All IPs > Analog & Mixed Signal > Power Management
In the realm of Analog & Mixed Signal technologies, Power Management semiconductor IPs are a crucial component. These IPs are designed to efficiently manage and regulate power across various electronic systems, ensuring stability and reliability in device performance. At Silicon Hub, our catalog of Power Management IPs encompasses a broad spectrum of solutions tailored to meet the diverse energy management needs of modern electronic devices.
Power Management IPs are integral to controlling power consumption, extending battery life in portable devices, and enhancing energy efficiency in high-performance systems. These IPs are used in a wide array of applications, from consumer electronics like smartphones and tablets to industrial equipment and automotive systems. They help in voltage regulation, current routing, power sequencing, and energy harvesting, ensuring that devices operate optimally under varying conditions.
The product range within this category includes voltage regulators, DC-DC converters, power switches, and battery management systems. Each of these solutions is designed to optimize power delivery and consumption, reducing heat generation and improving the overall lifespan of electronic components. As devices become increasingly power hungry with the adoption of more complex functionalities, efficient power management becomes essential. Our Power Management semiconductor IPs provide the necessary tools to tackle these challenges effectively.
By integrating our cutting-edge Power Management IPs, designers can achieve significant performance enhancements in their products. Whether designing for mobile devices that require sophisticated power management to maximize battery life or developing complex industrial systems that need robust voltage management, these semiconductor IPs offer reliable solutions. Explore the wide range of Power Management IPs available at Silicon Hub, your go-to source for innovative semiconductor solutions.
Silicon Creations' Analog Glue solutions provide essential analog functionalities to complete custom SoC designs seamlessly. These functional blocks, which constitute buffer and bandgap reference circuits, are vital for seamless on-chip clock distribution and ensure low-jitter operations. Analog Glue includes crucial components such as power-on reset (POR) generators and bridging circuits to support various protocols and interfaces within SoCs. These supplementary macros are crafted to complement existing PLLs and facilities like SerDes, securing reliable signal transmission under varied operating circumstances. Serving as the unsung heroes of chip integration, these Analog Glue functions mitigate the inevitable risks of complex SoC designs, supporting efficient design flows and effective population of chip real estate. Thus, by emphasizing critical system coherency, they enhance overall component functionality, providing a stable infrastructure upon which additional system insights can be leveraged.
The REFS, a robust band-gap and PTAT current reference, is designed to bolster RF, analog, and mixed-signal integrated circuits with significant stability even across varied operational conditions. This component outputs currents and voltages that remain consistent against temperature fluctuations, making it indispensable in high-precision electronic environments. It features multiple outputs referenced to both internal and external resistors, all of which are programmable within a flexibility range of ±30% to support custom calibration needs.
Aeonic Power revolutionizes power delivery in SoCs with on-die voltage regulation, optimizing energy use and reducing bill of materials. This IP family is highly configurable and offers deep insights into power behavior through advanced telemetry capabilities. Suitable for a range of requirements, Aeonic Power solutions improve robustness in power delivery networks by addressing factors like dynamic voltage scaling and IR drop mitigation. The flexibility and observability provided by Aeonic Power facilitate energy optimization and reliability for next-gen chip designs.
The MVPM100 Series offers cutting-edge particulate matter sensors that excel in compactness and accuracy, designed specifically for detecting PM2.5 particles. Leveraging advanced microsystem technology, these sensors measure the mass of particles directly, a method that provides superior precision compared to conventional optical sensors. Their versatile interface options and minimal power requirements make these sensors an ideal choice for a wide array of applications, with particular utility in environments that demand reliable air quality monitoring. These sensors cater to industrial, consumer, medical, and automotive sectors, ensuring broad applicability. The MVPM100’s compact form factor and robust design mean they are suitable for integration within various systems, offering consumer and industry professionals a trusted technology for high-quality particulate detection.
The Dual-Drive™ Power Amplifier FCM1401 is engineered to deliver superior efficiency and performance, specifically designed for demanding RF and mmWave applications. This amplifier distinguishes itself with its ability to produce more RF power while minimizing heat production, making it ideal for applications that require high thermal management. Key to its performance is the patented Dual-Drive™ architecture, which enhances output power and bandwidth significantly. This results in reduced need for large cooling systems and oversized batteries, making it a lighter and more energy-efficient solution. The design is process-agnostic, silicon-proven, and features a small silicon footprint, ensuring high adaptability in various applications. The FCM1401 is built to offer a seamless integration with plug-and-play functionality, allowing for straightforward implementation in existing systems. This makes it a versatile choice for sectors like satellite communications, telecom, and defense, where robust and efficient RF power solutions are critical. The advanced design flow aligns precisely with real-world measurements to within a 2% margin, ensuring reliability and performance consistency.
