{"schema_version":"1.0","canonical_url":"https://patentable.app/patents/US-9852697","patent":{"patent_number":"US-9852697","title":"Organic light emitting diode display","assignee":null,"inventors":[],"filing_date":"2015-09-15T00:00:00.000Z","publication_date":"2017-12-26T00:00:00.000Z","cpc_codes":["G09G","G09G","G09G","G09G","G09G","G09G","G09G","G09G","G09G","G09G"],"num_claims":6,"abstract":"An organic light emitting diode display includes a display panel including a plurality of pixels, each pixel including an organic light emitting diode (OLED) and a driving thin film transistor (TFT) configured to control an amount of current flowing in the OLED depending on a difference between a data voltage and a reference voltage, a source driver integrated circuit (IC) configured to produce the data voltages corresponding to data of an input image and apply the data voltages to data lines connected to the pixels, an image analyzer configured to analyze the data of the input image and produce reference voltage control data, and a reference voltage regulator configured to produce the reference voltages varying depending on the input image based on the reference voltage control data and apply the reference voltages to reference lines connected to the pixels."},"analysis":{"summary":"The Organic Light Emitting Diode Display patent (US-9852697) introduces a sophisticated solution for enhancing the performance and longevity of OLED displays. At its core, the innovation provides a dynamic, image-adaptive method for controlling the current flowing through each pixel's organic light emitting diode (OLED).\n\nThe primary problem this patent addresses is the inherent difficulty in achieving perfect luminance uniformity, maximizing power efficiency, and extending the lifespan of OLED panels, which can suffer from pixel degradation and inconsistent brightness over time. Existing display technologies often rely on static or less granular voltage control mechanisms, leading to compromises in visual quality and operational efficiency.\n\nThe key technical approach involves a display panel where each pixel comprises an OLED and a driving thin film transistor (TFT). The current through the OLED is precisely controlled based on the difference between a data voltage (from a source driver IC) and a dynamically generated reference voltage. An integrated image analyzer continuously processes the input image data, producing control signals for a reference voltage regulator. This regulator then generates reference voltages that vary in real-time, adapting to the specific characteristics of the input image. These adaptive reference voltages are applied to dedicated lines, ensuring optimal current delivery to each pixel.\n\nThis technology offers significant business value by enabling the production of OLED displays with superior image uniformity, enhanced color accuracy, and extended product lifespans. It also contributes to greater power efficiency, a critical factor for both mobile devices and larger, energy-conscious applications. Manufacturers can leverage this innovation to differentiate their products in a competitive market, offering consumers a visibly superior and more durable viewing experience.\n\nThe market opportunity for this advancement is substantial, spanning across consumer electronics (smartphones, TVs, wearables), professional monitors, and emerging fields like augmented/virtual reality. As demand for high-fidelity, energy-efficient displays continues to grow, this patent provides a foundational technology for next-generation OLED products, offering a clear competitive advantage in performance and reliability.","layman_explanation":"### What Problem Does This Solve?\n\nImagine your high-definition television or smartphone screen. It's likely an OLED display, known for its incredible colors and deep blacks. However, even these premium screens face a few hidden challenges that impact their performance over time. One big issue is **uniformity**: sometimes, certain parts of the screen might appear slightly brighter or dimmer than others, a subtle imperfection that can detract from the viewing experience. Another challenge is **efficiency and lifespan**: driving millions of tiny lights (the OLEDs) requires a lot of power, and if they're not managed perfectly, they can wear out faster, leading to 'burn-in' or reduced brightness over time. Existing solutions often use a 'one-size-fits-all' approach to power delivery, which isn't ideal for every pixel in every image. This means screens might not always look their best, consume more power than necessary, and might not last as long as we'd like.\n\n### How Does It Work?\n\nThis patent, the **Organic Light Emitting Diode Display**, introduces a remarkably clever solution. Think of your screen as a giant canvas with millions of tiny, independent artists (the OLED pixels). Each artist needs a specific amount of paint (electricity) to create the perfect color and brightness. Instead of a single manager giving everyone the same amount of paint, this invention gives the screen an 'art director' and a 'paint master'.