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ISO 13406-2
ISO 13406-2
ISO 13406-2
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ISO 13406-2 is an ISO standard, with the full title "Ergonomic requirements for work with visual displays based on flat panels -- Part 2: Ergonomic requirements for flat panel displays". It is best known to end consumers for defining a series of flat-panel display "classes" with different numbers of permitted defects (or "dead pixels"). ISO 13406-2 also provides a classification of Viewing Direction Range Classes and Reflection Classes.

As part of an ISO standard, the classes are guidelines, and not mandatory. Where implemented, the interpretation of the standard by the panel or end product manufacturer and effects in terms of labeling of products, what class of panel is used, etc., can vary. Most flat-panel makers use this standard as the excuse for not accepting returns of defective flat-panels. Many customers argue that it is not honest in the makers' part to sell a product that most people would not accept if they knew it had these defects. Also, there is little offer of Class I panels, that added to the fact that the price of these models is usually very high, make it difficult to buy a totally guaranteed product. One solution to this problem would be to sell these defected panels at a lower price than normal ones, clearly indicating the presence of such defects.

The ISO 13406-2:2001 standard has been withdrawn and revised by the ISO 9241-302, 303, 305 and 307:2008 standards.

Pixel Fault Classes

[edit]

The standard lists four classes of devices, where a device of a specified class may contain a certain maximum number of defective pixels. Three distinct types of defective pixels are described:

  • Type 1 = a hot pixel (always on, being colour white)
  • Type 2 = a dead pixel (always off, meaning black)
  • Type 3 = a stuck pixel (one or more sub-pixels (red, blue or green) are always on or always off)

The table below shows the maximum number of allowed defects (per type) per 1 million pixels.

Definition of Pixel Fault Classes – Maximum number of faults per million pixels
Class Type 1 Type 2 Type 3 Cluster with more than one type 1 or type 2 faults Cluster of type 3 faults
I 0 0 0 0 0
II 2 2 5 0 2
III 5 15 50 0 5
IV 50 150 500 5 50

As of 2007, most manufacturers specify their products as Pixel Fault Class II.[1]

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

ISO 13406-2

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ISO 13406-2:2001 is an international standard that establishes ergonomic requirements for the image quality of flat panel displays used in office work environments, focusing on aspects such as legibility, comfort, and visual performance to support human-system interaction. Developed by ISO Technical Committee 159, Subcommittee 4 on ergonomics of human-system interaction, the standard extends principles from ISO 9241 by addressing unique characteristics of flat panel technologies, including ambient light effects and reflections. It defines key terms, specifies assessment methods, and applies to displays with regular pixel arrays capable of rendering at least 40 Latin-origin characters, excluding projection or segmented fixed-message types. Key requirements include minimum luminance contrast ratios, uniformity of luminance across the screen, and limits on reflections to ensure readability under typical office lighting. A central element is the classification of pixel faults into four classes based on severity and density: Class I permits no defective pixels; Class II allows up to two always-lit (Type 1) pixels, two always-unlit (Type 2) pixels, five other abnormal pixels or subpixels (Type 3), and two Type 3 fault clusters per million pixels; Class III allows up to five Type 1, fifteen Type 2, fifty Type 3, and five Type 3 fault clusters per million pixels; Class IV allows up to fifty Type 1, one hundred fifty Type 2, five hundred Type 3, five Type 1 or 2 fault clusters, and fifty Type 3 fault clusters per million pixels. These classes guide manufacturers in categorizing display quality, with Class I representing the highest standard for fault-free performance. Published in December 2001, was withdrawn following its integration into the broader series on ergonomics of human-system interaction, specifically replacing elements in ISO 9241-302 (terminology), ISO 9241-303 (visual display requirements), ISO 9241-305 (optical characteristics), and ISO 9241-307 (display requirements for general viewing conditions). Despite its withdrawal, it remains influential in legacy discussions of display defect policies and ergonomic design for visual displays.

