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ASTM F733-90(2003)

(Practice)

Standard Practice for Optical Distortion and Deviation of Transparent Parts Using the Double-Exposure Method

Standard Practice for Optical Distortion and Deviation of Transparent Parts Using the Double-Exposure Method

SIGNIFICANCE AND USE
Transparent parts, such as aircraft windshields and windows, can be inspected using this practice, and the amount of optical distortion or deviation can be measured. The measurement can be checked for acceptability against the specification for the part. The photograph (print or negative) can be maintained as a permanent record of the optical quality of the part.
SCOPE
1.1 This photographic practice determines the optical distortion and deviation of a line of sight through a simple transparent part, such as a commercial aircraft windshield or a cabin window. This practice applies to essentially flat or nearly flat parts and may not be suitable for highly curved materials.
1.2 This standard does not purport to address the safety concerns associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use.

General Information

Status
Historical
Publication Date
30-Sep-2003
ICS
49.035 - Components for aerospace construction
Technical Committee
F07 - Aerospace and Aircraft
Drafting Committee
F07.08 - Transparent Enclosures and Materials
Current Stage
Ref Project

Relations

Replaces
ASTM F733-90(1997)e1 - Standard Practice for Optical Distortion and Deviation of Transparent Parts Using the Double-Exposure Method
Effective Date
01-Oct-2003
Replaced By
ASTM F733-09 - Standard Practice for Optical Distortion and Deviation of Transparent Parts Using the Double-Exposure Method
Effective Date
15-May-2009
Referred By
ASTM F2156-17(2022) - Standard Test Method for Measuring Optical Distortion in Transparent Parts Using Grid Line Slope
Effective Date
01-Oct-2003
Referred By
ASTM F801-21 - Standard Test Method for Measuring Optical Angular Deviation of Transparent Parts
Effective Date
01-Oct-2003
Referred By
ASTM C1652/C1652M-21 - Standard Test Method for Measuring Optical Distortion in Flat Glass Products Using Digital Photography of Grids
Effective Date
01-Oct-2003
Referred By
ASTM F2469-20 - Standard Test Method for Measuring Optical Angular Deviation of Transparent Parts Using the Double-Exposure Method
Effective Date
01-Oct-2003
Referred By
ASTM F790-23 - Standard Guide for Testing Materials for Aerospace Plastic Transparent Enclosures
Effective Date
01-Oct-2003

