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ASTM E1931-16(2022)

(Guide)

Standard Guide for Non-computed X-Ray Compton Scatter Tomography

Standard Guide for Non-computed X-Ray Compton Scatter Tomography

SIGNIFICANCE AND USE
5.1 Principal Advantage of Compton Scatter Tomography—The principal advantage of CST is the ability to perform three-dimensional X-ray examination without the requirement for access to the back side of the examination object. CST offers the possibility to perform X-ray examination that is not possible by any other method. The CST sub-surface slice image is minimally affected by examination object features outside the plane of examination. The result is a radioscopic image that contains information primarily from the slice plane. Scattered radiation limits image quality in normal radiographic and radioscopic imaging. Scatter radiation does not have the same detrimental effect upon CST because scatter radiation is used to form the image. In fact, the more radiation the examination object scatters, the better the CST result. Low subject contrast materials that cannot be imaged well by conventional radiographic and radioscopic means are often excellent candidates for CST. Very high contrast sensitivities and excellent spatial resolution are possible with CST tomography.  
5.2 Limitations—As with any nondestructive testing method, CST has its limitations. The technique is useful on reasonably thick sections of low-density materials. While a 25 mm (1 in.) depth in aluminum or 50 mm (2 in.) in plastic is achievable, the examination depth is decreased dramatically as the material density increases. Proper image interpretation requires the use of standards and examination objects with known internal conditions or representative quality indicators (RQIs). The examination volume is typically small, on the order of a few cubic inches and may require a few minutes to image. Therefore, completely examining large structures with CST requires intensive re-positioning of the examination volume that can be time-consuming. As with other penetrating radiation methods, the radiation hazard must be properly addressed.
SCOPE
1.1 Purpose—This guide covers a tutorial introduction to familiarize the reader with the operational capabilities and limitations inherent in a single non-computed X-ray Compton Scatter Tomography (CST). Also included is a brief description of the physics and typical hardware configuration for CST. This single technique is still used for a small number of inspections. This is not meant as comprehensive guide covering the variety of Compton scattering techniques that are now used for non-destructive testing and security screen screening.  
1.2 Advantages—X-ray Compton Scatter Tomography (CST) is a radiologic nondestructive examination method with several advantages that include:  
1.2.1 The ability to perform X-ray examination without access to the opposite side of the examination object;  
1.2.2 The X-ray beam need not completely penetrate the examination object allowing thick objects to be partially examined. Thick examination objects become part of the radiation shielding thereby reducing the radiation hazard;  
1.2.3 The ability to examine and image object subsurface features with minimal influence from surface features;  
1.2.4 The ability to obtain high-contrast images from low subject contrast materials that normally produce low-contrast images when using traditional transmitted beam X-ray imaging methods; and  
1.2.5 The ability to obtain depth information of object features thereby providing a three-dimensional examination. The ability to obtain depth information presupposes the use of a highly collimated detector system having a narrow angle of acceptance.  
1.3 Applications—This guide does not specify which examination objects are suitable, or unsuitable, for CST. As with most nondestructive examination techniques, CST is highly application specific thereby requiring the suitability of the method to be first demonstrated in the application laboratory. This guide does not provide guidance in the standardized practice or application of CST techniques. No guidance is provided co...

General Information

Status
Published
Publication Date
31-May-2022
ICS
11.040.50 - Radiographic equipment
Technical Committee
E07 - Nondestructive Testing
Drafting Committee
E07.01 - Radiology (X and Gamma) Method
Current Stage
Ref Project

