents rules for accepting or rejecting evidence based on a sample. Statistical evidence for this practice is in the form of an estimate of a proportion, an average, a total, or other numerical characteristic of a finite population or lot. It is an estimate of the result which would have been obtained by investigating the entire lot or population under the same rules and with the same care as was used for the sample.  
1.2 One purpose of this practice is to describe straightforward sample selection and data calculation procedures so that courts, commissions, etc. will be able to verify whether such procedures have been applied. The methods may not give least uncertainty at least cost, they should however furnish a reasonable estimate with calculable uncertainty.  
1.3 This practice is primarily intended for one-of-a-kind studies. Repetitive surveys allow estimates of sampling uncertainties to be pooled; the emphasis of this practice is on estimation of sampling uncertainty from the sample itself. The parameter of interest for this practice is effectively a constant. Thus, the principal inference is a simple point estimate to be used as if it were the unknown constant, rather than, for example, a forecast or prediction interval or distribution...

  • Standard
    6 pages
    English language
    sale 15% off
ASTM
ASTM E2709-23(Practice)
Standard Practice for Demonstrating Capability to Comply with an Acceptance Procedure

ABSTRACT
This practice provides a general methodology for evaluating single-stage or multiple-stage acceptance procedures which involve a quality characteristic measured on a numerical scale. This methodology computes, at a prescribed confidence level, a lower bound on the probability of passing an acceptance procedure, using estimates of the parameters of the distribution of test results from a sampled population.
SIGNIFICANCE AND USE
4.1 This practice considers inspection procedures that may involve multiple-stage sampling, where at each stage one can decide to accept or to continue sampling, and the decision to reject is deferred until the last stage.  
4.1.1 At each stage there are one or more acceptance criteria on the test results; for example, limits on each individual test result, or limits on statistics based on the sample of test results, such as the average, standard deviation, or coefficient of variation (relative standard deviation).  
4.2 The methodology in this practice defines an acceptance region for a set of test results from the sampled population such that, at a prescribed confidence level, the probability that a sample from the population will pass the acceptance procedure is greater than or equal to a prespecified lower bound.  
4.2.1 Having test results fall in the acceptance region is not equivalent to passing the acceptance procedure, but provides assurance that a sample would pass the acceptance procedure with a specified probability.  
4.2.2 This information can be used for process demonstration, validation of test methods, and qualification of instruments, processes, and materials.  
4.2.3 This information can be used for lot release (acceptance), but the lower bound may be conservative in some cases.  
4.2.4 If the results are to be applied to future test results from the same process, then it is assumed that the process is stable and predictable. If this is not the case then there can be no guarantee that the probability estimates would be valid predictions of future process performance.  
4.3 This methodology was originally developed (1-4)3 for use in two specific quality characteristics of drug products in the pharmaceutical industry but will be applicable for acceptance procedures in all industries.  
4.4 Mathematical derivations would be required that are specific to the individual criteria of each test.
SCOPE
1.1 This practice provides a general methodology for evaluating single-stage or multiple-stage acceptance procedures which involve a quality characteristic measured on a numerical scale. This methodology computes, at a prescribed confidence level, a lower bound on the probability of passing an acceptance procedure, using estimates of the parameters of the distribution of test results from a sampled population.  
1.2 For a prescribed lower probability bound, the methodology can also generate an acceptance limit table, which defines a set of test method outcomes (for example, sample averages and standard deviations) that would pass the acceptance procedure at a prescribed confidence level.  
1.3 This approach may be used for demonstrating compliance with in-process, validation, or lot-release specifications.  
1.4 The system of units for this practice is not specified.  
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 issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

  • Standard
    8 pages
    English language
    sale 15% off
  • Standard
    8 pages
    English language
    sale 15% off
ASTM
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 ...

  • Standard
    10 pages
    English language
    sale 15% off
ASTM
ASTM E1994-09(2023)(Practice)
Standard Practice for Use of Process Oriented AOQL and LTPD Sampling Plans

ABSTRACT
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. Two general types of tables are given, one based on the concept of lot tolerance, LTPD, and the other on AOQL. For each of the types, tables are provided both for single sampling and for double sampling. Each of the individual tables constitutes a collection of solutions to the problem of minimizing the over-all amount of inspection.
SIGNIFICANCE AND USE
4.1 Two general types of tables (Note 1) are given, one based on the concept of lot tolerance, LTPD, and the other on AOQL. The broad conditions under which the different types have been found best adapted are indicated below.  
4.1.1 For each of the types, tables are provided both for single sampling and for double sampling. Each of the individual tables constitutes a collection of solutions to the problem of minimizing the over-all amount of inspection. Because each line in the tables covers a range of lot sizes, the AOQL values in the LTPD tables and the LTPD values in the AOQL tables are often conservative.
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.

  • Standard
    23 pages
    English language
    sale 15% off
ASTM
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.

  • Standard
    5 pages
    English language
    sale 15% off
ASTM
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...

  • Standard
    29 pages
    English language
    sale 15% off
ASTM
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.

  • Standard
    26 pages
    English language
    sale 15% off
ASTM
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.

  • Standard
    11 pages
    English language
    sale 15% off
  • Standard
    11 pages
    English language
    sale 15% off
ASTM
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...

  • Standard
    24 pages
    English language
    sale 15% off
  • Standard
    24 pages
    English language
    sale 15% off