{"schema_version":"1.0","canonical_url":"https://patentable.app/patents/US-9852650","patent":{"patent_number":"US-9852650","title":"Simulation device","assignee":null,"inventors":[],"filing_date":"2015-07-02T00:00:00.000Z","publication_date":"2017-12-26T00:00:00.000Z","cpc_codes":["G09B","G09B"],"num_claims":11,"abstract":"A simulator device, comprising several components, in combination. There is an outer frame and an inner frame. The inner frame moves relative to the outer frame. The inner frame has two bevels which ride on two rollers to prevent cantilever of the inner frame. The bevels also provide a lifting of one end of the inner frame. There is an arcuate plate, which allows hydraulic rocking of a seat to about a six degree forward tilt or rearward tilt."},"analysis":{"summary":"The **Simulation Device** patent (US-9852650) introduces a groundbreaking simulator designed to deliver superior stability and dynamic realism. At its core, this innovation features an intricate mechanical assembly comprising an outer frame and an inner frame, where the inner frame is engineered for precise movement relative to the outer. The most significant technical advancement lies in the inner frame's integration of two bevels, which are strategically positioned to ride on two corresponding rollers. This clever design serves a dual purpose: it actively and effectively prevents the inner frame from experiencing cantilever effects, thereby ensuring remarkable stability during operation, and it also facilitates a controlled lifting of one end of the inner frame, contributing to the device's dynamic capabilities.\n\nFurther enhancing the immersive experience, the Simulation Device incorporates an arcuate plate. This component works in conjunction with a hydraulic system to enable a smooth, controlled rocking motion of the seat. Users can experience an approximate six-degree forward or rearward tilt, meticulously replicating sensations of acceleration, deceleration, or gradient changes. This precise tilting capability, combined with the inherent stability provided by the frame and roller system, allows for a highly realistic and engaging simulation experience.\n\nThis technology solves the critical problem of balancing dynamic motion with structural integrity in simulator design. By preventing cantilever and providing controlled, smooth tilt, the Simulation Device offers a safer, more realistic, and more reliable platform than many existing solutions. Its technical approach reduces the risk of instability and enhances the fidelity of simulated environments.\n\nFrom a business perspective, this invention opens significant market opportunities in professional training (e.g., flight, driving, heavy equipment), high-end entertainment (e.g., theme park rides, advanced VR arcades), and potentially even consumer-grade immersive experiences. The enhanced realism and safety provide a strong competitive advantage, promising improved user satisfaction and training effectiveness. This patent positions its assignee to capture a substantial share of the growing market for high-fidelity motion simulation systems.","layman_explanation":"## What Problem Does This Solve?\n\nImagine you're trying to learn to fly a plane, drive a high-performance race car, or even operate heavy construction equipment. To do this safely and effectively, you need a simulator that feels incredibly real. The big problem with many existing simulators is that they struggle to provide both realistic, dynamic movement (like feeling acceleration or tilting into a turn) and rock-solid stability at the same time. Often, they can feel wobbly, unstable, or even jarring, especially when moving aggressively. This 'wobble' is often due to parts of the simulator extending without full support, a technical issue called 'cantilever.' This not only breaks the illusion of reality but can also be uncomfortable or even unsafe, hindering effective training or enjoyment. Existing solutions are often either too expensive, too complex, or still fall short on delivering a truly seamless and stable experience.\n\n## How Does It Work?\n\nThe **Simulation Device** patent introduces a clever mechanical solution to this challenge. Think of it like a sophisticated sliding puzzle for motion. It has two main parts: an outer frame, which is the steady base, and an inner frame, where you'd sit. The genius lies in how the inner frame moves. It's not just sliding around; it has special 'ramps' on its underside (we call them bevels) that glide perfectly along 'wheels' (rollers) on the outer frame. This unique 'ramp-on-wheel' system does two very important things:\n\nFirst, it *always* keeps the inner frame fully supported. So, no matter how much it moves, it can't wobble or feel unsupported – it's like a train staying perfectly on its tracks, eliminating that 'cantilever' problem. This ensures incredible stability.\n\nSecond, the shape of these 'ramps' also helps one end of the inner frame to lift slightly as it moves. This controlled lifting, combined with another special 'curvy plate' and a hydraulic system (like a powerful, smooth piston), allows the entire seat to gently rock forward or backward by about six degrees. This rocking motion is incredibly smooth and precise, perfectly mimicking the sensation of accelerating, braking, or going up and down a hill. It's all about making the simulated experience feel as natural and believable as possible, without any distracting instability.