The MVH4000 Series are highly precise sensors for measuring relative humidity and temperature. These sensors are engineered using advanced Silicon Carbide MEMS technology, providing excellent long-term stability and reliability. With a swift response time and minimal power consumption, they are perfect for applications requiring fast and accurate environmental monitoring. These compact sensors, ideal for critical PCB real estate, include on-chip calibration, enabling straightforward integration into existing systems. Each sensor in the series offers different accuracy grades and outputs, allowing users to select the model that best fits their needs. The sensors' digital (I2C) or analog outputs ensure compatibility with a wide range of systems. Notably, their long-term stability and accuracy contribute to lowering the total cost of ownership, making them a cost-effective choice for industrial, consumer, medical, and automotive applications. The MVH4000 Series also come in a compact form factor of 2.5 x 2.5 x 0.9 mm, making them easy to fit into space-constrained devices. Additionally, the sensors’ robust design supports a broad operating temperature range from -40 to 125°C, making them suitable for diverse environments and demanding applications.
This Voltage-mode Buck Converter is a potent solution for managing power efficiently within embedded systems. With output current support ranging from 800mA to 1.5A, it operates across input voltages of 2.7V to 5.5V while providing output voltages from 0.6V to 2.5V. Designed for high efficiency with ground currents below 30µA, it is silicon-proven and built utilizing Magna's 180nm and 130nm technology nodes. Its wide range of operations and stringent efficiency marks make it an essential component for power-sensitive applications.
The MVUM1000 is a state-of-the-art ultrasound sensor array tailored for medical imaging applications. This linear array comprises up to 256 elements and is based on capacitive micromachined ultrasound transducers (CMUT), providing exceptional sensitivity and integrability with electronic interfaces. Boasting multiple imaging modes, such as time-of-flight and Doppler, these sensors can address a variety of medical diagnostic needs including point-of-care and handheld devices. The low power consumption combined with high sensitivity makes these sensors highly efficient for portable medical equipment. Functional across a wide range of frequencies, the MVUM1000 supports medical imaging with precision, offering device manufacturers flexibility in design with the possibility of integrating front-end electronics. It opens up new avenues for innovation in ultrasound technology while catering to ever-growing portable healthcare needs.
EnSilica’s eSi-Analog suite offers a broad array of Analog IP solutions essential for integrating analog functions into custom ASIC and SoC devices. Proven across various process nodes, these solutions are renowned for their performance, power efficiency, and adaptability to customer specifications, thereby expediting time-to-market and lowering costs. With an extensive range of easy-to-integrate IPs, eSi-Analog encompasses high-performance blocks like oscillators, SMPSs, PLLs, LDOs, and more, each optimized for low power consumption and high resolution. The flexibility of this IP suite allows for adaptation to various application needs, supporting industries as diverse as automotive and healthcare with critical analog capabilities. Specialized in enabling SoC platforms with robust analog interfaces, this IP package features components like temperature sensors and ultra-low power radios. The solutions in eSi-Analog are designed to integrate seamlessly across major foundry technologies, offering a competitive edge for customers seeking to enhance system performance with reliable analog solutions.
The mmWave PLL is a sophisticated phase-locked loop tailored for millimeter-wave frequencies, playing a crucial role in high-frequency applications such as 5G and beyond. It delivers exceptional frequency stability and low phase noise, which are vital for maintaining signal integrity in advanced communication systems. This product is engineered to handle the complexities of mmWave spectrum, providing precise frequency control necessary for next-generation wireless networks. Its capability to operate at high frequencies makes it an ideal fit for telecom infrastructure and consumer devices aiming to benefit from the expanded bandwidth of mmWave technology. The mmWave PLL is optimized for integration into compact designs, reducing overall system size while enhancing performance quality. By utilizing process technology that supports high-speed operations, the mmWave PLL ensures reliability and efficient energy use. With its precision engineering, the mmWave PLL is a critical component for companies looking to leverage mmWave spectrum advantages, offering the substantial benefits of improved data rates and connectivity. It is an essential element in RF module design, setting a new standard for high-frequency operation versatility across various sectors.
