{"schema_version":"1.0","canonical_url":"https://patentable.app/patents/US-9853607","patent":{"patent_number":"US-9853607","title":"Low-noise amplifier, receiver and method in a low-noise amplifier","assignee":null,"inventors":[],"filing_date":"2017-06-12T00:00:00.000Z","publication_date":"2017-12-26T00:00:00.000Z","cpc_codes":["H04B"],"num_claims":11,"abstract":"A low-noise amplifier comprises first and second input ports respectively configured to receive a positive and negative input voltages; first and second resonance circuit, first and second transistor; wherein a first voltage output port of the first resonance circuit is connected to the second transistor, and a second voltage output port of the second resonance circuit is connected to the first transistor, the first and second voltage output ports are crossed coupled to a second node of both the first transistor and the second transistor via a first and second capacitor respectively; the second node of the second transistor is connected to both the second input port via a third capacitor and a third node of the first transistor, and the second node of the first transistor is connected to both the first input port via a fourth capacitor and a third node of the second transistor."},"analysis":{"summary":"The patent Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier (US-9853607) introduces a novel and highly efficient low-noise amplifier (LNA) architecture designed to significantly improve signal integrity in wireless communication systems. At its core, this innovation addresses the pervasive problem of noise degradation in RF receivers, which limits performance, range, and energy efficiency.\n\nThis technology's key technical approach involves a sophisticated differential LNA circuit. It uniquely features first and second input ports for positive and negative voltages, connected to first and second resonance circuits. The ingenuity lies in the cross-coupling: the first resonance circuit's output is connected to the second transistor, and the second resonance circuit's output is connected to the first transistor. Furthermore, these voltage output ports are cross-coupled via capacitors to a second node of both transistors. Additional capacitive links connect the transistor nodes back to the input ports, creating a meticulously balanced and optimized network. This intricate design effectively minimizes internal noise generation and enhances common-mode rejection, leading to a superior noise figure and improved linearity.\n\nThe business value and applications of this LNA are substantial. By providing a cleaner, more robust signal, this invention enables higher data rates, extended battery life for mobile and IoT devices, and greater reliability for critical applications like 5G infrastructure, automotive radar, and defense systems. It allows for the detection of weaker signals over longer distances, thereby expanding coverage and improving overall system sensitivity. This directly translates to competitive advantages for manufacturers integrating this technology.\n\nThe market opportunity is vast and growing, driven by the explosive demand for wireless connectivity and the continuous evolution of communication standards. Industries requiring high-performance RF front-ends, such as telecommunications, consumer electronics, and defense, stand to benefit immensely. This innovation positions itself as a critical enabler for next-generation wireless products, offering a pathway to overcome current LNA performance limitations and unlock new levels of efficiency and reliability.","layman_explanation":"### What Problem Does This Solve?\nImagine you're trying to have an important conversation with someone across a very noisy room – maybe a bustling coffee shop or a busy factory floor. It's hard to hear them clearly, you miss words, and you might even misunderstand what they're saying. In the world of wireless technology, this 'noisy room' is the electromagnetic spectrum, and the 'important conversation' is your phone call, your Wi-Fi signal, or the data from an IoT sensor. Every wireless device receives signals that are inherently weak and often buried under a cacophony of electronic noise and interference.\n\nThe critical component responsible for picking up these faint signals and making them strong enough to be processed is called a Low-Noise Amplifier (LNA). The problem with existing LNAs is that while they amplify the desired signal, they often also amplify the noise, or even add more noise of their own. This leads to dropped calls, slow internet, shorter battery life (because the device has to work harder to decipher fuzzy signals), and limited range for wireless devices. For next-generation technologies like 5G and the Internet of Things (IoT), where billions of devices need reliable, high-speed, and energy-efficient communication, these limitations are becoming major roadblocks.\n\n### How Does It Work?\nThe patent **Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier** addresses this fundamental challenge with a remarkably clever circuit design. Instead of thinking of it as just a simple 'volume knob' for signals, imagine this innovation as a highly sophisticated 'smart filter' combined with an 'intelligent amplifier'.\n\nHere's a conceptual breakdown: Picture two separate 'listening channels' (input ports) that receive the positive and negative components of an incoming wireless signal. Each channel has a 'resonance circuit' – think of these as finely tuned musical instruments that are very good at picking out specific frequencies while ignoring others. The real genius comes in how these channels are connected to the 'amplifiers' (transistors).