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Security printing

Security printing is a specialized branch of the printing industry that employs advanced techniques, materials, and processes to produce documents and products resistant to forgery, counterfeiting, and tampering, such as banknotes, passports, cheques, identity cards, and tamper-evident labels.^[1]^[2] These methods integrate visible, hidden, and machine-readable features to authenticate items of high value, ensuring public trust in financial systems, personal identification, and product safety.^[1]^[2] The practice traces its origins to over 5,000 years ago in ancient Mesopotamia, where clay bullae served as early seals for document authentication, evolving through classical antiquity and in China with rudimentary stamping methods.^[1] In Europe, wax seals dominated until the 19th century for securing official documents, but by the mid-20th century, the focus shifted to printed seals and packaging due to rising tampering incidents, including a 1993 U.S. epidemic with 235 reported cases of product adulteration.^[1] A pivotal modern milestone occurred in 1982 when the U.S. Food and Drug Administration mandated tamper-resistant packaging following the cyanide-laced Tylenol poisonings, accelerating the integration of security features into labels and seals.^[3] Key techniques in security printing include intaglio printing, a centuries-old process that creates raised ink impressions for intricate details on banknotes and passports; letterpress for precise numbering; and simultan presses for accurate front-to-back alignment, such as see-through registers.^[1]^[4] Additional features encompass watermarks embedded in paper during manufacturing, holograms and optically variable inks that shift appearance with angle or light, microprinting too fine for casual replication, and security threads woven into substrates.^[1]^[2] Contemporary advancements incorporate UV-fluorescent inks, encrypted QR codes, and RFID tags for machine verification, enhancing layers of protection against sophisticated threats.^[2] Applications of security printing span government-issued documents like passports and currency, where features such as holograms and window threads deter forgery, as seen in British banknotes targeted in 1990s counterfeiting attempts.^[1] In the financial sector, it secures cheques and stock certificates with intricate designs and numbering to prevent fraud.^[2] Beyond documents, it protects pharmaceutical and cosmetic packaging with tamper-evident seals and serialized labels, while also authenticating software distribution via holographic stickers and enabling traceability in supply chains through RFID and blockchain integration.^[1]^[3] These measures are critical for mitigating economic losses from counterfeiting, estimated at hundreds of billions of dollars annually as of 2019, and safeguarding public health and security.^[5]

History and Evolution

Origins and Early Techniques

Security printing originated with ancient efforts to authenticate valuable items and prevent counterfeiting, beginning with the invention of coinage in the kingdom of Lydia around 630 BCE. Lydian rulers stamped electrum ingots—natural alloys of gold and silver—with official symbols using signet ring-like tools, guaranteeing their weight and purity to facilitate trade and deter imitation. This stamping technique marked the earliest known anti-counterfeiting measure, as counterfeiting emerged almost immediately after the introduction of standardized coins.^[6] In China, during the Tang dynasty in the 8th century CE, the precursors to paper money appeared as "flying cash" (feiqian), government-issued certificates designed to replace cumbersome copper coins for long-distance trade. These promissory notes were authenticated through official seals from the imperial treasury, providing basic verification of legitimacy and reducing the risk of forgery by limiting private issuance. By the Song dynasty (10th–13th centuries), this evolved into printed jiaozi banknotes with more elaborate seals and multicolored designs, further enhancing security against replication.^[7]^[8] The intaglio printing technique, which involves incising designs into a plate to hold ink in recessed lines, emerged in Europe during the 15th-century Renaissance, initially for artistic prints and maps. By the late 17th century, it was adapted for banknotes, with Sweden's Stockholms Banco issuing the first European paper currency in 1661 using copper-plate intaglio engraving to create fine, intricate details that were labor-intensive to copy. This method's raised ink and complex vignettes became a cornerstone of security printing, making unauthorized reproductions detectable through inferior line quality.^[9]^[10] In 19th-century Britain, guilloché patterns—intricate, interlocking geometric designs produced by mechanical lathes—were innovated as a key anti-counterfeiting feature for banknotes and documents. Firms like those associated with the Bank of England, under influences such as governor Thomson Hankey in the 1850s, incorporated these fine-line rosettes and spirals, which required specialized equipment and skill to replicate accurately. This technique deterred forgers by creating visually complex backgrounds that blurred when photocopied or poorly printed.^[11]^[12] A pivotal development occurred in the United States during the Civil War, when the Legal Tender Act of 1862 authorized the first federal banknotes—known as United States Notes—to finance the war effort amid rampant counterfeiting of state bank currency. These notes employed steel-plate engraving, a durable advancement over copper that allowed for sharper, more detailed vignettes and portraits, such as those of Salmon P. Chase and Liberty. By the war's end, an estimated one-third of circulating currency was fake, prompting the establishment of the Secret Service in 1865 specifically to combat this issue, with steel engraving proving instrumental in elevating U.S. security printing standards.^[13]^[14]

20th-Century Developments

The 20th century marked a significant shift in security printing toward industrialization, enabling mass production of secure documents like banknotes while incorporating more sophisticated anti-counterfeiting measures. Offset lithography, developed in the early 1900s, gained widespread adoption during the 1920s and 1930s for high-volume printing applications, including security features such as background patterns on currency and bonds, due to its efficiency in reproducing fine details and colors compared to earlier intaglio methods. This technique allowed printers to produce larger quantities at lower costs, facilitating the expansion of national currency systems post-World War I.^[15]^[16] A key innovation in substrate security emerged in the 1930s through collaboration between the Bank of England Printing Works and Portals Paper Mill, leading to the development of embedded metallic security threads designed to deter counterfeiting. These threads, initially continuous metal strips incorporated during papermaking, were first introduced in British £1 banknotes in 1940 amid concerns over wartime forgery attempts by Axis powers. Portals' expertise in cylinder-moulded paper enabled the seamless integration of these covert features, which became visible when held to light and set a precedent for global banknote security.^[17]^[18] Post-World War II, advancements in optical technologies drove the creation of optically variable inks (OVI) in the 1970s, based on thin-film interference pigments, with the first use on banknotes occurring in the late 1980s. The U.S. Bureau of Engraving and Printing (BEP) later adopted OVI in the 1990s as part of enhanced currency features; the first implementation appeared on the $100 Federal Reserve note in 1996, where the ink shifts color (e.g., from green to black) depending on viewing angle, providing a dynamic human-detectable safeguard against reproduction. This built on earlier intaglio roots but emphasized color-shifting effects for mass-produced notes.^[19] By the late 20th century, holograms emerged as a high-impact overt feature, prompting the formation of the International Hologram Manufacturers Association (IHMA, now the International Optical Technologies Association or IOTA) in 1993 to standardize and promote their integration in security printing. The IHMA, established by leading producers, focused on anti-counterfeiting applications for banknotes and documents, fostering global collaboration on hologram quality and authentication amid rising digital threats. This organization played a pivotal role in embedding diffractive optics into currency designs worldwide during the 1990s.^[20]

Modern Innovations and Standards

One of the most significant advancements in security printing since the late 20th century has been the transition to polymer substrates for banknotes, which offer enhanced durability, resistance to counterfeiting, and environmental benefits compared to traditional paper. Australia pioneered this shift with the issuance of the world's first circulating polymer banknote, a commemorative $10 note in January 1988, marking the bicentenary and incorporating advanced plastic-based materials developed by the Reserve Bank of Australia in collaboration with Note Printing Australia. By the 2010s, adoption became widespread globally, exemplified by the United Kingdom's introduction of polymer £5 notes in 2016, featuring improved security elements like transparent windows and tactile prints, as announced by the Bank of England to replace aging paper series and reduce circulation wear. This material innovation has since been embraced by over 70 countries (as of 2025), including Canada and the United Kingdom, contributing to longer note lifespans—up to 2.5 times that of paper equivalents—and lower replacement costs for central banks.^[21] In parallel, the 2010s saw the rise of nano-optic features, leveraging nanoscale structures to create sophisticated 3D visual effects without relying on traditional holograms, thereby complicating replication through high-precision lithography. These features, such as nano-optical images integrated into security holograms, manipulate light at the nanometer scale to produce dynamic, parallax-driven animations and color shifts visible under normal viewing conditions, enhancing authentication for documents and banknotes. For instance, technologies like those from Nanotech Security Corp. introduced multi-color, full-parallax depth effects in the mid-2010s, applied to high-security applications including passports and currency to deter sophisticated forgers by requiring specialized nanofabrication equipment. International standards have formalized these innovations to ensure consistency and reliability in security printing processes. The ISO 14298 series, first published in 2013 and updated in 2021, establishes requirements for security printing management systems, including risk assessment, personnel vetting, and supply chain controls to certify printers handling sensitive items like banknotes and IDs. Complementing this, the European Central Bank's guidelines for eurozone banknotes, outlined in the Europa series roadmap since 2013, mandate advanced features such as enhanced watermarks, holograms, and optically variable inks, with all notes produced under strict Eurosystem quality protocols to maintain integrity across member states. Emerging digital integrations, such as blockchain for serial number tracking, have entered pilot explorations by central banks in the 2020s to combat counterfeiting and monitor circulation in real-time. Research proposals from 2020 onward describe blockchain systems for localizing and verifying banknote serial numbers during exchanges, enabling immutable ledgers that central banks could integrate into pilot programs for enhanced traceability without altering physical notes. While full-scale adoption remains in early stages, these initiatives build on CBDC pilots to potentially link physical and digital asset tracking, as explored in academic and industry frameworks.

