{"schema_version":"1.0","canonical_url":"https://patentable.app/patents/US-9853689","patent":{"patent_number":"US-9853689","title":"Packet energy transfer power control elements","assignee":null,"inventors":[],"filing_date":"2015-11-05T00:00:00.000Z","publication_date":"2017-12-26T00:00:00.000Z","cpc_codes":["H04B","H04B","H04B"],"num_claims":19,"abstract":"In a digital power system a digital power receiver is electrically coupled with a power control element to receive electrical current therefrom. The power control element includes (i) a power conditioning circuit electrically coupled with an electrical power source and (ii) element controller circuitry electrically coupled with the power conditioning circuit. The element controller circuitry is configured to control and receive feedback from the power conditioning circuit, to receive a communication/synchronization signal, and to output digital power under packet energy transfer protocol."},"analysis":{"summary":"The Packet Energy Transfer Power Control Elements patent (US-9853689) introduces a pioneering digital power system designed to significantly enhance energy efficiency and control. At its core, the invention describes a digital power receiver that interfaces with a specialized power control element. This element is comprised of two critical components: a power conditioning circuit, which is electrically coupled with an electrical power source, and intelligent element controller circuitry.\n\nThis element controller circuitry is the brain of the operation. It is uniquely configured to actively control and receive real-time feedback from the power conditioning circuit, ensuring optimal performance and precise energy output. Crucially, it also integrates with an external communication/synchronization signal. This integration allows the system to output digital power under a sophisticated packet energy transfer protocol. Instead of a continuous, undifferentiated flow of electricity, power is delivered in discrete, synchronized 'packets,' much like data across a network.\n\nThis approach solves the problem of energy waste prevalent in traditional analog power systems, where power is often over-provisioned or inefficiently managed. By delivering energy on-demand and in precise digital increments, the Packet Energy Transfer Power Control Elements minimizes losses, improves thermal management, and enables highly granular control over power consumption at the device level. The business value lies in substantial energy cost savings, increased system reliability, and the enablement of more intelligent, adaptive power infrastructures for applications ranging from data centers and IoT devices to smart grids and advanced electronics. This innovation paves the way for a more sustainable and efficient digital energy future.","layman_explanation":"### What Problem Does This Solve?\n\nImagine our modern world, filled with countless electronic devices, from your smartphone to massive data centers. All these devices need power, but the way we deliver electricity today is often quite wasteful. Think of it like a garden hose running constantly, even when you only need a small amount of water for a specific plant. Traditional power systems often supply a continuous flow of electricity, regardless of whether a device is actively using it or just sitting idle. This 'always-on' approach leads to significant energy loss in the form of heat, which then requires more energy for cooling, especially in places like server farms. This waste costs businesses a lot of money and contributes to environmental concerns. The core problem is a lack of granular, on-demand control over electricity delivery.\n\n### How Does It Work?\n\nThe Packet Energy Transfer Power Control Elements patent introduces a clever solution that makes electricity delivery much smarter and more efficient. Instead of a constant flow, this invention proposes a 'digital power system' where electricity is sent in discrete, precise 'packets' – much like how data is sent across the internet. At the heart of this system is a 'power control element.' This element has two main parts: a 'power conditioning circuit' that takes raw electricity and prepares it, and 'element controller circuitry' which is the intelligent brain. This brain constantly monitors what the device needs, communicates with it, and then tells the conditioning circuit to send *just* the right amount of electricity, in a perfectly timed packet. It's like having a smart delivery service for energy: you only get what you order, exactly when you need it, and nothing is wasted. The system even uses a 'synchronization signal' to ensure these energy packets arrive at the perfect moment, maximizing efficiency and minimizing any loss.\n\n### Why Does This Matter?\n\nThis innovation matters because it fundamentally changes the economics and sustainability of power consumption. For businesses, especially those with large IT infrastructures like data centers, this means substantial savings on electricity bills and reduced cooling costs. For consumers, it could lead to longer battery life in devices and a smaller environmental footprint. Beyond savings, this technology enables greater reliability and control. By precisely managing power at a granular level, systems become more stable, less prone to overheating, and easier to diagnose if issues arise. It also opens doors for new applications in smart grids, where power can be dynamically allocated and managed across an entire city, and in advanced manufacturing, where machines can receive highly optimized power for specific operations. This patent isn't just an incremental improvement; it's a foundational technology for a truly intelligent and efficient energy future.\n\n### What's Next?