Fact-checked by Grok 2 weeks ago

Keycap

A keycap is a removable cover, typically constructed from or other materials, that mounts atop the of a key switch on a , serving as the primary contact surface for users to press and register keystrokes while often displaying legends indicating the key's function. Keycaps play a crucial role in and customization, influencing typing feel, sound, and through variations in , , and . They are especially prominent in keyboards, where enthusiasts frequently replace stock keycaps to personalize layouts, such as ANSI or ISO standards, and enhance durability against wear. Common materials include (ABS) for its smooth finish and affordability, though it is prone to shine and fading over time; (PBT) for superior durability and ; and (POM) for a premium, smooth typing experience at a higher cost. Keycap profiles define the ergonomic contour and height across rows, with popular designs like OEM (medium height, sculpted for finger adaptation), Cherry (similar but less angled), (tall and spherical for a pronounced feel), and (uniform height for consistency). Legends—the printed or molded characters on keycaps—are applied via methods such as (inexpensive but fades quickly), etching (durable through material removal), dye-sublimation (infuses color into PBT for longevity), and double-shot molding (uses two plastics for legends that never wear off). is essential, as keycaps must match the switch type (e.g., Cherry MX stems) and overall to ensure proper fit and functionality. Beyond standard sets, artisanal and custom keycaps crafted from materials like metal, , , or allow for unique artistic expressions, often sold in limited editions to appeal to the mechanical keyboard . High-quality keycaps contribute to reduced noise, improved grip, and resistance to environmental factors, making them a key upgrade for both professional typists and gamers seeking optimized performance.

Overview

Definition and Function

A keycap is the removable top portion of a , serving as the primary surface for user finger contact during input operations. It typically features engraved or molded legends, which are the symbols, characters, or icons indicating the 's function, such as letters, numbers, or modifiers like Shift or Enter. These components are standard primarily on keyboards, and some low-profile or chiclet-style keyboards, allowing for easy replacement or customization without altering the underlying hardware. In terms of function, a keycap acts as the for registering keystrokes by translating the force applied by the user's finger into activation of the keyboard's switch mechanism. When pressed, the keycap depresses the switch beneath it, which in turn triggers an electrical signal to the computer or device, registering the input without the keycap itself handling the electrical aspects. This process enables precise and repeatable input, with the keycap providing the necessary leverage and tactile feedback for efficient typing or control. The basic anatomy of a keycap consists of three main parts: the top surface, which bears the legend and receives direct finger pressure; the sides, which form the key's for ergonomic shaping; and the stem at the bottom, a protruding structure that attaches to the switch housing via a compatible mount, such as or plus-shaped designs. Keycaps are standardized in size using "u" units, where 1u represents the width of a typical alphanumeric key, measuring approximately 19.05 center-to-center, ensuring compatibility across various layouts. Larger keys, like spacebars, scale up to 6.25u or more, while modifiers may use 1.25u or 1.5u for balanced spacing.

Role in Keyboard Ergonomics

Keycaps play a pivotal role in ergonomics by optimizing finger interaction with the keyboard surface, thereby promoting natural hand positioning and minimizing strain during prolonged use. The shape of keycaps, particularly sculpted or designs, facilitates proper finger placement on the home row, allowing users to maintain a relaxed that supports efficient touch-typing without excessive extension or finger stretching. For instance, keycaps reduce finger strain by accommodating the natural of fingertips. Textured surfaces on keycaps further enhance , preventing slippage and enabling precise key location through tactile cues, which can reduce hand fatigue. In terms of , keycap design incorporates features that provide essential tactile and visual feedback for users with disabilities, enhancing overall usability. Height variations and textured finishes on keycaps offer distinguishable tactile markers, such as raised edges or roughened surfaces, which aid visually impaired individuals in navigating the without visual reliance, thereby supporting computing tasks. High-visibility legends, achieved through large, high-contrast on keycaps, improve legibility for those with low vision, boosting accuracy and user confidence by reducing the associated with key identification in dim lighting or under . Braille-embossed keycaps extend this further, enabling blind users to type with greater precision by integrating standardized tactile symbols directly into the keycap surface. The ergonomic contributions of keycaps extend to measurable improvements in performance, where well-designed profiles correlate with higher speed and lower rates. Studies on keycaps with varied profiles demonstrate a 12.1% reduction in task completion time for common operations, attributed to enhanced haptic distinguishability that minimizes visual scanning and refocusing. Haptic from textured or contoured keycaps can improve speed and decrease rates, as the tactile confirmation reinforces accurate key presses and supports fluid touch-typing rhythms. These benefits are particularly evident in profiles like OEM or , which reduce fatigue during extended sessions by aligning key heights with natural finger arcs, though individual preferences may vary based on hand size and .