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ASTM E1316-24 - Standard Terminology for <?Pub Dtl?>Nondestructive Examinations
Effective Date
01-Feb-2024
Refers
ASTM E1255-23 - Standard Practice for Radioscopy
Effective Date
01-Dec-2023
Refers
ASTM E1316-19b - Standard Terminology for Nondestructive Examinations
Effective Date
01-Dec-2019
Refers
ASTM E1316-19 - Standard Terminology for Nondestructive Examinations
Effective Date
01-Mar-2019
Refers
ASTM E1025-18 - Standard Practice for Design, Manufacture, and Material Grouping Classification of Hole-Type Image Quality Indicators (IQI) Used for Radiography
Effective Date
01-Feb-2018
Refers
ASTM E1316-18 - Standard Terminology for Nondestructive Examinations
Effective Date
01-Jan-2018
Refers
ASTM E1316-17a - Standard Terminology for Nondestructive Examinations
Effective Date
15-Jun-2017
Refers
ASTM E1316-17 - Standard Terminology for Nondestructive Examinations
Effective Date
01-Feb-2017
Refers
ASTM E1316-16a - Standard Terminology for Nondestructive Examinations
Effective Date
01-Aug-2016
Refers
ASTM E1316-16 - Standard Terminology for Nondestructive Examinations
Effective Date
01-Feb-2016
Refers
ASTM E1316-15a - Standard Terminology for Nondestructive Examinations
Effective Date
01-Dec-2015
Refers
ASTM E1316-15 - Standard Terminology for Nondestructive Examinations
Effective Date
01-Sep-2015
Refers
ASTM E1316-14e1 - Standard Terminology for Nondestructive Examinations
Effective Date
01-Jun-2014
Refers
ASTM E1316-14 - Standard Terminology for Nondestructive Examinations
Effective Date
01-Jun-2014
Refers
ASTM E1316-13d - Standard Terminology for Nondestructive Examinations
Effective Date
01-Dec-2013

