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ASTM F1467-18

(Guide)

Standard Guide for Use of an X-Ray Tester (≈10 keV Photons) in Ionizing Radiation Effects Testing of Semiconductor Devices and Microcircuits

Standard Guide for Use of an X-Ray Tester (≈10 keV Photons) in Ionizing Radiation Effects Testing of Semiconductor Devices and Microcircuits

SIGNIFICANCE AND USE
4.1 Electronic circuits used in many space, military and nuclear power systems may be exposed to various levels of ionizing radiation dose. It is essential for the design and fabrication of such circuits that test methods be available that can determine the vulnerability or hardness (measure of nonvulnerability) of components to be used in such systems.  
4.2 Manufacturers are currently selling semiconductor parts with guaranteed hardness ratings, and the military specification system is being expanded to cover hardness specification for parts. Therefore test methods and guides are required to standardize qualification testing.  
4.3 Use of low energy (≈10 keV) X-ray sources has been examined as an alternative to cobalt-60 for the ionizing radiation effects testing of microelectronic devices (3, 4, 5, 6). The goal of this guide is to provide background information and guidance for such use where appropriate.
Note 3: Cobalt-60—The most commonly used source of ionizing radiation for ionizing radiation (“total dose”) testing is cobalt-60. Gamma rays with energies of 1.17 and 1.33 MeV are the primary ionizing radiation emitted by cobalt-60. In exposures using cobalt-60 sources, test specimens must be enclosed in a lead-aluminum container to minimize dose-enhancement effects caused by low-energy scattered radiation (unless it has been demonstrated that these effects are negligible). For this lead-aluminum container, a minimum of 1.5 mm of lead surrounding an inner shield of 0.7 to 1.0 mm of aluminum is required. (See 8.2.2.2 and Practice E1249.)  
4.4 The X-ray tester has proven to be a useful ionizing radiation effects testing tool because:  
4.4.1 It offers a relatively high dose rate, in comparison to most cobalt-60 sources, thus offering reduced testing time.  
4.4.2 The radiation is of sufficiently low energy that it can be readily collimated. As a result, it is possible to irradiate a single device on a wafer.  
4.4.3 Radiation safety issues are more easily...
SCOPE
1.1 This guide covers recommended procedures for the use of X-ray testers (that is, sources with a photon spectrum having ≈10 keV mean photon energy and ≈50 keV maximum energy) in testing semiconductor discrete devices and integrated circuits for effects from ionizing radiation.  
1.2 The X-ray tester may be appropriate for investigating the susceptibility of wafer level or delidded microelectronic devices to ionizing radiation effects. It is not appropriate for investigating other radiation-induced effects such as single-event effects (SEE) or effects due to displacement damage.  
1.3 This guide focuses on radiation effects in metal oxide semiconductor (MOS) circuit elements, either designed (as in MOS transistors) or parasitic (as in parasitic MOS elements in bipolar transistors).  
1.4 Information is given about appropriate comparison of ionizing radiation hardness results obtained with an X-ray tester to those results obtained with cobalt-60 gamma irradiation. Several differences in radiation-induced effects caused by differences in the photon energies of the X-ray and cobalt-60 gamma sources are evaluated. Quantitative estimates of the magnitude of these differences in effects, and other factors that should be considered in setting up test protocols, are presented.  
1.5 If a 10-keV X-ray tester is to be used for qualification testing or lot acceptance testing, it is recommended that such tests be supported by cross checking with cobalt-60 gamma irradiations.  
1.6 Comparisons of ionizing radiation hardness results obtained with an X-ray tester with results obtained with a LINAC, with protons, etc. are outside the scope of this guide.  
1.7 Current understanding of the differences between the physical effects caused by X-ray and cobalt-60 gamma irradiations is used to provide an estimate of the ratio (number-of-holes-cobalt-60)/(number-of-holes-X-ray). Several cases are defined where the differences in the eff...

