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ASTM E2152-12(2023)

(Practice)

Standard Practice for Computing the Colors of Fluorescent Objects from Bispectral Photometric Data

Standard Practice for Computing the Colors of Fluorescent Objects from Bispectral Photometric Data

SIGNIFICANCE AND USE
5.1 The bispectral or two-monochromator method is the definitive method for the determination of the general radiation-transfer properties of fluorescent specimens (2). In this method, the measuring instrument is equipped with two separate monochromators. The first, the irradiation monochromator, irradiates the specimen with monochromatic light. The second, the viewing monochromator, analyzes the radiation leaving the specimen. A two-dimensional array of bispectral photometric values is obtained by setting the irradiation monochromator at a series of fixed wavelengths (μ) in the ultraviolet and visible range, and for each μ, using the viewing monochromator to record readings for each wavelength (λ) in the visible range. The resulting array, once properly corrected, is known as the Donaldson matrix, and the value of each element (μ,λ) of this array is here described as the Donaldson radiance factor (D(μ,λ)). The Donaldson radiance factor is an instrument- and illuminant-independent photometric property of the specimen, and can be used to calculate its color for any desired illuminant and observer. The advantage of this method is that it provides a comprehensive characterization of the specimen’s radiation-transfer properties, without the inaccuracies associated with source simulation and various methods of approximation.
SCOPE
1.1 This practice provides the values and practical computation procedures needed to obtain tristimulus values, designated X, Y, Z and X10, Y10, Z10 for the CIE 1931 and 1964 observers, respectively, from bispectral photometric data for the specimen. Procedures for obtaining such bispectral photometric data are contained in Practice E2153.  
1.2 Procedures for conversion of results to color spaces that are part of the CIE system, such as CIELAB and CIELUV are contained in Practice E308.  
1.3 This standard may involve hazardous materials, operations, and equipment. 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.

General Information

Status
Published
Publication Date
31-May-2023
ICS
35.240.99 - IT applications in other fields
Technical Committee
E12 - Color and Appearance
Drafting Committee
E12.05 - Fluorescence
Current Stage
Ref Project

Relations

Refers
ASTM E308-17 - Standard Practice for Computing the Colors of Objects by Using the CIE System
Effective Date
01-May-2017
Refers
ASTM E308-15 - Standard Practice for Computing the Colors of Objects by Using the CIE System
Effective Date
01-Apr-2015
Refers
ASTM E284-13b - Standard Terminology of Appearance
Effective Date
01-Nov-2013
Refers
ASTM E284-13a - Standard Terminology of Appearance
Effective Date
01-Jun-2013
Refers
ASTM E284-13 - Standard Terminology of Appearance
Effective Date
01-Jan-2013
Refers
ASTM E308-12 - Standard Practice for Computing the Colors of Objects by Using the CIE System
Effective Date
01-Jul-2012
Refers
ASTM E284-12 - Standard Terminology of Appearance
Effective Date
01-Jul-2012
Refers
ASTM E2153-01(2011) - Standard Practice for Obtaining Bispectral Photometric Data for Evaluation of Fluorescent Color
Effective Date
01-Nov-2011
Refers
ASTM E284-09a - Standard Terminology of Appearance
Effective Date
01-Jun-2009
Refers
ASTM E284-09 - Standard Terminology of Appearance
Effective Date
01-Jan-2009
Refers
ASTM E308-08 - Standard Practice for Computing the Colors of Objects by Using the CIE System
Effective Date
01-Dec-2008
Refers
ASTM E284-08 - Standard Terminology of Appearance
Effective Date
01-Aug-2008
Refers
ASTM E284-07 - Standard Terminology of Appearance
Effective Date
15-Jul-2007
Refers
ASTM E284-06b - Standard Terminology of Appearance
Effective Date
01-Dec-2006
Refers
ASTM E308-06 - Standard Practice for Computing the Colors of Objects by Using the CIE System
Effective Date
01-Dec-2006

