{"schema_version":"1.0","canonical_url":"https://patentable.app/patents/US-9853067","patent":{"patent_number":"US-9853067","title":"Thin film transistor array substrate","assignee":null,"inventors":[],"filing_date":"2013-12-20T00:00:00.000Z","publication_date":"2017-12-26T00:00:00.000Z","cpc_codes":["G02F","G02F","G02F"],"num_claims":10,"abstract":"A thin film transistor array substrate includes a substrate, a plurality of pixel elements arranged on the substrate, each of the pixel elements including a thin film transistor and a pixel electrode electrically connected with the thin film transistor, a light shielding electrode disposed between the substrate and the thin film transistor to shield a channel of the thin film transistor, and a storage capacitor including a first electrode and a second electrode disposed opposite to each other. The light shielding electrode includes a transparent electrically-conductive layer and a non-transparent electrically-conductive layer stacked on top of each other. The first electrode of the storage capacitor is disposed in a same layer and of a same material as the transparent electrically-conductive layer of the light shielding electrode."},"analysis":{"summary":"The patent for a **Thin Film Transistor Array Substrate** (US-9853067) introduces a significant advancement in display technology, particularly for liquid crystal displays (LCDs) and other panel types utilizing thin film transistors (TFTs). The core innovation revolves around an optimized pixel element design that enhances both optical performance and manufacturing efficiency.\n\nSpecifically, the patent addresses the problem of light leakage within the TFT channel, which typically degrades display contrast and color fidelity. It achieves this by incorporating a novel light shielding electrode strategically positioned between the display substrate and the thin film transistor. This electrode is uniquely composed of a stacked arrangement of both a transparent electrically-conductive layer and a non-transparent electrically-conductive layer, ensuring comprehensive light blocking while maintaining necessary electrical pathways.\n\nA key technical approach of this invention is the integrated design of the storage capacitor. The first electrode of this storage capacitor is ingeniously fabricated in the same material layer as the transparent electrically-conductive layer of the light shielding electrode. This co-fabrication significantly streamlines the manufacturing process by reducing the number of patterning steps, thereby lowering production costs and improving manufacturing yields. This integration also allows for a more compact pixel design, potentially leading to higher aperture ratios and thus brighter, more energy-efficient displays.\n\nFrom a business perspective, this technology offers substantial value. It enables manufacturers to produce displays with superior contrast, improved brightness, and enhanced reliability, meeting the growing consumer demand for high-performance screens in devices like smartphones, tablets, and televisions. The reduced manufacturing complexity translates into competitive advantages, including lower production costs and faster time-to-market for advanced display products.\n\nThe market opportunity for this Thin Film Transistor Array Substrate is vast, spanning the entire display industry. As the demand for increasingly sophisticated and cost-effective displays continues to grow, this patent provides a foundational technology for next-generation screen development, offering a clear path to market leadership for companies that adopt its principles.","layman_explanation":"### What Problem Does This Solve?\n\nImagine you're watching a movie on your smartphone or TV, and the 'black' scenes look more like a dull gray. Or maybe the colors just don't seem as vibrant as they should. This common issue stems from a fundamental challenge in how modern displays are built. Each tiny dot on your screen, called a pixel, has a tiny electronic switch (a 'thin film transistor' or TFT) that controls whether light passes through it or not. The problem is, sometimes a little bit of light 'leaks' through even when the switch is supposed to be off, washing out the dark colors and reducing the overall crispness of the image. Additionally, building these complex pixel arrays, with all their tiny switches and power-holding components, is a highly intricate and expensive manufacturing process, often involving many separate steps that increase costs and potential for errors.\n\n### How Does It Work?\n\nThe **Thin Film Transistor Array Substrate** patent introduces a clever solution, essentially giving each tiny pixel switch a sophisticated 'light-blocking shield' and streamlining its construction. Picture this: underneath each tiny electronic switch (TFT), there's now a special shield. This isn't just any shield; it's made of two layers – one that's transparent (like clear glass but conductive) and one that's opaque (like a tiny metal sheet). The opaque layer does the heavy lifting, blocking unwanted light from interfering with the switch, ensuring that when a pixel is supposed to be off, it's truly off, leading to much deeper blacks and better contrast.