Overview

Scope and Purpose

ISO 13406-2, titled "Ergonomic requirements for work with visual displays based on flat panels — Part 2: Ergonomic requirements for flat panel displays," was published in 2001 by the (ISO). It was developed by Technical Committee ISO/TC 159, , Subcommittee SC 4, Ergonomics of human-system interaction. The standard's primary purpose is to establish minimum ergonomic requirements for image quality in flat panel displays, such as displays (LCDs), used in tasks. It addresses key differences from cathode ray tube (CRT) displays covered in the earlier series by focusing on visual ergonomics specific to flat panels, including legibility, comfort, and acceptability during prolonged use. The scope of ISO 13406-2 applies to both monochrome and color flat panel displays with integral screens intended for office environments, with a design viewing distance specified by the supplier and subject to ergonomic constraints. It covers displays with regular pixel arrays capable of rendering at least 40 Latin-origin characters, supporting alphabets such as Latin, Cyrillic, Greek, Arabic numerals, and Asian characters. The standard specifies methods for conformity assessment, including image quality evaluation, and excludes projection displays, fixed-message or segmented alphanumeric displays, and non-office applications. Certain measurements, like contrast and luminance, are not applicable to reflective flat panels. By defining criteria for visibility, legibility, and aspects like pixel faults, the standard promotes ergonomic benefits such as reduced , minimized visual fatigue, and fewer user errors in office settings. These requirements, grounded in visual ergonomic research, enhance overall user comfort and task performance for extended interactions with flat panel displays.

Key Concepts and Definitions

ISO 13406-2 provides precise definitions for core components of flat panel displays to ensure consistent application in ergonomic assessments. A subpixel is defined as a separately addressed internal structure within a pixel that extends its functional capabilities, such as primary color subpixels (e.g., red, green, blue in an RGB configuration) or multiple-size subpixels used for grayscale effects. A pixel, in contrast, represents the smallest addressable unit on the display that forms a single color point, typically comprising a group of subpixels to produce the intended hue. These elements are fundamental to flat panel displays, which encompass both non-emissive technologies like liquid crystal displays (LCDs) and emissive ones such as plasma displays, designed for use in visual display units (VDUs). Ergonomic considerations in the standard extend to terms related to user interaction and performance. A visual display terminal (VDT) refers to office workstation equipment incorporating a flat panel display for human-system interaction, aligning with broader ergonomic principles for workplace environments. Image quality is characterized as the integrated attributes of , color reproduction, resolution, and fault-free rendering, ensuring displays meet user comfort and productivity needs in office settings. Fault-related terminology addresses display imperfections systematically. A pixel fault denotes the anomalous behavior of a or subpixel, encompassing local defects that deviate from normal operation. Clustered faults are specified as two or more faulty s or subpixels occurring within a 5 × 5 block, where such groupings are treated as a single fault for evaluation purposes to reflect their compounded visual impact. Viewing conditions are defined to simulate typical use, influencing how display performance is assessed. Ambient illuminance is considered up to 300 , representing standard indoor lighting levels that affect screen visibility and . The viewing distance is the design viewing distance specified by the supplier, subject to ergonomic constraints (minimum 0.4 m), with an example of 500 mm provided in the standard. These parameters support the standard's application to office ergonomics by establishing baseline environmental factors for display evaluation.

Technical Specifications

Image Quality Requirements

ISO 13406-2 establishes quantitative ergonomic criteria for the overall image quality of flat panel displays used in environments, focusing on photometry, , and other performance parameters to promote , visual comfort, and reduced during prolonged use. These requirements exclude pixel-specific defects and are divided into three compliance classes—I (highest quality, for critical viewing tasks), II (moderate quality, ), and III (basic quality, for less demanding applications)—allowing manufacturers to select appropriate thresholds based on intended use. In terms of photometry, the standard specifies minimum levels to ensure sufficient for under typical lighting: 120 cd/m² for Class I, 100 cd/m² for Class II, and 70 cd/m² for Class III, measured at the design viewing direction using full-screen white patterns. uniformity must be at least 80% across the display surface (i.e., variation no greater than 20%), assessed by comparing at multiple points such as the center and edges, to prevent distracting gradients. Additionally, the minimum is set at 3:1 for Class I and II, evaluated with area-based targets to simulate real content without pixel-level influences. Colorimetry requirements emphasize consistent color reproduction to maintain neutral visuals and minimize color-induced fatigue. While no specific color temperature is mandated, chromaticity uniformity is required with a maximum difference of 0.01 on the CIE 1976 u'v' diagram between measurement sites across the screen, ensuring even color distribution without shifts that could affect perception. The standard does not prescribe a minimum color gamut but prioritizes low color differences (e.g., ΔE*uv thresholds aligned with application needs) for accurate representation of standard color spaces like sRGB in office settings. Other parameters address additional aspects of display performance critical for ergonomic use. Resolution is conceptually tied to pixel density sufficient for legible text and , without numerical minima, focusing instead on overall sharpness for viewing distances of 50–80 cm. Flicker must be imperceptible to the , avoiding temporal modulation that causes discomfort, typically assessed through subjective observation or modulation depth below visible thresholds. Reflection and glare limits are controlled via a maximum luminance factor of 0.015 under diffuse illumination up to 500 lx, to reduce distracting reflections from overhead lights. All measurements are conducted under standardized conditions to ensure : at the nominal viewing distance and angle, with test patterns covering at least 10 pixels but less than 2% of the screen to represent area , in a controlled ambient of 200–500 lx from a diffuse source, and by observers or instruments positioned perpendicular to the display center. Compliance is verified against the selected class, with Class II serving as the default for most office monitors due to its balance of performance and manufacturability, permitting minor deviations while upholding essential ergonomic benefits.

