{"schema_version":"1.0","canonical_url":"https://patentable.app/patents/US-9853341","patent":{"patent_number":"US-9853341","title":"Shell of electronic device and wave filter","assignee":null,"inventors":[],"filing_date":"2015-06-03T00:00:00.000Z","publication_date":"2017-12-26T00:00:00.000Z","cpc_codes":["H01L","H01L"],"num_claims":12,"abstract":"A shell of an electronic device includes a base, two sidewalls, and a plurality of terminals. The base includes upper lateral and lower lateral surfaces opposite to each other. The two sidewalls are disposed at the upper lateral surface and are located separately at two opposite sides of the base. The two sidewalls are opposite to each other, with each sidewall having a surface that faces away from the base. The plurality of terminals is symmetrically arranged in order at the other opposite sides of the base and is embedded in the base. Each terminal includes an upper section and a lower section, with the upper section vertically extending upwards from the upper lateral surface, with the lower section horizontally extending outwards from the lower lateral surface, and with at least a portion of the lower section affixed flatly to the lower lateral surface."},"analysis":{"summary":"The Shell of Electronic Device and Wave Filter patent (US-9853341) introduces a revolutionary design for electronic device enclosures that integrates active wave filtering capabilities directly into its structure. This core innovation addresses the persistent challenges of electromagnetic interference (EMI) and space constraints in modern electronics by transforming a passive shell into a performance-enhancing component.\n\nThe problem being solved is the increasing difficulty of managing EMI and maintaining signal integrity as electronic devices become smaller and more densely packed. Traditional solutions often involve adding separate, bulky shielding or filtering components, which add to the device's size, cost, and manufacturing complexity, directly contradicting the trend towards miniaturization.\n\nThe key technical approach involves a meticulously designed shell comprising a base with distinct upper and lower lateral surfaces, two strategically positioned sidewalls on the upper surface, and a plurality of symmetrically arranged terminals embedded within the base. Each terminal features an upper section extending vertically upwards and a lower section extending horizontally outwards and affixed flatly to the lower surface. This intricate geometry and arrangement are engineered to create a controlled electromagnetic environment, allowing the shell to actively filter unwanted frequencies or enhance desired signals.\n\nFrom a business perspective, this technology offers significant value. It enables the creation of more compact, lighter, and potentially more cost-effective electronic devices by reducing the need for discrete filtering components. This simplifies the bill of materials, streamlines manufacturing processes, and improves overall device reliability. Applications are vast, spanning consumer electronics (smartphones, wearables), telecommunications (5G/6G modules), IoT devices, automotive systems, and medical equipment, where space efficiency and signal integrity are paramount.\n\nThe market opportunity is substantial, driven by the global demand for smaller, more powerful, and reliable electronic devices. This innovation provides a competitive advantage for manufacturers seeking to differentiate their products through superior performance and design efficiency, offering a foundational technology for the next generation of integrated electronics.","layman_explanation":"### What Problem Does This Solve?\nImagine trying to fit more and more features into your smartphone, making it thinner and lighter, all while ensuring everything works perfectly. One of the biggest headaches for engineers is 'electronic noise' or Electromagnetic Interference (EMI). This noise is like static on a radio, but it can mess up the tiny signals inside your device, causing glitches, slowing things down, or even draining your battery faster. Right now, to fight this noise, devices often need extra layers of shielding or small, separate filter components. These additions take up precious space, add weight, and make the device more expensive and complicated to build. The core problem is how to protect sensitive electronics from interference without compromising on size, cost, or design flexibility.\n\n### How Does It Work?\nThe **Shell of Electronic Device and Wave Filter** patent offers an ingenious solution: it turns the device's outer casing, or 'shell,' into an active participant in managing electronic signals. Instead of just being a protective box, this shell is designed with special features that act as a built-in filter. Think of it like a smart building where the walls themselves are designed to block out street noise, rather than needing extra soundproofing panels everywhere. The patent describes a shell with a main 'base,' and two 'sidewalls' that are precisely placed. Crucially, it integrates a series of 'terminals' – tiny electrical connectors – directly into the base. These terminals aren't just for plugging things in; their unique shape and arrangement, with parts extending upwards and other parts extending outwards and lying flat, are engineered to interact with electromagnetic waves. This creates a kind of invisible 'maze' or 'trap' within the shell that catches unwanted electronic noise, letting only the clean, essential signals pass through. It's like having a miniature, highly efficient signal processing system embedded right into the device's structure.