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ASTM G138-12(2020)e1

(Test Method)

Standard Test Method for Calibration of a Spectroradiometer Using a Standard Source of Irradiance

Standard Test Method for Calibration of a Spectroradiometer Using a Standard Source of Irradiance

SIGNIFICANCE AND USE
4.1 This method is intended for use by laboratories performing calibration of a spectroradiometer for spectral irradiance measurements using a spectral irradiance standard with known spectral irradiance values and associated uncertainties traceable to a national metrological laboratory that has participated in intercomparisons of standards of spectral irradiance, known uncertainties and known measurement geometry.  
4.2 This method is generalized to allow for the use of different types of input optics provided that those input optics are suitable for the wavelength range and measurement geometry of the calibration.  
4.3 This method is generalized to allow for the use of different types of monochromators provided that they can be configured for a bandwidth, wavelength range, and throughput levels suitable for the calibration being performed.  
4.4 This method is generalized to allow for the use of different types of optical radiation detectors provided that the spectral response of the detector over the wavelength range of the calibration is appropriate to the signal levels produced by the monochromator.
SCOPE
1.1 This test method covers the calibration of spectroradiometers for the measurement of spectral irradiance using a standard of spectral irradiance that is traceable to a national metrological laboratory that has participated in intercomparisons of standards of spectral irradiance.  
1.2 This method is not limited by the input optics of the spectroradiometric system. However, choice of input optics affects the overall uncertainty of the calibration.  
1.3 This method is not limited by the type of monochromator or optical detector used in the spectroradiometer system. Parts of the method may not apply to determine which parts apply to the specific spectroradiometer being used. It is important that the choice of monochromator and detector be appropriate for the wavelength range of interest for the calibration. Though the method generally applies to photodiode array detector based systems, the user should note that these types of spectroradiometers often suffer from stray light problems and have limited dynamic range. Diode array spectroradiometers are not recommended for use in the ultraviolet range unless these specific problems are addressed.  
1.4 The calibration described in this method employs the use of a standard of spectral irradiance. The standard of spectral irradiance must have known spectral irradiance values at given wavelengths for a specific input current and clearly defined measurement geometry. Uncertainties must also be known for the spectral irradiance values. The values assigned to this standard must be traceable to a national metrological laboratory that has participated in intercomparisons of standards of spectral irradiance. These standards may be obtained from a number of national standards laboratories and commercial laboratories. The spectral irradiance standards consist mainly of tungsten halogen lamps with coiled filaments enclosed in a quartz envelope, though other types of lamps are used. Standards can be obtained with calibration values covering all or part of the wavelength range from 200 to 4500 nm.  
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.2  
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.

General Information

Status
Published
Publication Date
31-May-2020
ICS
19.100 - Non-destructive testing
Technical Committee
G03 - Weathering and Durability
Drafting Committee
G03.09 - Radiometry
Current Stage
Ref Project

Relations

Replaces
ASTM G138-12 - Standard Test Method for Calibration of a Spectroradiometer Using a Standard Source of Irradiance
Effective Date
01-Jun-2020
Refers
ASTM E772-13 - Standard Terminology of Solar Energy Conversion
Effective Date
01-Sep-2013
Refers
ASTM E1341-06(2011)e1 - Standard Practice for Obtaining Spectroradiometric Data from Radiant Sources for Colorimetry
Effective Date
01-Nov-2011
Refers
ASTM E772-11 - Standard Terminology of Solar Energy Conversion
Effective Date
01-Sep-2011
Refers
ASTM E1341-06 - Standard Practice for Obtaining Spectroradiometric Data from Radiant Sources for Colorimetry
Effective Date
01-Jul-2006
Refers
ASTM E772-05 - Standard Terminology Relating to Solar Energy Conversion
Effective Date
01-Apr-2005
Refers
ASTM E1341-96 - Standard Practice for Obtaining Spectroradiometric Data from Radiant Sources for Colorimetry
Effective Date
01-Jan-2001
Refers
ASTM E1341-96(2001) - Standard Practice for Obtaining Spectroradiometric Data from Radiant Sources for Colorimetry
Effective Date
01-Jan-2001
Refers
ASTM E772-87(1993)e1 - Standard Terminology Relating to Solar Energy Conversion
Effective Date
27-Feb-1987
Refers
ASTM E772-87(2001) - Standard Terminology Relating to Solar Energy Conversion
Effective Date
27-Feb-1987
Referred By
ASTM G130-12(2020) - Standard Test Method for Calibration of Narrow- and Broad-Band Ultraviolet Radiometers Using a Spectroradiometer
Effective Date
01-Jun-2020
Referred By
ASTM E824-10(2018)e1 - Standard Test Method for Transfer of Calibration From Reference to Field Radiometers
Effective Date
01-Jun-2020
Referred By
ASTM E927-19 - Standard Classification for Solar Simulators for Electrical Performance Testing of Photovoltaic Devices
Effective Date
01-Jun-2020
Referred By
ASTM E2848-13(2023) - Standard Test Method for Reporting Photovoltaic Non-Concentrator System Performance
Effective Date
01-Jun-2020
Referred By
ASTM E1125-16(2020) - Standard Test Method for Calibration of Primary Non-Concentrator Terrestrial Photovoltaic Reference Cells Using a Tabular Spectrum
Effective Date
01-Jun-2020