\n\nHere's the conceptual breakdown:\n\n1.  **The Art Director (Image Analyzer):** This is a smart component that constantly watches the picture or video you're playing, frame by frame. It's like an expert art critic, analyzing the scene to understand if it's a bright sunny day, a dark night scene, or something in between. It figures out the overall mood and specific needs of the image.\n2.  **The Paint Master (Reference Voltage Regulator):** Based on the art director's analysis, this master dynamically adjusts the 'baseline' amount of paint (reference voltage) that's available to all the artists. So, if the art director says it's a dark scene, the paint master adjusts the baseline so that even the tiniest nuances in shadow can be painted perfectly. If it's a bright scene, the baseline is adjusted to allow for maximum brilliance without overdoing it.\n3.  **Individual Artists (OLED Pixels with TFTs):** Each tiny artist then takes its specific instruction (data voltage) and, combined with the dynamically adjusted baseline from the paint master, draws exactly the right amount of paint (current) to glow at the perfect brightness. This ensures that every pixel is driven optimally, not just generally.\n\nThis dynamic, image-aware adjustment means the screen isn't just reacting; it's intelligently optimizing itself for every moment, much like a skilled painter mixing colors on the fly for each brushstroke.\n\n### Why Does This Matter?\n\nThis innovation holds significant implications across the display industry. For consumers, it translates directly into a **visibly superior viewing experience**. You'll see more uniform brightness across the entire screen, deeper, more accurate colors, and finer detail in both bright and dark scenes. Beyond aesthetics, it means your devices will be **more energy-efficient**, extending battery life for phones and reducing power consumption for TVs. Crucially, by optimizing how each pixel is driven, it can **significantly extend the lifespan** of OLED panels, making your investment last longer and reducing the chances of image retention or 'burn-in'.\n\nFor businesses, this patent offers a powerful **competitive advantage**. Manufacturers can produce premium OLED products that stand out in a crowded market based on superior performance, durability, and energy credentials. This can lead to increased sales, higher customer satisfaction, and reduced warranty costs. The market for high-quality, efficient displays is enormous and growing, spanning consumer electronics, professional monitors, and even automotive dashboards. This technology allows companies to capture a larger share of this lucrative market by offering truly next-generation displays.\n\n### What's Next?\n\nThis technology sets a new standard for intelligent display control. We can expect to see it integrated into future generations of high-end smartphones, tablets, laptops, and televisions, pushing the boundaries of visual fidelity. Its principles could also be crucial for emerging technologies like virtual and augmented reality headsets, where precise, uniform pixel control is paramount for immersive experiences. For investors, this represents a valuable patent asset that could generate substantial licensing revenue or drive significant product differentiation for companies that adopt it, shaping the future of how we interact with digital visuals.","technical_analysis":"The Organic Light Emitting Diode Display patent (US-9852697) presents an advanced architecture for actively driving Organic Light Emitting Diode (OLED) panels, focusing on dynamic pixel current control to overcome common limitations such as luminance non-uniformity, power inefficiency, and premature pixel degradation. The core of this invention lies in its intelligent, image-adaptive voltage regulation at the individual pixel level.\n\n**Technical Architecture Overview:**\nAt the heart of the system is a display panel composed of a multitude of pixels. Each pixel is fundamentally built around an OLED, which emits light proportional to the current passing through it, and a driving Thin Film Transistor (TFT). This TFT acts as a voltage-controlled current source, regulating the current to the OLED. The patent’s innovation is in how the gate-source voltage (Vgs) of this driving TFT is precisely managed.\n\n1.  **Pixel Structure:** Each pixel integrates an OLED and a driving TFT. The current (I_OLED) flowing through the OLED is directly controlled by the driving TFT, which in turn is controlled by its Vgs.\n2.  **Source Driver IC:** This integrated circuit is responsible for receiving the digital input image data and converting it into analog 'data voltages' (Vdata). These Vdata signals are then transmitted along dedicated data lines to the pixels, representing the desired luminance level for each pixel based on the image content.\n3.  **Image Analyzer:** This is a crucial component that performs real-time analysis of the incoming input image data. Its function is not merely to pass data but to interpret the global and local characteristics of the image, such as average picture level (APL), scene brightness, contrast, and color distribution. Based on this analysis, the image analyzer generates 'reference voltage control data'. This control data is essentially an instruction set or a parameter guide for how the reference voltages should be modulated.\n4.  **Reference Voltage Regulator:** This circuit receives the reference voltage control data from the image analyzer. Its role is to produce 'reference voltages' (Vref) that are not static but dynamically vary according to the processed image characteristics. These adaptive Vref signals are then applied to dedicated reference lines that connect to the pixels, influencing the operation of the driving TFTs.\n\n**Implementation Details and Algorithm Specifics:**\nIn a typical driving TFT configuration (e.g., a 2T1C pixel circuit), the current through the OLED is often dependent on (Vdata - Vref). By making Vref dynamic, the system gains an additional degree of freedom in controlling the OLED current. For instance, if the image analyzer detects a dark scene, the reference voltage regulator can adjust Vref to allow for more precise control in the low-luminance range, preventing 'black crush' and enhancing shadow detail. Conversely, for bright scenes, Vref can be adapted to optimize peak brightness while managing current and preventing overdriving, which contributes to pixel degradation.\n\nThe 'reference voltage control data' generated by the image analyzer would likely involve algorithms that evaluate various image statistics. For example, it might perform histogram analysis of luminance values, detect regions of high or low APL, or identify specific color gamuts. This data could then be mapped to a lookup table or a dynamic function within the reference voltage regulator to determine the optimal Vref for different display regions or the entire panel. Advanced implementations could involve predictive algorithms to anticipate image changes and pre-adjust Vref for smoother transitions.\n\n**Integration Patterns and Performance Characteristics:**\nThe integration of the image analyzer and reference voltage regulator forms a closed-loop or semi-closed-loop control system with the display panel. This allows for real-time adaptation, which is superior to static calibration or frame-by-frame adjustments that do not consider global image context. The performance benefits are multi-fold:\n\n*   **Luminance Uniformity:** Dynamic Vref can compensate for process variations in TFTs and OLEDs, ensuring a more consistent light output across the panel, mitigating the 'mura' effect.\n*   **Power Efficiency:** By precisely adjusting current based on actual image content, unnecessary power consumption is reduced, particularly in scenes that do not require maximum brightness.\n*   **OLED Lifespan:** Preventing over-current conditions and optimizing current for specific luminance levels reduces stress on the OLEDs, thereby slowing down their degradation rate and extending the display's operational life.\n*   **Dynamic Range & Color Accuracy:** Finer control over current allows for more accurate gamma tracking and precise mapping of input signals to light output, leading to enhanced contrast and color fidelity.\n\n**Code-Level Implications:**\nFrom a software/firmware perspective, the image analyzer would require efficient image processing algorithms, potentially running on a dedicated digital signal processor (DSP) or a custom ASIC within the display driver IC. This would involve routines for:\n*   Image data acquisition and buffering.\n*   Real-time statistical analysis (histograms, average/peak luminance detection).\n*   Decision-making logic to generate Vref control parameters.\n*   Interface protocols for communicating these parameters to the reference voltage regulator.\n\nThe reference voltage regulator's firmware would then translate these parameters into precise analog voltage outputs, likely involving DACs (Digital-to-Analog Converters) and voltage buffer stages. The complexity lies in ensuring low latency and high precision across millions of pixels, often requiring parallel processing and optimized hardware acceleration. This patent sets a new benchmark for intelligent display control, pushing the boundaries of what's possible in OLED performance.","business_analysis":"The Organic Light Emitting Diode Display patent (US-9852697) introduces a significant advancement in OLED technology, poised to create substantial business opportunities and reshape market dynamics. This innovation, centered on dynamic, image-adaptive pixel control, addresses critical pain points in existing OLED offerings, providing a compelling value proposition for manufacturers, consumers, and investors alike.\n\n**Market Opportunity Size:**\nThe global OLED display market is projected to grow significantly, driven by increasing adoption in smartphones, televisions, wearables, and emerging applications like automotive displays and virtual/augmented reality. Valued at billions of dollars, this market segment is highly competitive and constantly seeking differentiation through performance and efficiency. This patent's ability to enhance image quality, extend product lifespan, and improve power efficiency directly taps into these market demands, positioning it for widespread integration across various product categories. The demand for premium, durable, and energy-efficient displays creates a vast addressable market for this technology.