\n\n## Why Does This Matter?\n\nThis innovation matters because it fundamentally improves the quality of simulated experiences across a wide range of industries. For professional training – like pilots, truck drivers, or crane operators – the enhanced realism and unwavering stability mean more effective and safer practice. Trainees can develop muscle memory and reactions in an environment that truly mimics real-world conditions, leading to better-prepared professionals and reduced real-world accidents. In the entertainment sector, imagine theme park rides, advanced virtual reality arcades, or even high-end home gaming setups that offer an unparalleled sense of immersion. The elimination of wobble and the introduction of precise, smooth tilt will make these experiences far more convincing and enjoyable. From a business perspective, companies adopting this patented technology can offer a superior product, gaining a significant competitive edge and potentially commanding premium pricing. It's a technology that promises higher user satisfaction, better training outcomes, and new avenues for immersive entertainment, driving market growth and innovation.\n\n## What's Next?\n\nThe **Simulation Device** technology is poised to become a foundational component for next-generation motion platforms. We can expect to see its principles integrated into more compact and versatile simulators, potentially democratizing access to high-fidelity motion. Future applications might include advanced haptic feedback systems, interactive virtual environments for rehabilitation, or even personal, home-based simulators that deliver professional-grade realism. As the demand for immersive experiences continues to grow, this innovation provides a robust and elegant solution that could accelerate market adoption and investment in simulation technologies, paving the way for even more sophisticated and believable virtual worlds.","technical_analysis":"The **Simulation Device** patent (US-9852650) details a sophisticated mechanical system engineered to overcome fundamental challenges in motion simulator design, primarily focusing on stability and dynamic realism. The technical architecture is built around a robust dual-frame configuration and an innovative motion-control mechanism.\n\n**Technical Architecture and Components:**\n\nThe system comprises two primary structural elements: an **outer frame** and an **inner frame**. The outer frame provides the stationary base or the larger supporting structure. The inner frame is the component designed for dynamic movement, typically carrying the user's seat and associated controls. The interaction between these two frames is the cornerstone of this innovation.\n\n1.  **Inner and Outer Frame System:** The inner frame is configured to move linearly or curvilinearly relative to the outer frame. This relative motion is precisely guided and controlled to ensure smooth operation.\n\n2.  **Bevels and Rollers:** The most critical technical innovation lies in the integration of **two bevels** on the inner frame and **two corresponding rollers** on the outer frame. These are not merely frictional contact points but are geometrically designed to perform specific functions:\n    *   **Cantilever Prevention:** As the inner frame moves, the bevels continuously ride on the rollers. The angular relationship and contact points between the bevels and rollers are engineered such that the inner frame is always supported, effectively distributing loads and eliminating the bending moments associated with cantilevered structures. This inherent stability mechanism is a significant departure from systems that rely on external bracing or complex counterweights, which can add mass and latency.\n    *   **Controlled Vertical Lift:** The specific profile of the bevels and their interaction with the rollers also facilitates a controlled vertical displacement. As the inner frame translates, the geometry of the bevel-roller interface causes one end of the inner frame to lift predictably. This mechanical advantage is strategically utilized to contribute to the overall motion profile, specifically complementing the tilting mechanism by providing a vertical component of motion.\n\n3.  **Arcuate Plate and Hydraulic System:** Further enhancing the dynamic capabilities is an **arcuate plate**. This plate is mechanically linked to the seat and is actuated by a hydraulic system. Hydraulics are chosen for their ability to provide high force, precise control, and smooth, continuous motion. The arcuate shape ensures a consistent pivot point for the seat's rocking motion, allowing for a controlled tilt of approximately six degrees forward or rearward. This range is crucial for replicating subtle yet impactful sensations of acceleration, deceleration, and pitch changes.\n\n**Implementation Details and Performance Characteristics:**\n\nThe implementation of this design implies a carefully calibrated system where the geometry of the bevels, the diameter and placement of the rollers, and the force/stroke characteristics of the hydraulic actuator are harmonized. The materials used for the bevels and rollers would need to be durable, low-friction, and wear-resistant to ensure longevity and smooth operation. Precision machining would be essential for the bevels to ensure consistent contact and movement without binding.