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ASTM E1931-16(2022) - Standard Guide for Non-computed X-Ray Compton Scatter TomographyASTM E1931-16(2022) - Standard Guide for Non-computed X-Ray Compton Scatter Tomography
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ASTM E1931-16(2022) - Standard Guide for Non-computed X-Ray Compton Scatter Tomography
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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.
Designation: E1931 − 16 (Reapproved 2022)
Standard Guide for
Non-computed X-Ray Compton Scatter Tomography
This standard is issued under the fixed designation E1931; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope provided concerning the acceptance or rejection of examina-
tion objects examined with CST.
1.1 Purpose—This guide covers a tutorial introduction to
familiarize the reader with the operational capabilities and 1.4 Limitations—As with all nondestructive examination
limitations inherent in a single non-computed X-ray Compton
methods, CST has limitations and is complementary to other
ScatterTomography(CST).Alsoincludedisabriefdescription NDE methods. Chief among the limitations is the difficulty in
ofthephysicsandtypicalhardwareconfigurationforCST.This
performing CST on thick sections of high-Z materials. CST is
single technique is still used for a small number of inspections. best applied to thinner sections of lower Z materials. The
This is not meant as comprehensive guide covering the variety
following provides a general idea of the range of CST
of Compton scattering techniques that are now used for applicability when using a 160 keV constant potential X-ray
non-destructive testing and security screen screening.
source:
Material Practical Thickness Range
1.2 Advantages—X-ray Compton Scatter Tomography
(CST) is a radiologic nondestructive examination method with
Steel Up to about 3 mm ( ⁄8 in.)
several advantages that include:
Aluminum Up to about 25 mm (1 in.)
Aerospace composites Up to about 50 mm (2 in.)
1.2.1 The ability to perform X-ray examination without
Polyurethane Foam Up to about 300 mm (12 in.)
access to the opposite side of the examination object;
The limitations of the technique must also consider the
1.2.2 The X-ray beam need not completely penetrate the
required X, Y, and Z axis resolutions, the speed of image
examination object allowing thick objects to be partially
formation, image quality and the difference in the X-ray
examined. Thick examination objects become part of the
scattering characteristics of the parent material and the internal
radiation shielding thereby reducing the radiation hazard;
features that are to be imaged.
1.2.3 The ability to examine and image object subsurface
features with minimal influence from surface features;
1.5 The values stated in both inch-pound and SI units are to
1.2.4 The ability to obtain high-contrast images from low
be regarded separately as the standard. The values given in
subject contrast materials that normally produce low-contrast
parentheses are for information only.
imageswhenusingtraditionaltransmittedbeamX-rayimaging
1.6 This standard does not purport to address all of the
methods; and
safety concerns, if any, associated with its use. It is the
1.2.5 The ability to obtain depth information of object
responsibility of the user of this standard to establish appro-
features thereby providing a three-dimensional examination.
priate safety, health, and environmental practices and deter-
The ability to obtain depth information presupposes the use of
mine the applicability of regulatory limitations prior to use.
a highly collimated detector system having a narrow angle of
1.7 This international standard was developed in accor-
acceptance.
dance with internationally recognized principles on standard-
1.3 Applications—Thisguidedoesnotspecifywhichexami-
ization established in the Decision on Principles for the
nation objects are suitable, or unsuitable, for CST. As with
Development of International Standards, Guides and Recom-
most nondestructive examination techniques, CST is highly
mendations issued by the World Trade Organization Technical
application specific thereby requiring the suitability of the
Barriers to Trade (TBT) Committee.
method to be first demonstrated in the application laboratory.
This guide does not provide guidance in the standardized
2. Referenced Documents
practice or application of CST techniques. No guidance is
2.1 ASTM Standards:
This guide is under the jurisdiction of ASTM Committee E07 on Nondestruc-
tiveTesting and is the direct responsibility of E07.01 on Radiology (X and Gamma)
Method. For referenced ASTM standards, visit the ASTM website, www.astm.org, or
CurrenteditionapprovedJune1,2022.PublishedJuly2022.Originallyapproved contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
in 1997. Last previous edition approved in 2016 as E1931 – 16. DOI: 10.1520/ Standards volume information, refer to the standard’s Document Summary page on
E1931-16R22. the ASTM website.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
E1931 − 16 (2022)
E747 Practice for Design, Manufacture and Material Group- respect to the examination object thickness (slice images) and
ing Classification of Wire Image Quality Indicators (IQI) which are at right angles to the X-ray beam. Each two-
Used for Radiology dimensional slice image (X–Y axes) is produced at an incre-
E1025 Practice for Design, Manufacture, and Material mental distance along and orthogonal to the X-ray beam
Grouping Classification of Hole-Type Image Quality In-
(Z–axis). A stack of CST images therefore represents a solid
dicators (IQI) Used for Radiography volume within the examination object. Each slice image
E1255 Practice for Radioscopy
contains examination object information which lies predomi-
E1316 Terminology for Nondestructive Examinations nantly within the desired slice. To make an analogy as to how
E1441 Guide for Computed Tomography (CT)
CST works, consider a book. The examination object may be
E1453 Guide for Storage of Magnetic Tape Media that larger or smaller (in length, width and depth) then the analo-
Contains Analog or Digital Radioscopic Data
gous book. The CST slice images are the pages in the book.
E1475 Guide for Data Fields for Computerized Transfer of
Paging through the slice images provides information about
Digital Radiological Examination Data
examination object features lying at different depths within the
E1647 Practice for Determining Contrast Sensitivity in Ra-
examination object.
diology
4.2 Image Formation—CST produces one or more digital
2.2 ANSI/ASNT Standards:
slice plane images per scan. Multiple slice images can be
SNT-TC-1A ASNT Recommended Practice for Personnel
producedintimesrangingfromafewsecondstoafewminutes
Qualification and Certification in Nondestructive Testing
depending upon the examined area, desired spatial resolution
ANSI/ASNT CP-189 Standard for Qualification and Certifi-
and signal-to-noise ratio. The image is digital and is typically
cation in Nondestructive Testing Personnel
assembled by computer. CST images are free from reconstruc-
2.3 Military Standard:
tion artifacts as the CST image is produced directly and is not
MIL-STD-410 Nondestructive Testing Personnel Qualifica-
a calculated image. Because CST images are digital, they may
tion and Certification