History

Origins in Typewriters and Early Computers

The origins of keycaps can be traced to the development of mechanical typewriters in the , marking the first widespread use of dedicated finger-actuated caps on input devices. In , American inventors , Carlos Glidden, and Samuel W. Soule received U.S. Patent No. 79,265 for an improved type-writing machine, which featured a of keys arranged in a layout resembling keys to actuate typebars. The patent model's keys were constructed primarily from wood, reflecting the rudimentary materials available for prototypes. This design laid the foundation for keycaps as tactile interfaces, with each key pivoting on a to engage a corresponding typebar via a wire finger mechanism. The first commercially viable iteration, the Sholes & Glidden Type-Writer produced in 1873, was refined and manufactured by E. Remington & Sons starting in 1874 as the Remington No. 1. This model introduced metal keycaps with clear glass tops encasing printed characters on white paper inserts, providing visibility of legends while protecting them from wear; the keys measured approximately 3/4 inch in diameter and were flat for uniform finger contact. Early keycap designs in s were characteristically flat and non-removable, integrated directly onto the key levers to ensure mechanical stability during operation. These caps prioritized durability over customization, with the glass-topped metal construction in the Remington No. 1 allowing for precise strikes without frequent maintenance. Materials evolved from wooden components in prototypes to more robust options like metal and in production models, though some contemporaneous devices incorporated or (derived from tagua nuts) for smoother tactile feedback and aesthetic appeal. For instance, by the 1890s, the Caligraph series transitioned to keytops with engraved characters, offering a premium feel akin to keys while resisting cracking better than natural . Non-removable designs dominated until the limitations of legend wear became apparent in high-use environments, prompting innovations in . The shift toward removable keycaps emerged in the early to simplify legend replacement and repairs. By the , Underwood typewriters, such as models in their Standard series, featured key constructions where tops could be detached from levers using simple tools like prick punches or for reattachment, often revealing underlying or metal rings with inserts. During the and , some typewriters began incorporating early plastic materials like for key tops, offering lighter weight and easier legend application while maintaining durability. This reduced downtime in office settings, as worn legends could be swapped without disassembling the entire mechanism. Prior to widespread typewriter adoption, similar key-like structures appeared in precursors such as telegraph keys, which used wooden or metal knobs on levers for transmission starting in the mid-19th century, and adding machines like the 1887 , whose full-keyboard arrays employed metal tops in columns for numerical input. By the 1930s, keycap designs in office typewriters achieved greater uniformity to support standardized typing practices and ergonomic efficiency. Major manufacturers like Underwood, , and Remington converged on consistent key sizes—typically 3/4-inch diameter round caps with 3/4-inch spacing—facilitating and training across models. This standardization, driven by the proliferation of mechanical office typewriters, ensured reliable performance in professional environments and set precedents for later mechanical input devices.

Transition to Personal Computing Era

The transition to personal computing in the marked a significant shift in design, with the introduction of electronic keyboards featuring keycaps to accommodate emerging microcomputers. keyboards, which used flexible layers for key registration, emerged in the early , offering a cost-effective to mechanisms for early devices like calculators and terminals. keyboards also began evolving during this decade, building on heritage with individual switches under keycaps to provide tactile feedback in the first personal computers. For instance, systems like the 1977 utilized chiclet-style keycaps, flat and membrane-based, which prioritized compactness over the raised profiles of prior eras. These innovations reflected the need for affordable, reliable input in hobbyist machines, contrasting with the metal components of earlier systems. A pivotal milestone came with the PC 5150 in 1981, which popularized snap-on, removable keycaps on its equipped with buckling spring switches. This design allowed users and manufacturers to easily swap keycaps for different layouts or repairs, standardizing modular construction in personal computing. The buckling springs provided audible and tactile response, enhancing typing accuracy for office and home use, and set a for durability in mass-market PCs. In the and , advancements focused on materials and for scalable production. (ABS) plastic became widely adopted for keycaps due to its affordability, moldability, and suitability for double-shot molding of legends, enabling vibrant, wear-resistant designs in consumer keyboards. A key enabler was the Cherry MX switch series, patented in , which featured a cross-shaped that facilitated interchangeable, removable keycaps across various layouts. This supported the proliferation of standardized keyboards in business and education, with ABS keycaps appearing in models like early Cherry G80 series units. From the onward, and portable drove further evolution toward slimmer keycap profiles. The resurgence of mechanical keyboards in emphasized responsive, durable designs with low-profile keycaps for faster actuation in competitive play. keyboards adopted chiclet-style keycaps with reduced height and spacing for portability, influencing variants to incorporate similar slim aesthetics. In the , the rise of wireless keyboards incorporated lightweight and keycaps to minimize overall device weight while maintaining functionality, supporting in mobile setups.