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ASTM E2152-12(2023) - Standard Practice for Computing the Colors of Fluorescent Objects from Bispectral Photometric DataASTM E2152-12(2023) - Standard Practice for Computing the Colors of Fluorescent Objects from Bispectral Photometric Data
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ASTM E2152-12(2023) - Standard Practice for Computing the Colors of Fluorescent Objects from Bispectral Photometric Data
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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: E2152 − 12 (Reapproved 2023)
Standard Practice for
Computing the Colors of Fluorescent Objects from
Bispectral Photometric Data
This standard is issued under the fixed designation E2152; 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.
INTRODUCTION
The fundamental procedure for evaluating the color of a fluorescent specimen is to obtain bispectral
photometric data for specified irradiating and viewing geometries, and from these data to compute
tristimulus values based on a CIE (International Commission on Illumination) standard observer and
a CIE standard illuminant. Procedures for such computation are contained in this practice. This
practice also contains procedures for computing illuminant-specific spectral radiance factor values
from illuminant-independent bispectral photometric data.
1. Scope 2. Referenced Documents
1.1 This practice provides the values and practical compu- 2.1 ASTM Standards:
tation procedures needed to obtain tristimulus values, desig- E284 Terminology of Appearance
nated X, Y, Z and X , Y , Z for the CIE 1931 and 1964 E308 Practice for Computing the Colors of Objects by Using
10 10 10
observers, respectively, from bispectral photometric data for the CIE System
the specimen. Procedures for obtaining such bispectral photo- E2153 Practice for Obtaining Bispectral Photometric Data
metric data are contained in Practice E2153. for Evaluation of Fluorescent Color
2.2 CIE Standards:
1.2 Procedures for conversion of results to color spaces that
CIE 15 Colorimetry
are part of the CIE system, such as CIELAB and CIELUV are
2.3 ISO Standards:
contained in Practice E308.
ISO 11476 Paper and Board—Determination of CIE-
1.3 This standard may involve hazardous materials, 4
Whiteness, C/2 Degrees
operations, and equipment. This standard does not purport to
address all of the safety concerns, if any, associated with its
3. Terminology
use. It is the responsibility of the user of this standard to
3.1 Definitions—The definitions contained in Terminology
establish appropriate safety, health, and environmental prac-
E284 are applicable to this practice.
tices and determine the applicability of regulatory limitations
3.2 Definitions of Terms Specific to This Standard:
prior to use.
3.2.1 bispectrometer, n—an optical instrument equipped
1.4 This international standard was developed in accor-
with a source of irradiation, two monochromators, and a
dance with internationally recognized principles on standard-
detection system, such that a specimen can be measured at
ization established in the Decision on Principles for the
independently-controlled irradiation and viewing wavelengths.
Development of International Standards, Guides and Recom-
The bispectrometer is designed to allow for calibration to
mendations issued by the World Trade Organization Technical
Barriers to Trade (TBT) Committee.
For referenced ASTM standards, visit the ASTM website, www.astm.org, or
contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
This practice is under the jurisdiction of ASTM Committee E12 on Color and Standards volume information, refer to the standard’s Document Summary page on
Appearance and is the direct responsibility of Subcommittee E12.05 on Fluores- the ASTM website.
cence. Available from CIE (International Commission on Illumination) at www.cie-
Current edition approved June 1, 2023. Published July 2023. Originally approved .co.at or www.techstreet.com.
in 2001. Last previous edition approved in 2017 as E2152 – 12 (2017). DOI: Available from American National Standards Institute (ANSI), 25 W. 43rd St.,
10.1520/E2152-12R23. 4th Floor, New York, NY 10036, http://www.ansi.org.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
E2152 − 12 (2023)
provide quantitative determination of the bispectral radiation- color for any desired illuminant and observer. The advantage of
transfer properties of the specimen (1). this method is that it provides a comprehensive characteriza-
tion of the specimen’s radiation-transfer properties, without the
NOTE 1—Typically, a reference detection system monitors the radiation
inaccuracies associated with source simulation and various
incident on the specimen. This reference detection system serves to
methods of approximation.
compensate for both temporal and spectral variations in the flux incident
upon the specimen, by normalization of readings from the instrument’s
emission detection system.
6. Procedure
3.2.2 diagonal elements, n—elements of a bispectral matrix
6.1 Selecting Standard Observer—Select standard observer
for which irradiation and viewing wavelengths are equal.
according to the guidelines of Practice E308.
3.2.3 fluorescence, n—this standard uses the term “fluores-
6.2 Selecting Illuminants—Select illuminants that are simi-
cence” as a general term, including both true fluorescence
lar to the light under which the objects will be viewed or for
-8
(with a luminescent decay time of less than 10 s) and
which their colors will be specified or evaluated. In general,
phosphorescence with a delay time short enough to be indis-
follow the recommendations of Practice E308. For fluorescent
tinguishable from fluorescence for the purpose of colorimetry.
samples, however, special attention must be given to the
3.2.4 off-diagonal element, n—any element of a bispectral relative UV content of the selected illuminants and the light
matrix for which irradiation and viewing wavelengths are not
under which the objects will be viewed.
equal. 6.2.1 When object will be viewed indoors, by daylight
filtered through a glass window, use values for the extended
4. Summary of Practice
version of Illuminant C defined in ISO 11476.
6.2.2 When object will be viewed outdoors, by unfiltered
4.1 Procedures—Procedures are given for computing from
daylight, use values for CIE Illuminant D65, or other daylight
bispectral photometric measurements the CIE tristimulus val-
illuminants, as defined by the formulas developed by Judd, and
ues X, Y, Z for the CIE 1931 standard observer and the CIE
presented in CIE 15.
1964 supplementary standard observer. While recognizing the
6.2.3 When object will be viewed under well-defined spe-
CIE recommendation of numerical integration at 1 nm intervals
cial conditions of irradiation which are not similar to any
(in CIE 15) as the basic definition, this practice is limited in
standard illuminant, a provisional illuminant may be defined.
scope to measurements and calculations using spectral inter-
Such a provisional illuminant must represent the relative
vals greater than or equal to 5 nm.
spectral irradiance upon the object surface under these special
4.2 Calculations—CIE tristimulus values X, Y, Z or X ,
conditions.
Y , Z are calculated by numerical summation of the prod-
10 10
ucts of weighting factors for selected illuminants and observers
7. Calculation
