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Viewing direction

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Figure 1: Illustration of the variation of the direction of observation (i.e. viewing direction) across the area of the display.

When a display with non-vanishing size is seen by an observer, every point of the display area is seen from a different direction as illustrated in fig. 1. No two spots on the display are seen from the same direction. The larger the display is and the closer the observer is to the display the more the viewing direction varies over the surface area of the display.

Colloquially, the viewing direction is often called "viewing angle". This is a slobby expression which should be avoided, because the viewing direction is specified by two polar angles: the angle of inclination, θ (measured from the surface normal of the display) and the azimuth angle, Φ, measured in the plane of the display as shown in figure 3.

Figure 2: Illustration of the specification of the viewing direction by two polar angles: the angle of incliantion (measured from the surface normal of the display) and the azimuth angle, measured in the plane of the display.

In fig. 2, the eyeball represents the observer that is looking at a specific spot on the display which is identical to the origin of the polar coordinate system. The green arrow is the viewing direction (i.e. direction of observation). The viewing direction is specified by the angle of inclination, θ, measured from the surface normal of the display (blue vertical arrow) while the azimuth angle, Φ, is the angle that the projection of the viewing direction onto the surface of the display makes with the x-axis (red arrow). The projection of the viewing direction is shown here as the shadow of the green arrow. The azimuth angle Φ increases counterclockwise.

Viewing cone

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Figure 3: Illustration of the specification of the viewing direction by two polar angles: the angle of incliantion (measured from the surface normal of the display) and the azimut angle, measured in the plane of the display

The multitude of directions, from which a display can be seen without artefacts and distortions that would render its intended use impossible (e.g. computerized office work, television, entertainment) is called the viewing cone (even though its shape might be that of a generalized cone).

Figure 4: Illustration of the specification of the range of viewing directions (aka viewing cone) in a polar coordinate system. The pseudo-colors represent the value of a physical quantity (e.g. luminance) for each viewing direction.

The concept of the viewing cone has been introduced for the first time in the international standard ISO 13406-2:2001 "Ergonomic requirements for work with visual displays based on flat panels -- Part 2: Ergonomic requirements for flat panel displays". This standard provides a classification for computer monitors with LCDs according to the range of viewing directions that can safely be used for the intended task (here: office work) without "reduced visual performance". The classification is according to "Viewing Direction Range Classes" with the "range of viewing directions" being equivalent to the viewing cone.

ISO 13406-2 describes a complex procedure according to which the usable viewing cone can be evaluated from measurements of luminance and chromaticity versus direction of observation. ISO 13406-2 introduces 4 viewing direction range classes of which the first (class I) is a wide viewing cone for many simultaneous observers and the last (class IV) is a so called "privacy display" with a severely limited viewing cone.

Depending on the actual task to be performed with a certain display device (e.g. office work, entertainment, home theater. etc.) the requirements for the display are different. Compliance routes for different display applications can now be found in the successor standard ISO 9241-300.

Viewing directions are conveniently represented in a polar coordinate system with the angle of inclination, θ, being represented by the radial distance from the origin and the azimuth, Φ, increasing counterclockwise as shown in figure 4. In this coordinate system every point corresponds to one viewing direction. A viewing cone is thus defined by a locus (a closed line) in this coordinate system as indicated by the square and the ellipse in fig. 4.

If a viewing cone is specified by four directions only (e.g. in the horizontal and the vertical plane), it does not become clear if it is the reactangle or the elliptical cone according to fig. 4. In order to resolve this amibiguity, the viewing cone should be specified by at least 8 directions, located in the horizontal and vertical plane and in the two diagonal planes (Φ = 45° and 135°).

Each direction in the polar coordinate system of fig. 4 can be assigned a (scalar) physical quantity, e.g. luminance, contrast, etc.. This quantity can then be represented by lines of equal values (contour lines), by shades of gray or by pseudo-colors (as shown in fig. 4).