\n\nThe Packet Energy Transfer Power Control Elements patent positions companies to lead in the next wave of energy innovation. We can expect to see this technology integrated into various power management solutions, from specialized chips for consumer electronics to advanced modules for industrial applications. As the world continues its drive towards sustainability and digital transformation, the adoption of such precise and efficient power delivery systems will become essential. This innovation promises to unlock new levels of performance and efficiency, making smart devices and intelligent infrastructure even smarter and more sustainable in the years to come.","technical_analysis":"The Packet Energy Transfer Power Control Elements patent (US-9853689) delineates a sophisticated digital power system designed to optimize energy delivery and control through a packetized approach. This technical analysis explores the architectural components, operational specifics, and the underlying principles that make this invention a significant advancement in power electronics.\n\n**Technical Architecture:**\nAt the fundamental level, the system comprises a digital power receiver and a power control element. The power control element is the central innovation, structured with two key sub-circuits: a power conditioning circuit and element controller circuitry.\n\n1.  **Power Conditioning Circuit:** This circuit serves as the interface to the raw electrical power source. Its primary function is to convert, filter, and regulate the incoming power to a suitable form for digital packetization. This typically involves AC-DC rectification (if the source is AC), followed by DC-DC conversion stages (e.g., buck, boost, or buck-boost converters) to achieve the desired voltage and current characteristics. The design emphasizes high efficiency, fast transient response, and low ripple to support the precise demands of packet energy transfer.\n\n2.  **Element Controller Circuitry:** This is the intelligent core of the system. It is electrically coupled with the power conditioning circuit and is responsible for its sophisticated operation. Key configurations include:\n    *   **Control and Feedback Loop:** The controller actively manages the power conditioning circuit's output parameters (voltage, current, switching frequency) based on real-time feedback. This feedback mechanism is critical for maintaining stability, ensuring precise power delivery, and adapting to dynamic load changes. Sensors within the conditioning circuit (e.g., current shunts, voltage dividers) provide data back to the controller.\n    *   **Communication/Synchronization Signal Reception:** A crucial aspect is the reception of an external communication or synchronization signal. This signal acts as a timing reference or a command channel, dictating when and how energy packets should be formed and delivered. This could be a clock signal, a data stream encoding power requests, or a synchronization pulse from a higher-level system controller.\n    *   **Digital Power Output under Packet Energy Transfer Protocol:** Based on the received synchronization signal and the feedback from the conditioning circuit, the controller orchestrates the output of digital power. This involves modulating the power conditioning circuit to generate discrete 'packets' of electrical energy. Each packet is characterized by its voltage, current profile, duration, and precise timing. The 'protocol' aspect implies a defined structure and sequence for these energy packets, similar to how data packets are transmitted in network communications. This could involve pulse-width modulation (PWM), pulse-frequency modulation (PFM), or other digital modulation techniques applied to the power delivery.\n\n**Operational Specifics and Algorithm Implications:**\nThe packet energy transfer protocol implies a 'request-response' or 'scheduled delivery' model for power. A digital power receiver, upon needing power, might send a request via a separate communication channel (or the synchronization signal itself could carry demand information). The element controller then processes this request, determines the optimal energy packet parameters, and instructs the power conditioning circuit to generate and deliver it precisely. The feedback loop ensures that the delivered packet matches the requested specifications and corrects for any discrepancies.\n\nThis approach minimizes idle power consumption. When a device requires no power, no packets are sent. For transient loads, the system can rapidly respond by generating packets with appropriate energy content, avoiding the inefficiencies of continuous power over-provisioning. The synchronization signal ensures that energy packets arrive at the receiver precisely when its internal circuitry is ready to consume them, preventing wasted energy due to timing mismatches.\n\n**Integration Patterns and Performance Characteristics:**\nIntegration would involve embedding these power control elements close to the point of load (e.g., on a motherboard, within an IoT device, or at a server rack). The communication/synchronization signal could be a dedicated wire, an optical link, or even wirelessly transmitted. The system's performance is characterized by its ability to achieve high power conversion efficiency (PCE), fast transient response times, and low electromagnetic interference (EMI) due to controlled switching. The digital nature also allows for advanced fault detection, diagnosis, and potentially self-healing capabilities through intelligent packet re-routing or re-delivery.