\n\nPerformance-wise, the Simulation Device is designed to offer:\n*   **High Stability:** The active cantilever prevention mechanism ensures a stable platform even during rapid and dynamic movements, reducing unwanted oscillations or jarring.\n*   **Smooth Motion:** The hydraulic actuation combined with the guided roller system provides fluid and realistic motion profiles.\n*   **Responsive Control:** Hydraulic systems are inherently responsive, allowing for quick and accurate replication of simulated forces.\n*   **Reduced Complexity (relative to multi-axis systems):** By integrating stability into the core movement mechanism, the overall mechanical complexity could be reduced compared to traditional multi-DOF platforms that require extensive bracing or complex linkages.\n\n**Code-Level Implications and Integration Patterns:**\n\nFor control engineers, the predictable mechanical behavior of this system simplifies the control algorithms. The primary control loop would focus on translating desired simulated forces and movements into precise hydraulic actuator commands and inner frame positions. Sensors (e.g., encoders for frame position, accelerometers for tilt feedback) would provide real-time data to a central processing unit, which would then drive the hydraulic pump and valving system. Integration with external simulation software (e.g., flight simulators, racing games, VR engines) would involve standard API calls to translate virtual environment physics into physical motion commands for the Simulation Device. The inherent stability also means less computational overhead for compensation algorithms, allowing for more focus on fidelity.","business_analysis":"The **Simulation Device** patent (US-9852650) represents a significant advancement in motion simulation technology, poised to create substantial business value across multiple sectors. Its core innovation — achieving both high dynamic fidelity and inherent stability through a novel mechanical design — positions it uniquely in a market hungry for more realistic and reliable immersive experiences.\n\n**Market Opportunity Size:** The global market for simulation and training is vast and expanding, driven by demand from defense, aerospace, automotive, healthcare, and entertainment industries. The professional simulator market alone is projected to reach billions of dollars, while the consumer-grade VR and entertainment segment is experiencing explosive growth. The Simulation Device's ability to offer superior stability and dynamic range within a potentially more compact and efficient design positions it to capture a significant share of both high-end professional and mass-market entertainment segments. Its cost-effectiveness and enhanced realism could open up new applications where current solutions are either too expensive or technically inadequate.\n\n**Competitive Advantages:**\n1.  **Unparalleled Stability:** The active cantilever prevention mechanism is a key differentiator. Many existing motion platforms, especially those with high degrees of freedom, struggle with inherent instability or require complex, heavy, and expensive counter-measures. The Simulation Device's integrated solution offers a smoother, safer, and more realistic experience.\n2.  **Enhanced Realism:** The precise six-degree hydraulic tilt, combined with the stable frame movement, allows for a more accurate replication of real-world forces (acceleration, deceleration, pitch). This fidelity is crucial for effective training and deeply immersive entertainment.\n3.  **Reduced Footprint and Complexity (Potential):** By integrating stability into the core frame mechanism, the design could potentially lead to more compact and less mechanically complex systems, reducing manufacturing costs, maintenance, and space requirements.\n4.  **Safety:** Inherently stable operation reduces risks associated with simulator malfunctions or erratic movements, making it more appealing for high-liability applications.\n\n**Revenue Potential and Business Models:** This patented technology could generate revenue through various models:\n*   **Direct Licensing:** Licensing the patent to established simulator manufacturers for integration into their product lines.\n*   **Product Development:** Developing and manufacturing proprietary Simulation Device-powered simulators for specific niches (e.g., flight schools, advanced VR arcades, medical training facilities).\n*   **Component Sales:** Manufacturing and selling the core mechanical sub-assembly (inner/outer frame with bevels/rollers, arcuate plate) to other OEMs.\n*   **Service & Maintenance:** Offering specialized maintenance and support services for systems utilizing the technology.\n*   **Franchising/Experience Centers:** Creating branded immersive experience centers that leverage the superior realism of the Simulation Device.\n\n**Strategic Positioning:** The Simulation Device can be strategically positioned as the 'gold standard' for stable, high-fidelity motion. It can target markets where realism and safety are paramount (e.g., defense, aviation, medical) and also disrupt the high-end entertainment market by offering a superior user experience. Its unique mechanical advantage provides a strong barrier to entry for competitors attempting to replicate its combination of stability and dynamic range.