Design and Construction

Materials and Durability

Keycaps are primarily manufactured from thermoplastic polymers such as (ABS), (PBT), and , each offering distinct properties suited to different user needs and production methods. ABS is the most common material due to its low cost, ease of molding, and glossy finish, which provides a typing feel initially; however, it is prone to developing a shiny surface from oils and wear, yellowing under UV exposure, and having relatively low heat resistance, with a temperature of approximately 105°C (221°F), which can lead to softening under moderate heat exposure. In contrast, PBT delivers superior with a matte, textured surface that resists shine and maintains grip over time, along with higher heat tolerance, with a of approximately 225°C (437°F), and strong UV resistance to prevent color degradation. Polycarbonate, often used for its translucency that enhances backlighting effects in RGB s, offers excellent impact resistance and toughness for daily use but comes at a higher cost, with limited availability and a harder feel compared to ABS or PBT. Another material is (POM), valued for its exceptionally , self-lubricating surface and resistance to wear, providing a premium experience similar to but more durable than polycarbonate. Durability in keycaps hinges on material composition and manufacturing processes, particularly wear resistance against repeated keypresses and environmental factors. PBT keycaps excel in longevity, resisting shine and maintaining texture far longer than under repeated use, due to their harder, more abrasion-resistant composition. Modern production also incorporates non-toxic, eco-friendly dyes, especially in dye-sublimation processes, to minimize environmental impact and ensure safety for prolonged skin contact. Testing for keycap durability typically involves abrasion assessments to evaluate fade resistance and overall wear, often following standards like ISO 18947-1 for printed materials, which simulates rubbing and smudging to measure legend integrity. For instance, dye-sublimated PBT keycaps demonstrate exceptional legend retention, resisting fade even after extended heavy use equivalent to a lifetime of normal typing, as the dye embeds deeply into the material rather than sitting on the surface.

Attachment Mechanisms

Keycaps attach to switches via specialized protruding from their underside, which with the switch housing to ensure stable actuation and prevent wobbling during use. These vary by switch type and are designed to clip securely into corresponding slots or receptacles within the switch, allowing the keycap to move vertically without lateral play. The primary designs include the cross-shaped Cherry MX-style, the rectangular finger , and the cylindrical Topre , each optimized for specific switch architectures. The Cherry MX-style stem features a cross or plus-shaped configuration, typically molded as four perpendicular arms that snap into the cross-slotted housing of Cherry MX or compatible switches. This design, originating with Cherry's MX switches introduced in 1983, provides a firm grip through friction and interlocking arms, distributing force evenly across the switch top. In contrast, the Alps finger stem uses a narrow, elongated rectangular protrusion—often described as a "finger" or square post—that slots into the matching rectangular opening in Alps switch housings, offering a simpler clip mechanism but limited to Alps-compatible setups. The Topre cylindrical stem, employed in electrostatic capacitive switches, consists of a round post that fits snugly into a circular receptacle, relying on the switch's rubber dome and housing for retention rather than complex interlocking. These stems can be visualized as follows: the MX cross aligns its arms with the switch's orthogonal slots for a locked fit; the Alps finger slides into a linear channel for axial stability; and the Topre cylinder seats directly into a bore for concentric movement. Compatibility between keycaps and switches hinges on stem-switch matching, with Cherry MX-style stems serving as the industry benchmark due to widespread adoption. MX clones from manufacturers like Gateron, Kailh, and modern GX series use identical cross stems, enabling seamless interchangeability for upgrades. However, proprietary stems, such as 's older Romer-G design with its unique T-shaped post, resist MX keycaps and require brand-specific replacements. Universal stem compatibility, particularly the MX cross, emerged prominently in the as computers proliferated, standardizing swaps and fostering a modular beyond original equipment. Stems are typically constructed from durable plastics like or to withstand repeated insertions, though this intersects with broader material considerations. Mismatched stems, such as forcing an MX cross into an housing, can lead to incomplete seating or breakage. Installation and removal of keycaps involve aligning the stem with the switch and pressing down firmly for attachment, or using specialized tools for to avoid deformation. Keycap pullers—often wire-based or ring-shaped devices—hook under the keycap edges and apply even upward force, distributing pressure to prevent stem slippage or housing cracks. These tools, commonly included with enthusiast keyboards, reduce the risk of damage compared to manual prying with fingernails, which can bend stems or dislodge switch components. Risks from mismatched or forceful handling include snapped stem arms, scratched switch tops, or permanent wobble, potentially rendering the switch inoperable; always verify stem before swapping to mitigate such issues.