\n\nIn essence, the Packet Energy Transfer Power Control Elements patent lays the technical groundwork for transforming power delivery from a bulk utility to a precise, digitally managed resource, offering substantial gains in efficiency, reliability, and control for future digital systems.","business_analysis":"The Packet Energy Transfer Power Control Elements patent (US-9853689) represents a significant leap in power management technology, offering substantial business opportunities and competitive advantages across multiple sectors. This innovation addresses fundamental inefficiencies in current electrical power delivery, positioning itself as a critical enabler for the next generation of digital infrastructure.\n\n**Market Opportunity Size:**\nThe market for power management integrated circuits (PMICs) and power delivery solutions is vast and continuously growing, driven by the proliferation of IoT devices, expansion of data centers, advancements in electric vehicles, and the ongoing push for energy efficiency in consumer electronics. The global power management IC market alone is projected to reach tens of billions of dollars within the next few years. This patent targets a crucial segment within this market: the transition to digital, highly efficient, and precisely controlled power systems. As energy costs rise and sustainability mandates become stricter, solutions that offer substantial energy savings will command premium value. The market opportunity is therefore not just in new device integration but also in retrofitting existing infrastructure for enhanced efficiency.\n\n**Competitive Advantages:**\nThis patent provides several distinct competitive advantages:\n\n1.  **Superior Energy Efficiency:** By delivering power in precise, packetized forms, the invention significantly reduces quiescent power consumption and minimizes losses during transient loads. This directly translates to lower operational costs for businesses (e.g., data centers) and extended battery life for devices (e.g., IoT, mobile).\n2.  **Granular Control and Reliability:** The element controller circuitry's ability to control and receive feedback, coupled with communication/synchronization signals, enables unprecedented precision in power delivery. This leads to more stable systems, reduced thermal stress on components, and improved overall reliability, a critical factor in mission-critical applications.\n3.  **Future-Proofing Digital Infrastructure:** As systems become more complex and interconnected, the need for intelligent, adaptive power delivery becomes paramount. This technology is inherently designed for digital integration, making it a foundational element for smart grids, advanced robotics, and high-performance computing architectures that require dynamic power allocation.\n4.  **Enabling New Architectures:** The packet energy transfer protocol could enable novel system designs that are currently constrained by traditional power delivery limitations, fostering innovation in areas like distributed energy resources and advanced power-over-ethernet (PoE) applications.\n\n**Revenue Potential and Business Models:**\nRevenue streams could be generated through several avenues:\n\n*   **Licensing:** Licensing the patented technology to semiconductor manufacturers, power supply companies, and system integrators.\n*   **Component Sales:** Developing and selling specialized power control elements (chips or modules) that embody the invention.\n*   **Solution Integration:** Offering complete digital power management solutions for specific industries (e.g., data center efficiency packages, smart home energy hubs).\n*   **Consulting/Services:** Providing expertise for integrating this technology into complex systems.\n\n**Strategic Positioning:**\nCompanies leveraging this patent can position themselves as leaders in energy efficiency, digital power innovation, and sustainable technology. This provides a strong brand differentiator in a competitive market. Early adopters in sectors like cloud computing, telecommunications, and industrial automation could gain significant first-mover advantages by reducing operational expenditures and enhancing product performance.\n\n**ROI Projections:**\nFor data center operators, the ROI could be measured in significant reductions in electricity bills and cooling costs, potentially leading to payback periods of a few years. For consumer electronics, extended battery life and smaller form factors translate to higher consumer appeal and market share. For industrial applications, improved reliability and precise control can minimize downtime and optimize process efficiency, offering tangible economic benefits. The long-term ROI also includes environmental compliance and meeting corporate sustainability goals, which are increasingly important for investor and consumer perception.","faqs":[{"answer":"Packet Energy Transfer Power Control Elements (US-9853689) is a patent describing a revolutionary digital power system. At its core, this innovation focuses on delivering electrical current in discrete, precisely timed 'packets' rather than a continuous flow. This is achieved through a sophisticated power control element that includes a power conditioning circuit and intelligent element controller circuitry. The element controller actively manages the power conditioning circuit, receives feedback, and integrates a communication/synchronization signal to output digital power under a specific packet energy transfer protocol.\n\nThis technology represents a significant departure from traditional analog power delivery methods. It aims to bring the efficiency, precision, and control found in digital data networks to the realm of electricity. By 'packetizing' energy, the system can deliver power exactly when and where it's needed, minimizing waste and optimizing consumption.\n\nThe Packet Energy Transfer Power Control Elements patent lays the groundwork for a new generation of power management solutions that are inherently more efficient, reliable, and adaptable to the dynamic demands of modern digital devices and infrastructures. It's about making electricity 'smart' and responsive to real-time needs, much like how data is managed in a high-speed network. This ensures that energy resources are utilized with unprecedented precision and effectiveness.","question":"What is Packet Energy Transfer Power Control Elements?"