{"schema_version":"1.0","canonical_url":"https://patentable.app/patents/US-9853060","patent":{"patent_number":"US-9853060","title":"Thin film transistor substrate and method of manufacturing the same","assignee":null,"inventors":[],"filing_date":"2015-05-08T00:00:00.000Z","publication_date":"2017-12-26T00:00:00.000Z","cpc_codes":["G02F","G02F","H01L","G02F","G09G"],"num_claims":13,"abstract":"A TFT substrate including a base substrate that includes a plurality of pixel areas; a gate line on the base substrate and extending in a first direction; a data line on the gate line and extending in a second direction; a TFT connected to the gate line and the data line, the TFT including a gate electrode, a semiconductor pattern, and source and drain electrodes, the semiconductor pattern overlapping the gate electrode, the source electrode and the drain electrode overlapping the semiconductor pattern, and the drain electrode being spaced apart from the source electrode; an inorganic insulating pattern covering the data line, the inorganic insulating pattern including an opening aligned with the pixel areas; a shielding electrode overlapping the data line, the shielding electrode on the inorganic insulating pattern; and a pixel electrode on the pixel areas, the pixel electrode being electrically connected to the drain electrode through a first contact hole."},"analysis":{"summary":"The patent titled \"Thin Film Transistor Substrate and Method of Manufacturing the Same\" (US-9853060) introduces a groundbreaking advancement in display technology, specifically for Thin Film Transistor (TFT) substrates. The core innovation lies in its meticulously designed layered structure and an optimized manufacturing process aimed at significantly enhancing display performance and fabrication efficiency.\n\nThe primary problem this invention solves is the pervasive issue of signal interference, known as parasitic capacitance and crosstalk, within high-resolution displays. Traditional TFT architectures often suffer from these issues, leading to visual artifacts, reduced image quality, and complex, costly manufacturing processes. This patent directly addresses these challenges by proposing a novel structural configuration.\n\nKey to its technical approach is a TFT substrate comprising a base substrate, gate and data lines, and a TFT with a gate electrode, semiconductor pattern, and source/drain electrodes. The breakthrough comes with the inclusion of an inorganic insulating pattern covering the data line, which features an opening aligned with pixel areas. Crucially, a shielding electrode is strategically placed on this inorganic insulating pattern, overlapping the data line. This shielding electrode acts as an electrostatic barrier, effectively minimizing unwanted electrical coupling between the data line and the pixel electrode, thereby ensuring cleaner signal transmission.\n\nFrom a business perspective, this technology offers substantial value. It enables the production of higher-resolution, more reliable, and energy-efficient displays, which are increasingly demanded across various sectors. Manufacturers can benefit from potentially streamlined fabrication processes, reduced defect rates, and improved yields, leading to lower production costs. The market opportunity is immense, spanning consumer electronics like smartphones, tablets, and advanced televisions, to specialized applications in automotive displays, virtual reality headsets, and industrial monitors. This innovation provides a competitive edge for companies adopting it, positioning them at the forefront of the next generation of visual display solutions.","layman_explanation":"### What Problem Does This Solve?\n\nImagine you're trying to send millions of tiny, precise instructions every second to light up the individual pixels on your smartphone or TV screen. Each instruction needs to be perfectly clear, otherwise, your picture looks fuzzy, colors aren't quite right, or fast-moving action blurs. The core issue in current display technology is like having too many wires running too close together: the electrical signals can 'leak' or 'interfere' with each other. This interference, called parasitic capacitance or crosstalk, is a huge headache for manufacturers. It makes it incredibly difficult and expensive to build screens with super high resolutions (like 4K or 8K) or super-fast refresh rates (like for gaming), because the clearer you want the picture, the more precisely those signals need to be isolated. Existing solutions often involve complex, costly workarounds or simply accepting a lower quality ceiling.\n\n### How Does It Work?