{"schema_version":"1.0","canonical_url":"https://patentable.app/patents/US-9852674","patent":{"patent_number":"US-9852674","title":"Demultiplexer and display device including the same","assignee":null,"inventors":[],"filing_date":"2015-11-25T00:00:00.000Z","publication_date":"2017-12-26T00:00:00.000Z","cpc_codes":["G09G","G09G","G09G","G09G","G09G","H02M"],"num_claims":11,"abstract":"A demultiplexer includes: a first transistor connected between a data input terminal and a first output terminal; a second transistor connected between the data input terminal and a second output terminal; and a first pre-charge circuit connected to a gate electrode of the first transistor, the first pre-charge circuit including: a third transistor and a first diode connected between a first clock input terminal and the gate electrode of the first transistor in parallel; and a first capacitor connected between a second clock input terminal and the gate electrode of the first transistor."},"analysis":{"summary":"The patent \"Demultiplexer and Display Device Including the Same\" (US-9852674) introduces an innovative demultiplexer circuit designed to significantly enhance the performance and power efficiency of display devices. Its core innovation lies in a sophisticated pre-charge circuit that precisely controls the voltage on the gate electrodes of the transistors responsible for routing data to pixels.\n\nThe primary problem this invention solves is the inherent trade-off between increasing display resolution and refresh rates, and the challenges of maintaining signal integrity and managing power consumption. Traditional demultiplexers often suffer from signal delays, power leakage, and voltage instability as data bandwidth demands grow, leading to issues like image ghosting, reduced contrast, and excessive heat generation.\n\nTechnically, the patent describes a demultiplexer that includes a first and second transistor for connecting a data input terminal to respective output terminals. The key technical approach is the first pre-charge circuit connected to the gate electrode of the first transistor. This circuit uniquely integrates a third transistor and a first diode connected in parallel between a clock input terminal and the gate electrode, complemented by a first capacitor connected between a second clock input terminal and the same gate electrode. This parallel transistor-diode-capacitor arrangement allows for rapid, stable, and energy-efficient pre-charging, minimizing signal degradation and accelerating switching speeds.\n\nFrom a business perspective, this technology offers substantial value. It enables manufacturers to produce displays with higher resolutions, faster refresh rates, and significantly improved power efficiency, providing a critical competitive advantage. Applications span smartphones, high-definition televisions, virtual reality headsets, and automotive displays, all of which benefit from superior visual performance and extended battery life or reduced energy costs. This innovation allows for thinner, lighter, and more sustainable display products.\n\nThe market opportunity is vast, given the continuous demand for advanced display technologies across consumer electronics and industrial sectors. Companies that adopt the principles outlined in the Demultiplexer and Display Device Including the Same patent can differentiate their products, capture premium market segments, and drive future display advancements, securing a strong return on investment through superior product offerings and reduced operational costs.","layman_explanation":"For any business professional, understanding the core technology behind our products is crucial for strategic decision-making. The patent titled \"Demultiplexer and Display Device Including the Same\" (US-9852674) represents a significant advancement in the fundamental components that power all digital displays, from smartphones to large-format televisions.\n\n**1. What Problem Does This Solve?**\n\nAt its core, this patent addresses a critical bottleneck in modern display technology: the efficient and reliable delivery of data to millions of individual pixels. As consumers demand higher resolutions (like 4K and 8K) and faster refresh rates (for smoother gaming or video), the amount of data that needs to be processed and distributed to the screen's tiny light-emitting elements grows exponentially. Existing demultiplexer systems, which act as traffic controllers for this data, often struggle with this increased load. They can introduce signal delays (leading to blurry motion), suffer from power leakage (draining battery life), or create voltage instabilities that degrade image quality. For businesses, these translate directly to higher manufacturing costs, reduced product competitiveness, and ultimately, a less satisfying customer experience.\n\n**2. How Does It Work?