Legend Application Techniques

Legend application techniques refer to the methods used to imprint characters, symbols, and icons onto keycaps, ensuring and under repeated use. These processes vary in complexity, cost, and longevity, directly impacting by affecting how well legends resist , shine through backlighting, and maintain contrast over time. Common techniques include , dye-sublimation, and laser etching, each suited to different materials and production scales. For keyboards with backlighting, specialized approaches like double-shot molding enable translucent legends that allow light to pass through without fading. Pad printing is a widely used, single-color technique that applies legends cost-effectively through a pad that transfers from an engraved metal plate to the keycap surface. This method involves the desired design into a plate filled with , which the flexible pad picks up and presses onto the keycap, creating a thin layer of that adheres via solvent evaporation. It is particularly advantageous for high-volume production on or PBT keycaps, offering flexibility for custom designs but producing opaque legends that can fade or chip after prolonged use, especially under heavy typing or cleaning. As a result, is common in entry-level and office keyboards where budget constraints prioritize speed over extreme durability. Dye-sublimation provides a more durable, multi-layer alternative by heat-transferring directly into the keycap's substrate, creating wear-proof legends that integrate seamlessly with the material. The process begins with the design onto special sublimation paper using inks, positioning the paper over the blank keycap (typically PBT or ), and applying —around 175–200°C for 3–5 minutes in a —to vaporize the , allowing it to bond molecularly with the as it cools. This results in vibrant, oil- and UV-resistant legends that withstand without peeling or fading, though they remain opaque and perform best on lighter-colored keycaps for optimal . Dye-sublimation enhances in demanding environments, such as or professional typing, by maintaining legibility far longer than surface-printed methods. Laser etching offers precise legend application without inks, ideal for creating fade-resistant designs through controlled material removal. The technique starts with a painted or coated keycap, often made of transparent or , where a beam burns away the top layer to expose the underlying color or , sometimes followed by filling etched grooves with contrasting for visibility. This no-ink ensures legends do not fade from , providing sharp, customizable details and compatibility with backlighting via translucent areas, though the paint fill may wear after 2–3 years of intensive use. Laser etching is favored for its accuracy in producing tactile, textured legends that improve touch-typing . For backlit keyboards, double-shot molding stands out by creating translucent legends during the keycap formation itself, allowing RGB or LED illumination to shine through effectively. This involves injecting a first layer of translucent to form the legend, followed by a second opaque layer for the keycap body, fusing them inseparably in a molding process. Introduced in the to support the rise of illuminated keyboards, this ensures legends remain indestructible and evenly lit even after millions of presses, though it requires specialized molds and is more expensive. It significantly boosts in low-light conditions by providing clear, glowing visibility without compromising durability.

Profiles and Variations

Standard Key Profiles

Standard key profiles refer to the geometric shapes and varying heights of keycaps designed for ergonomic typing on mainstream mechanical and membrane keyboards, typically following sculpted designs where heights increase progressively from the bottom row to the top row to match natural finger positions. These profiles are standardized to fit common layouts such as and , which define key widths in "u" units—where 1u equals approximately 19.05 mm wide for alphanumeric keys—and ensure compatibility across manufacturers. Uniform-height profiles, such as (Distinct Sky Appearance), provide consistent height across all rows for a flat typing surface, promoting uniformity in finger travel and often featuring slightly concave or spherical tops for centering. DSA keycaps typically measure around 9-10 mm in height for all rows, making them lower-profile than most sculpted designs while maintaining compatibility with standard ANSI/ISO layouts and Cherry MX-style stems. This profile, developed in the early 2010s by enthusiasts, gained popularity for its modern, minimalist aesthetic and reduced visual row distinction. The (Original Equipment Manufacturer) profile is one of the most prevalent sculpted designs, featuring medium-height keycaps with angled tops and mild row sculpting, where each row has a distinct height to promote comfortable reach during . In this profile, the home row (often designated as R2 or R3 depending on convention, corresponding to the middle alphanumeric row) typically measures around 11.5 mm in height, with bottom rows shorter (e.g., approximately 9-10 mm) and top rows taller (up to 13-14 mm) to create a subtle incline. This allows OEM keycaps to be mass-produced for stock keyboards, ensuring broad with Cherry MX-style stems and layouts that accommodate both ANSI's horizontal and ISO's L-shaped variant. The Cherry profile, a shorter sculpted variant similar to OEM but with less aggressive angles and subtler curves, originated in the 1980s with the Cherry G80-3000 series keyboards produced by the company Cherry Corporation, which helped establish it as a benchmark for ergonomic keycap geometry in early mechanical keyboards. Keycaps in this profile generally stand at about 9.4 mm in overall height for the home row, with row-specific variations such as R1 (bottom row) around 7-8 mm, R2 (home) at 9.4 mm, R3 at 10.5 mm, and R4 (top) up to 11.7 mm, providing a lower silhouette that reduces finger extension while maintaining the sculpted incline aligned with ANSI and ISO standards. Its design emphasizes uniformity in feel across rows despite height differences, making it a staple in professional and gaming keyboards. SA (Spherical-Concave or Spherical All-Rounder) profile keycaps feature tall, sculpted heights with distinctive spherical tops that create a uniform concave surface for consistent finger centering, regardless of row position, which enhances tactile feedback in high-profile setups. The home row height in SA profiles reaches approximately 14-15 mm, with overall maximum heights up to 16.5 mm on top rows and minimums around 12 mm on bottom rows, following the same progressive sculpting as OEM and Cherry to fit standard ANSI/ISO layouts. This profile evolved from earlier unsculpted uniform designs in the mid-20th century but gained popularity in the enthusiast community for its retro aesthetic and deep key travel, though it adheres to the same dimensional standards for broad keyboard compatibility.