Substrates and Materials

Paper Substrates

Paper substrates form the foundational material in traditional security printing, particularly for banknotes and high-value documents, due to their cellulose-based composition derived from natural fibers. These substrates are typically made from a blend of cotton and linen rag fibers, with United States currency paper consisting of 75% cotton and 25% linen to provide exceptional durability and a distinctive crisp texture without incorporating wood pulp or starch, which could compromise security tests.^[22]^[23] The high cotton content, often ranging from 75% to 100% in various security papers, ensures long fiber length that enhances tensile strength and resistance to tearing during handling.^[24] Additives such as cationic polymers or specialized sizing agents may be incorporated during pulping to further bolster dry strength and prevent fiber separation, though formulations avoid common fillers like starch to maintain authenticity verification properties.^[25] A key security aspect of paper substrates lies in the integration of embedded elements during the manufacturing process, which deter counterfeiting by adding verifiable physical characteristics. Visible colored fibers, such as red and blue strands, are randomly distributed throughout the paper sheet to create an irregular pattern that is difficult to replicate precisely, as seen in genuine U.S. currency where these fibers are randomly embedded throughout the paper.^[26] Metallic or fluorescent fibers, often invisible under normal light but glowing under ultraviolet (UV) examination, provide an additional layer of authentication, with the metallic variants offering a subtle sheen that enhances tamper detection.^[27] Complementing these are planchettes—small, disc-shaped particles (typically 2-4 mm in diameter) with a metallic or iridescent coating—that are interspersed within the pulp, creating sparkling inclusions visible to the naked eye and reactive under UV light for machine-readable verification.^[28] Watermarks, another integral security feature, are formed directly into the paper substrate during the papermaking process using a dandy roll or cylinder mold that varies the fiber density to produce translucent images or patterns, such as portraits or denominations, visible when held against light.^[29] This technique dates back to colonial U.S. currency in the 18th century and was reintroduced in modern federal notes starting with the 1996 series to enhance security against counterfeiting.^[22] The process involves feeding the cotton-linen pulp onto a wire mesh screen with a relief design, allowing excess water to drain unevenly and embed the watermark as a permanent, integral part of the substrate rather than a printed overlay.^[30] Paper substrates offer distinct advantages in security printing, including a premium tactile feel that users associate with authenticity—characterized by a crisp, non-porous surface that resists ink bleeding—and compatibility with traditional printing methods like intaglio for raised ink effects.^[31] However, they are susceptible to wear from soil, folding, and moisture, with average circulation lifetimes varying by denomination from about 5.8 years for $5 notes to 22.9 years for $100 notes in high-use scenarios, according to Federal Reserve estimates as of 2023.^[32] Recycling poses challenges due to the embedded security elements, such as metallic fibers and planchettes, which can contaminate standard paper recycling streams and require specialized de-inking processes to separate fibers without damaging authenticity features.^[25]

Polymer and Hybrid Substrates

Polymer substrates represent a significant advancement in security printing, utilizing synthetic materials to enhance durability and incorporate unique optical security elements that are difficult to replicate. These substrates are primarily composed of biaxially oriented polypropylene (BOPP), a thin, flexible plastic film that provides resistance to wear, tearing, and moisture compared to traditional paper. BOPP is produced by stretching polypropylene sheets in both longitudinal and transverse directions, resulting in a strong, transparent base that can be opacified with white or colored layers for printing while retaining areas of clarity for specialized features.^[33] The development of polymer substrates for security applications originated from research by Australia's Commonwealth Scientific and Industrial Research Organisation (CSIRO), which filed the first patent for polymer banknotes in 1973 to address rising counterfeiting threats following the introduction of color photocopiers. This innovation laid the foundation for modern polymer notes, with the first issuance occurring in Australia in 1988. In addition to full polymer substrates, hybrid variants combine paper with polymer layers, such as laminates where a polymer film is fused to paper cores, offering a balance of tactile familiarity and enhanced protection. These hybrids are particularly used in passports, where the polymer component strengthens data pages against tampering and environmental damage while allowing integration of paper-based security elements like watermarks.^[34]^[35] Key security features in polymer and hybrid substrates exploit their transparency and multi-layer structure. Transparent windows, often positioned at edges or centrally, enable see-through registers where printed elements on both sides of the note align precisely when held to light, creating intricate patterns or images that verify authenticity. In hybrids, the polymer core facilitates crystal-clear windows like Thrusafe™ or Viewsafe™, which can incorporate diffractive optics or threads visible only from specific angles, adding layers of machine-readable security. Unlike paper, which excels in providing a distinctive tactile feel, polymer's smooth surface prioritizes optical verification over texture.^[36]^[35] Notable examples include Canada's polymer $20 note, introduced in 2012 as part of the Frontiers series, featuring a holographic stripe with a metallic portrait of Queen Elizabeth II that shifts colors and a frosted maple leaf transparent window for see-through alignment. Durability tests demonstrate that polymer notes withstand circulation approximately 2.5 times longer than paper equivalents, reducing replacement frequency and associated costs over time.^[37]^[38] Recent advancements as of 2025 include bio-based polymer alternatives and advanced film concepts, such as Covestro's polymeric substrates, aimed at improving sustainability and recyclability while maintaining security.^[39] Despite these advantages, polymer and hybrid substrates face challenges, including higher initial production costs due to specialized extrusion and lamination processes, which can exceed those of paper by 20-50% per unit. Environmental concerns also arise from recyclability issues, as BOPP-based polymers are derived from petrochemicals and require energy-intensive sorting and processing at end-of-life, unlike paper's more straightforward pulping. Ongoing research aims to improve bio-based alternatives and recycling methods to mitigate these impacts.^[40]^[41]

Specialized Formats and Coatings

Specialized formats in security printing deviate from standard rectangular shapes to incorporate tactile variations and complicate automated replication or scanning processes. For instance, some identification documents feature rounded corners, which enhance durability by reducing wear at edges while subtly altering the document's profile to disrupt scanner alignment algorithms designed for uniform rectangular inputs. This format choice aids in human verification through feel and makes high-fidelity counterfeiting more challenging, as precise edge replication requires advanced die-cutting equipment.^[42] Variable thickness formats further contribute to tactile security by creating uneven surfaces that can be discerned by touch, integrating seamlessly with raised printing elements for enhanced authenticity checks. These variations, often achieved through layered substrates or embossing, provide a subtle dimensional profile that resists flat-bed scanning and promotes manual inspection. In integration with tactile printing techniques, such formats amplify detectability without relying on optical aids.^[43] Coatings applied post-substrate production play a critical role in bolstering security by adding protective and interactive layers that deter tampering and environmental degradation. UV-curable varnishes, which polymerize rapidly under ultraviolet light, offer superior scratch resistance to printed security elements, preserving intricate patterns like guilloches or microtext during circulation. These varnishes are particularly valued in high-security applications for their ability to maintain print integrity under mechanical stress, as seen in formulations tailored for offset and flexographic processes.^[44] Anti-soiling coatings, such as those developed through trials in the mid-2000s and applied to later euro banknote series (e.g., Europa series from 2019 onward), form a thin protective barrier that repels dirt, oils, and moisture, extending note lifespan and reducing replacement costs. Applied via high-speed coaters, these layers—often polymer-based—enhance circulation durability by up to 200% in some implementations, while maintaining the note's aesthetic and functional qualities. For example, trials on 20 and 50 euro denominations demonstrated improved soil impermeability, addressing common counterfeit vulnerabilities in soiled conditions.^[45]^[31] Tamper-evident coatings represent another specialized application, designed to reveal latent images or warning patterns upon abrasion or attempted removal, thereby exposing alterations. These interactive layers, typically comprising micro-encapsulated inks or fragile films, activate under friction to display hidden motifs like "VOID" or authentication symbols, serving as a forensic deterrent against forgery. Such coatings are integral to documents requiring post-issuance integrity, ensuring that any surface manipulation compromises the security feature visibly. A notable example of innovative format integration is the 2019 Eastern Caribbean polymer banknotes, which employ a flexible, foldable design allowing repeated bending without creasing or delamination, thereby enhancing portability and resistance to wear. This format, issued in denominations from $5 to $100, combines with durable coatings to achieve a circulation life approximately three times longer than traditional paper equivalents, while the foldability itself acts as a subtle security cue against rigid counterfeit attempts.^[46]