\n\nThe patent titled \"Thin Film Transistor Substrate and Method of Manufacturing the Same\" offers an elegant solution by redesigning the very foundation of the screen: the Thin Film Transistor (TFT) substrate. Think of the TFT substrate as the intricate circuit board behind every single pixel. This innovation introduces a clever layering approach. Instead of just having the basic wires (gate lines and data lines) and tiny switches (TFTs) for each pixel, this patent adds two crucial elements. First, it places a special, durable insulating layer (an inorganic insulating pattern) that covers the main data-carrying wires. Second, and most ingeniously, it adds a thin, conductive 'shield' (a shielding electrode) directly over these data wires, but separated by the insulation. This shield acts like an invisible, electrical fence. When the data signal travels down its wire, the shield captures any 'leaked' electricity and prevents it from interfering with the neighboring pixel's instructions. It's like giving each whisper a soundproof booth so it only reaches the intended ear, ensuring every pixel gets its crystal-clear command without distortion.\n\n### Why Does This Matter?\n\nThis invention matters because it unlocks the next generation of visual experiences. By effectively eliminating signal interference at the fundamental substrate level, this technology allows manufacturers to build displays that are significantly clearer, sharper, and more vibrant. This means your next TV could have even more stunning 8K resolution without any visual compromises, your smartphone screen could be brighter and more responsive, and new applications like highly immersive virtual reality headsets could finally deliver truly seamless visuals. For businesses, this translates into several key advantages: a competitive edge through superior product performance, potentially lower manufacturing costs due to reduced defects and simpler assembly (as complex external compensation circuits might become unnecessary), and access to growing markets for high-end displays. This innovation isn't just about making screens look better; it's about enabling a whole new class of devices and user interactions.\n\n### What's Next?\n\nThe impact of this technology will likely be seen across various industries. From consumer electronics driving demand for higher quality, to specialized fields like medical imaging, automotive displays, and even aerospace, where clarity and reliability are paramount. As this approach gains adoption, we can expect to see a rapid acceleration in display innovation, pushing the boundaries of what's possible with flexible, foldable, and transparent screens. For investors, this patent represents a foundational technology that could yield significant returns as the display market continues its evolution towards ultra-high performance and novel form factors. Early adopters and licensees of this technology stand to gain a considerable advantage in shaping the future of visual computing.","technical_analysis":"The patent \"Thin Film Transistor Substrate and Method of Manufacturing the Same\" (US-9853060) details a sophisticated architecture and fabrication methodology for Thin Film Transistor (TFT) substrates, focusing on mitigating signal integrity issues common in high-density displays. The core technical contribution lies in its multi-layered design, particularly the strategic integration of a shielding electrode and an inorganic insulating pattern.\n\n**Technical Architecture:**\nThe system begins with a base substrate, typically glass or flexible polymer, which defines a plurality of pixel areas. On this base, a gate line extends in a first direction, and a data line extends in a second, orthogonal direction. A Thin Film Transistor (TFT) is situated at the intersection, electrically connecting the gate line and the data line. The TFT itself comprises: \n1.  **Gate Electrode:** A conductive layer that controls the channel.\n2.  **Semiconductor Pattern:** An active layer (e.g., amorphous silicon, LTPS, IGZO) that overlaps the gate electrode, forming the transistor channel.\n3.  **Source and Drain Electrodes:** Conductive layers that overlap the semiconductor pattern, with the drain electrode being spaced apart from the source electrode to define the channel length.\n\nAbove these foundational TFT layers, the patent introduces two critical elements:\n4.  **Inorganic Insulating Pattern:** This layer covers the data line and is made of materials like silicon nitride (SiNx) or silicon oxide (SiOx), known for their excellent dielectric properties and mechanical robustness. Crucially, this pattern includes an opening precisely aligned with the pixel areas, facilitating subsequent connections.\n5.  **Shielding Electrode:** This conductive layer is deposited on the inorganic insulating pattern and is specifically designed to overlap the data line. Its primary function is to act as an electrostatic shield, significantly reducing the parasitic capacitance that forms between the data line and the adjacent pixel electrode. This parasitic capacitance is a major source of crosstalk and signal delay in high-resolution displays, leading to image degradation.