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ASTM G138-12(2020)e1 - Standard Test Method for Calibration of a Spectroradiometer Using a Standard Source of IrradianceASTM G138-12(2020)e1 - Standard Test Method for Calibration of a Spectroradiometer Using a Standard Source of Irradiance
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ASTM G138-12(2020)e1 - Standard Test Method for Calibration of a Spectroradiometer Using a Standard Source of Irradiance
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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.
´1
Designation: G138 − 12 (Reapproved 2020)
Standard Test Method for
Calibration of a Spectroradiometer Using a Standard Source
of Irradiance
This standard is issued under the fixed designation G138; 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.
ε NOTE—An editorial change was made to 3.1 in July 2020.
INTRODUCTION
Astandardized means of performing and reporting calibration of the spectroradiometer for spectral
irradiance measurements is desirable.
This test method presents specific technical requirements for a laboratory performing calibration of
a spectroradiometer for spectral irradiance measurements. A detailed procedure for performing the
calibration and reporting the results is outlined.
This test method for calibration is applicable to spectroradiometric systems consisting of at least a
monochromator, input optics, and an optical radiation detector, and applies to spectroradiometric
calibrations performed with a standard of spectral irradiance with known irradiance values traceable
to a national metrological laboratory that has participated in intercomparisons of standards of spectral
irradiance. The standard must also have known uncertainties and measurement geometry associated
with its irradiance values.
1. Scope troradiometers are not recommended for use in the ultraviolet
range unless these specific problems are addressed.
1.1 This test method covers the calibration of spectroradi-
ometers for the measurement of spectral irradiance using a 1.4 The calibration described in this method employs the
use of a standard of spectral irradiance. The standard of
standard of spectral irradiance that is traceable to a national
metrological laboratory that has participated in intercompari- spectral irradiance must have known spectral irradiance values
at given wavelengths for a specific input current and clearly
sons of standards of spectral irradiance.
defined measurement geometry. Uncertainties must also be
1.2 This method is not limited by the input optics of the
known for the spectral irradiance values. The values assigned
spectroradiometric system. However, choice of input optics
to this standard must be traceable to a national metrological
affects the overall uncertainty of the calibration.
laboratory that has participated in intercomparisons of stan-
1.3 This method is not limited by the type of monochroma-
dards of spectral irradiance. These standards may be obtained
tor or optical detector used in the spectroradiometer system.
from a number of national standards laboratories and commer-
Parts of the method may not apply to determine which parts
cial laboratories. The spectral irradiance standards consist
apply to the specific spectroradiometer being used. It is
mainly of tungsten halogen lamps with coiled filaments en-
important that the choice of monochromator and detector be
closed in a quartz envelope, though other types of lamps are
appropriate for the wavelength range of interest for the
used. Standards can be obtained with calibration values cov-
calibration. Though the method generally applies to photo-
ering all or part of the wavelength range from 200 to 4500 nm.
diode array detector based systems, the user should note that
1.5 This standard does not purport to address all of the
these types of spectroradiometers often suffer from stray light
safety concerns, if any, associated with its use. It is the
problems and have limited dynamic range. Diode array spec-
responsibility of the user of this standard to establish appro-
priate safety, health, and environmental practices and deter-
mine the applicability of regulatory limitations prior to use.
This test method is under the jurisdiction of ASTM Committee G03 on
Weathering and Durability and is the direct responsibility of Subcommittee G03.09
on Radiometry.
CurrenteditionapprovedJune1,2020.PublishedJuly2020.Originallyapproved Available from the CIE, (International Commission on Illumination), http://
in 1996. Last previous edition approved in 2012 as G138–12. DOI: 10.1520/ www.techstreet.com/ciegate.tmpl CIE Central Bureau, Kegelgasse 27, A-1030
G0138-12R20E01. Vienna, Austria.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
´1
G138 − 12 (2020)
1.6 This international standard was developed in accor- 3.1.11 ultraviolet, adj—optical radiation at wavelengths be-
dance with internationally recognized principles on standard- low 400 nanometres.
ization established in the Decision on Principles for the
3.2 Definitions of Terms Specific to This Standard:
Development of International Standards, Guides and Recom-
3.2.1 calibration subsystems, n—the instruments used to
mendations issued by the World Trade Organization Technical
supply and monitor current to a standard lamp during
Barriers to Trade (TBT) Committee.
calibration, consisting of a DC power supply, a current shunt,
and a digital voltmeter.
2. Referenced Documents
3.2.2 National Metrological Institution (NMI), n—A na-
2.1 ASTM Standards:
tion‘s internationally recognized standardization laboratory.
E772Terminology of Solar Energy Conversion
3.2.2.1 Discussion—The International Bureau of Weights
E1341Practice for Obtaining Spectroradiometric Data from
andMeasurements(abbreviationBIPMfromtheFrenchterms)
Radiant Sources for Colorimetry
establishestherecognitionthroughMutualRecognitionAgree-
2.2 Other Documents: ments. See http://www.bipm.org/en/cipm-mra. The NMI for
the United States of America is the National Institute for
CIEPublicationNo.63 TheSpectrodiometricMeasurement
of Light Sources Standards and Technology (NIST).
NIST Technical Note 1927:Guidelines for Evaluation and
3.2.3 passband,n—theeffectivebandwidth(c.f.),orspectral
Expressing Uncertainty of NIST Measurement Results
interval, over which the spectroradiometer system transmits at
agivenwavelengthsetting.Expressedasfull-widthatone-half
3. Terminology
maximum, as in bandwidth.Afunction of the linear dispersion
(nm/mm) and slit or aperture widths (mm) of the monochro-
3.1 Definitions:
mator system.
3.1.1 General terms pertaining to optical radiation and
opticalmeasurementsystemsaredefinedinTerminologyE772.
3.2.4 primary standard of spectral irradiance, n—a broad
Some of the more important terms from that standard used in
spectrum light source with known spectral irradiance values at
this paper are listed here.
various wavelengths which are traceable to a national metro-
3.1.2 bandwidth, n—the extent of a band of radiation
logical laboratory that has participated in intercomparisons of
reported as the difference between the two wavelengths at
standards of spectral irradiance.
which the amount of radiation is half of its maximum over the
3.2.5 responsivity, n—symbol R = dS/dφ, S is signal from
given band.
spectroradiometer detector, φ is radiant flux at the detector.