Pixel Fault Classification

ISO 13406-2 defines a system for classifying pixel faults in flat panel displays to ensure ergonomic image quality suitable for office environments. Pixel faults are categorized into three primary types based on their behavior across display modes: Type 1 faults, also known as always-on or hot , appear as bright white spots in all and color states; Type 2 faults, or always-off/, remain black regardless of input; and Type 3 faults are abnormal pixels or subpixels, such as stuck subpixels fixed to one (, , or blue) in all states. These classifications focus on discrete defects that can distract users during prolonged viewing. The standard also addresses clustered faults, where two or more defective or subpixels occur within a 5 × 5 block; such clusters are treated as a single fault to account for manufacturing imperfections that may group defects. Subpixel faults are included within Type 3 assessments, recognizing that RGB subpixels can fail independently while still impacting overall image integrity. This approach allows for nuanced assessment, as subpixel defects may be less noticeable than full- ones but can still cause color inaccuracies. Pixel faults are grouped into three classes based on maximum allowable defects per million , enabling manufacturers to balance production yields with quality thresholds. Class I permits zero faults of any type, representing an ideal but rarely achievable standard for premium displays. Class II allows up to 2 Type 1 faults, 2 Type 2 faults, 5 Type 3 faults, and 2 clusters, suitable for general office use where minor defects are unlikely to impair readability. Class III accommodates higher tolerances—up to 5 Type 1, 5 Type 2, 15 Type 3, and 5 clusters—intended for less critical applications. These limits are calculated proportionally for the display's total count.
ClassType 1 (per million)Type 2 (per million)Type 3 (per million)Clusters (per million)
I0000
II2252
III55155
Detection of these faults requires under controlled conditions to simulate typical usage, including display of uniform full-field patterns in white, black, red, green, and blue at a of 100 cd/m², with the observer at a viewing of 50 cm in a darkened . This method ensures faults are identifiable without specialized equipment, emphasizing human perception over automated measurement. The classification system in ISO 13406-2 aims to reconcile practical realities—where zero-defect yields are economically challenging—with ergonomic imperatives, minimizing visible distractions that could lead to or reduced in professional settings. By setting graduated classes, the standard supports a range of display applications while promoting consistent assessment across the industry.