Human-Detectable Security Features

Visible Features

Visible features in security printing encompass overt elements designed for easy public authentication using the naked eye, typically by holding the document to light or tilting it to observe dynamic effects. These features deter counterfeiting by incorporating complex optical properties that are difficult to replicate without specialized equipment. Common examples include watermarks, security threads, optically variable inks, and diffractive devices like holograms and kinegrams, each contributing to layered visual verification.^[29] Watermarks are translucent, multi-tonal images or patterns embedded into the paper substrate during the manufacturing process by varying the thickness and density of fibers, creating lighter and darker areas visible when the document is held against light. This technique, originating from traditional papermaking, produces a three-dimensional effect that integrates seamlessly with the substrate, making it resistant to photocopying or scanning replication. For instance, United States dollar bills feature portrait watermarks, such as the faint image of Benjamin Franklin on the $100 note, positioned to the right of the main portrait and discernible from both sides when backlit.^[26]^[47]^[29] Security threads consist of narrow metallic, plastic, or polymer strips embedded or windowed into the substrate, appearing as a continuous dark line when held to light and often incorporating microprinted text or holographic elements for added visibility. These threads enhance authenticity checks by their precise placement and material properties, which cause them to shimmer or reveal hidden patterns under normal viewing conditions. In euro banknotes, the security thread is a metallized strip with a holographic effect, displaying the denomination value and "EURO" in microtext, visible as a dark stripe across the note when backlit.^[48]^[49] Optically variable ink (OVI) employs interference pigments that produce color-shifting effects based on the angle of light incidence and observation, appearing as one color straight-on and transforming to another when tilted. This overt feature relies on thin-film multilayer coatings, typically using materials like titanium dioxide and silica, to create iridescent shifts that are challenging for counterfeiters to mimic accurately. The United States $100 Federal Reserve Note, redesigned in 1996, introduced OVI on the lower-right numeral "100," which shifts from green to black, enhancing public verification of high-denomination bills.^[50]^[51]^[52] Holograms and kinegrams are diffractive optically variable image devices (DOVIDs) that generate three-dimensional, motion-based illusions through light diffraction on microstructured surfaces, revealing animated patterns, depth, or flipping images upon tilting. Holograms, often produced via laser interference, are foil-based patches or stripes that display kinetic effects like moving stars or portraits, while kinegrams utilize advanced diffractive gratings for smoother, customizable animations exclusive to secure applications. These DOVIDs are integrated into banknotes and identity documents for vivid, public-facing authentication; for example, Australian polymer banknotes incorporate holographic patches with dynamic bird motifs, and kinegrams appear on Swiss identity cards as tilting seals with color transitions.^[53]^[54]^[55]

Tactile Features

Tactile features in security printing are designed to be detectable by touch, providing an accessible method for authenticity verification, particularly for visually impaired individuals. These elements create distinct textures or raised surfaces that differ from common counterfeits, enhancing public confidence in documents like banknotes and passports. By relying on the sense of touch, they complement visual inspections and serve as a first-line defense against forgery. Intaglio printing is a cornerstone tactile feature, achieved through high-pressure engraving where ink is forced into recessed plate areas, resulting in raised relief on the substrate. This technique produces portraits and other motifs on banknotes with a height typically between 0.05 and 0.1 mm, allowing users to feel the distinct elevation by running a finger across the surface. For instance, the portraits on Australian banknotes feature this raised intaglio texture for easy identification. The process not only imparts a premium feel but also makes replication challenging due to the specialized equipment required. Embossing provides another key tactile element, involving the creation of raised or recessed impressions without ink, either as blind embossing or registered with printed designs. In passports, blind embossing is often used for subtle textures, such as intricate patterns on covers or data pages, which can be felt but not easily seen. Examples include the galaxy motif blind-embossed on certain passport pages by manufacturers like IDEMIA, adding a layer of security through verifiable texture. This method is particularly effective for personal documents, where the embossed elements protect sensitive areas like portraits from tampering. The substrate material significantly influences the overall tactile experience. Traditional cotton rag paper, composed of high-quality cotton fibers, imparts a crisp, firm feel to banknotes, distinguishing them from smoother counterfeits or alternative materials. This texture is a trusted sensory cue for users, as noted in the production of many national currencies. In contrast, polymer substrates offer a smoother, more flexible touch, which, while durable, provides a different but intentional tactile profile to aid differentiation in polymer-based notes. Micro-perforation introduces tactile patterns through laser-drilled micro-holes that form images or symbols detectable by touch in certain configurations. These perforations create subtle raised or uneven surfaces around the holes, enhancing security in banknotes like the Swiss franc series, where they combine visual transmission effects with a faint tactile quality. Such features, often integrated near demetalized windows in polymer notes, allow for basic manual verification while maintaining aesthetic integrity.

Auditory and Olfactory Features

Auditory features in security printing provide a subtle yet effective means for human verification of documents like banknotes, relying on the distinctive sounds generated during handling. Traditional paper substrates, composed primarily of cotton fibers (often 75% cotton and 25% linen in currencies such as the U.S. dollar), produce a characteristic crisp rustle or snap when flicked or rubbed between fingers. This sharper, high-pitched sound arises from the paper's density and fiber structure, making it difficult for counterfeiters using standard wood-pulp paper to replicate accurately.^[56]^[31] In comparison, polymer or hybrid substrates yield a duller, more muted rustle due to their plastic-like composition and smoother surface, which lacks the fibrous texture of cotton paper. This auditory difference aids public familiarity checks, particularly in regions transitioning from paper to polymer notes, such as the United Kingdom's polymer series introduced in 2016. While not as overt as visual features, the sound complements tactile sensations, enhancing overall sensory authentication without requiring tools.^[57]^[58] Olfactory features remain rare in security printing, primarily explored in experimental contexts rather than widespread production. Modern trials with scented inks face challenges like fading over time and environmental variability, rendering them subjective and less reliable for practical use. Research acknowledges potential in olfactory cues for counterfeit detection, though implementation focuses more on machine-based sensors than human perception.^[59] Both auditory and olfactory elements are inherently subjective, influenced by factors like humidity, user hearing or smell sensitivity, and note condition, which can complicate verification. Consequently, production emphasizes consistency in substrate materials to standardize these sensory traits, prioritizing them as supplementary to more robust features.

Features Detectable with Simple Tools

Chemical and Optical Tests

Chemical tests for security printing primarily involve simple reactions using everyday tools to distinguish genuine documents from counterfeits. Counterfeit detection pens, which contain iodine-based ink, exploit the composition of substrate materials in secure prints. When applied to genuine currency paper—typically composed of cotton and linen without added starch—the pen produces a light yellow mark due to the absence of a starch-iodine complex formation. In contrast, counterfeits made from bleached ordinary paper containing starch react to form a dark brown or black mark, indicating fakery. This method, while effective for initial screening, has limitations such as false positives from starch contamination on genuine notes or false negatives from coatings on fakes.^[60] Optical tests rely on basic magnification or light manipulation to reveal subtle printing characteristics. The halo effect, observed under a magnifying glass, appears as a diffuse glow or outline around printed areas in techniques like intaglio or letterpress, resulting from excess ink being squeezed out and partially absorbed into the substrate. This feature is prominent in security documents such as banknotes and checks, where the ink's interaction with the paper fibers creates a subtle spread not easily replicated by copiers or low-quality printers. Forensic examiners use 10x magnification to confirm the halo's presence, which aids in authenticity verification without specialized equipment.^[61]^[62] Latent images constitute another low-tech optical and tactile test, becoming visible through heat or pressure application. These patterns, printed with thermochromic or friction-sensitive inks, remain invisible under normal conditions but darken or change color when rubbed, generating localized heat. For instance, certain silver-based formulations oxidize slightly upon friction, revealing hidden motifs like denominations or symbols on banknotes and checks. This rub-and-reveal mechanism allows quick verification using only finger pressure, enhancing public-level security without advanced tools.^[63] Copy-evident features target reproduction attempts by incorporating elements that degrade or activate during photocopying. Fine-line patterns, consisting of intricate lines thinner than typical scanner resolution, appear sharp on originals but blur or fill in on copies due to the device's inability to resolve micro-details. Similarly, void pantographs embed latent words like "VOID" or "COPY" in the background; these remain camouflaged in the original but emerge prominently when photocopied, as the fine microdots forming the message are selectively lost in reproduction. These designs, common in checks and certificates, provide a clear visual cue of tampering using standard office equipment.^[64]^[65]

UV and IR Basic Detection

Ultraviolet (UV) and infrared (IR) basic detection relies on the optical properties of specialized inks and materials in security printing, which become apparent only under specific wavelengths of light using simple handheld devices. These features are designed to be covert under normal visible light, aiding in the authentication of documents like banknotes by revealing hidden patterns or colors that counterfeiters often fail to replicate accurately.^[66] UV features commonly incorporate fluorescent dyes embedded in security threads or inks that emit visible light when exposed to ultraviolet radiation, typically from a blacklight source around 365 nm wavelength. For instance, in U.S. dollar banknotes, the embedded security thread glows in a denomination-specific color under UV light: blue for $5 bills, orange for $10, green for $20, yellow for $50, and pink for $100.^[48]^[67] This fluorescence arises from photoluminescent compounds that absorb UV energy and re-emit it at longer visible wavelengths, creating a bright glow absent in fakes using standard inks.^[68] In contrast, IR characteristics exploit absorption or transparency differences in the near-infrared spectrum (around 700–1100 nm), where certain inks become invisible or selectively opaque. Euro banknotes, for example, use printing inks formulated to drop out under IR illumination, rendering most of the front-side architectural motif transparent except for a sharp vertical split on the right-hand side; on the reverse, the image is fully transparent, with only the upper serial number (and the value numeral on higher denominations like €50 and above) appearing dark due to IR-absorbing properties.^[69] This selective visibility stems from pigments that do not reflect IR light, unlike common black inks in counterfeits that may remain fully opaque.^[70] Fluorescent fibers, often randomly embedded in the substrate during paper manufacturing, provide another layer of UV-detectable security. These thin threads, invisible under white light, fluoresce in distinct colors—such as red, blue, or green—when illuminated by UV, confirming the document's authenticity through their irregular distribution and spectral response. In banknote production, these fibers are incorporated to mimic natural variations while ensuring machine-invisible complexity for basic checks. Testing with UV and IR involves portable, battery-powered lamps or viewers, which are inexpensive and user-friendly for non-experts like retailers. A handheld UV lamp reveals glowing threads, fibers, or patterns on genuine items, while an IR viewer exposes transparent zones or absorbing elements, highlighting discrepancies in counterfeits where features either fail to appear or exhibit incorrect behaviors.^[71] These tools enable quick, on-site verification without advanced equipment, focusing on spectral mismatches that basic replication cannot achieve.^[72]