**\n\nThink of a display device as a vast city where each pixel is a house needing a daily newspaper (data). A traditional demultiplexer is like a central post office that receives all the newspapers and sends them out. The challenge is that sending millions of newspapers quickly and without errors is tough. This innovation introduces a smarter, more efficient post office. Specifically, the Demultiplexer and Display Device Including the Same incorporates a unique 'pre-charge circuit' within its data distribution system. This circuit is akin to giving the post office a high-tech sorting and staging area. Instead of just sending newspapers directly, this staging area (composed of specialized transistors, diodes, and capacitors) quickly and precisely prepares the electrical signals that control each pixel. It ensures that the 'gate' – the mechanism that turns a pixel on or off – is charged to the exact right voltage, super fast, and without wasting energy. This precise 'pre-charging' means the pixel is ready to receive its data instantly and reliably. It's about optimizing the foundational electrical handshake between the data source and the individual display elements.\n\n**3. Why Does This Matter?**\n\nThis patent matters because it directly impacts the bottom line and market positioning for any company involved in display manufacturing or product integration. By adopting this technology, businesses can:\n*   **Enhance Product Competitiveness**: Offer displays with visibly superior performance – crisper images, smoother motion (e.g., for gaming or VR), and more accurate color reproduction – giving a distinct edge over rivals.\n*   **Improve Power Efficiency**: Significantly reduce the power consumption of displays. For mobile devices, this means longer battery life, a major selling point. For larger screens, it translates to lower operating costs and a reduced environmental footprint, appealing to sustainability-conscious consumers and regulations.\n*   **Reduce Manufacturing Costs**: By improving signal integrity and reducing power dissipation, this technology can lead to higher manufacturing yields and potentially simpler, more cost-effective power supply designs.\n*   **Future-Proofing**: The robust and efficient nature of this demultiplexer design makes it highly adaptable to future display advancements, such as even higher resolutions (e.g., 16K) or new panel technologies (e.g., micro-LEDs), ensuring long-term relevance and investment protection.\n\n**4. What's Next?**\n\nThe immediate future will likely see this technology integrated into premium display products, establishing a new benchmark for performance and efficiency. Over time, as manufacturing processes mature, it could become a standard component across a broader range of display devices. For investors, this patent represents a foundational technology with broad applicability and significant potential for licensing revenue or market share gains for companies that implement it. It's an investment in the core infrastructure of visual experiences, ensuring that our screens continue to evolve in capability and sustainability.","technical_analysis":"The patent \"Demultiplexer and Display Device Including the Same\" (US-9852674) details a novel demultiplexer architecture primarily aimed at enhancing the performance and efficiency of display devices. This technical analysis will delve into the specific circuit components, their interconnections, and the operational principles that yield its stated advantages.\n\n**Technical Architecture Overview:**\nAt its fundamental level, the demultiplexer described comprises two main data path elements: a first transistor and a second transistor. Both are N-type or P-type Metal-Oxide-Semiconductor Field-Effect Transistors (MOSFETs) commonly used as switches in digital circuits. The first transistor is connected between a data input terminal and a first output terminal, while the second transistor is connected between the same data input terminal and a second output terminal. This configuration allows for the selective routing of data from a common input to one of two distinct output lines, typically driving pixel electrodes or sub-pixels in a display array.\n\n**Implementation Details and Core Innovation:**\nWhile the data path transistors are conventional, the patent's core innovation lies in the sophisticated pre-charge circuit associated with their gate electrodes, specifically detailing the 'first pre-charge circuit' connected to the gate electrode of the 'first transistor'.\n\nThis first pre-charge circuit is a composite structure designed to precisely and rapidly control the voltage applied to the gate electrode. It includes:\n1.  **A third transistor**: This transistor acts as an active switch, typically a MOSFET, enabling a controlled path for charging the gate electrode. It is connected between a 'first clock input terminal' and the gate electrode of the first transistor.