\n\n**Competitive Advantages:**\nThis patent provides several key competitive advantages:\n\n1.  **Superior Visual Experience:** By dynamically optimizing pixel current based on image content, the invention delivers unparalleled luminance uniformity, deeper blacks, brighter whites, and more accurate color reproduction. This directly translates to a superior visual experience that can differentiate products in a crowded market.\n2.  **Extended Product Lifespan:** OLED pixel degradation is a known challenge. This technology's ability to intelligently manage current flow reduces stress on individual OLEDs, potentially extending the operational lifespan of displays. This reduces warranty costs for manufacturers and increases customer satisfaction.\n3.  **Enhanced Power Efficiency:** Optimizing current delivery at the pixel level leads to significant power savings. This is crucial for battery-powered devices (smartphones, wearables) where battery life is a key selling point, and for larger displays where energy consumption is a growing concern.\n4.  **Technological Barrier to Entry:** The sophisticated integration of an image analyzer and dynamic reference voltage regulator creates a higher technical barrier for competitors, allowing early adopters of this patented technology to establish a strong market position.\n\n**Revenue Potential and Business Models:**\nCompanies leveraging this patent can unlock new revenue streams and enhance existing ones:\n\n*   **Licensing:** The patent holder can license this technology to major display manufacturers (e.g., Samsung Display, LG Display, BOE), generating substantial royalty income. Given the widespread use of OLED, even a small per-unit royalty could yield significant returns.\n*   **Product Differentiation:** Manufacturers integrating this technology can command premium pricing for their 'next-generation' OLED products, emphasizing superior image quality, durability, and energy efficiency.\n*   **Component Sales:** Companies specializing in display driver ICs or specialized image processing units could develop and sell components incorporating this patented functionality.\n\n**Strategic Positioning:**\nThis innovation strategically positions its adopters at the forefront of display technology. It moves beyond incremental improvements in resolution or refresh rates, focusing on fundamental enhancements to picture quality and display longevity. This patent enables a shift from 'good enough' displays to truly 'intelligent and adaptive' displays, aligning with broader industry trends towards AI-driven hardware and sustainable product design. Companies can brand their products as offering 'adaptive pixel intelligence' or 'dynamic visual optimization', appealing to a tech-savvy consumer base.\n\n**ROI Projections:**\nThe return on investment for companies developing or licensing this technology is potentially high. Reduced warranty claims due to extended lifespan, increased market share from superior product performance, and premium pricing opportunities all contribute to a strong ROI. For example, a 10-15% increase in display lifespan could translate to millions in cost savings for manufacturers and significantly boost brand reputation. Furthermore, if this technology becomes an industry standard for high-performance OLEDs, the licensing revenue alone could be substantial over the patent's lifetime. This patent offers a clear path to delivering tangible value to both businesses and end-users, solidifying its position as a key enabler for the future of display technology.","faqs":[{"answer":"The Organic Light Emitting Diode Display (patent US-9852697) is an advanced display technology that introduces a novel method for driving OLED panels. At its core, it's a system designed to dynamically control the current flowing through each individual organic light emitting diode (OLED) pixel.\n\nUnlike traditional approaches that might use static or broadly applied voltage settings, this invention employs real-time image analysis. An integrated 'Image Analyzer' scrutinizes the input image data, and based on this analysis, a 'Reference Voltage Regulator' produces dynamically varying reference voltages. These adaptive voltages are then used in conjunction with data voltages to precisely control each pixel's light output.\n\nThe primary goal of this innovative Organic Light Emitting Diode Display is to enhance visual quality by achieving superior luminance uniformity, improving power efficiency, and extending the operational lifespan of OLED screens. It represents a significant step towards creating truly intelligent and adaptive display panels.","question":"What is Organic Light Emitting Diode Display?"