Functioning as a comprehensive cross-correlator, the XCM_64X64 facilitates efficient and precise signal processing required in synthetic radar receivers and advanced spectrometers. Designed on IBM's 45nm SOI CMOS technology, it supports ultra-low power operation at about 1.5W for the entire array, with a sampling performance of 1GSps across a bandwidth of 10MHz to 500MHz. The ASIC is engineered to manage high-throughput data channels, a vital component for high-energy physics and space observation instruments.
Archband Labs' Cap-less LDO Regulator is crafted to offer excellent power regulation without the need for external capacitors. It is suited for a variety of compact electronic devices that require efficient voltage stabilization. This regulator stands out due to its minimal footprint and power consumption, making it an ideal solution for portable and space-constrained applications. It ensures stable voltage output and reduces noise, offering a high level of interference immunity which is critical in maintaining the performance of sensitive electronic components. With its focus on energy efficiency, the Cap-less LDO Regulator is engineered to provide consistent output even under variable load conditions. The simplicity of not requiring external components also reduces the overall system cost and design complexity, aiding in quicker development cycles and more robust device longevity.
The PLL12G, serving as a Clock Multiplication Unit, is engineered to generate clock outputs in the 8.5GHz to 11.3GHz range, complementing a host of transceiver standards like 10GbE and OC-192. It operates with low power consumption, courtesy of IBM's 65nm process, making it suitable for various clocking modes crucial in phase-locked loop systems. Its diverse functionality ensures it's integral to telecommunications infrastructures where multiple clocking modes, including FEC support, are required.
The BCD Technology for Power Management by Tower Semiconductor integrates the benefits of bipolar, CMOS, and DMOS technologies in a single platform, tailored for power management applications. This pioneering approach delivers efficient power handling, superior driving capability, and excellent performance in various operating environments. By integrating these technologies, BCD provides flexibility and functionality for designing complex power management ICs. The bipolar component ensures robust amplification, while CMOS and DMOS elements provide high-density logic and efficient power conversion, respectively. This blend is vital for applications requiring both digital control and power regulation. Tower Semiconductor's BCD technology is specially crafted for high reliability, emphasizing its extensive operational compatibility and reduced time-to-market for new products. Designed for longevity and performance, this technology addresses the diverse requirements of power-intensive applications across multiple sectors.
The MVDP2000 Series showcases a line of highly sensitive differential pressure sensors designed for precision and robustness in demanding environments. These sensors apply a proprietary capacitive sensing technology that ensures digital calibration across temperature and pressure variables, thus enhancing accuracy and reliability. With a compact size and power efficiency, the MVDP2000 sensors are ideal for applications requiring fast response and low power usage, such as portable and OEM devices. Their range of use includes respiratory equipment, gas flow instruments, and pressure monitoring systems in various industries. These sensors provide quick analog and digital outputs with resolutions between 15 to 21 bit, maintaining an error band of less than 1% FS. Their broad operating range and low power draw further bolster the sensors’ applicability, catering especially to consumer and medical industries.
The XCM_64X64_A is a powerful array designed for cross-correlation operations, integrating 128 ADCs each capable of 1GSps. Targeted at high-precision synthetic radar and radiometer systems, this ASIC delivers ultra-low power consumption around 0.5W, ensuring efficient performance over a wide bandwidth range from 10MHz to 500MHz. Built on IBM's 45nm SOI CMOS technology, it forms a critical component in systems requiring rapid data sampling and intricate signal processing, all executed with high accuracy, making it ideal for airborne and space-based applications.
The agileREF consists of a bandgap reference core together with a bandgap reference voltage generator (VREF), VREF replica current generators and bias current generators. The number of output bias currents can be specified up to a maximum of 16 configurable outputs. Agile Analog designs are based on tried and tested architectures to ensure reliability and functionality. Our automated design methodology is programmatic, systematic and repeatable leading to analog IP that is more verifiable, more robust and more reliable. Our methodology also allows us to quickly re-target our IP to different process options. Our highly configurable and multi-node analog IP products are developed to meet the customer’s exact requirements. These digitally-wrapped and verified solutions can be seamlessly integrated into any SoC, significantly reducing complexity, time and costs.