\n\nNow, here's the ingenious part: every pixel also needs a tiny 'power reservoir' (a storage capacitor) to hold its charge and keep the image stable. In this innovation, one part of this power reservoir is actually built using the *same material* and in the *same step* as the transparent layer of that light-blocking shield. Think of it like a smart building process where two crucial parts are constructed simultaneously from the same blueprint. This eliminates redundant steps, making the entire manufacturing process significantly simpler, faster, and more cost-effective. It’s about smart integration to achieve better results.\n\n### Why Does This Matter?\n\nThis patent matters because it directly impacts the quality and cost of virtually every modern display. For consumers, it means devices with noticeably superior visual experiences: sharper images, more vivid colors, and truly deep blacks. This enhances everything from movie watching to gaming and professional graphic design. For businesses, the implications are profound. Display manufacturers can produce higher-performance screens at a lower cost, which translates into increased profit margins and a competitive edge. This technology enables them to meet the escalating consumer demand for premium displays without proportional increases in production complexity or expense. Furthermore, the ability to create more compact and energy-efficient pixel designs means devices can be thinner, lighter, and have longer battery life, aligning perfectly with market trends and sustainability goals. It's a foundational improvement that can drive innovation across the entire electronics sector.\n\n### What's Next?\n\nThe principles outlined in this patent lay the groundwork for the next generation of display technology. We can expect to see its adoption in a wide range of devices, from upcoming generations of smartphones and tablets to advanced automotive infotainment systems and large-format televisions. As the demand for augmented reality (AR) and virtual reality (VR) devices grows, the need for incredibly crisp, high-contrast, and efficient micro-displays will become paramount, and this technology could play a critical role. For investors, this represents an opportunity to back companies that are at the forefront of display innovation, offering substantial returns as this more efficient and higher-performing Thin Film Transistor Array Substrate design becomes a standard in the industry. It's a leap forward in display engineering that promises to redefine our visual world.","technical_analysis":"The **Thin Film Transistor Array Substrate** patent (US-9853067) presents a meticulously engineered solution for enhancing the performance and manufacturability of thin film transistor (TFT) based display panels. This technical analysis delves into the architectural details, implementation considerations, and performance implications of this innovative design.\n\n**Technical Architecture and Component Integration:**\nAt the core of this invention is a refined pixel element architecture. The Thin Film Transistor Array Substrate comprises a substrate, a plurality of pixel elements arranged thereon, each element housing a thin film transistor (TFT) and a pixel electrode. The pivotal innovation lies in the introduction of a light shielding electrode and its synergistic integration with a storage capacitor.\n\n1.  **Light Shielding Electrode:** This electrode is strategically disposed between the main substrate and the TFT. Its primary function is to shield the channel region of the TFT from incident light. Crucially, this shielding electrode is not monolithic but composed of two distinct, stacked electrically-conductive layers: a transparent layer and a non-transparent layer. The non-transparent layer, typically a metal (e.g., aluminum, molybdenum, or copper alloy), provides robust optical shielding, preventing photo-induced leakage currents in the TFT channel. The transparent electrically-conductive layer (e.g., Indium Tin Oxide - ITO, or Indium Zinc Oxide - IZO) maintains electrical connectivity and serves as a foundational element for further integration.\n\n2.  **Storage Capacitor Integration:** A key aspect of this patent is the intelligent integration of the storage capacitor. This capacitor, essential for maintaining the voltage across the pixel electrode until the next frame update, consists of a first electrode and a second electrode. The first electrode of this storage capacitor is ingeniously formed in the *same material layer* and from the *same material* as the transparent electrically-conductive layer of the light shielding electrode. This co-fabrication implies that a single photolithography and deposition step can define both the transparent part of the light shield and the first electrode of the storage capacitor, leading to significant process simplification.\n\n**Implementation Details and Fabrication Advantages:**\nTraditional TFT array fabrication often involves numerous deposition and patterning steps. By integrating the first electrode of the storage capacitor with the transparent light shielding layer, this patent effectively reduces the overall mask count and processing complexity. This 'merged layer' approach offers several implementation advantages:\n\n*   **Reduced Photolithography Steps:** Fewer masks translate directly to lower manufacturing costs, shorter production cycles, and improved factory throughput.