be enhanced, analyzed, archived and in general handled as any
2.4 Aerospace Standard:
other digital information.
AIA-NAS-410 Aerospace Industries Association, National
Aerospace Standard-4105 Certification and Qualification 4.3 Calibration Standards—As with all nondestructive
of Nondestructive Test Personnel examinations, known standards are required for the calibration
and performance monitoring of the CST method. Practice
2.5 ISO Standard:
E1255 calibration block standards that are representative of the
ISO 9712 Nondestructive Testing—Qualification and Certi-
actual examination object are the best means for CST perfor-
fication of NDT Personnel
mance monitoring. Conventional radiologic performance mea-
3. Terminology
suring devices, such as Test Method E747 and Practice E1025
image quality indicators or Practice E1647 contrast sensitivity
3.1 Definitions:
gagesaredesignedfortransmittedX-raybeamimagingandare
3.1.1 CST, being a radiologic examination method, uses
of little use for CST. With appropriate calibration, CST can be
much the same vocabulary as other X-ray examination meth-
utilized to make three-dimensional measurements of internal
ods. A number of terms used in this standard are defined in
examination object features.
Terminology E1316. It may also be helpful to read Guide
E1441.
5. Significance and Use
4. Summary of Guide
5.1 Principal Advantage of Compton Scatter Tomography—
4.1 Description—Compton Scatter Tomography is a
The principal advantage of CST is the ability to perform
uniquely different nondestructive test method utilizing pen-
three-dimensional X-ray examination without the requirement
etrating X-ray or gamma-ray radiation. Unlike computed
for access to the back side of the examination object. CST
tomography(CT),CSTproducesradioscopicimageswhichare
offers the possibility to perform X-ray examination that is not
not computed images. Multiple slice images can be simultane-
possible by any other method. The CST sub-surface slice
ously produced so that the time per slice image is in the range
image is minimally affected by examination object features
of a few seconds. CST can produce images that are thin with
outside the plane of examination. The result is a radioscopic
image that contains information primarily from the slice plane.
Scattered radiation limits image quality in normal radiographic
Available fromAmerican National Standards Institute (ANSI), 25 W. 43rd St.,
and radioscopic imaging. Scatter radiation does not have the
4th Floor, New York, NY 10036, http://www.ansi.org.
Available from Standardization Documents Order Desk, DODSSP, Bldg. 4,
same detrimental effect upon CST because scatter radiation is
Section D, 700 Robbins Ave., Philadelphia, PA 19111-5098, http://
used to form the image. In fact, the more radiation the
www.dodssp.daps.mil.
5 examination object scatters, the better the CST result. Low
Available from Federal Aviation Administration (FAA), 800 Independence
subject contrast materials that cannot be imaged well by
Ave., SW, Washington, DC 20591, http://www.faa.gov.
This document has superseded MIL-STD-410; however, MIL-STD-410 is still
conventional radiographic and radioscopic means are often
acceptable to the FAA
excellent candidates for CST. Very high contrast sensitivities
Available from International Organization for Standardization (ISO), ISO
and excellent spatial resolution are possible with CST tomog-
Central Secretariat, BIBC II, Chemin de Blandonnet 8, CP 401, 1214 Vernier,
Geneva, Switzerland, http://www.iso.org. raphy.
E1931 − 16 (2022)
5.2 Limitations—As with any nondestructive testing
method, CST has its limitations. The technique is useful on
reasonably thick sections of low-density materials. While a 25
mm (1 in.) depth in aluminum or 50 mm (2 in.) in plastic is
achievable, the examination depth is decreased dramatically as
the material density increases. Proper image interpretation
requires the use of standards and examination objects with
known internal conditions or representative quality indicators
(RQIs). The examination volume is typically small, on the
order of a few cubic inches and may require a few minutes to
image. Therefore, completely examining large structures with
CST requires intensive re-positioning of the examination
volume that can be time-consuming.As with other penetrating
radiation methods, the radiation hazard must be properly
addressed.
FIG. 1 Relationship Between Photoelectric, Compton, and Pair
6. Basis of Application
Production Effects
5 7/2
6.1 Personnel Qualification is subject to contractual agree-
Photoelectric Effect: τ = Z / E
Compton Scattering: σ = Z / E
ment between the parties using or referencing this standard.
Pair Production : κ = Z (lnE - constant)
6.1.1 If specified in the contractual agreement, personnel
performing examinations to this standard shall be qualified in
accordance with a nationally or internationally recognized
moving left to right in the graph, the green lines represent the
NDT personnel qualification practice or standard such as
boundaries of the regions where the photoelectric, Compton
ANSI/ASNT-CP-189, SNT-TC-1A, NAS-410, MIL-STD-
and pair-production events are dominant, respectively. The
410E, ISO 9712, or a similar document and certified by the
graph is useful for understanding the X-ray properties of a
employer or certifying agency, as applicable. The practice or
material, by knowing its predominant mass number Z. For
standard used and its applicable revision shall be identified in
example, it could be used to estimate its interaction regime
the contractual agreement between the using parties.
based on the Z of the material and energy of interrogation
photons.
7. Technical Description
7.1.1 CST is best suited for lower Z materials such as
7.1 General Description of Compton Scatter Tomography—
aluminum ( Z=13 ) using a commercially available 160 keV
Transmitted beam radiologic techniques used in radiography,
X-ray generating system. Somewhat higher Z materials may be
radioscopy and computed tomography have dominated the use
examined by utilizing a higher energy X-ray generator rated at
of penetrating radiation for industrial nondestructive examina-
225, 320, or 450 keV.
tion. The transmitted beam technique depends upon the pen-
7.1.2 It is useful to envision the CST process as one where
etrating radiation attenuation mechanisms of photoelectric
the X-rays that produce the CST image originate from many
absorption and Compton scattering. For low- Z materials at
discrete points within the examined volume. Each Compton
energies up to about 50 keV, the photoelectric effect is the
scatter event generates a lower energy X ray that emanates
dominant attenuation mechanism. As X-ray energy increases,
from the scattering site. Singly scattered X rays that reach the
Compton scattering becomes the dominant attenuation mecha-
detector carry information about the examination object mate-
nism.Pairproductioncomesintoplayabove1.02MeVandcan
rial characteristics at the site where it was generated. The
become the dominant effect for higher X-ray energies. The
scatter radiation is also affected by the material through which
following relationships are plotted in Fig. 1 and show the
it passes on the way to the detector. The external source of
approximate dependence of the photoelectric effect and Co
...