Designed for high-capacity data transfer over fiber optic networks, the SER12G facilitates 32:1 serialization for robust telecommunications. Capable of sustaining data rates from 8.5Gb/s to 11.3Gb/s, this module is essential for SONET/SDH and 10GbE operations, embracing IBM's 65nm CMOS technology. The design boasts low power requirements and integrates CMU and frac N PLL, making it suitable for both line and host side transmission, effectively enhancing data throughput and signal integrity.
The CurrentRF CC-100 Power Optimizer is central to the company's innovative energy harvesting technology, utilized in devices like the PowerStic and Exodus. This optimizer is engineered to be a fundamental component in intercepting digital noise currents and recycling them back into the system, effectively reducing operational power. It supports the enhancement of system battery life by up to 40%, serving as a critical device in power-conscious design strategies for integrated circuits and electric vehicles. The CC-100 ensures power savings when systems remain active, making it a vital tool for extending battery life in IC and systems design.
TechwidU's Band-Gap Reference provides a stable voltage output ranging from 0.6V to 1.2V, crucial for ensuring the reliable operation of electronic circuits. This component is pivotal in generating a consistent reference voltage across variations in environmental conditions such as temperature and power supply changes. Designed with Magna, Samsung, and TSMC’s advanced nodes, it promises precision and efficiency with an operational current of 25µA.
Bridging complex data communication requirements, the SERDES12G offers comprehensive serialization/deserialization capabilities, supporting 32:1 and 1:32 operations at speeds of 8.5Gb/s to 11.3Gb/s. With robust low power features, its design leverages IBM's 65nm technology, vital for SONET/SDH and XFI protocols in modern telecommunication systems. By integrating CDR and CMU, it provides high performance and stability, ensuring seamless data handling across a wide array of applications.
The agileLDO is a linear low drop-out (LDO) voltage regulator providing precision and programmable voltage regulation across a wide range of input and output voltages. The regulator architecture provides a high dynamic performance making it suitable for demanding digital applications. Whilst the low noise and high PSRR lends itself to powering noise-sensitive analog circuits. Agile Analog designs are based on tried and tested architectures to ensure reliability and functionality. Our automated design methodology is programmatic, systematic and repeatable leading to analog IP that is more verifiable, more robust and more reliable. Our methodology also allows us to quickly re-target our IP to different process options. Our highly configurable and multi-node analog IP products are developed to meet the customer’s exact requirements. These digitally-wrapped and verified solutions can be seamlessly integrated into any SoC, significantly reducing complexity, time and costs.
Certus Semiconductor's Analog I/O offerings bring ultra-low capacitance and robust ESD protection to the forefront. These solutions are crafted to handle extreme voltage conditions while securing signal integrity by minimizing impedance mismatches. Key features include integrated ESD and power clamps, support for broad RF frequencies, and the ability to handle signal swings below ground. Ideal for high-speed RF applications, these Analog I/Os provide superior protection and performance, aligning with the most demanding circuit requirements.
TechwidU’s General-purpose Power-on Reset (POR) module ensures reliable initialization of electronic devices, safeguarding their functionality from erroneous starts. It monitors the supply voltage, guaranteeing that digital circuits and systems only begin operation once suitable power conditions are achieved. Silicon-proven across multiple foundry processes, this POR is available through various manufacturing nodes, enhancing compatibility and reliability across diverse electronic frameworks.
The VR-3V3-1V2-1-55-U is a specialized voltage regulator designed to efficiently downscale a 3.3V input to a 1.2V output, with impressive power conservation features marked by a minimal quiescent current of only 1.8μA. This regulator exemplifies a balance between performance and energy efficiency, making it ideal for applications with stringent power requirements. Prominent in its design is its capacity to sustain operations with minimal power wastage, a trait crucial in devices where power efficiency directly correlates to battery life. Its ability to regulate voltage with precision makes it essential in maintaining system stability and performance, especially in environments where reliability is paramount. This voltage regulator accommodates varied electronic setups by providing a consistent power supply that adheres to strict voltage mandates. Its deployment facilitates the optimization of power distribution across circuits, ultimately aiding in extending device longevity and operational efficiency.