Mechanical and Pattern-Based Tests

Mechanical and pattern-based tests form a cornerstone of basic authentication for security-printed documents, relying on physical handling and simple aids like light sources, magnifiers, or rulers to inspect alignments, fine details, and intricate designs that resist replication by unauthorized means. These methods empower users without specialized equipment to detect counterfeits by exploiting the precision of professional printing processes, such as intaglio and offset lithography, which produce features beyond the capabilities of consumer devices. By examining how patterns interact under light or magnification, individuals can verify the document's integrity, distinguishing genuine items from reproductions that often exhibit blurring, misalignment, or coarseness. The see-through register exemplifies precise front-to-back alignment, where complementary graphical elements—such as guilloche rosettes, architectural motifs, or symbolic icons—merge seamlessly when the document is held against transmitted light to form a unified, continuous image. This feature demands sub-millimeter registration accuracy during production, achieved through multi-layer printing on high-tension presses, making it exceptionally difficult for counterfeiters to achieve without industrial-scale equipment. In Euro banknotes, for instance, the Europa series incorporates see-through registers in the architectural illustrations, where windows and portals on opposite sides align to create a coherent European landmark viewable only under light. Similarly, Thai baht notes feature aligned numerical registers, like the embossed "20" visible through a clear window from both sides. Verification involves tilting the document to light and observing the flawless superposition; any offset or distortion signals a fake. Microprinting employs minuscule alphanumeric text or line work, typically under 0.3 mm in height, rendering it illegible to the unaided eye and appearing as uniform strokes or borders, but resolvable as sharp, readable script under 10x magnification. Introduced to counter advancing digital reproduction technologies, this feature capitalizes on the limited resolution of scanners and printers, which blur or fill in the fine characters during copying. On U.S. $100 notes since the 1990 Series, microprinting includes repeated phrases like "USA 100" encircling Benjamin Franklin's collar and along the edges of the Federal Reserve Bank seal, verifiable with a loupe to confirm crisp legibility without bleeding. Australian banknotes similarly integrate microprint in borders and portraits, such as tiny "5" numerals on the $5 note, emphasizing its role in public scrutiny. Geometric lathe work consists of elaborate, mechanically engraved interlacing patterns—known as guilloche—generated by 19th-century rose-engine lathes that rotate and oscillate a cutting tool against a plate to produce thousands of variably curved, fine lines, often tens of micrometers wide, impossible to forge manually or digitally without artifacts. These hypnotic, non-repeating designs serve as tamper-evident backgrounds, with their complexity deterring photographic or inkjet replication due to moiré effects or line inconsistencies. U.S. Demand Notes from 1862 pioneered this in currency, featuring dense lathe-turned borders and vignettes for anti-forgery protection. Modern applications persist in intaglio-raised elements on banknotes, where a magnifying glass reveals the smooth gradients and unbroken continuity; the Bank of Canada describes the process as rocking a metal plate to vary line depth subtly, ensuring patterns withstand casual inspection while challenging precise duplication. False-positive testing incorporates intentional pattern anomalies or misalignments in control samples to rigorously evaluate mechanical verification methods, confirming that detection tools do not erroneously validate flawed documents as authentic. This approach simulates subtle counterfeits, using rulers for dimensional checks or magnifiers for line inspection to calibrate sensitivity thresholds and reduce authentication errors in field use. In security printing workflows, such tests ensure pattern-based features like microtext or registers trigger correct rejections, maintaining system reliability against evolving threats.

Machine-Readable and Advanced Features

Magnetic and Electronic Elements

Magnetic and electronic elements in security printing incorporate materials and technologies that enable automated detection and verification by machines, enhancing anti-counterfeiting measures in documents like banknotes and identification cards. These features rely on magnetic properties or embedded electronics to store and transmit data, allowing for rapid, non-visual authentication in high-volume processing environments such as banking and border control.^[73] One foundational application is Magnetic Ink Character Recognition (MICR), which uses ink formulated with ferromagnetic iron oxide particles, such as magnetite (Fe₃O₄), to create readable characters on negotiable instruments like checks. This ink's magnetic properties allow sorting machines to detect and interpret the encoded information even if the print is smudged or overlaid. The E-13B font, consisting of 14 standardized characters including digits and control symbols, was developed in the 1950s and adopted as the American Bankers Association (ABA) standard in 1958 for check processing, with subsequent international standardization under ISO 1004:1995. MICR lines typically appear at the bottom of checks, encoding account details for automated clearinghouse operations.^[74]^[75]^[76] Magnetic threads represent another key element, embedded within the substrate of banknotes to provide machine-readable authentication. These thin strips, often metallized polymers with incorporated magnetic pigments, generate detectable signals under magnetic sensors, aiding in denomination verification and counterfeit detection in automated systems like vending machines and currency sorters. For instance, euro banknotes feature such threads with magnetic properties that allow devices to confirm the note's authenticity by sensing specific magnetic signatures during processing. This integration ensures the thread's presence and orientation are verifiable without altering the document's tactile feel.^[73]^[77]^[78] Advancing beyond passive magnetic features, electronic elements like Radio Frequency Identification (RFID) chips introduce active data storage in high-security documents. These thin, contactless tags, compliant with ISO/IEC 14443 standards for proximity cards, are embedded in e-passports to hold biometric and personal data in a secure, encrypted format. The International Civil Aviation Organization (ICAO) established global standards for these e-Machine Readable Travel Documents (eMRTDs) in Doc 9303, Part 1, with standards established in 2006, leading to widespread implementation for new passports to facilitate automated border management and identity verification. The chips operate at 13.56 MHz, allowing short-range reading (up to 10 cm) without physical contact, and include public key infrastructure for data integrity.^[79]^[79] Verification of these magnetic and electronic elements often involves specialized readers that analyze unique signal patterns for authenticity. Magnetic stripe readers, for example, detect the irregular distribution of magnetic particles in encoded stripes, creating a "magnetic fingerprint" or signature that is compared against expected profiles to identify alterations or forgeries. This dynamic authentication method, leveraging low-coercivity or high-coercivity stripes, is widely used in access cards and financial instruments to ensure data matches predefined patterns during swiping or insertion. Similarly, RFID readers interrogate chips via electromagnetic fields, retrieving and validating digitally signed data groups like facial images or MRZ information.^[80]^[81]^[79]

Digital and Phosphorescent Markers

Digital and phosphorescent markers represent advanced optical and algorithmic elements in security printing, designed for machine-readable verification that enhances authenticity checks beyond human perception. Phosphorescent inks, a type of light-emitting dye, absorb ultraviolet (UV) light and continue to emit visible light after the excitation source is removed, providing a delayed glow that is difficult for counterfeiters to replicate accurately. These inks are commonly integrated into security threads or patterns on banknotes, where they produce specific colors, such as a green afterglow lasting several seconds when excited by UV light at 365 nm. For example, the 500 Kenyan shilling banknote from 2019 exhibits UV phosphorescence that fades within a few seconds, serving as a covert marker detectable by specialized scanners.^[82] This property stems from the material's ability to store energy in excited states longer than fluorescent counterparts, making it a reliable forensic tool in high-security applications.^[83] Machine-readable zones (MRZ) and algorithmic serial numbers further enable automated authentication through standardized encoding. The MRZ, mandated by the International Civil Aviation Organization (ICAO), consists of two or three lines of alphanumeric characters at the bottom of passports and other travel documents, formatted for optical character recognition (OCR) scanning by machines at border controls. This zone encodes personal details like passport number, nationality, and expiration date, with fixed dimensions ensuring compatibility across global systems; for TD3 passports, it features two 44-character lines within a defined effective reading zone.^[84] Serial numbers on security documents, such as banknotes, often incorporate checksum algorithms to detect transcription errors or forgeries during verification. A common example is the Luhn algorithm, a modulus 10 checksum where digits are weighted (doubling every second from the right, summing digits if doubled value exceeds 9), and the total sum modulo 10 equals 0 for validity. This method, while simple, catches common input mistakes and is applied in various identification systems, including some financial instruments.^[85] In Euro banknotes, a similar modulo 9 checksum validates the serial number by matching the remainder of the numeric part to the prefix letter's position in the alphabet.^[86] At the forensic level, known as Level 3 security features, digital watermarks integrate cryptographic elements for tamper-proof analysis. These imperceptible markers embed hidden data into printed images or substrates using techniques like spread-spectrum modulation, allowing extraction only with proprietary software. Public-private key encryption enhances their security by signing the watermark payload, enabling authenticated verification where the private key embeds the mark and the public key confirms integrity during forensic examination. This approach is particularly valuable in identity documents, where watermarks can link to chip data or serial numbers, deterring counterfeiting through traceable, encrypted provenance. For instance, schemes combining digital watermarking with asymmetric cryptography ensure that alterations to the document invalidate the signature, facilitating post-incident investigations.^[87]^[88] Such features prioritize robustness against removal or forgery, providing high-impact protection in applications like passports and high-value certificates.^[89]

