{"schema_version":"1.0","canonical_url":"https://patentable.app/patents/US-9854175","patent":{"patent_number":"US-9854175","title":"System optical magnification change without image quality deterioration of reduction","assignee":null,"inventors":[],"filing_date":"2016-06-23T00:00:00.000Z","publication_date":"2017-12-26T00:00:00.000Z","cpc_codes":["H04N","H04N","H04N","H04N"],"num_claims":20,"abstract":"In an implementation, a computer-implemented method includes receiving a digital signal from an image acquisition sensor, the digital signal encoded with an initial resolution. A video image is constructed from the digital signal to display on a micro display of an optical system, an initial linear dimension of the video image smaller than a linear dimension of an active area of the micro display. A display of the video image is initiated on the micro display using monochrome sub-pixels configured to act as independent pixels for display of the video image. A magnification request is received for the video image on the micro display, and the video image is adjusted on the micro display by increasing a linear dimension of the video image on the micro display by combining groups of monochrome sub-pixels to collectively represent a single pixel of the video image at the initial resolution."},"analysis":{"summary":"The System Optical Magnification Change Without Image Quality Deterioration of Reduction patent introduces a novel approach to maintaining image quality during magnification on micro-displays. The core innovation lies in its ability to dynamically adjust video images by combining groups of monochrome sub-pixels to represent a single pixel at the initial resolution. This addresses the pervasive problem of image degradation that occurs when video images are magnified, resulting in pixelation and loss of detail. The key technical approach involves receiving a digital signal from an image acquisition sensor, encoded with an initial resolution, and displaying the video image on a micro-display using monochrome sub-pixels as independent pixels. Upon receiving a magnification request, the system increases the linear dimension of the video image by combining these sub-pixels, effectively maintaining the original clarity and detail. The business value and applications of this technology are significant, particularly in industries such as virtual reality (VR), augmented reality (AR), and medical imaging, where high-resolution images are critical. The market opportunity is substantial, as this technology offers a superior solution for enhancing visual performance and user experience. By preventing image quality deterioration during magnification, this patent sets a new standard for display technology.","layman_explanation":"The System Optical Magnification Change Without Image Quality Deterioration of Reduction patent addresses a common issue in display technology: the degradation of image quality when zooming in or magnifying an image on a micro-display. Micro-displays are used in various applications, including virtual reality headsets, augmented reality glasses, and medical imaging devices. A key challenge in these applications is maintaining high image resolution and clarity, especially when the display is magnified to fit the user's field of view or to examine fine details. Existing solutions often fall short because they result in pixelation and loss of detail, which can detract from the user experience and limit the effectiveness of the technology.\n\nThis patent solves this problem by dynamically adjusting video images on the micro-display. Instead of simply stretching the existing pixels, the system uses a unique approach involving monochrome sub-pixels. Imagine a screen made up of many tiny lights, each of which can be turned on or off individually. These lights are grouped together to form larger pixels, which create the image. When a magnification request is received, the system increases the size of the pixels by combining groups of these tiny lights. This allows the system to create a larger image without sacrificing the original resolution. It's like having a set of building blocks that can be combined in different ways to create larger structures without losing the original detail.\n\nThis technology matters because it significantly improves the visual experience in various applications. In VR and AR headsets, it allows for more immersive and realistic virtual environments. In medical imaging, it enables doctors to examine fine details with greater clarity, leading to more accurate diagnoses. The competitive advantage of this patent lies in its ability to maintain high image resolution during magnification, which is a key differentiator in the market. The potential ROI is significant, as this technology can be licensed to micro-display manufacturers and integrated into various products.