Advanced Silicon's High-Voltage ICs are specialized for driving TFT technology, well suited for turning on/off thin film switching devices. These ICs include digital-to-analog converters (DACs) capable of managing high output grey scales and voltage levels, critical for various display technologies and MEMS devices. Whether it's amorphous silicon, poly-silicon, or IGZO, these HV ICs are versatile for several thin film materials. Their robustness makes them ideal for applications requiring high-pin count, such as elaborate digital flat panel X-ray detectors where radiation hardness is crucial. By delivering up to 512 output channels in COF packaging, our line drivers simplify complex system requirements. For more precision, our digital-to-analog source drivers provide fine voltage control, essential for large pixel capacitive loads in flat panel display setups, featuring DAC resolutions of up to 1024 levels. In essence, these HV ICs are indispensable for modern display technologies, ranging from LCDs to advanced OLEDs and microLED displays. Their capability to manage precise voltage applications across diverse TFT setups ensures their value in today's high-tech landscape.
This high-capacity Voltage-mode Buck Converter handles a significant output current of 3A and is engineered for applications needing substantial power conversion capabilities. Designed for seamless operation with input voltages from 4.5V to 48V and output voltages between 5V to 20V, it is constructed using X-FAB's 180nm node. Such specifications make it a linchpin in systems that deal with wide voltage range applications, guaranteeing high efficiency and precision.
A powerful solution within the buck converter category, this Current-mode Buck Converter provides a consistent output current of 2.5A. It supports input voltages ranging from 2.7V to 5.5V and offers output voltages between 0.6V to 2.5V. The highly efficient design ensures ground currents remain under 30µA, with precision managed at an accuracy of 1.5%. Developed using Samsung's robust 65nm process node, this converter is silicon-proven and ideal for applications requiring steady power supply and efficient operation under varying loads.
The CurrentRF PowerPad is an innovative IP embedded solution aimed at reducing dynamic power in semiconductor designs. It serves as a replacement for traditional IC power and ground bond pads, integrating seamlessly without significantly increasing IC area. This IP allows for efficient energy harvesting and reduction in IC operating power, contributing to extended battery life and overall system efficiency. By leveraging techniques such as capacitance multiplication and series inductance nullification, the PowerPad is optimized for power-conscious technology applications and eco-friendly IC designs.
The RFicient chip is an innovative solution developed by Fraunhofer IIS, aimed at advancing the Internet of Things (IoT) connectivity. Designed with efficiency in mind, this chip enables significant power savings, reducing consumption by 99% compared to traditional systems. This allows for prolonged operation of IoT devices without frequent recharging or battery replacement, making it ideal for remote and hard-to-reach locations where power sources are scarce. The chip excels in facilitating robust communication within the IoT ecosystem, handling extensive data transfer from numerous devices seamlessly. It supports various IoT applications by enabling reliable data transmission over long distances, ensuring devices remain interconnected without interruption. Additionally, the chip's design allows it to operate effectively even in energy-scarce environments, aligning with rising demands for sustainable technology that supports the global shift towards greener practices. Technical advancements in the RFicient chip underline its competitive edge in IoT applications. Not only does it contribute to the reduction of carbon footprints by prolonging device operational times, but it also opens new fronts for IoT deployment in areas previously constrained by energy limitations. By integrating this chip, businesses and service providers can boost their IoT infrastructure's resilience and adaptability, ensuring continuous service delivery and operational efficiency.
This Cap-less Low-Dropout Regulator (LDO) by TechwidU is unique for its ability to function without external capacitors while delivering a stable current supply of 100mA. Supporting input voltages between 1.7V and 5.5V and maintaining output voltages from 0.8V to 4V with just 2% accuracy variation, it is perfect for compact designs. Built on the well-regarded Magna node at 180nm and 130nm, the cap-less design reduces overall system complexity and conserves board space.
The Bandgap Voltage Reference from X-FAB ensures high stability and precision in voltage references, an essential component for many analog and digital circuits. This device outputs a consistent 1.2V voltage and a current reference of 1uA, providing a reliable foundation for voltage regulation and current sourcing applications. Designed for high accuracy, the Bandgap Voltage Reference can be deployed in a variety of applications including power management, sensor technologies, and general-purpose electronic designs. Its operational stability over a wide range of temperatures and conditions makes it an indispensable tool in creating reliable semiconductor solutions. Utilizing leading edge manufacturing techniques, this reference device delivers reliable performance, which is crucial for ensuring the overall integrity of complex embedded systems. The combination of precision and stability makes it a preferred choice for engineers seeking robust voltage regulation components.