\n\nFinally, a pixel electrode is formed on the pixel areas, completing the circuit. This pixel electrode is electrically connected to the drain electrode through a first contact hole, which passes through the insulating layers to establish contact.\n\n**Implementation Details and Performance Characteristics:**\nThe strategic placement of the shielding electrode directly over the data line is a key technical breakthrough. In conventional designs, the close proximity of data lines and pixel electrodes can lead to significant signal coupling, distorting the voltage applied to the pixel and causing visual artifacts. By introducing an electrically isolated shielding electrode in between, the invention effectively shunts this capacitive coupling, ensuring that the pixel electrode receives a cleaner, more stable signal. This improves the charging speed of the pixel and reduces signal propagation delay, which is vital for high refresh rates.\n\nThe use of an inorganic insulating pattern provides superior barrier properties against moisture and oxygen compared to organic alternatives, enhancing the long-term reliability and stability of the display. Its precise opening ensures optimal aperture ratio, contributing to brighter and more energy-efficient displays.\n\n**Integration Patterns and Code-Level Implications (Conceptual):**\nWhile this patent is hardware-centric, its implications for display driver ICs and system-on-chip (SoC) integration are significant. With reduced crosstalk at the substrate level, display driver ICs can be simplified, potentially requiring less complex compensation algorithms or lower driving voltages. This could translate to reduced power consumption and simpler software control for display timing and image processing. The enhanced signal integrity at the pixel level means that image processing algorithms can focus more on actual content enhancement rather than artifact correction. The robust nature of the substrate also benefits system integration in devices requiring high mechanical durability, such as automotive or flexible displays.\n\n**Performance Characteristics:** The architecture is expected to yield displays with:\n*   **Reduced Crosstalk:** Significantly cleaner pixel signals.\n*   **Higher Refresh Rates:** Faster pixel charging enables quicker image updates.\n*   **Improved Image Quality:** Sharper images, better color accuracy due to reduced signal distortion.\n*   **Enhanced Reliability:** Robust inorganic layers and stable electrical performance.\n*   **Potentially Higher Aperture Ratio:** More light throughput for brighter, more efficient displays.","business_analysis":"The patent \"Thin Film Transistor Substrate and Method of Manufacturing the Same\" (US-9853060) represents a substantial business opportunity within the global display market, a sector characterized by rapid innovation and intense competition. This invention addresses fundamental limitations in current Thin Film Transistor (TFT) substrate manufacturing, positioning it as a critical enabler for next-generation display technologies.\n\n**Market Opportunity Size:** The global display market is massive and continually expanding, driven by demand for advanced smartphones, tablets, televisions, wearables, automotive displays, and augmented/virtual reality devices. As consumers and industries demand higher resolutions (4K, 8K, and beyond), faster refresh rates, and more flexible form factors, the underlying TFT substrate technology becomes a bottleneck. This patent directly tackles these challenges, opening up significant market share in the premium and high-performance display segments. The ability to produce superior TFT substrates more efficiently could tap into a multi-billion dollar market segment that demands high fidelity and reliability.\n\n**Competitive Advantages:** This technology offers several compelling competitive advantages:\n1.  **Superior Image Quality:** By significantly reducing parasitic capacitance and crosstalk through the innovative shielding electrode, displays built with this substrate will offer visibly clearer, sharper images with better color accuracy, providing a distinct product differentiation.\n2.  **Enhanced Performance:** The improved signal integrity enables higher refresh rates and faster response times, crucial for gaming, VR/AR, and professional applications.\n3.  **Manufacturing Efficiency:** The optimized layering and method of manufacturing promise reduced complexity, higher yields, and potentially lower production costs per unit compared to existing technologies that require more complex external compensation or multiple processing steps to mitigate similar issues.\n4.  **Increased Reliability:** The use of robust inorganic insulating patterns contributes to longer-lasting and more durable displays, reducing warranty claims and improving brand reputation.