with the bispectral Donaldson radiance factor of the specimen.
7.1 Calculation of Colorimetric Quantities—Use the
The tristimulus values so calculated may be converted to
method of calculating tristimulus values at 5 nm intervals over
coordinates in a more nearly uniform color space such as
the viewing wavelength range 380 nm to 780 nm, and irradia-
CIELAB or CIELUV.
tion wavelength range 300 nm to 780 nm.
5. Significance and Use
7.2 Calculation of Tristimulus Values—The calculation pro-
cedures described below involve numerical summation of the
5.1 The bispectral or two-monochromator method is the
products of the Donaldson radiance factor of the specimen and
definitive method for the determination of the general
a bispectral factor derived from the tabulated standard illumi-
radiation-transfer properties of fluorescent specimens (2). In
nant and observer functions. After normalization, the sums are
this method, the measuring instrument is equipped with two
the CIE tristimulus values X, Y, Z (3, 2, 1).
separate monochromators. The first, the irradiation
7.2.1 Application of Illuminant Weights—Select the desired
monochromator, irradiates the specimen with monochromatic
CIE standard illuminant from Tables given in Practice E308.
light. The second, the viewing monochromator, analyzes the
Multiply each element D(μ,λ) of the specimen’s Donaldson
radiation leaving the specimen. A two-dimensional array of
matrix by the tabulated value of the relative spectral power of
bispectral photometric values is obtained by setting the irra-
the illuminant Φ at the element’s irradiation wavelength (μ).
diation monochromator at a series of fixed wavelengths (μ) in
7.2.2 Calculation of Stimulus Function—Obtain the sum
the ultraviolet and visible range, and for each μ, using the
over μ of these products at 5 nm intervals over the wavelength
viewing monochromator to record readings for each wave-
range 300 nm to 780 nm. The sum obtained at each viewing
length (λ) in the visible range. The resulting array, once
wavelength λ is the value of the specimen’s stimulus function
properly corrected, is known as the Donaldson matrix, and the
(relative spectral radiance) F(λ), under the specified conditions
value of each element (μ,λ) of this array is here described as the
of irradiation. From these values, either tristimulus values or
Donaldson radiance factor (D(μ,λ)). The Donaldson radiance
spectral radiance factor values may be derived.
factor is an instrument- and illuminant-independent photomet-
ric property of the specimen, and can be used to calculate its
F λ 5 Φ μ D μ,λ (1)
~ ! ~ ! ~ !
(
μ5300
7.2.3 Derivation of Tristimulus Values—Use the color-
The boldface numbers in parentheses refer to a list of references at the end of
this standard. matching functions selected in 6.1. Multiply the specimen’s
E2152 − 12 (2023)
stimulus function at each viewing wavelength (λ) by the fluorescence components may be employed, description of
corresponding tabulated values of the observer color-matching such calculations lies outside the scope of this standard.
functions. Obtain the sum of these spectral products at 5 nm
7.6 Abridged Calculation Procedures:
intervals over the wavelength range 380 nm to 780 nm:
7.6.1 Wavelength Intervals of Greater than 5 nm—When
data for D(μ,λ) are not available at 5 nm intervals, estimated
X 5 k xH λ F λ (2)
~ ! ~ !
(
values at 5 nm intervals should be derived by appropriate
λ5380
interpolation, as described in Annex A1.
7.6.2 Viewing Wavelength Range Less Than 380 nm to 780
Y 5 k yH λ F λ
~ ! ~ !
(
λ5380 nm—When data for D(μ,λ) are not available for the full
viewing wavelength range, add the illuminant or observer
weights, or both, at the wavelengths for which data are not
Z 5 k zH~λ!F~λ!
(
λ5380
available to the weights at the shortest and longest wavelength
for which spectral data are available. Note that such use of
where:
spectrally-truncated data is not recommended when significant
k = the normalization constant:
fluorescent emission occurs in the region of truncation.
7.6.3 Irradiation Wavelength Range Less Than 300 nm to
k 5 (3)
780 nm—When the bispectral region of fluorescence is known
Φ~λ!yH~λ!
(
for a particular specimen, it is acceptable to limit the collection
λ5380
of fluorescence data (off-diagonal values) to this region.
7.3 Derivation of Other Colorimetric Quantities—Other
Complete the standard Donaldson matrix by setting off-
colorimetric values, such as chromaticity coordinates, CIELAB
diagonal values outside this region to zero.
and CIELUV values, may be calculated from tristimulus values
as described in Practice E308.
8. Report
NOTE 2—The validity of CIELAB and CIELUV values for describing
8.1 The report of the measurement of colorimetric for
the color of fluorescent materials is subject to question, for two reasons.
fluorescent samples data shall include the following:
First, because the appearance of a fluorescent material may be influenced
by irradiation at wavelengths outside the visible range, the appropriate
8.2 Specimen Description—Including the following:
definition of the “white point” (incorporated in the CIELAB and CIELUV
8.2.1 Type and identification,
calculations) is not clear. Second, the perceptual uniformity of these color
spaces has not been evaluated in regions where L* exceeds 100, as it may 8.2.2 Date of preparation or manufacture, if required,
for fluorescent materials. It is the responsibility of the user to determine
8.2.3 Method of cleaning and date, if cleaned,
the appropriateness of such metrics for any particular specimen and
8.2.4 Orientation of the specimen during measurement, and
application.
8.2.5 Any changes in the specimen during measurement.
7.4 Derivation of Spectral Radiance Factors—Calculate the
8.3 Source of Date—Give instrument identification, irradi-
specimen’s stimulus function (relative spectral radiance) F(λ)
ating and viewing geometry, spectral bandpass, and date of
for the selected illuminant as described in section 7.2.2. Divide
measurement.
F at each viewing wavelength (λ) by the corresponding
tabulated value of the relative spectral power Φ of the selected 8.4 Observer—Indicate whether the reported data were
I
illuminant. Note that for a fluorescent specimen, the spectral computed for the CIE 1931 standard observer (2°) or the 1964
radiance factor (β (λ) is illuminant-specific (3). supplementary standard observer (10°).
I
F λ Φ μ 8.5 Illuminants—Indicate which illuminants were used.
~ ! ~ !
I I
β ~λ! 5 5 D~μ,λ! (4)
I (
Φ ~λ! Φ ~λ!
μ5300
I I
8.6 Method of Calculation—Indicate whether the procedure
7.5 Separation of Fluorescence and Reflection using a 5 nm wavelength interval, or a specified abridged
Components—Fluorescence and reflection components of tris- procedure was used, and what wavelength range of spectral
timulus and spectral radiance factor values can be calculated by data was available.
substituting the fluorescent or reflection components of Don-
8.7 Colorimetric Data—Report according to the guidelines
aldson radiance factor (D or D ) for Donaldson radiance
F R
of Practice E308.
factor (D) in the calculations described in sections 7.2 and 7.3.
8.8 Spectral Radiance Factor (Optional)—When reporting
This separation of components is valid for D, β, and tristimulus
spectral radiance factor values for fluorescent samples, indicate
values; it may not be valid for other colorimetric valu
...