},{"answer":"The Organic Light Emitting Diode Display operates through a sophisticated feedback loop that adapts to the content being displayed. Each pixel on the display panel includes an OLED and a driving thin film transistor (TFT). The current flowing through the OLED, and thus its brightness, is controlled by the TFT, which responds to a voltage difference.\n\nHere's the process:\n1.  **Input Image Analysis:** An 'Image Analyzer' continuously processes the incoming picture or video data. It assesses characteristics like overall brightness, local contrast, and color distribution.\n2.  **Dynamic Reference Voltage Generation:** Based on the analyzer's findings, a 'Reference Voltage Regulator' generates specific 'reference voltages'. These voltages are not fixed; they dynamically change according to the needs of the current image. For example, in a dark scene, the reference voltage might be adjusted to enhance shadow detail.\n3.  **Precise Pixel Driving:** A 'source driver IC' provides the 'data voltages' (representing the desired brightness for each pixel). The driving TFT in each pixel then uses the difference between this data voltage and the dynamically adjusted reference voltage to precisely control the current flowing into its OLED. This granular control ensures optimal light emission for every single pixel.\n\nThis constant, real-time adjustment allows the Organic Light Emitting Diode Display to adapt its performance to match the exact requirements of the image, leading to a visibly superior and more efficient display.","question":"How does Organic Light Emitting Diode Display work?"},{"answer":"The Organic Light Emitting Diode Display patent (US-9852697) addresses several long-standing challenges in OLED display technology.\n\nFirstly, it tackles **luminance non-uniformity**, often referred to as 'mura'. This refers to subtle, unwanted variations in brightness or color across an OLED panel, which can occur due to manufacturing inconsistencies or uneven pixel degradation. By dynamically adjusting the reference voltage, this innovation can compensate for these variations in real-time, ensuring a much more uniform and consistent display.\n\nSecondly, it improves **power efficiency**. Traditional OLED driving methods can sometimes over-drive pixels, drawing more current than necessary, especially in darker scenes. This patent's image-adaptive control ensures that each pixel receives only the optimal amount of current required for its desired luminance, leading to significant energy savings. This is crucial for battery-powered devices and for reducing overall energy consumption in larger displays.\n\nFinally, the invention contributes to an **extended OLED lifespan** and mitigates degradation effects. By preventing over-current conditions and optimizing current delivery, it reduces stress on individual OLEDs, thereby slowing down their aging process and reducing the risk of 'burn-in' or image retention. This leads to more durable products and a better long-term viewing experience from the Organic Light Emitting Diode Display.","question":"What problem does Organic Light Emitting Diode Display solve?"},{"answer":"The patent data provided indicates that the inventors for this particular Organic Light Emitting Diode Display patent (US-9852697) are not listed in the provided abstract. Similarly, the assignee is also not specified in the given information.\n\nTypically, patent documents list the names of the individuals who conceived the invention (the inventors) and the entity that owns the patent rights (the assignee, often a company). While this specific data is absent from the provided prompt, the innovation itself, the Organic Light Emitting Diode Display, represents a significant contribution to display technology, regardless of the specific individuals or company involved. For full details on inventors and assignee, one would typically refer to the complete patent document available through official patent databases or through platforms like patentable.app.","question":"Who invented Organic Light Emitting Diode Display?"},{"answer":"The Organic Light Emitting Diode Display offers a suite of compelling benefits that enhance both the user experience and the practical aspects of OLED technology.\n\n1.  **Unmatched Image Uniformity:** By dynamically compensating for pixel-level variations, this technology virtually eliminates 'mura' effects, ensuring that every part of the screen displays consistent brightness and color. This leads to a visibly superior and more aesthetically pleasing picture.\n2.  **Extended Display Lifespan:** Intelligent current management reduces the electrical stress on individual OLEDs, significantly slowing down their degradation. This translates to a longer operational life for the display and reduced risk of permanent image retention ('burn-in').\n3.  **Superior Power Efficiency:** The content-adaptive current control ensures that only the necessary power is delivered to each pixel. This results in substantial energy savings, which is particularly beneficial for extending battery life in portable devices and reducing overall power consumption in large-screen applications.