{"schema_version":"1.0","canonical_url":"https://patentable.app/patents/US-9853495","patent":{"patent_number":"US-9853495","title":"Discharge circuit, information processing apparatus, discharge method, and storage medium","assignee":null,"inventors":[],"filing_date":"2014-11-25T00:00:00.000Z","publication_date":"2017-12-26T00:00:00.000Z","cpc_codes":["G06F","H02J","H02J"],"num_claims":13,"abstract":"A discharge circuit for a decoupling capacitor to stabilize a voltage supplied from a first power supply unit to a first load includes a first capacitor, a first switch, and a discharge control circuit. The first capacitor is charged by power supplied from a second power supply unit that supplies power to a second load that is different from the first load. The first switch is arranged between the decoupling capacitor and ground. The discharge control circuit discharges, in a case where power supplied from the second power supply unit to the second load is cut off, charges of the decoupling capacitor to the ground by driving the first switch using charges stored in the first capacitor."},"analysis":{"summary":"The patent titled **Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium** (US-9853495) introduces a crucial advancement in power management, specifically addressing the safe and efficient discharge of decoupling capacitors in complex electronic systems. Its core innovation lies in creating a self-sufficient discharge mechanism that enhances voltage stability and system reliability, particularly for information processing apparatuses.\n\nThe primary problem this invention solves is the uncontrolled discharge of decoupling capacitors when power supplies are cut off. In multi-power-domain systems, residual charges in these capacitors can lead to voltage transients, data corruption, and potential damage to sensitive components. Existing solutions often involve passive bleed resistors, which are slow and inefficient, or complex active circuits that rely on the very power supply that might be failing.\n\nThe key technical approach involves a discharge circuit that includes a first capacitor, a first switch, and a discharge control circuit. Uniquely, the first capacitor is charged by a *second* power supply unit, which is typically dedicated to a *different* load. When this second power supply is cut off, the discharge control circuit intelligently uses the charges stored in the first capacitor to activate the first switch. This action rapidly and safely discharges the main decoupling capacitor to ground, ensuring power integrity even during unexpected power transitions.\n\nFrom a business perspective, this technology offers significant value. It provides a robust solution for manufacturers of information processing apparatuses—ranging from servers and embedded systems to consumer electronics—to enhance product reliability and longevity. By mitigating risks of data loss and hardware damage, it reduces warranty claims, improves customer satisfaction, and lowers maintenance costs. The market opportunity lies in any sector requiring high power integrity and system uptime, offering a competitive advantage to adopters.\n\nThis innovation promises to improve the resilience and efficiency of electronic devices, making them more robust against power fluctuations and unexpected shutdowns. It represents a forward-thinking solution for the increasingly complex power demands of modern digital infrastructure.","layman_explanation":"### What Problem Does This Solve?\n\nImagine you have a high-performance computer, a server in a data center, or even an advanced medical device. These complex 'information processing apparatuses' rely on multiple power sources to keep different parts running smoothly. A crucial component in these systems is called a 'decoupling capacitor.' Think of it like a tiny, super-fast battery that smooths out any little bumps in the power supply, ensuring a steady flow of electricity to sensitive components. The problem arises when one of these power supplies suddenly cuts off, perhaps due to a system shutdown or an unexpected power interruption. These decoupling capacitors can hold onto a 'residual charge' for a while. If this charge isn't properly and quickly dissipated, it can cause a cascade of problems: voltage spikes that damage delicate circuits, data corruption in memory, or even prevent the system from restarting cleanly. Existing solutions are often either too slow (like simple resistors that bleed off power gradually) or rely on the very power supply that might be failing, which isn't ideal for reliability.\n\n### How Does It Work?\n\nThe patent, known as **Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium**, introduces an ingenious solution. Picture a main power supply (let's call it 'Power Source A') that powers the most important part of your device. To keep this main part stable, it has a decoupling capacitor. Now, imagine there's also a secondary power supply ('Power Source B') that powers a *different*, less critical part of the device. This invention cleverly uses Power Source B to charge a *small, separate capacitor* (let's call it 'Reserve Capacitor').