A viewing cone can be defined starting from a certain application and the related geometry of observation, from which a range of directions can be obtained that specify the viewing cone required for that task. Inside this viewing cone certain physical parameters that are related to the visual performance of the display device must remain within certain (task dependent) limits.

A viewing cone can also result from measurements (versus viewing direction) carried out with a certain display device under specified operating conditions. Then the viewing cone is obtained by limiting values of a visual quantity (e.g. contrast) which for a certain application is required to be above e.g. 10. Then the line for which the contrast equals 10 defines the viewing cone.

Recent experiments[1] have shown that the acceptable viewing cone is rather determined by decrease of luminance and change of chromaticity than by the decrease of contrast.

Luminance and Contrast versus Viewing Direction

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[[Image:Contrast-vs-Viewing-Direction.png|thumb|300px|right|Figure 5: Luminance and contrast versus viewing direction in a polar coordinate system. The left column shows the directional luminance distribution of the dark state of the display (IPS LCD), the center column shows the bright state and the right column shows the (luminance) contrast (ratio) resulting from the preceeding two luminance distributions. The value is coded by (pseudo) colors. The graphs below the polar coordinate systems each show a cross section in the horizontal plane and indicate the values for luminance and for the contrast. Each borderline between two (shades of) colors represents a line of constant value, in the case of contrast an iso-contrast (contour) line. Note, that "iso" is used in the sense of "equal", it does NOT establish a relation to the International Organisation for Standardisation, ISO.

Fig. 5 shows luminance and contrast versus viewing direction in a polar coordinate system. The left column shows the directional luminance distribution of the dark state of the display (here: IPS-LCD), the center column shows the bright state and the right column shows the (luminance) contrast (ratio) resulting from the preceeding two luminance distributions. The value is coded by (pseudo) colors. The graphs below the polar coordinate systems each show a cross section in the horizontal plane and indicate the values for luminance and for the contrast.

Each borderline between two (shades of) colors represents a line of constant value, in the case of contrast an iso-contrast (contour) line. Note, that "iso" is used here in the sense of "equal", it does NOT establish a relation to the International Organisation for Standardisation, ISO.

This way of representing the variation of a quantity of a display with direction of observation originates from an optical technique called conoscopy. Conoscopy, originally proposed and used by Maugin for examination of the state of liquid crystal alignment in 1911 [2] has been used in every LCD-laboratory in the late seventies and throughout the eighties for measurement and evaluation of the optical properties of LCDs and for measurement of LCD-contrast. In the conoscopic mode of observation, in the old days often realized with a polarizing microscope, a directions image is generated in the rear focal plane of the objective lens [3]. This directions images is based on the same coordinates as the representation in the polar coordinate system shown in figs. 4 and 5.

The first publication of the variation of the contrast of reflective LCDs measured with a (mechanically scanning) gonioscopic device and represented as a conoscopic directions figure was published in 1979 [4].

References

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  1. ^ K. Teunissen, et al.: "A perceptually based metric to characterize the viewing-angle range of matrix displays", JSID16/1(2008)27
  2. ^ Ch. Maugin: "Sur les cristaux liquides de Lehmann", Bull. Soc. Fran. Min. 34(1911)71)
  3. ^ More details on conoscopy are available "here".
  4. ^ "A new method for characterization and evaluation of the optical appearance of reflective TN-LCDs", Displays 1979, p. 12


  • ISO 13406-2:2000 "Ergonomic requirements for work with visual displays based on flat panels -- Part 2: Ergonomic requirements for flat panel displays."
  • ISO 9241-300: "Ergonomics of human-system interaction -- Part 300: Introduction to electronic visual display requirements." The ISO 9241-300 series establishes requirements for the ergonomic design of electronic visual displays. These requirements are stated as performance specifications, aimed at ensuring effective and comfortable viewing conditions for users with normal or adjusted-to-normal eyesight. Test methods and metrology, yielding conformance measurements and criteria, are provided for design evaluation. ISO 9241 is applicable to the visual ergonomics design of electronic visual displays for a diversity of tasks in a wide variety of work environments.


Category:Display_technology Category:Liquid_crystal_displays