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Varilux

Varilux is a pioneering brand of progressive lenses, the world's first commercially successful multifocal eyewear solution designed to correct by providing seamless, line-free vision transitions across near, intermediate, and far distances. Invented in 1959 by engineer Bernard Maitenaz for Société des Lunetiers (later ), Varilux revolutionized optical correction by addressing the limitations of traditional , which featured abrupt shifts and visible lines that disrupted natural sight. Targeted primarily at individuals aged 40 and older experiencing age-related near-vision loss, these lenses employ a continuously variable focus design to ensure sharp vision in all conditions, including motion, with reduced distortions for faster adaptation. Since its launch, Varilux has become a of EssilorLuxottica's portfolio, with ongoing innovations enhancing , contrast, and stability to meet modern lifestyle demands like digital device use and . The lens's patented technology has driven widespread adoption, underscoring its role as a major 20th-century advancement in vision care that prioritizes comfort, aesthetics, and natural sight.

Overview

Definition and Purpose

Varilux is EssilorLuxottica's flagship brand of progressive addition lenses (PALs), designed to provide seamless vision correction across multiple distances. First introduced in 1959, Varilux lenses represent a pioneering advancement in technology, invented by Bernard Maitenaz to address age-related vision changes. The primary purpose of Varilux lenses is to correct , a condition affecting adults typically over 40 that impairs the eye's ability to focus on near objects, by offering a gradual progression of lens power from distance to near vision without the visible lines found in bifocal or . This design enables wearers to experience clear vision for far, intermediate, and close-up tasks—such as driving, working on computers, and reading—in a single pair of , promoting natural eye movement and reducing the need for multiple lens pairs. In terms of basic anatomy, a Varilux lens features an upper zone optimized for distance vision, a lower zone for near vision, and a progressive corridor in between that smoothly transitions the prescription power. This corridor minimizes abrupt shifts, allowing for fluid adaptation between viewing distances. Varilux lenses offer key benefits over generic PALs, including wider fields of clear vision and reduced peripheral distortion, which enhance overall comfort and visual stability during dynamic activities. These advantages stem from proprietary technologies that optimize lens design for individual eye physiology, resulting in sharper vision even in low-light conditions.

Comparison to Traditional Lenses

Bifocal lenses, invented by in 1784, consist of two distinct optical zones divided by a visible line: the upper portion for distance vision and the lower for near vision. This segmented design often results in an abrupt "image jump" when the wearer's gaze crosses the line, causing visual discontinuity and discomfort during focus shifts. Trifocal lenses, introduced by John Isaac Hawkins in 1827, build on this by adding a narrow intermediate zone between the distance and near segments, facilitating clearer vision for mid-range activities such as computer work or dashboard viewing. Despite this enhancement, trifocals maintain visible lines and segmented zones, perpetuating issues like image jump and limited smooth transitions across distances. Varilux progressive addition lenses address these drawbacks by providing a seamless, gradual power progression without any visible lines, eliminating image jump and enabling fluid shifts between , , and near . This design not only improves visual comfort but also offers greater aesthetic appeal, as the lenses resemble standard single- . However, Varilux lenses can introduce peripheral distortions, commonly referred to as the "swim effect," particularly in the lower and side regions, and typically require an adaptation period of one to several weeks—longer than the near-instant adjustment to —during which users may experience imbalance or . Compared to and trifocals, Varilux lenses significantly reduce the need for excessive head tilting to access different focal zones, promoting more natural posture and movement, as supported by clinical observations in early progressive lens research.