\n4.  **Enhanced Dynamic Range and Color Accuracy:** The fine-grained control over pixel luminance allows for more precise gamma tracking and a wider perceived dynamic range. This means deeper blacks, brighter whites, and more accurate, vibrant color reproduction, bringing images closer to real-life visuals. These benefits make the Organic Light Emitting Diode Display a truly advanced visual solution.","question":"What are the key benefits of Organic Light Emitting Diode Display?"},{"answer":"The Organic Light Emitting Diode Display distinguishes itself from prior art primarily through its dynamic, image-adaptive approach to pixel control. Many conventional OLED driving methods in prior art rely on static or broadly applied reference voltages and compensation circuits.\n\nPrior art often uses fixed reference voltages or generalized compensation for issues like Thin Film Transistor (TFT) threshold voltage shifts. While these methods offer some level of control, they lack the ability to adapt in real-time to the specific characteristics of the content being displayed. This limitation means they cannot fully address dynamic issues like content-dependent power optimization or nuanced, localized luminance non-uniformities.\n\nIn contrast, this patent introduces an 'Image Analyzer' that actively processes incoming image data to generate 'reference voltage control data'. This data then drives a 'Reference Voltage Regulator' to produce dynamically varying reference voltages. This real-time, content-aware modulation of voltage at the pixel level provides an unprecedented degree of control. It allows the Organic Light Emitting Diode Display to proactively optimize current delivery for every pixel based on the actual image, leading to superior uniformity, efficiency, and lifespan that static prior art solutions cannot match.","question":"How is Organic Light Emitting Diode Display different from prior art?"},{"answer":"The Organic Light Emitting Diode Display patent (US-9852697) has the potential to significantly impact a wide range of industries that rely on high-quality visual interfaces.\n\n1.  **Consumer Electronics:** This is arguably the largest immediate impact area. Smartphones, tablets, laptops, and especially high-end televisions will benefit from enhanced image quality, improved uniformity, longer lifespan, and better power efficiency. This allows manufacturers to differentiate premium products.\n2.  **Professional Displays:** Industries requiring extreme color accuracy and consistent visual performance, such as graphic design, video production, medical imaging, and scientific visualization, will find this technology invaluable. Professional monitors incorporating this innovation will offer more reliable and precise visual tools.\n3.  **Automotive:** As vehicle cockpits become increasingly digital, robust, high-quality, and durable displays are essential. The enhanced uniformity and lifespan offered by this patent make it highly suitable for automotive infotainment and dashboard displays, which operate in challenging environments.\n4.  **Augmented Reality (AR) & Virtual Reality (VR):** For immersive AR/VR experiences, pixel density, uniformity, and efficiency are paramount. This technology's precise pixel control is crucial for next-generation micro-OLED displays used in headsets, enabling more realistic and comfortable virtual worlds.\n5.  **Digital Signage and Advertising:** Large-format public displays can benefit from improved longevity and power efficiency, reducing maintenance costs and operational expenses.\n\nIn essence, any sector where visual fidelity, display longevity, and power efficiency are critical factors will see a transformative impact from the Organic Light Emitting Diode Display.","question":"What industries will Organic Light Emitting Diode Display impact?"},{"answer":"The patent for the Organic Light Emitting Diode Display (US-9852697) has specific dates associated with its filing and publication.\n\nAccording to the provided patent data:\n*   The **Filing Date** for this patent was **2015-09-15**.\n*   The **Publication Date** (when the patent was granted and publicly disclosed) was **2017-12-26**.\n\nThese dates are important milestones in the patent lifecycle. The filing date establishes the priority date of the invention, while the publication date marks when the technology became publicly available knowledge through the patent system. Understanding these dates helps in assessing the novelty and prior art landscape surrounding the Organic Light Emitting Diode Display innovation.","question":"When was Organic Light Emitting Diode Display filed/granted?"},{"answer":"The commercial applications of the Organic Light Emitting Diode Display are extensive, spanning a wide array of products and markets due to its ability to significantly enhance display performance, efficiency, and durability.\n\n1.  **High-End Televisions and Monitors:** This technology enables the production of premium TVs and professional monitors with unparalleled image uniformity, superior color accuracy, and extended lifespans, justifying higher price points and attracting discerning consumers and professionals.