Implementation and Impact

Industry Adoption

The adoption of ISO 13406-2 significantly shaped warranty practices among major display manufacturers, with many establishing Class II as the baseline for acceptable pixel faults in standard products. For instance, conformed to the standard's Class II limits for dead or missing s in LCD monitors, allowing up to a specified number of defects depending on panel size while providing replacements only for exceedances. However, for premium offerings, vendors often implemented stricter policies exceeding the standard; introduced a zero dead guarantee for TFT panels sold in starting in 2005, surpassing Class II requirements to enhance consumer satisfaction. Similarly, defined warranty thresholds based on sub-pixel defects in LCD monitors, treating small numbers of bright or dark sub-pixels as non-functional impacts unless thresholds were exceeded, though without explicit reference to the ISO standard. In , the standard became integral to production testing protocols for LCD panels, enabling manufacturers to reject units surpassing defined fault limits and thereby supporting defect classification during assembly. This application facilitated automated inspections and uniformity measurements, as outlined in the standard's and fault guidelines, which helped standardize evaluation methods across facilities. Post-2001, following the standard's publication, these practices contributed to broader improvements in LCD yields by emphasizing ergonomic quality criteria that reduced variability in defect rates and lowered overall production costs through better process controls. The standard influenced consumer expectations by establishing clear thresholds for "acceptable" defects, framing minor faults as inherent to LCD rather than warranting returns in most cases. This helped normalize up to the Class II limits—such as a few dead or stuck sub-—across product classes, thereby reducing unnecessary return rates for panels meeting the criteria and streamlining support processes for retailers and manufacturers. Challenges arose from interpretive variability, particularly in distinguishing sub-pixel faults from full pixel defects, as the standard defines types like permanently on/off sub-pixels separately from clustered faults, leading to inconsistencies in how vendors applied thresholds. In the early 2000s, this ambiguity fueled consumer disputes over "dead pixels," with some manufacturers refusing replacements for isolated sub-pixel issues deemed compliant, prompting widespread frustration and calls for stricter accountability. Globally, ISO 13406-2 saw widespread application in the production and specification of PC monitors, laptop displays, and televisions, serving as a benchmark for ergonomic in consumer active-matrix LCDs until its eventual supersession. Its fault classification guidelines were routinely referenced in device certifications and warranties across these categories, promoting consistent expectations in markets from to . ISO 13406-2 extends the ergonomic requirements outlined in the series from the 1990s, which primarily addressed cathode ray tube (CRT) displays, by incorporating provisions for flat panel technologies that account for distinct issues such as discrete and uniformity not applicable to analog CRT systems. While parts like 9241-3 focused on visual display requirements for CRTs, including character height and flicker, ISO 13406-2 adapts these to the fixed-grid nature of flat panels, emphasizing measurable image quality metrics tailored to digital matrix displays. In relation to ISO 13406-1, which establishes general ergonomic guidelines for visual display terminals (VDTs) encompassing hardware like input devices and environmental factors such as furniture layout, ISO 13406-2 specifically targets the of flat panel displays without overlapping into those broader workstation elements. This complementary focus allows ISO 13406-2 to delve into display-specific attributes like resolution and contrast, building on the foundational definitions in Part 1 for consistent application across VDT technologies. Compared to early standards from the Video Electronics Standards Association (VESA), such as the Flat Panel Display Measurements (FPDM) standard, ISO 13406-2 prioritizes human-centered ergonomics over VESA's emphasis on electrical interfaces, timing signals, and automated measurement protocols for display hardware integration. VESA FPDM provides tools for quantifying parameters like response time and power consumption to support manufacturing and interoperability, whereas ISO 13406-2 evaluates usability impacts on viewers, such as visual comfort during prolonged office tasks. A primary differentiator of ISO 13406-2 lies in its pixel fault classification system, developed specifically for matrix-addressed displays like displays (LCDs), which features discrete sub-pixel elements unlike the continuous scanning in CRT defect models. These classes define allowable defects—such as Type 1 (permanently lit pixels), Type 2 (permanently dark pixels), and Type 3 (stuck sub-pixels)—based on their visibility and clustering within the matrix grid, enabling standardized assessment absent in CRT-focused norms. ISO 13406-2 influenced the evolution of the series by providing core concepts for flat panel ergonomics that informed more granular specifications in subsequent parts, including ISO 9241-307 on pixel defects and ISO 9241-303 on optical characteristics. This foundational role facilitated the integration of flat panel requirements into the broader human-system interaction framework, leading to the eventual supersession and refinement of ISO 13406-2 within the updated 9241 structure.

History and Status

Development and Publication

The development of ISO 13406-2 was initiated in the late 1990s by Technical Committee ISO/TC 159 (), Subcommittee SC 4 (Ergonomics of human-system interaction), in response to the growing adoption of flat panel displays for office and professional use. This effort built on earlier ergonomic standards for cathode-ray tube (CRT) displays, such as ISO 9241 parts 3, 7, and 8, but addressed the unique characteristics of emerging (LCD) technologies. Ergonomic research during this period revealed that flat panel displays reduced issues like flicker and geometric distortion common in CRTs, but introduced new concerns including pixel defects, luminance uniformity variations, and color reproduction challenges that could affect user comfort and productivity. These findings motivated the subcommittee to establish specific image quality requirements tailored to flat panels, drawing from studies on visual performance and acceptability in prolonged viewing scenarios. International experts in and display technology contributed to the drafting process, with notable input from specialists in —where LCD manufacturing was rapidly expanding—and European organizations focused on human-system interaction standards. The first draft aligned with the publication of ISO 13406-1 in 1999, which provided foundational definitions, while the final version of part 2 was completed after iterative reviews by the subcommittee. ISO 13406-2:2001 was officially published in December 2001 as a 147-page document, available in English and French editions through the ISO store for purchase. Upon release, the standard received positive initial reception for filling a critical gap in ergonomic guidelines amid the industry-wide shift from bulky CRTs to compact flat panels, promoting higher display quality and user well-being. It was swiftly incorporated into national and regional frameworks, including the European Norm EN ISO 13406-2:2001, facilitating consistent application across member states.