Anti-Copying and Forensic Features

Anti-copying and forensic features in security printing incorporate covert elements designed to reveal duplication attempts or facilitate traceability during investigations. These features often rely on patterns and materials that degrade or alter predictably when subjected to unauthorized reproduction processes, such as scanning and reprinting, while remaining imperceptible to the naked eye. They enable authentication through specialized software or analytical equipment, enhancing the security of documents like banknotes and passports by deterring counterfeiters and aiding forensic analysis. Copy detection patterns (CDPs) consist of microdots or steganographic data embedded within printed images, typically as small areas filled with randomized pixel values that are invisible without magnification or digital processing. These patterns exploit the noise and distortions introduced during the print-scan cycle, such as moiré effects or geometric shifts, to signal reproduction; original prints maintain a consistent noise signature, while copies exhibit detectable anomalies when analyzed by software. For instance, the Digimarc system integrates CDPs into digital watermarks that use AI-driven detection to identify subtle alterations indicative of copying, allowing instant verification of authenticity in high-value printed materials.^[90]^[91] Digital watermarks embed imperceptible data signals into the printed substrate, engineered to survive mechanical transformations like printing and scanning through robust encoding techniques. These watermarks often utilize phase-shift patterns, where subtle variations in halftone dot placement or frequency modulation create hidden information that persists despite degradation from reproduction devices. In security applications, such watermarks can encode identifiers or calibration data, enabling scanners to detect and decode the signal even after photocopy-induced blurring or rotation, thus confirming the document's originality.^[92]^[93] Forensic taggants involve chemical isotopes or compounds integrated into inks and substrates to provide unique traceability markers for origin verification and counterfeiter prosecution. These taggants, often comprising rare earth elements like lanthanides, are covertly added in precise ratios that can be analyzed post-production using techniques such as laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS). By linking the elemental signature to a specific manufacturing batch or facility, authorities can track illicit reproductions, as the taggants remain stable through printing but are difficult and costly to replicate accurately.^[94]^[95] Anti-Stokes inks represent up-converting luminescent materials that absorb lower-energy infrared light and emit higher-energy visible fluorescence, creating machine-detectable responses without visible glow under standard illumination. Activated by near-infrared sources (typically 970-980 nm), these inks produce a brighter emission than the input energy, allowing differentiation from standard dyes via specialized detectors that confirm authenticity in printed security features. This property ensures the inks are suitable for offset or flexographic printing on documents, where forensic scanners can verify the up-conversion effect to rule out counterfeits lacking the precise luminescent response.^[96]^[97]

Production Processes and Techniques

Printing Methods

Security printing employs specialized techniques to embed protective features into documents like banknotes and passports, ensuring resistance to counterfeiting through precise ink application and substrate interaction. These methods leverage mechanical pressure, ink transfer mechanisms, and material properties to produce elements that are difficult to replicate with standard equipment. Core processes include intaglio, offset lithography, gravure, screen printing, and letterpress, each contributing unique security attributes such as tactile relief, intricate patterns, and color-shifting effects. Intaglio printing involves incising designs into recessed metal plates, which are then inked and pressed against the substrate under high pressure—typically around 1 to 2 tons per square centimeter—to force ink into fine lines and create a raised, tactile surface.^[98] This method is particularly suited for portraits and value numerals on banknotes, where the embossed ink provides a distinctive "feel" that aids public verification and resists flatbed replication by consumer printers. Security stems from the ability to produce ultra-fine lines narrower than 0.1 mm, along with micro-text and guilloche patterns that blur or distort under low-resolution scanning, as the high-pressure process compresses the paper fibers for enhanced durability. Originating in the 15th century for artistic engravings, intaglio remains a cornerstone of modern security due to its overt tactile feature, detectable by touch without tools.^[99]^[100]^[101] Letterpress printing uses raised type or plates to apply pressure directly to the substrate, transferring ink in a way that produces sharp, precise impressions ideal for serial numbering and fine text on cheques and certificates. In security applications, it ensures accurate, non-reproducible numbering sequences that are difficult to alter without detection, often combined with perforations for added tamper evidence. Its simplicity and control over ink density make it suitable for high-security personalization.^[1] Offset lithography utilizes a planographic process where images are transferred from a flat aluminum plate to a rubber blanket before being applied to the substrate, allowing for high-speed, multi-color printing of uniform, non-raised ink layers. In security applications, it excels at creating complex backgrounds, vignettes, and anti-copy patterns on banknotes, where precise registration between front and back sides enables see-through features that align perfectly under light. The technique's security benefits include subtle color bleeding and moiré effects that scanners misinterpret as noise, preventing faithful digital reproduction, while its efficiency supports large-scale production without compromising detail in guilloche designs. Presses often operate in perfecting mode, printing both sides simultaneously to maintain alignment tolerances below 0.1 mm.^[102]^[103]^[104] Gravure printing, also known as rotogravure, employs engraved cylinders where cells of varying depths hold ink, which is then transferred directly to the substrate under controlled pressure, ideal for high-volume runs with consistent ink density. This cylinder-based method is used in security printing for embedding security threads and producing fine-line patterns on substrates like polymer notes, where the deep-etch cells (up to 50 microns) enable precise deposition of metallic or fluorescent inks that integrate seamlessly during lamination. Its security advantage lies in the difficulty of replicating the uniform ink fill and sharp edges of engraved cells, which standard offset or digital methods cannot match, thus deterring high-fidelity counterfeits in mass-produced documents. Gravure's high setup cost ensures economic viability only for authorized, large-scale operations.^[105]^[106] Screen printing applies viscous inks through a mesh stencil stretched over a frame, forcing the material onto the substrate with a squeegee to deposit thick layers (10-25 microns) that conventional methods cannot achieve. In security contexts, it is essential for applying optically variable inks (OVI), such as those used in euro banknote denominations, where the ink's flake pigments create angle-dependent color shifts visible to the naked eye but challenging to photocopy due to specular reflection loss. This technique accommodates metallic and iridescent formulations for guilloche overprints or patches, enhancing anti-counterfeiting by producing non-reproducible sheen and opacity gradients. Screen printing's versatility allows integration with other processes, like overprinting intaglio elements, for multi-layered protection.^[99]^[51]^[107]

Quality Control and Verification

Quality control and verification in security printing encompass rigorous inspection protocols implemented during and post-production to maintain the integrity of security features, ensuring that documents such as banknotes and identification papers resist counterfeiting effectively. These processes involve real-time monitoring and systematic audits to detect deviations in material properties, alignment, and overall feature performance, minimizing the risk of defective outputs that could compromise security. Adherence to international standards like ISO 14298:2021 guides these efforts, establishing a framework for security printing management systems that prioritize confidentiality, process control, and continuous improvement.^[108] Inline spectroscopy plays a crucial role in real-time quality assurance, particularly for verifying ink consistency during production. Techniques such as near-infrared (NIR) spectroscopy enable non-destructive, inline scanning to assess chemical composition and uniformity of inks, including those with UV or IR-responsive properties essential for security features. For instance, UV and IR scanning systems integrated into printing lines detect variations in pigment distribution or fluorescence, ensuring that specialized inks maintain their covert optical behaviors without halting operations. These methods allow for immediate adjustments, preventing inconsistencies that could weaken anti-counterfeiting measures.^[109] Automated vision systems further enhance precision by performing camera-based checks for registration alignment across multiple print layers, a critical aspect for features like see-through registers and intricate patterns. High-resolution line-scan cameras, often combined with multi-spectral illumination, monitor tolerances as tight as 0.05 mm to ensure perfect overlay of front and back impressions, identifying misalignments that could expose vulnerabilities. These systems process images in real time, flagging defects such as shifts in guilloche lines or holographic alignments, thereby upholding the structural security of the printed product. Machine-readable features, such as magnetic inks, are similarly validated through these vision protocols to confirm their positional accuracy.^[109]^[110] Sampling protocols under ISO 14298 Level 3 provide comprehensive oversight, mandating third-party audits for high-security applications like banknote production. This highest certification level requires accredited bodies to conduct initial and recurring audits—typically every three years with annual surveillance—to evaluate the entire supply chain, from substrate preparation to final personalization. These audits assess compliance with security controls, including defect detection rates and risk mitigation, ensuring that only verified processes are used for sensitive documents. Such independent testing reinforces trust in the output quality and helps combat forgery risks.^[111] Defect handling protocols emphasize proactive rejection to achieve minimal error propagation, with automated systems diverting faulty sheets during high-volume runs. For critical issues like watermark misalignment, rejection rates are maintained at levels below 1% through stringent inline checks, preventing circulation of compromised items. This approach not only safeguards feature integrity but also optimizes production efficiency, as rejected materials are recycled or reprocessed under controlled conditions. Overall, these verification measures ensure that security printing outputs meet exacting standards for authenticity and durability.^[112]