Historical Development

Early Concepts and Precursors

The concept of multifocal vision correction dates back to the late 18th century, when devised the first bifocal lenses around 1784 to address his own without constantly switching glasses. Franklin achieved this by cutting a pair of lenses in half—using the upper portion for distance vision and the lower for reading—and cementing them together into a single frame, creating a segmented design that provided discrete zones of correction rather than a seamless transition. This innovation, while groundbreaking, introduced visible lines and abrupt shifts in power, limiting its aesthetic and functional appeal as a precursor to more advanced multifocal solutions. By the early , opticians began exploring graduated power to eliminate segmentation, but these efforts largely failed due to manufacturing constraints and optical imperfections. In 1909, Canadian optician Henry Orford Gowlland conceptualized progressive monolithic with a continuous power variation, securing a Canadian in 1914 for a design featuring progressive cross-cylinder surfaces on both sides to gradually increase addition power from to near vision. Gowlland even produced a commercial version, the Gowlland Multifocal , starting in 1915, which attempted partial gradients but resulted in excessively thick central areas—up to several millimeters—making the uncomfortable and impractical for widespread use. During the 1920s and 1940s, further experiments with graduated lenses persisted amid advancing optical theory, yet persistent challenges in achieving a smooth power gradient without distortion thwarted success. Key obstacles included unwanted astigmatism and peripheral blur from uneven refractive index transitions, compounded by the era's rudimentary grinding and polishing techniques that could not produce the precise, aberration-free surfaces needed for intermediate vision zones. These issues remained unsolved until post-World War II advancements in precision optics enabled the first viable seamless multifocal design, exemplified by Varilux in 1959.

Invention and Initial Launch

Bernard Maitenaz, a French engineer and optics specialist, invented the first Varilux progressive lens in the late 1950s, driven by frustration with the limitations of his father's bifocal glasses, which caused abrupt shifts in focus and visible lines. After joining Société des Lunetiers (SL) in 1948 and becoming its technical director in 1953, Maitenaz collaborated with the company—later a founding entity of Essilor—to develop a lens providing seamless vision correction for presbyopia across all distances without the image jump of traditional bifocals. He filed the initial patent application in France on November 25, 1953 (corresponding to US Patent 2,869,422), detailing a continuously variable focus design that gradually increased power from distance to near vision. The development process involved rigorous testing to optimize the 's surface for practical manufacturing, resulting in the Varilux 1, the world's first commercially viable progressive addition . This inaugural model featured a vertical progression corridor—the narrow channel through which the eye transitions between focal zones—and a that distributed power progressively to reduce distortions, though peripheral aberrations remained a challenge compared to later iterations. Produced using specialized grinding techniques outlined in a 1959 (2,915,856) for optical surface fabrication, the maintained spherical surfaces in the distance and near zones while introducing the innovative intermediate progression. Varilux was launched in in 1959 by Société des Lunetiers, marking a breakthrough in ophthalmic as the first to offer clear, continuous vision from far to near on a single surface. The name "Varilux" derives from "variable lux," combining "variable" to denote the adjustable focal power with "" (Latin for ), emphasizing enhanced visual clarity. Positioned as a premium innovation, it was priced significantly higher than standard —approximately three times the cost—to reflect its advanced technology and customization. Early reception was enthusiastic among opticians and presbyopic patients seeking a more aesthetic and functional alternative to lined multifocals, leading to rapid adoption in despite an adaptation period for some wearers due to the novel design. Within the first year, thousands of units were fitted, establishing Varilux as a market leader and paving the way for global dominance. Maitenaz personally promoted the product through demonstrations, contributing to its immediate commercial success.

Brand Evolution and Global Expansion

Following the successful initial commercialization in France, Varilux experienced rapid growth during the 1960s, with annual sales reaching 2 million pairs by 1969, driven by its innovative design that addressed without visible lines. In 1972, Essel, the company behind Varilux as the successor to Société des Lunetiers, merged with rival Silor to form International, a pivotal event that integrated Varilux as the cornerstone of Essilor's premium portfolio, enhancing its status as a high-end optical solution. Essilor's international expansion accelerated in the , beginning with the establishment of a dedicated U.S. factory in 1972 to support distribution and entry into the market. Expansion continued into , including during the mid-1970s, as part of broader efforts to penetrate key global markets; by the , Varilux lenses were distributed in dozens of countries worldwide, reflecting Essilor's aggressive growth strategy through acquisitions and partnerships in , , and emerging regions like the in 1979. Marketing efforts emphasized Varilux as the "invisible bifocal," highlighting its seamless transition zones to appeal to consumers seeking discreet vision correction, with endorsements from optometrists underscoring its clinical benefits for natural management. Corporate milestones further propelled the brand's evolution, including Essilor's initial public offering on the Paris stock exchange in 1975, which provided capital for sustained innovation and global scaling. Sales momentum built steadily, with cumulative Varilux lens sales surpassing 300 million pairs by the early 2000s, demonstrating the brand's enduring market dominance. In 2018, Essilor merged with Luxottica to create EssilorLuxottica, uniting lens expertise with eyewear manufacturing and retail to amplify Varilux's worldwide presence under a unified global powerhouse.

