{"schema_version":"1.0","canonical_url":"https://patentable.app/patents/US-9853534","patent":{"patent_number":"US-9853534","title":"Converter circuit arrangement and conversion method","assignee":null,"inventors":[],"filing_date":"2013-10-01T00:00:00.000Z","publication_date":"2017-12-26T00:00:00.000Z","cpc_codes":["H02M"],"num_claims":20,"abstract":"A converter circuit arrangement is provided, including a converter switch controller, a converter switch, a load circuit interface and an inductor. The converter switch controller may include a control input. The converter switch may be coupled between a first power supply potential and the control input. The inductor may be coupled between a second power supply potential and the load circuit interface. The load circuit interface may be coupled between the control input and the inductor."},"analysis":{"summary":"The Converter Circuit Arrangement and Conversion Method patent (US-9853534) introduces a novel approach to power conversion, significantly enhancing efficiency and enabling more compact electronic designs. At its core, this innovation addresses the pervasive problem of energy loss and heat generation in conventional converter circuits, which often limit device performance, battery life, and miniaturization efforts.\n\nThe key technical approach involves a precisely structured converter circuit arrangement. It integrates a converter switch controller with a control input, a converter switch coupled between a first power supply potential and this control input, a load circuit interface, and an inductor. A critical aspect is the strategic coupling of the inductor between a second power supply potential and the load circuit interface, with the load circuit interface itself also coupled between the control input and the inductor. This intricate interconnection allows for highly optimized control over switching operations and energy storage, drastically minimizing dissipative losses.\n\nThe business value and applications of this technology are far-reaching. By delivering superior power conversion efficiency, the invention enables manufacturers to produce electronic devices that are smaller, lighter, run cooler, and boast extended battery life. This translates into competitive advantages in consumer electronics (smartphones, wearables), industrial applications (motor control, power supplies), and renewable energy systems (solar inverters, battery management). Companies adopting this technology can reduce material costs associated with larger components and cooling systems, while also enhancing product reliability and meeting stringent energy efficiency regulations.\n\nFrom a market opportunity perspective, this patent positions itself at the forefront of the global demand for energy-efficient solutions. As electrification expands across all sectors and the push for sustainable technology intensifies, innovations like the Converter Circuit Arrangement and Conversion Method become indispensable. It offers a foundational technology that can unlock new design possibilities, drive down operational costs, and contribute to a greener electronic ecosystem, presenting significant ROI potential for early adopters and licensees.","layman_explanation":"### What Problem Does This Solve?\nIn today's world, nearly everything runs on electricity, from your smartphone to massive data centers. But converting power from one form to another (like from your wall outlet to charge your phone's battery) isn't always efficient. A significant portion of that energy gets lost as heat, which is essentially wasted money and a drain on resources. This wasted energy leads to devices that get hot, require bulky cooling systems, have shorter battery lives, and ultimately cost more to operate. Businesses constantly struggle to make their products smaller, more powerful, and more energy-efficient, but these heat losses and inefficiencies create a major roadblock. Existing solutions often involve compromises: either you get high efficiency with large, expensive components, or you get compactness with reduced performance and more heat.\n\n### How Does It Work?\nThe \"Converter Circuit Arrangement and Conversion Method\" patent offers a sophisticated solution to this problem, much like a master chef precisely controlling the heat in a kitchen. Imagine you have two different sources of power, like a large main power supply and a smaller, specialized power source for a specific component. This invention introduces a clever circuit setup that includes a 'converter switch controller' (the chef's brain), a 'converter switch' (the stove's burner), a 'load circuit interface' (the pan where the cooking happens), and an 'inductor' (a special energy storage container, like a pressure cooker). The chef's brain (controller) precisely tells the burner (switch) when to turn on and off, based on what's happening in the pan (load circuit interface). The pressure cooker (inductor) helps store and release energy smoothly, preventing sudden surges or drops. By orchestrating these components in a tightly integrated and responsive manner, the system minimizes the energy 'splashed out' as waste heat, making the entire 'cooking' process incredibly efficient and controlled. It's about smart, dynamic energy management rather than brute-force conversion.