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4.5 Practice E2698 is designed to assist the end user to set up the DDA with minimum requirements for radiological examinations. This standard will also help the user to get the required SNR, to set up the required magnification, and provides guidance for viewing and storage of radiographs. Discussion is also...
SCOPE
1.1 This standard is a user guide, which is intended to serve as a tutorial for selection and use of various digital detector array systems nominally composed of the detector array and an imaging system to perform digital radiography. This guide also serves as an in-detail reference for the following standards: Practices E2597, E2698, and E2737.  
1.2 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.  
1.3 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM E2597/E2597M-22(Practice)
Standard Practice for Manufacturing Characterization of Digital Detector Arrays

SIGNIFICANCE AND USE
4.1 This practice provides a means to compare DDAs on a common set of technical measurements, realizing that in practice, adjustments can be made to achieve similar results even with disparate DDAs, given geometric magnification, or other industrial radiologic settings that may compensate for one shortcoming of a device.  
4.2 A user should understand the definitions and corresponding performance parameters used in this practice in order to make an informed decision on how a given DDA can be used in the target application.  
4.3 The factors that will be evaluated for each DDA are: interpolated basic spatial resolution (iSRbdetector), efficiency (normalized Detector  SNR (SNRN) at 1 mGy, for different energies and beam qualities), achievable contrast sensitivity (CSa), specific material thickness range (SMTR) and ISO-MTL , image lag, burn-in, bad pixels distribution and statistics and internal scatter ratio (ISR).  
4.4 Given that each of these parameters are discussed together in many of the following sections, the following list will be helpful in selecting the key sections for a given test as follows. It should be noted that other sections of the document are needed to establish the appropriate technique for the parameter under test. Note that for each parameter (test), the first section listed is typically an apparatus or gauge (if required), the second section listed are the standardized measurements, and the third section listed involves the analysis or computations:  
4.4.1 For iSRbdetector, see 5.1, 7.7, 8.2.  
4.4.2 For Detector Efficiency, see 5.3, 7.8, 8.3.  
4.4.3 For CSa, see 5.2, 7.9, 8.4.  
4.4.4 For SMTR, see 5.2 (or 7.9, if already completed), 7.10, 8.5.  
4.4.5 For ISO-MTL, see 5.2 (or 7.9, if already completed), 7.10, 8.6.  
4.4.6 For Image Lag, see 7.11.1, 8.7.1.  
4.4.7 For Burn-in, see 5.4, 7.11.2, 8.7.2.  
4.4.8 For Bad Pixel Tests, see 6.2, 7.12, 8.8.  
4.4.9 For ISR, see 5.4, 7.13, 8.9.
SCOPE
1.1 This practice describes the evaluation of Digital Detector Arrays (DDAs), and assures that one common standard exists for quantitative comparison of DDAs so that an appropriate DDA is selected to meet NDT requirements.  
1.2 This practice is intended for use by manufacturers or integrators of DDAs to provide quantitative results of DDA characteristics for NDT user or purchaser consumption. Some of these tests require specialized test phantoms to assure consistency among results among suppliers or manufacturers. These tests are not intended for users to complete, nor are they intended for long term stability tracking and lifetime measurements. However, they may be used for this purpose, if so desired.
Note 1: Further information on application of DDAs is contained in Guide E2736 and Practices E2698 and E2737.  
1.3 The results reported based on this practice should be based on a group of at least three individual detectors for a particular model number.  
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 are not necessarily exact equivalents; therefore, to ensure conformance with the standard, each system shall be used independently of the other, and values from the two systems shall not be combined.  
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 E1672-12(2020)(Guide)
Standard Guide for Computed Tomography (CT) System Selection