Withdrawal and Supersession

ISO 13406-2 was officially withdrawn by the (ISO) on November 14, 2008, and remains marked as withdrawn in the ISO catalog as of 2025. The withdrawal occurred to accommodate advances in display technology and science, which had outpaced the 2001 specifications originally tailored primarily to (LCD) panels; the update extended coverage to a broader range of electronic visual displays, including emerging technologies beyond LCDs such as organic light-emitting diodes (OLEDs), while incorporating higher resolutions and more diverse usage environments. This shift also aligned with the need for modular, updatable requirements within the series on of human-system interaction, allowing for targeted revisions rather than overhauling a standalone standard. The content of ISO 13406-2 was integrated into several parts of the series published in 2008, specifically ISO 9241-302 (terminology for electronic visual displays), ISO 9241-303 (requirements for electronic visual displays), ISO 9241-305 (optical measurements for electronic visual displays), and ISO 9241-307 (general quality requirements for electronic visual displays). Pixel fault classification, a key aspect of the original standard, was revised and relocated to ISO 9241-302 with stricter criteria, including weighted sensitivity units for subpixel faults (e.g., bright subpixels deemed more perceptible than dark ones) and reduced allowable defect counts per class compared to ISO 13406-2. Following withdrawal, legacy applications of ISO 13406-2 persisted in manufacturer warranties and quality assurances through the , even as compliance shifted to the newer standards, which expanded considerations to dynamic content rendering and higher ambient lighting conditions. Currently, ISO 13406-2 has no active amendments or revisions and is referenced only for historical context, not for ongoing compliance or certification purposes.

References

  1. https://www.iso.org/standard/25670.html
  2. https://cdn.standards.iteh.ai/samples/25670/71b1e867547e4851b751f8250f08cb95/ISO-13406-2-2001.pdf
  3. https://www.iso.org/obp/ui/#iso:std:iso:13406:-2:en
  4. https://www.iso.org/obp/ui#iso:std:iso:9241:-303:ed-1:en
  5. https://www.origo.hu/attached/20061207i13406e2.pdf
  6. https://www.scribd.com/document/254781954/ISO-13406-2
  7. https://www.compro.com.au/support/MAG_Pixel_Policy.pdf
  8. https://www.dguv.de/medien/ifa/en/pub/rep/pdf/reports2016/rep_indoor_air/chapter_7_3.pdf
  9. https://forums.whirlpool.net.au/archive/707858
  10. https://hardware.slashdot.org/story/05/01/01/1440201/samsung-announces-zero-dead-pixel-policy
  11. https://www.lg.com/content/dam/channel/wcms/ca_en/products/documents/LG%20LCD%20Monitor%20Pixel%20Policy.pdf
  12. https://agdisplays.com/services/zero-pixel-inspection
  13. https://www.westardisplaytechnologies.com/wp-content/uploads/FPD-Measurement-Standards.pdf
  14. https://fr.scribd.com/document/163420114/Dead-Pixels
  15. https://help.overclockers.co.uk/hc/en-gb/articles/23588435152413-Understanding-Our-Policy-on-Pixel-Errors-in-Monitors
  16. https://forums.overclockers.co.uk/threads/zero-dead-pixel-policies-iso-13406-2.17555499/
  17. https://www.nist.gov/document/no-11-pr-12-1-flat-panel-2011pdf
  18. https://www.iso.org/obp/ui/#iso:std:iso:13406:-1:en
  19. https://www.researchgate.net/publication/294133524_A_closer_look_at_flat-panel-display_measurement_standards_and_trends
  20. https://www.aapm.org/pubs/reports/or_03.pdf
  21. https://www.microgamma.com/tecnologia/iso_9241.php
  22. https://www.koreascience.kr/article/JAKO201433150756232.pdf
  23. https://ergo.human.cornell.edu/Pub/LCD_vs_CRT_AH.pdf
  24. https://www.baua.de/DE/Angebote/Publikationen/Berichte/F1846.pdf?__blob=publicationFile&v=7
  25. https://www.display-messtechnik.de/fileadmin/template/main/docs/usability-2006.pdf
  26. https://standards.iteh.ai/catalog/standards/cen/346aee7a-22c1-466a-9acf-622f79ee1937/en-iso-13406-2-2001
  27. https://www.iso.org/obp/ui/#iso:std:iso:9241:-302:en
  28. https://forums.overclockers.co.uk/threads/monitor-returns-policy.18884226/
  29. https://www.viewsonic.com/vsAssetFile/global/file/pdf/uk/lcd-pixel-policy.pdf
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