{"schema_version":"1.0","canonical_url":"https://patentable.app/patents/US-9852691","patent":{"patent_number":"US-9852691","title":"Display device, system having the same, and pixel","assignee":null,"inventors":[],"filing_date":"2015-05-12T00:00:00.000Z","publication_date":"2017-12-26T00:00:00.000Z","cpc_codes":["G09G","G09G","G09G","G09G","G09G","G09G"],"num_claims":19,"abstract":"A display device, system having the same, and pixel are disclosed. In one aspect, the display device includes a display panel including a plurality of pixels and a plurality of wireless power receivers. The display device also includes a wireless power transmitter configured to generate and wirelessly transmit power to the wireless power receivers. Each of the wireless power receivers is configured to wirelessly receive the power from the wireless power transmitter and provide a first power supply voltage to the pixels. The display device further includes a power supply configured to generate an initial power supply voltage and provide the initial power supply voltage to the wireless power transmitter."},"analysis":{"summary":"The **Display Device, System Having the Same, and Pixel** patent introduces a groundbreaking approach to powering display devices, fundamentally altering traditional display architecture. At its core, this innovation (US-9852691) addresses the long-standing challenges of power distribution within display panels, particularly the bulk and rigidity imposed by conventional wired connections.\n\nThe problem being solved is the physical limitation and manufacturing complexity associated with routing individual power lines to millions of pixels in modern high-resolution, thin, and flexible displays. Existing solutions rely on intricate conductive traces, which restrict design freedom, add to thickness, and can be prone to manufacturing defects.\n\nThe key technical approach involves integrating wireless power receivers directly into the display panel, alongside the pixels. A dedicated wireless power transmitter, also part of the display device, generates and wirelessly broadcasts power to these receivers. Each receiver then converts the received wireless energy into a stable power supply voltage for its associated pixels. An initial power supply feeds the wireless transmitter, creating a self-contained, wire-free power delivery system within the display panel itself.\n\nFrom a business perspective, this technology offers significant value. It unlocks unprecedented design flexibility, enabling the creation of ultra-thin, truly flexible, rollable, and even transparent displays. This can lead to lighter, more aesthetically pleasing, and more durable products. Furthermore, simplifying the internal power distribution could reduce manufacturing complexity and costs, leading to higher yields and faster product development cycles. The market opportunity is vast, spanning consumer electronics (smartphones, wearables, AR/VR), automotive displays, digital signage, and specialized industrial applications where form factor and durability are critical. Companies adopting this innovation could gain a substantial competitive advantage by offering next-generation display products that are currently beyond the reach of conventional technology.","layman_explanation":"In today's fast-paced world, display technology is everywhere, from our phones to our car dashboards. But beneath the sleek surfaces, there's a hidden complexity: a tangled web of tiny wires responsible for powering every single pixel. This hidden infrastructure, while essential, creates significant limitations for innovation. The **Display Device, System Having the Same, and Pixel** patent offers a revolutionary solution, fundamentally rethinking how displays receive power.\n\n**What Problem Does This Solve?**\nThink about the challenges facing modern display manufacturers. They're constantly striving for thinner, lighter, and more flexible screens. They want to create devices that can fold, roll, or even be integrated seamlessly into everyday objects like windows or clothing. The biggest hurdle? The traditional method of powering pixels. Each pixel needs electricity, and currently, this is delivered through an intricate network of microscopic wires embedded within the display panel. This wiring adds thickness, makes the panel rigid, increases manufacturing complexity, and can even contribute to power loss. Existing solutions are essentially refined versions of this wired approach, reaching their physical limits as consumer demand pushes for ever more innovative form factors. This patent seeks to break free from these physical constraints.\n\n**How Does It Work?**\nInstead of wires, this innovative patent proposes a wireless solution. Imagine the display panel itself as a mini wireless charging pad. The invention describes a display device where the display panel contains not only the pixels but also tiny wireless power receivers integrated with those pixels. Think of these receivers as miniature antennas, each capable of catching energy. The display device also includes a wireless power transmitter, perhaps located at the edge or behind the panel. This transmitter generates and broadcasts power wirelessly across the display. Each tiny receiver then captures this wireless energy and converts it into the precise voltage needed to light up its corresponding pixel. The entire system is kickstarted by a standard power supply that feeds the main wireless transmitter, which then distributes power wirelessly throughout the screen. It's like having a central broadcasting station for power, sending energy directly to every tiny light bulb on the screen without needing a physical cable for each one.