3.1.3 diffuser, n—a device used to scatter or disperse light
3.2.6 secondary standard of spectral irradiance, n—a stan-
usually through the process of diffuse transmission or reflec-
dard calibrated by reference to another standard such as a
tion.
primary or reference standard.
3.1.4 integrating sphere, n—a hollow sphere coated inter-
3.2.7 slit scattering function, n—symbol Z(λ ,λ),therespon-
o
nallywithawhitediffusereflectingmaterialandprovidedwith
sivity of the combined detector and monochromator system as
separate openings for incident and exiting radiation.
a function of wavelengths, λ, in the neighborhood of a given
3.1.5 irradiance, n—radiant flux incident per unit area of a
wavelength setting, λ . The slit scattering function is the
o
surface.
spectral responsivity in the neighborhood of specific wave-
length setting, λ .
3.1.6 monochromator, n—aninstrumentforisolatingnarrow
o
portions of the optical spectrum of a light source
3.2.8 spectral scattering (stray light), n— light with wave-
lengthsoutsidethepassbandofaspectroradiometeraparticular
3.1.7 polarization, n—with respect to optical radiation, the
wavelength setting that is received by the detector and contrib-
restriction of the magnetic or electric field vector to a single
utes to the output signal.
plane.
3.1.8 radiant flux, n—thetimerateofflowofradiantenergy
4. Significance and Use
measured in watts.
4.1 Thismethodisintendedforusebylaboratoriesperform-
3.1.9 spectral irradiance, n—irradianceperunitwavelength
ing calibration of a spectroradiometer for spectral irradiance
interval at a given wavelength.
measurements using a spectral irradiance standard with known
3.1.10 spectroradiometer, n—an instrument for measuring
spectral irradiance values and associated uncertainties trace-
the radiant energy of a light source at each wavelength
able to a national metrological laboratory that has participated
throughout the spectrum.
in intercomparisons of standards of spectral irradiance, known
uncertainties and known measurement geometry.
4.2 This method is generalized to allow for the use of
For referenced ASTM standards, visit the ASTM website, www.astm.org, or
different types of input optics provided that those input optics
contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
are suitable for the wavelength range and measurement geom-
Standards volume information, refer to the standard’s Document Summary page on
etry of the calibration.
the ASTM website.
G03
4.3 This method is generalized to allow for the use of
Available from American National Standards Institute, 11 West 42nd Street,
13th Floor, New York, NY 10036 different types of monochromators provided that they can be
´1
G138 − 12 (2020)
configured for a bandwidth, wavelength range, and throughput 1). If the monochromator has interchangeable slits, it is
levels suitable for the calibration being performed. important that the manufacturer document the effective band-
width of the monochromator with all possible combinations of
4.4 This method is generalized to allow for the use of
the slits or that these bandwidths be determined experimen-
different types of optical radiation detectors provided that the
tally. Configuration of the slits should be such that the
spectral response of the detector over the wavelength range of
bandpass function of the monochromator is symmetric, pref-
the calibration is appropriate to the signal levels produced by
erably triangular. The bandwidth should be constant across the
the monochromator.
wavelength region of interest and maintained between 85%
5. Apparatus and 100% of the measurement wavelength interval. The
precision of the wavelength positioning of the monochromator
5.1 Laboratory:
should be 0.1 nm with an absolute accuracy of better than 0.5
5.1.1 The room in which the calibrations are performed and
nm (see Practice E1341). For improved performance in the uv,
especially the area surrounding the optical bench should be
itisrecommendedthathighorderrejectionfiltersbeinsertedin
devoidofreflectivesurfaces.Thecalibrationvaluesassignedto
theopticalpathinthemonochromator.Thepurposeofthehigh
the spectral irradiance standard are for direct irradiance from
order rejection filters is to block radiation in the monochroma-
the lamp and any radiation entering the monochromator from
tor of unwanted wavelengths that could otherwise overpower
some other source including ambient reflections will be a
the signals being measured. The effects of variations in
source of error.
temperature and humidity on the performance of the mono-
5.1.2 The temperature and humidity in the laboratory shall
chromator should be addressed in writing by the manufacturer.
be maintained so as to agree with the conditions under which
5.2.1.2 The monochromator shall not be subject to shock or
the calibrations of the spectral irradiance standard and the
mechanical vibration during the calibration. This can be
calibration subsystems were performed (typically 20 °C,
facilitated by the use of a vibration isolated lab table. If any
25°C, 50% relative humidity).
optical parts in the monochromator are configurable by the
5.1.3 Air drafts in the laboratory should be minimized since
they could affect the output of electrical discharge lamps. user, refer to the manufacturer precautions about opening the
monochromator and handling any parts therein.
5.2 Spectroradiometer
5.2.2 Optical Radiation Detector:
5.2.1 Monochromator:
5.2.1.1 This can be a fixed or scanning, single or multiple, 5.2.2.1 The optical radiation detector employed by the
monochromator employing holographic or ruled gratings or spectroradiometer shall be selected for optimal response over
prisms or a combination of these dispersive elements. For the wavelength range of interest. It is also important that the
improved performance in the ultraviolet (UV) portion of the detector is sensitive enough to measure the levels of light that
spectrum, it is recommended that a scanning double mono- will be produced by the monochromator when it is configured
chromator be used to achieve lower stray light levels (see Fig. forthecalibrationprocess.Theactiveareaofthedetectorshall
FIG. 1 Typical Double Grating Monochromator Layout (courtesy Optronic Laboratories, Used with Permission)
´1
G138 − 12 (2020)
be evenly illuminated by the radiation leaving the exit slit of 5.3.2 Compare the signal from the detector with the filter in
the monochromator. A photomultiplier is typically used be- place to the shuttered, or dark signal of the detector. A signal
cause of its high responsivity and good signal-to-noise ratio. between 10% and 90% of the unfiltered signal indicates
For this reason it is recommended for use when measuring significant scattered light is reaching the detector, possibly due
spectral irradiance in the uv portion of the spectrum. to a non-light-tight enclosure.
5.2.2.2 Anyeffectsofvariationintemperatureandhumidity
5.4 Optical Radiation Sources
on the response of the detector documented by the manufac-
5.4.1 Wavelength Calibration Source:
turer shall be reported. Of all components of the
5.4.1.1 A stable wavelength source is required to calibrate
spectroradiometer, the detector is usually the most sensitive to
the wavelength positioning accuracy of the monochromator.
changesintemperature.Somedetectorsmayrequirecoolingin
Thiscanbeagasdischargelamporalaser.Theimportantthing
order to maintain a specific tempe
...