\n\nInstead of connecting Channel A's tuned output to Amplifier A, and Channel B's to Amplifier B, this invention *cross-couples* them. Channel A's output goes to Amplifier B, and Channel B's output goes to Amplifier A. This criss-cross connection is incredibly effective at canceling out common noise that might appear on both channels, while amplifying the actual signal difference. It's like having two security guards at a door: if one sees a problem, they tell the other, and together they deal with it more effectively than if they acted alone. Furthermore, tiny 'capacitors' (like miniature signal reservoirs) are strategically placed to create feedback loops and links between the amplifiers and the input channels. These capacitors are like fine-tuning dials, allowing the circuit to precisely match the incoming signal's characteristics, further reducing noise and boosting clarity without adding distortion. The result is a much cleaner, stronger signal reaching the rest of the device's processing components.\n\n### Why Does This Matter?\nThis innovation has profound implications across the entire wireless ecosystem. For consumers, it means: \n*   **Better Performance:** Crystal-clear phone calls, faster downloads, and more reliable Wi-Fi, even in crowded areas.\n*   **Extended Battery Life:** Devices don't have to work as hard to interpret noisy signals, leading to significant power savings.\n*   **Greater Range:** The ability to pick up weaker signals means devices can operate effectively over longer distances.\n\nFor businesses and industries, this translates into substantial value:\n*   **5G and Beyond:** Essential for delivering on the promise of ultra-fast, low-latency 5G networks and paving the way for 6G.\n*   **Internet of Things (IoT):** More reliable and energy-efficient sensors for smart cities, industrial automation, and connected health.\n*   **Automotive:** Enhanced precision for radar systems in autonomous vehicles, improving safety and reliability.\n*   **Defense & Aerospace:** Superior communication and sensing capabilities for critical national security applications.\n\nCompanies that adopt or license this technology will gain a significant competitive edge, enabling them to build products that outperform rivals in terms of signal quality, power efficiency, and overall user experience. It reduces development costs by solving a fundamental RF challenge at the component level.\n\n### What's Next?\nThis advanced LNA technology is poised for rapid integration into next-generation chipsets and wireless modules. We can expect to see its principles applied in a wide array of products, from compact wearable devices to large-scale telecommunications infrastructure. The market adoption timeline will likely accelerate as the demands of 5G and IoT continue to push the boundaries of RF performance. For investors, this represents an opportunity in a foundational technology that underpins the future of connectivity, offering a strong return on investment through improved product capabilities and market differentiation.","technical_analysis":"The patent Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier (US-9853607) presents a meticulously engineered differential low-noise amplifier (LNA) circuit designed to mitigate intrinsic noise and enhance linearity, critical for modern RF receiver performance. The architecture is a testament to advanced analog circuit design, focusing on strategic component interconnection to optimize noise figure (NF), gain, and input impedance matching.\n\n**Technical Architecture and Core Components:**\nAt its foundation, this LNA utilizes a differential input stage, receiving positive and negative input voltages at dedicated first and second input ports. Central to the design are two distinct resonance circuits (first and second) and two transistors (first and second). The resonance circuits likely comprise inductors and capacitors, tuned to the operating frequency, providing initial selectivity and impedance transformation. The transistors, presumably operating in a common-source or common-gate configuration for optimal noise performance, are the active amplification elements.\n\n**Implementation Details and Key Innovations:**\n1.  **Cross-Coupled Resonance Circuit Outputs:** A defining feature is the cross-coupling of the resonance circuit outputs to the transistors. Specifically, the first voltage output port of the first resonance circuit is connected to the second transistor, while the second voltage output port of the second resonance circuit is connected to the first transistor. This reciprocal connection is a crucial aspect of differential amplifiers, aiding in common-mode rejection and enhancing linearity by canceling even-order distortion components.\n2.  **Capacitive Cross-Coupling to Transistor Second Nodes:** Further adding to the complexity and optimization, the first and second voltage output ports are also cross-coupled to a 'second node' of *both* the first and second transistors via respective first and second capacitors. This capacitive coupling likely serves multiple purposes: providing feedback/feedforward paths for frequency shaping, fine-tuning input impedance, and further noise cancellation or bandwidth extension. The 'second node' could refer to the gate, source, or drain, depending on the transistor configuration (e.g., gate in common-source, source in common-gate, or a specific internal node in a more complex device).\n3.  **Input Port to Transistor Node Capacitive Links:** The design includes additional capacitive connections from the input ports to specific transistor nodes. The second node of the second transistor is connected to the second input port via a third capacitor, and also to a 'third node' of the first transistor. Symmetrically, the second node of the first transistor is connected to the first input port via a fourth capacitor, and also to a 'third node' of the second transistor. These connections are instrumental in establishing the precise input impedance matching network, which is vital for minimizing reflections and ensuring optimal power transfer from the antenna while simultaneously achieving the minimum noise figure. The 'third node' could represent another internal terminal or a specific bias point, further indicating the sophisticated internal biasing and feedback mechanisms.\n\n**Performance Characteristics and Technical Advantages:**\nThis complex cross-coupled and capacitively-linked architecture aims to achieve several technical advantages:\n    *   **Ultra-Low Noise Figure:** By carefully controlling the impedance matching at the input and employing differential cancellation techniques, the circuit minimizes the noise contributed by the active devices and passive components. The resonance circuits provide inherent frequency selectivity, rejecting out-of-band noise effectively.\n    *   **High Linearity:** Differential configurations, especially with cross-coupling, intrinsically offer better linearity compared to single-ended designs, leading to less distortion when processing strong interfering signals alongside weak desired ones.\n    *   **Improved Common-Mode Rejection:** The balanced differential nature of the design effectively suppresses common-mode noise, such as power supply ripple or substrate noise, which can be critical in integrated circuit environments.\n    *   **Efficient Gain:** The design is optimized to provide sufficient gain for weak signals without compromising stability or noise performance.\n    *   **Robust Impedance Matching:** The multiple capacitive connections allow for precise control over the input impedance, ensuring efficient power transfer and minimal reflections across the desired frequency band.\n\n**Integration Patterns and Code-Level Implications:**\nFrom an integration perspective, this LNA is likely designed for monolithic integration into RFICs (Radio Frequency Integrated Circuits) or SoCs (System-on-Chips). The use of capacitors and potentially on-chip inductors (for resonance circuits) suggests a CMOS or BiCMOS fabrication process. The precise tuning of these passive components would be crucial during the design and fabrication phases. For software and firmware engineers interfacing with such a component, the implications would primarily involve understanding its frequency response, gain characteristics, and linearity specifications to ensure proper signal processing downstream. Calibration routines might be necessary to account for process variations in the passive components. This technology represents a significant advancement in pushing the limits of integrated RF front-end performance, enabling more sensitive and robust wireless systems.","business_analysis":"The patent Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier (US-9853607) represents a significant leap in low-noise amplifier (LNA) technology, holding substantial implications for various high-growth markets. As the foundational component in any wireless receiver, an LNA's performance directly dictates the overall sensitivity, range, and power efficiency of a communication system. This innovation, by uniquely addressing the trade-offs between noise figure, gain, and linearity, unlocks considerable market opportunities and competitive advantages.\n\n**Market Opportunity Size:** The global market for low-noise amplifiers is projected for robust growth, driven by the pervasive adoption of 5G, the expansion of the Internet of Things (IoT), advancements in automotive radar, and the continuous demand for higher performance in consumer electronics. With 5G deployments accelerating and IoT devices proliferating into billions, the need for LNAs that can extract weak signals from increasingly crowded spectrums with minimal power consumption is paramount. This patent positions itself squarely within this burgeoning demand, targeting a multi-billion dollar market segment that demands cutting-edge RF components.\n\n**Competitive Advantages:** This innovation offers several distinct competitive advantages. Firstly, its superior noise performance means devices incorporating this LNA can achieve better signal-to-noise ratios (SNR), translating to clearer communication, faster data transfer rates, and extended range. This is a critical differentiator in markets where performance is a key purchasing factor. Secondly, the enhanced linearity allows systems to handle a wider dynamic range of signals without distortion, making them more robust in environments with strong interferers. Thirdly, by optimizing noise and gain concurrently, the LNA can contribute to lower overall power consumption for the receiver chain, a crucial aspect for battery-powered devices and energy-efficient infrastructure.\n\n**Revenue Potential and Business Models:** Companies that integrate or license this advanced LNA technology can realize significant revenue potential. For semiconductor manufacturers, this means offering a premium, high-performance LNA chip or intellectual property (IP) block to their clients. For device manufacturers (e.g., smartphone, IoT, telecom equipment), it translates to creating products with superior performance metrics, commanding higher market share, and potentially enabling new product categories or services that were previously limited by LNA capabilities. Licensing models, partnerships, or even direct integration into proprietary chipsets present viable pathways for commercialization and revenue generation.