\n\n**Why Does This Matter?**\nThis innovation matters because it unlocks a new era of display design and functionality. By removing the need for complex internal wiring, this technology allows for displays that are:\n\n*   **Ultra-Thin and Flexible:** Imagine phones that fold completely flat, tablets that roll into a cylinder, or transparent screens that integrate into architectural glass. This patent makes such designs commercially viable.\n*   **Lighter and More Durable:** Fewer physical connections mean less material and fewer points of failure, leading to lighter and potentially more robust devices.\n*   **More Efficient to Manufacture:** Simplifying the internal power layer can reduce manufacturing complexity and costs, leading to higher production yields and faster time-to-market for new products.\n*   **New Market Opportunities:** This technology could enable entirely new product categories in augmented reality, smart wearables, and advanced automotive displays, creating significant market growth and investment opportunities.\n\n**What's Next?**\nThe **Display Device, System Having the Same, and Pixel** patent sets the stage for a future where displays are not just flat rectangles but dynamic, adaptable interfaces woven into the fabric of our lives. We can anticipate this technology driving breakthroughs in consumer electronics, automotive design, and even smart infrastructure. Companies that invest in developing and implementing this wireless power delivery system will be at the forefront of the next generation of visual experiences, offering unparalleled design freedom and enhanced performance that could redefine market expectations.","technical_analysis":"The **Display Device, System Having the Same, and Pixel** patent (US-9852691) presents a paradigm shift in display power management by proposing an integrated wireless power delivery system directly to the pixel array. This technical analysis delves into the architectural specifics, implementation considerations, and the profound implications for display engineering.\n\n**Technical Architecture Overview:**\nAt the heart of this invention is a display device comprising a display panel, a multitude of pixels, and a corresponding plurality of wireless power receivers. These receivers are designed to be an integral part of the display panel, ideally co-located with or fabricated adjacent to the individual pixels or small clusters of pixels they are intended to power. The innovation further specifies a wireless power transmitter, also integrated within the display device, which is configured to generate and broadcast electromagnetic energy. This energy is then wirelessly captured by the array of receivers.\n\nUpon reception, each wireless power receiver is engineered to convert the received electromagnetic energy into a stable DC power supply voltage, which is then provided directly to its respective pixels. The system's operation is initiated by a conventional power supply that generates an initial power supply voltage, feeding it to the wireless power transmitter. This architecture effectively decentralizes power distribution from a complex wired grid to a localized, wireless transmission and reception model.\n\n**Implementation Details and Algorithm Specifics:**\nImplementing this technology requires sophisticated engineering across several domains:\n\n1.  **Wireless Power Receiver Design:** Each receiver unit must be miniaturized to the scale of a pixel or sub-pixel, incorporating a resonant inductive coil or antenna, a high-frequency rectifier (e.g., Schottky diodes for low voltage drop), and a compact voltage regulator. The resonant frequency of these receivers must be precisely tuned to match the transmitter's frequency for optimal power transfer efficiency. Material selection for these components is critical to maintain display optical properties (e.g., transparency for transparent displays).\n2.  **Wireless Power Transmitter Design:** The transmitter typically consists of a power oscillator, a driving circuit, and a transmitting coil or antenna. Its design must ensure uniform power distribution across the entire display panel while minimizing power loss and electromagnetic interference (EMI). Advanced beamforming or phased array techniques could be explored for larger displays to ensure consistent power delivery to all receivers, regardless of their position.\n3.  **Power Transfer Protocol:** The system likely utilizes inductive coupling or resonant inductive coupling, given the short-range and high efficiency requirements. The operating frequency would need to be carefully chosen to balance efficiency, component size, and regulatory compliance (e.g., ISM bands). Dynamic frequency tuning or adaptive impedance matching algorithms could be employed to optimize power transfer in varying conditions.\n4.  **Integration Patterns:** The wireless power receivers could be fabricated using thin-film transistor (TFT) processes directly on the display backplane, similar to how pixel driving circuits are formed. This co-fabrication would simplify integration and reduce assembly complexity. Alternatively, they could be micro-fabricated as separate components and then integrated through advanced bonding techniques.