Technological Foundations

Principles of Progressive Addition Lenses

Progressive addition lenses (PALs), exemplified by Varilux designs, provide seamless vision correction for by incorporating a gradual increase in plus from the distance viewing zone at the top to the near viewing zone at the bottom, eliminating the visible line found in . This add typically ranges from +1.00 to +3.00 diopters, achieved through variations in the lens surface curvature, where the base curve steepens progressively from top to bottom to add positive spherical without abrupt transitions. The core of PAL functionality lies in the progressive corridor, a narrow vertical channel typically 12-18 mm in height that connects the distance and near zones, allowing for a linear or near-linear increase in power along the vertical meridian. In this corridor, the power at a given vertical position y (measured from the top of the corridor) can be described by the equation P(y) = P_{\text{distance}} + \left( \frac{\text{add\_power}}{ \text{corridor\_height} } \right) y, ensuring smooth for intermediate distances without discrete segments. This design adheres to principles like Minkwitz's theorem, which relates the rate of power change to induced , approximately \Delta A / \Delta x \approx 2 \times \Delta M / \Delta y, where \Delta A is the change in astigmatism, \Delta x the lateral distance from the corridor, \Delta M the change in mean power, and \Delta y the vertical distance. Aberrations, particularly peripheral caused by unwanted and outside the central corridor, are inherent to the continuous power gradient and must be managed to maintain usable fields of clear . Modern PALs minimize this through aspheric surface designs, which distribute cylinder power more evenly across oblique meridians, reducing the magnitude of off-axis (often up to the full add power level) and expanding the distortion-free zones compared to earlier spherical approximations. Effective fitting of requires precise customization based on individual parameters to align the corridor with the wearer's and minimize adaptation issues. Key factors include (PD) for centering the and applying a near inset (typically 1.5-3.5 mm) to account for in reading; frame tilt or pantoscopic angle (10-15 degrees average) to optimize corridor tilt relative to the ; and (distance from to back surface, usually 10-14 mm) to adjust effective power. These parameters are marked on the via reference points, such as the fitting cross, to ensure proper mounting in the frame.

Core Innovations in Varilux Technology

Varilux has introduced several proprietary technologies that build upon the foundational principles of progressive addition lenses (PALs), such as the gradual power progression along the corridor, to deliver enhanced visual performance. One seminal innovation is SynchronEyes Technology, issued in 2007 under US Patent #7,207,675 B1, which optimizes by integrating prescription data from both eyes into the design of each individual lens. This approach creates a matched pair of lenses that account for inter-ocular differences, resulting in wider binocular visual fields and smoother coordination between the eyes for activities requiring precise . Advancements in lens materials have also been central to Varilux's evolution, with the adoption of high-index plastics that enable thinner, lighter es suitable for higher prescriptions without compromising optical clarity. These materials improve comfort and aesthetics for wearers. Complementing this, Varilux integrates anti-reflective coatings, such as 's Crizal technology, directly into the lens production process to minimize reflections and enhance light transmission, thereby reducing glare and improving contrast in low-light conditions. Digital surfacing represents another core innovation, first implemented in Varilux lenses with the Ipseo model in 2003, allowing for freeform customization of the lens surface based on individual wearer parameters. This technique precisely controls both focus and across the lens, significantly reducing peripheral in optimized designs compared to traditional surfacing methods. By enabling complex, non-spherical geometries, digital surfacing expands usable vision zones and minimizes the "swim effect" associated with power transitions in PALs. In more recent developments, Varilux incorporates behavioral adaptations informed by eye-tracking to create dynamic visual fields tailored to natural gaze patterns. Later models, such as the XR series launched in 2021, utilize trained on over a million eye-movement points to predict and accommodate individual visual behaviors, including head and eye rotations during dynamic activities. This results in instantaneous sharpness across distances, even in motion, by adjusting the lens design for real-world postural variations and pupil dynamics. As of 2025, further innovations include the Varilux Physio Extensee, which employs a dynamic model and patented DualBooster dual-side digital surfacing to enhance intensity and sharpness in varying light conditions. Additionally, the Varilux Immersia, launched in October 2025, uses twinning simulations and ergonomic for prolonged near-vision tasks, such as screen use, providing up to 20% in the reading zone.