General Information

Status
Published
Publication Date
28-Feb-2018
ICS
31.020 - Electronic components in general
Technical Committee
E10 - Nuclear Technology and Applications
Drafting Committee
E10.07 - Radiation Dosimetry for Radiation Effects on Materials and Devices
Current Stage
Ref Project

Relations

Refers
ASTM E170-15 - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
15-Mar-2015
Refers
ASTM E170-15a - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
01-Sep-2015
Refers
ASTM E170-16 - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
15-Feb-2016
Refers
ASTM E170-16a - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
01-Oct-2016
Refers
ASTM E1894-18 - Standard Guide for Selecting Dosimetry Systems for Application in Pulsed X-Ray Sources
Effective Date
01-Dec-2018
Refers
ASTM E170-17 - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
01-Jun-2017
Refers
ASTM E668-20 - Standard Practice for Application of Thermoluminescence-Dosimetry (TLD) Systems for Determining Absorbed Dose in Radiation-Hardness Testing of Electronic Devices
Effective Date
01-Jul-2020
Refers
ASTM E170-14a - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
15-Oct-2014
Refers
ASTM E170-14 - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
01-Sep-2014

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ASTM F1467-18 - Standard Guide for Use of an X-Ray Tester (≈10 keV Photons) in Ionizing Radiation Effects Testing of Semiconductor Devices and MicrocircuitsASTM F1467-18 - Standard Guide for Use of an X-Ray Tester (≈10 keV Photons) in Ionizing Radiation Effects Testing of Semiconductor Devices and Microcircuits
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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: F1467 − 18
Standard Guide for
Use of an X-Ray Tester ('10 keV Photons) in Ionizing
Radiation Effects Testing of Semiconductor Devices and
1
Microcircuits
This standard is issued under the fixed designation F1467; 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 tions is used to provide an estimate of the ratio (number-of-
holes-cobalt-60)/(number-of-holes-X-ray). Several cases are
1.1 This guide covers recommended procedures for the use
defined where the differences in the effects caused by X-rays
of X-ray testers (that is, sources with a photon spectrum having
and cobalt-60 gammas are expected to be small. Other cases
≈10 keV mean photon energy and ≈50 keV maximum energy)
where the differences could potentially be as great as a factor
in testing semiconductor discrete devices and integrated cir-
of four are described.
cuits for effects from ionizing radiation.
1.8 It should be recognized that neither X-ray testers nor
1.2 The X-ray tester may be appropriate for investigating
cobalt-60 gamma sources will provide, in general, an accurate
the susceptibility of wafer level or delidded microelectronic
simulation of a specified system radiation environment. The
devices to ionizing radiation effects. It is not appropriate for
use of either test source will require extrapolation to the effects
investigating other radiation-induced effects such as single-
to be expected from the specified radiation environment. In this
event effects (SEE) or effects due to displacement damage.
guide, we discuss the differences between X-ray tester and
1.3 This guide focuses on radiation effects in metal oxide
cobalt-60 gamma effects. This discussion should be useful as
semiconductor (MOS) circuit elements, either designed (as in
background to the problem of extrapolation to effects expected
MOS transistors) or parasitic (as in parasitic MOS elements in
from a different radiation environment. However, the process
bipolar transistors).
of extrapolation to the expected real environment is treated
2
1.4 Information is given about appropriate comparison of elsewhere (1, 2).
ionizing radiation hardness results obtained with an X-ray
1.9 The time scale of an X-ray irradiation and measurement
tester to those results obtained with cobalt-60 gamma irradia-
may be much different than the irradiation time in the expected
tion. Several differences in radiation-induced effects caused by
device application. Information on time-dependent effects is
differences in the photon energies of the X-ray and cobalt-60
given.
gamma sources are evaluated. Quantitative estimates of the
1.10 Possible lateral spreading of the collimated X-ray
magnitude of these differences in effects, and other factors that
beam beyond the desired irradiated region on a wafer is also
should be considered in setting up test protocols, are presented.
discussed.
1.5 If a 10-keV X-ray tester is to be used for qualification
1.11 Information is given about recommended experimental
testing or lot acceptance testing, it is recommended that such
methodology, dosimetry, and data interpretation.
tests be supported by cross checking with cobalt-60 gamma
irradiations. 1.12 Radiation testing of semiconductor devices may pro-
duce severe degradation of the electrical parameters of irradi-
1.6 Comparisons of ionizing radiation hardness results ob-
ated devices and should therefore be considered a destructive
tained with an X-ray tester with results obtained with a
test.
LINAC, with protons, etc. are outside the scope of this guide.
1.13 The values stated in SI units are to be regarded as
1.7 Current understanding of the differences between the
standard. No other units of measurement are included in this
physical effects caused by X-ray and cobalt-60 gamma irradia-
standard.
1.14 This standard does not purport to address all of the
safety concerns, if any, associated with its use. It is the
1
This guide is under the jurisdiction of ASTM Committee E10 on Nuclear
Technology and Applications and is the direct responsibility of Subcommittee
E10.07 on Radiation Dosimetry for Radiation Effects on Materials and Devices.
Current edition approved March 1, 2018. Published April 2018. Originally
2
approved in 1993. Last previous edition approved in 2011 as F1467 – 11. DOI: The boldface numbers in parentheses refer to the list of references at the end of
10.1520/F1467-18. this guide.
Copyright © ASTM International, 100 Barr Ha
...

