LENS TECHNOLOGY

With the optimisation of lenses the Individual Lens Technology takes into consideration the individual parameters, the Perfect Balance Principle, the free design of lenses and the Unique Customisation

Digital Freeform

SHARP VISION PRINCIPLE

INDIVIDUAL OPTIMIZED INSET

INDIVIDUAL PARAMETERS

Multipath Simulation

Stability Optimization Algorithm

digital freeform

Our backside digital surfacing ensures perfect alignment of design and prescription, enabling optical solutions with higher resolution, wider fields of view, and lower aberration.

digital freeform

Our backside digital surfacing ensures perfect alignment of design and prescription, enabling optical solutions with higher resolution, wider fields of view, and lower aberration.

sharp vision principle

Ensuring a sharp vision, the power of the lens in front of the eye should coincide with the refraction data. In most cases, the actual power values of the lenses optimized for wearing position are different from the order value because of differences inthe ray paths.

By taking the real-wearing situation into account, the wearer is provided with the exact prescription he or she needs at the near vision. Our Sharp Focus Principle ensures a true image focus on the retina.

INDIVIDUAL PARAMETERS

Each face is unique, and so is the fit of the frame. Generally, it can divide into 4 parameters: interpupillary distance, pantoscopic angle, wrap angle, and back vertex distance. Vision images can be significantly improved by using these 4 parameters in lens optimization.

INDIVIDUAL PARAMETERS

Each face is unique, and so is the fit of the frame. Generally, it can divide into 4 parameters: interpupillary distance, pantoscopic angle, wrap angle, and back vertex distance. Vision images can be significantly improved by using these 4 parameters in lens optimization.

Corneal Vertex
Distance (CVD)

Face-Form-Angle (FFA)

Pupillary Distance (PD)

Pantoscopic Tilt (PT)

INDIVIDUAL OPTIMIZED INSET

Ensuring a sharp vision, the power of the lens in front of the eye should coincide with the refraction data. In most cases, the actual power values of the lenses optimized for wearing position are different from the order value because of differences in the ray paths.

Stability Optimization Algorithm

This methodology marks a milestone in digital lenses because it allows rigid control of mean power in the distance and removes almost all peripheral spherical power error, which translates into benefits like less swim effect, the highest visual stability and many more.

Multipath Simulation

An innovative simulation model considers the lens’s actual position and the eyes’ natural movements in each direction of gaze, including all available information on the wearer, frame, and lens blank. It then uses the accommodation of the human eye to significantly reduce oblique aberrations, which results, among other benefits, in a precise and comfortable vision and amazing visual quality.

Stability Optimization Algorithm

This methodology marks a milestone in digital lenses because it allows rigid control of mean power in the distance and removes almost all peripheral spherical power error, which translates into benefits like less swim effect, the highest visual stability and many more.

Multipath Simulation

An innovative simulation model considers the lens’s actual position and the eyes’ natural movements in each direction of gaze, including all available information on the wearer, frame, and lens blank. It then uses the accommodation of the human eye to significantly reduce oblique aberrations, which results, among other benefits, in a precise and comfortable vision and amazing visual quality.