Custom and Artisan Keycaps

Custom and artisan represent a vibrant segment of the mechanical enthusiast community, where users seek personalized, non-standard designs to enhance and express individuality beyond mass-produced options. These keycaps often build upon standard profiles like Cherry or OEM for compatibility but diverge through unique artistic elements, allowing hobbyists to customize single keys or full sets with themes. Artisan keycaps, in particular, are handcrafted individual pieces created by independent artists or small studios, typically focusing on a single key such as the spacebar or key. Common techniques include hand-painting for intricate details, sculpting from clay or for custom shapes, and resin pours to cast translucent or embedded designs, resulting in one-of-a-kind items like Clack Factory's motifs or Binge's airbrushed characters. For instance, GMK keycap sets exemplify custom production with themed artwork, such as the WWII-inspired Pacific collection featuring blues and grays, produced in coordinated sets for full overhauls. Production of these keycaps frequently begins with prototypes to refine shapes and fit, followed by small-batch molding using for to enable limited runs without industrial-scale equipment. The popularity of custom and artisan keycaps surged in the 2010s through online communities and platforms, with early milestones like the 2010 launch of Clack Factory's resin-cast offerings and the 2012 founding of Massdrop for group buys, enabling artists to fund projects and distribute sets often priced at $100 or more. Their collectibility stems from limited-edition releases, such as runs of 500 units or fewer, which create scarcity and drive values among enthusiasts. Community events like Keycon conventions further amplify this culture, serving as hubs for showcasing new works, trading rares, and fostering collaborations since the event's inception in the mid-2010s.

Standards and Customization

Industry Standards

Industry standards for keycaps primarily revolve around layout specifications, mechanical compatibility, ergonomic guidelines, and material certifications to ensure interoperability, safety, and usability across keyboards. The (ANSI) defines the US 104-key layout, which standardizes keycap sizes and positions for full-size keyboards, including 1-unit alphanumeric keys, a 2.25-unit left Shift, a 2.75-unit right Shift, and an L-shaped , facilitating consistent in and compatible regions. In contrast, the [International Organization for Standardization](/page/International Organization for Standardization) (ISO) specifies the European 105-key layout under ISO/IEC 9995, incorporating an additional key (typically for ) adjacent to the left Shift, with adjusted sizes such as a 1.25-unit left Shift and a taller, vertical to accommodate needs while maintaining uniform spacing and positions. Mechanical standards for keycap attachment emphasize compatibility with switch stems, where the Cherry MX design has served as the since its in 1984, featuring a cross-shaped that allows secure, mounting on most mechanical keyboards through an expired enabling widespread adoption by manufacturers. Complementing this, ISO 9995 provides ergonomic principles for keyboard layouts, including tolerances for keycap spacing (typically 19 mm center-to-center horizontally and vertically), shapes, and relative placements to minimize user fatigue and promote across text and office systems. Certifications further govern keycap production, with the European Union's mandating compliance for materials like or PBT plastics, limiting lead, mercury, , and other toxins to below 0.1% by weight to protect and the in electronic components such as keycaps. Additionally, the USB (HID) class standard indirectly supports keycap legend universality by defining consistent usage codes for keys (e.g., HID Usage ID 0x04 for 'A'), ensuring that legends like alphanumeric characters and symbols are interpretable across operating systems without custom drivers.

Community and Aftermarket Practices

The mechanical keyboard enthusiast community thrives on customization of keycaps, driven by a desire to personalize experience and beyond stock offerings. Online vendors such as Drop.com specialize in selling diverse keycap sets, ranging from standard PBT and profiles to limited-edition designs, enabling users to upgrade their keyboards easily. Similarly, platforms like KBDfans and CannonKeys provide extensive inventories of aftermarket keycaps, supporting the hobbyist that emphasizes quality and variety in materials and layouts. This has fueled significant economic activity, with the custom keycaps segment valued at approximately $710 million in 2025 and projected to grow at a 5.12% CAGR through 2035. Central to this community is Reddit's r/MechanicalKeyboards subreddit, created on July 10, 2012, which has grown to over 1.3 million subscribers and serves as a primary for discussions, showcases, and resource sharing on keycap modifications. Group buys represent a hallmark practice, where enthusiasts collectively fund the production of bespoke keycap sets through organizers on sites like KeebFinder, often resulting in unique designs unavailable through retail channels; for instance, GMK collaborations have become iconic for their high-quality double-shot molding and thematic coherence. These initiatives not only democratize access to premium keycaps but also foster collaboration among designers, vendors, and users, with hundreds of active group buys tracked annually across the community. Modification techniques further exemplify community ingenuity, including swapping entire keycap sets for themed aesthetics, such as anime-inspired collections featuring characters from series like or , available from specialized retailers like MyAnimeKeycaps.