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SIGNIFICANCE AND USE
5.1 The bispectral or two-monochromator method is the definitive method for the determination of the general (illuminant-independent) radiation-transfer properties of fluorescent specimens (2). The Donaldson radiance factor is an instrument- and illuminant-independent photometric property of the specimen, and can be used to calculate its color for any desired illuminant and observer. The advantage of this method is that it provides a comprehensive characterization of the specimen’s radiation-transfer properties, without the inaccuracies associated with source simulation and various methods of approximation.  
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5.1 The bispectral or two-monochromator method is the definitive method for the determination of the general (illuminant-independent) radiation-transfer properties of fluorescent specimens (2). The Donaldson radiance factor is an instrument- and illuminant-independent photometric property of the specimen, and can be used to calculate its color for any desired illuminant and observer. The advantage of this method is that it provides a comprehensive characterization of the specimen’s radiation-transfer properties, without the inaccuracies associated with source simulation and various methods of approximation.  
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1.1 This practice addresses the instrumental measurement requirements, calibration procedures, and material standards needed for obtaining precise bispectral photometric data for computing the colors of fluorescent specimens.  
1.2 This practice lists the parameters that must be specified when bispectral photometric measurements are required in specific methods, practices, or specifications.  
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SIGNIFICANCE AND USE
5.1 This guide describes the recommended procedure for using software to assist with the identification of indications in digital radiographic images. Some of the concepts presented may be appropriate for other nondestructive test methods.  
5.2 When properly applied, the methods and techniques outlined in this guide offer radiographic testing practitioners the potential to improve inspection reliability, reduce inspection cycle time, and harness inspection statistics for improving manufacturing processes.  
5.3 The typical goal of a nondestructive test is to identify flaws that exceed the acceptance criteria. Due to the variability and uncertainty present in any inspection process, acceptance thresholds are established so that some acceptable components are discarded in an effort to prevent parts with discontinuities that exceed the acceptance criteria from entering service. This type of error, called a false positive, is considered less critical than a false negative error which would allow a nonconforming part into service. A successful application of AssistDR minimizes the false positive rate while reducing the false negative rate to levels appropriate for the intended application. The methods and techniques described in this guide facilitate achieving this desired outcome.  
5.4 With the advent of deep learning, convolutional neural networks, and other forms of artificial intelligence, scenarios become possible where an AssistDR system continues to evolve or learn after qualification for production use. This guide does not address learning-based AssistDR systems. This guide addresses only deterministic systems that have software code and parameters that are fixed after qualification. Note that this limitation does not prohibit the use of this guide for developing a qualification and usage strategy for software using deep learning technology. The training or learning process for the deep learning system would need to be completed before qualification and all ...
SCOPE
1.1 Assisted defect recognition (AssistDR) describes a class of computer algorithms that assist a human operator in making a determination about nondestructive test data. This guide uses the term AssistDR to describe those computer assisted evaluation algorithms and associated software. For the purposes of this guide, the usage of the words “defect,” “evaluate,” “evaluation,” etc., in no way implies that the algorithms are dispositioning or otherwise making an unaided final disposition. Depending on the application, AssistDR computer algorithms detect and optionally classify indications of defects, flaws, discontinuities, or other anomalous signals in the acquired images. Software that does make an unaided final disposition is classified as automated defect recognition (AutoDR). While the concepts discussed in this guide are pertinent to AutoDR applications, additional validation tests or controls may be necessary when implementing AutoDR.  
1.2 This guide establishes the minimum considerations for the radiographical examination of components using AssistDR for non-film radiographic test data. Most of the examples and discussion in this guide are built around two-dimensional test data for simplicity. The principles can be applied to three (volumetric computed tomography, for example) or higher dimensional test data.  
1.3 The methods and practices described in this guide are intended for the application of AssistDR where image analysis will aid a human operator in the detection and evaluation of indications. The degree to which AssistDR is integrated into the testing and evaluation process will help the user determine the appropriate levels of process qualification and control required. This guide is not intended for applications wishing to employ AutoDR in which there is no human review of the results.  
1.4 This guide applies to radiographic examination using an X-ray source. Some of the concepts presented may be ap...