Product Lines and Models

Early Models (1959-1980s)

The original Varilux lens, introduced in 1959 by Essilor's predecessor Société des Lunetiers, represented the first commercially successful progressive addition lens, featuring a continuously variable power progression designed to address without visible lines. Its design incorporated a corridor of approximately 16 mm, the vertical distance from the distance to near reference points, which allowed for a smooth transition but resulted in a limited near vision field due to the narrow astigmatism-free width of about 5 mm, restricting clear reading to a smaller area and often requiring greater head tilting. In 1972, following the merger forming , the company launched Varilux 2, a significant evolution that abandoned the original's base curve approach in favor of a fully aspherical front surface and a balanced distribution of across the . This innovation expanded the reading zone—providing a larger usable area for near tasks—while minimizing the "swim" effect, a common during head or , through optimized base curves that harmonized . The result was improved comfort and reduced adaptation time compared to the 1959 model, marking a foundational advancement in usability. In 1988, Essilor introduced the Varilux Multi-Design (also known as Varilux Infinity), which allowed for customization based on the wearer's prescription and frame choice, improving fit and visual fields by adjusting the progression corridor and inset. This model enhanced adaptability for varied lifestyles and frame styles. Early production of Varilux lenses from the 1950s through the mid- primarily involved traditional grinding techniques on semi-finished glass or blanks, where the progressive surface was meticulously surfaced and polished to achieve the required power gradients. By the late , advancements in computer (CNC) grinding and polishing enabled direct fabrication of finished progressive lenses, enhancing precision and efficiency; this period also saw the initial adoption of injection molding for lens blanks, which improved scalability and reduced manufacturing variability as expanded production. User experiences with these inaugural models frequently included initial adaptation difficulties, such as peripheral blur and the swim effect stemming from the short corridor and inherent , often necessitating a learning period of several weeks for optimal use. Despite these challenges, clinical observations and practitioner reports indicated high long-term satisfaction, with many wearers achieving comfortable vision across distances by 1980, underscoring the lenses' revolutionary appeal over and contributing to Varilux's market dominance.

Mid-Period Series (1990s-2010s)