References

  1. [1]
    Ultimate guide on keyboard keycaps:All you need to know.
    ### Summary of Keycaps for Encyclopedia Introduction
  2. [2]
    Keycaps: The Essential Guide for Keyboard Enthusiasts - HHKB
    ### Summary of Keycaps Guide
  3. [3]
    Guide for Keycap Profiles | Types, Shapes, and Layouts Explained
    ### Summary of Keycap Information
  4. [4]
    Understanding Keycaps: A Closer Look at Legends and Sub-Legends
    Keycaps are the removable caps placed over the switches of a keyboard. They are typically made from plastic or metal and vary in shape, size, and color, ...
  5. [5]
    Glossary of Important Terms in Mechanical Keyboard - Credkeys
    Mar 28, 2024 · Keycaps are the physical covers placed on top of the switches. They are of different shapes, sizes, and materials, allowing for customization ...<|separator|>
  6. [6]
    All the Parts of a Mechanical Keyboard Explained
    May 12, 2022 · When you push on a keycap, it pushes down the switch and activates the keystroke. Both the keycaps and the switches are above the top plate, ...
  7. [7]
    https://gimsuncustom.com/blogs/gimsuncustom-keyboard-keycaps/keyboard-anatomy-101-understanding-keycap-sizes-and-layout-standards
  8. [8]
    Keyboard Anatomy 101: Understanding Keycap Sizes and Layout ...
    Keycap sizes are measured in 'u' units, with 1u being about 19.05mm. Alphanumeric keys are typically 1u wide, while spacebars are 6.25u. ANSI and ISO layouts ...
  9. [9]
    The Size Effects Of Keyboards (Keycaps) On Computer Typing Tasks
    The research tested QWERTY and Dvorak layouts, finding the Dvorak layout led to a 12% reduction in typing errors. When do keycap slopes affect typist ergonomics ...
  10. [10]
    Analysis of the relationship between keycaps and ergonomics
    ### Summary of the Relationship Between Keycaps and Ergonomics
  11. [11]
    [PDF] Haptic Keyclick Feedback Improves Typing Speed and Reduces ...
    The present study used a flat keyboard without moving keys and enabled with haptic keyclick feedback to.<|separator|>
  12. [12]
    https://www.researchgate.net/publication/361261752_How_a_Few_Custom_Keycaps_Make_Keyboards_More_Ergonomic_and_Reduce_Eye_Movement_by_35
  13. [13]
    Braille Keycaps Guide: Enhance Accessibility with Keyboards
    Aug 26, 2024 · Keycaps are essential in making keyboards accessible for visually impaired users, helping them type more accurately and navigate computers more ...
  14. [14]
    (PDF) How a Few Custom Keycaps Make Keyboards More ...
    Ergonomically designed devices for better workplace design get too little at-tention compared to the annual cost of long-term damage.
  15. [15]
    Keycap Profiles Comparison: Which One Matches Your Style?
    No readable text found in the HTML.<|separator|>
  16. [16]
    US79265A - Improvement in type-writing machines - Google Patents
    ### Summary of Keys or Keycaps in Typewriter Patent US79265A
  17. [17]
    Sholes, Glidden, & Soule Typewriter Patent Model
    Physical Description: wood (overall material) ; Measurements: overall: 5 1/4 in x 12 1/4 in x 12 1/8 in; 13.335 cm x 31.115 cm x 30.7975 cm.
  18. [18]
    Production on the Sholes and Glidden Type-Writer Began
    In the U.S., one of the first commercially made typewriters was patented in 1868 (US 79,265 External) by Christopher Latham Sholes, Carlos Glidden, and Samuel W ...
  19. [19]
    Typewriter by E Remington & Sons, 1874-1878
    This is the first typewriter to use the QWERTY keyboard, the keys are metal with clear glass tops, the characters underneath are black printed on white.
  20. [20]
    Century Typewriter Model Serial Number Database
    In 1890, keys changed to a Vegetable Ivory keytop with engraved characters, then later the key shape was changed to hexagonal from round. 35,160,161, 162,163.
  21. [21]
    [PDF] Underwood service manual - the Xavier University Personal Web Site
    key tops are loose on key levers, they can be made solid by soldering or wedging in place with prick punch. The key ring glass and paper should be taken out ...
  22. [22]
    Key-Driven Calculators ("Comptometers") - John Wolff's Web Museum
    Dec 8, 2017 · The key-driven calculator, of which the "Comptometer" is the definitive example, was the work-horse of business and commercial offices for almost eighty years.<|control11|><|separator|>
  23. [23]