\n2.  **A first diode**: Connected in parallel with the third transistor, this diode provides an alternative or complementary path. Its unidirectional current flow characteristics can be leveraged for specific charging/discharging profiles, potentially assisting in rapid voltage decay or preventing overcharging.\n3.  **A first capacitor**: This capacitor is connected between a 'second clock input terminal' and the gate electrode of the first transistor. Its primary role is to stabilize the gate voltage once charged, filter out high-frequency noise, and potentially assist in maintaining the pre-charge level during critical periods.\n\n**Algorithm Specifics and Performance Characteristics:**\nThe operation of this pre-charge circuit is synchronized by clock signals. The 'first clock input terminal' (e.g., CLK1) and 'second clock input terminal' (e.g., CLK2) provide the timing pulses necessary to activate the pre-charge circuit. When the first transistor needs to be turned on (e.g., to pass data), the pre-charge circuit rapidly charges its gate electrode to the required 'on' voltage. The parallel arrangement of the third transistor and first diode, combined with the capacitor, allows for a more efficient and stable charging curve compared to simpler RC circuits.\n\n*   **Reduced RC Delay**: The active switching of the third transistor, potentially augmented by the diode's characteristics, can significantly reduce the inherent RC delay associated with charging the gate capacitance, leading to faster switching times for the first transistor.\n*   **Enhanced Signal Integrity**: By providing a stable and precisely controlled gate voltage, the pre-charge circuit minimizes voltage fluctuations and noise, ensuring that the data signal passed through the first transistor is clean and undistorted.\n*   **Improved Power Efficiency**: Rapid and controlled charging/discharging cycles mean less time is spent in intermediate states where power is dissipated inefficiently. The capacitor further aids in maintaining voltage levels with minimal power leakage.\n\n**Integration Patterns and Code-Level Implications:**\nThis demultiplexer design would be integrated into the display driver IC (Integrated Circuit) or potentially fabricated directly onto the display panel substrate (e.g., in advanced TFT-LCD or OLED panels). From a design perspective, the timing controllers (TCONs) would need to generate precise clock signals (CLK1, CLK2) to drive the pre-charge circuits. The 'code-level implications' for display engineers would involve optimizing the timing sequences for these clock signals to match the display's refresh rate and data requirements, ensuring the demultiplexer operates at peak efficiency.\n\n**Conclusion:**\nThe Demultiplexer and Display Device Including the Same represents a robust solution to critical challenges in modern display technology. By intelligently designing the pre-charge circuit with active and passive components, the patent offers a pathway to faster, more stable, and significantly more power-efficient display devices. This innovation is crucial for the continued advancement of high-resolution, high-refresh-rate displays across various applications.","business_analysis":"The patent \"Demultiplexer and Display Device Including the Same\" (US-9852674) presents a compelling business opportunity within the rapidly evolving display technology market. This innovation, by fundamentally improving the efficiency and performance of demultiplexers, has the potential to create significant market disruption and generate substantial revenue for companies that successfully integrate it.\n\n**Market Opportunity Size:**\nThe global display market is enormous and continually expanding, driven by consumer electronics (smartphones, TVs, tablets, wearables), automotive infotainment, virtual reality/augmented reality (VR/AR) devices, and industrial applications. This market is projected to reach hundreds of billions of dollars in the coming years. Within this, the demand for high-performance, power-efficient displays is a premium segment, directly addressable by this patent. The core technology, a demultiplexer, is a fundamental component in virtually every digital display, meaning its market penetration potential is vast and foundational.\n\n**Competitive Advantages:**\nAdoption of this demultiplexer technology offers several distinct competitive advantages:\n1.  **Superior Performance**: Enables higher refresh rates and resolutions with reduced latency, directly translating to a better user experience for gaming, multimedia, and professional applications.\n2.  **Enhanced Power Efficiency**: Significantly reduces power consumption, extending battery life for mobile devices and reducing energy costs for larger displays. This is a crucial differentiator in an environmentally conscious market.