Integration of Multiple Features

Security printing employs a defense-in-depth strategy by integrating multiple layers of security features—overt (visible to the naked eye), covert (requiring simple tools like UV light), and forensic (detectable only with specialized equipment)—to create overlapping protections that deter counterfeiters across varying levels of sophistication.^[113] This layered approach ensures that while overt features like watermarks provide immediate public verification, covert elements such as UV-reactive inks add machine-readable checks, and forensic taggants enable law enforcement tracing, collectively raising the barriers to replication.^[114] Precise registration techniques are essential for combining these features effectively, particularly in multi-axis alignment where elements from different printing processes must overlay accurately. For instance, see-through registration aligns front and back images—such as a Swiss cross on banknotes—to form a cohesive pattern visible when held to light, often using fiducial marks during production to ensure sub-millimeter precision in intaglio and offset printing.^[113] These methods prevent misalignment that could compromise security, as even minor offsets would reveal counterfeits under scrutiny. A prominent example of such integration is the Swiss National Bank's ninth series banknotes, introduced with the 100-franc note in 2019, which incorporate numerous distinct features including tactile intaglio, security strips, and microperforations, all layered on a three-layer Durasafe substrate for enhanced durability and authenticity.^[115] This redesign exemplifies how overt elements like tilt-dependent color shifts complement covert UV features and forensic markers, providing comprehensive protection without altering the note's usability. However, integrating multiple features presents challenges, including balancing production costs against security gains—advanced substrates and alignments can increase expenses significantly, estimated in the tens of millions for large-scale issuance—and ensuring compatibility across diverse materials like paper or polymer to maintain print quality and feature efficacy.^[113]

Applications and Challenges

Currency and Financial Instruments

Security printing plays a crucial role in the production of banknotes, incorporating multiple layers of features to deter counterfeiting and ensure authenticity in high-value financial transactions. These designs typically combine overt elements visible to the public, such as holograms and color-shifting inks, with covert markers detectable only by specialized equipment. For instance, the Europa series €20 banknote features a portrait hologram that displays a window and the denomination numeral upon tilting, enhancing visual verification.^[116] It also includes an emerald number printed in optically variable ink (OVI), which shifts from green to deep blue when tilted, providing an additional anti-counterfeiting measure.^[116] Cheques, as negotiable financial instruments, rely on security printing to prevent fraud during processing and clearing. A key feature is the Magnetic Ink Character Recognition (MICR) line at the bottom, printed with iron oxide-based ink that allows automated sorting and reading by banking machines while resisting alteration.^[117] Pantograph backgrounds further protect against photocopying or scanning; these intricate patterns reveal the word "VOID" or similar warnings on reproductions, rendering copies invalid.^[118] Such features are standardized in check stock paper, often combined with microprinting along borders that blurs into lines when duplicated.^[119] A notable case study is the 2013 redesign of the U.S. $100 banknote, which introduced advanced features like a blue 3D security ribbon woven into the paper, displaying bells and "100s" that shift with movement.^[120] This overhaul, developed in collaboration with the U.S. Secret Service, incorporated intaglio printing, microprinting, and color-shifting ink to address evolving threats.^[121] Post-redesign, counterfeit $100 notes have declined by over 85% compared to pre-2013 levels, significantly reducing passed counterfeits in circulation.^[122] Many modern banknotes utilize polymer substrates to improve durability and integrate embedded security elements, such as transparent windows for holograms.^[123]

Identification Documents and Passports

Security printing plays a critical role in identification documents and passports, where the need for personalization and long-term durability is paramount to prevent identity fraud and ensure border security. These documents incorporate layered security features that combine visible, tactile, and machine-readable elements to authenticate the holder's identity while withstanding environmental stresses like wear, heat, and tampering attempts. Unlike mass-produced items, identification documents require individualized production processes that integrate biographical data, photographs, and unique identifiers directly into robust substrates, making replication exceedingly difficult. Modern passports adhere to the International Civil Aviation Organization (ICAO) standards for electronic Machine Readable Travel Documents (eMRTDs), which were established in 2006 to incorporate biometric data and enhanced security. A key feature is the use of polycarbonate data pages, a durable, tamper-evident material that resists delamination and chemical alteration. These pages are personalized through laser engraving, which etches variable information such as the holder's name, photograph, and passport number into the substrate, creating a permanent, high-contrast image that cannot be easily removed or altered without visible damage.^[124] Many eMRTDs also integrate electronic chips for biometric storage, briefly referenced here as a complementary machine-readable layer embedded within the polycarbonate structure.^[79] Identification cards, such as national ID cards and driving licenses, employ similar principles but emphasize laminate-based protections suited to card formats. In the European Union, driving licenses feature holographic laminates that overlay the personalized data, producing optically variable effects like shifting colors and images when tilted, which deter counterfeiting.^[125] UV portraits and microtext are additional safeguards; under ultraviolet light, invisible fluorescent inks reveal secondary images of the holder's face or intricate text lines finer than 0.3 mm, verifiable only with magnification or specialized equipment.^[125] For instance, EU driving licenses include microtext integrated into borders and backgrounds, reading phrases like "DRIVING LICENCE" in repeating patterns that blur under scanning attempts.^[126] Personalization in these documents relies on variable data printing techniques to embed unique elements like photographs and serial numbers during production. Inkjet systems, particularly drop-on-demand (DOD) variants with secure inks, enable high-resolution printing of full-color portraits and alphanumeric data directly onto the substrate or laminate, allowing for efficient, on-demand issuance without compromising security.^[127] This method supports rapid customization for each document while maintaining durability against fading or smudging, often combined with UV-curable inks for enhanced adhesion.^[128] A primary threat to these documents is forgery through page substitution, where fraudsters replace the genuine biographical data page with a falsified one to assume another identity.^[124] Countermeasures include rainbow printing, a gradient color transition technique using offset lithography that creates seamless blends difficult to replicate on consumer printers, integrated into the data page background to match the passport's binding and stitching.^[124] This, alongside unique page numbering and microprinted alignment markers, ensures that substitutions disrupt the document's cohesive design, enabling detection during inspection.^[124]

Emerging Threats and Future Directions

The advent of 3D printing technologies since the 2010s has significantly amplified counterfeiting risks in security printing, enabling the production of high-fidelity fakes for documents and currency with reduced barriers to entry and lower costs.^[129] This rise is evidenced by reports highlighting how additive manufacturing facilitates unlicensed replication of complex security features, posing threats to financial instruments and identification documents.^[130] Similarly, artificial intelligence (AI) has emerged as a potent tool for generating designs that evade traditional security patterns, such as by analyzing authentic packaging or holograms to replicate visual effects before physical printing occurs.^[131] AI-driven counterfeits, including deepfakes and manipulated images, further complicate detection in printed media, with instances of AI-generated fake IDs demonstrating the technology's ability to bypass forensic markers.^[132]^[133] Looking ahead, quantum dots represent a promising advancement in taggant technology, offering physically unclonable functions (PUFs) for unbreakable authentication in security printing. These nanoscale semiconductors enable inkjet-printed fluorescent labels with unique, random patterns that are optically verifiable yet difficult to replicate, as demonstrated in studies on RGB-emitting quantum dot inks for anti-counterfeiting.^[134] Their size-tunable emission properties allow integration into substrates for invisible, tamper-proof markers, enhancing protection across applications like currency and passports.^[135] Complementing this, blockchain serialization of physical banknotes is being piloted to link unique serial numbers with digital ledgers for real-time verification, as seen in initiatives like Fastex's crypto banknote project, which incorporates NFTs and blockchain for secure tracking.^[136] Sustainability efforts in security printing are gaining traction through bio-based inks and recyclable polymers, addressing environmental concerns without compromising security. Bio-based inks, derived from renewable sources like algae or soy, reduce toxicity and wastewater pollution while maintaining print quality on secure substrates.^[137] Recyclable single-polymer materials, such as Covestro's CERTEVO®, enable circular economy practices in banknote production by allowing full material recovery post-use.^[138] By 2030, industry forecasts predict widespread adoption of digital-physical hybrid systems in currency and documents, blending central bank digital currencies (CBDCs) with physical features for seamless verification via blockchain and biometrics.^[139] G7 principles emphasize that such hybrids must prioritize financial stability, privacy, and interoperability, with projections indicating at least 15 CBDCs in circulation to support this transition.^[140]^[141] These developments, per reports from the Bank for International Settlements, could transform payments into instant, decentralized ecosystems integrating physical tokens with digital ledgers.^[142]