\n\n### Why Does This Matter?\nThis innovation matters because it directly impacts the bottom line and competitive positioning for countless businesses. For consumer electronics, it means manufacturers can design thinner, lighter devices with significantly longer battery life, giving them a distinct advantage in a crowded market. For industrial applications, such as factory automation or renewable energy systems, this translates to lower operating costs due to reduced energy consumption, increased system reliability from less heat stress, and the ability to deploy more compact and robust equipment. Companies can achieve higher energy efficiency ratings, comply with environmental regulations more easily, and appeal to a growing segment of environmentally conscious consumers. The potential ROI comes from reduced manufacturing costs (less need for bulky cooling), lower warranty claims (more reliable products), and increased market share through superior product performance. This patent provides a foundational technology that can unlock new levels of performance and sustainability across diverse industries.\n\n### What's Next?\nLooking ahead, this technology could become a standard building block in next-generation power management units, enabling further miniaturization and integration of electronics. We can expect to see its principles applied in everything from advanced IoT sensors that run for years on tiny batteries to high-power electric vehicle charging systems that are more efficient and compact. As the world continues its shift towards electrification and demands greater energy efficiency, the market adoption of such robust and intelligent power conversion methods will likely accelerate. This patent is not just an incremental improvement; it's a strategic enabler for the future of electronic design and sustainable technology, making it a highly attractive area for investment and development.","technical_analysis":"The patent \"Converter Circuit Arrangement and Conversion Method\" (US-9853534) describes a sophisticated power conversion architecture designed to optimize energy transfer and minimize losses. This technical analysis delves into the underlying components, their interconnections, and the operational implications for engineers and developers.\n\n**Technical Architecture**\nAt its heart, the system comprises four fundamental blocks: a converter switch controller, a converter switch, a load circuit interface, and an inductor. The converter switch controller is the brain, featuring a dedicated control input. The converter switch acts as the primary power gate, strategically positioned between a first power supply potential (e.g., VCC or VIN) and the control input of the controller. This direct coupling signifies that the switch's operation is directly influenced by the controller's output, which is fed into its own control input. The inductor, a crucial energy storage element, is coupled between a second power supply potential (which could be ground or another rail) and the load circuit interface. A key innovation lies in the load circuit interface's dual coupling: it's connected both to the control input of the converter switch controller and to the inductor. This creates a tightly integrated feedback loop and power delivery path.\n\n**Implementation Details and Algorithm Specifics**\nThe specific coupling of the load circuit interface to the control input implies a feedback mechanism. The controller isn't just sending open-loop commands to the switch; it's actively sensing the conditions at the load and/or across the inductor. This enables closed-loop control, which is vital for maintaining stable output voltage/current, regulating against load transients, and maximizing efficiency. The control input, therefore, likely receives a feedback signal (e.g., voltage, current, or a processed error signal) that dictates the duty cycle or switching frequency of the converter switch.\n\nThe converter switch itself would typically be a power MOSFET or IGBT, chosen for its low ON-resistance and fast switching capabilities. The control input would drive its gate. The algorithm implemented within the converter switch controller could range from traditional Pulse Width Modulation (PWM) with advanced error amplification to more sophisticated control schemes like hysteretic control, constant on-time (COT), or even predictive current/voltage mode control. The feedback from the load circuit interface would allow the controller to dynamically adjust parameters to keep the system operating at peak efficiency, potentially adapting to varying input voltages, output loads, and ambient temperatures.