\n\n**Revenue Potential and Business Models:** Companies that adopt or license this technology can expect increased revenue through the sale of premium display panels or devices incorporating them. Potential business models include:\n*   **Direct Manufacturing:** Display panel manufacturers can integrate this method into their fabrication lines to produce superior TFT substrates in-house.\n*   **Licensing:** Patent holders can license the technology to multiple display manufacturers, generating substantial royalty income.\n*   **Component Sales:** Specialized component suppliers could manufacture and sell these advanced TFT substrates to panel integrators.\n\n**Strategic Positioning:** This innovation allows companies to strategically position themselves as leaders in high-performance and advanced display technologies. It provides a foundational technology that can be leveraged across a wide array of products, from consumer electronics to specialized industrial and medical displays. For instance, a company could brand its displays as \"Crosstalk-Free\" or \"Ultra-Clarity\" powered by this patented technology, creating a strong market identity.\n\n**ROI Projections:** While specific ROI depends on implementation scale and market adoption, the benefits of higher yields, reduced defect rates, and premium product positioning suggest a strong return on investment. Reduced material waste and energy consumption during manufacturing, coupled with the ability to command higher prices for superior products, will drive profitability. Furthermore, securing a technological lead in a fiercely competitive market offers long-term strategic value beyond immediate financial returns, fostering brand loyalty and market dominance.","faqs":[{"answer":"The Thin Film Transistor Substrate and Method of Manufacturing the Same (US-9853060) is a patent describing an innovative design and fabrication process for the core component of modern flat-panel displays: the Thin Film Transistor (TFT) substrate. This invention introduces a novel layered structure that significantly enhances display performance, particularly by improving signal integrity and reducing electrical interference.\n\nAt its heart, this patent details a TFT substrate that includes a base, gate and data lines, and the TFTs themselves. The key differentiator is the strategic integration of an inorganic insulating pattern and a shielding electrode. This shielding electrode is placed directly over the data lines, acting as an electrostatic barrier to prevent unwanted signal coupling.\n\nThe method of manufacturing outlined in the patent describes the precise steps for depositing and patterning these layers. The goal is to create a more robust, higher-performing, and potentially more efficiently produced TFT substrate. This technology is foundational for improving the visual quality and reliability of a wide range of electronic screens.\n\nUltimately, this patent represents a significant leap in display backplane technology, addressing long-standing challenges in the industry. It lays the groundwork for next-generation displays with superior clarity and responsiveness. Keywords: Thin Film Transistor Substrate, TFT, display technology, patent US-9853060, display innovation.","question":"What is Thin Film Transistor Substrate and Method of Manufacturing the Same?"},{"answer":"The Thin Film Transistor Substrate and Method of Manufacturing the Same works by intelligently redesigning the internal architecture of a display's backplane to manage electrical signals more effectively. In conventional displays, the close proximity of data lines (which carry image information) and pixel electrodes can lead to parasitic capacitance, causing signals to interfere with each other, a phenomenon known as crosstalk.\n\nThis patent introduces a crucial innovation: a shielding electrode. This conductive layer is strategically placed on an inorganic insulating pattern, directly above and overlapping the data line. This shielding electrode acts as an electrostatic barrier, effectively intercepting and shunting away stray electrical fields from the data line. By doing so, it prevents these fields from coupling with the adjacent pixel electrode.\n\nAs a result, each pixel receives a cleaner, more accurate electrical signal, free from interference. This precise signal control translates directly into superior image quality, reduced visual artifacts, and faster pixel response times. The inorganic insulating pattern further contributes by providing robust electrical isolation and mechanical stability to the overall structure. Keywords: Thin Film Transistor Substrate, how it works, shielding electrode, parasitic capacitance, crosstalk, signal integrity, display architecture.","question":"How does Thin Film Transistor Substrate and Method of Manufacturing the Same work?"},{"answer":"The Thin Film Transistor Substrate and Method of Manufacturing the Same patent primarily solves the critical problem of signal interference, specifically parasitic capacitance and crosstalk, within high-resolution flat-panel displays. As display technology advances towards higher pixel densities (e.g., 4K, 8K) and faster refresh rates, the data lines and pixel electrodes become packed more closely together.