SIGNIFICANCE AND USE
5.1 This guide will aid the purchaser in generating a CT system specification. This guide covers the conversion of purchaser's requirements to system components that must occur for a useful CT system specification to be prepared.  
5.2 Additional information can be gained in discussions with potential suppliers or with independent consultants.  
5.3 This guide is applicable to purchasers seeking scan services.  
5.4 This guide is applicable to purchasers needing to procure a CT system for a specific examination application.
SCOPE
1.1 This guide covers guidelines for translating application requirements into computed tomography (CT) system requirements/specifications and establishes a common terminology to guide both purchaser and supplier in the CT system selection process. This guide is applicable to the purchaser of both CT systems and scan services. Computed tomography systems are complex instruments, consisting of many components that must correctly interact in order to yield images that repeatedly reproduce satisfactory examination results. Computed tomography system purchasers are generally concerned with application requirements. Computed tomography system suppliers are generally concerned with the system component selection to meet the purchaser's performance requirements. This guide is not intended to be limiting or restrictive, but rather to address the relationships between application requirements and performance specifications that must be understood and considered for proper CT system selection.  
1.2 Computed tomography (CT) may be used for new applications or in place of radiography or radioscopy, provided that the capability to disclose physical features or indications that form the acceptance/rejection criteria is fully documented and available for review. In general, CT has lower spatial resolution than film radiography and is of comparable spatial resolution with digital radiography or radioscopy unless magnification is used. Magnification can be used in CT or radiography/radioscopy to increase spatial resolution but concurrently with loss of field of view.  
1.3 Computed tomography (CT) systems use a set of transmission measurements made along a set of paths projected through the object from many different directions. Each of the transmission measurements within these views is digitized and stored in a computer, where they are subsequently conditioned (for example, normalized and corrected) and reconstructed, typically into slices of the object normal to the set of projection paths by one of a variety of techniques. If many slices are reconstructed, a three dimensional representation of the object is obtained. An in-depth treatment of CT principles is given in Guide E1441.  
1.4 Computed tomography (CT), as with conventional radiography and radioscopic examinations, is broadly applicable to any material or object through which a beam of penetrating radiation may be passed and detected, including metals, plastics, ceramics, metallic/nonmetallic composite material and assemblies. The principal advantage of CT is that it has the potential to provide densitometric (that is, radiological density and geometry) images of thin cross sections through an object. In many newer systems the cross-sections are now combined into 3D data volumes for additional interpretation. Because of the absence of structural superposition, images may be much easier to interpret than conventional radiological images. The new purchaser can quickly learn to read CT data because images correspond more closely to the way the human mind visualizes 3D structures than conventional projection radiology. Further, because CT images are digital, the images may be enhanced, analyzed, compressed, archived, input as data into performance calculations, compared with digital data from other nondestructive evaluation modalities, or transmitted to other locations for remote viewing. 3D data sets can be rendered ...