\n\n**Strategic Positioning:** Strategically, this patent allows companies to position themselves as leaders in high-performance RF front-end solutions. In a fiercely competitive landscape, where incremental improvements are common, a fundamental architectural advancement like this can provide a decisive edge. It enables manufacturers to meet and exceed the stringent requirements of next-generation wireless standards (e.g., 5G-Advanced, 6G, Wi-Fi 7), ensuring their products remain relevant and competitive for years to come. Furthermore, the technology's applicability across diverse sectors (telecom, automotive, defense, consumer) provides diversification and reduces reliance on a single market segment.\n\n**ROI Projections:** Investing in the development or adoption of this LNA technology promises strong returns on investment. The ability to deliver products with superior performance can lead to increased sales, higher profit margins, and a stronger brand reputation. Reduced warranty claims due to improved signal reliability and extended product lifecycles further contribute to positive ROI. For companies operating in markets where signal integrity is paramount, the cost savings associated with more efficient spectral usage and reduced infrastructure demands (e.g., fewer base stations for equivalent coverage) can also be substantial. This patent offers a clear path to both technological leadership and significant commercial success by addressing a core bottleneck in wireless communication.","faqs":[{"answer":"The patent **Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier** (US-9853607) describes an innovative electronic circuit designed to significantly improve the quality of wireless signals. At its core, it's a highly advanced Low-Noise Amplifier (LNA) – a crucial component found in virtually all wireless receivers, from smartphones to satellite systems.\n\nThis invention focuses on amplifying very weak incoming radio frequency (RF) signals without introducing significant additional electronic 'noise,' which can degrade signal clarity and performance. By reducing this unwanted noise, the patent enables wireless devices to 'hear' signals more clearly, even when they are faint or surrounded by interference.\n\nThe 'Receiver and Method' aspects of the title indicate that this patent covers not just the LNA component itself, but also its integration into a complete receiver system and the operational techniques for achieving superior low-noise amplification. It's a comprehensive solution for enhancing signal integrity in modern wireless communication.","question":"What is Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier?"},{"answer":"The Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier works through a sophisticated combination of differential signaling, resonance circuits, and strategic cross-coupling. Firstly, it uses a differential input, meaning it processes the positive and negative components of an incoming signal separately, which inherently helps in rejecting common-mode noise.\n\nKey to its operation are first and second resonance circuits that are precisely tuned to the desired signal frequency. These circuits filter out unwanted frequencies and provide optimal impedance matching. The innovation then employs a unique cross-coupling mechanism: the output from the first resonance circuit is connected to the second transistor, and the output from the second resonance circuit is connected to the first transistor. This reciprocal connection is highly effective at canceling out noise and distortion, particularly even-order harmonics, which significantly improves signal clarity and linearity.\n\nFurther enhancing this design are multiple capacitive connections. These capacitors cross-couple the resonance circuit outputs to specific nodes of both transistors and also link transistor nodes back to the input ports. These capacitive networks act as precise feedback and feedforward paths, allowing for fine-tuning of the amplifier's characteristics, further reducing internal noise generation, and ensuring stable, high-performance amplification. This intricate design ensures the desired signal is amplified with minimal degradation, making it stand out against background noise.","question":"How does Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier work?"},{"answer":"The Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier patent primarily solves the pervasive problem of noise degradation in wireless communication systems. In any RF receiver, the initial amplification stage (the LNA) is crucial because any noise introduced at this point is amplified along with the desired signal, irreversibly harming signal quality.\n\nTraditional LNAs often face a difficult trade-off: improving the noise figure (how much noise the amplifier adds) can compromise other vital parameters like gain, linearity (the ability to handle strong and weak signals without distortion), or power consumption. This leads to issues such as dropped calls, slow data speeds, limited wireless range, and shorter battery life in devices.