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ASTM E2842-14(2021)(Guide)
Standard Guide for Credentialing for Access to an Incident or Event Site

SIGNIFICANCE AND USE
4.1 There is currently no way to ensure consistency among all entities across the nation for access to an incident or event scene. This guide is intended to enable consistency in credentials with respect to verification of identity, qualifications, and deployment authorization (NIMS 0002).  
4.2 This guide is intended to be used by any entity that manages and controls access to an incident scene to facilitate interoperability and ensure consistency.
SCOPE
1.1 The focus of this guide is on the development of guidelines for credentialing for access. The guide addresses the fundamental terms, criteria, references, definitions, and process model for implementation of credentialing or a credentialing program.  
1.2 This guide explains and identifies actions and processes that can provide the foundation for consistent use and interoperability of credentialing for all entities.  
1.3 This guide describes the activities involved in creating a credentialing framework, which may include a physical badge; however, it does not define the knowledge, skills, or abilities required to gain access to a site or event. This guide does not address a requirement for a physical badge as a prerequisite for a credential. A badge may be an accepted credential across jurisdictional lines and other credentials may be issues by the AHJ at the scene.  
1.4 This guide reinforces the importance of controlling access to a site by individuals with the proper identification, qualification, and authorization, which supports effective management of deployed resources.  
1.5 This guide relies on the existing rules, regulations, laws, and policies of the AHJ. Regulations identifying personal and private information as public record may differ from a responder’s home jurisdiction.  
1.6 This guide utilizes the principles of the Data Management Association Guide to the Data Management Body of Knowledge (DAMA-DMBOK) in order to effectively control data and information assets and does not prescribe the use of technology-based solutions.  
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 D7780-20(Practice)
Standard Practice for Minimum Geospatial Data for Representing Coal Mining Features