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ASTM F733-90(2003) - Standard Practice for Optical Distortion and Deviation of Transparent Parts Using the Double-Exposure MethodASTM F733-90(2003) - Standard Practice for Optical Distortion and Deviation of Transparent Parts Using the Double-Exposure Method
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ASTM F733-90(2003) - Standard Practice for Optical Distortion and Deviation of Transparent Parts Using the Double-Exposure Method
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NOTICE: This standard has either been superseded and replaced by a new version or withdrawn.
Contact ASTM International (www.astm.org) for the latest information
Designation:F733–90 (Reapproved 2003)
Standard Practice for
Optical Distortion and Deviation of Transparent Parts Using
the Double-Exposure Method
This standard is issued under the fixed designation F733; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision.Anumber in parentheses indicates the year of last reapproval.A
superscript epsilon (e) indicates an editorial change since the last revision or reapproval.
1. Scope 4. Significance and Use
1.1 This photographic practice determines the optical dis- 4.1 Transparent parts, such as aircraft windshields and
tortion and deviation of a line of sight through a simple windows, can be inspected using this practice, and the amount
transparent part, such as a commercial aircraft windshield or a of optical distortion or deviation can be measured. The
cabinwindow.Thispracticeappliestoessentiallyflatornearly measurement can be checked for acceptability against the
flat parts and may not be suitable for highly curved materials. specification for the part. The photograph (print or negative)
1.2 This standard does not purport to address the safety can be maintained as a permanent record of the optical quality
concerns associated with its use. It is the responsibility of the of the part.
user of this standard to establish appropriate safety and health
5. Apparatus
practices and determine the applicability of regulatory limita-
5.1 Test Room—The test room must be large enough to
tions prior to use.
properly locate the required testing equipment.
2. Terminology
5.1.1 MethodArequires a room approximately 12 m (40 ft)
2.1 Definitions: long.
2.1.1 deviation—the displacement of a line or object when 5.1.2 Method B requires a room approximately 7 m (23 ft)
viewed through the transparent part. Expressed as the angular long.
measurementofthedisplacedline,forexample,milliradiansof 5.1.3 The walls, ceiling, and floor shall have low reflec-
angle. tance. A flat black paint or coating is preferred.
2.1.2 distortion—the rate of change of deviation resulting 5.2 Grid Board—The grid board provides a defined pattern
from an irregularity in a transparent part. againstwhichthetransparentpartisexamined.Gridboardsare
2.1.3 Expressed as the angular bending of the light ray per of the following types.
unit of length of the part, for example, milliradians per 5.2.1 Type 1—The grid board is composed of white strings
centimetre. held taut, each spaced at a specific interval, with the strings
2.1.4 May also be expressed as the slope of the angle of stretched vertically and horizontally.The grid board frame and
localized grid line bending, for example, 1 in 5 (see Fig. 1). background shall have a flat black finish to reduce light
2.1.5 installed angle—the part attitude as installed in the reflection. A bank of fluorescent lights at each side provides
aircraft. Defined by the angle from a horizontal line to the illumination of the strings.
vertical plane of the part, and the angle of sweep back from a 5.2.2 Type 2—The grid board is a transparent sheet having
horizontallinenormaltothecenterlineoftheaircraft.SeeFig. anopaque,flatblackoutersurfaceexceptforthegridlines.The
2 for an example. grid lines are left transparent, and when lighted from behind
with fluorescent lights, provide a bright grid pattern with
3. Summary of Practice
excellent photographic characteristics.
3.1 The transparent part is placed a given distance from a
5.2.3 Type 3—The grid board is a rigid sheet of material
grid line pattern. A camera is placed so as to photograph the which has a grid pattern printed on the front surface. Details of
gridpatternasviewedthroughthepart.Thephotographisthen
the grid lines, pattern, and lighting shall be as specified by the
examined and optical distortion or deviation is measured. procuring activity.
5.2.4 The grid board shall have a width and height large
enough so that the area of the part to be photographed can be
This practice is under the jurisdiction ofASTM Committee F07 onAerospace
superimposedwithintheperimeterofthegridboard.Detailsof
andAircraft and is the direct responsibility of Subcommittee F07.08 onTransparent
the grid square size shall be as specified by the procuring
Enclosures and Materials.
activity, but grids shall not have a line spacing less than 1.27
Current edition approved Oct. 1, 2003. Published November 2003. Originally
e1 1
approved in 1981. Last previous edition approved in 1997 as F733–90 (1997) . cm ( ⁄2 in.), or more than 2.54 cm (1 in.).
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959, United States.
F733–90 (2003)
FIG. 1 Optical Distortion Represented by Tangent
TABLE 1 Optical Inspection Distances
5.3 Camera—Unless otherwise specified, the camera shall
Method A
utilizea4by 5-in. film size.The lens opening used shall be f8
Camera-to-grid-board dis- 1000 cm (32 ft 10 in.)
or smaller. The camera shall be firmly mounted to prevent any
tance
movement during the photographic exposure. Camera-to-part distance 550 cm (18 ft 1 in.)
Part-to-grid board distance 450 cm (14 ft 9 in.)
Method B
6. Test Specimen
Camera-to-grid-board dis- 450 cm (14 ft 9 in.)
tance
6.1 The part to be checked shall be cleaned, using any
Camera-to-part distance 150 cm (4 ft 11 in.)
acceptable procedure, to remove any foreign material that
Part-to-grid-board distance 300 cm (9 ft 10 in.)
might cause localized optical distortion. No special condition-
ing, other than cleaning, is required. The part shall be at
ambient temperature. 7.2.2 The distances for positioning of camera, part, and grid
board shall be in accordance with Method A or Method B as
7. Procedure
shown in Table 1.Adepiction of the set up is shown in Fig. 2.
7.1 The procuring activity shall specify whether Method A 7.2.3 Prepareasingleexposurephotographofthegridboard
or Method B (see Table 1) shall be used to measure optical viewed through the part. The camera shall focus on the grid
distortion and deviation. When the part is flat and mounted board.
nearly vertical, Meth
...