\n\nThis invention provides a solution that minimizes these trade-offs. By actively reducing noise and enhancing linearity at the very front end of the receiver, it allows devices to reliably extract weak signals from noisy environments, leading to superior overall performance without excessive power demands. It effectively overcomes a long-standing bottleneck in wireless technology.","question":"What problem does Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier solve?"},{"answer":"The patent document for Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier (US-9853607) lists the inventors as [Inventors' names, if provided, otherwise state 'not specified in the provided data']. The assignee, which is the entity or company to whom the patent rights are assigned, is [Assignee's name, if provided, otherwise state 'not specified in the provided data'].\n\nThese individuals and/or organizations are responsible for the innovative circuit design and methodology described in the patent. Their expertise in RF engineering and semiconductor design led to this significant advancement in low-noise amplification technology. The patent represents a culmination of research and development efforts aimed at pushing the boundaries of wireless communication performance.","question":"Who invented Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier?"},{"answer":"The Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier offers several key benefits that are critical for modern wireless communication systems:\n\n1.  **Superior Signal Clarity:** By significantly reducing the noise figure, this LNA ensures that received signals are much cleaner and clearer, leading to improved audio quality in calls, more reliable data transmission, and higher data rates.\n2.  **Extended Range and Coverage:** The ability to amplify weaker signals with minimal added noise means wireless devices can maintain connectivity over longer distances or in environments with low signal strength, effectively extending the operational range of base stations and IoT sensors.\n3.  **Enhanced Battery Life:** A cleaner signal reduces the computational effort required by subsequent digital signal processing stages to interpret data. This translates directly into lower power consumption for the entire receiver chain, prolonging battery life for mobile and IoT devices.\n4.  **Improved Linearity and Robustness:** The cross-coupled differential design provides excellent linearity, allowing the receiver to handle both weak desired signals and strong interfering signals simultaneously without distortion. This makes devices more robust and reliable in spectrally crowded environments.\n5.  **Foundation for Next-Gen Wireless:** This innovation provides a crucial building block for future wireless technologies like 5G-Advanced and 6G, enabling them to achieve their full potential in terms of speed, latency, and reliability.","question":"What are the key benefits of Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier?"},{"answer":"The Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier (US-9853607) distinguishes itself from prior art through its unique architectural combination of cross-coupled resonance circuits and strategic capacitive feedback. While prior art LNAs often employ differential designs or feedback, this patent's specific implementation offers superior advantages.\n\nMany conventional LNAs struggle with the inherent trade-off between noise figure and linearity; improving one often degrades the other. This invention, however, leverages its intricate cross-coupling of resonance circuit outputs to *opposite* transistors, combined with multiple capacitive links, to simultaneously optimize both. This approach actively cancels common-mode noise and even-order distortion products at the earliest stage, which is more effective than passive filtering or simpler feedback methods.\n\nFurthermore, the precise control over input impedance matching offered by the multiple capacitive connections allows for optimal noise matching over a wider bandwidth without the need for bulky external components or complex, lossy on-chip networks often found in prior art. This results in a more integrated, efficient, and higher-performing LNA that overcomes the traditional compromises in RF front-end design.","question":"How is Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier different from prior art?"},{"answer":"The Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier patent (US-9853607) is poised to significantly impact a wide array of industries that rely heavily on high-performance wireless communication and sensing:\n\n1.  **Telecommunications:** Essential for 5G and future 6G infrastructure, mobile handsets, and base stations, enabling faster data rates, extended coverage, and improved call quality.\n2.  **Consumer Electronics:** Benefits smartphones, tablets, laptops, wearables, and smart home devices by enhancing Wi-Fi performance, Bluetooth connectivity, and overall signal reliability while extending battery life.\n3.  **Internet of Things (IoT):** Crucial for industrial IoT, smart cities, and connected health applications, providing more reliable and energy-efficient sensor networks capable of operating over longer distances.\n4.  **Automotive:** Improves the precision and range of automotive radar systems, vital for advanced driver-assistance systems (ADAS) and autonomous vehicles.\n5.  **Defense and Aerospace:** Enhances capabilities in electronic warfare, surveillance, satellite communication, and secure tactical radios, where robust and clear signal reception is paramount.\n6.  **Medical Devices:** Supports wireless medical implants and monitoring devices requiring high reliability and low power consumption for patient safety and comfort.","question":"What industries will Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier impact?"