The agilePOR is a power-on-reset circuit. Based on a traditional architecture, it allows for programmable thresholds for normal and low power modes, programmable delays and includes hysteresis to avoid false resets in noisy environments. Agile Analog designs are based on tried and tested architectures to ensure reliability and functionality. Our automated design methodology is programmatic, systematic and repeatable leading to analog IP that is more verifiable, more robust and more reliable. Our methodology also allows us to quickly re-target our IP to different process options. Our highly configurable and multi-node analog IP products are developed to meet the customer’s exact requirements. These digitally-wrapped and verified solutions can be seamlessly integrated into any SoC, significantly reducing complexity, time and costs.
Goliath is an advanced solid-state battery technology from Ilika, designed for electric vehicles and cordless consumer electronics. This technology features an oxide solid electrolyte combined with a silicon anode, ensuring enhanced safety during production, storage, and usage. Unlike lithium-ion batteries, Goliath allows for operation at higher temperatures, reducing the complexity of battery management systems. This results in a safer solution with increased energy and power density, enabling extended range and rapid charging capabilities. The Goliath batteries promise a future of seamless electric transportation by focusing on a higher cell-to-pack ratio, contributing to lighter vehicles that maintain strong performance. The innovation behind Goliath lies in its approach to safety without sacrificing power, providing a cutting-edge alternative suitable for the demanding requirements of next-generation electric vehicles. The expansion and scale-up of Goliath are central to Ilika's strategic plans. The company aims to transition to giga-scale production after initial infrastructure expansions designed to accommodate MWh-level manufacturing. This growth plan is supported by comprehensive partnerships with major industrial players, ensuring that Goliath remains at the forefront of automotive energy solutions.
The Fractal-DTM Amplifier by SiliconIntervention addresses the critical need for highly efficient Class-D drivers across diverse power levels. This architectural marvel boasts a self-adjusting capability that ensures peak efficiency, adapting seamlessly to various operational ranges. The innovative design underpins a wide array of applications, offering significant enhancements in power management without compromising on performance. Through SiliconIntervention’s proprietary technology, this amplifier redefines expectations in the amplifier market by delivering adaptive performance that sets a new standard for versatility in handling dynamic power requirements. It stands as an exemplary model of how intelligent design can revolutionize device efficiency, essential for future-forward consumer and industrial applications. The Fractal-DTM Amplifier not only elevates operational efficiency but also extends its capabilities to versatile applications, making it a valuable asset for developers seeking cutting-edge performance and environmental adaptability. Its implementation is a testament to SiliconIntervention’s commitment to pioneering innovative solutions within the analog domain, demonstrating an important leap in analog signal processing technologies.
The SPIDER Power Management Platform is a state-of-the-art solution designed to enhance energy efficiency for System-on-Chip (SoC) designs. Available across various process nodes, SPIDER integrates voltage regulators, low-frequency oscillators, and voltage monitors to ensure reliable power supply for active and always-on domains. This platform is celebrated for its ability to extend battery life utilizing low quiescent currents ideal for deep-sleep modes and high efficiency for active modes. Additionally, its comprehensive offerings include adaptive body biasing (ABB) to unlock optimal performance, yielding exceptional energy savings and reliability. SPIDER's versatile nature allows for direct battery or USB connections, accommodating an input voltage up to 5.5V. This ability reduces cost by enabling a single DC/DC converter to support multiple domains with low-cost and compact components. The platform is meticulously designed with advanced features like automated regulator control, power/clock gating, and voltage scaling, facilitating effortless implementation of efficient power networks. One of the central highlights of the SPIDER platform is its capability to supply both always-on and active domains from a single DC/DC buck converter, supporting various input energy sources such as Lithium-ion or Alkaline batteries. Overall, SPIDER represents a comprehensive power management solution aimed at maximizing SoC performance through efficient energy utilization.
This 16mA 4V Voltage Regulator ensures stable and reliable voltage supply for electronic devices, optimized to handle specific power requirements efficiently. Its design focuses on delivering consistent power output with minimal deviation, suitable for use in portable devices and embedded systems where power stability is crucial.