\n\nThe magic happens when Power Source B is cut off. The system has a 'smart control circuit' that detects this event. Crucially, this smart control circuit doesn't need Power Source A to work; it draws its power from the Reserve Capacitor, which was charged by Power Source B. Using this stored energy, the smart control circuit then instantly activates a 'fast switch.' This switch acts like a bypass, rapidly draining all the leftover charge from the main decoupling capacitor (the one stabilizing Power Source A) safely into the ground. It's an autonomous, self-powered emergency discharge system that ensures stability without adding complexity or inefficiency during normal operation.\n\n### Why Does This Matter?\n\nThis innovation holds significant implications for any business involved in electronics. In today's digital economy, reliability and data integrity are paramount. For manufacturers of servers, networking gear, automotive electronics, and high-end consumer devices, this technology offers a powerful competitive advantage. By integrating this discharge circuit, companies can build products that are inherently more robust and less prone to power-related failures. This translates directly into: \n\n*   **Higher Uptime:** Systems stay operational longer, reducing costly downtime.\n*   **Reduced Data Loss:** Critical information processing apparatuses are protected from corruption during power events.\n*   **Lower Maintenance Costs:** Fewer component failures mean less need for repairs and replacements.\n*   **Enhanced Brand Reputation:** Customers trust products that are consistently reliable.\n\nThis patent provides a foundational improvement in power management, allowing businesses to deliver more dependable and efficient electronic devices, thereby capturing market share in quality-sensitive sectors. The ROI comes from improved product quality, reduced operational expenses, and stronger customer loyalty.\n\n### What's Next?\n\nThis technology is poised to become a standard feature in next-generation power management solutions. We can expect to see it integrated into custom chip designs or offered as specialized power management modules. Its principles could also extend to battery-powered devices, improving their efficiency and longevity by ensuring clean power cycling. As electronic systems become even more complex and critical to our daily lives, innovations like the **Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium** will be essential for building a truly resilient and reliable digital infrastructure. Companies that embrace this approach early will be well-positioned to lead in the evolving landscape of advanced electronics.","technical_analysis":"The patent **Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium** (US-9853495) details a sophisticated power management solution designed to enhance the stability and reliability of information processing apparatuses. The core technical problem it addresses is the controlled and efficient discharge of decoupling capacitors, which are critical for voltage stabilization, particularly in multi-power-domain systems where power supply interruptions can lead to detrimental effects.\n\n**Technical Architecture:**\nThe invention proposes a discharge circuit for a decoupling capacitor (C_dec) that is connected to a first load (Load1) and supplied by a first power supply unit (PSU1). The unique aspect of this architecture involves leveraging a *second* power supply unit (PSU2), which supplies power to a *second, distinct load* (Load2), to facilitate the discharge of C_dec. The circuit comprises three main components:\n\n1.  **First Capacitor (C1):** This capacitor is charged by PSU2. It acts as a local energy reservoir, providing the necessary power to the discharge control circuit when PSU2 itself is cut off.\n2.  **First Switch (S1):** Positioned between C_dec and ground, S1 provides a low-impedance path for C_dec to discharge its stored energy. S1 is typically a transistor (e.g., MOSFET) capable of handling the discharge current.\n3.  **Discharge Control Circuit (DCC):** This is the intelligent core. It monitors the status of PSU2. When PSU2's power supply to Load2 is interrupted (e.g., voltage drops below a threshold), the DCC draws power from the charges stored in C1. Using this energy, the DCC generates a control signal to drive S1, causing it to close and rapidly discharge C_dec.\n\n**Implementation Details and Algorithm Specifics:**\nThe DCC's implementation would typically involve a voltage comparator or a supervisory circuit that continuously monitors the output voltage of PSU2. When this voltage falls below a predetermined threshold, indicating a power cut-off, the DCC's internal logic is activated. The energy stored in C1 is then used to power a gate driver or a simple switching circuit within the DCC, which in turn drives the gate of S1. The selection of C1's capacitance and S1's characteristics (e.g., R_DS(on)) is crucial to ensure a sufficiently rapid and complete discharge of C_dec without excessive current spikes.\n\nFor instance, if PSU2 operates at 3.3V, C1 would be charged to approximately 3.3V. When PSU2 drops to 0V, the DCC detects this. C1, still charged, powers the DCC's output stage, which then applies a voltage to S1's gate, turning it 'on.' This creates a direct path for C_dec, which might be charged to 5V or 1.8V, to discharge through S1 to ground. The discharge time constant would be primarily determined by C_dec and S1's on-resistance.\n\n**Integration Patterns:**\nThis discharge circuit can be integrated as a discrete component alongside existing power management ICs or directly embedded within custom ASICs or power management units (PMUs). Its autonomous nature makes it highly adaptable to various system architectures, especially those with segregated power domains common in modern SoCs for processors, memory, and peripherals. It provides a 'fail-safe' discharge mechanism that doesn't rely on the potentially failing primary power rail.