This document is not an ASTM standard and is intended only to provide the user of an ASTM 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.
Designation: F1467 − 11 F1467 − 18
Standard Guide for
Use of an X-Ray Tester ('10 keV Photons) in Ionizing
Radiation Effects Testing of Semiconductor Devices and
1
Microcircuits
This standard is issued under the fixed designation F1467; 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
1.1 This guide covers recommended procedures for the use of X-ray testers (that is, sources with a photon spectrum having ≈10
keV mean photon energy and ≈50 keV maximum energy) in testing semiconductor discrete devices and integrated circuits for
effects from ionizing radiation.
1.2 The X-ray tester may be appropriate for investigating the susceptibility of wafer level or delidded microelectronic devices
to ionizing radiation effects. It is not appropriate for investigating other radiation-induced effects such as single-event effects (SEE)
or effects due to displacement damage.
1.3 This guide focuses on radiation effects in metal oxide semiconductor (MOS) circuit elements, either designed (as in MOS
transistors) or parasitic (as in parasitic MOS elements in bipolar transistors).
1.4 Information is given about appropriate comparison of ionizing radiation hardness results obtained with an X-ray tester to
those results obtained with cobalt-60 gamma irradiation. Several differences in radiation-induced effects caused by differences in
the photon energies of the X-ray and cobalt-60 gamma sources are evaluated. Quantitative estimates of the magnitude of these
differences in effects, and other factors that should be considered in setting up test protocols, are presented.
1.5 If a 10-keV X-ray tester is to be used for qualification testing or lot acceptance testing, it is recommended that such tests
be supported by cross checking with cobalt-60 gamma irradiations.
1.6 Comparisons of ionizing radiation hardness results obtained with an X-ray tester with results obtained with a LINAC, with
protons, etc. are outside the scope of this guide.
1.7 Current understanding of the differences between the physical effects caused by X-ray and cobalt-60 gamma irradiations is
used to provide an estimate of the ratio (number-of-holes-cobalt-60)/(number-of-holes-X-ray). Several cases are defined where the
differences in the effects caused by X-rays and cobalt-60 gammas are expected to be small. Other cases where the differences could
potentially be as great as a factor of four are described.
1.8 It should be recognized that neither X-ray testers nor cobalt-60 gamma sources will provide, in general, an accurate
simulation of a specified system radiation environment. The use of either test source will require extrapolation to the effects to be
expected from the specified radiation environment. In this guide, we discuss the differences between X-ray tester and cobalt-60
gamma effects. This discussion should be useful as background to the problem of extrapolation to effects expected from a different
2
radiation environment. However, the process of extrapolation to the expected real environment is treated elsewhere (1, 2).
1.9 The time scale of an X-ray irradiation and measurement may be much different than the irradiation time in the expected
device application. Information on time-dependent effects is given.
1.10 Possible lateral spreading of the collimated X-ray beam beyond the desired irradiated region on a wafer is also discussed.
1.11 Information is given about recommended experimental methodology, dosimetry, and data interpretation.
1.12 Radiation testing of semiconductor devices may produce severe degradation of the electrical parameters of irradiated
devices and should therefore be considered a destructive test.
1
This guide is under the jurisdiction of ASTM Committee F01 on Electronicsand is the direct responsibility of Subcommittee F01.11 on Nuclear and Space Radiation
Effects.
Current edition approved Oct. 1, 2011March 1, 2018. Published October 2011April 2018. Originally approved in 1993. Last previous edition approved in 20052011 as
ε1
F1467 - 99F1467 - 11.(2005) . DOI: 10.1520/F1467-11.10.1520/F1467-18.
2
The boldface numbers in parentheses refer to the list of references at the end of this guide.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
1

