Enhance dynamic visual perception while maintaining stable static vision,
thus making the wearer's field of view clearer and brighter.
Dynamic Aberration Optimize
Single Vision lenses inevitably produce aberrations due to their characteristics, which in turn lead to incomplete or unclear imaging and make it more difficult to meet the wearer's visual requirements when forming a gaze. Dynamic aberration optimize technology uses vector aberration theory for dynamic analysis of aberration on the basis of the mirror-eye imaging model, and corrects oblique image dispersion, refractive error and aberration in the near-axis range by accurately controlling the Seidel coefficients based on the ideal eye model.
On the basis of correcting static Saidel aberration, a dynamic optimize term for different distances and eye rotation angles is added, which significantly alleviates dynamic aberration, increases the clarity and comfort of dynamic vision, and solves the contradiction between the optimize of static aberration and the destruction of eye rotation patterns.
Dynamic Aberration modulation
The Free-Toric Cyl lens optimizing uses a free-ring design that enables subdividing each quadrant of the lens to optimize the zoning independently, thus reducing the axial superimposed interference of prescription astigmatism. By optimizing the curvature in the spherical and cylindrical directions, it provides more precise correction. Free-Aoric Cyl lens optimizing offers more efficient and flexible optimization possibilities than traditional Satoric designs, effectively reducing potential interference aberrations. The Seidel aberration is also calculated to compensate for the correction of off-axis optical aberration and oblique axial dispersion of the lens, and during the design process, a weight distribution function is set to further control and reduce regional interference on the surface of the single vision lens.
Dual Compound Technology
Dual is the maximum possible optimization of the lens design by means of a double-sided superimposition of the first and second surfaces of the lens in conjunction with each other, breaks through the limitations of the traditional laws of optical design as well as the limits of the processing range of the equipment. The result is an optimal balance between aesthetics, lightness and fashion, and the optic function and wearing comfort of the lens.
Benefits:
1. The technology has been widely applied to all age groups and types of lenses, achieving a more refined and comfortable visual experience for the wearer.
2. Smoother visual transitions are achieved, reducing the blurring and discomfort that can occur in areas of varying luminosity with traditional single vision lenses.
3. The technology can better control and reduce the visual discomfort caused by peripheral aberration, enabling the wearer to have a wider field of vision when switching between different vision.
