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User:Dan Polansky/Corrective lens

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Aspheric lens

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Aspheric lens are allegedly thinner than spheric ones; to be verified.

Aspheric lens reduce distortion at the edges of the lens as compared to spheric ones; to be verified.

Do aspheric lens increase chromatic aberration as compared to spheric ones? An editor seems to think so:

See also:

Chromatic aberration

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High-index lens tend to have higher chromatic aberration AKA color distortion. This directly depends on the Abbe number, listed in #Ophthalmic material property tables; the higher the Abbe number, the lower the distortion.

See also:

Links:

Weight

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The effectively lightest material for corrective lens for glasses for many combinations of prescription and diameter seems to be Trivex. The weight of a lens depends on two factors: the volume of the lens and the density of the used material. Hi-index materials provide lower volume of a lens, albeit often at the cost of higher density. Trivex leading to lightest lens follows from Materials for spectacle lenses by Mo Jalie; verify for yourself; danger of error on my part. There, by combining the data from Table 2, Table 3, Table 4, and Table 5, lens made from Trivex appear to be the lightest for diameter 40 and 50; Trivex is represented in table 2 in row 4, starting with "1.532 / 1.10"; for diameter 60, material "1.74 / 1.4" comes out the same as Trivex: 10.2 g; for diameter 70, materials represented as "1.710 / 1.4" and "1.74 / 1.4" outperform Trivex in weight by a narrow margin (Trives: 17.8 g vs. "1.710 / 1.4": 17.7 g vs. "1.74 / 1.4" 17.1 g). These tables are for -5.00D lenses; with higher-prescription lens and high diameter, other materials may outperform Trivex as for weight.

Ideally, one should be able to determine the weight from the index, density, center thickness, prescription, and the diameter using a formula; I am unable to do that.

The characteristics in Table 2, Table 3, Table 4, and Table 5 of Mo Jalie are as follows:

  • nd - index AKA refractive index
  • D - density (g/cm3)
  • ct - center thickness (mm)
  • et - edge thickness (mm)
  • wt - weight (g)
  • diameter - diameter of the lens (mm)

Trivex is marketed by HOYA under the Phoenix brand (PNX)[1], by Younger Optics under Trilogy brand[2][3], by Augen Optics[4] and by X-Cel Optical[5].

Frame weight: The weight of the lens is one of the two components of the overall weight of glasses. Glasses can be made as light as possible by minimizing both lens weight and frame weight. Frame weight can be minimized by using rimless frame made from titanium; the choice involved is the one of (a) rimless frame and (b) titanium rather than steel. While the density of steel usually ranges between 7.75 and 8.05 g/cm3 (as per Steel), the density of titanium is 4.506 g/cm3 (as per Titanium), making the same-volume titanium frames up to 1.78 times lighter. It would have to be clarified whether titanium frames really are being made of the same volume as steel ones. Moreover, titanium rimless frames seem to be made from titanium alloys, so the density of the alloy would have to be considered instead of the density of titanium alone.

Ophthalmic material property tables

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The following originates from Glasses#Ophthalmic material property tables. It can be in part confirmed in the following sources:

Material, Plastic Index (Nd) Abbe (Vd) Density (g/cm3) UVB/ UVA Reflected light (%) Note
CR-39 Hard Resin 1.49 59 1.31 100% / 90% 7.97
PPG Trivex (Average) 1.53 44 1.11 100% / 100% 8.70 PPG, Augen, HOYA, Thai Optical, X-cel, Younger
SOLA Spectralite 1.54 47 1.21 100% / 98% 8.96 (also Vision 3456 (Kodak)?)
Essilor Ormex 1.56 37 1.23 100% / 100% 9.52
Polycarbonate 1.586 30 1.20 100% / 100% 10.27 Tegra (Vision-Ease) Airwear (Essilor) FeatherWates (LensCrafters)
MR-8 1.6 Plastic 1.6 [1] 41 1.30 100% / 100% 10.43
MR-6 1.6 Plastic 1.6 36 1.34 100% / 100% 10.57
MR-20 1.6 Plastic 1.60 42 1.30 100% / 100%
SOLA Finalite 1.60 42 1.22 100% / 100% 10.65
MR-7 1.67 Plastic 1.67 [1] 32 1.35 100% / 100% 12.26
MR-10 1.67 Plastic 1.67 [1] 32 1.37 100% / 100% 12.34
Nikon 4 Plastic NL4 1.67 32 1.35 100% / 100%
Hoya EYRY 1.70 36 1.41 100% / 100% 13.44
MR-174 1.74 Plastic 1.74 [1] 33 1.47 100% / 100% 14.36 Hyperindex 174 (Optima)
Nikon 5 Plastic NL5 1.74 33 1.46 100% / 100%
Tokai 1.76 30 1.49 100% / 100%
Material, Glass Index (Nd) ABBE (Vd) Density UVB/ UVA Reflected light (%) Note
Crown Glass 1.525 59 2.54 79% / 20% 8.59
PhotoGray Extra 1.523 57 2.41 100% / 97% 8.59
1.6 Glass 1.604 40 2.62 100% / 61% 10.68 Zeiss Uropal, VisionEase, X-Cel
1.7 Glass 1.706 30 2.93 100% / 76% 13.47 Zeiss Tital, X-Cel, VisionEase, Phillips
1.8 Glass 1.800 25 3.37 100% / 81% 16.47 Zeiss Tital, X-Cell, Phillips, VisionEase,Zhong Chuan Optical(China)
1.9 Glass 1.893 31 4.02 100% / 76% 18.85 Zeiss Lantal, Zhong Chuan Optical(China)
not FDA-approved for sale in USA

See also

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References

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  1. ^ a b c d "MR™ Series | Mitsui Chemicals". Mitsuichem.com. Retrieved 2014-05-03.