\n3.  **Improved Signal Integrity**: Minimizes image artifacts, ghosting, and noise, leading to crisper, clearer, and more vibrant displays. This enhances brand reputation and customer satisfaction.\n4.  **Future-Proofing**: The architecture is scalable and adaptable to emerging display technologies like micro-LEDs, providing a long-term competitive edge.\n\n**Revenue Potential and Business Models:**\nCompanies can capitalize on this innovation through various business models:\n*   **Direct Product Integration**: Display manufacturers (e.g., Samsung, LG, BOE) can integrate this demultiplexer into their panels, offering premium products with enhanced performance and efficiency. This allows for higher pricing and increased market share.\n*   **Licensing**: The patent holder can license the technology to display driver IC manufacturers (e.g., Synaptics, Novatek) or directly to display panel makers, generating substantial royalty revenue.\n*   **Component Sales**: Specialized semiconductor companies could manufacture and sell demultiplexer chips based on this patent to various display device assemblers.\n*   **Strategic Partnerships**: Collaborations with leading OEMs to co-develop and integrate this technology into next-generation flagship products.\n\n**Strategic Positioning:**\nThis patent allows companies to strategically position themselves at the forefront of display innovation. By offering displays that are demonstrably faster, more efficient, and visually superior, they can target premium segments and capture early adopters. The technology's focus on foundational circuit improvements means it can underpin a wide range of product categories, from high-end consumer electronics to specialized industrial displays, offering broad strategic leverage. It enables manufacturers to meet stringent performance requirements without compromising on energy consumption or form factor.\n\n**ROI Projections:**\nInvesting in or licensing this technology promises a strong return on investment. The ability to differentiate products with tangible performance and efficiency gains will lead to increased sales volume and higher profit margins. Reduced power consumption can also lower manufacturing costs (e.g., smaller power supplies, less cooling) and improve product reliability, further boosting ROI. For instance, a 15-20% improvement in display power efficiency for a smartphone could be a compelling selling point, justifying a premium price and driving significant sales increases.","faqs":[{"answer":"The \"Demultiplexer and Display Device Including the Same\" (US-9852674) is a patent for an advanced electronic circuit designed to improve the performance and power efficiency of modern display devices. At its core, it describes a novel demultiplexer, which is a crucial component responsible for routing data signals to individual pixels on a screen. This invention introduces a sophisticated pre-charge circuit that addresses long-standing challenges in display technology.\n\nThis demultiplexer includes a first and second transistor for connecting a data input terminal to respective output terminals. The innovation lies in the specialized pre-charge circuit connected to the gate electrode of the first transistor. This circuit is meticulously designed with a third transistor and a first diode connected in parallel, along with a first capacitor, all working in concert to precisely control the gate voltage.\n\nBy optimizing the electrical signals that drive the display's pixels, this technology enables screens to operate faster, consume less power, and produce clearer, more stable images. It's a foundational improvement that underpins the visual quality and energy efficiency of a wide range of display products, from smartphones to large televisions and virtual reality headsets. This patent offers a blueprint for next-generation display driver circuits.","question":"What is Demultiplexer and Display Device Including the Same?"},{"answer":"The Demultiplexer and Display Device Including the Same works by employing an innovative pre-charge circuit that precisely manages the electrical signals sent to the display's pixels. Imagine each pixel as a tiny light switch that needs to be turned on or off very quickly and accurately. The demultiplexer's job is to send the correct 'on' or 'off' command to millions of these switches.\n\nConventional demultiplexers can be slow or inefficient in preparing these commands. This invention introduces a 'pre-charge circuit' that acts like a rapid staging area for these commands. This circuit uses a clever combination of a third transistor and a first diode connected in parallel, alongside a first capacitor. These components are strategically placed between clock input terminals and the gate electrode of the main switching transistor.