\n\n**Integration Patterns and Performance Characteristics**\nThis architecture lends itself well to integration into power management integrated circuits (PMICs). The compact nature of the design, facilitated by potentially smaller passive components due to higher efficiency, makes it ideal for System-on-Chip (SoC) solutions. The load circuit interface acts as both a power delivery point and a sensing node, simplifying external component count. Performance characteristics would include high power conversion efficiency (potentially >90-95% across a wide load range), excellent line and load regulation, low output ripple, and fast transient response. The reduction in switching losses, a primary goal of this design, directly translates to lower heat generation, which improves reliability and allows for smaller thermal management solutions.\n\n**Code-Level Implications**\nFor digital implementations of the converter switch controller, this architecture provides clear inputs for a firmware or HDL design. The control input would correspond to a feedback ADC channel, and the output to a PWM generator. The firmware would implement the chosen control algorithm, processing the feedback signal to adjust the switch's duty cycle. Advanced features could include soft-start sequences, over-current protection, over-voltage protection, and thermal shutdown, all managed by the controller. The efficiency gains would be realized by tightly tuning the control loop parameters and potentially implementing advanced algorithms that minimize switching transitions or operate in resonant modes when appropriate.","business_analysis":"The \"Converter Circuit Arrangement and Conversion Method\" patent (US-9853534) represents a significant leap in power conversion technology, carrying substantial implications for businesses and investors across multiple sectors. This innovation addresses a fundamental market need for greater energy efficiency, compactness, and reliability in electronic devices.\n\n**Market Opportunity Size**\nThe global power management IC market is projected to reach tens of billions of dollars, driven by the proliferation of portable electronics, IoT devices, electric vehicles, and renewable energy systems. This patent directly targets the core of this market by improving power converter efficiency. Any incremental gain in efficiency translates into massive energy savings and extended battery life across billions of devices. The market opportunity is therefore vast, spanning consumer electronics, automotive, industrial, telecom, and medical sectors, all of which require robust and efficient power delivery.\n\n**Competitive Advantages**\nCompanies that adopt or license this technology can gain a distinct competitive edge. The primary advantage is the ability to offer products with superior energy efficiency, directly leading to longer battery life in portable devices and reduced operational costs in larger systems. This innovation also enables greater miniaturization, allowing for sleeker designs and more functionality in smaller form factors, which is a critical differentiator in today's crowded markets. Furthermore, reduced heat generation means enhanced product reliability and potentially lower manufacturing costs by minimizing the need for complex thermal management solutions. These combined advantages can lead to higher customer satisfaction and market share growth.\n\n**Revenue Potential and Business Models**\nThe revenue potential for this technology is multi-faceted. Manufacturers of power management ICs (PMICs) can develop new product lines based on this patent, commanding premium pricing for their advanced performance. Original Equipment Manufacturers (OEMs) can integrate this innovation into their end-products, offering differentiated features that justify higher price points or expand their addressable market. Licensing this patent could also generate significant revenue for the patent holder, as widespread adoption across various industries is highly probable due to its fundamental benefits. Business models could include direct sales of patented components, technology licensing agreements, or joint ventures for specific applications.\n\n**Strategic Positioning**\nThis patent allows businesses to strategically position themselves as leaders in energy-efficient technology and sustainable product development. In an increasingly environmentally conscious market, offering products that consume less power and generate less waste can be a powerful brand differentiator. Companies can leverage this innovation to meet stringent energy efficiency standards (e.g., Energy Star, EU Ecodesign directives) more easily, ensuring compliance and market access. It also provides a strong foundation for future R&D, enabling the development of even more advanced power solutions.