    The standardization of a technical practice: typing (1883-1930)
    The progressive standardization of typing was structured around the ten-finger technique, the memorization of the keyboard and new positions for the body. It ...
  24. [24]
    When Did Membrane Keyboards Come Out: A Brief History
    The earliest version of the custom membrane keyboards were invented in the 1970s by George H. Heilmeier, a scientist at RCA.
  25. [25]
    The Evolution of Mechanical Keyboards: A Brief History
    May 2, 2023 · Mechanical keyboards can be traced back to the 1970s. · As the popularity of mechanical keyboards grew, more companies began to produce them.
  26. [26]
    Chiclet keyboard - Wikipedia
    A chiclet keyboard is a computer keyboard with keys that form an array of small, flat rectangular or lozenge-shaped rubber or plastic keys that look like ...
  27. [27]
    Inside the World's Greatest Keyboard | PCWorld
    Jul 8, 2008 · Almost every key on the keyboard has an easily removable keycap that allowed the user–or IBM–to easily change the layout or color of the ...
  28. [28]
    The History of Cherry Keyboards
    Apr 27, 2022 · 1980s: Revolutionary Cherry MX Switches​​ In 1984, the company released the Cherry G80-0427 keyboard, one of the first to feature Cherry MX Black ...Missing: modular | Show results with:modular
  29. [29]
    The History of Cherry MX Keyboard Switches @CherryMX
    Jul 31, 2018 · It was the MX switch, a device that the company first built in the 1980s, that came to define the Cherry name. Patented in 1984, the device ...Missing: keycaps | Show results with:keycaps
  30. [30]
    When Did Mechanical Keyboards Become Popular - Meetion
    Mar 9, 2024 · It wasn't until the rise of gaming culture in the early 2000s that mechanical keyboards began to regain their popularity. The gaming ...
  31. [31]
    The Best Wireless Keyboards of 2025 - Tech Gear Lab
    May 22, 2025 · The lightest keyboards in our lineup include the Omoton (8 ounces), Apple (13 ounces), K380s (15 ounces), and Arteck (15 ounces) and Pebble ...
  32. [32]
    ABS vs PBT keycaps: Which is better?
    ### ABS vs PBT Keycaps Summary
  33. [33]
    Should I buy ABS vs. PBT Keycaps? | Kinetic Labs Blog
    Jul 13, 2022 · Mechanical keyboard keycaps made from PBT are thicker, heavier, and stronger than ABS keycaps, leading to an overall improvement in durability ...
  34. [34]
    ABS vs PBT Keycaps - RTINGS.com
    Aug 26, 2025 · ABS keycaps generally produce a brighter, higher-pitched "click" sound compared to PBT's deeper "thock." This will vary from one keycap to ...
  35. [35]
    Clear Keycaps Materials Explained: ABS vs PBT vs Polycarbonate
    Aug 10, 2025 · Cons: Most expensive keycap material option; Limited availability compared to ABS/PBT; Can feel slightly harder than other materials; Fewer ...
  36. [36]
    https://oshid.com/blogs/news/explore-the-dye-sublimation-keycap-process-the-perfect-collision-of-personalization-and-quality
  37. [37]
    https://kineticlabs.com/blog/dye-sublimation-vs-double-shot-legends-in-keyboard-keycaps
  38. [38]
    Dye-Sub vs Double-Shot Legends in Keyboard Keycaps - Kinetic Labs
    Apr 15, 2023 · If purchased from a reputable brand, dye-sublimated legends on a keycap should last a lifetime and will not crack (for example some vintage ...Missing: retention 50000 hours
  39. [39]
    https://glacierpcgaming.com/blogs/news/understanding-key-switch-stems-why-they-matter-in-keycap-compatibility
  40. [40]
    Understanding Key Switch Stems: Why They Matter in Keycap Compatibilit
    ### Summary of Key Switch Stem Types and Compatibility
  41. [41]
    A Guide to Cherry MX Switches - Das Keyboard
    Mar 28, 2022 · Switching slide/stem: When pressed, the keycap pushes down a certain amount of pre-travel distance on the stem when it slides inside the body of ...
  42. [42]
    How to Buy the Best Keycaps for Your Mechanical Keyboard - WIRED
    Mar 24, 2025 · The three most common “alternative” switches are Alps switches, which have a small minus-shaped stem, Topre (also referred to as EC) switches, ...<|separator|>
  43. [43]
    https://blog.silverpc.hu/2025/10/21/keycap-swap-question-will-keys-from-a-logitech-g213-suit-a-g-pro-with-linear-switches/
  44. [44]
    Keycap Swap Question: Will Keys from a Logitech G213 Suit a G Pro ...