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SIGNIFICANCE AND USE
5.1 Transparent parts, such as aircraft windshields, canopies, cabin windows, and visors, shall be measured for compliance with optical distortion specifications using this test method. This test method is suitable for assessing optical distortion of transparent parts as it relates to the visual perception of distortion. It is not suitable for assessing distortion as it relates to pure angular deviation of light as it passes through the part. Either Test Method F801 or Practice F733 is appropriate and shall be used for this latter application. This test method is not recommended for raw material.
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1.1 When an observer looks through an aerospace transparency, relative optical distortion results, specifically in thick, highly angled, multilayered plastic parts. Distortion occurs in all transparencies but is especially critical to aerospace applications such as combat and commercial aircraft windscreens, canopies, or cabin windows. This is especially true during operations such as takeoff, landing, and aerial refueling. It is critical to be able to quantify optical distortion for procurement activities.  
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5.1 One of the measures of optical quality of a transparent part is its angular deviation. It is possible that excessive angular deviation, or variations in angular deviation throughout the part, will result in visible distortion of scenes viewed through the part. Angular deviation, its detection, and quantification are of extreme importance in the area of certain aircraft transparency applications, that is, aircraft equipped with Heads-up Displays (HUD). It is possible that HUDs will require stringent control over the optics of the portion of the transparency (windscreen or canopy) which lies between the HUD combining glass and the external environment. Military aircraft equipped with HUDs or similar devices require precise knowledge of the effects of the windscreen or canopy on image position in order to maintain weapons aiming accuracy.  
5.2 Two optical parameters have the effect of changing image position. The first, lateral displacement, is inherent in any transparency which is tilted with respect to the line of sight. The effect of lateral displacement is constant over distance, and seldom exceeds a fraction of an inch. The second parameter, angular deviation, is usually caused by a wedginess or nonparallelism of the transparency surfaces. The effect of angular deviation is related to the tangent of the angle of deviation, thus the magnitude of the image position displacement increases as does the distance between image and transparency. The quantification of angular deviation is then the more critical of the two parameters. Both parameters are illustrated in Fig. X1.1.
SCOPE
1.1 This test method covers measuring the angular deviation of a light ray imposed by transparent parts such as aircraft windscreens and canopies. The results are uncontaminated by the effects of lateral displacement, and it is possible to perform the procedure in a relatively short optical path length. This is not intended as a referee standard. It is one convenient method for measuring angular deviations through transparent windows.  
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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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Standard Practice for Optical Distortion and Deviation of Transparent Parts Using the Double-Exposure Method

SIGNIFICANCE AND USE
5.1 Transparent parts, such as aircraft windshields and windows, can be inspected using this practice, and the amount of optical distortion or deviation can be measured. The measurement shall be checked for acceptability against the specification for the part. The photograph (digital file, print, or negative) shall be maintained as a permanent record of the optical quality of the part.
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Standard Practice for Ultrasonic Testing of Flat Panel Composites and Sandwich Core Materials Used in Aerospace Applications

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FIG. 1 Test Procedure A, Example Pulse Echo Apparatus Set-ups  
1.3.2 Test Procedure B, Through Transmission,  is a combination of two transducers. One transmits a longitudinal wave and the other receives the longitudinal wave in the range of 0.5 MHz to 20 MHz (see Fig. 2 for an example set-up using squirters). This procedure requires access to both sides of the specimen. This procedure is automated and the examination results are recorded.
FIG. 2 Test Procedure B, Through Transmission Apparatus Set-up Using Squirters  
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1.10 The user of this standard should not assume regulators’ endorsement of this standard as accepted mean of compliance.  
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ASTM F2156-17(2022)(Test Method)
Standard Test Method for Measuring Optical Distortion in Transparent Parts Using Grid Line Slope