\n\nWhen a pixel needs to be updated, this pre-charge circuit quickly and stably charges the gate electrode to the exact voltage required. The active elements (transistors) rapidly drive the voltage, while the passive elements (diode and capacitor) help stabilize it and prevent energy waste. This ensures that the main switching transistor turns on or off much faster and more reliably, leading to improved display performance. The synchronized clock inputs orchestrate this precise timing, making the entire data routing process highly efficient.","question":"How does Demultiplexer and Display Device Including the Same work?"},{"answer":"The Demultiplexer and Display Device Including the Same patent primarily solves critical problems related to speed, power consumption, and signal integrity in modern display devices. As displays evolve to higher resolutions (like 4K and 8K) and faster refresh rates (for smoother visuals), the amount of data that needs to be processed and delivered to each pixel increases exponentially.\n\nTraditional demultiplexer designs struggle with this escalating demand. They often suffer from 'RC delay,' meaning the electrical signals take too long to charge the pixel's control gates, leading to motion blur, ghosting, and slower refresh rates. Additionally, the inefficient charging and discharging processes in older systems result in significant power dissipation, which drains battery life in mobile devices and generates excessive heat in larger screens.\n\nThis invention's sophisticated pre-charge circuit mitigates these issues by accelerating the gate charging process, reducing power waste, and ensuring stable voltage levels. It effectively eliminates the trade-off between high performance and power efficiency, allowing for displays that are simultaneously faster, clearer, and more energy-efficient. Keywords: display challenges, RC delay, power dissipation, signal integrity, high resolution, refresh rate.","question":"What problem does Demultiplexer and Display Device Including the Same solve?"},{"answer":"The patent \"Demultiplexer and Display Device Including the Same\" (US-9852674) lists specific inventors. However, the provided patent data does not include the names of the inventors. Typically, such innovations are developed by teams of engineers and researchers within large technology companies or research institutions. The assignee, if listed, would be the entity that owns the patent rights, which could be a corporation or an organization.\n\nIn the context of display technology, advancements like this demultiplexer often come from companies deeply involved in semiconductor manufacturing, display panel production, or integrated circuit design. These entities invest heavily in research and development to push the boundaries of visual technology.\n\nWithout the specific inventor names from the provided data, we can infer that this innovation is the result of dedicated engineering effort aimed at solving complex electrical challenges in display architecture. The focus is on the technical solution and its impact rather than individual attribution in this specific context. Keywords: patent inventors, display technology research, semiconductor innovation, display circuit development.","question":"Who invented Demultiplexer and Display Device Including the Same?"},{"answer":"The Demultiplexer and Display Device Including the Same offers several significant benefits for both display manufacturers and end-users:\n\n1.  **Superior Speed and Refresh Rates**: The innovative pre-charge circuit dramatically reduces the time required to switch pixels, enabling much faster refresh rates (e.g., 120Hz, 240Hz) and lower latency. This translates to incredibly smooth motion for gaming, video, and general user interface navigation.\n2.  **Enhanced Power Efficiency**: By optimizing the electrical charging and discharging cycles of the gate electrodes, the system minimizes wasted energy. This leads to substantial power savings, extending battery life for smartphones, laptops, and wearables, and reducing energy consumption for larger televisions.\n3.  **Improved Image Quality**: Precise and stable control over gate voltages ensures cleaner data signals, eliminating common display artifacts like ghosting, flicker, and crosstalk. The result is crisper images, more accurate colors, and higher contrast ratios.\n4.  **Increased Reliability and Scalability**: The robust design of this demultiplexer makes it less susceptible to manufacturing variations and external noise, leading to more consistent performance and higher manufacturing yields. Its efficient architecture is also highly scalable for future ultra-high-resolution displays and emerging technologies like micro-LEDs. Keywords: display benefits, faster displays, power saving, image clarity, display reliability, scalable technology.","question":"What are the key benefits of Demultiplexer and Display Device Including the Same?"