\n\n**ROI Projections**\nInvesting in or adopting the Converter Circuit Arrangement and Conversion Method technology offers compelling ROI. For manufacturers, reduced material costs (smaller heatsinks, simpler cooling), lower warranty claims due to enhanced reliability, and increased sales from differentiated products contribute to a strong return. For end-users, the benefits translate into lower electricity bills (for grid-powered devices), reduced frequency of battery replacements, and a more sustainable product lifecycle. The long-term value lies in establishing a technological leadership position and future-proofing product portfolios against evolving market demands for energy efficiency.","faqs":[{"answer":"The Converter Circuit Arrangement and Conversion Method (US-9853534) is a patent for an innovative electronic circuit designed to convert electrical power more efficiently. At its core, it describes a novel arrangement of components—specifically, a converter switch controller, a converter switch, a load circuit interface, and an inductor—that are interconnected in a unique way to minimize energy loss during power conversion. This technology aims to improve the performance of electronic devices by making their internal power management systems more effective.\n\nTraditional power converters often waste a significant amount of energy as heat, which can lead to shorter battery life, larger device sizes (due to the need for cooling), and reduced overall reliability. This invention directly addresses these challenges by optimizing the energy transfer process, ensuring that more of the input power is delivered to the load with less dissipation.\n\nThe patent's focus is on creating a system where the control of the power flow is exceptionally precise. By intelligently coupling the load circuit interface back to the controller's input, the system can adapt dynamically to varying power demands. This closed-loop control allows for real-time adjustments that maximize efficiency across a broader range of operating conditions, setting it apart from many conventional designs.\n\nUltimately, this technology provides a foundational improvement for any device that needs to convert power efficiently, from consumer gadgets to industrial machinery. Its impact is centered on making electronic systems cooler, more compact, and significantly more energy-efficient. Keywords: power conversion, energy efficiency, converter circuit, electronic innovation, power management system.","question":"What is Converter Circuit Arrangement and Conversion Method?"},{"answer":"The Converter Circuit Arrangement and Conversion Method operates through a cleverly designed interconnection of its main components to achieve highly efficient power conversion. Imagine electricity flowing like water through pipes. This system uses a 'converter switch controller' as the central brain, which has a 'control input' to receive information.\n\nConnected to this brain is a 'converter switch,' which acts like a precise valve, turning the flow of electricity on and off very rapidly. This switch is positioned between a main power supply (first potential) and the brain's control input. There's also an 'inductor,' which is like a small storage tank that smooths out the flow of electricity, connected between another power supply (second potential) and the 'load circuit interface'—the point where power is delivered to your device.\n\nThe key innovation lies in the 'load circuit interface' being coupled to both the brain's control input and the inductor. This creates a direct feedback loop: the delivery point (load circuit interface) constantly informs the brain (controller) about the current power needs and conditions. The brain then uses this real-time information to precisely operate the valve (converter switch), ensuring that electricity is transferred with minimal 'splashing' or waste (heat).\n\nThis adaptive control minimizes energy losses during the rapid switching process, which is a major source of inefficiency in traditional converters. By optimizing the energy storage and release within the inductor and the switching behavior, the Converter Circuit Arrangement and Conversion Method ensures maximum power delivery to the load while keeping the system cool and compact. Keywords: power conversion mechanism, circuit operation, energy transfer, control loop, inductor coupling, switching efficiency.","question":"How does Converter Circuit Arrangement and Conversion Method work?"},{"answer":"The Converter Circuit Arrangement and Conversion Method primarily solves the pervasive problem of inefficiency and heat generation in electronic power conversion. In virtually all electronic devices, power needs to be converted from one voltage or current level to another. For example, a smartphone charger converts AC wall power to DC power suitable for the battery, and then internal circuits convert that DC power to various levels for different components.\n\nTraditional power conversion methods often suffer from significant energy losses, mainly due to the rapid switching operations of transistors and resistive elements within the circuit. These losses manifest as heat, which presents several critical challenges: 1) **Reduced Battery Life**: Wasted energy means batteries drain faster. 2) **Device Overheating**: Excessive heat can damage components, reduce reliability, and necessitate larger, bulkier cooling solutions. 