SIGNIFICANCE AND USE
5.1 Transparent parts, such as aircraft windshields, canopies, cabin windows, and visors, shall be measured for compliance with optical distortion specifications using this test method. This test method is suitable for assessing optical distortion of transparent parts as it relates to the visual perception of distortion. It is not suitable for assessing distortion as it relates to pure angular deviation of light as it passes through the part. Either Test Method F801 or Practice F733 is appropriate and shall be used for this latter application. This test method is not recommended for raw material.
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1.2 This test method covers the apparatus and procedures that are suitable for measuring the grid line slope (GLS) of transparent parts, including those that are small or large, thin or thick, flat or curved, or already installed. This test method is not recommended for raw material.  
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1.3.1 Exception—The values given in parentheses are for information only.  
1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
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ASTM F801-21(Test Method)
Standard Test Method for Measuring Optical Angular Deviation of Transparent Parts

SIGNIFICANCE AND USE
5.1 One of the measures of optical quality of a transparent part is its angular deviation. It is possible that excessive angular deviation, or variations in angular deviation throughout the part, will result in visible distortion of scenes viewed through the part. Angular deviation, its detection, and quantification are of extreme importance in the area of certain aircraft transparency applications, that is, aircraft equipped with Heads-up Displays (HUD). It is possible that HUDs will require stringent control over the optics of the portion of the transparency (windscreen or canopy) which lies between the HUD combining glass and the external environment. Military aircraft equipped with HUDs or similar devices require precise knowledge of the effects of the windscreen or canopy on image position in order to maintain weapons aiming accuracy.  
5.2 Two optical parameters have the effect of changing image position. The first, lateral displacement, is inherent in any transparency which is tilted with respect to the line of sight. The effect of lateral displacement is constant over distance, and seldom exceeds a fraction of an inch. The second parameter, angular deviation, is usually caused by a wedginess or nonparallelism of the transparency surfaces. The effect of angular deviation is related to the tangent of the angle of deviation, thus the magnitude of the image position displacement increases as does the distance between image and transparency. The quantification of angular deviation is then the more critical of the two parameters. Both parameters are illustrated in Fig. X1.1.
SCOPE
1.1 This test method covers measuring the angular deviation of a light ray imposed by transparent parts such as aircraft windscreens and canopies. The results are uncontaminated by the effects of lateral displacement, and it is possible to perform the procedure in a relatively short optical path length. This is not intended as a referee standard. It is one convenient method for measuring angular deviations through transparent windows.  
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 E2582-21(Practice)
Standard Practice for Infrared Flash Thermography of Composite Panels and Repair Patches Used in Aerospace Applications

SIGNIFICANCE AND USE
5.1 Typically, FT is used to identify flaws that occur in the manufacture of composite structures, or to identify and track flaws that develop during the service lifetime of the structure. Flaws detected with FT include delamination, disbonds, voids, inclusions, foreign object debris, porosity, or the presence of fluid that is in contact with the backside of the inspection surface. For example, the effect of variable ply number (or thickness), bridging, and an insert simulating delamination on heat flow into a composite is shown in Fig. 1 (left). Bridging (Fig. 1, right) or delaminated areas show up as hot spots due to discontinuous heat flow, causing heating to be localized close to the inspection surface. With dedicated signal processing and the use of representative test samples, characterization of flaw depth and size, or measurement of component thickness and thermal diffusivity, may be performed.
FIG. 1 Variation of Heat Flow Into a Composite With Variable Ply Thickness (Scenarios 1, 3, and 4), Bridging (Scenario 2) And an Insert (Scenario 5) (Left), And a Post Layup Line Scan Showing Bright Spots Attributed to Bridging (Right) (Courtesy of NASA Langley Research Center)  
5.2 Since FT is based on the diffusion of thermal energy from the inspection surface of the specimen to the opposing surface (or the depth plane of interest), the practice requires that data acquisition allows sufficient time for this process to occur, and that at the completion of the acquisition process, the radiated surface temperature signal collected by the IR camera is strong enough to be distinguished from spurious IR contributions from background sources or system noise.  
5.3 This method is based on accurate detection of changes in the emitted IR energy emanating from the inspection surface during the cooling process. As the emissivity of the inspection surface falls below that of an ideal blackbody (blackbody emissivity = 1), the signal detected by the IR camera may include comp...
SCOPE
1.1 This practice describes a procedure for detecting subsurface flaws in composite panels and repair patches using Flash Thermography (FT), in which an infrared (IR) camera is used to detect anomalous cooling behavior of a sample surface after it has been heated with a spatially uniform light pulse from a flash lamp array.  
1.2 This practice describes established FT test methods that are currently used by industry, and have demonstrated utility in quality assurance of composite structures during post-manufacturing and in-service examinations.  
1.3 This practice has utility for testing of polymer composite panels and repair patches containing, but not limited to, bismaleimide, epoxy, phenolic, poly(amide imide), polybenzimidazole, polyester (thermosetting and thermoplastic), poly(ether ether ketone), poly(ether imide), polyimide (thermosetting and thermoplastic), poly(phenylene sulfide), or polysulfone matrices; and alumina, aramid, boron, carbon, glass, quartz, or silicon carbide fibers. Typical as-fabricated geometries include uniaxial, cross ply, and angle ply laminates; as well as honeycomb core sandwich core materials.  
1.4 This practice has utility for testing of ceramic matrix composite panels containing, but not limited to, silicon carbide, silicon nitride, and carbon matrix and fibers.  
1.5 This practice applies to polymer or ceramic matrix composite structures with inspection surfaces that are sufficiently optically opaque to absorb incident light, and that have sufficient emissivity to allow monitoring of the surface temperature with an IR camera. Excessively thick samples, or samples with low thermal diffusivities, require long acquisition periods and yield weak signals approaching background and noise levels, and may be impractical for this technique.  
1.6 This practice applies to detection of flaws in a composite panel or repair patch, or at the bonded interface between the panel and a supporting ...