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Standard Test Method for Determination of Turbidity Below 5 NTU in Static Mode

SIGNIFICANCE AND USE
5.1 Turbidity is undesirable in drinking water, plant effluent waters, water for food and beverage processing, and for a large number of other water-dependent manufacturing processes. Removal is often accomplished by coagulation, settling, and filtration. Measurement of turbidity provides a rapid means of process control for when, how, and to what extent the water must be treated to meet specifications.  
5.2 This test method is suitable to turbidity such as that found in drinking water, process water, and high purity industrial water.  
5.3 When reporting the measured result, appropriate units should also be reported. The units are reflective of the technology used to generate the result, and if necessary, provide more adequate comparison to historical data sets.  
5.3.1 Table 1 describes technologies and reporting results (see also Refs (1-3)).6 Those technologies listed are appropriate for the range of measurement prescribed in this test method. Others may come available in the future. Fig. X5.1 provides a flow chart to aid in selection of the appropriate technology for low-level static turbidity applications.  
5.3.2 If a design that falls outside of the criteria listed in Table 1 is used, the turbidity should be reported in turbidity units (TU) with a subscripted wavelength value to characterize the light source that was used.
SCOPE
1.1 This test method covers the static determination of turbidity in water (see 4.1).  
1.2 This test method is applicable to the measurement of turbidities under 5.0 nephelometric turbidity units (NTU).  
1.3 This test method was tested on municipal drinking water, ultra-pure water, and low turbidity samples. It is the users responsibility to ensure the validity of this test method for waters of untested matrices.  
1.4 This test method uses calibration standards are defined in NTU values, but other assigned turbidity units are assumed to be equivalent.  
1.5 This test method assigns traceable reporting units to the type of respective technology that was used to perform the measurement. Units are numerically equivalent with respect to the calibration standard. For example, a 1.0 NTU formazin standard is also equal to a 1.0 FNU standard, a 1.0 FNRU standard, and so forth.  
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. Refer to the MSDSs for all chemicals used in this test method.  
1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM E2546-15(2023)(Practice)
Standard Practice for Instrumented Indentation Testing