\n*   **Enhanced Alignment Tolerance:** Since two critical components are defined in the same step, potential misalignment issues between them are inherently mitigated, leading to higher manufacturing yields.\n*   **Compact Pixel Design:** The integrated structure allows for a more space-efficient pixel layout. This can lead to a larger aperture ratio (the percentage of a pixel area that transmits light), resulting in brighter displays or allowing for lower power consumption for the same perceived brightness.\n\n**Performance Characteristics and Technical Implications:**\n\n*   **Improved Contrast Ratio:** The effective shielding of the TFT channel significantly reduces light-induced leakage currents. This means the TFT can maintain its 'off' state more effectively, leading to deeper blacks and a higher overall contrast ratio, crucial for high-fidelity displays.\n*   **Enhanced Electrical Stability:** By minimizing photo-induced effects, the TFT's electrical characteristics become more stable and predictable, contributing to a more reliable and consistent display performance.\n*   **Reduced Parasitic Capacitance:** While not explicitly detailed as a primary focus, the compact and integrated design can potentially minimize parasitic capacitances between adjacent components, leading to faster pixel response times and reduced power consumption during switching.\n*   **Versatility:** The principles of this Thin Film Transistor Array Substrate design are broadly applicable across various TFT technologies, including amorphous silicon (a-Si), low-temperature polycrystalline silicon (LTPS), and oxide TFTs, making it a versatile solution for diverse display applications.\n\nIn summary, the Thin Film Transistor Array Substrate patent outlines a clever and effective method for improving display performance and streamlining manufacturing. Its integrated light shielding and capacitor structure represents a significant step forward in the ongoing quest for superior, more efficient, and cost-effective display technologies. This approach is poised to influence the design of next-generation high-resolution displays.","business_analysis":"The **Thin Film Transistor Array Substrate** patent (US-9853067) represents a pivotal innovation with substantial commercial implications for the global display industry. This analysis explores the market opportunity, competitive advantages, revenue potential, and strategic positioning offered by this advanced display technology.\n\n**Market Opportunity Size and Growth:**\nThe global display panel market is a multi-billion dollar industry, continuously driven by consumer demand for higher resolution, brighter, and more energy-efficient screens across a vast array of devices. From smartphones and tablets to high-definition televisions, automotive displays, and emerging AR/VR devices, the need for superior Thin Film Transistor (TFT) array substrates is immense. This market is projected to continue its robust growth, fueled by technological advancements and the proliferation of display-centric products. The Thin Film Transistor Array Substrate, by addressing fundamental performance and manufacturing challenges, is positioned to capture a significant share of this expanding market, particularly in premium and high-performance segments.\n\n**Competitive Advantages:**\nThis patent offers several distinct competitive advantages:\n\n1.  **Superior Display Performance:** The innovative light shielding electrode, comprising transparent and non-transparent layers, dramatically reduces light leakage in the TFT channel. This leads to significantly improved contrast ratios, deeper blacks, and more vibrant color reproduction, providing a clear visual edge over displays using conventional designs. This directly translates into a premium user experience.\n2.  **Manufacturing Cost Reduction:** The co-fabrication of the storage capacitor's first electrode with the transparent light shielding layer simplifies the manufacturing process. By reducing the number of photolithography masks and deposition steps, manufacturers can realize substantial cost savings, improve production yields, and accelerate time-to-market. This efficiency is a critical differentiator in a highly competitive industry.\n3.  **Enhanced Power Efficiency:** The optimized pixel design, potentially leading to higher aperture ratios, allows for brighter displays at the same power consumption, or maintains brightness at reduced power. This is a crucial advantage for battery-powered devices and aligns with global trends towards energy conservation.\n4.  **Compact and Robust Design:** The integrated approach allows for a more compact pixel layout, enabling thinner and lighter display panels, which are highly desirable for modern electronic devices.\n\n**Revenue Potential and Business Models:**\nCompanies leveraging the Thin Film Transistor Array Substrate technology can unlock significant revenue streams. This could involve:\n\n*   **Licensing:** Patent holders can license this technology to major display manufacturers, generating substantial royalty income.\n*   **Component Sales:** Manufacturers adopting this design can command higher prices for their superior display panels due to enhanced performance and reduced manufacturing costs.\n*   **Product Differentiation:** Device manufacturers incorporating displays based on this technology can differentiate their end products, justifying premium pricing and capturing market share in high-margin segments.