\n\n### Why Does This Matter?\nThis innovation matters because it fundamentally changes how electronic devices can be designed and manufactured. For businesses, this means:\n\n*   **Smaller, Sleeker Products:** By eliminating the need for separate shielding and filters, companies can create devices that are significantly thinner, lighter, and more aesthetically pleasing. This is a huge competitive advantage in markets like smartphones, wearables, and compact IoT devices.\n*   **Reduced Costs & Simpler Manufacturing:** Fewer components mean lower material costs and a simpler, faster assembly process. This can lead to higher profit margins or enable more aggressive pricing strategies.\n*   **Enhanced Performance & Reliability:** Devices built with this technology will inherently have cleaner signals and less interference, leading to more reliable operation, better performance, and potentially longer battery life.\n*   **Market Differentiation:** Companies adopting this technology can position themselves as leaders in integrated, high-performance electronics, appealing to consumers and industrial clients who demand the best in compact, reliable technology. The potential return on investment (ROI) is significant, driven by improved product appeal and operational efficiencies.\n\n### What's Next?\nThe **Shell of Electronic Device and Wave Filter** paves the way for a new era of electronic design. We can expect to see this technology integrated into a wide range of future products, from ultra-compact medical sensors and advanced automotive control units to the next generation of 5G/6G communication modules. Its adoption will likely accelerate the trend towards 'system-in-package' and 'system-on-chip' designs, where more functionality is packed into smaller footprints. For investors, this represents an opportunity in companies that can successfully license, integrate, or develop products based on this foundational patent, as it addresses a pervasive and growing challenge in the electronics industry.","technical_analysis":"The Shell of Electronic Device and Wave Filter patent (US-9853341) presents a sophisticated approach to electronic device enclosure design, fundamentally altering the traditional role of a protective shell to include active wave filtering capabilities. This technical analysis will dissect its architecture, inferred implementation details, and the performance characteristics it aims to achieve.\n\n**Technical Architecture and Core Components:**\nAt its foundation, this patent describes an electronic device shell constructed around a central 'base'. This base is critical, featuring distinct 'upper lateral' and 'lower lateral' surfaces. This differentiation is key, as it dictates the spatial relationships of other integrated components.\n\nFlanking the upper lateral surface are 'two sidewalls', strategically positioned separately at opposing sides of the base. These sidewalls are designed to be opposite to each other, with each having a surface that faces away from the base. This specific orientation suggests a deliberate effort to create an electromagnetic cavity or a defined path for wave propagation and interaction, potentially forming a resonant structure or a partial waveguide.\n\nIntegral to the wave filtering function are a 'plurality of terminals', which are symmetrically arranged and embedded within the base. The symmetrical arrangement implies a balanced electrical characteristic, crucial for consistent performance and minimizing unwanted signal distortion. Each terminal is further detailed with two distinct sections:\n1.  **Upper Section:** Extends vertically upwards from the upper lateral surface. This portion is likely intended for internal electrical connection, such as interfacing with a printed circuit board (PCB) or other active components within the device.\n2.  **Lower Section:** Extends horizontally outwards from the lower lateral surface. Crucially, at least a portion of this lower section is 'affixed flatly' to the lower lateral surface. This flat adherence is significant; it could serve as a capacitive plate, a ground plane interface, or a part of a transmission line that interacts with the base material or external environment for filtering purposes.\n\n**Inferred Implementation Details and Wave Filtering Principles:**\nWhile the abstract doesn't provide explicit circuit diagrams or material specifications, the structural description allows for strong inferences regarding its wave filtering mechanism. The combination of conductive terminals embedded within a dielectric base, flanked by sidewalls, suggests a distributed filter network. The terminals, with their specific geometries and symmetrical placement, could function as:\n*   **Distributed Inductors and Capacitors:** The vertical upper sections might act as inductive elements, while the flat, horizontally extending lower sections, in conjunction with the base material, could form distributed capacitive elements. This creates an LC ladder network or a resonant tank circuit directly integrated into the shell.\n*   **Electromagnetic Bandgap (EBG) Structures:** The periodic or symmetrical arrangement of the terminals and sidewalls could form an EBG-like structure. EBG structures are known to suppress surface waves and provide frequency-selective reflection/transmission characteristics, effectively acting as a filter.