SIGNIFICANCE AND USE
5.1 IIT Instruments are used to quantitatively measure various mechanical properties of thin coatings and other volumes of material when other traditional methods of determining material properties cannot be used due to the size or condition of the sample. This practice will establish the basic requirements for those instruments. It is intended that IIT based test methods will be able to refer to this practice for the basic requirements for force and displacement accuracy, reproducibility, verification, reporting, etc., that are necessary for obtaining meaningful test results.  
5.2 IIT is not restricted to specific test forces, displacement ranges, or indenter types. This practice covers the requirements for a wide range of nano, micro, and macro (see ISO 14577-1) indentation testing applications. The various IIT instruments are required to adhere to the requirements of the practice within their specific design ranges.
SCOPE
1.1 This practice defines the basic steps of Instrumented Indentation Testing (IIT) and establishes the requirements, accuracies, and capabilities needed by an instrument to successfully perform the test and produce the data that can be used for the determination of indentation hardness and other material characteristics. IIT is a mechanical test that measures the response of a material to the imposed stress and strain of a shaped indenter by forcing the indenter into a material and monitoring the force on, and displacement of, the indenter as a function of time during the full loading-unloading test cycle.  
1.2 The operational features of an IIT instrument, as well as requirements for Instrument Verification (Annex A1), Standardized Reference Blocks (Annex A2) and Indenter Requirements (Annex A3) are defined. This practice is not intended to be a complete purchase specification for an IIT instrument.  
1.3 With the exception of the non-mandatory Appendix X4, this practice does not define the analysis necessary to determine material properties. That analysis is left for other test methods. Appendix X4 includes some basic analysis techniques to allow for the indirect performance verification of an IIT instrument by using test blocks.  
1.4 Zero point determination, instrument compliance determination and the indirect determination of an indenter’s area function are important parts of the IIT process. The practice defines the requirements for these items and includes non-mandatory appendixes to help the user define them.  
1.5 The use of deliberate lateral displacements is not included in this practice (that is, scratch testing).  
1.6 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.7 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.  
1.8 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 E2862-23(Practice)
Standard Practice for Probability of Detection Analysis for Hit/Miss Data