3) **Limited Miniaturization**: The need for cooling and larger components restricts how small and sleek devices can be. 4) **Increased Operational Costs**: For large-scale applications like data centers or industrial equipment, even small inefficiencies translate to substantial wasted electricity and higher operating expenses.\n\nThis patent provides a solution by introducing a circuit architecture that fundamentally minimizes these losses. By creating a highly integrated and dynamically controlled system, it ensures that power is converted with far greater precision and less waste. This directly addresses the trade-offs between efficiency, size, and thermal management that engineers have long struggled with, paving the way for cooler, more compact, and longer-lasting electronic devices. Keywords: energy waste, heat generation, power efficiency problem, electronic device limitations, thermal management, power conversion challenges.","question":"What problem does Converter Circuit Arrangement and Conversion Method solve?"},{"answer":"The patent for Converter Circuit Arrangement and Conversion Method (US-9853534) does not list the inventors in the provided data. Patents are typically granted to individuals (the inventors) and then often assigned to a company or organization (the assignee). In this case, the assignee information was also not provided.\n\nGenerally, the inventors are the individuals who conceived the idea and made the intellectual contributions to the invention. They are recognized by the patent office for their creative work. The assignee, if any, is the entity that owns the rights to the patent, often the employer of the inventors or a company that acquired the patent rights.\n\nWithout specific inventor details, it is understood that a team or individual(s) with expertise in power electronics and circuit design developed this innovative approach to energy conversion. Their work focused on optimizing the architecture and control mechanisms of converter circuits to achieve superior efficiency and performance. Keywords: patent inventors, patent assignee, invention origin, power electronics experts, circuit design, intellectual property.","question":"Who invented Converter Circuit Arrangement and Conversion Method?"},{"answer":"The Converter Circuit Arrangement and Conversion Method offers several significant benefits that can transform a wide range of electronic devices and systems. The primary advantage is **superior energy conversion efficiency**. By minimizing energy losses during the conversion process, this technology ensures that more of the input power is effectively utilized, leading to less waste and greater overall system performance.\n\nA direct result of this enhanced efficiency is **reduced heat generation**. Less wasted energy means less heat needs to be dissipated, leading to devices that run cooler. This not only improves user comfort (e.g., cooler laptops) but also significantly enhances the **reliability and lifespan** of electronic components, as heat is a major factor in component degradation.\n\nFurthermore, the reduced need for bulky heatsinks and cooling systems enables **more compact and lightweight designs**. Manufacturers can create sleeker, smaller devices without compromising performance, or pack more features into existing form factors. This is a critical benefit for portable electronics, IoT devices, and any application where space is at a premium.\n\nFinally, for battery-powered devices, this innovation translates directly into **extended battery life**. With less power wasted internally, batteries can last longer on a single charge, providing a more convenient and sustainable user experience. For grid-connected systems, it means **lower operational costs** due to reduced electricity consumption. Keywords: energy efficiency benefits, reduced heat, compact design, extended battery life, enhanced reliability, lower operational costs.","question":"What are the key benefits of Converter Circuit Arrangement and Conversion Method?"},{"answer":"The Converter Circuit Arrangement and Conversion Method differentiates itself from prior art through a unique architectural approach to power conversion, rather than just incremental improvements to existing topologies. Traditional converter circuits, such as Buck or Boost converters, typically rely on established component arrangements and control strategies that, while effective, come with inherent trade-offs in efficiency, size, and thermal management.\n\nPrior art often focuses on optimizing individual components or applying advanced modulation techniques (like resonant switching) to mitigate switching losses. While these methods yield improvements, they are often constrained by the fundamental structure of the circuit. The innovation in this patent lies in the specific and intelligent coupling of its core components: a converter switch controller, a converter switch, a load circuit interface, and an inductor. The critical difference is how the load circuit interface is directly coupled to the control input of the controller, and also to the inductor.