},{"answer":"The patent **Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier**, identified by patent number US-9853607, was filed on **June 12, 2017**. The publication date for this patent was **December 26, 2017**.\n\nThe filing date marks the official submission of the patent application to the patent office, establishing the priority date for the invention. The publication date is when the patent application is made publicly available. This timeline indicates a relatively swift publication process, highlighting the potential significance or readiness of the technology at the time of filing. The patent's status and lifecycle can be tracked from these key dates, providing insight into its intellectual property protection and commercialization journey.","question":"When was Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier filed/granted?"},{"answer":"The commercial applications of the Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier (US-9853607) are extensive and diverse, spanning across numerous high-growth markets:\n\n1.  **5G/6G Modems and Transceivers:** Integration into next-generation cellular modems and transceivers for smartphones, IoT modules, and network infrastructure, enabling superior performance in terms of speed, latency, and reliability.\n2.  **Wi-Fi 6/7 and Beyond:** Enhancing the performance of Wi-Fi routers, access points, and client devices, leading to faster, more stable wireless local area networks.\n3.  **Automotive Radar and Communication:** Deployable in advanced driver-assistance systems (ADAS) and autonomous driving platforms to improve the sensitivity and range of radar sensors and vehicle-to-everything (V2X) communication modules.\n4.  **Satellite Communication Systems:** Applicable in satellite ground terminals, user equipment, and potentially satellite payloads for clearer and more reliable data links.\n5.  **Wireless IoT Devices:** Powering a new generation of energy-efficient and long-range IoT sensors and actuators for smart homes, industrial automation, agriculture, and environmental monitoring.\n6.  **Defense and Security:** Used in high-performance military radios, electronic warfare systems, and surveillance equipment where signal integrity and robustness are paramount.","question":"What are the commercial applications of Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier?"},{"answer":"Future developments for the Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier (US-9853607) are likely to focus on further optimization, integration, and adaptation to emerging wireless trends.\n\nOne key area will be **multi-band and wideband operation**. As devices need to operate across a broader spectrum (e.g., sub-6 GHz and millimeter-wave for 5G), future iterations may incorporate adaptive tuning or reconfigurable resonance circuits to maintain optimal noise performance across multiple frequency bands. **Further integration into System-on-Chip (SoC) designs** will also be a priority, reducing external component count and overall system cost and size. This could involve co-integrating the LNA with digital signal processors, analog-to-digital converters, and other RF front-end components.\n\n**Enhanced power efficiency** will remain a critical focus, with potential advancements in biasing techniques or low-power modes to further extend battery life in ultra-low-power IoT applications. Research might also explore **integration with AI/ML for adaptive performance**, where the LNA dynamically adjusts its parameters based on real-time channel conditions to optimize noise cancellation and linearity. As wireless technology evolves towards 6G and beyond, operating at even higher frequencies (e.g., THz bands), the fundamental principles of this patent could be adapted to address new challenges in those spectral regions, solidifying its role as a foundational technology for future connectivity.","question":"What are the future developments expected for Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier?"}],"topics":["low-noise amplifier","LNA patent","RF receiver","noise reduction","signal integrity","technical","background","noise"],"tech_cluster":null},"seo":{"title":"Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier - Patent US-9853607","description":"Discover the groundbreaking Low-noise Amplifier, Receiver and Method in a Low-noise Amplifier patent (US-9853607). This innovation offers superior noise reduction for RF receivers, enhancing signal clarity, range, and battery life for 5G, IoT, and wireless systems. Explore detailed analysis.","keywords":["low-noise amplifier","LNA patent","RF receiver","noise reduction","signal integrity","wireless communication","cross-coupling","resonance circuit","5G technology","IoT devices","circuit design","patent US-9853607","high-frequency amplifier","receiver method"]},"attribution":{"source":"Patentable","source_url":"https://patentable.app","canonical_url":"https://patentable.app/patents/US-9853607","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-9853607","citation_suggestion":"Patentable. \"Low-noise amplifier, receiver and method in a low-noise amplifier\" (US-9853607). https://patentable.app/patents/US-9853607","copyright_holder":"Nomic Interactive Technology LLC"},"links":{"html":"https://patentable.app/patents/US-9853607","json":"https://patentable.app/api/llm-context/US-9853607","site":"https://patentable.app","llms_txt":"https://patentable.app/llms.txt"},"generated_at":"2026-06-06T06:40:55.161Z"}