---------------------- Page: 1 --------
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4.1 Although Co-60 nuclei only emit monoenergetic gamma rays at 1.17 and 1.33 MeV, the finite thickness of sources, and encapsulation materials and other surrounding structures that are inevitably present in irradiators can contribute a substantial amount of low-energy gamma radiation, principally by Compton scattering (1, 2).3 In radiation-hardness testing of electronic devices this low-energy photon component of the gamma spectrum can introduce significant dosimetry errors for a device under test since the equilibrium absorbed dose as measured by a dosimeter can be quite different from the absorbed dose deposited in the device under test because of absorbed dose enhancement effects (3, 4). Absorbed dose enhancement effects refer to the deviations from equilibrium absorbed dose caused by non-equilibrium electron transport near boundaries between dissimilar materials.  
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ASTM
ASTM E668-20(Practice)
Standard Practice for Application of Thermoluminescence-Dosimetry (TLD) Systems for Determining Absorbed Dose in Radiation-Hardness Testing of Electronic Devices

SIGNIFICANCE AND USE
4.1 Absorbed dose in a material is an important parameter that can be correlated with radiation effects produced in electronic components and devices that are exposed to ionizing radiation. Reasonable estimates of this parameter can be calculated if knowledge of the source radiation field (that is, energy spectrum and particle fluence) is available. Sufficiently detailed information about the radiation field is generally not available. However, measurements of absorbed dose with passive dosimeters in a radiation test facility can provide information from which the absorbed dose in a material of interest can be inferred. Under certain prescribed conditions, TLDs are quite suitable for performing such measurements.
Note 2: For comprehensive discussions of various dosimetry methods applicable to the radiation types and energy and absorbed dose-rate range discussed in this practice, see ICRU Reports 14, 17, 21, and 34.
SCOPE
1.1 This practice covers procedures for the use of thermoluminescence dosimeters (TLDs) to determine the absorbed dose in a material irradiated by ionizing radiation. Although some elements of the procedures have broader application, the specific area of concern is radiation-hardness testing of electronic devices. This practice is applicable to the measurement of absorbed dose in materials irradiated by gamma rays, X rays, and electrons of energies from 12 to 60 MeV. Specific energy limits are covered in appropriate sections describing specific applications of the procedures. The range of absorbed dose covered is approximately from 10−2 to 104 Gy (1 to 106 rad), and the range of absorbed dose rates is approximately from 10−2 to 1010 Gy/s (1 to 1012 rad/s). Absorbed dose and absorbed dose-rate measurements in materials subjected to neutron irradiation are not covered in this practice. (See Practice E2450 for guidance in mixed fields.) Further, the portion of these procedures that deal with electron irradiation are primarily intended for use in parts testing. Testing of devices as a part of more massive components such as electronics boards or boxes may require techniques outside the scope of this practice.
Note 1: The purpose of the upper and lower limits on the energy for electron irradiation is to approach a limiting case where dosimetry is simplified. Specifically, the dosimetry methodology specified requires that the following three limiting conditions be approached: (a) energy loss of the primary electrons is small, (b) secondary electrons are largely stopped within the dosimeter, and (c) bremsstrahlung radiation generated by the primary electrons is largely lost.  
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
ASTM F1263-11(2019)(Guide)
Standard Guide for Analysis of Overtest Data in Radiation Testing of Electronic Parts

SIGNIFICANCE AND USE
5.1 Overtesting should be done when (a) testing by variables is impractical because of time and cost considerations or because the probability distribution of stress to failure cannot be estimated with sufficient accuracy, and (b) an unrealistically large number of parts would have to be tested at the specification stress for the necessary confidence and survival probability.
SCOPE
1.1 This guide covers the use of overtesting in order to reduce the required number of parts that must be tested to meet a given quality acceptance standard. Overtesting is testing a sample number of parts at a stress level higher than their specification stress in order to reduce the amount of necessary data taking. This guide discusses when and how overtesting may be applied to forming probabilistic estimates for the survival of electronic piece parts subjected to radiation stress. Some knowledge of the probability distribution governing the stress-to-failure of the parts is necessary, although exact knowledge may be replaced by over-conservative estimates of this distribution.  
1.2 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM E1854-19(Practice)
Standard Practice for Ensuring Test Consistency in Neutron-Induced Displacement Damage of Electronic Parts