},{"answer":"The Demultiplexer and Display Device Including the Same distinguishes itself from prior art through its highly optimized and active pre-charge circuit, which is a significant departure from conventional designs. Prior art demultiplexers often rely on simpler transistor arrays combined with passive RC (resistor-capacitor) networks for gate electrode charging.\n\nKey differences include:\n\n1.  **Active vs. Passive Pre-charging**: While prior art often uses passive RC charging, this invention employs an active third transistor in parallel with a first diode to rapidly and precisely charge the gate electrode. This active component drastically reduces RC delay and allows for much faster voltage transitions.\n2.  **Enhanced Voltage Stability**: The parallel diode and the strategically placed capacitor in this patent's pre-charge circuit provide superior voltage stabilization and noise filtering compared to simpler prior art designs. This results in cleaner signals and more consistent pixel performance.\n3.  **Optimized Power Management**: By actively controlling the charging and discharging, this technology minimizes the time components spend in inefficient states, leading to significantly better power efficiency than traditional methods that dissipate more energy through resistive paths.\n\nIn essence, the Demultiplexer and Display Device Including the Same moves beyond the limitations of passive charging to offer a dynamic, precise, and energy-efficient solution for data distribution in displays. Keywords: patent difference, prior art comparison, active pre-charge, passive charging, voltage stability, power management display.","question":"How is Demultiplexer and Display Device Including the Same different from prior art?"},{"answer":"The Demultiplexer and Display Device Including the Same patent has the potential to significantly impact a wide array of industries that rely heavily on advanced display technologies:\n\n1.  **Consumer Electronics**: This includes smartphones, tablets, laptops, smartwatches, and high-definition televisions. Consumers will benefit from longer battery life, faster refresh rates for gaming and video, and superior image quality.\n2.  **Gaming**: The reduction in latency and increase in refresh rates will provide a more immersive and responsive gaming experience across consoles, PCs, and mobile platforms.\n3.  **Virtual Reality (VR) and Augmented Reality (AR)**: For VR/AR headsets, ultra-low latency and high-resolution, artifact-free displays are crucial for immersion and preventing motion sickness. This technology can greatly enhance these devices.\n4.  **Automotive**: Modern vehicles feature increasingly sophisticated infotainment systems and digital dashboards. This innovation can lead to brighter, more reliable, and power-efficient displays for automotive applications.\n5.  **Professional and Industrial Displays**: Industries requiring high-fidelity displays, such as medical imaging, broadcasting, graphic design, and control rooms, will benefit from the improved clarity and stability offered by this demultiplexer.\n\nEssentially, any sector where visual performance and power efficiency are critical will see a positive impact from the adoption of this technology. Keywords: industry impact, consumer electronics, gaming displays, VR/AR technology, automotive displays, professional displays, display market.","question":"What industries will Demultiplexer and Display Device Including the Same impact?"},{"answer":"The patent \"Demultiplexer and Display Device Including the Same\" (US-9852674) has specific dates associated with its lifecycle:\n\n*   **Filing Date**: The patent application was filed on **2015-11-25**. This is the date when the inventors or their assignee submitted the application to the patent office, initiating the patent examination process.\n*   **Publication Date**: The patent was subsequently published on **2017-12-26**. This is typically when the patent document becomes publicly accessible, allowing others to review its contents. The publication date often precedes the grant date, providing transparency during the examination period.\n\nWhile the grant date is not explicitly provided in the initial data, the publication of the patent number US-9852674 on 2017-12-26 indicates that it has been granted, as this format is typically used for issued patents. The period between filing and publication involves examination by a patent examiner to determine novelty, non-obviousness, and utility. Keywords: patent filing date, patent publication date, US-9852674, patent timeline, patent grant.","question":"When was Demultiplexer and Display Device Including the Same filed/granted?"