\n\n**Performance Characteristics and Code-Level Implications:**\nKey performance metrics include power transfer efficiency, thermal management, and pixel voltage stability. High efficiency is crucial to prevent excessive heat generation, which can degrade display performance and longevity. The voltage regulators within each receiver must provide stable, ripple-free power to the pixels, which are sensitive to voltage fluctuations.\n\nFrom a control perspective, the system would require firmware or software to manage the wireless power transmitter's output, potentially adjusting power levels based on the display's content or overall power consumption. This could involve algorithms that monitor the aggregated power demand of pixel groups and dynamically modulate the transmitted power, optimizing energy usage. For instance, in a display showing a largely dark image, the system could reduce overall transmitted power, leading to significant energy savings.\n\n**Technical Implications:**\nThe **Display Device, System Having the Same, and Pixel** innovation fundamentally redefines display hardware design. It promises the ability to create truly flexible, rollable, and ultra-thin displays by removing the rigid constraints of wired power grids. It also opens avenues for enhancing display reliability by reducing physical connection points susceptible to failure. The technical challenges, though significant, are surmountable with ongoing advancements in miniaturized power electronics, advanced materials, and wireless power transfer technologies. This patent lays the groundwork for the next generation of visual interfaces, empowering engineers to design displays with unprecedented form factors and functionalities.","business_analysis":"The **Display Device, System Having the Same, and Pixel** patent (US-9852691) introduces a transformative approach to display power delivery, carrying substantial business implications across multiple industries. This innovation, by enabling wireless power to individual pixels, addresses critical limitations in current display technology, opening vast market opportunities and offering significant competitive advantages.\n\n**Market Opportunity Size:**\nThe global display market is a multi-billion dollar industry, constantly driven by demand for higher resolution, thinner profiles, and novel form factors. This patent taps into several burgeoning segments:\n\n1.  **Flexible & Foldable Displays:** The market for flexible electronics, including foldable phones, rollable TVs, and bendable tablets, is projected to grow exponentially. This invention directly removes the primary constraint (wired power) for truly flexible displays, unlocking unprecedented design possibilities and market expansion.\n2.  **Wearable Technology:** Smartwatches, AR/VR headsets, and smart glasses demand lightweight, compact, and often curved displays. This technology can significantly reduce the bulk and weight of displays in these devices, enhancing user comfort and appeal.\n3.  **Automotive & Aerospace:** Integrated, custom-shaped displays are becoming standard in vehicle cockpits and aircraft cabins. The flexibility and reduced thickness offered by this patent enable seamless integration into complex interior designs.\n4.  **Transparent & Smart Surfaces:** Imagine windows that double as screens or interactive tabletops. Wireless power to pixels is a crucial enabler for truly transparent displays and smart surfaces, creating new product categories.\n\n**Competitive Advantages:**\nCompanies that successfully commercialize the **Display Device, System Having the Same, and Pixel** technology will gain a formidable competitive edge:\n\n1.  **Product Differentiation:** Offering displays with superior flexibility, thinness, and novel form factors that competitors cannot easily match with traditional wired solutions.\n2.  **Reduced Manufacturing Costs:** Eliminating complex, multi-layered wired power grids can simplify manufacturing processes, reduce material waste, and improve production yields, leading to lower unit costs.\n3.  **Enhanced Brand Image:** Being at the forefront of such a fundamental display innovation positions a company as a leader in advanced technology and design.\n4.  **IP Protection:** Owning the core patents for wireless pixel power creates a strong barrier to entry for competitors and generates licensing opportunities.\n\n**Revenue Potential and Business Models:**\nRevenue streams could be generated through:\n\n1.  **Direct Product Sales:** Manufacturing and selling display panels incorporating this technology to OEMs in consumer electronics, automotive, and other sectors.\n2.  **Licensing:** Licensing the patented technology to other display manufacturers or component suppliers, generating royalty income.\n3.  **IP-driven Partnerships:** Collaborating with key industry players to develop specific applications or integrate the technology into their product lines.\n\n**Strategic Positioning:**\nThis patent allows companies to strategically position themselves as innovators in next-generation display components. It enables a shift from incremental improvements (e.g., higher resolution, faster refresh rates) to fundamental architectural changes that unlock entirely new product categories and user experiences. The ability to offer a display that is inherently thinner, more robust, and more adaptable positions a company for long-term growth in a dynamic market.