SIGNIFICANCE AND USE
4.1 This practice addresses coal mining geospatial data in general and is significant to the coal mining community because it provides uniformity of geospatial data pertaining to coal mining features.  
4.2 Some RA data for coal mining feature attributes may not have values. Those RAs may not collect those attributes as part of their regulatory program or those attributes may not be applicable within their area of responsibility. As a result, a national dataset of coal mining features may appear to be incomplete for those RAs.  
4.3 Within its area of exclusive jurisdiction, each RA is the ADS for the coal mining geospatial data that it creates and uses to regulate mining activity.  
4.4 Limitations of Use—Uses of a national dataset are limited by several factors affecting the completeness, currency, and accuracy, of various data sources.  
4.4.1 Completeness—Participation in the compilation of spatial data may not be uniform across RAs, which may affect completeness, both in terms of spatial data, and associated attributes. For some RAs, this standard may not be applicable because features described herein do not occur within their area of responsibility.  
4.4.2 Currency—Source data is subject to change as a result of regulatory actions that may change the geographical location, extent, or attributes of particular features which may not be reflected in the national dataset. If detailed information is needed for individual features, the appropriate RA should be contacted for additional information.  
4.4.3 Data compiled in accordance with this standard is not intended to be used as a primary source for evaluating risk or safety.  
4.4.4 Data compiled in accordance with this standard is intended for informative purposes; it is not authoritative.
SCOPE
1.1 This practice defines a set of terms, procedures, and data required to define the accurate location and description of the minimum geospatial data for surface coal mining operations (CMO), underground coal mining extents, land reclamation and performance bond statuses, lands unsuitable for mining petitions (LUMP) and designated areas, coal spoil and refuse features, coal preparation plants, environmental resource monitoring locations (ERMLs), and postmining land uses.  
1.2 Units—The values stated in inch-pound units are to be regarded as standard. No other units of measurement are included in this 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 and health practices and determine the applicability of regulator limitations prior to use.  
1.3.1 This practice offers a set of instructions for performing one or more specific operations. This document cannot replace education or experience and should be used in conjunction with professional judgment. Not all aspects of this practice may be applicable in all circumstances. This ASTM standard is not intended to represent or replace the adequacy of a professional service, nor should this document be applied without consideration of a project’s many unique aspects. The word “Standard” in the title of this document means only that the document has been approved through the ASTM consensus process.  
1.4 Surface CMOs—As used in this practice, a surface CMO represents an area where coal removal, reclamation, and related supporting activities have occurred, is occurring, is pending authorization or is authorized by the Regulatory Authority (RA) within a defined surface CMO or any other unpermitted area that has been identified by the RA.  
1.4.1 This practice addresses coal mining geospatial data, interim permits, and permanent program permits. Each RA shall be the authoritative data source (ADS) for coal mining geospatial data.  
1.5 Underground Coal Mining Extents—This practice addresses underground coal mining extents that represent a...