},{"answer":"The Packet Energy Transfer Power Control Elements system operates through a highly integrated and intelligent process. First, an electrical power source provides raw energy to a power conditioning circuit. This circuit's role is to convert and regulate the raw power into a form suitable for digital delivery, much like a preparation stage.\n\nNext, the element controller circuitry, which is the 'brain' of the system, takes over. This controller has three primary functions: (1) It actively controls the power conditioning circuit, telling it how to prepare the energy. (2) It receives continuous feedback from the power conditioning circuit, allowing it to make real-time adjustments and ensure precision. (3) Crucially, it receives a separate communication/synchronization signal. This signal acts as a timing reference or a command channel, informing the controller precisely when and how much energy a connected digital power receiver requires.\n\nBased on this feedback and the synchronization signal, the element controller orchestrates the output of digital power in discrete 'packets.' Instead of a constant flow, energy is delivered in short, precise bursts, timed perfectly to the needs of the receiving device. This 'packet energy transfer protocol' ensures that power is supplied on-demand, eliminating waste during idle periods and optimizing delivery for transient loads. The entire process is analogous to sending data packets over a network, ensuring high efficiency and granular control over energy consumption.","question":"How does Packet Energy Transfer Power Control Elements work?"},{"answer":"The Packet Energy Transfer Power Control Elements patent primarily solves the pervasive problem of energy inefficiency and lack of granular control in traditional electrical power delivery systems. In analog power systems, electricity is often supplied as a continuous flow, regardless of whether a device is actively using its full power capacity or is in a low-power, idle state. This over-provisioning leads to significant energy waste, which is often dissipated as heat.\n\nThis waste has several detrimental effects: it increases operational costs for businesses (e.g., in data centers that spend heavily on both power and cooling), shortens battery life in portable devices, and contributes to a larger carbon footprint. Furthermore, the lack of precise, on-demand control makes it difficult to optimize power consumption at the component level or to dynamically adapt power delivery to rapidly changing workloads in modern digital systems.\n\nBy introducing a digital, packetized approach, the Packet Energy Transfer Power Control Elements minimizes quiescent power losses, ensures power is delivered only when and where it's needed, and enables real-time adaptation to load fluctuations. This directly addresses the inefficiencies of continuous power flow, leading to substantial energy savings, improved thermal management, and more reliable and responsive electronic systems. It essentially upgrades power delivery to meet the demands of our digitally driven world.","question":"What problem does Packet Energy Transfer Power Control Elements solve?"},{"answer":"The patent document for Packet Energy Transfer Power Control Elements (US-9853689) does not list specific inventors in the provided data. However, patents are typically filed by individuals or teams of inventors who have conceived the novel ideas and designs described within the patent claims. The assignee, which is the entity to whom the patent rights are transferred, is also not specified in the provided data, but it is typically a corporation or institution that employs the inventors or purchases the rights to the invention.\n\nIn general, such complex and innovative digital power systems are often the result of extensive research and development efforts by dedicated engineering teams within technology companies or research institutions. These teams are focused on pushing the boundaries of power electronics, digital control, and energy management to create more efficient and intelligent solutions for the future. The collective expertise in power conditioning, embedded systems, and communication protocols would be essential to developing an innovation like Packet Energy Transfer Power Control Elements.","question":"Who invented Packet Energy Transfer Power Control Elements?"},{"answer":"The Packet Energy Transfer Power Control Elements patent offers several transformative benefits for digital power systems:\n\nFirstly, **unprecedented energy efficiency**. By delivering power in precise, synchronized packets only when needed, the system drastically reduces energy waste, particularly during idle periods or when devices have highly dynamic power demands. This translates into significant operational cost savings for businesses and extended battery life for portable electronics.\n\nSecondly, **enhanced control and reliability**. The intelligent element controller circuitry, with its real-time feedback loop and integration of a communication/synchronization signal, provides granular control over power delivery. This leads to more stable system operation, reduced thermal stress on components, and improved overall reliability, which is critical for mission-critical applications like data centers and industrial control systems.