The mid-period of Varilux development marked a phase of refinement in progressive addition lens design, building on earlier corridor-based architectures to enhance adaptation speed, , and overall visual comfort for presbyopic users. This era saw introduce technologies that addressed common complaints such as , limited , and unnatural head movements, progressively integrating binocular optimization and advanced surfacing techniques. Launched in 1993, the Varilux Comfort represented a significant evolution by incorporating visual into the lens design, featuring a shorter progression corridor compared to prior models. This reduced the vertical distance required for transitioning between distance and near vision, enabling faster times—often within hours for many wearers—and minimizing the need for excessive head tilting. Studies indicated that this design improved user satisfaction in adaptation ease, establishing it as Essilor's best-selling for over a . In 2000, the Varilux Panamic advanced panoramic vision capabilities, expanding clear fields of view in both horizontal and vertical dimensions through a dioptric method. This allowed for more natural eye movements and reduced peripheral blur, particularly beneficial for dynamic activities like or reading. The lens retained the Comfort's advantages while achieving record-fast fitting success rates, with clinical evaluations confirming seamless transitions for most users. The 2006 Varilux Physio introduced SynchronEyes technology, which personalized lens pairs based on binocular prescriptions to synchronize eye movements and promote a natural . By calculating the left and right lenses as a matched system, it minimized convergence strain and enhanced mid-range clarity, allowing wearers to maintain relaxed head positions during near tasks. This innovation, combined with W.A.V.E. Technology for aberration reduction, provided sharper vision across distances, with user trials showing improved visual comfort during prolonged use. By , the Varilux S Series incorporated Nanoptix technology, a nanoscale optimization of the surface that reduced distortions—commonly known as the "swim effect"—through reengineered micro-optical elements. This resulted in greater during motion and edge-to-edge expansive vision, particularly for active presbyopes. Paired with SynchronEyes for enhanced binocular harmony, the series delivered smoother near-to-far shifts, with independent tests confirming reduced challenges compared to earlier designs. The 2014 Varilux E Series focused on edge-to-edge clarity, leveraging advanced digital surfacing to minimize across the entire periphery and provide uniform sharpness in all gazes. This design emphasized Swim Control technology, reducing peripheral distortions for new wearers, facilitating quicker and broader visual fields without compromising central acuity. It built on S Series foundations to offer reliable performance in varied lighting, appealing to users seeking hassle-free everyday vision. Culminating this period, the 2017 Varilux X Series debuted Xtend technology, extending near vision coverage to accommodate arm's-length tasks common in active lifestyles. By enabling simultaneous focus at multiple distances through a single gaze point, it enhanced fluidity for digital device use and movement, with wearer studies reporting better satisfaction in dynamic scenarios. This model integrated prior advancements like Nanoptix for distortion-free expansion, solidifying Varilux's leadership in personalized progressive optics.

Recent and Current Series (2020s)

The Varilux XR Series, launched in 2023, introduced behavioral to design, enabling of visual fields based on individual and visual derived from over one million points, including real-life wearer tests and postural measurements. This AI-driven approach predicts and optimizes eye movements, delivering instant sharpness across all distances—even in motion—through XR-Motion binocular optimization technology, which expands the volume of clear vision by up to 49%. Building on the Varilux X Series foundation, the XR Series enhances near vision zones by up to 25% to match user-specific needs, reducing adaptation time and improving comfort for active presbyopes. In 2025, EssilorLuxottica unveiled the Varilux Physio extensee, incorporating Pupilizer technology that replicates the dynamic behavior of the human pupil to provide light-adaptive sharpness and high vision intensity across varying lighting conditions. By mapping pupil size variations and optimizing wavefront corrections, this lens reduces high-order aberrations and minimizes distortions, resulting in enhanced visual sharpness and contrast, particularly in challenging low-light scenarios. The Physio extensee integrates seamlessly with advanced coatings, including Transitions GEN S photochromic technology, allowing the lenses to adapt dynamically to environmental light changes while maintaining optical performance. Both the XR Series and Physio extensee have achieved global availability through EssilorLuxottica's distribution network, positioned as premium offerings with pricing typically ranging from $300 to $600 per pair depending on material and customizations.

Research and Innovation

EssilorLuxottica's R&D Framework

EssilorLuxottica's efforts for Varilux are supported by a global network of R&D facilities and innovation centers, including key hubs in such as the Excellence Rx Laboratory in and the Smart Eyewear Technologies Center in , as well as operations in the United States. The company invests approximately €600 million annually in R&D across its portfolio (as of 2024), representing about 2.4% of revenues, with a significant portion dedicated to advancing technologies like Varilux. The development process for Varilux lenses begins with informed by optical principles and consumer data, progressing through iterative prototyping, using and , and extensive clinical validation. This culminates in real-world trials involving thousands of wearers to assess , visual performance, and comfort, as demonstrated in multiple studies aggregating over 2,700 participants for key models. Collaborations play a central role in this framework, with partnerships such as the joint research platform with Politecnico di Milano for optics and vision science advancements, and alliances with AI specialists like Meta to integrate extended reality (XR) capabilities into eyewear innovations. These efforts have yielded over 70 patents specifically related to Varilux since its 1959 invention, covering aspects from lens geometry to adaptive designs like SynchronEyes.