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Euro banknotes have security features like a security thread, watermark, hologram stripe, and a glossy stripe. Always check several features.Missing: eurozone | Show results with:eurozone
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What is Optically Variable Ink (OVI)? | Banknote Glossary
Optically Variable Ink (OVI) is an ink with pigments that change color depending on the angle of light incidence and view.
[50]
Printed Security Features - Louisenthal
Printed features using optically variable inks (OVIs) are proven anti-copy security features. They create effects that are either visible, change colour or ...
[51]
THE NEW COLOR OF MONEY - The Washington Post
Mar 18, 1996 · CAPTION: Eduardo Beruff, SICPA Industries president, explains his company's color-changing ink that is being used on redesigned $100 bills. The ...
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30 years of holograms on banknotes - Giesecke+Devrient
Holograms, also known as diffractive Optically Variable Devices (OVDs), have become one of the most common Level 1 security features on banknotes.Missing: thickness tactile
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DOVIDs secure passports and identity documents - KINEGRAM
The KINEGRAM are security features based on optical effects created by diffraction. Secure DOVIDs drastically increase the protection of passports, visas, ID ...
[54]
KINEGRAM vs. HOLOGRAM: A Detailed Comparison
Unlike traditional, commercially available security holograms, the KINEGRAM is a proprietary DOVID technology exclusively offered to governments for protecting ...
[55]
[PDF] K now You r M oney - Secret Service
All Federal Reserve Notes are printed on paper featuring red and blue embedded fibers. Federal Reserve Notes designed before 1990 do not contain security ...
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[57]
[PDF] Noticeability of features of secure documents - GovInfo
A review of the literature on the noticeability of features of counterfeit bills, primarily British pound notes, is presented. The review suggests that ...
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US5799102A - Bank note scanner utilizing olfactory characteristics ...
The invention concerns a bank note scanner (2) for assessing the authenticity of a bank note, which includes a vacuum pump (4), an olfactory sensor (8), ...
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[PDF] Limitations of the Counterfeit Detection Pen On United States Currency
the current version of the Counterfeit Detection Pen was introduced (2009). The current Counterfeit Detection Pen utilizes a starch-iodine chemical reaction.
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FDE 101: Mechanical Printing Processes
### Summary: Halo Effect in Mechanical Printing Processes for Security Documents
[61]
Printing Techniques, a Weapon against Check Forgers
The difficulties of check forging and the use of security printing techniques to create safe checks.
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Security Inks - Tamper Evident & Instant Verification
Thermochromic Ink - These inks change colour or disappear when heat or friction is applied making them perfect for fast document verification. They are ...Missing: latent darken
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Pantographs as a Security Feature: Why They Work, Why They Fail
The security feature only becomes evident when a copy is made. At this time, a latent word or message, such as “void,” “copy,” or “unauthorized copy ...
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Check fraud security features for checks and documents
May 17, 2023 · This blog will look at the various security features used to prevent the forging, altering and counterfeiting of checks.Missing: irregular anti-
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Fluorescence in Banknotes and Passports: Using Portable ...
Discover how fluorescence spectroscopy enhances document security by detecting counterfeit banknotes and passports through hidden fluorescence features.
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Real vs. Fake Money: A Guide to U.S. Currency Security Features
Aug 26, 2024 · All genuine FRNs, except the $1 and $2 denominations, contain a clear security thread embedded vertically in the paper. This thread is inscribed ...
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What is UV-fluorescent Ink? | Banknote Glossary - Regula Forensics
Ink containing fluorescent substances (pigments) which glows when exposed to UV light (wavelength is usually of 365 nm and 254 nm).
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[PDF] Euro banknotes - Banque centrale du Luxembourg
Apr 11, 2022 · The most common colours of security inks used in IBNS are violet, green, blue, red and black. When a banknote is stained by an IBNS, the ...<|control11|><|separator|>
[69]
Clearly Not a Counterfeit Bill - Laser Components
Mar 6, 2017 · If you hold a euro banknote under IR light, you will only see parts of the print. Fluorescence. Fluorescent printing inks and fibers illuminate ...
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How to detect counterfeits | Banco de Portugal
Use the FEEL, LOOK, and TILT method to check security features. Compare with a known genuine banknote. If in doubt, do not accept it.
[71]
[PDF] REAL OR FAKE ?
Hold the banknote against the light. The thread will appear as a dark stripe. The word “EURO” and the value can be seen in tiny letters on the stripe ...
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Security threads: exciting banknote protection | G+D
Color shift, 3D effects, demetalization, fluorescence, and magnetic elements mean our fine security threads offer effective protection. A scalable product ...<|separator|>
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How to Tell If Toner Is MICR: Know the Difference
Aug 18, 2025 · MICR toner is a special type of toner that contains magnetic iron oxide particles. It's used to print the check's “MICR line”, which includes ...
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https://acombusiness.com/blogs/helpful-articles/how-to-tell-if-toner-is-micr
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[PDF] Generic MICR Fundamentals Guide - Support - Xerox
The specifications for producing the E13B font using magnetic ink were accepted as a standard by the American Bankers. Association (ABA) in 1958. In April 1959, ...
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How Do Vending Machines Know Money is Real?
It has a magnetic head that detects the magnetic ink. Every bill has signature features. The machine uses them to sort every denomination. However, these ...
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Overview of security features - CCE GmbH
On some banknotes, only the (predominantly black) serial number is marked with magnetically pigmented printing ink. But entire areas on banknotes can also ...Missing: absorption | Show results with:absorption
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[PDF] Doc 9303 Machine Readable Travel Documents - ICAO
Part 1 (Machine Readable Passports) in 2006, and Volume 2 of the Third Edition of Doc 9303, Part 3 (Machine. Readable Official Travel Documents) in 2008. 2 ...
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[PDF] An Introduction to Dynamic Authentication | MagTek
Dynamic authentication uses unique magnetic particle patterns on a card's stripe, like a "magnetic fingerprinting" process, to identify the card.Missing: verification | Show results with:verification
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Magnetic stripes: More than you ever wanted to know
Feb 1, 2002 · Make a pattern of negative charged particles and positive charged particles and you can symbolize data in the patterns. Inside an encoding ...
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Shedding Light on Luminescent Inks: How They Help Detect Fakes
Sep 28, 2023 · For instance, the UV phosphorescence in a 500 Kenyan shilling banknote from 2019 excited by UV 365 nm fades away within a few seconds when ...
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The bright world of the security printing and brand protection ...
Mar 24, 2022 · Without organic fluorescent pigments and dyes, it would be impossible to design banknotes, tax stamps, ID cards, or passports. These security ...
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[PDF] Doc 9303 Machine Readable Travel Documents - ICAO
Mar 20, 2024 · The MRZ shall be located such that the two OCR lines contained therein are within the Effective Reading Zone (ERZ) as defined in Doc 9303-3.
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What is the Luhn algorithm and how does it work? | Stripe
Apr 21, 2025 · The Luhn algorithm, also known as the Luhn formula, “modulus 10,” or “mod 10” algorithm, is a simple checksum formula used to validate identification numbers.
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€uro Checksum
€uro Checksum. €uro Checksum verifies the serial number of your Euro banknotes; if the checksum is valid, the banknotes is not counterfeit (probably).
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Levels of Security Features - Keesing Technologies
Security features are commonly categorized by level 1 overt (Cursory examination/ easily identifiable visual or tactile features), 2 covert (Examination by ...
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(PDF) Digital Watermarking System for Copyright Protection and ...
Aug 5, 2022 · Therefore, a novel watermarking scheme is proposed to ensure copyright protection and authentication of images using cryptography techniques.<|control11|><|separator|>
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[PDF] enhancing personal identity verification with digital watermarks ...
The digital watermarking security layer contains personalized/unique digital identifiers, such as the serial number of the in-card chip, unique identity ...
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(PDF) A Practical Print-and-Scan Resilient Watermarking for High ...
Aug 7, 2025 · A copy detection pattern (CDP) is a shape (typically a rectangle) filled with pixels of random grey levels and incorporated in a digital ...
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Digital Security Solution - Digimarc
Enhance your product security with Digimarc's AI-driven copy detection feature. This advanced technology detects subtle, imperceptible alterations that signal ...Missing: pattern | Show results with:pattern
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Digital watermarks and methods for security documents
A processor inside the device analyzes graphical image data to be printed, looking for watermarks associated with security documents. ... (C.f. public and private ...
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[PDF] Show-through Watermarking of Duplex Printed Documents
Watermark information is embedded in halftones used to print images on either side. The watermark pattern is imperceptible when images printed on either side.
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[PDF] Taggant materials in forensic science - King's Research Portal
Aug 11, 2016 · Property taggants are usually invisible to the naked eye in order to prevent spoiling the item's aesthetic or to avoid detection by offenders. •.
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Taggant materials in forensic science: A review - ResearchGate
Covert anti-counterfeiting technologies include security inks, digital watermarks, biological, chemical or microscopic taggants [18] , QR or RFID tags, etc.
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[PDF] Security Printing Inks
It shows an additional anti-Stokes luminescence compared to our tri- fluorescent ink. Anti-Stokes inks. These inks are to be activated with IR irradiation.
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Anti-Stokes (up-converting) pigments - Luminochem