\n\nLooking ahead, this technology could be further developed to improve the energy efficiency of micro-displays and to enhance the color accuracy of magnified images. The market adoption timeline will depend on the pace of innovation in the micro-display industry and the demand for high-resolution displays in VR, AR, and medical imaging. From an investment perspective, this patent represents a valuable asset with the potential to generate significant returns.","technical_analysis":"The System Optical Magnification Change Without Image Quality Deterioration of Reduction patent presents a sophisticated solution to the challenge of maintaining image quality during magnification on micro-displays. The technical architecture of this system is designed to dynamically adjust video images by combining groups of monochrome sub-pixels. The process begins with an image acquisition sensor that captures a digital signal encoded with an initial resolution. This signal is then used to construct a video image, which is displayed on a micro-display. The initial linear dimension of the video image is smaller than the active area of the micro-display, allowing for subsequent magnification. The system initiates the display of the video image using monochrome sub-pixels, which are configured to act as independent pixels. This is a crucial aspect of the innovation, as it allows for fine-grained control over the image. When a magnification request is received, the system adjusts the video image by increasing the linear dimension of the video image on the micro-display. This is achieved by combining groups of monochrome sub-pixels to collectively represent a single pixel of the video image at the initial resolution. The implementation details involve complex algorithms for image scaling and interpolation. These algorithms ensure that the magnified image retains its original clarity and detail. The integration patterns are designed for real-time performance, ensuring that the magnified image is displayed without any noticeable delay. The performance characteristics of this system are significantly improved compared to traditional magnification techniques. By using monochrome sub-pixels as independent pixels, the system can dynamically adjust the image without sacrificing resolution. The code-level implications involve the development of optimized video processing algorithms and efficient memory management techniques. This requires a deep understanding of micro-display technology and video processing principles. The System Optical Magnification Change Without Image Quality Deterioration of Reduction patent represents a significant advancement in micro-display technology, offering a superior solution for maintaining image quality during magnification.","business_analysis":"The System Optical Magnification Change Without Image Quality Deterioration of Reduction patent presents a significant market opportunity within the micro-display technology sector. The core innovation of this patent, which focuses on maintaining image quality during magnification, addresses a critical need in various industries, including virtual reality (VR), augmented reality (AR), and medical imaging. The market opportunity size for high-resolution micro-displays is substantial and growing. As VR and AR technologies become more prevalent, the demand for displays that can deliver clear and detailed images will continue to increase. Similarly, in the medical imaging field, high-resolution displays are essential for accurate diagnoses and treatment planning. The System Optical Magnification Change Without Image Quality Deterioration of Reduction patent offers several competitive advantages over existing solutions. Traditional magnification techniques often result in pixelation and loss of detail, which can detract from the user experience. This patent solves this problem by dynamically adjusting video images using monochrome sub-pixels, ensuring that the magnified image retains its original clarity and detail. The revenue potential for this technology is significant. Micro-display manufacturers can license this patent to improve the performance of their products. VR and AR headset makers can incorporate this technology to deliver a superior visual experience. Medical device companies can use this technology to enhance the accuracy of their imaging systems. Several business models are viable for this technology. Licensing the patent to micro-display manufacturers is one option. Developing and selling integrated micro-display solutions is another. Partnering with VR and AR headset makers to incorporate this technology into their products is also a possibility. From a strategic positioning perspective, this patent positions the company as a leader in micro-display technology innovation. The ability to maintain image quality during magnification is a key differentiator that can attract customers and partners. ROI projections for this technology are promising. By licensing the patent to multiple manufacturers and partnering with key players in the VR, AR, and medical imaging industries, the company can generate substantial revenue streams. The initial investment in research and development can be recouped quickly, leading to significant long-term profitability.","faqs":null,"topics":["image magnification","micro-display","resolution enhancement","VR display","AR display"],"tech_cluster":null},"seo":{"title":"Clear Zoom Tech: System Optical Magnification Change Without Image Quality Deterioration of Reduction - US-9854175","description":"Discover the System Optical Magnification Change Without Image Quality Deterioration of Reduction patent for crystal-clear zoomed images. Full analysis, claims, and applications.","keywords":["image magnification","micro-display","resolution enhancement","VR display","AR display","monochrome sub-pixels","patent","patent US-9854175"]},"attribution":{"source":"Patentable","source_url":"https://patentable.app","canonical_url":"https://patentable.app/patents/US-9854175","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-9854175","citation_suggestion":"Patentable. \"System optical magnification change without image quality deterioration of reduction\" (US-9854175). https://patentable.app/patents/US-9854175","copyright_holder":"Nomic Interactive Technology LLC"},"links":{"html":"https://patentable.app/patents/US-9854175","json":"https://patentable.app/api/llm-context/US-9854175","site":"https://patentable.app","llms_txt":"https://patentable.app/llms.txt"},"generated_at":"2026-05-31T04:48:17.156Z"}