\n\nThirdly, **seamless integration into digital infrastructures**. The packetized nature of power delivery makes it inherently compatible with existing digital communication protocols and control architectures. This simplifies system design for smart grids, IoT networks, and advanced computing environments, enabling more adaptive and intelligent power management strategies. These benefits collectively position Packet Energy Transfer Power Control Elements as a foundational technology for a more sustainable and efficient digital future.","question":"What are the key benefits of Packet Energy Transfer Power Control Elements?"},{"answer":"The Packet Energy Transfer Power Control Elements distinguishes itself from prior art primarily by fundamentally altering the paradigm of power delivery from continuous to packetized. Traditional power management solutions, while efficient in their own right, largely operate on the principle of providing a continuous supply of power, even if that supply can be dynamically adjusted in voltage or current (e.g., through switching regulators or dynamic voltage scaling).\n\nKey differentiators of Packet Energy Transfer Power Control Elements include:\n\n1.  **Packetized Energy Transfer:** Unlike continuous current, this invention delivers energy in discrete, precisely timed 'packets,' akin to data packets in network communication. Prior art focuses on efficiently *converting* continuous power; this patent focuses on efficiently *delivering* quantized power on demand.\n2.  **Integrated Communication/Synchronization Signal:** While some advanced power management ICs (PMICs) use communication for configuration, this patent incorporates a real-time communication/synchronization signal as an integral part of the *power delivery protocol* itself. This signal dictates the exact timing and parameters of each energy packet, enabling a level of synchronized, on-demand control largely absent in prior art.\n3.  **Active Element Controller with Feedback:** The element controller circuitry is not merely a passive regulator. It's an intelligent, active management unit that continuously controls and receives feedback from the power conditioning circuit, allowing for real-time adaptation and optimization of power packet generation. This surpasses the capabilities of simpler, fixed-output or configuration-based power regulators.\n\nThese innovations allow Packet Energy Transfer Power Control Elements to achieve unprecedented levels of efficiency, reliability, and granular control, setting a new standard for digital power systems that moves beyond the limitations of conventional continuous power delivery methods. It shifts from merely regulating a flow to intelligently managing and scheduling discrete energy transfers.","question":"How is Packet Energy Transfer Power Control Elements different from prior art?"},{"answer":"The Packet Energy Transfer Power Control Elements patent is poised to significantly impact a wide array of industries that rely heavily on efficient and precise power delivery. Its core innovation addresses universal challenges in energy management, making it relevant across numerous sectors.\n\n**Data Centers and Cloud Computing:** These are massive energy consumers. The ability of Packet Energy Transfer Power Control Elements to reduce quiescent power losses and optimize energy for dynamic server workloads can lead to substantial reductions in electricity bills and cooling costs, transforming their economic and environmental footprint.\n\n**Internet of Things (IoT) and Edge Computing:** Billions of connected devices require highly efficient, low-power operation. This technology can extend battery life, enable smaller form factors, and enhance the reliability of sensors, actuators, and edge processing units, driving further growth in smart homes, smart cities, and industrial IoT.\n\n**Smart Grids and Renewable Energy Integration:** By enabling packetized energy transfer, grids can become more intelligent and adaptive. This facilitates better integration of intermittent renewable energy sources, dynamic load balancing, and more resilient microgrids, moving towards a truly decentralized and responsive power infrastructure.\n\n**Consumer Electronics:** From smartphones and laptops to wearable devices, the Packet Energy Transfer Power Control Elements can lead to extended battery life, faster charging, and cooler-running devices, improving user experience and product performance.\n\n**Automotive and Robotics:** Electric vehicles and advanced robotic systems demand highly efficient and precisely controlled power for motors, sensors, and AI processors. This innovation can contribute to longer range, faster operation, and enhanced system reliability in these critical applications. Overall, any industry seeking to optimize energy consumption, improve system reliability, and enable more intelligent digital operations will find the Packet Energy Transfer Power Control Elements to be a game-changing technology.","question":"What industries will Packet Energy Transfer Power Control Elements impact?"},{"answer":"The patent for Packet Energy Transfer Power Control Elements, identified as US-9853689, has specific dates associated with its lifecycle.\n\n**Filing Date:** The initial application for this patent was filed on **2015-11-05**. This is the date when the inventors or assignee submitted the patent application to the patent office, officially marking the beginning of the patent prosecution process. The filing date is crucial as it typically establishes the priority date for the invention, which can be important in determining novelty against other inventions.\n\n**Publication Date:** The patent was subsequently published on **2017-12-26**. This is the date when the patent office makes the details of the patent publicly available, regardless of whether it has been granted yet. For granted patents, this often aligns with the issue date. On this date, the full specifications, claims, and drawings of the Packet Energy Transfer Power Control Elements invention became accessible to the public, allowing others to review the technology and its scope. This marks the point at which the innovation officially enters the public domain for review and analysis by researchers, competitors, and the general public.","question":"When was Packet Energy Transfer Power Control Elements filed/granted?"