\n\n**ROI Projections:** Investment in developing and commercializing products based on this patent could yield substantial returns. The enhanced features and competitive advantages would allow for premium pricing in professional markets, while efficiency gains could enable competitive pricing in broader consumer markets. The broad applicability across industries ensures a diverse revenue stream and reduces reliance on a single sector. Early adoption by key industry players could rapidly establish market dominance, leading to significant long-term ROI through licensing fees and product sales.","faqs":[{"answer":"The **Simulation Device** patent (US-9852650) describes a novel simulator device designed to provide highly stable and dynamically realistic motion. At its core, it features a unique mechanical assembly comprising an outer frame and an inner frame. The inner frame is engineered to move precisely relative to the outer frame.\n\nThe key innovation of this technology lies in the integration of two bevels on the inner frame. These bevels are strategically positioned to ride on two corresponding rollers. This clever interaction serves a dual purpose: it actively prevents the inner frame from experiencing undesirable cantilever effects, thereby ensuring remarkable stability during operation, and it also facilitates a controlled lifting of one end of the inner frame.\n\nFurthermore, the Simulation Device incorporates an arcuate plate, which works in conjunction with a hydraulic system. This allows the seat to execute a smooth rocking motion, providing approximately a six-degree forward or rearward tilt. This precise tilting capability, combined with the inherent stability of the frame and roller system, enables a highly realistic and immersive simulation experience, solving critical challenges in balancing dynamic motion with structural integrity.","question":"What is the Simulation Device patent (US-9852650)?"},{"answer":"The **Simulation Device** employs an ingenious mechanical mechanism to actively prevent instability, specifically addressing the common problem of cantilever. The invention features an inner frame that moves within an outer frame. On the inner frame, there are two precisely designed bevels. These bevels are not just passive supports; they are engineered to continuously ride on two corresponding rollers that are fixed to the outer frame.\n\nThis continuous interaction between the bevels and rollers ensures that the inner frame is always fully supported along its path of travel. By maintaining constant contact and distributing the load evenly, the system effectively eliminates the bending moments that typically cause parts of a moving structure to 'cantilever' or wobble. This inherent mechanical stability is a fundamental aspect of the Simulation Device, distinguishing it from systems that rely on external bracing or complex software compensation to mitigate instability. The result is a simulator that remains rock-solid even during dynamic movements, enhancing both safety and realism.","question":"How does the Simulation Device work to prevent instability?"},{"answer":"The **Simulation Device** patent primarily solves the long-standing problem of reconciling dynamic, realistic motion with inherent structural stability in simulator design. Traditional motion platforms often face a trade-off: achieving a wide range of motion can introduce instability, such as 'cantilever' effects, where unsupported parts of the system wobble or vibrate. Conversely, highly stable systems often provide limited dynamic movement, reducing the realism of the simulation.\n\nThis technology overcomes this paradox by integrating a unique bevel-and-roller system that actively prevents cantilever, ensuring continuous support for the inner frame even during movement. This means the Simulation Device can deliver dynamic, precise motion (like its six-degree hydraulic tilt) without compromising on stability. It eliminates the jarring, unrealistic movements that can break immersion, cause discomfort, or reduce the effectiveness of training, thereby improving the overall fidelity, safety, and user experience of simulated environments. Keywords: motion simulation problem, stability, cantilever, dynamic realism, simulator challenges.","question":"What problem does the Simulation Device solve in motion simulation?"},{"answer":"The patent for the **Simulation Device** (US-9852650) was filed on **July 2, 2015**, and subsequently published on **December 26, 2017**. While the patent abstract does not list specific inventors or an assignee, the filing and publication dates mark key milestones in the intellectual property protection of this innovative motion simulation technology. The development of such a sophisticated mechanical system typically involves a team of engineers and designers specializing in kinematics, hydraulics, and structural mechanics.\n\nThe absence of publicly listed inventors or an assignee in the provided abstract is not uncommon for early-stage patent data or specific database representations. However, the official patent document, US-9852650, would contain these details. The timely filing and publication demonstrate a commitment to protecting the unique design principles and functional aspects of the Simulation Device, paving the way for its potential commercialization and integration into various industries seeking advanced simulation solutions. Keywords: Simulation Device inventors, patent filing date, publication date, US-9852650 history.","question":"Who invented the Simulation Device and when was it filed/published?"