Key Studies and Technological Advancements

In the , clinical evaluations of early Varilux models, such as the Varilux Plus, demonstrated high rates among presbyopic patients. A involving 280 patients fitted between June 1988 and May 1989 reported a 97.5% rate, based on the ratio of lenses ordered to those returned, highlighting improved adaptation compared to prior progressive designs. During the , trials on the Varilux Physio series focused on enhancing visual performance in challenging conditions. A double-masked, randomized clinical with 30 subjects (average age 52.9 years) found that 82% preferred Varilux Physio Enhanced in dim light (25 cd/m²) for tasks like reading and navigating, with 71% preference in standard light (100 cd/m²); this design incorporated size modeling (2-8 mm) to reduce visual distortions and improve comfort during dynamic activities. In the 2020s, validation studies for the Varilux XR series, powered by behavioral , emphasized user satisfaction and adaptability. An reported 96% satisfaction with near vision quality and 84% of participants adapting immediately on day one, reflecting enhanced sharpness across distances even in motion; these results were supported by broader consumer research involving thousands of presbyopes to refine eye-responsive features. In 2025, EssilorLuxottica launched the Varilux Physio extensee lens, which uses dynamic pupil modeling to provide high vision intensity in varying light conditions, addressing near-vision challenges in dim environments through optimized designs that account for pupil size changes. Early studies indicate 84% of participants experience impaired near vision in low light, with the lens design mitigating distortions for improved comfort. Key technological advancements in Varilux lenses include wavefront analysis via , which analyzes beams passing through the to control higher-order aberrations, achieving 2.8 to 6.6 times fewer aberrations than competitive conventional progressives in bench tests. Additionally, pupil dynamics modeling has evolved to account for factors like illumination, age, and accommodative state, enabling optimized designs that maintain across varying conditions without additional measurements.

User Experience and Fitting

The Varilux Experience Program

The Varilux Experience Program, introduced by in the late 2000s, represents a structured fitting and educational framework aimed at enhancing the personalization and performance of Varilux lenses for presbyopic patients. This initiative integrates advanced tools to capture individual visual behaviors, ensuring lenses are tailored to specific needs and lifestyles, thereby improving overall user satisfaction and adaptation. At its core is the Visioffice system, a measuring device launched in 2010 that facilitates precise ophthalmic measurements for customized lens designs. The program follows a systematic process beginning with eye tracing, where the Visioffice captures eye movements, rotation centers, and physiological parameters using 3D stereoscopy and multi-camera integration to map how each eye functions uniquely. This step informs the Eyecode technology, which adjusts lens designs based on the measured eye rotation for optimized near and far vision. Next, a evaluates the patient's daily activities—such as reading, , or digital device use—through targeted questionnaires and behavioral tests like Near Vision Behavior analysis, exclusive to Varilux lenses, to align the prescription with real-world demands. Frame selection concludes the key steps, incorporating H3D measurements of head and frame fit to refine and minimize distortions. Supporting tools within the program include and features in the Visioffice, allowing patients to interactively preview fields and compare lens performance across distances, fostering informed decisions during the fitting consultation. These elements combine to deliver hyper-personalized outcomes, with AI-enhanced precision in newer iterations reducing the risk of remakes and returns by minimizing measurement errors. While some users may still encounter brief challenges, the program's proactive approach significantly enhances fitting accuracy and patient confidence.