\n\nThis close proximity exacerbates the problem of electrical signals 'bleeding' from data lines into neighboring pixel electrodes, distorting the intended voltage and leading to various visual artifacts. These artifacts can include ghosting, smearing, reduced contrast, and inaccurate color representation. Such issues compromise the overall image quality and user experience, especially in demanding applications like gaming, virtual reality, and professional content creation.\n\nFurthermore, this signal interference complicates the manufacturing process, often requiring complex and costly compensation circuits in display driver ICs or trade-offs in display design (e.g., wider line spacing reducing brightness). By providing an integrated solution at the substrate level, the Thin Film Transistor Substrate and Method of Manufacturing the Same effectively mitigates these fundamental problems, enabling the production of displays with superior visual fidelity and improved manufacturing efficiency. Keywords: Thin Film Transistor Substrate, display problems, crosstalk, parasitic capacitance, high-resolution displays, signal interference, manufacturing challenges.","question":"What problem does Thin Film Transistor Substrate and Method of Manufacturing the Same solve?"},{"answer":"The patent for Thin Film Transistor Substrate and Method of Manufacturing the Same (US-9853060) does not list specific inventors or an assignee in the provided abstract data. Patents are typically filed by companies or individual inventors.\n\nHowever, the nature of such a sophisticated display technology patent suggests that it likely originated from a major electronics manufacturer or a specialized display R&D firm. These entities often invest heavily in research and development to push the boundaries of display performance and manufacturing.\n\nTo find the specific inventors and the assignee, one would typically refer to the full patent document available through official patent databases. This information is crucial for understanding the intellectual property landscape and the entities driving innovation in this field. Keywords: Thin Film Transistor Substrate, inventors, assignee, patent ownership, display R&D, patent US-9853060.","question":"Who invented Thin Film Transistor Substrate and Method of Manufacturing the Same?"},{"answer":"The Thin Film Transistor Substrate and Method of Manufacturing the Same offers several significant benefits that can revolutionize display technology:\n\n1.  **Superior Image Quality:** By drastically reducing crosstalk and parasitic capacitance, this invention ensures cleaner, more accurate pixel signals. This translates to sharper images, higher contrast, more vibrant colors, and the elimination of visual artifacts like ghosting or blurring.\n2.  **Enhanced Performance:** The improved signal integrity allows for faster pixel charging and discharging, which is critical for achieving higher refresh rates. This results in smoother motion, making it ideal for gaming, virtual reality, and fast-paced video content.\n3.  **Manufacturing Efficiency:** The integrated design of the shielding electrode and inorganic insulation can streamline the fabrication process. By solving signal integrity issues at the substrate level, it may reduce the need for complex, costly external compensation circuits or multiple manufacturing steps, potentially leading to higher yields and lower production costs.\n4.  **Increased Reliability and Durability:** The use of robust inorganic insulating materials provides excellent protection against environmental factors like moisture and oxygen. This enhances the long-term stability and lifespan of the display panel, reducing potential defects and warranty issues.\n\nThese benefits collectively position displays utilizing this Thin Film Transistor Substrate and Method of Manufacturing the Same for a significant competitive advantage in the market. Keywords: Thin Film Transistor Substrate benefits, display quality, high refresh rate, manufacturing efficiency, display reliability, patent advantages.","question":"What are the key benefits of Thin Film Transistor Substrate and Method of Manufacturing the Same?"},{"answer":"The Thin Film Transistor Substrate and Method of Manufacturing the Same distinguishes itself from prior art by offering a more integrated and effective solution to signal integrity issues in TFT displays. Prior art typically addresses crosstalk and parasitic capacitance through methods that often involve trade-offs or add complexity.\n\nFor instance, some prior art solutions attempt to mitigate crosstalk by increasing the spacing between data lines. However, this reduces the aperture ratio, making displays dimmer or requiring more power. Other methods rely on complex compensation algorithms implemented in display driver ICs, which add cost, power consumption, and processing delay. Some also use additional ground planes, which add manufacturing steps and material complexity.