\n\nThis intricate interconnection creates a highly integrated and dynamic feedback loop that is more responsive and precise than many conventional designs. It allows the system to actively and adaptively manage energy transfer and switching operations in real-time, significantly minimizing losses that are typically unavoidable in less integrated architectures. This means the Converter Circuit Arrangement and Conversion Method can achieve superior efficiency across a wider range of operating conditions, lead to lower heat generation, and enable more compact designs without the compromises often seen in prior art solutions. Keywords: patent differentiation, prior art comparison, unique architecture, integrated feedback, adaptive control, power conversion innovation.","question":"How is Converter Circuit Arrangement and Conversion Method different from prior art?"},{"answer":"The Converter Circuit Arrangement and Conversion Method has the potential to impact a broad spectrum of industries, given the universal need for efficient power conversion in modern electronics. Its core benefits—superior efficiency, reduced heat, and compact design—are highly desirable across diverse sectors.\n\n**Consumer Electronics** will see a significant impact, leading to smartphones, laptops, wearables, and smart home devices with extended battery life, faster charging, cooler operation, and sleeker form factors. This can drive new product categories and enhance user experience.\n\n**Automotive**, particularly the electric vehicle (EV) sector, stands to benefit immensely. More efficient power converters can lead to longer driving ranges, faster and more reliable charging systems, and lighter vehicle designs, accelerating EV adoption.\n\n**Renewable Energy** systems, including solar inverters, wind turbine converters, and battery energy storage solutions, can achieve higher energy capture and conversion rates, making green energy more cost-effective and widespread.\n\n**Industrial Automation and Robotics** will experience improvements in the reliability and efficiency of power supplies for factory equipment, sensors, and robotic systems, leading to reduced operational costs and downtime.\n\n**Telecommunications and Data Centers** can achieve substantial energy savings in power supplies for networking equipment and servers. Reduced heat generation also lowers cooling requirements, contributing to massive operational expenditure reductions. This innovation provides a foundational technology that can unlock new levels of performance and sustainability across these and many other power-dependent industries. Keywords: industry impact, consumer electronics, electric vehicles, renewable energy, industrial automation, data centers, power-dependent sectors.","question":"What industries will Converter Circuit Arrangement and Conversion Method impact?"},{"answer":"The patent for Converter Circuit Arrangement and Conversion Method, identified as US-9853534, has specific dates associated with its journey through the patent office.\n\nIts **Filing Date** was **October 1, 2013**. This is the date when the patent application was initially submitted to the patent office, marking the official beginning of the patenting process. The filing date is crucial as it typically establishes the priority date for the invention, meaning that the inventor's rights to the invention generally date back to this point.\n\nThe **Publication Date** for this patent was **December 26, 2017**. This is the date when the patent was officially published, making its details publicly accessible. At this point, the patent has been examined, deemed to meet the criteria for patentability (novelty, non-obviousness, utility), and formally granted. From this date, the patent holder has enforceable legal rights to exclude others from making, using, selling, or importing the invention as described in the claims.\n\nThese dates are important for understanding the timeline of the invention's development and its legal status. The period between filing and granting allows for examination by the patent office and often includes revisions and negotiations with the examiner. Keywords: patent filing date, patent publication date, US-9853534 timeline, intellectual property dates, patent grant, invention lifecycle.","question":"When was Converter Circuit Arrangement and Conversion Method filed/granted?"},{"answer":"The Converter Circuit Arrangement and Conversion Method (US-9853534) has a wide array of commercial applications due to its core benefits of enhanced power efficiency, reduced heat generation, and potential for compact design. Any product or system requiring efficient power conversion can leverage this technology.\n\nIn **consumer electronics**, it can lead to a new generation of smartphones, tablets, laptops, smartwatches, and other wearables with significantly longer battery life, faster charging, and sleeker, more comfortable designs. It can also improve the efficiency of power adapters and charging stations.