    Oct 21, 2025 · Logitech's GX switches are Cherry MX clones, meaning they use the same cross-shaped stem. Even Logitech's proprietary Romer-G switches, while ...
  45. [45]
    https://unikeyboards.com/blogs/weekeebpedia/how-to-replace-keycaps-on-your-mechanical-keyboard-step-by-step-guide
  46. [46]
    https://keebsforall.com/blogs/mechanical-keyboards-101/keycaps-not-fitting-common-causes
  47. [47]
    https://thomasbaart.nl/2019/02/10/keycap-count-by-size-and-row-for-ansi-and-iso/
  48. [48]
    Keycap count by size and row for ANSI and ISO keyboard layouts
    Feb 10, 2019 · In this post, you'll find keycap counts for ANSI 104 and ISO 105. I have not included the counts for JIS, since I wasn't able to find a definitive standardized ...
  49. [49]
    https://www.daskeyboard.com/blog/types-of-keycap-profiles/
  50. [50]
    Keycap Profile & Size Information - MAX Keyboards
    Sep 23, 2016 · Different rows (R1-R4) on the keyboard have different height and angle slope. Below is the chart illustrate our keycap profile. Max Keyboard ...
  51. [51]
    https://blog.maxkeyboard.com/dwkb/keycap-profile-size-information/
  52. [52]
    Keycap Profiles: How to Choose the Best Type for You - HHKB
    ### Summary of Keycap Profiles: OEM, Cherry, SA
  53. [53]
    https://www.keychron.com/blogs/news/oem-vs-cherry-profile
  54. [54]
    https://en.akkogear.com/blog-ultimate-guide-to-keycap-profiles/
  55. [55]
    https://www.cerakey.com/blogs/all-blog/a-complete-guide-to-keycaps-profile-and-material
  56. [56]
    https://hirosarts.com/blog/sa-profile-keycap-guide/
  57. [57]
    https://hirosarts.com/blog/what-are-artisan-keycaps/
  58. [58]
    Artisan Keycap History
    Typewriter with QWERTY layout first developed and patented in 1868 by Christopher Sholes, Carlos Glidden, and Samuel W. Soule. The first keyboard with a Shift ...
  59. [59]
    https://www.gmk.net/shop/en
  60. [60]
    How to Make Resin Artisan Keycaps - Part 1: Getting Started and ...
    Feb 17, 2021 · Learn what materials, equipment, and techniques you need in order to sculpt, mold, and cast resin artisan keycaps for mechanical keyboards.
  61. [61]
    dwarf factory's entire making keycap process
    Aug 3, 2020 · >> MODEL THE 3D PROTOTYPE. When we decide to produce a keycap with a big volume, we study 3D printing and learn to use the help of new ...
  62. [62]
    KeyCon 2024 Artisan Sessions
    May 6, 2024 · A brief walk through artisan keycap history, showcasing caps from each era. Includes a retrospective of early Keycon events.
  63. [63]
    https://thekapco.com/blogs/article?page=2
  64. [64]
    https://www.keychron.com/blogs/news/what-is-ansi-keyboard
  65. [65]
    #ORIGINALMX: OFTEN COPIED, NEVER REACHED! - Cherry
    The first mechanical key switch ever was the MX Black, which was introduced in 1983. With this switch, CHERRY laid the foundation for the MX technology which is ...
  66. [66]
    [PDF] HID Usage Tables - Universal Serial Bus (USB)
    Oct 12, 2020 · These are HID Usage Tables for Universal Serial Bus (USB), version 1.21, and include an introduction, management overview, and usage pages.
  67. [67]
    https://drop.com
  68. [68]
    https://kbdfans.com
  69. [69]
    Custom Keycaps Market Trends [2025], Scope & Forecast [2035]
    Oct 27, 2025 · The global custom keycaps market stood at $ 0.71 billion in 2025 and will grow to $ 0.75 billion in 2026 and $ 1.17 billion by 2035, ...
  70. [70]
    None
    - **Creation Date**: The subreddit r/MechanicalKeyboards was created on July 10, 2012 (derived from Unix timestamp 1341751668.0).
  71. [71]
    Custom Keyboard and Keycaps Group Buys & Pre-Orders
    Stay ahead of the curve with KeebFinder's comprehensive list of active group buys and pre-orders for mechanical keyboards and related products.
  72. [72]
    r/MechanicalKeyboards Wiki: Keycap Shopping Guide - Reddit
    Nov 8, 2021 · This keycap shopping wiki page lists keycap vendors, but that might not be what you were looking for. Here are some links to other keycap-related wiki pages.
  73. [73]
    https://myanimekeycaps.com/
  74. [74]
    https://attackshark.com/blogs/news/keyboard-switch-lubing-guide
  75. [75]
    Tools to Mod Your Mechanical Keyboard Switches - Kinetic Labs
    Feb 26, 2025 · Here's the exact types of tools you will need to interact with, modify, and customize your mechanical keyboard switches.