},{"answer":"The **Simulation Device** offers several key benefits and features that set it apart in the field of motion simulation:\n\n1.  **Unparalleled Stability:** Its most significant benefit is the active prevention of cantilever effects through an innovative bevel-and-roller system. This ensures the inner frame remains continuously supported, eliminating wobble and vibrations, leading to a much more stable and predictable experience.\n2.  **Dynamic and Precise Tilt:** The device incorporates an arcuate plate with a hydraulic system that allows for a smooth, controlled six-degree forward or rearward tilt of the seat. This precision is crucial for accurately replicating sensations of acceleration, deceleration, and pitch changes, significantly enhancing realism.\n3.  **Enhanced Immersion:** By combining rock-solid stability with fluid, accurate motion, the Simulation Device creates a highly immersive experience, reducing simulator sickness and increasing user engagement.\n4.  **Improved Safety:** The inherent stability and controlled movements reduce mechanical stress and the risk of unexpected or jarring motions, making the device safer for users and more reliable in operation.\n5.  **Potential for Reduced Complexity:** The integrated approach to stability may allow for a simpler mechanical design compared to multi-axis systems that require extensive external bracing or complex linkages. Keywords: Simulation Device benefits, key features, stability, dynamic tilt, immersion, safety, US-9852650 advantages.","question":"What are the key benefits and features of the Simulation Device?"},{"answer":"The **Simulation Device** differentiates itself from prior art motion simulators primarily through its innovative approach to achieving stability and dynamic motion simultaneously. Many traditional simulators, especially those with multiple degrees of freedom (DOF), often struggle with a fundamental trade-off: increased dynamic range can lead to instability, particularly cantilever effects, where unsupported components cause wobbling or jarring movements. Prior art often attempts to mitigate this with heavy structures, complex linkages, or active damping systems, which add cost, complexity, and maintenance.\n\nIn contrast, the Simulation Device's unique bevel-and-roller system *actively prevents* cantilever from occurring in the first place. The inner frame is continuously supported, providing inherent, rock-solid stability without the need for extensive external compensation. Furthermore, its integrated hydraulic tilt mechanism, utilizing an arcuate plate, delivers a precise and smooth six-degree tilt, offering a level of dynamic realism that is seamlessly integrated with its unparalleled stability. This integrated design offers a more elegant, potentially more compact, and fundamentally more stable platform compared to many existing complex or limited-motion solutions. Keywords: Simulation Device differentiation, prior art comparison, cantilever prevention, hydraulic tilt, simulator innovation, US-985650 unique.","question":"How is the Simulation Device different from prior art motion simulators?"},{"answer":"The **Simulation Device** patent (US-9852650) is poised to significantly impact a wide array of industries that rely on high-fidelity motion simulation. Its unique combination of unwavering stability and precise dynamic tilt makes it suitable for diverse applications:\n\n1.  **Aerospace and Defense:** For pilot training, flight simulation, and military vehicle operation, the enhanced realism and safety are paramount. The device's stability will lead to more effective and accurate training scenarios.\n2.  **Automotive:** Driver training, autonomous vehicle development, and racing simulation will benefit from precise replication of vehicle dynamics, acceleration, and braking forces.\n3.  **Heavy Equipment Operation:** Training for construction, mining, and agricultural machinery can be made safer and more effective by accurately simulating heavy loads and terrain changes.\n4.  **Entertainment and Virtual Reality (VR):** Theme park rides, advanced VR arcades, and immersive gaming experiences will achieve new levels of realism and immersion, free from distracting instabilities.\n5.  **Healthcare and Medical Training:** Potential applications include surgical simulation, rehabilitation devices, and systems for studying human balance and motion perception, where precision and stability are critical. Keywords: Simulation Device industries, impact, aerospace, automotive, entertainment, VR, training, US-9852650 applications.","question":"What industries will the Simulation Device patent impact?"},{"answer":"The commercial applications of the **Simulation Device** are extensive, driven by its ability to deliver superior stability and dynamic realism in motion simulation. This patented technology can be utilized in various commercial products and services:\n\n1.  **Professional Training Simulators:** Manufacturers can integrate the Simulation Device into high-end simulators for pilots, military personnel, heavy machinery operators, and truck drivers, offering a premium training experience with enhanced safety and effectiveness.