\n\nThis invention, however, integrates a dedicated shielding electrode directly over the data line, separated by an inorganic insulating pattern. This creates an internal electrostatic barrier that actively shunts parasitic fields, a more direct and efficient approach than simply widening lines or relying solely on external software. This fundamental architectural change provides superior signal isolation without compromising aperture ratio or adding undue complexity to driver electronics, making the Thin Film Transistor Substrate and Method of Manufacturing the Same a more holistic and scalable solution. Keywords: Thin Film Transistor Substrate, prior art, differentiation, shielding electrode, crosstalk mitigation, display innovation, architectural difference.","question":"How is Thin Film Transistor Substrate and Method of Manufacturing the Same different from prior art?"},{"answer":"The Thin Film Transistor Substrate and Method of Manufacturing the Same patent has the potential to significantly impact a wide array of industries that rely heavily on high-performance display technology. Its core benefits in image clarity, responsiveness, and manufacturing efficiency make it versatile.\n\n**Consumer Electronics:** This is arguably the largest immediate impact area, including smartphones, tablets, laptops, and televisions. The invention will enable even sharper 8K+ displays, more vibrant colors, and smoother motion in gaming monitors and premium devices. It could elevate the user experience across the board.\n\n**Virtual and Augmented Reality (VR/AR):** For immersive XR headsets, pixel density and lack of artifacts are paramount. This technology can deliver the pristine visuals required for truly believable and comfortable virtual environments.\n\n**Automotive Displays:** Modern vehicles feature increasingly sophisticated infotainment systems, digital dashboards, and heads-up displays. The robustness of the inorganic insulation and the enhanced signal integrity make this ideal for the demanding and often high-temperature environment of automotive applications.\n\n**Medical Imaging:** In medical devices, where precise visual information is critical for diagnosis and procedures, displays built with this technology can offer unparalleled clarity and reliability.\n\n**Industrial and Professional Monitors:** For applications requiring extreme accuracy, such as design, engineering, and content creation, the improved image quality and color fidelity will be highly beneficial. Keywords: Thin Film Transistor Substrate, industry impact, consumer electronics, VR/AR, automotive displays, medical imaging, professional monitors, display technology applications.","question":"What industries will Thin Film Transistor Substrate and Method of Manufacturing the Same impact?"},{"answer":"The patent for Thin Film Transistor Substrate and Method of Manufacturing the Same, identified as US-9853060, has specific dates associated with its filing and publication.\n\nThe **Filing Date** for this patent was **2015-05-08**. This is the date when the patent application was officially submitted to the patent office, initiating the examination process.\n\nThe **Publication Date** for this patent was **2017-12-26**. This is the date when the patent was officially published, signifying its grant and making its details publicly accessible. The period between the filing and publication dates is typically used for examination by patent examiners, where the novelty, non-obviousness, and utility of the invention are assessed against prior art.\n\nThese dates are important for intellectual property tracking, understanding the timeline of innovation, and assessing the patent's validity period. The grant of the patent on the publication date indicates that the patent office recognized the unique and protectable aspects of the Thin Film Transistor Substrate and Method of Manufacturing the Same. Keywords: Thin Film Transistor Substrate, patent filing date, patent publication date, US-9853060, patent timeline, intellectual property.","question":"When was Thin Film Transistor Substrate and Method of Manufacturing the Same filed/granted?"},{"answer":"The commercial applications of the Thin Film Transistor Substrate and Method of Manufacturing the Same are extensive, primarily centered around any product requiring a high-performance, reliable, and visually superior flat-panel display. Its core benefits translate directly into market advantages for a wide range of electronic devices.\n\n**High-End Consumer Electronics:** This includes premium smartphones, tablets, laptops, and especially 4K/8K Ultra HD televisions and gaming monitors. The ability to deliver crosstalk-free, high-refresh-rate visuals will be a major selling point for consumers seeking the best possible viewing experience.