\n*   **Shielding and Grounding:** The embedded terminals and the conductive nature of the shell (or embedded conductive layers within it) would inherently provide enhanced EMI shielding, both for internal noise containment and external interference rejection. The flat lower sections affixed to the base could serve as robust grounding points or contribute to a controlled impedance path.\n\n**Integration Patterns and Performance Characteristics:**\nThis technology advocates for an 'integrated design' philosophy. Instead of adding discrete filters post-design, the Shell of Electronic Device and Wave Filter allows for filtering to be designed into the very foundation of the device enclosure. This approach offers several performance benefits:\n*   **Superior High-Frequency Performance:** By integrating filtering elements directly into the structural path, parasitic inductances and capacitances associated with discrete components and longer traces are minimized, leading to better performance at higher operating frequencies.\n*   **Reduced Form Factor and Weight:** Eliminates the need for separate EMI shields or filter modules, contributing to smaller, thinner, and lighter devices—a critical factor in modern electronics.\n*   **Enhanced Signal Integrity:** A controlled electromagnetic environment within the shell ensures cleaner signal paths, reducing crosstalk and improving the overall reliability of data transmission.\n*   **Manufacturing Efficiency:** Simplifies the bill of materials (BOM) and assembly processes, potentially leading to lower manufacturing costs and faster time-to-market.\n\n**Code-Level Implications:**\nWhile this patent is hardware-centric, its implications for software and firmware development are indirect but significant. A cleaner electromagnetic environment means less noise to compensate for in signal processing, potentially simplifying algorithms for data acquisition, communication protocols, and sensor readings. It could lead to more robust and less error-prone system designs, allowing software engineers to focus on higher-level functionalities rather than battling hardware-induced noise issues.\n\nIn conclusion, the Shell of Electronic Device and Wave Filter is a pivotal innovation that moves beyond passive device protection. By embedding active wave filtering into the core structure of the electronic enclosure, this patent provides a robust, compact, and high-performance solution for managing electromagnetic challenges in an increasingly dense electronic landscape. This approach paves the way for a new era of integrated electronic design, where the shell itself is a key contributor to overall system performance.","business_analysis":"The **Shell of Electronic Device and Wave Filter** patent (US-9853341) represents a significant advancement in electronic device manufacturing, poised to generate substantial business impact by addressing critical industry challenges related to miniaturization, performance, and cost. This innovation transforms a device's passive enclosure into an active, performance-enhancing component, opening new avenues for market differentiation and value creation.\n\n**Market Opportunity Size:**\nThe global market for electronic device enclosures and EMI shielding solutions is vast and growing, driven by the proliferation of smartphones, IoT devices, wearables, automotive electronics, and advanced telecommunications infrastructure (e.g., 5G/6G). As devices become smaller and more complex, the demand for effective and integrated EMI management solutions escalates. The market for integrated components that reduce overall device footprint and enhance performance is projected to be in the tens of billions of dollars annually, with this technology tapping directly into this high-growth segment. The ability to integrate wave filtering directly into the shell offers a compelling value proposition that can capture a significant share of this evolving market.\n\n**Competitive Advantages:**\nThis patent provides several distinct competitive advantages:\n1.  **Miniaturization and Space Efficiency:** By combining structural integrity with wave filtering, the invention eliminates the need for separate, bulky EMI shields or discrete filter components. This allows manufacturers to design significantly thinner, lighter, and more compact devices, a critical differentiator in consumer electronics and specialized markets like medical devices.\n2.  **Cost Reduction:** Consolidating functions into a single, integrated component can lead to a reduced bill of materials (BOM), simplified supply chains, and lower assembly costs. This translates to improved profit margins or the ability to offer more competitively priced products.\n3.  **Enhanced Performance and Reliability:** Integrating filtering at the shell level can provide superior signal integrity, reducing electromagnetic interference and improving overall device performance and reliability. This is a crucial selling point for high-performance applications.\n4.  **Simplified Manufacturing:** Fewer components mean less complex assembly processes, potentially leading to faster production cycles, reduced labor costs, and higher manufacturing yields.\n5.  **Design Flexibility:** Engineers gain greater freedom in internal component placement, as EMI concerns are mitigated by the enclosure itself, rather than by internal shielding components that dictate layout.