\n2.  **Immersive Entertainment Systems:** Theme parks can develop more thrilling and realistic motion rides. VR arcade operators can offer cutting-edge experiences where users feel every movement with unparalleled fidelity. The technology could also enable advanced home simulation setups for serious enthusiasts.\n3.  **Research and Development Platforms:** Academic institutions and R&D departments in various industries can use the Simulation Device as a robust platform for studying human-machine interaction, motion sickness, and new simulation paradigms.\n4.  **Product Prototyping and Testing:** Automotive and aerospace companies could use the device for early-stage physical prototyping and testing of vehicle dynamics in a controlled, realistic environment. Keywords: Simulation Device commercial applications, training, entertainment, VR, research, product development, US-9852650 commercial.","question":"What are the commercial applications of the Simulation Device?"},{"answer":"The **Simulation Device** patent provides a robust foundation for numerous future developments in motion simulation technology. Building upon its core innovation of integrated stability and precise tilt, we can anticipate several evolutionary paths:\n\n1.  **Expanded Degrees of Freedom:** While the current patent focuses on a critical tilting mechanism and cantilever prevention, future iterations could integrate additional degrees of freedom (e.g., yaw, heave, surge) while maintaining the inherent stability of the bevel-and-roller system. This would create even more comprehensive motion platforms.\n2.  **Miniaturization and Scalability:** The principles of the Simulation Device could be scaled down for more compact, personal simulators for home use or scaled up for very large, high-payload professional systems, adapting to diverse market needs.\n3.  **Integration with Advanced Haptics and VR:** Expect seamless integration with cutting-edge haptic feedback systems, advanced virtual reality headsets, and augmented reality overlays, creating truly multi-sensory and hyper-realistic immersive environments.\n4.  **Adaptive Control Systems:** Future developments may include AI-driven adaptive control systems that can dynamically adjust the motion profile based on user input, physiological responses, or specific training scenarios, further enhancing realism and personalization. Keywords: Simulation Device future, developments, degrees of freedom, scalability, haptics, VR integration, adaptive control, US-9852650 future.","question":"What are the future developments expected for the Simulation Device?"},{"answer":"Yes, the **Simulation Device** holds significant potential for consumer-grade virtual reality (VR) experiences, particularly at the higher end of the market. While the initial applications might target professional training or commercial entertainment centers due to its advanced engineering, the core benefits of this technology are highly desirable for consumers.\n\nThe device's ability to provide unparalleled stability and a precise six-degree forward or rearward hydraulic tilt would dramatically enhance the immersion and realism of home VR setups. Imagine feeling the subtle G-forces in a racing game or the pitch of a virtual rollercoaster without any distracting wobbles or jerky movements. This level of physical feedback can significantly reduce simulator sickness, a common issue in VR, and make the virtual world feel far more convincing.\n\nAs manufacturing processes evolve and costs potentially decrease, the principles behind the Simulation Device could be adapted for more accessible consumer products, creating a new benchmark for home-based immersive gaming and entertainment. It represents a pathway to bringing professional-grade motion realism into the consumer market. Keywords: Simulation Device consumer VR, home VR, virtual reality experiences, immersive gaming, motion sickness, US-9852650 consumer.","question":"Can the Simulation Device be used for consumer-grade virtual reality experiences?"}],"topics":["simulation device","motion simulator","patent US-9852650","cantilever prevention","hydraulic tilt","technical","background","unresolved"],"tech_cluster":null},"seo":{"title":"Simulation Device - Advanced Motion Simulator Patent US-9852650","description":"Discover the Simulation Device patent (US-9852650): a revolutionary motion simulator preventing cantilever with dynamic 6-degree hydraulic tilt. Enhance realism and stability.","keywords":["simulation device","motion simulator","patent US-9852650","cantilever prevention","hydraulic tilt","immersive technology","training simulator","virtual reality motion","simulator stability","dynamic motion platform","patent analysis","mechanical design","simulation innovation","US-9852650"]},"attribution":{"source":"Patentable","source_url":"https://patentable.app","canonical_url":"https://patentable.app/patents/US-9852650","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-9852650","citation_suggestion":"Patentable. \"Simulation device\" (US-9852650). https://patentable.app/patents/US-9852650","copyright_holder":"Nomic Interactive Technology LLC"},"links":{"html":"https://patentable.app/patents/US-9852650","json":"https://patentable.app/api/llm-context/US-9852650","site":"https://patentable.app","llms_txt":"https://patentable.app/llms.txt"},"generated_at":"2026-06-06T06:36:52.304Z"}