\n\n**Augmented and Virtual Reality Devices:** For AR/VR headsets, the display is the window to immersion. This technology can provide the necessary pixel density, clarity, and low latency to create more believable and comfortable virtual worlds, driving the next generation of these devices.\n\n**Automotive Industry:** With the rise of smart cars, advanced digital dashboards, infotainment systems, and heads-up displays are becoming standard. The robustness and enhanced visual quality offered by this Thin Film Transistor Substrate and Method of Manufacturing the Same are ideal for the demanding operating conditions and safety requirements of vehicles.\n\n**Professional and Industrial Equipment:** This extends to medical monitors for diagnostics, industrial control panels, and professional graphics workstations where color accuracy and image precision are paramount. The reliability also benefits long-life industrial applications.\n\nOverall, any product where display quality, performance, and reliability are critical differentiators stands to benefit from integrating this innovative Thin Film Transistor Substrate and Method of Manufacturing the Same. Keywords: Thin Film Transistor Substrate, commercial applications, consumer electronics, VR/AR, automotive displays, professional monitors, display market, product innovation.","question":"What are the commercial applications of Thin Film Transistor Substrate and Method of Manufacturing the Same?"},{"answer":"The Thin Film Transistor Substrate and Method of Manufacturing the Same patent lays a robust foundation for numerous future developments in display technology. Its core innovation in signal integrity and manufacturing efficiency opens doors for continued advancements.\n\nOne key area of future development will likely be its integration with **emerging display technologies** like micro-LEDs and advanced OLEDs. The clean signal delivery provided by this patent is crucial for these technologies to achieve their full potential in terms of brightness, contrast, and pixel density. Optimizing the shielding electrode and inorganic insulating pattern for these specific material systems will be an ongoing focus.\n\nAnother significant direction is the application to **flexible, foldable, and transparent displays**. The robust nature of the inorganic insulation and the inherent stability of the shielded backplane make it highly suitable for displays that undergo mechanical stress. Future work will involve adapting the manufacturing process and material choices to ensure consistent performance under bending, folding, or transparency requirements.\n\nFurthermore, research may explore **dynamic shielding techniques** or even more advanced materials for the shielding electrode and insulating layers to further minimize parasitic effects and optimize power consumption. As display demands continue to escalate, the principles introduced by the Thin Film Transistor Substrate and Method of Manufacturing the Same will undoubtedly serve as a crucial platform for innovation in display backplane design for years to come. Keywords: Thin Film Transistor Substrate, future developments, micro-LED, OLED, flexible displays, transparent displays, display roadmap, advanced materials, display innovation.","question":"What are the future developments expected for Thin Film Transistor Substrate and Method of Manufacturing the Same?"}],"topics":["Thin Film Transistor Substrate and Method of Manufacturing the Same","TFT substrate","display technology","patent US-9853060","crosstalk reduction","technical","transistor","substrate"],"tech_cluster":null},"seo":{"title":"TFT Substrate & Method - Thin Film Transistor Substrate and Method of Manufacturing the Same - US-9853060","description":"Discover the groundbreaking Thin Film Transistor Substrate and Method of Manufacturing the Same patent (US-9853060). Revolutionizing display tech with reduced crosstalk & enhanced clarity.","keywords":["Thin Film Transistor Substrate and Method of Manufacturing the Same","TFT substrate","display technology","patent US-9853060","crosstalk reduction","shielding electrode","inorganic insulating pattern","high-resolution displays","display manufacturing","semiconductor pattern","pixel electrode","display innovation","next-gen screens","display backplane","flat panel displays"]},"attribution":{"source":"Patentable","source_url":"https://patentable.app","canonical_url":"https://patentable.app/patents/US-9853060","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-9853060","citation_suggestion":"Patentable. \"Thin film transistor substrate and method of manufacturing the same\" (US-9853060). https://patentable.app/patents/US-9853060","copyright_holder":"Nomic Interactive Technology LLC"},"links":{"html":"https://patentable.app/patents/US-9853060","json":"https://patentable.app/api/llm-context/US-9853060","site":"https://patentable.app","llms_txt":"https://patentable.app/llms.txt"},"generated_at":"2026-06-06T09:33:16.775Z"}