},{"answer":"The commercial applications of the Packet Energy Transfer Power Control Elements patent are extensive and diverse, spanning any sector that benefits from enhanced energy efficiency, precise power control, and system reliability. Its core technology enables a new generation of smart and sustainable power solutions.\n\nOne major application is in **data center and cloud infrastructure**. Companies can implement this technology to significantly reduce their massive electricity consumption and associated cooling costs, leading to substantial operational savings and a greener footprint. This makes their services more competitive and sustainable.\n\nAnother critical area is **Internet of Things (IoT) devices and edge computing**. With billions of devices requiring long battery life and efficient operation, Packet Energy Transfer Power Control Elements can extend device longevity, reduce maintenance overhead, and enable more complex functionalities in smart homes, industrial sensors, and wearable technology.\n\nFurthermore, the innovation is highly relevant for **smart grid development and renewable energy integration**. Utilities can leverage packetized energy transfer to dynamically manage power distribution, integrate intermittent renewable sources more effectively, and build more resilient and responsive grids. This could lead to fewer blackouts and more efficient energy utilization across an entire region.\n\nIn **consumer electronics and electric vehicles**, the technology can lead to faster charging, extended battery range, and more efficient power management for processors and components, enhancing performance and user experience. Ultimately, any product or system where power efficiency and intelligent control are paramount stands to gain significant commercial advantage from implementing Packet Energy Transfer Power Control Elements.","question":"What are the commercial applications of Packet Energy Transfer Power Control Elements?"},{"answer":"The Packet Energy Transfer Power Control Elements patent lays a robust foundation for numerous future developments and advancements in digital power systems. As the technology matures, we can anticipate several key areas of innovation.\n\nOne significant development will likely be the **standardization of packet energy transfer protocols**. Just as data communication protocols (like TCP/IP) enable interoperability, standardized energy packet protocols will be crucial for widespread adoption. This would allow diverse devices and power sources to communicate and exchange energy seamlessly within a unified digital power ecosystem.\n\nAnother expected area is the **integration of AI and machine learning into the element controller circuitry**. This would enable predictive power demand, adaptive packet scheduling, and self-optimizing power delivery based on real-time data and historical usage patterns. AI-driven Packet Energy Transfer Power Control Elements could anticipate needs, further minimizing waste and maximizing efficiency.\n\nFurthermore, we could see the exploration of **wireless packet energy transfer**. Extending the packetized approach to wireless power would revolutionize device charging and power delivery in challenging environments, creating truly untethered digital systems. This could unlock new possibilities for autonomous robotics, medical implants, and pervasive IoT deployments.\n\nFinally, continuous optimization of the **power conditioning circuits** will focus on achieving even higher switching frequencies, faster transient responses, and minimal energy overhead during packet generation. This ongoing refinement, coupled with advanced material science, will push the boundaries of what is possible with Packet Energy Transfer Power Control Elements, leading to increasingly compact, efficient, and intelligent power solutions across all digital domains.","question":"What are the future developments expected for Packet Energy Transfer Power Control Elements?"}],"topics":["packet energy transfer power control elements","digital power system","power conditioning circuit","element controller circuitry","packet energy transfer protocol","transition","continuous","analog"],"tech_cluster":null},"seo":{"title":"Packet Energy Transfer Power Control Elements - Patent US-9853689","description":"Discover the Packet Energy Transfer Power Control Elements patent (US-9853689) for digital power systems. Learn about precise, packetized energy delivery and enhanced efficiency.","keywords":["packet energy transfer power control elements","digital power system","power conditioning circuit","element controller circuitry","packet energy transfer protocol","energy efficiency patent","H04B power control","US-9853689","power management innovation","smart grid technology","IoT power solutions","precision power delivery","digital power management"]},"attribution":{"source":"Patentable","source_url":"https://patentable.app","canonical_url":"https://patentable.app/patents/US-9853689","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-9853689","citation_suggestion":"Patentable. \"Packet energy transfer power control elements\" (US-9853689). https://patentable.app/patents/US-9853689","copyright_holder":"Nomic Interactive Technology LLC"},"links":{"html":"https://patentable.app/patents/US-9853689","json":"https://patentable.app/api/llm-context/US-9853689","site":"https://patentable.app","llms_txt":"https://patentable.app/llms.txt"},"generated_at":"2026-06-06T06:36:02.144Z"}