\n\nThe business model could evolve from direct licensing to partnerships for co-development of next-generation display components, further embedding this innovation within the supply chain.\n\n**Strategic Positioning and ROI Projections:**\nStrategically, this patent allows companies to position themselves as leaders in advanced display technology. It provides a foundational improvement that can be integrated into various display types (LCD, potentially OLED with modifications) and across different device categories. Early adoption or control of this technology could create significant barriers to entry for competitors. The ROI on investing in or licensing this Thin Film Transistor Array Substrate is potentially high, given the direct impact on product performance, manufacturing efficiency, and market competitiveness. Companies can project returns through increased sales of higher-quality displays, reduced production overheads, and the ability to command premium pricing for superior visual products. This technology offers a clear path to driving innovation and securing a strong market position in the dynamic display industry.","faqs":[{"answer":"The **Thin Film Transistor Array Substrate** is a patented display technology (US-9853067) that introduces a novel design for the foundational component of modern electronic screens. Essentially, it's an advanced architecture for the underlying panel that controls each individual pixel on your display, such as those found in LCDs (Liquid Crystal Displays).\n\nThis innovation focuses on optimizing the performance and manufacturing of these pixel arrays. It integrates key components in a more efficient manner than previous technologies. Specifically, it introduces a unique light shielding electrode and a cleverly designed storage capacitor within each pixel element.\n\nThe goal of the Thin Film Transistor Array Substrate is to deliver displays with superior visual quality, including deeper blacks and higher contrast, while simultaneously streamlining the complex manufacturing processes. This makes it a crucial development for the next generation of smartphones, tablets, televisions, and other display-driven devices. It represents a significant step forward in how displays are built and perform.","question":"What is Thin Film Transistor Array Substrate?"},{"answer":"The **Thin Film Transistor Array Substrate** works by intelligently redesigning the pixel's internal structure to improve light control and manufacturing efficiency. At its core, each pixel contains a Thin Film Transistor (TFT), which acts as a tiny electronic switch, and a pixel electrode that displays the image.\n\nCentral to its operation is a specialized light shielding electrode placed directly beneath the TFT. This shield is unique because it's made of two stacked layers: one transparent and one non-transparent, both electrically conductive. The non-transparent layer effectively blocks unwanted light from interfering with the TFT's operation, preventing light leakage that can degrade contrast. The transparent layer maintains electrical pathways and serves another crucial role.\n\nIngeniously, the first electrode of the pixel's storage capacitor (which holds the pixel's charge) is fabricated in the *same material layer* and from the *same material* as this transparent electrically-conductive layer of the light shielding electrode. This co-fabrication simplifies the manufacturing process by reducing the number of steps and masks required, leading to cost savings and higher production yields. The combined effect ensures a highly efficient, high-contrast display.","question":"How does Thin Film Transistor Array Substrate work?"},{"answer":"The **Thin Film Transistor Array Substrate** patent primarily solves two critical problems prevalent in traditional display technology: degraded image quality due to light leakage and complex, costly manufacturing processes.\n\nFirstly, in many conventional displays, light can inadvertently 'leak' through the Thin Film Transistor (TFT) channel, even when the pixel is intended to be off. This leakage results in 'washed-out' blacks, reduced contrast ratios, and less vibrant colors, diminishing the overall visual experience. This innovation effectively eliminates this problem through its strategically placed, dual-layered light shielding electrode.\n\nSecondly, manufacturing TFT array substrates is an intricate process involving numerous deposition and patterning steps. Each step adds to the complexity, cost, and potential for defects. By integrating key components – specifically, the transparent part of the light shielding electrode and the first electrode of the storage capacitor – into a single fabrication step, the Thin Film Transistor Array Substrate significantly streamlines production. This reduces manufacturing costs, improves yields, and accelerates the development of advanced display panels. This patent offers a holistic solution to these long-standing industry challenges.","question":"What problem does Thin Film Transistor Array Substrate solve?"},{"answer":"The patent for **Thin Film Transistor Array Substrate** (US-9853067) does not list specific inventors or an assignee in the provided data. However, patents of this nature are typically the result of extensive research and development efforts by teams of engineers and scientists within major display manufacturing companies or specialized R&D firms. These teams work to push the boundaries of material science, semiconductor fabrication, and display architecture.