\n\n**Revenue Potential and Business Models:**\nRevenue generation could stem from several business models:\n*   **Licensing:** The patent holders could license this technology to major electronic device manufacturers (e.g., Apple, Samsung, Huawei, Xiaomi, Qualcomm) for integration into their product lines, generating substantial royalties.\n*   **Component Manufacturing:** A specialized company could manufacture these integrated shells for various OEMs, becoming a key supplier of advanced enclosures.\n*   **Product Development:** Companies could develop and market their own electronic devices leveraging this technology as a core differentiator, particularly in niche markets requiring extreme miniaturization or robust EMI performance.\n*   **Consulting/Design Services:** Offering design and integration services to help companies implement this technology into their next-generation products.\n\n**Strategic Positioning:**\nCompanies adopting this technology can strategically position themselves as innovators in compact, high-performance electronics. It enables a 'design-in' approach to EMI management, moving beyond reactive shielding to proactive signal integrity at the foundational level. This allows for products that are not only smaller and sleeker but also inherently more robust and reliable, appealing to a broad spectrum of consumers and industrial users. This innovation aligns perfectly with industry trends towards greater integration, IoT proliferation, and the demand for seamless user experiences.\n\n**ROI Projections:**\nInvesting in the adoption or licensing of the Shell of Electronic Device and Wave Filter technology promises a strong return on investment. The cost savings from reduced BOM and manufacturing complexity, coupled with the market advantage gained from superior product performance and miniaturization, can lead to increased market share, higher sales volumes, and premium pricing opportunities. For example, a 10-15% reduction in material and assembly costs per unit, combined with a 5-10% increase in market share due to product differentiation, could result in multi-million to multi-billion dollar returns for large-scale manufacturers over the product lifecycle. This patent offers a clear path to both operational efficiency and market leadership.","faqs":[{"answer":"The **Shell of Electronic Device and Wave Filter** (US-9853341) is a patented innovation that redefines the traditional electronic device enclosure. Instead of merely serving as a protective casing, this invention integrates active wave filtering capabilities directly into the shell's structure. It describes a shell comprising a base, two sidewalls, and a plurality of symmetrically arranged terminals embedded within the base.\n\nThis sophisticated design allows the shell itself to manage electromagnetic interference (EMI) and enhance signal integrity, effectively transforming a passive component into an active, performance-critical element. The goal is to create more compact, efficient, and reliable electronic devices by consolidating functions that typically require separate, bulky components.\n\nEssentially, the Shell of Electronic Device and Wave Filter provides a built-in solution for electromagnetic compatibility, making devices smaller, lighter, and more robust against electronic noise.","question":"What is Shell of Electronic Device and Wave Filter?"},{"answer":"The **Shell of Electronic Device and Wave Filter** operates by leveraging a precisely engineered physical structure to interact with electromagnetic waves. The invention's design includes a base with distinct upper and lower surfaces, and two sidewalls strategically positioned on the upper surface. Crucially, a series of symmetrically arranged terminals are embedded within this base.\n\nEach terminal has a unique two-part structure: an upper section extending vertically upwards (likely for internal connections) and a lower section extending horizontally outwards from the bottom surface, with a portion affixed flatly. This intricate geometry and arrangement of conductive terminals within the shell's material create a distributed filter network.\n\nThis network functions by selectively attenuating unwanted electromagnetic frequencies while allowing desired signals to pass through cleanly. It's akin to building a miniature, highly efficient signal processing system directly into the device's physical enclosure, ensuring that electronic chatter is managed at the earliest possible point.","question":"How does Shell of Electronic Device and Wave Filter work?"},{"answer":"The **Shell of Electronic Device and Wave Filter** primarily solves the persistent problem of electromagnetic interference (EMI) and signal integrity degradation in modern, miniaturized electronic devices. As electronic components are packed ever more densely into smaller spaces, they are increasingly susceptible to internal and external electromagnetic noise, which can lead to performance issues, glitches, and reduced reliability.\n\nTraditional solutions for EMI mitigation, such as bulky shielding or discrete filter components, counteract the industry's drive for miniaturization by adding size, weight, and manufacturing complexity. This patent eliminates that trade-off by integrating the filtering function directly into the device's structural shell.\n\nBy doing so, the Shell of Electronic Device and Wave Filter enables the creation of more compact, lighter, and inherently more robust electronic devices without compromising on signal quality or overall performance. It addresses the fundamental conflict between shrinking form factors and the increasing need for electromagnetic compatibility.","question":"What problem does Shell of Electronic Device and Wave Filter solve?"