SIGNIFICANCE AND USE
5.1 The POD analysis method described herein is based on a well-known and well established statistical regression method. It shall be used to quantify the demonstrated POD for a specific set of examination parameters and known range of discontinuity sizes under the following conditions.  
5.1.1 The initial response from a nondestructive evaluation inspection system is ultimately binary in nature (that is, hit or miss).  
5.1.2 Discontinuity size is the predictor variable and can be accurately quantified.  
5.1.3 A relationship between discontinuity size and POD exists and is best described by a generalized linear model with the appropriate link function for binary outcomes.  
5.2 This practice does not limit the use of a generalized linear model with more than one predictor variable or other types of statistical models if justified as more appropriate for the hit/miss data.  
5.3 If the initial response from a nondestructive evaluation inspection system is measurable and can be classified as a continuous variable (for example, data collected from an Eddy Current inspection system), then Practice E3023 may be more appropriate.  
5.4 Prior to performing the analysis it is assumed that the discontinuity of interest is clearly defined; the number and distribution of induced discontinuity sizes in the POD specimen set is known and well-documented; discontinuities in the POD specimen set are unobstructed; and the POD examination administration procedure (including data collection method) is well-designed, well-defined, under control, and unbiased. The analysis results are only valid if convergence is achieved and the model adequately represents the data.  
5.5 The POD analysis method described herein is consistent with the analysis method for binary data described in MIL-HDBK-1823A, and is included in several widely utilized POD software packages to perform a POD analysis on hit/miss data. It is also found in statistical software packages that have generalized line...
SCOPE
1.1 This practice covers the procedure for performing a statistical analysis on nondestructive testing hit/miss data to determine the demonstrated probability of detection (POD) for a specific set of examination parameters. Topics covered include the standard hit/miss POD curve formulation, validation techniques, and correct interpretation of results.  
1.2 The values stated in inch-pound units are to be regarded as standard. The values given in parentheses are mathematical conversions to SI units that are provided for information only and are not considered standard.  
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 E3370-23(Practice)
Standard Practice for Matrix Array Ultrasonic Testing of Composites, Sandwich Core Constructions, and Metals