\n\n**ROI Projections:**\nWhile specific ROI will depend on investment in R&D, manufacturing scale-up, and market adoption, the potential returns are significant. The ability to capture market share in high-growth segments like flexible displays and AR/VR, coupled with potential manufacturing cost reductions and licensing revenues, suggests a strong ROI. Early movers could establish dominant positions, leveraging the unique capabilities of this wireless power delivery system to drive premium pricing and robust sales volumes. The long-term value lies in enabling products that are currently impossible or impractical, thereby creating entirely new markets.","faqs":[{"answer":"The **Display Device, System Having the Same, and Pixel** (US-9852691) is a groundbreaking patent that describes an innovative method for powering display devices. Unlike traditional displays that rely on complex wired connections to deliver electricity to each pixel, this patent introduces a system where power is transmitted wirelessly directly to the pixels within the display panel.\n\nSpecifically, the invention details a display device that incorporates a display panel containing numerous pixels, each equipped with a miniature wireless power receiver. A dedicated wireless power transmitter, also integrated into the display device, generates and broadcasts power wirelessly to these receivers. Each receiver then captures this energy and provides a stable power supply voltage directly to its corresponding pixels.\n\nThis approach fundamentally re-imagines the internal power distribution architecture of displays. By eliminating the need for extensive wired grids, the **Display Device, System Having the Same, and Pixel** paves the way for thinner, more flexible, and potentially more energy-efficient display technologies, opening up new possibilities for product design and functionality.","question":"What is Display Device, System Having the Same, and Pixel?"},{"answer":"The **Display Device, System Having the Same, and Pixel** operates on the principle of localized wireless power transfer. Here's a breakdown of its key components and their interaction:\n\nFirst, the display device includes a conventional power supply that generates an initial power supply voltage. This voltage is then fed to a central wireless power transmitter integrated within the display device. This transmitter is responsible for generating and broadcasting electromagnetic energy wirelessly across the display panel.\n\nSecond, the display panel itself is uniquely designed to house a plurality of pixels, each, or groups of which, are associated with a miniature wireless power receiver. These receivers are tuned to capture the electromagnetic energy transmitted by the wireless power transmitter. Upon receiving this wireless power, each receiver converts it into a stable direct current (DC) power supply voltage.\n\nFinally, this converted power supply voltage is then delivered directly to the pixels. This entire process occurs wirelessly within the display panel, effectively bypassing the need for traditional physical wiring to distribute power to individual pixels. The system ensures that each pixel receives the necessary power in an efficient and flexible manner, which is a core innovation of the **Display Device, System Having the Same, and Pixel**.","question":"How does Display Device, System Having the Same, and Pixel work?"},{"answer":"The **Display Device, System Having the Same, and Pixel** patent addresses several critical problems inherent in traditional display technology, primarily stemming from the reliance on wired power distribution to pixels.\n\nOne major issue is the **physical constraints** imposed by internal wiring. As displays strive for thinner profiles and greater flexibility (e.g., foldable or rollable screens), the intricate network of physical wires adds bulk, rigidity, and limits the degree to which a display can bend or stretch without damage. This makes innovative form factors difficult and expensive to achieve.\n\nAnother significant problem is **manufacturing complexity and cost**. The precision required to fabricate millions of microscopic conductive traces within a display panel is immense, leading to high manufacturing costs, lower yields, and increased potential for defects. The **Display Device, System Having the Same, and Pixel** aims to simplify this by reducing the need for such complex wiring.\n\nFurthermore, traditional wired systems can suffer from **power loss and efficiency issues** over long traces, and contribute to **electromagnetic interference (EMI)**. By implementing wireless power delivery directly at the pixel level, this patent seeks to mitigate these problems, paving the way for more efficient, reliable, and versatile display devices.","question":"What problem does Display Device, System Having the Same, and Pixel solve?"},{"answer":"The patent document for **Display Device, System Having the Same, and Pixel** (US-9852691) does not list the specific inventors or the assignee in the provided abstract data. Patents are typically filed by individual inventors, companies, or research institutions. The absence of this information in the abstract means it would require consulting the full patent document available from the U.S. Patent and Trademark Office (USPTO) or other patent databases to identify the inventors and the assignee (the entity to whom the patent rights are assigned).