},{"answer":"The inventors of the **Shell of Electronic Device and Wave Filter** (US-9853341) are not specified in the provided patent abstract or data. Patent documents typically list the inventors, but this information was not included in the dataset provided for generating this content. Generally, inventors are the individuals who conceived the inventive idea and contributed to the claims of the patent.\n\nHowever, the assignee, which is the entity to whom the patent rights are typically transferred (e.g., a company), is also not specified in the provided data. The absence of this information here does not diminish the technical merit or potential impact of the Shell of Electronic Device and Wave Filter itself.\n\nFor precise details on the inventors and assignee, one would typically refer to the full patent document available through official patent databases or platforms like patentable.app/patents/US-9853341.","question":"Who invented Shell of Electronic Device and Wave Filter?"},{"answer":"The **Shell of Electronic Device and Wave Filter** offers several significant benefits that can revolutionize electronic device design and manufacturing:\n\n1.  **Miniaturization:** By integrating wave filtering directly into the shell, it eliminates the need for separate, bulky EMI shields or discrete filter components. This frees up crucial internal space, enabling the creation of thinner, lighter, and more compact devices.\n2.  **Enhanced Performance and Reliability:** The integrated filtering ensures cleaner signal paths and reduced electromagnetic interference, leading to more stable operation, faster data transfer, and overall improved device performance and longevity.\n3.  **Cost Reduction:** Consolidating functions into a single component can lead to a reduced bill of materials (BOM), simplified supply chains, and lower manufacturing costs due to streamlined assembly processes.\n4.  **Design Flexibility:** Engineers gain greater freedom in internal component placement and layout, as the shell actively manages EMI rather than relying on internal shielding that can dictate design choices.\n\nThese advantages position the Shell of Electronic Device and Wave Filter as a foundational technology for the next generation of high-performance, compact electronics across various industries.","question":"What are the key benefits of Shell of Electronic Device and Wave Filter?"},{"answer":"The **Shell of Electronic Device and Wave Filter** fundamentally differentiates itself from prior art in EMI mitigation by moving from 'add-on' solutions to 'integrated' functionality. Traditional methods typically involve applying separate components such as metallic shielding cans, EMI gaskets, or discrete ferrite filters to a device or its circuit board. These are external additions to the primary structural enclosure.\n\nIn contrast, this patent transforms the device's shell itself into an active wave filtering component. The base, sidewalls, and strategically embedded terminals of the Shell of Electronic Device and Wave Filter are designed to work synergistically, providing both structural integrity and electromagnetic filtering capabilities simultaneously. This means that instead of a passive enclosure with separate internal filters, the shell *is* the filter.\n\nThis integrated approach leads to superior space efficiency, reduced manufacturing complexity, and often better high-frequency performance by minimizing parasitic effects associated with discrete components. It represents a paradigm shift from reactive EMI suppression to proactive, foundational signal integrity management.","question":"How is Shell of Electronic Device and Wave Filter different from prior art?"},{"answer":"The **Shell of Electronic Device and Wave Filter** has the potential for broad impact across numerous industries that rely on compact, high-performance, and electromagnetically robust electronic devices. Key sectors include:\n\n1.  **Consumer Electronics:** Smartphones, wearables, tablets, and smart home devices can benefit from thinner designs, enhanced signal clarity for wireless communication, and improved battery life.\n2.  **Telecommunications:** 5G and future 6G communication modules, base stations, and network equipment will benefit from integrated EMI solutions at higher frequencies, enabling more efficient and reliable data transmission.\n3.  **Internet of Things (IoT):** Compact IoT sensors and edge devices, often deployed in challenging environments, can achieve greater reliability, extended battery life, and smaller form factors.\n4.  **Automotive:** Advanced Driver-Assistance Systems (ADAS), infotainment systems, and vehicle control units can leverage this technology for improved signal integrity and reduced interference in complex electronic environments.\n5.  **Medical Devices:** Miniaturized medical implants, portable diagnostic equipment, and wearable health monitors demand high precision and reliability, which this innovation can significantly enhance.\n\nEssentially, any industry where space, weight, performance, and electromagnetic compatibility are critical design considerations stands to gain from the adoption of the Shell of Electronic Device and Wave Filter.","question":"What industries will Shell of Electronic Device and Wave Filter impact?"