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ASTM
ASTM D7699/D7699M-20(Practice)
Standard Practice for Minimum Geospatial Data for Abandoned Mine Land Problem Areas, Planning Units, Keyword Features, and Project Sites

SIGNIFICANCE AND USE
4.1 This practice addresses AML PAs, PUs, Keyword Features, and Project Sites. This practice is significant as it provides for uniformity of geospatial data pertaining to the geographic location and description of AML sites located throughout the United States.  
4.2 This geospatial data standard will help ensure uniformity of data contributed by each RA and assist organizations in efforts to create, utilize, and share geospatial data. Use of this standard will result in organized and accessible data to support programmatic decisions and work plan development, increased awareness of AML problems, and better communication between RA, the public, industry, and other interested parties.  
4.3 The geospatial data may be served as a layer in a national dataset and map service.
SCOPE
1.1 This practice covers the minimum elements for the accurate location and description of geospatial data for defining Abandoned Mine Land (AML) Problem Areas, Planning Units, Keyword Features, and Project Sites as originally defined by the Office of Surface Mining Reclamation and Enforcement (OSMRE), through its Abandoned Mine Land Inventory Manual (Directive AML-1) under the jurisdiction of Surface Mining Control and Reclamation Act of 1977. These standards remain applicable to mining organizations that geospatially locate and identify AML sites, however these standards can be used for entities that are in beginning phases of mapping and identifying AML sites using protocol that is consistent with existing nomenclature.  
1.1.1 Abandoned mine lands consist of those lands and waters which were mined for coal or other minerals, or both, and abandoned or left in an inadequate condition of reclamation and for which there is no continuing reclamation responsibility for mitigation of adverse impacts to human health and safety or environmental resources.  
1.1.2 As used in this practice, an AML Problem Area (PA) represents a closed polygon boundary for a uniquely defined geographic area contained within an AML Planning Unit (PU). An AML PA is a subdivision of an AML PU that contains one or more AML keyword features together with impacted land or water resources or both. An AML PA should not cross PU boundaries.  
1.1.3 As used in this practice, an AML PU represents a closed polygon boundary of a uniquely defined geographic area identified by unique numbers and names. An entire WCU may be delineated as a single PU or subdivided into multiple PUs.  
1.1.4 As used in this practice, an AML Keyword Feature is a point, line, or polygon defining the location of a specific on-the-ground feature contained within an AML Problem Area (PA) as described in the AML Inventory Manual.  
1.1.5 As used in this practice, an AML Project Site is a closed polygon boundary for a uniquely defined geographic area that includes the area disturbed to achieve the reclamation. An AML Project Site may contain one or more AML keyword features together with impacted land or water resources or both.  
1.2 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.  
1.3 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 practice offers a set of instructions for performing one or more specific operations. This document cannot replace education or experience and should be used in conjunction with professional judgment. Not all aspects of this practice may be applicable in all circumstances. This ASTM standard is not intended to represent...

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ASTM E3016-18(Guide)
Standard Guide for Establishing Confidence in Digital and Multimedia Evidence Forensic Results by Error Mitigation Analysis