},{"answer":"The commercial applications of the Demultiplexer and Display Device Including the Same are extensive, driven by its ability to deliver superior display performance and power efficiency across various product categories:\n\n1.  **High-End Consumer Electronics**: Integration into premium smartphones, tablets, laptops, and smart TVs to offer differentiating features like ultra-high refresh rates, extended battery life, and unparalleled image quality.\n2.  **Gaming Hardware**: Essential for next-generation gaming monitors, laptops, and handheld devices that demand minimal latency and high frame rates for a competitive edge.\n3.  **Immersive Technologies**: Crucial for VR/AR headsets to achieve the necessary low latency, high resolution, and power efficiency for comfortable and realistic immersive experiences.\n4.  **Automotive Infotainment**: Enabling brighter, more reliable, and energy-efficient displays for in-car navigation, entertainment, and driver information systems.\n5.  **Professional Displays**: Applications in medical imaging, broadcasting, digital signage, and control rooms where color accuracy, stability, and high performance are paramount.\n\nManufacturers can leverage this technology to create premium products, gain a competitive advantage, and address growing market demands for advanced visual interfaces. The patent also offers licensing opportunities for technology providers to integrate this solution into their display driver ICs. Keywords: commercial applications, display products, gaming hardware, VR/AR applications, automotive displays, professional screens, market differentiation.","question":"What are the commercial applications of Demultiplexer and Display Device Including the Same?"},{"answer":"The Demultiplexer and Display Device Including the Same patent lays a robust foundation for numerous future developments in display technology. Its efficient and scalable architecture makes it highly adaptable to emerging trends and demands:\n\n1.  **Ultra-High Resolution Displays**: As we move beyond 8K to 16K and higher resolutions, the need for extremely precise and fast data routing will become even more critical. This demultiplexer's design is well-positioned to handle these demands.\n2.  **Micro-LED Technology**: Micro-LEDs, with their tiny pixel sizes and high-density arrays, require highly efficient and stable pixel control. This innovation could be a key enabler for the widespread adoption and commercialization of micro-LED displays.\n3.  **Flexible and Transparent Displays**: For displays that are foldable, rollable, or transparent, maintaining signal integrity and power efficiency across dynamic form factors is a challenge. The robust nature of this demultiplexer can support these next-generation form factors.\n4.  **Adaptive Refresh Rate Technologies**: Further integration with advanced timing controllers could lead to displays that intelligently adjust their refresh rates and power consumption in real-time based on content and user activity, optimizing both performance and efficiency.\n5.  **System-on-Panel (SoP) Integration**: The compact and efficient design may facilitate deeper integration of driver circuitry directly onto the display panel substrate, leading to thinner, lighter, and more cost-effective display modules. Keywords: future display tech, micro-LEDs, flexible displays, transparent screens, adaptive refresh rates, System-on-Panel, display innovation roadmap.","question":"What are the future developments expected for Demultiplexer and Display Device Including the Same?"}],"topics":["demultiplexer","display device","patent US-9852674","display technology","power efficiency","continuous","evolution","display"],"tech_cluster":null},"seo":{"title":"Demultiplexer & Display Device Including the Same - Patent US-9852674","description":"Discover the Demultiplexer and Display Device Including the Same patent: a groundbreaking innovation for faster, more power-efficient, and clearer display technology. Full analysis.","keywords":["demultiplexer","display device","patent US-9852674","display technology","power efficiency","high refresh rate","signal integrity","display driver","pre-charge circuit","TFT display","OLED display","display innovation","electronic display"]},"attribution":{"source":"Patentable","source_url":"https://patentable.app","canonical_url":"https://patentable.app/patents/US-9852674","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-9852674","citation_suggestion":"Patentable. \"Demultiplexer and display device including the same\" (US-9852674). https://patentable.app/patents/US-9852674","copyright_holder":"Nomic Interactive Technology LLC"},"links":{"html":"https://patentable.app/patents/US-9852674","json":"https://patentable.app/api/llm-context/US-9852674","site":"https://patentable.app","llms_txt":"https://patentable.app/llms.txt"},"generated_at":"2026-06-06T08:59:52.311Z"}