\n\n**Performance Characteristics:**\n*   **Discharge Speed:** Significantly faster than passive bleed resistors, crucial for preventing data corruption in volatile memory. The speed is dictated by S1's switching characteristics and C_dec's capacitance.\n*   **Energy Efficiency:** The circuit is largely passive during normal operation, with C1 charging. Power consumption is minimal until an actual discharge event, making it more efficient than constant bleed resistors.\n*   **Reliability:** By decoupling the discharge mechanism from the main power supply (PSU1), the system gains robustness against primary power failures. The use of C1 as an independent power source for the DCC ensures activation even when PSU2 is completely down.\n\n**Code-Level Implications:**\nWhile this patent primarily describes hardware, its implications for firmware and software are significant. The improved power integrity means that system software can rely on more predictable power-down sequences. For instance, operating systems can implement more reliable graceful shutdown procedures, knowing that critical hardware components like decoupling capacitors will be discharged safely. This reduces the need for complex software-based workarounds to manage power glitches or potential component resets, simplifying embedded software development and improving overall system stability.","business_analysis":"The patent **Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium** (US-9853495) presents a compelling business opportunity by addressing a fundamental challenge in power management for information processing apparatuses: ensuring reliable and safe power discharge. This innovation directly impacts product reliability, operational efficiency, and ultimately, market competitiveness across numerous high-tech sectors.\n\n**Market Opportunity Size:**\nThe market for power management integrated circuits (PMICs) and discrete power components is substantial and continuously growing, driven by the proliferation of electronic devices, IoT, AI, data centers, and automotive electronics. Within this vast market, solutions that enhance power integrity and system resilience are in high demand. The global power management IC market alone is projected to reach over $50 billion by 2028. This patent targets a critical niche within this market—reliable capacitor discharge—which is essential for virtually all digital systems. The addressable market includes manufacturers of servers, networking equipment, embedded systems, automotive ECUs, industrial control systems, consumer electronics (e.g., high-end PCs, gaming consoles), and any device requiring robust power stability.\n\n**Competitive Advantages:**\nAdoption of this technology offers several distinct competitive advantages:\n\n1.  **Superior Reliability:** Products integrating this discharge circuit will boast enhanced resilience against power fluctuations and unexpected shutdowns. This translates to fewer field failures, reduced warranty claims, and higher customer satisfaction.\n2.  **Data Integrity:** For information processing apparatuses, protecting data during power transitions is paramount. This invention ensures critical capacitors are discharged quickly and safely, minimizing the risk of data corruption, a significant differentiator in data-sensitive applications.\n3.  **Cost Reduction:** By preventing component damage and data loss, businesses can significantly reduce repair, replacement, and data recovery costs. Improved system uptime also contributes to lower operational expenses.\n4.  **Energy Efficiency:** Unlike passive bleed resistors that constantly dissipate power, this active discharge mechanism only consumes significant energy when needed, contributing to overall system efficiency and potentially longer battery life in portable devices.\n5.  **Simplified Design:** For engineers, this provides a robust, pre-engineered solution for a complex problem, potentially reducing design complexity and time-to-market for new products.\n\n**Revenue Potential and Business Models:**\nRevenue potential for this patent could stem from several avenues:\n\n*   **Licensing:** The patent holder could license the technology to major semiconductor manufacturers (e.g., Texas Instruments, Analog Devices, STMicroelectronics) for integration into their PMIC portfolios or discrete power management components.\n*   **Component Sales:** If the patent holder develops a product (e.g., a small ASIC or module) implementing this circuit, direct sales to OEMs would be a viable model.\n*   **Consulting/Design Services:** Offering expertise in integrating this technology into complex system designs.\n\n**Strategic Positioning:**\nThis innovation allows companies to strategically position their products as 'ultra-reliable' or 'mission-critical ready.' In industries like automotive (ADAS/autonomous driving), medical devices, and industrial IoT, where failure is not an option, this technology provides a crucial selling point. It helps companies differentiate themselves from competitors relying on less robust or less efficient power management solutions.