We offer anti-Stokes luminescent security pigments with high stability, good light fastness and fine particle size in order to enable offset printing.Missing: glow energy
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Print effects: improve aesthetics and security | G+D
Exclusive intaglio printing in particular gives the note a high-quality appearance, striking colors, vivid motifs and tactile relief.
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Banknote Security Features - Bank of Thailand
Clear Window. The upper clear window can be seen through from both sides of banknote with the embossed “20”. ช่องใส. 5. ภาพซ้อนทับ. See-through Register. Such ...
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Understanding banknote printing - Security printing
Oct 20, 2025 · Intaglio gives banknotes their raised, tactile feel, allowing the public to verify authenticity simply by touch.
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Security Printing Solutions From Koenig & Bauer
Key Features for Security Printing Excellence · Intaglio printing: Creating raised images with exceptional tactile quality for enhanced security · Offset ...
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Offset printing - Cash Essentials
Feb 3, 2021 · A printing process that is used for printing multi-colour backgrounds of the banknotes. Offset presses that print simultaneously the back and front.
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Production of banknotes - BANK AL-MAGHRIB
OFFSET PRINTING This method also enables the printing of some security features, such as the See-through register as well as anti-copy patterns. Commemorative ...
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Security printing - BOBST
Around the globe, security applications includes gravure and offset printing, lamination, selective metallization, die-cutting, embossing, hot foil & hologram ...<|separator|>
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Gravure Printing: A Detailed Overview - flexo printing & packaging
Feb 24, 2025 · Engraved gravure printing, known for its fine lines and difficulty to counterfeit, is often used for printing securities such as banknotes, ...
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What Types of Security Ink Are There? Benefits and Applications
Jul 10, 2025 · The silk screen printing process is often employed for OVI application due to its ability to handle the thick, viscous nature of the ink and to ...<|separator|>
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ISO 14298:2021 - Management of security printing processes
This document specifies requirements for a security printing management system for security printers.<|separator|>
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inspection solutions for security printing - Isra Vision
High-speed, high-resolution line-scan cameras; Ultra-bright illumination modules; Inspection using visible, ultraviolet or infrared light; Real-time processing.
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Registration in Printing - What Is It? Tolerance - Sticky Business
Sep 11, 2018 · Print registration tolerance. In digital printing, registration tolerance is about 1/100”, which is extremely accurate thereby making visible ...
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[PDF] iso 14298 | intergraf 15374 - let's talk about certification
INTERGRAF ISO 14298 certification levels. FUNDAMENTAL applies to printers supplying commercial security printing products and security products to government ...Missing: testing | Show results with:testing
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Security substrates und printing inspection: BankSTAR Product Line
Unwanted security fibers - visible or UV-reactive - are faithfully detected by dedicated hardware processing in near real-time at even the highest web speeds. ...
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Chapter: 4 Innovative Counterfeit-Deterrent Features
The features can be combined in different ways to provide a layered defense against the various classes of counterfeiter. Ultimately, then, the prioritization ...
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Counterfeit money detection | Banknote security features
Oct 12, 2021 · Visual authentication features are still the best-known security features among the general public: the watermark and the security thread.
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Check if your note is genuine - Swiss National Bank
Swiss banknotes have numerous security features, including a three-layer substrate, making them difficult to counterfeit. The security concept is identical ...Missing: 2019 integration
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[PDF] THE NEW €20 BANKNOTE | European Central Bank
Feb 24, 2015 · The new €20 has a portrait window in the hologram, an emerald number, and a portrait of Europa in the watermark, visible on both sides.
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[PDF] Squealing Euros: Privacy Protection in RFID-Enabled Banknotes
With this in mind, the European Central Bank has proposed to embed small, radio-frequency-emitting identification (RFID) tags in. Euro banknotes by 2005 as a ...
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MICR Check Printing : What Is It and Why It Matters - PCI Group
Nov 21, 2022 · The micr ink prints on the MICR line at the bottom of checks, with numbers and characters. It consists of the check, account, and bank routing ...
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https://pcigroup.com/what-is-micr-printing-and-why-does-it-matter/
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Document Security - Printegra
Indicates that additional security features have been incorporated in the design. Upgrade Print Security Features. ODT™ Void Pantograph • The word “VOID” ...
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https://www.printegra.com/document-security/
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https://www.federalreserve.gov/newsevents/pressreleases/other20131008a.htm
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Federal Reserve Board issues redesigned $100 note
Oct 8, 2013 · ... U.S. Secret Service partner to redesign Federal Reserve notes to stay ahead of counterfeiting threats. The redesigned $100 note includes two ...
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$$100 Note
### Summary of Visible Security Features on the $100 Bill (2013-Present)
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85% Decline in US $100 Counterfeits - Crane Currency
Mar 20, 2025 · In fact, for $100 bills specifically, the incidence of counterfeits has plummeted by over 85% since the 1990s. This means encountering a ...
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SAFEGUARD® polymer banknote substrate - De La Rue
SAFEGUARD® polymer substrate is durable, sustainable, and packed with anti-counterfeiting features, meeting central bank demands since its launch in 2012.
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[PDF] Doc 9303 Machine Readable Travel Documents - ICAO
Security features and/or techniques should be included in travel documents to protect against unauthorized reproduction, alteration and other forms of tampering ...
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Ireland - IRL3 - Mobility & Transport - Road Safety
Transparent holographic image. Location: On the front, partially covering the photo. · Method of verification: Move the document under ordinary light. ; Microtext.
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[PDF] PRADO GLOSSARY - consilium.europa.eu
Anti-scan / anti-copy pattern. Anti-scan / anti-copy patterns are printed security features integrated in the background / security printing to protect ...
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Security Solutions for Passport and ID | Sun Chemical
Sun Chemical offers security inks, stitching threads, lamination plates, pre-patched holograms, and pre-laid magnetic stripes for passports and IDs.Missing: countermeasures rainbow<|control11|><|separator|>
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[PDF] Secure Identity Technologies Brochure - Entrust
A thin polymer film, which may include registered holograms, microtext, and laser retrievable text, can be quickly and economically applied to passport as part ...
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[PDF] US Intellectual Property and Counterfeit Goods - USPTO
The analysis in this report is based on documents published and produced by governmental, intergovernmental, and nongovernmental agencies, as well as studies ...Missing: currency | Show results with:currency
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[PDF] Combating Trafficking in Counterfeit and Pirated Goods
Jan 24, 2020 · 3D printing reduce the barriers for reverse engineering and the costs of manufacturing counterfeit products. Lower production costs can also ...Missing: currency | Show results with:currency
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AI automated document fraud detection with digital manipulation ...
May 20, 2025 · Mitek's digital manipulation detection tackles the rise of AI-generated fake ids. Digital manipulation of IDs The democratization of fraud.<|separator|>
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Tackling Deepfake and AI-Generated Counterfeits: A Trademark ...
Oct 29, 2025 · Explore how to combat deepfake and AI-generated counterfeits, ensuring your trademarks remain secure in the era of advanced technology.
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Inkjet-printed unclonable quantum dot fluorescent anti-counterfeiting ...
Jun 3, 2019 · The authors develop an inkjet-printable and unclonable security label based on random patterning of quantum dot inks, and accompany it with an artificial ...Missing: unbreakable | Show results with:unbreakable
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Optically Readable, Physically Unclonable Subwavelength Pixel via ...
May 29, 2024 · By utilizing the RGB emission quantum dots, full-color fluorescence security labels can be produced. A convenient and reliable AI-based ...Missing: future | Show results with:future
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Authentix Powers Fastex's Groundbreaking Crypto Banknote with ...
The crypto banknote features serial numbers, intaglio and optically variable inks, metallic security foil, and a polymer substrate, with NFTs for verification.Missing: serialization pilots
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Vision Life Holdings launches biobased ink to address wastewater ...
Feb 24, 2025 · Vision Life Holdings has introduced UTEX Eco Ink after extensive research. This innovative ink significantly reduces wastewater pollution.
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Covestro unveils CERTEVO®: An innovative polymeric substrate
Nov 28, 2024 · Bio-based Aniline ... As a single-polymer composition, CERTEVO® is recyclable, meeting the demand for sustainable security printing materials.
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CBDC Transactions to Exceed $213 Billion by 2030 Globally | Press
Mar 13, 2023 · The value of payments via CBDCs (Central Bank Digital Currencies) will reach $213 billion annually by 2030; up from just $100 million in 2023.<|separator|>
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G7 Public Policy Principles for Retail Central Bank Digital ...
The G7 published principles for CBDCs, which could be a digital form of central bank money. Factors include financial stability, cyber security, and privacy.
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CBDCs: 15 central bank digital currencies by 2030, BIS says
Jul 10, 2023 · Predictions from Juniper Research, published earlier this year, show that the value of CBDCs could reach US$213bn a year by 2030 – up from just ...
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[PDF] The Landscape in 2030: CBDCs or Private Digital Payment Solutions?
Jun 29, 2022 · CBDC is a digital money issued by central banks, with over two-thirds of central banks likely to issue it. The Bahamas and Nigeria have ...