SIGNIFICANCE AND USE
3.1 Digital and multimedia evidence forensics is a complex field that is heavily reliant on algorithms that are embedded in automated tools and used to process evidence. Weaknesses or errors in these algorithms, tools, and processes can potentially lead to incorrect findings. Indeed, errors have occurred in a variety of contexts, demonstrating the need for more scientific rigor in digital and multimedia evidence forensics. This guide proposes a disciplined approach to mitigating potential errors in evidence processing to reduce the risk of inaccuracies, oversights, or misinterpretations in digital and multimedia evidence forensics. This approach provides a scientific basis for confidence in digital and multimedia evidence forensic results.  
3.2 Error rates are used across the sciences to characterize the likelihood that a given result is correct. The goal is to explain to the reader (or receiver of the result) the confidence the provider of the result has that it is correct. Many forensic disciplines use error rates as a part of how they communicate their results. Similarly, digital and multimedia evidence forensics needs to communicate how and why there is confidence in the results. Because of intrinsic difference between the biological and chemical sciences and computer science, it is necessary to go beyond error rates. One difference between chemistry and computer science is that digital technology is constantly changing and individuals put their computers to unique uses, making it infeasible to develop a representative sample to use for error rate calculations. Furthermore, a digital and multimedia evidence forensic method may work well in one environment but fail completely in a different environment.  
3.3 This guide provides a disciplined and structured approach for addressing and explaining potential errors and error rates associated with the use of digital and multimedia evidence forensic tools/processes in any given environment. This approach to establi...
SCOPE
1.1 This guide provides a process for recognizing and describing both errors and limitations associated with tools, techniques, and methods used to support digital and multimedia evidence forensics. This is accomplished by explaining how the concepts of errors and error rates should be addressed in digital and multimedia evidence forensics. It is important for practitioners and stakeholders to understand that digital and multimedia evidence forensic techniques and tools have known limitations, but those limitations have differences from errors and error rates in other forensic disciplines. This guide proposes that confidence in digital and multimedia evidence forensic results is best achieved by using an error mitigation analysis approach that focuses on recognizing potential sources of error and then applying techniques used to mitigate them, including trained and competent personnel using tested and validated methods and practices. Sources of error not directly related to tool usage are beyond the scope of this guide.  
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 E2077-00(2016)(Specification)
Standard Specification for Analytical Data Interchange Protocol for Mass Spectrometric Data

ABSTRACT
This specification covers an analytical data interchange protocol for mass spectrometric data representation and a software vehicle to affect the transfer of mass spectrometric data between instrument data systems. This specification does not provide for the storage of data acquired simultaneous to and integrated with the mass spectrometric data, but on other detectors. The protocol, which is designed to benefit users of analytical instruments and increase laboratory productivity and efficiency, provides a standardized format for the creation of raw data files, library spectrum files or results files. This file, which has a ".cdf" extension, contains typical header information like instrument, sample, and acquisition method description, followed by raw, library, or processed data. Once data have been written or converted to this protocol, they can be read and processed by software packages that support the protocol. This protocol is intended to perform the following functions: (1) transfer data between various vendors' instrument systems; (2) provide Laboratory Information Management Systems (LIMS) communications; (3) link data to document processing applications; (4) link data to spreadsheet applications, and (5) archive analytical data, or a combination thereof.
SCOPE
1.1 This specification covers a standardized format for mass spectrometric data representation and a software vehicle to effect the transfer of mass spectrometric data between instrument data systems. This specification provides a protocol designed to benefit users of analytical instruments and increase laboratory productivity and efficiency.  
1.2 The protocol in this specification provides a standardized format for the creation of raw data files, library spectrum files or results files. This standard format has the extension “.cdf” (derived from NetCDF). The contents of the file include typical header information like instrument, sample, and acquisition method description, followed by raw, library or processed data. Once data have been written or converted to this protocol, they can be read and processed by software packages that support the protocol.  
1.3 This specification does not provide for the storage of data acquired simultaneous to and integrated with the mass spectrometric data, but on other detectors; for example attached to the mass spectrometer's liquid or gas chromatographic system. Related Specification E1947 and Guide E1948 describe the storage of 2-dimensional chromatographic data.  
1.4 The software transfer vehicle used for the protocol in this specification is NetCDF, which was developed by the Unidata Program and is funded by the Division of Atmospheric Sciences of the National Science Foundation.2  
1.5 The protocol in this specification is intended to (1) transfer data between various vendors' instrument systems, (2) provide Laboratory Information Management Systems (LIMS) communications, (3) link data to document processing applications, (4) link data to spreadsheet applications, and (5) archive analytical data, or a combination thereof. The protocol is a consistent, vendor independent data format that facilitates the analytical data interchange for these activities.  
1.6 The protocol consists of:  
1.6.1 This specification on mass spectrometric data, which gives the full definitions for each one of the generic mass spectrometric data elements used in implementation of the protocol. It defines the analytical information categories, which are a convenient way for sorting analytical data elements to make them easier to standardize.  
1.6.2 Guide E2078 on mass spectrometric data, which gives the full details on how to implement the content of the protocol using the public-domain NetCDF data interchange system. It includes a brief introduction to using NetCDF and describes an API (Application Programming Interface) that is intended to be incorporated into application programs to read or write NetCDF files. I...

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