\n\n**ROI Projections:**\nWhile specific ROI depends on adoption rates and licensing terms, the value proposition is clear. For an OEM, investing in this technology (either through licensing or direct component purchase) can yield significant returns through:\n\n*   **Reduced Support Costs:** Fewer product returns and customer complaints.\n*   **Enhanced Brand Reputation:** Known for reliability and quality.\n*   **Market Share Gain:** Capturing segments that prioritize power integrity.\n*   **Faster Product Cycles:** Simplified power design allows engineers to focus on other innovations.\n\nIn essence, the **Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium** patent provides a foundational improvement that translates directly into tangible business benefits, making it an attractive proposition for investment and adoption in the rapidly evolving electronics landscape.","faqs":[{"answer":"The **Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium** (US-9853495) is a patent for an innovative power management technology. It introduces a novel circuit designed to safely and efficiently discharge decoupling capacitors in electronic devices, particularly those classified as information processing apparatuses.\n\nDecoupling capacitors are critical components that stabilize voltage supplied to various parts of a circuit. This invention provides a mechanism to ensure that when power supplies are cut off, the residual charge in these capacitors is quickly and cleanly dissipated to ground, preventing potential issues like voltage spikes, data corruption, or component damage.\n\nThe essence of this patent lies in its autonomous operation, leveraging an auxiliary power source to power its discharge control mechanism, making it highly reliable even during complex power transition events. It's a foundational improvement for the stability and integrity of modern electronic systems. Keywords: patent US-9853495, discharge circuit, power management, decoupling capacitor, information processing apparatus, voltage stabilization.","question":"What is 'Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium'?"},{"answer":"The **Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium** works through a clever, self-sufficient mechanism. It focuses on a decoupling capacitor that stabilizes a voltage from a 'first power supply unit' to a 'first load.' The innovation comes into play with a 'second power supply unit' that powers a 'second load' (different from the first).\n\nHere's the breakdown: A 'first capacitor' is charged by this second power supply. A 'first switch' is placed between the main decoupling capacitor and ground. The core intelligence is a 'discharge control circuit' that constantly monitors the second power supply. If the second power supply is cut off, the discharge control circuit uses the energy stored in the *first capacitor* (which was charged by the second power supply) to activate the first switch. This action rapidly connects the main decoupling capacitor to ground, safely discharging its stored energy.\n\nThis autonomous process ensures that the capacitor is discharged quickly and reliably, without depending on the primary power supply that might be failing. Keywords: how it works, discharge mechanism, decoupling capacitor, power supply unit, discharge control circuit, first capacitor, first switch, autonomous discharge.","question":"How does 'Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium' work?"},{"answer":"The **Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium** solves the critical problem of uncontrolled and inefficient discharge of decoupling capacitors in electronic systems, particularly information processing apparatuses. In complex devices with multiple power domains, when a power supply is cut off (e.g., during shutdown or failure), decoupling capacitors can retain a residual charge.\n\nThis lingering charge can lead to several severe issues: voltage spikes that could damage sensitive components, electromagnetic interference (EMI), data corruption in volatile memory, or preventing a clean system reset. Traditional passive discharge methods (like bleed resistors) are too slow and inefficient, while many active methods depend on the very power supply that might be failing, compromising their reliability.\n\nThis invention provides a robust, fast, and autonomous solution that ensures these capacitors are safely discharged, thereby enhancing power integrity, protecting hardware, and safeguarding data. Keywords: problem solved, uncontrolled discharge, decoupling capacitor, power integrity, data corruption, component damage, system stability, power cut-off, electronic reliability.","question":"What problem does 'Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium' solve?"},{"answer":"The patent **Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium** (US-9853495) does not list specific inventors in the provided data. Patent filings typically include the names of the inventors who conceived the invention, but this information was not available in the abstract or the minimal patent data provided.\n\nOften, in large corporations, inventions are assigned to the company, and the individual inventors' names are recorded in the full patent document. For detailed inventor information, one would typically consult the full patent document available from patent offices like the USPTO or through patent databases. Keywords: inventors, patent US-9853495, invention origin, patent assignee, patent information.","question":"Who invented 'Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium'?"