SIGNIFICANCE AND USE
5.1 The procedures described in this practice have proven utility in the inspecting (1) monolithic polymer matrix composites (laminates) for bulk defects, (2) metals for corrosion during the service life of the part of interest, (3) thickness checks, (4) adhesive bonding of metals, composites, and sandwich core constructions, (5) coatings, and (6) composite filament windings. Both unpressurized, and with suitable precautions, pressurized materials and components are inspected.  
5.2 This practice provides guidelines for the application of longitudinal wave examination to the detection and quantitative evaluation of damage, discontinuities, and thickness variations in materials.  
5.3 This practice is intended primarily for the testing of parts to acceptance criteria most typically specified in a purchase order or other contractual document, and for testing of parts in-service to detect and evaluate damage.  
5.4 MAUT search units provide near-surface resolution and detection of small discontinuities comparable to phased array transducers. They may or may not be capable of beam steering. The advantage of MAUT for straight-beam longitudinal wave inspections is the ability to provide real-time C-scan data, which facilitates data interpretation and shortens inspection time. Depending on inspection needs, data can be displayed as A-, B- or C-scans, or three-dimensional renderings. Toggling between pulse-echo and through transmission ultrasonic (TTU) modes without having to use another system or changing transducers is also possible.  
5.5 The MAUT technique has proven utility in the inspection of multi-ply carbon-fiber reinforced laminates used in primary aircraft structures.11  
5.6 For ultrasonic testing of laminate composites and sandwich core materials using conventional UT equipment consult Practice E2580. Consult Practice E114 for ultrasonic testing of materials by the pulse-echo method using straightbeam longitudinal waves introduced by a piezoelectric elemen...
SCOPE
1.1 This practice covers procedures for matrix array ultrasonic testing (MAUT) of monolithic composites, composite sandwich constructions, and metallic test articles. These procedures can be used throughout the life cycle of a part during product and process design optimization, on line process control, post-manufacturing inspection, and in-service inspection.  
1.2 In general, ultrasonic testing is a common volumetric method for detection of embedded or subsurface discontinuities. This practice includes general requirements and procedures which may be used for detecting flaws and for making a relative or approximate evaluation of the size of discontinuities and part anomalies. The types of flaws or discontinuities detected include interply delaminations, foreign object debris (FOD), inclusions, disbond/un-bond, fiber debonding, fiber fracture, porosity, voids, impact damage, thickness variation, and corrosion.  
1.3 Typical test articles include monolithic composite layups such as uniaxial, cross ply and angle ply laminates, sandwich constructions, bonded structures, and filament windings, as well as forged, wrought and cast metallic parts. Two techniques can be considered based on accessibility of the inspection surface: namely, pulse echo inspection for one-sided access and through-transmission for two-sided access. As used in this practice, both require the use of a pulsed straight-beam ultrasonic longitudinal wave followed by observing indications of either the reflected (pulse-echo) or received (through transmission) wave.  
1.4 This practice provides two ultrasonic test procedures. Each has its own merits and requirements for inspection and shall be selected as agreed upon in a contractual document.  
1.4.1 Test Procedure A, Pulse Echo (non-contacting and contacting) is at a minimum a single matrix array transducer transmitting and receiving longitudinal waves in the range of 0.5 MHz to 20 MHz (see Fig. 1). Th...

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ASTM E1901-23(Guide)
Standard Guide for Detection and Evaluation of Discontinuities by Contact Pulse-Echo Straight-Beam Ultrasonic Methods

SIGNIFICANCE AND USE
6.1 This guide provides procedures for the application of contact straight-beam examination for the detection and quantitative evaluation of discontinuities in materials.  
6.2 Although not all requirements of this guide can be applied universally to all examinations, situations, and materials, it does provide basis for establishing contractual criteria between the users, and may be used as a general guide for preparing detailed specifications for a particular application.  
6.3 This guide is directed towards the evaluation of discontinuities detectable with the beam normal to the entry surface. If discontinuities or other orientations are of concern, alternate scanning techniques are required.
SCOPE
1.1 This guide covers procedures for the contact ultrasonic examination of bulk materials or parts by transmitting pulsed ultrasonic waves into the material and observing the indications of reflected waves. This guide covers only examinations in which one search unit is used as both transmitter and receiver (pulse-echo). This guide includes general requirements and procedures that may be used for detecting discontinuities, locating depth and distance from a point of reference and for making a relative or approximate evaluation of the size of discontinuities as compared to a reference standard.  
1.2 This guide complements Practice E114 by providing more detailed procedures for the selection and standardization of the examination system and for evaluation of the indications obtained.  
1.3 The values stated in inch-pound units are to be regarded as standard. The values given in parentheses are mathematical conversions to SI units that are provided for information only and are not considered standard.  
1.4 This guide 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 guide to establish the appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.5 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM E165/E165M-23(Practice)
Standard Practice for Liquid Penetrant Testing for General Industry