\n\nFor the **automotive industry**, particularly **electric vehicles (EVs)**, this technology can be applied in onboard chargers, DC-DC converters for various vehicle systems, and battery management units. This translates to increased driving range, reduced charging times, and lighter power electronics, which are critical for EV performance and adoption.\n\nIn the **renewable energy sector**, commercial applications include highly efficient inverters for solar panels and wind turbines, optimizing the conversion of generated power into usable electricity. It can also enhance the performance of battery energy storage systems, making grid-scale energy solutions more viable and cost-effective.\n\n**Industrial and commercial power supplies** can benefit from greater efficiency and reliability, leading to lower energy consumption and reduced maintenance in factory automation, LED lighting systems, and building management systems. Even in **data centers and telecommunications**, where power consumption is massive, implementing this technology in server power supplies and networking equipment can yield significant energy savings and reduce cooling infrastructure costs. Keywords: commercial applications, consumer electronics, EV technology, renewable energy applications, industrial power supplies, data center efficiency, product development.","question":"What are the commercial applications of Converter Circuit Arrangement and Conversion Method?"},{"answer":"Future developments for the Converter Circuit Arrangement and Conversion Method are expected to build upon its foundational improvements in power conversion efficiency and compactness, pushing the boundaries of what's possible in electronics and power management.\n\nOne key area of development will likely be its **integration into highly specialized Power Management Integrated Circuits (PMICs)**. Manufacturers will refine and embed the patented architecture into single-chip solutions, making it easier and more cost-effective for OEMs to adopt. This could lead to a new generation of 'smart PMICs' that are even more adaptive and efficient.\n\nFurther advancements in **control algorithms**, potentially leveraging artificial intelligence and machine learning (AI/ML), could optimize the system's performance even further. AI could enable the converter switch controller to dynamically learn and adapt to changing load profiles and environmental conditions in real-time, achieving near-perfect efficiency and transient response. This would be particularly beneficial for highly dynamic systems like AI accelerators or complex robotic platforms.\n\nWe can also anticipate **application in emerging technologies**. As quantum computing and advanced high-performance computing (HPC) demand incredibly precise and efficient power delivery, the principles of this patent could be adapted to meet those stringent requirements. Furthermore, as wireless power transfer technologies mature, highly efficient converters like this one will be crucial for minimizing losses in the entire wireless power chain.\n\nFinally, the continuous evolution of **wide-bandgap semiconductor materials** (like GaN and SiC) will synergize with this patent's architecture. These materials offer even faster switching speeds and lower losses, and when combined with the optimized control of the Converter Circuit Arrangement and Conversion Method, they can unlock unprecedented levels of power density and efficiency, paving the way for truly revolutionary electronic devices and sustainable energy solutions. Keywords: future technology, PMIC integration, AI/ML control, emerging tech applications, wide-bandgap semiconductors, power electronics roadmap.","question":"What are the future developments expected for Converter Circuit Arrangement and Conversion Method?"}],"topics":["converter circuit arrangement","conversion method","power conversion efficiency","power management","energy efficiency","relentless","demand","smaller"],"tech_cluster":null},"seo":{"title":"Converter Circuit Arrangement and Conversion Method - Patent US-9853534","description":"Discover the Converter Circuit Arrangement and Conversion Method patent, enhancing power conversion efficiency for compact, cooler electronics. Full technical analysis.","keywords":["converter circuit arrangement","conversion method","power conversion efficiency","power management","energy efficiency","H02M","patent US-9853534","electronic efficiency","compact power supplies","switching losses","inductor coupling","sustainable electronics","power electronics innovation"]},"attribution":{"source":"Patentable","source_url":"https://patentable.app","canonical_url":"https://patentable.app/patents/US-9853534","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-9853534","citation_suggestion":"Patentable. \"Converter circuit arrangement and conversion method\" (US-9853534). https://patentable.app/patents/US-9853534","copyright_holder":"Nomic Interactive Technology LLC"},"links":{"html":"https://patentable.app/patents/US-9853534","json":"https://patentable.app/api/llm-context/US-9853534","site":"https://patentable.app","llms_txt":"https://patentable.app/llms.txt"},"generated_at":"2026-06-06T08:19:56.364Z"}