Myolens
Grid Array Plus Lens
Based on the structural characteristics of insect compound eyes and the hypothesis of myopia defocus, designed Grid Array Plus Lens. While appropriately reducing the diameter of the central bright field to introduce more stimulation signals to the sensitive area of the retina. Dynamic aberration modulation technology is also added to the lens to better match the eye data of each different patient and reduce the negative impact of hyperopia defocus on myopic patients, in an attempt to further improve the myopia prevention and control effect of Grid Array Plus Lens.
MW Circular Lens
Based on the hypothesis of myopia defocus, the micro eccentric ring technique is adopted to form a non concentric phenomenon of each ring, and a micro eccentric defocus ring with gradually increasing spacing from the center to the outside is constructed to continuously provide differentiated stimulation to the periphery of the retina, making myopia prevention and control effective. Provide a smaller diameter of the central optical zone, while ensuring clear vision in the central macular area, close to the sensitive area of the retina, and with relatively small ring spacing in the sensitive area of the retina, to further enhance myopia control.
Grid Array Lens
Based on the myopia defocus hypothesis, a special mesh filling structure is adopted to present differences between the peripheral imaging of the retina and the central imaging, in order to better guide the development direction of myopia. At the same time, a small optical zone is set to make the imaging position of peripheral objects closer to the sensitive area of the retina, enhancing the myopia control effect; And dynamic aberration modulation technology is used to match the eye data of different patients, calculate more accurate lens data, and produce lenses that better fit the patient's eyes, achieving better myopia prevention and control effects.
HOA-Blended Lens
Based on the higher-order aberrations and myopia defocus hypothesis, and adopting the technique of coexisting dual stimulus signals, forward defocusing is added to the lens, and higher-order aberrations are introduced through quantization modulation using a free ring surface. The two microstructures are interlocked and connected to form an annular shape, in order to generate sufficient myopic defocusing and higher-order aberration modulation signals within the range of pupil scanning. The coexistence of dual mechanisms not only solves the early adaptability problem of simple higher-order aberrations, but also avoids the decrease in energy efficiency in controlling the post defocusing stage of simple myopia, achieving a more effective suppression of axial growth.
WTR Lens
Based on the hypothesis of with-the-rule astigmatism and myopic defocus, and using multiple stimulus signals and dynamic aberration modulation techniques, designed the "WTR lens". The dual mechanism of myopic defocus stimulation and forward astigmatism stimulation signals coexists to suppress axial growth. The special layout of the lens makes the stimulation signal area larger, providing stimulation micro wave modulation signals near the macular fovea while ensuring stable and balanced stimulation signals in all directions.
Diffusion-Blended Lens
Based on the hypotheses of diffuse plaques and myopia defocus, and using the multiple stimulus signals and stimulus quantitative evaluation system techniques, designed the "Diffusion Blended Lens". The lens introduces both myopia defocus signal and diffuse plaques signal to enhance the stimulation of the retina periphery and further reduce the visual quality of the retina periphery; At the same time, by using quantitative methods to select the design scheme with appropriate stimulation and the best prevention and control effect, in order to more efficiently and accurately reduce the visual quality around the retina.
Molded SV Lens
Molded SV Lens
Aberration Optimized Lens is a functional lens specially designed for people with hyperopia and myopia who are in pursuit of high quality vision, as compared to traditional aspheric lenses in terms of wearing comfort, first-time adaptability, and contrast sensitivity after wearing the lenses; in particular, the detection of contrast sensitivity after wearing the lenses is increased by more than 20% as compared to that of spherical lenses.
Molded Progressive Lens
E-Free Lens
Solution:
Molded progressive lens semi and finished
Design Feature:
①Huge low distortion can be even compared to some freeform pals. Max unwanted astigmatism equals to
70%-75% of add value.
②Comparatively wide far vision with 178° angle of 0.5D Cylinder line at FRP.
③Wide and stable effective visual area.
E-Sharp Lens
Function enhanced ultra-short corridor hard design. The add value from FC to NRP occupies 95% of total value with a 13 mm only total corridor length.
E-Reader Lens
Occupational design with an extremely low distortion at mid area. Max unwanted astigmatism lower than 70% of add value and located on far vision area which is far from the fitting center.
Mineral Glass Lens
Internal Aspheric Finished Lens
Internal aspheric lenses are advanced optical lenses that have been individually designed and processed to optimize them for individual visual requirements. The principle of this type of lens lies in the use of computer-controlled precision machining processes that incorporate an internal optimization process, allowing the surface of the lens to be produced in a variety of shapes to meet the visual requirements of the individual.
Progressive Semi Finished Lens
Minernal glass progressive products are characterized by lenses that have significant advantages in optical performance. It offers superior image quality and better correction of various vision problems such as nearsightedness, farsightedness and astigmatism. Glass progressive lenses also have higher light transmission for better protection from UV and other harmful rays and are more attractive in appearance.