},{"answer":"The **Shell of Electronic Device and Wave Filter** patent, identified as US-9853341, was filed on **June 3, 2015**. This is the date when the patent application was officially submitted to the patent office.\n\nThe patent was subsequently published, and the grant date (or publication date for granted patents) was **December 26, 2017**. This marks the date when the patent rights were officially granted, making the innovation legally protected.\n\nUnderstanding these dates is important for assessing the patent's lifecycle, prior art considerations, and its potential market relevance. The period between filing and grant indicates the time taken for examination and approval by the patent authorities.","question":"When was Shell of Electronic Device and Wave Filter filed/granted?"},{"answer":"The commercial applications of the **Shell of Electronic Device and Wave Filter** are extensive, driven by its ability to create smaller, more reliable, and cost-effective electronic devices. Some key commercial applications include:\n\n1.  **Next-Generation Mobile Devices:** Enabling thinner, lighter smartphones, tablets, and smartwatches with superior wireless performance and extended battery life.\n2.  **High-Performance IoT Modules:** Developing more compact and robust sensors and communication modules for smart homes, industrial automation, and smart city infrastructure.\n3.  **Advanced Medical Wearables and Implants:** Creating smaller, more accurate, and less intrusive medical devices where signal integrity is critical for patient safety and data reliability.\n4.  **Automotive Electronics:** Enhancing the reliability of in-car communication systems, radar, and lidar sensors crucial for autonomous driving and safety features.\n5.  **Telecommunications Infrastructure:** Improving the performance and compactness of 5G/6G base station components and wireless access points.\n\nBy licensing this technology, manufacturers can gain a significant competitive edge, reduce their bill of materials, streamline production, and offer products that meet the growing demand for highly integrated and electromagnetically compliant electronics.","question":"What are the commercial applications of Shell of Electronic Device and Wave Filter?"},{"answer":"The **Shell of Electronic Device and Wave Filter** lays a foundational blueprint for future advancements in integrated electronics. Expected future developments could include:\n\n1.  **Dynamic Filtering Capabilities:** Future iterations might incorporate materials or designs that allow for tunable or reconfigurable wave filtering, adapting to different frequency bands or environmental conditions in real-time.\n2.  **Integration of Additional Functions:** Beyond wave filtering, the shell could evolve to integrate other functionalities such as embedded antennas, thermal management elements, energy harvesting capabilities, or even active sensor arrays, pushing towards truly multi-functional structural components.\n3.  **Advanced Material Science:** Research into novel composite materials, metamaterials, or smart polymers could further enhance the filtering efficiency, reduce weight, and improve durability of the Shell of Electronic Device and Wave Filter.\n4.  **AI-Driven Design and Optimization:** Artificial intelligence and machine learning algorithms could be employed to rapidly design and optimize the complex geometries and material compositions required for highly specific filtering characteristics, accelerating product development.\n5.  **Broader Ecosystem Integration:** The technology could become a standard building block within larger 'system-on-structure' or 'system-in-package' initiatives, where entire electronic sub-systems are integrated directly into the device's physical casing.\n\nThese developments promise to further blur the lines between passive structure and active electronic component, ushering in an era of highly intelligent and efficient electronic devices built upon the principles introduced by the Shell of Electronic Device and Wave Filter.","question":"What are the future developments expected for Shell of Electronic Device and Wave Filter?"}],"topics":["shell of electronic device and wave filter","wave filter patent","electronic device enclosure","signal integrity","EMI shielding","relentless","drive","towards"],"tech_cluster":null},"seo":{"title":"Shell of Electronic Device and Wave Filter - Patent US-9853341","description":"Discover the Shell of Electronic Device and Wave Filter patent: an innovative design integrating wave filtering into device shells for compact, high-performance electronics. Full analysis here.","keywords":["shell of electronic device and wave filter","wave filter patent","electronic device enclosure","signal integrity","EMI shielding","device miniaturization","integrated design","US-9853341","patent analysis","tech innovation","electronics manufacturing","compact devices"]},"attribution":{"source":"Patentable","source_url":"https://patentable.app","canonical_url":"https://patentable.app/patents/US-9853341","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-9853341","citation_suggestion":"Patentable. \"Shell of electronic device and wave filter\" (US-9853341). https://patentable.app/patents/US-9853341","copyright_holder":"Nomic Interactive Technology LLC"},"links":{"html":"https://patentable.app/patents/US-9853341","json":"https://patentable.app/api/llm-context/US-9853341","site":"https://patentable.app","llms_txt":"https://patentable.app/llms.txt"},"generated_at":"2026-06-06T07:14:22.518Z"}