},{"answer":"The **Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium** offers several significant benefits for electronic systems, particularly information processing apparatuses:\n\n1.  **Enhanced System Reliability:** It ensures a controlled and predictable power-down sequence, significantly reducing the risk of system failures, glitches, and unexpected reboots caused by residual charges.\n2.  **Improved Power Integrity:** By rapidly and safely discharging capacitors, it prevents undesirable voltage transients and noise, which is crucial for the stable operation of sensitive digital and analog circuits.\n3.  **Data Protection:** For devices handling critical information, it mitigates the risk of data corruption or loss in volatile memory during sudden power interruptions.\n4.  **Component Longevity:** Preventing voltage spikes and uncontrolled energy dissipation helps protect delicate electronic components from stress and damage, extending their operational lifespan.\n5.  **Energy Efficiency:** Unlike passive discharge methods that continuously draw power, this active solution only consumes significant energy during the brief discharge event, contributing to overall system efficiency.\n\nThese benefits collectively lead to more robust, durable, and trustworthy electronic products across various industries. Keywords: key benefits, system reliability, power integrity, data protection, component longevity, energy efficiency, information processing apparatus, patent advantages.","question":"What are the key benefits of 'Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium'?"},{"answer":"The **Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium** significantly differentiates itself from prior art solutions primarily through its autonomous and self-powered discharge mechanism.\n\nPrior art often relies on passive bleed resistors, which are slow, inefficient (continuously drawing power), and inadequate for rapid power-down requirements. Other active discharge circuits typically depend on the primary power supply for their operation. If this primary supply fails, the discharge circuit itself may become inoperative or unreliable, leaving the capacitors charged.\n\nIn contrast, this invention uses a *separate* power supply (for a different load) to charge a dedicated 'first capacitor.' This first capacitor then provides the power to the 'discharge control circuit' that activates the discharge. This independence means the discharge mechanism is robust and functions reliably even if the main power supply or the secondary power supply is cut off. It provides a faster, more efficient, and fundamentally more reliable discharge path, addressing the critical limitations of existing methods. Keywords: prior art comparison, unique features, autonomous discharge, self-powered, passive vs active, power management innovation, reliability difference.","question":"How is 'Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium' different from prior art?"},{"answer":"The **Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium** has the potential to impact a wide array of industries that rely heavily on stable and reliable electronic systems, particularly those categorized as information processing apparatuses:\n\n*   **Data Centers & Cloud Computing:** Critical for ensuring server stability, preventing data loss, and enabling graceful shutdowns during power events, leading to higher uptime.\n*   **Automotive Electronics:** Essential for safety-critical systems like ADAS (Advanced Driver-Assistance Systems), autonomous driving, and complex infotainment systems where power integrity is paramount.\n*   **Industrial Automation & IoT:** Enhances the reliability of PLCs, sensors, and control systems operating in harsh or remote environments, reducing maintenance and operational failures.\n*   **Telecommunications:** Improves the stability of networking equipment, routers, and base stations, ensuring uninterrupted communication services.\n*   **Consumer Electronics:** Benefits high-end devices like gaming consoles, laptops, and smart home hubs by providing greater resilience against power glitches and extending product lifespan.\n*   **Medical Devices:** Crucial for devices where reliability is directly linked to patient safety and accurate operation.\n\nAny sector requiring robust power management, high system uptime, and data integrity will find this technology invaluable. Keywords: industry impact, data centers, automotive, industrial IoT, telecommunications, consumer electronics, medical devices, information processing apparatus, power reliability.","question":"What industries will 'Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium' impact?"},{"answer":"The patent titled **Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium** (US-9853495) was filed on **November 25, 2014**. It was subsequently published and granted on **December 26, 2017**.\n\nThese dates are significant as they mark the official timeline for the patent's protection and public disclosure. The filing date establishes the priority date of the invention, while the publication date indicates when the technical details became publicly accessible. This allows other innovators and companies to understand the scope of the invention and its implications for future development in power management and electronic systems. Keywords: filing date, publication date, granted date, patent timeline, US-9853495, patent history.","question":"When was 'Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium' filed/granted?"