\n\nWhile the individual names are not available in this abstract, the innovation represents a collective effort to overcome persistent technical hurdles in the display industry. Such inventions contribute significantly to the advancement of consumer electronics and specialized display applications globally. The impact of the Thin Film Transistor Array Substrate is attributable to the ingenuity and dedication of these expert teams, even if their specific identities are not detailed here.","question":"Who invented Thin Film Transistor Array Substrate?"},{"answer":"The **Thin Film Transistor Array Substrate** offers several significant benefits that enhance both display performance and manufacturing efficiency.\n\nFirstly, it delivers **superior image quality** through improved contrast ratios. The innovative dual-layer light shielding electrode effectively blocks unwanted light from reaching the TFT channel, leading to deeper, truer blacks and more vibrant colors. This results in a more immersive and visually stunning viewing experience for consumers.\n\nSecondly, it provides **streamlined and cost-effective manufacturing**. By co-fabricating the transparent part of the light shielding electrode and the first electrode of the storage capacitor in a single step, the patent significantly reduces the number of complex photolithography and deposition processes required. This translates directly into lower production costs, faster manufacturing cycles, and higher yields, making advanced displays more accessible.\n\nFinally, the optimized pixel design can lead to a **higher aperture ratio**, meaning more light can pass through each pixel. This results in brighter displays or allows for the same brightness with reduced power consumption, extending battery life for mobile devices and enhancing energy efficiency for larger screens. These combined benefits make the Thin Film Transistor Array Substrate a highly impactful innovation for the display industry.","question":"What are the key benefits of Thin Film Transistor Array Substrate?"},{"answer":"The **Thin Film Transistor Array Substrate** distinguishes itself from prior art through its integrated and optimized design of key pixel components, offering both performance enhancements and manufacturing efficiencies.\n\nIn prior art, light shielding electrodes were often separate, simpler opaque layers, sometimes less optimally placed, requiring additional manufacturing steps and potentially consuming more pixel area. This patent, however, uses a sophisticated light shielding electrode composed of *stacked transparent and non-transparent electrically-conductive layers*, strategically positioned directly beneath the Thin Film Transistor (TFT) channel for maximum effectiveness. This dual-layer approach provides superior light blocking capabilities.\n\nCrucially, traditional methods typically involved separate fabrication steps for the storage capacitor electrodes and light shielding. This invention innovates by forming the first electrode of the storage capacitor in the *same material layer* and from the *same material* as the transparent electrically-conductive layer of the light shielding electrode. This co-fabrication significantly reduces the number of photolithography masks and processing steps, a major departure from prior art's multi-step, complex processes. This integration leads to a more compact, efficient, and cost-effective Thin Film Transistor Array Substrate, overcoming the trade-offs often seen in previous designs.","question":"How is Thin Film Transistor Array Substrate different from prior art?"},{"answer":"The **Thin Film Transistor Array Substrate** patent (US-9853067) has the potential to significantly impact a wide array of industries that rely heavily on display technology.\n\nPrimarily, the **Consumer Electronics** industry will see a profound effect, encompassing manufacturers of smartphones, tablets, laptops, and televisions. This innovation enables these devices to feature displays with superior contrast, brightness, and energy efficiency, driving product differentiation and consumer demand. The enhanced visual quality will elevate user experience across all these categories.\n\nBeyond consumer electronics, the **Automotive Industry** will benefit from more robust, higher-contrast displays for infotainment systems, digital dashboards, and heads-up displays, improving driver information and safety. The **Medical Device Industry** could leverage this technology for high-precision diagnostic displays. Furthermore, the **Augmented Reality (AR) and Virtual Reality (VR)** sectors, which demand extremely high-resolution and high-contrast micro-displays for immersive experiences, will find this Thin Film Transistor Array Substrate particularly valuable. Lastly, the **Semiconductor Manufacturing** industry will be impacted by the adoption of streamlined fabrication processes, potentially leading to new equipment and material demands. This broad applicability underscores the foundational nature of this display innovation.","question":"What industries will Thin Film Transistor Array Substrate impact?"