SIGNIFICANCE AND USE
5.1 Liquid penetrant testing methods indicate the presence, location, and to a limited extent, the nature and magnitude of the detected discontinuities. Each of the various penetrant methods has been designed for specific uses such as critical service items, volume of parts, portability, or localized areas of examination. The method selected will depend accordingly on the design and service requirements of the parts or materials being tested.
SCOPE
1.1 This practice2 covers procedures for penetrant examination of materials. Penetrant testing is a nondestructive testing method for detecting discontinuities that are open to the surface such as cracks, seams, laps, cold shuts, shrinkage, laminations, through leaks, or lack of fusion and is applicable to in-process, final, and maintenance examinations. It can be effectively used in the examination of nonporous, metallic materials, ferrous and nonferrous metals, and of nonmetallic materials such as nonporous glazed or fully densified ceramics, as well as certain nonporous plastics, and glass.  
1.2 This practice also provides a reference:  
1.2.1 By which a liquid penetrant examination process recommended or required by individual organizations can be reviewed to ascertain its applicability and completeness.  
1.2.2 For use in the preparation of process specifications and procedures dealing with the liquid penetrant testing of parts and materials. Agreement by the customer requesting penetrant testing is strongly recommended. All areas of this practice may be open to agreement between the cognizant engineering organization and the supplier, or specific direction from the cognizant engineering organization.  
1.2.3 For use in the organization of facilities and personnel concerned with liquid penetrant testing.  
1.3 This practice does not indicate or suggest criteria for evaluation of the indications obtained by penetrant testing. It should be pointed out, however, that after indications have been found, they must be interpreted or classified and then evaluated. For this purpose there must be a separate code, standard, or a specific agreement to define the type, size, location, and direction of indications considered acceptable, and those considered unacceptable.  
1.4 Units—The values stated in either SI units or inch-pound units are to be regarded separately as standard. The values stated in each system may not be exact equivalents; therefore, each system shall be used independently of the other. Combining values from the two systems may result in non-conformance with the standard.  
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.

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ASTM E2663-23(Practice)
Standard Practice for Digital Imaging and Communication in Nondestructive Evaluation (DICONDE) for Ultrasonic Test Methods

SIGNIFICANCE AND USE
5.1 Personnel that are responsible for the creation, transfer, and storage of ultrasonic test results will use this standard. This practice defines a set of information modules that, along with Practice E2339 and the DICOM standard, provides a standard means to organize ultrasonic test parameters and results. The ultrasonic test results may be displayed and analyzed on any device that conforms to this standard. Personnel wishing to view any ultrasonic inspection data stored in DICONDE format may use this document to help them decode and display the data contained in the DICONDE compliant inspection record.
SCOPE
1.1 This practice covers the interoperability of ultrasonic imaging equipment by specifying image data transfer and archival storage methods in commonly accepted terms. This document is intended to be used in conjunction with Practice E2339. Practice E2339 defines an industrial adaptation of NEMA PS3 / ISO 12052 (DICOM, see http://medical.nema.org), an international standard for image data acquisition, review, transfer, and archival storage. The goal of Practice E2339, commonly referred to as DICONDE, is to provide a standard that facilitates the display and analysis of NDE test results on any system conforming to the DICONDE standard. Toward that end, Practice E2339 provides a data dictionary and set of information modules that are applicable to all NDE modalities. This practice supplements Practice E2339 by providing information object definitions, information modules, and data dictionary that are specific to ultrasonic test methods.  
1.2 This practice has been developed to overcome the issues that arise when analyzing or archiving data from ultrasonic test equipment using proprietary data transfer and storage methods. As digital technologies evolve, data must remain decipherable through the use of open, industry-wide methods for data transfer and archival storage. This practice defines a method where all the ultrasonic technique parameters and test results are communicated and stored in a standard format regardless of changes in digital technology.  
1.3 This practice does not specify:  
1.3.1 A testing or validation procedure to assess an implementation's conformance to the standard.  
1.3.2 The implementation details of any features of the standard on a device claiming conformance.  
1.3.3 The overall set of features and functions to be expected from a system implemented by integrating a group of devices each claiming DICONDE conformance.  
1.4 Although this practice contains no values that require units, it does describe methods to store and communicate data that do require units to be properly interpreted. The SI units required by this practice are to be regarded as standard. No other units of measurement are included in this standard.  
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.

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