SIGNIFICANCE AND USE
4.1 This practice was written primarily to guide test participants in establishing, identifying, maintaining, and using suitable environments for conducting high quality neutron tests. Its development was motivated, in large measure, because inadequate controls in the neutron-effects-test process have, in some past instances, resulted in exposures that have differed by factors of three or more from irradiation specifications. A radiation test environment generally differs from the environment in which the electronics must operate (the operational environment); therefore, a high quality test requires not only the use of a suitable radiation environment, but also control and compensation for contributions to damage that differ from those in the operational environment. In general, the responsibility for identifying suitable test environments to accomplish test objectives lies with the sponsor/user/tester and test specialist part of the team, with the assistance of an independent validator, if available. The responsibility for the establishment and maintenance of suitable environments lies with the facility operator/dosimetrist and test specialist, again with the possible assistance of an independent validator. Additional guidance on the selection of an irradiation facility is provided in Practice F1190.  
4.2 This practice identifies the tasks that must be accomplished to ensure a successful high quality test. It is the overall responsibility of the sponsor or user to ensure that all of the required tasks are complete and conditions are met. Other participants provide appropriate documentation to enable the sponsor or user to make that determination.  
4.3 The principal determinants of a properly conducted test are: (1) the radiation test environment shall be well characterized, controlled, and correlated with the specified irradiation levels; (2) damage produced in the electronic materials and devices is caused by the desired, specified component of the environment...
SCOPE
1.1 This practice sets forth requirements to ensure consistency in neutron-induced displacement damage testing of silicon and gallium arsenide electronic piece parts. This requires controls on facility, dosimetry, tester, and communications processes that affect the accuracy and reproducibility of these tests. It provides background information on the technical basis for the requirements and additional recommendations on neutron testing.  
1.2 Methods are presented for ensuring and validating consistency in neutron displacement damage testing of electronic parts such as integrated circuits, transistors, and diodes. The issues identified and the controls set forth in this practice address the characterization and suitability of the radiation environments. They generally apply to reactor sources, accelerator-based neutron sources, such as 14-MeV DT sources, and  252Cf sources. Facility and environment characteristics that introduce complications or problems are identified, and recommendations are offered to recognize, minimize or eliminate these problems. This practice may be used by facility users, test personnel, facility operators, and independent process validators to determine the suitability of a specific environment within a facility and of the testing process as a whole. Electrical measurements are addressed in other standards, such as Guide F980. Additional information on conducting irradiations can be found in Practices E798 and F1190. This practice also may be of use to test sponsors (organizations that establish test specifications or otherwise have a vested interest in the performance of electronics in neutron environments).  
1.3 Methods for the evaluation and control of undesired contributions to damage are discussed in this practice. References to relevant ASTM standards and technical reports are provided. Processes and methods used to arrive at the appropriate test environments and specification levels f...

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ASTM
ASTM F1190-18(Guide)
Standard Guide for Neutron Irradiation of Unbiased Electronic Components

SIGNIFICANCE AND USE
5.1 Semiconductor devices can be permanently damaged by neutrons (1, 2)6. The effect of such damage on the performance of an electronic component can be determined by measuring the component’s electrical characteristics before and after exposure to fast neutrons in the neutron fluence range of interest. The resulting data can be utilized in the design of electronic circuits that are tolerant of the degradation exhibited by that component.  
5.2 This guide provides a method by which the exposure of silicon and gallium arsenide semiconductor devices to neutron irradiation may be performed in a manner that is repeatable and which will allow comparison to be made of data taken at different facilities.  
5.3 For semiconductors other than silicon and gallium arsenide, applicable validated 1-MeV damage functions are not available in codified National standards. In the absence of a validated 1-MeV damage function, the non-ionizing energy loss (NIEL) or the displacement kerma, as a function of incident neutron energy, normalized to the response in the 1 MeV energy region, may be used as an approximation. See Practice E722 for a description of the method used to determine the damage functions in Si and GaAs (3).
SCOPE
1.1 This guide strictly applies only to the exposure of unbiased silicon (Si) or gallium arsenide (GaAs) semiconductor components (integrated circuits, transistors, and diodes) to neutron radiation to determine the permanent damage in the components. Validated 1-MeV displacement damage functions codified in National Standards are not currently available for other semiconductor materials.  
1.2 Elements of this guide, with the deviations noted, may also be applicable to the exposure of semiconductors comprised of other materials except that validated 1-MeV displacement damage functions codified in National standards are not currently available.  
1.3 Only the conditions of exposure are addressed in this guide. The effects of radiation on the test sample should be determined using appropriate electrical test methods.  
1.4 This guide addresses those issues and concerns pertaining to irradiations with neutrons.  
1.5 System and subsystem exposures and test methods are not included in this guide.  
1.6 The range of interest for neutron fluence in displacement damage semiconductor testing range from approximately 109 to 1016  1-MeV n/cm2.  
1.7 This guide does not address neutron-induced single or multiple neutron event effects or transient annealing.  
1.8 This guide provides an alternative to Test Method 1017, Neutron Displacement Testing, a component of MIL-STD-883 and MIL-STD-750.  
1.9 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.  
1.10 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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