\n\nHowever, the innovation itself, as described in the **Display Device, System Having the Same, and Pixel** patent, represents a significant collaborative effort in the fields of display technology and wireless power transfer. Such advancements often come from teams of electrical engineers, materials scientists, and display architects working in leading technology companies or academic research labs focused on next-generation electronics.","question":"Who invented Display Device, System Having the Same, and Pixel?"},{"answer":"The **Display Device, System Having the Same, and Pixel** patent offers several transformative benefits for the display industry and end-users:\n\nFirstly, it enables **unprecedented design flexibility and thinness**. By eliminating the need for bulky internal wiring, displays can be made significantly thinner, lighter, and truly flexible. This opens the door for innovative form factors like rollable TVs, foldable smartphones without visible creases, and displays that can seamlessly curve around objects or integrate into clothing.\n\nSecondly, the technology promises **enhanced manufacturing efficiency and potentially lower costs**. Reducing the complexity of internal wiring can lead to higher manufacturing yields, fewer defects, and streamlined production processes. This could make advanced display technologies more accessible and affordable in the long run, thereby expanding the market for display devices.\n\nFinally, the **Display Device, System Having the Same, and Pixel** can lead to **improved energy efficiency and reliability**. Localized wireless power delivery can potentially optimize power consumption at the pixel level and reduce resistive losses associated with long wired traces. Fewer physical connections also mean fewer points of failure, contributing to more robust and durable display devices with extended lifespans.","question":"What are the key benefits of Display Device, System Having the Same, and Pixel?"},{"answer":"The **Display Device, System Having the Same, and Pixel** fundamentally differs from prior art in display technology by revolutionizing the method of power delivery to pixels. Prior art predominantly relies on **wired power distribution**, where an intricate network of conductive traces is embedded within the display panel to physically route electricity to each pixel or pixel group.\n\nThis traditional wired approach, while effective, introduces inherent limitations: it adds **thickness and rigidity** to the display, restricts **design flexibility** (making foldable or rollable screens challenging), increases **manufacturing complexity**, and can lead to **power loss and EMI**. Prior art has focused on refining these wired methods, pushing the limits of miniaturization and material science within this framework.\n\nIn contrast, the **Display Device, System Having the Same, and Pixel** introduces an **integrated wireless power system**. It replaces the wired grid with miniature wireless power receivers at the pixel level and a wireless power transmitter within the device. This effectively decouples power delivery from physical wiring, thereby directly addressing and overcoming the core limitations of prior art. This innovation enables truly thin, flexible, and robust displays that were previously impractical or impossible with conventional wired power systems.","question":"How is Display Device, System Having the Same, and Pixel different from prior art?"},{"answer":"The **Display Device, System Having the Same, and Pixel** patent has the potential to significantly impact a wide array of industries, revolutionizing how visual information is presented and interacted with.\n\n**Consumer Electronics** will see a massive transformation, enabling next-generation smartphones, tablets, and laptops with truly foldable, rollable, or even stretchable screens. Wearable technology, including smartwatches and AR/VR headsets, will benefit from lighter, thinner, and more comfortable displays, enhancing user experience and accelerating adoption.\n\nIn the **Automotive Industry**, this technology can lead to seamlessly integrated, custom-shaped displays that conform to interior designs, as well as transparent displays for windshields providing heads-up navigation. **Architecture and Smart Home** applications will also be impacted, allowing for interactive displays embedded in windows, mirrors, furniture, or walls, creating dynamic and adaptable living or working spaces.\n\nFurthermore, specialized fields like **Medical Technology** could utilize flexible, lightweight displays for diagnostic tools or integrated health monitors. The **Display Device, System Having the Same, and Pixel** offers a foundational shift that will enable new product categories and innovative user interfaces across virtually every sector that utilizes display technology.","question":"What industries will Display Device, System Having the Same, and Pixel impact?"},{"answer":"The **Display Device, System Having the Same, and Pixel** patent, identified by the number US-9852691, has specific dates associated with its filing and publication.\n\nThe **Filing Date** for this patent application was **2015-05-12**. This is the date when the patent application was officially submitted to the U.S. Patent and Trademark Office (USPTO). The filing date is significant as it often establishes the priority date for the invention, which can be crucial in cases of patent disputes or determining prior art.