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ASTM E1695-20e1(Test Method)
Standard Test Method for Measurement of Computed Tomography (CT) System Performance

SIGNIFICANCE AND USE
4.1 The major factors affecting the quality of a CT image are total image unsharpness (UTimage), contrast (Δµ), and random noise (σ). Geometrical and detector unsharpness limit the spatial resolution of a CT system, that is, its ability to image fine structural detail in an object. Random noise and contrast response limit the contrast sensitivity of a CT system, that is, its ability to detect the presence or absence of features in an object. Spatial resolution and contrast sensitivity may be measured in various ways. In this test method, spatial resolution is quantified in terms of the modulation transfer function (MTF), and contrast sensitivity is quantified in terms of the contrast discrimination function (CDF). The relationship between contrast sensitivity and spatial resolution describing the resolving and detecting capabilities is given by the contrast-detail-diagram (CDD metric, see also Guide E1441 and Practice E1570). This test method allows the purchaser or the provider of CT systems or services, or both, to measure and specify spatial resolution and contrast sensitivity and is a measure for system stability over time and performance acceptability.
SCOPE
1.1 This test method provides instruction for determining the spatial resolution and contrast sensitivity in X-ray and γ-ray computed tomography (CT) volumes. The determination is based on examination of the CT volume of a uniform cylinder of material. The spatial resolution measurement (Modulation Transfer Function) is derived from an image analysis of the sharpness at the edges of the reconstructed cylinder slices. The contrast sensitivity measurement (Contrast Discrimination Function) is derived from an image analysis of the contrast and the statistical noise at the center of the cylinder slices.  
1.2 This test method is more quantitative and less susceptible to interpretation than alternative approaches because the required cylinder is easy to fabricate and the analysis easy to perform.  
1.3 This test method is not to predict the detectability of specific object features or flaws in a specific application. This is subject of IQI and RQI standards and standard practices.  
1.4 This method tests and describes overall CT system performance. Performance tests of systems components such as X-ray tubes, gamma sources, and detectors are covered by separate documents, namely Guide E1000, Practice E2737, and Practice E2002; c.f. 2.1, which should be consulted for further system analysis.  
1.5 Units—The values stated in SI units are to be regarded as standard. The values given in parentheses after SI units are provided for information only and are not considered standard.  
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM E1570-19(Practice)
Standard Practice for Fan Beam Computed Tomographic (CT) Examination

SIGNIFICANCE AND USE
5.1 This practice establishes the basic parameters for the application and control of fan-beam CT examinations. This practice is written so it can be specified on the engineering drawing, specification, or contract. It will require a detailed procedure delineating the technique or procedure requirements and shall be approved by the Cognizant Engineering Organization (CEO).  
5.2 The requirements in this practice shall be used when placing a CT system into NDT service and establishing a baseline of system performance measures. Monitoring the system performance over time shall be performed, including calibration procedures, performance measurements, and system maintenance in accordance with Section 9.
SCOPE
1.1 This practice establishes the minimum requirements for computed tomography (CT) examination of test objects using fan beam systems (systems that generate one or a few CT cross sectional slices at a time). The examination may be used to nondestructively disclose physical features or anomalies within a test object by providing radiological density and geometric measurements. This practice implicitly assumes the use of penetrating radiation, specifically X-ray and γ-ray.  
1.2 CT is broadly applicable to any material or test object through which a beam of penetrating radiation passes. The principal advantage of CT is that it provides densitometric (that is, radiological density and geometry) images of thin cross sections through an object without the structural superposition in projection radiography.  
1.3 There are areas in this practice that may require agreement between the purchaser and the supplier, or specific direction from the cognizant engineering organization. These items should be addressed in the purchase order or the contract. Generally, the items are application specific or performance related, or both.  
1.4 Techniques and applications employed with CT are diverse. This practice is not intended to be limiting or restrictive. Refer to Guides E1441 and E1672 that provide additional information and guidance on CT fundamentals and tradeoffs in designing or purchasing a CT system, or both.  
1.5 Units—The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM E2698-18e1(Practice)
Standard Practice for Radiographic Examination Using Digital Detector Arrays