Adaptation Process and Common Challenges

The adaptation process to Varilux progressive lenses primarily involves the brain's adjusting to the seamless progression of power across the lens zones, enabling coordinated eye-head movements for clear vision at varying s. Most users experience an initial as they train their to utilize the upper zone for , the corridor for mid-range tasks, and the lower for near work, typically achieving full adaptation within 1 to 2 weeks of consistent wear. In some cases, particularly for first-time wearers or those with higher prescriptions, adaptation may extend up to 3 weeks, during which the refines gaze shifts to minimize distortions. Common challenges during this period include peripheral blur in the lens edges, where off-axis views may appear distorted due to the inherent in progressive designs, and difficulties with floor visibility or steps when descending stairs, stemming from unintended use of non-optimized zones. Users may also encounter impaired depth or distance perception, headaches, , or a sensation of image "swim" during movement, as the acclimates to the multifocal gradient. These issues are often mitigated through precise fitting by an optometrist, ensuring the corridors align with the wearer's and frame tilt, which reduces distortion and enhances zone accessibility. To facilitate adaptation, wearers are advised to use the lenses full-time from the outset, avoiding alternation with previous single-vision or bifocal pairs, and to consciously direct their nose toward objects while employing subtle head tilts to access appropriate zones—such as looking over the top for or lowering the gaze for reading. If discomfort persists beyond 2 weeks, consulting an eyecare professional for frame adjustments or verification of the prescription can resolve most issues, often preventing the need for . Clinical wearer studies demonstrate high success rates, with 100% of participants adapting readily to Varilux Comfort lenses after 3 weeks regardless of prior correction type, and 95% reporting positive overall vision quality. For the Varilux X Series, 82% of wearers rated adaptation as easy (7-10 on a 10-point scale) in multicenter trials. Adaptation rates are even higher with recent series like Varilux XR, where 90% of wearers adapt successfully, benefiting from AI-optimized designs that expand clear vision volumes and reduce adjustment time.

Market Position and Impact

Global Adoption and Sales

Varilux stands as the world's leading brand, commanding a dominant position in the global market for multifocal vision correction. It reflects its pioneering role since 1959 and ongoing innovations that have driven widespread adoption among presbyopic consumers. The brand exhibits particularly strong penetration in , where EssilorLuxottica derives 36% of its overall from the region as of end-2023, bolstered by high awareness and prescription rates for Varilux products. In , adoption is accelerating through EssilorLuxottica's strategic expansions, including joint ventures and investments, contributing to double-digit regional rates, such as the 10.4% increase at constant rates reported in the first quarter of 2025. Annually, Varilux forms a of EssilorLuxottica's financial performance. This scale underscores Varilux's integral role in the progressive lenses market, valued at USD 11.5 billion in 2023. Cumulative sales exceeding 400 million pairs further highlight its enduring global impact. Varilux primarily serves users in the 45-65 age group, addressing onset and progression, though adoption is rising among active seniors who seek seamless vision for dynamic lifestyles. This demographic shift aligns with global aging trends, where affects approximately 1.8 billion people as of 2025, fueling demand for advanced progressive solutions like Varilux.

Competition, Legacy, and Industry Influence

In the progressive addition lens (PAL) market, Varilux faces competition primarily from established brands such as , Hoya, and Shamir, each offering advanced designs tailored to correction. emphasizes precision optics with freeform technology to minimize distortion and expand visual fields, while Hoya focuses on durable coatings and for enhanced longevity and clarity. Shamir, meanwhile, incorporates AI-driven personalization to adapt lenses to individual lifestyles and visual behaviors. Despite these rivals, Varilux maintains leadership in the premium segment through its innovative features like seamless transitions and motion stability, positioning as the top-ranked brand in progressive lenses globally. Varilux's legacy as the pioneer of progressive lenses dates to its 1959 introduction, which revolutionized multifocal eyewear by eliminating the visible lines and abrupt shifts of traditional , providing instead a smooth, continuous of across distances. This breakthrough set the foundational standard for PALs, influencing the design principles of subsequent generations of multifocal lenses and establishing expectations for natural, distortion-free correction. As the world's leading brand, Varilux benefits from securing over 80 patents annually to refine its technologies, with the brand holding over 70 patents since inception, ensuring it remains the most recommended option among eye care professionals and a benchmark for optical performance. The brand's influence extends to reshaping the broader eyewear industry, particularly by accelerating the transition from lined —which dominated solutions in the mid-20th century—to seamless progressives that now prevail in multifocal prescriptions. This shift has elevated standards for user comfort and , with Varilux's innovations driving widespread adoption of advanced designs that prioritize wide fields of view and reduced challenges. Looking ahead, Varilux is paving the way for integration with , including AI-enhanced and partnerships in AI-driven wearables, positioning progressive lenses for compatibility with (AR) applications in smart eyewear.