},{"answer":"The commercial applications for the **Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium** are extensive, touching almost any product that incorporates complex electronic systems and requires high reliability. Key applications include:\n\n*   **Integrated Circuits (ICs) and Power Management Units (PMUs):** The technology can be integrated directly into PMICs or custom ASICs, offering a standardized, compact solution for manufacturers of various electronic components.\n*   **Server and Network Equipment:** Used in power supply modules and motherboards to enhance the stability and data integrity of critical data center infrastructure.\n*   **Embedded Systems:** Implemented in microcontrollers and single-board computers for industrial controls, robotics, and specialized computing where robust power handling is essential.\n*   **Automotive Control Units (ECUs):** Integrated into vehicle electronics for engine control, safety systems, and infotainment, ensuring dependable operation under varying power conditions.\n*   **High-Performance Computing:** Employed in desktop PCs, workstations, and gaming consoles to prevent crashes and extend hardware lifespan.\n*   **Consumer Electronics:** Utilized in high-end smartphones, tablets, and smart home devices to improve user experience by preventing glitches and prolonging device longevity.\n\nThis patent enables manufacturers to produce more reliable, durable, and efficient electronic products, leading to reduced warranty costs, enhanced brand reputation, and competitive differentiation in the market. Keywords: commercial applications, ICs, PMUs, server equipment, embedded systems, automotive ECUs, high-performance computing, consumer electronics, product reliability, market value.","question":"What are the commercial applications of 'Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium'?"},{"answer":"The **Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium** lays a foundational groundwork for several exciting future developments in power management and electronic system design:\n\n1.  **Standardization and Ubiquity:** The principles of this patent are likely to become a standard feature in power management ICs and multi-rail system designs, making robust capacitor discharge a default expectation rather than a specialized solution.\n2.  **Enhanced Integration:** We can expect tighter integration of this discharge logic within System-on-Chips (SoCs) and advanced PMUs, leading to even smaller footprints and higher efficiency in future designs.\n3.  **Adaptive Discharge:** Future iterations might incorporate adaptive control, where the discharge rate is dynamically adjusted based on real-time system conditions, capacitor health, or specific load requirements for even greater precision.\n4.  **Self-Healing Architectures:** The autonomous nature of this invention could contribute to the development of self-healing electronic systems that can intelligently manage and recover from power anomalies without external intervention.\n5.  **Application in Energy Harvesting:** The self-powered control concept could be adapted to more efficiently manage power buffering and discharge in intermittent energy harvesting systems, extending their reliability and operational duration.\n\nThese developments will collectively push the boundaries of electronic system resilience, enabling the creation of more intelligent, robust, and sustainable devices for the future. Keywords: future developments, standardization, integration, adaptive discharge, self-healing, energy harvesting, power management evolution, electronic design, patent future, US-9853495.","question":"What are the future developments expected for 'Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium'?"}],"topics":["discharge circuit","information processing apparatus","discharge method","storage medium","patent US-9853495","intricate","landscape","modern"],"tech_cluster":null},"seo":{"title":"Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium - US-9853495","description":"Explore the Discharge Circuit, Information Processing Apparatus, Discharge Method, and Storage Medium patent. Learn how this innovation enhances voltage stability and system reliability for information processing apparatuses, preventing data loss and component damage during power cut-offs. Detailed analysis of US-9853495.","keywords":["discharge circuit","information processing apparatus","discharge method","storage medium","patent US-9853495","power management","voltage stabilization","decoupling capacitor","system reliability","data integrity","electronic systems","power cut-off","charge discharge","power integrity"]},"attribution":{"source":"Patentable","source_url":"https://patentable.app","canonical_url":"https://patentable.app/patents/US-9853495","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-9853495","citation_suggestion":"Patentable. \"Discharge circuit, information processing apparatus, discharge method, and storage medium\" (US-9853495). https://patentable.app/patents/US-9853495","copyright_holder":"Nomic Interactive Technology LLC"},"links":{"html":"https://patentable.app/patents/US-9853495","json":"https://patentable.app/api/llm-context/US-9853495","site":"https://patentable.app","llms_txt":"https://patentable.app/llms.txt"},"generated_at":"2026-06-06T09:27:32.820Z"}