SIGNIFICANCE AND USE
4.1 This practice establishes the basic parameters for the application and control of the digital detector array radiographic method. This practice is written so it can be specified on the engineering drawing, specification, or contract. It will require a detailed procedure delineating the technique or procedure requirements and shall be approved by the Cognizant Engineering Organization (CEO).
SCOPE
1.1 This practice establishes the minimum requirements for radiographic examination of metallic and nonmetallic materials using digital detector arrays (DDAs).  
1.2 The stated requirements of this specification are based on the use of an X-ray generating source. Additionally, some of the tests and requirements may not be applicable to X-ray energy levels >450kV.  
1.3 The requirements in this practice are intended to control the quality of radiographic examinations obtained using DDAs and are not intended to establish acceptance criteria for parts or materials.  
1.4 This practice covers the radiographic examination with DDAs including DDAs described in Practice E2597/E2597M such as a device that contains a photoconductor attached to a Thin Film Transistor (TFT) read out structure, a device that has a phosphor coupled directly to an amorphous silicon read-out structure, and devices where a phosphor is coupled to a CMOS (complementary metal–oxide–semiconductor) array, or a CCD (charge coupled device) crystalline silicon read-out structure.  
1.5 The requirements of this practice and Practice E2737 shall be used together. The requirements of Practice E2737 will provide the baseline evaluation and long term stability test procedures for the DDA system. The user of the DDA system shall establish a written procedure that addresses the specific requirements and tests to be used in their application and shall be approved by the Cognizant Radiographic Level 3 before examination of production hardware. This practice also requires the user to perform a system qualification suitable for its intended purpose and to issue a system qualification report (see 9.1).  
1.6 The DDA shall be selected for an NDT application based on knowledge of the technology described in Guide E2736, and of the selected DDA properties provided by the manufacturer in accordance with Practice E2597/E2597M.  
1.7 Techniques and applications employed with DDAs are diverse. This practice is not intended to be limiting or restrictive. Refer to Guides E94/E94M, E1000, and E2736, Terminology E1316, Practices E747 and E1025, and Federal Standards 21-CFR-1020.40 and 29-CFR-1910.96 for a list of documents that provide additional information and guidance.  
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 E2903-18(Test Method)
Standard Test Method for Measurement of the Effective Focal Spot Size of Mini and Micro Focus X-ray Tubes

SIGNIFICANCE AND USE
5.1 One of the factors affecting the image quality of a radiographic image is geometric unsharpness. The degree of geometric unsharpness is dependent upon the focal spot size of the radiation source, the distance between the source and the object to be radiographed, the distance between the object to be radiographed and the image plane (film, imaging plate, Digital Detector Array (DDA), or radioscopic detector). This test method allows the user to determine the effective focal spot size (dimensions) of the X-ray source. This result can then be used to establish source to object and object to image detector distances appropriate for maintaining the desired degree of geometric unsharpness or maximum magnification possible, or both, for a given radiographic imaging application. The accuracy of this method is dependent upon the spatial resolution of the imaging system, magnification, and signal-to-noise of the resultant images.
SCOPE
1.1 The image quality and the resolution of X-ray images highly depend on the characteristics of the focal spot. The imaging qualities of the focal spot are based on its two dimensional intensity distribution as seen from the imaging place.  
1.2 This test method provides instructions for determining the effecting size (dimensions) of mini and micro focal spots of industrial X-ray tubes. It is based on the European standard, EN 12543–5, Non-destructive testing - Characteristics of focal spots in industrial X-ray systems for use in non-destructive testing - Part 5: Measurement of the effective focal spot size of mini and micro focus X-ray tubes.  
1.3 This standard specifies a method for the measurement of effective focal spot dimensions from 5 up to 300 μm of X-ray systems up to and including 225 kV tube voltage, by means of radiographs of edges. Larger focal spots should be measured using Test Method E1165 Standard Test Method for Measurement of Focal Spots of Industrial X-Ray Tubes by Pinhole Imaging.  
1.4 The same procedure can be used at higher kilovoltages by agreement, but the accuracy of the measurement may be poorer.  
1.5 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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