TechwidU's general-purpose Low-Dropout Regulator (LDO) is a standout in power management, offering a flexible output current range from 150mA to 450mA. With input voltage ranging from 1.7V to 5.5V, and an output voltage range of 0.8V to 4V, this silicon-proven LDO maintains low ground current to enhance efficiency. It is a versatile solution ideal for various applications needing stable voltage supply and has been precisely fabricated using the Magna process at 180nm and 130nm nodes.
The CC-100IP RF is designed to mitigate RF emissions within integrated circuit power grids. This on-chip solution not only reduces emissions but also enhances cybersecurity measures by decreasing up to 40% of digital dynamic currents. By establishing the lowest impedance point within the power grid, the CC-100IP RF achieves significant improvements in supply filtering efficiency, boasting up to a 600-fold increase in reservoir capacitance. This robust RF and EMI reduction capability within IC power grids positions it as a crucial asset in maintaining optimal operational conditions.
This General-purpose Power-on Reset module by TechwidU is critical for securing proper start-up in electronic devices, especially under unstable power conditions. Designed using Samsung's 65nm process technology, it functions by assuring system components are reset into a known state during power-up which prevents erroneous operation. Its reliable operation across different systems makes it an essential inclusion in power management controls.
Crest Factor Reduction technology is pivotal for streamlining power supply design requirements in RF Power Amplifiers. By reducing peak power demands, it translates into less stressful operating conditions for devices, improving both performance and lifespan. CFR technology is central to maintaining amplitude levels within defined limits, thus preventing distortion and inefficiencies in signal processing. This technology optimally aligns with the operational parameters of RF systems, ensuring a balance between performance and cost-effectiveness. Its implementation means that equipment can achieve higher throughput with reduced energy consumption, benefiting both urban and remote communication setups. The resulting operational efficiency brings forth advantages in application areas such as telecommunications and broadcast networks. In practice, CFR assists in mitigating the effects of signal peaks that can otherwise lead to power losses and signal degradation. It ensures that the amplification process is continuous and seamless, essential for environments with multiple and potentially overlapping signals, maintaining quality and reliability.
The Power Management IC from CoreHW is an innovative component designed to enhance the efficiency and performance of electronic devices by optimizing power usage. Its integrated circuit solutions provide precise management of voltage, current, and power, contributing significantly to extending battery life and device reliability. This makes it ideal for mobile, portable, and energy-sensitive applications. CoreHW's Power Management IC is built to support high-efficiency energy regulation, featuring advanced technology that minimizes energy waste while maximizing performance output. The design encompasses features such as dynamic power scaling and thermal management, crucial for reducing the thermal footprint of electronic systems. This allows devices to operate efficiently even under strenuous conditions, ensuring longevity and stability. Versatile in its application, the Power Management IC is employed across various sectors, including consumer electronics, automotive, and telecommunications. Its compact size and functional flexibility make it a preferred choice for developers seeking integrated solutions without compromising on performance. The IC's robust design ensures it can handle the complexities of modern electronic systems effectively.
The pPOR01 is a critical Power-On Reset solution that ensures safe initialization of digital circuits by monitoring the supply voltage levels. This IP plays a fundamental role in maintaining system stability by generating a reset signal whenever the power supply deviates from specified thresholds, thus safeguarding against unexpected power fluctuations. Effectively designed for use in various digital logic environments, the pPOR01 offers a reliable method to ensure system integrity and operational correctness upon power-up. Its features include precise voltage sensing, minimal power consumption, and easy integration into diverse semiconductor processes, affirming its adaptability to various applications and technologies. The pPOR01's robust architecture is aimed at maximizing compatibility and performance across different power supply conditions, making it a vital asset in the arsenal of any digital designer looking to bolster the reliability and performance of their system's power management strategy.
Rezonent's Energy Recycling System is crafted to curtail the escalating power consumption within semiconductor chips, serving industries from consumer electronics to high-computation environments like AI and data centers. The technology captures energy, traditionally lost as heat, using integrated on-chip inductors, which recycle this energy back into the system, thereby reducing overall power needs. This innovative method weaves RF analog techniques with high-speed digital switching across vital circuits such as Clock, Data, and Memory. This recycling process significantly boosts efficiency, achieving over 30% power savings without a drop in performance, thus offering a cost-effective way to maintain system integrity while adapting to next-generation performance standards. Beyond power conservation, the Energy Recycling System also facilitates a seamless transition for companies aiming to minimize their carbon footprint. The system’s ability to integrate easily with new and existing semiconductor architectures makes it a versatile solution for those looking to comply with both immediate and future energy regulations. It stands not only as a technological advance but as a measure towards broader environmental objectives.