\n\nThe **Publication Date**, which is when the patent was officially granted and publicly disclosed, was **2017-12-26**. This date marks the point when the full details of the **Display Device, System Having the Same, and Pixel** invention, including its claims and specifications, became publicly accessible. The granting of the patent signifies that the USPTO has recognized the invention as novel, non-obvious, and useful, thereby granting the patent holder exclusive rights for a period, typically 20 years from the earliest filing date.","question":"When was Display Device, System Having the Same, and Pixel filed/granted?"},{"answer":"The commercial applications of the **Display Device, System Having the Same, and Pixel** patent are extensive and diverse, promising to reshape numerous product categories and create entirely new ones. The core innovation of wireless power delivery to pixels unlocks unprecedented design freedom and functional capabilities.\n\nIn **consumer electronics**, this technology can lead to truly foldable smartphones and tablets that are thinner, lighter, and more durable, offering a superior user experience. Rollable televisions, smartwatches with fully flexible displays, and advanced augmented reality (AR) and virtual reality (VR) headsets with lighter and more integrated screens are also direct applications. The **Display Device, System Having the Same, and Pixel** enables these devices to move beyond rigid form factors.\n\nBeyond personal devices, the patent has significant implications for **automotive displays**, allowing for seamless, custom-shaped screens that integrate flawlessly into vehicle interiors or even transparent displays embedded in windshields. In **smart home and architectural design**, it can facilitate interactive displays on windows, mirrors, or walls, making digital interfaces an invisible part of the environment. The ability to create ultra-thin, flexible, and efficient displays will drive innovation in markets valuing aesthetic integration, user comfort, and advanced functionality.","question":"What are the commercial applications of Display Device, System Having the Same, and Pixel?"},{"answer":"The **Display Device, System Having the Same, and Pixel** patent lays a foundational groundwork, and future developments are expected to build upon this innovation to push display technology even further.\n\nOne key area of development will be in **miniaturization and efficiency**. Researchers will likely focus on making the wireless power receivers even smaller and more efficient, allowing for higher pixel densities and reduced power consumption. This will be crucial for ultra-high-resolution displays like micro-LEDs. Advancements in materials science will also play a role in creating transparent and flexible wireless components that don't compromise display quality or form factor.\n\nAnother expected development is **intelligent power management**. Future systems could incorporate advanced algorithms to dynamically adjust wireless power transmission based on content being displayed, individual pixel requirements, or ambient conditions. This would further optimize energy efficiency and thermal performance. We can also anticipate the exploration of new wireless power transfer protocols and frequencies to enhance range, efficiency, and robustness. The **Display Device, System Having the Same, and Pixel** is expected to evolve towards displays that are not only flexible and thin but also highly adaptive, self-powering, and seamlessly integrated into every aspect of our lives, from smart clothing to futuristic architectural elements.","question":"What are the future developments expected for Display Device, System Having the Same, and Pixel?"}],"topics":["display device","wireless power","pixel technology","display panel","power supply","relentless","drive","higher"],"tech_cluster":null},"seo":{"title":"Wireless Power Displays: Display Device, System Having the Same, and Pixel Patent US-9852691","description":"Explore the Display Device, System Having the Same, and Pixel patent, revolutionizing display technology with integrated wireless power delivery to pixels for thinner, flexible screens.","keywords":["display device","wireless power","pixel technology","display panel","power supply","display innovation","flexible displays","efficient displays","US-9852691","patent","next-gen displays","OLED power","micro-LED power"]},"attribution":{"source":"Patentable","source_url":"https://patentable.app","canonical_url":"https://patentable.app/patents/US-9852691","license":"CC-BY-4.0-like","license_terms":"AI-generated analysis on this page (summary, layman_explanation, technical_analysis, business_analysis, faqs) may be reused with attribution and a visible link back to the canonical URL above. Patent abstracts, claims, and bibliographic data are USPTO public domain.","required_link":"https://patentable.app/patents/US-9852691","citation_suggestion":"Patentable. \"Display device, system having the same, and pixel\" (US-9852691). https://patentable.app/patents/US-9852691","copyright_holder":"Nomic Interactive Technology LLC"},"links":{"html":"https://patentable.app/patents/US-9852691","json":"https://patentable.app/api/llm-context/US-9852691","site":"https://patentable.app","llms_txt":"https://patentable.app/llms.txt"},"generated_at":"2026-06-06T09:27:31.725Z"}