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ASTM
ASTM F3498-21(Practice)
Standard Practice for Developing Simplified Fatigue Load Spectra

SIGNIFICANCE AND USE
4.1 This standard practice provides one means for determining fatigue load spectra for aeroplane durability assessments. This information can be used in conjunction with Specification F3115/F3115M, Section 5, Load Considerations.  
4.1.1 Users of this practice may propose alternate spectra, subject to the approval of their CAA.  
4.2 The methods are applicable to the durability evaluation of wings of small aeroplanes. Additional calculation (such as methods noted in ACE-100-01) are needed to properly develop load spectra for fatigue evaluation of empennage and/or configurations with canards (or forward wings) and/or winglets (or tip fins), fuselage, and potentially other components, with approval from appropriate regulatory agency.  
4.3 Much of the material presented herein is directly taken from AC 23-13A. The FAA developed the flight load spectra, presented herein, based on a statistical analysis of the data presented in DOT/FAA/CT-91/20. The ground load spectra are directly from AFS-120-73-2.  
4.4 The flight load spectra, presented in Section 7, includes an adjustment (1.5 standard deviations) to the average measured load frequency. The adjustment accounts for the variability in the loading spectra experienced by individual aeroplanes, as well as across aeroplane types. The magnitude of the adjustment was selected to maintain the probability that a component will reach its safe-life without a detectable fatigue crack established by scatter factor (see paragraph 2–15 of AC 23-13A).
SCOPE
1.1 This practice provides data to develop simplified loading spectra that can be used to perform structural durability analysis for aeroplanes, specifically for wings of small aeroplanes. The material was developed through open consensus of international experts in general aviation. The information was created by focusing on Level 1, 2, 3, and 4 Normal Category aeroplanes. The content may be more broadly applicable; it is the responsibility of the applicant to substantiate broader applicability as a specific means of compliance.  
1.2 An applicant intending to propose this information as Means of Compliance for a design approval must seek guidance from their respective oversight authority (for example, published guidance from applicable civil aviation authorities, or CAAs) concerning the acceptable use and application thereof. For information on which oversight authorities have accepted this standard (whole or in part) as an acceptable Means of Compliance to their regulatory requirements (hereinafter “the Rules”), refer to the ASTM Committee F44 web page (www.astm.org/COMMITTEE/F44.htm).  
1.3 The values stated in inch-pound units are to be regarded as standard. No other units of measurement are included in this standard.  
1.4 This standard 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.  
1.5 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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