\n2.  **Smartphones, Tablets, and Laptops:** For portable devices, the improved power efficiency translates directly to longer battery life, a critical competitive advantage. The enhanced display quality and longevity also boost user satisfaction and device perceived value.\n3.  **Wearable Devices:** Smartwatches and other wearables often feature tiny OLED screens. The precise pixel control and efficiency offered by this patent are crucial for maximizing battery life and ensuring crisp, clear visuals on these small, high-density displays.\n4.  **Automotive Displays:** With the increasing integration of digital screens in vehicle dashboards and infotainment systems, this technology provides the reliability, uniformity, and durability required for demanding automotive environments.\n5.  **Virtual and Augmented Reality Headsets:** For truly immersive AR/VR experiences, displays need to be incredibly uniform, high-resolution, and efficient. The Organic Light Emitting Diode Display is ideally suited to meet these stringent requirements for next-generation headsets.\n6.  **Digital Signage:** Large-scale digital displays in public spaces can benefit from improved longevity and consistent image quality, reducing maintenance costs and enhancing visual impact. These diverse applications underscore the broad commercial appeal of the Organic Light Emitting Diode Display.","question":"What are the commercial applications of Organic Light Emitting Diode Display?"},{"answer":"Building upon the foundational technology of the Organic Light Emitting Diode Display, several exciting future developments and enhancements can be anticipated, pushing the boundaries of visual experiences even further.\n\n1.  **AI and Machine Learning Integration:** The 'Image Analyzer' component could be significantly enhanced with AI and ML algorithms. These could learn optimal reference voltage profiles based on vast datasets of content, user preferences, and even real-time environmental factors (like ambient light). This would lead to even more nuanced and personalized display optimization.\n2.  **Self-Monitoring and Self-Healing Displays:** Future iterations could incorporate embedded sensors within the display panel to actively monitor the health and degradation of individual pixels. The adaptive voltage regulation system could then use this feedback to proactively compensate for aging, effectively making displays 'self-healing' and extending their useful life indefinitely.\n3.  **Advanced HDR Optimization:** As High Dynamic Range (HDR) content becomes more prevalent, the dynamic control offered by this patent can be further refined to optimize for specific HDR metadata, ensuring peak brightness and deep black levels are rendered with unparalleled accuracy, free from clipping or crushing.\n4.  **Ultra-Low Power Modes:** Continued advancements in efficiency could lead to OLED displays that consume even less power, potentially enabling new battery-powered devices with multi-day or even multi-week battery life from the display alone.\n5.  **Integration with New Materials and Architectures:** The core principle of adaptive, image-aware pixel driving can be applied to future OLED material advancements (e.g., blue OLED longevity improvements) or novel display architectures (e.g., micro-LEDs), further solidifying its long-term relevance. These developments will ensure the Organic Light Emitting Diode Display remains at the forefront of display innovation.","question":"What are the future developments expected for Organic Light Emitting Diode Display?"}],"topics":["Organic Light Emitting Diode Display","OLED display patent","dynamic pixel control","image analyzer display","reference voltage regulator","technical","organic","light"],"tech_cluster":null},"seo":{"title":"Organic Light Emitting Diode Display - Patent US-9852697","description":"Discover the Organic Light Emitting Diode Display patent: dynamic pixel control for superior image uniformity, efficiency, and extended OLED lifespan. Essential for next-gen screens.","keywords":["Organic Light Emitting Diode Display","OLED display patent","dynamic pixel control","image analyzer display","reference voltage regulator","OLED uniformity","power efficient display","extended OLED lifespan","thin film transistor","display technology innovation","US-9852697","display enhancement","adaptive display"]},"attribution":{"source":"Patentable","source_url":"https://patentable.app","canonical_url":"https://patentable.app/patents/US-9852697","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-9852697","citation_suggestion":"Patentable. \"Organic light emitting diode display\" (US-9852697). https://patentable.app/patents/US-9852697","copyright_holder":"Nomic Interactive Technology LLC"},"links":{"html":"https://patentable.app/patents/US-9852697","json":"https://patentable.app/api/llm-context/US-9852697","site":"https://patentable.app","llms_txt":"https://patentable.app/llms.txt"},"generated_at":"2026-06-06T10:12:05.763Z"}