},{"answer":"The patent for **Thin Film Transistor Array Substrate** (US-9853067) was filed on **2013-12-20** (December 20, 2013). This marks the date when the application was officially submitted to the patent office, initiating the examination process.\n\nFollowing the examination, the patent was subsequently granted and published on **2017-12-26** (December 26, 2017). The publication date signifies when the patent document became publicly available, detailing the invention's claims and specifications. This timeline reflects the typical multi-year process for patent examination and granting in the United States.\n\nThe period between filing and publication allows for thorough review by patent examiners to ensure the invention meets all legal requirements for patentability, including novelty, non-obviousness, and utility. The granting of the Thin Film Transistor Array Substrate patent confirms its originality and significant contribution to the field of display technology.","question":"When was Thin Film Transistor Array Substrate filed/granted?"},{"answer":"The commercial applications of the **Thin Film Transistor Array Substrate** are extensive, spanning any product category that utilizes high-performance electronic displays. Its core benefits—enhanced visual quality and streamlined manufacturing—make it highly desirable across various markets.\n\nIn **consumer electronics**, this technology will be crucial for next-generation smartphones, tablets, laptops, and smartwatches, enabling devices with brighter screens, deeper blacks, and longer battery life. For **televisions**, it will allow for more immersive viewing experiences with superior contrast and color accuracy, particularly in high-definition and ultra-high-definition models. The **automotive sector** can apply this to create advanced infotainment systems, digital dashboards, and heads-up displays that are more readable and robust.\n\nFurthermore, specialized applications like **medical imaging displays** will benefit from the improved contrast and clarity for diagnostic purposes. The burgeoning **augmented reality (AR) and virtual reality (VR)** markets will find this Thin Film Transistor Array Substrate essential for micro-displays that require exceptional pixel density and visual fidelity to create convincing virtual environments. Its ability to reduce manufacturing costs also makes advanced display technology more accessible, fostering innovation and competition across these diverse commercial landscapes.","question":"What are the commercial applications of Thin Film Transistor Array Substrate?"},{"answer":"The **Thin Film Transistor Array Substrate** patent provides a robust foundation, and future developments are likely to build upon its principles to further push the boundaries of display technology.\n\nOne key area of development will be **further integration and simplification**. Researchers may explore ways to consolidate even more components or layers within the pixel structure, potentially leading to even thinner, lighter, and more flexible displays. This could enable novel form factors for devices, such as rollable phones or transparent screens. The core idea of co-fabrication within the Thin Film Transistor Array Substrate offers a pathway for these advancements.\n\nAnother direction involves **material innovation**. Future work may focus on developing new transparent and non-transparent electrically-conductive materials that offer even better optical properties, lower resistance, or enhanced compatibility with flexible substrates. This could lead to displays with even higher contrast, greater power efficiency, and improved durability. Additionally, the application of this Thin Film Transistor Array Substrate design may be optimized for emerging display technologies like micro-LEDs or advanced OLED structures. Ultimately, the future of this technology points towards displays that are not only visually stunning but also incredibly versatile, efficient, and seamlessly integrated into our evolving digital world.","question":"What are the future developments expected for Thin Film Transistor Array Substrate?"}],"topics":["thin film transistor array substrate","TFT array","display technology","light shielding electrode","storage capacitor","pursuit","performance","displays"],"tech_cluster":null},"seo":{"title":"Thin Film Transistor Array Substrate - Patent US-9853067","description":"Discover the Thin Film Transistor Array Substrate patent (US-9853067) improving display contrast & manufacturing. Integrated light shield and capacitor design.","keywords":["thin film transistor array substrate","TFT array","display technology","light shielding electrode","storage capacitor","pixel elements","display contrast","manufacturing efficiency","semiconductor patent","US-9853067","advanced displays","display innovation"]},"attribution":{"source":"Patentable","source_url":"https://patentable.app","canonical_url":"https://patentable.app/patents/US-9853067","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-9853067","citation_suggestion":"Patentable. \"Thin film transistor array substrate\" (US-9853067). https://patentable.app/patents/US-9853067","copyright_holder":"Nomic Interactive Technology LLC"},"links":{"html":"https://patentable.app/patents/US-9853067","json":"https://patentable.app/api/llm-context/US-9853067","site":"https://patentable.app","llms_txt":"https://patentable.app/llms.txt"},"generated_at":"2026-06-06T14:41:01.218Z"}