A comprehensive photonic interconnect that delivers exceptionally high data throughput across various communication channels. It integrates seamlessly with existing systems to enhance performance in broadband applications. Designed for scalability, it supports significant data loads without compromising speed or reliability. Featuring low power consumption, its operation is both cost-effective and environmentally sustainable. The integration helps eliminate bottlenecks typically associated with high-volume data transfer, ensuring smooth and efficient data management across platforms.
Specializing in ESD protections, Certus Semiconductor offers highly adaptive solutions that meet various operational demands. These circuits provide enduring defense against ESD threats, surpassing traditional HBM and CDM specifications. Capabilities include low capacitance solutions and customized protections tailored to endure voltages between -18V to +30V. These ESD circuits are integrated with specialized features like Rad-Hard technology, high-temperature resilience, and enhanced burst immunity, setting a standard for highly secure semiconductor solutions in harsh environments.
Nexperia's SiC Schottky Diode is engineered for high-efficiency power conversion and rectification tasks. It leverages silicon carbide material to achieve lower forward voltage drop and reduced power losses, making it a preferred choice for power converters and inverters. This diode's capability to operate at higher junction temperatures enhances its reliability in demanding industrial and automotive applications. One of the defining characteristics of the SiC Schottky Diode is its enhanced switching speed, which minimizes power loss and improves overall efficiency. This attribute not only aids in energy savings but also supports the compact design of modern electronic systems by enabling smaller passive components. Suited for applications like power factor correction (PFC) and photovoltaic inverters, this diode plays a crucial role in enhancing the performance of electronic systems where efficiency and thermal management are paramount. Its robust design ensures long-term operational stability, even under fluctuating environmental conditions.
The SGC21412 presents itself as an advanced power controller, offering an array of functionalities including Power on Reset (POR), making it a foundational component within Power Management Units (PMUs). Designed for integration into SoC systems, it provides pivotal support functions such as Under Voltage Lock Out (UVLO), start-up sequencing, and efficient power monitoring. This controller excels in precision with a better than 1% voltage reference accuracy, attributed to its digital trimming capabilities that allow fine-tuning across line, temperature, and process variations. Engineered to function impressively even without external decoupling capacitors, it simplifies design while maintaining high-stability outputs across its input voltage range from 1.6V to 3.6V. Flexibility defines the SGC21412, allowing it to drive multiple regulated voltages and diverse reset signals essential for complex PMU environments. Its significant power rejection capability and compact build stand out, adding robust power management to modern integrated systems.
The NSF030120 SiC MOSFET is designed to deliver superior efficiency and robustness in high-power applications. Its silicon carbide technology enables it to withstand higher thermal stress compared to traditional silicon alternatives, making it ideal for power-intensive environments. This MOSFET offers lower switching losses, which enhances energy efficiency and reliability, critical for applications such as power inverters and electric vehicle systems. With an emphasis on improving power conversion efficiency, the NSF030120 excels in environments demanding continuous high performance. Its efficient thermal management capabilities make it suitable for both industrial and automotive applications, where it significantly boosts power density and system reliability. The NSF030120 SiC MOSFET suits various applications, from renewable energy setups to automotive power trains. Its ability to handle extreme temperature variations and reduce system overheads makes it indispensable in designing next-generation electronics systems.
Omni Design's linear regulators and bandgap reference solutions are developed to provide robust power management for high-speed semiconductor applications. These components utilize advanced control methodologies to deliver excellent transient response and low noise, crucial for high-performance data converters. Internally compensated LDOs feature an integrated pass transistor and sustain stability with minimal capacitance, optimizing the overall solution size and performance. While the externally compensated variants achieve excellent stability with significant external capacitance, these linear regulators are particularly suited to environments demanding high power supply rejection. Equipped with high-performance bandgap architectures, these solutions affirm stable reference voltages and currents across a wide bandwidth, seamlessly integrating with Omni Design's comprehensive product offerings. Their applicability extends across diverse process nodes, ensuring consistent power management efficiency in an array of cutting-edge integrated circuits.
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