Description of Terminology

Refractive Index

The refractive index is the most critical element in the process of producing slim lenses. Light refraction refers to changes in the direction of movement of light caused by boundary surfaces of different media.

The refractive index is a value unique to a certain material and is used to indicate the degree to which the material in question is capable of refracting light.
Therefore, the greater the refractive index of a material used, the thinner the resulting lens of identical power will be. Currently available plastic lenses have been developed with a refractive index of up to 1.49 - 1.74.

Specific Gravity

The term "specific gravity of a substance" refers to the ratio of "the mass of the substance in question" to "the mass of a standard substance of the same volume." Normally, water of a temperature of 4 degrees Celsius is used as the standard substance.
Since lenses become lighter the lower the specific gravity value, lenses with a low specific gravity tend to have a low refractive index, and, in some cases, this necessitates thickening of the lens, resulting in increased lens weight.

Abbe Value

It is common knowledge that light from the sun (white light) comprises a mixture of various colors, and when this light passes through a spot in the lens with a prism effect, it divides into spectra (in wavelength sequence from red to blue) as shown in Fig. 2. This phenomenon is referred to as "light dispersion" and gives rise to the problem of chromatic aberration in a lens. Abbe's number is a value that shows the degree of light dispersion: The smaller the value of Abbe's number, the greater the degree of chromatic aberration, the greater the value, the lower the degree of chromatic aberration.
When chromatic aberration occurs, the object viewed becomes colored and appears blurred. Taking the prism on the lens to be P (Δ) and the Abbe's value of the lens material to be v, the amount of chromatic aberration Pc is derived from the equation Pc = P/v, as shown in Fig. 3, and, while there are differences depending on the individual, normally, eyesight deteriorates when the Pc value is greater than 0.2.

Progressive Power Corridor

Progressive lenses comprise of a "long-sight portion" for viewing objects in the distance and a "near-sight portion" for viewing objects at close quarters and these two are divided by a "progressive power portion" that progressively changes the strength of the lens. The progressive power corridor is the length from the bottom edge of the long-sight portion to the top edge of the near-sight portion. Therefore, normally, progressive lenses enable the wearer to view objects in the distance by raising the eyes a little and objects nearby by lowering the eyes slightly. While a short power corridor reduces the degree by which eyes need to be lowered to view objects nearby, providing a wider range of close vision, the shorter the progressive power corridor, the greater the degree of distortion, known as astigmatism, at the sides, resulting in discomfort for the wearer. Although this depends on factors such as the application the wearer requires and becoming accustomed to the spectacles, the usual progressive power corridor length is approximately 14 mm for habitual, daily use.

Aspheric Design

The strength of an aspheric design lens is determined by the combination of its front and back surface curvatures.
Although, previously, both front and back surface curvatures featured spherical design, thanks to advances in technology, "aspheric design lenses" with an "aspheric" front surface, have become the mainstream type. This type of lens offers the advantage of being able to produce a thin, lightweight lens.

Double-sided Aspheric Design

Seiko succeeded in realizing the world's first "Double-sided Aspheric design" that features aspheric design on both the front and back surfaces.
The result is the achievement of a lens that is even thinner and lighter.
We hope that you will discover for yourself the wonderful comfort of Seiko spectacles.

Progressive Lens

Basically, refractive correction of presbyopia requires two pairs of spectacles, one for viewing objects in the distance and one for viewing objects nearby, but constantly having to change from one pair of spectacles to the other is irksome. To solve this problem, the multifocal lens that enables the wearer to view objects in the distance and at close range with a single pair of spectacles was developed. The simplest form of multifocal lens if the bifocal lens, known as the EX type, that features a lens for distance viewing and a lens for near viewing joined at the middle to form a single lens. In addition, trifocal lens are also available that enable the wearer to see not only objects nearby and in the distance, but also in the intermediate distance. Addition of finer gradations in the segment for intermediate distance vision results in a lens capable of graded variation from the long-sight lens strength to the near-sight lens strength. This is the basic concept of the progressive lens.

The greatest advantage of the progressive lens is its superbly fashionable appearance due the absence of the conspicuous boundary line seen in the bifocal lens. In addition, the intermediate portion enables non-graduated changes in the lens strength, making this an outstanding lens that allows the user to focus on objects at any distance from close to long range. There are, however, some drawbacks. Because multiple strengths are incorporated into a single lens, objects in the lateral domain may appear blurred and shaking the head from side to side may give the wearer a swaying sensation. Moreover, objects may appear hazy. Mitigation of such drawbacks is dependent on progressive lens standards.