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.
The REFS IP block integrates a band-gap reference with PTAT (Proportional to Absolute Temperature) current outputs, vital for mixed-signal ICs requiring stable voltage references. Developed using IBM's 65nm 10LPe process, the REFS block offers multiple outputs, adjustable through internal and external resistors, providing flexibility for various analog applications. Its capability to program current outputs within ±30% demonstrates its adaptability, allowing for precise control in complex circuits. This feature, combined with its stability across temperature variations, makes the REFS block indispensable in RF, analog, and mixed-signal designs. Incorporating the REFS block into a system enhances operational reliability and efficiency, crucial for long-term functionality of semiconductor devices. Its robust design addresses the need for consistent performance under varying environmental conditions, a must for specialized electronic applications.
The Cap-less LDO Regulator delivers efficient voltage regulation without the need for external capacitors, simplifying design and reducing board space. Ideal for power-sensitive applications, its architecture supports stable output voltage under varying load conditions. This regulator is tailored for systems requiring high regulation accuracy with minimal noise, making it suitable for sensitive analog circuits and RF modules. It is predominantly applied in battery-powered devices and IoT gadgets, where efficiency and size constraints are critical.
The Bandgap offering from SkyeChip is a precise voltage reference circuit aimed at maintaining stability across variations in temperature and power supply. This analog IP delivers a consistent output voltage of about 0.9V with minimal deviation, making it crucial for applications requiring stability across a wide temperature range from -40C to 125C. Its low power consumption and robust design suit a variety of circuits where voltage stability is critical. The Bandgap circuit ensures effective performance in diverse conditions, contributing to the reliability and accuracy of the systems it supports.
The MVPM100 series leverages cutting-edge microsystem technology to deliver highly accurate particulate matter measurements. Unlike traditional optical sensors, these sensors measure the mass of particulate matter directly, providing reliable data in a compact form factor. Their small size and low power consumption make them suitable for a range of applications in industrial, consumer, and medical fields. With a wide operating range and precision typically reserved for larger sensors, the MVPM100 series marks a significant advancement in particulate matter measurement. Technical specifications reveal a measurement range of 0 to 1000 μg/m3, with high accuracy allowing them to be utilized in challenging environments. These sensors support an I2C and UART interface, offering versatility in integration across various platforms.
The ABX Platform by Racyics utilizes Adaptive Body Biasing (ABB) technology to drive performance in ultra-low voltage scenarios. This platform is tailored for extensive applications requiring ultra-low power as well as high performance. The ABB generator, along with the standard cells and SRAM IP, form the core of the ABX Platform, providing efficient compensation for process variations, supply voltage fluctuations, and temperature changes.\n\nFor automotive applications, the ABX Platform delivers notable improvements in leakage power, achieving up to 76% reduction for automotive-grade applications with temperatures reaching 150°C. The platform's RBB feature substantially enhances leakage control, making it ideal for automotive uses. Beyond automotive, the ABX Platform's FBB functionality significantly boosts performance, offering up to 10.3 times the output at 0.5V operation compared to non-bias implementations.\n\nExtensively tested and silicon-proven, the ABX Platform ensures reliability and power efficiency with easy integration into standard design flows. The solution also provides tight cornering and ABB-aware implementations for improved Power-Performance-Area (PPA) metrics. As a turnkey solution, it is designed for seamless integration into existing systems and comes with a free evaluation kit for potential customers to explore its capabilities before committing.
The MVH4000 series offers exceptional reliability and precision in humidity and temperature measurement. Utilizing advanced Silicon Carbide MEMS technology, these sensors boast impressive longevity and minimal power consumption. They are compact, measuring just 2.5 x 2.5 x 0.9 mm, making them perfect for applications where space is at a premium. These sensors are designed to provide fast and accurate readings, making them suitable for various time-sensitive applications. The sensors are available in digital and analog outputs, with different accuracy grades to cater to various needs and budgets. The MVH4000 series includes several models, each tailored for specific accuracy and output requirements. This range ensures that the sensors can be effectively utilized in industrial, consumer, medical, and automotive applications, offering on-chip calibration for quick and easy implementation. Key technical specifications include an operating temperature range of -40 to 125 °C, digital I2C interface, and on-chip calibration that facilitates plug-and-play functionality. These attributes make the MVH4000 series an ideal choice for applications demanding precise environmental monitoring.
Aeonic Power provides scalable on-die voltage regulation for power delivery in SOCs and chiplets. It features an architecture designed for energy optimization, offering functionalities like static IR drop mitigation and virtual power islands. This IP family is pivotal for meeting stringent power distribution requirements, particularly beneficial in the dynamic environments of digital cores and interface solutions, enabling simplification of power delivery structures.
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.
The MVDP2000 series represents a class of highly sensitive differential pressure sensors that stand out for stability and precision. Utilizing proprietary capacitive sensing technology, they are optimized for rapid response and low power usage and suited for OEM applications, such as respiratory equipment, gas flow instruments, and HVAC systems. The sensors offer a wide measurement range and come digitally calibrated for both pressure and temperature. With digital and analog outputs, they present flexibility and precision across diverse applications. Their low power consumption, combined with high resolution, allows for efficient operation even in demanding conditions, making them advantageous for integration into portable devices. With high accuracy, low total error band, and compact design in a 7 x 7 mm DFN package, the MVDP2000 series emphasizes reliability and versatility. Their extensive operational temperature range provides a robust solution for high-precision environments.
Power Management IC from CoreHW is an efficient solution for optimizing power delivery across electronic systems. Designed to enhance signal integrity and voltage regulation, it comprises DC-DC converters and LDOs tailored for high precision applications. This IC portfolio ensures robust power management through low-dropout regulators (LDOs) featuring varying voltage specifications. Whether integrating into compact or large-scale devices, this IC facilitates excellent power conversion with minimal noise, making it suitable for precision-demanding tasks. CoreHW's power management solutions are noted for their high integration levels, reducing the need for multiple components. With features including optional dual-phase support and efficiency optimization, these products enable streamlined design and operation across sectors like automotive, industrial, and consumer electronics.
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.
Omni Design Technologies' Linear Regulators & Bandgap Reference IP is crafted to handle the stringent power requirements of today's integrated circuits. These IPs utilize advanced control methodologies to provide excellent transient response and low noise output, delivering robust power supply solutions for high-performance systems. The LDO regulators are available in both internally and externally compensated variations, stabilizing factors like power supply rejection across wide bandwidths vital for stable device operation. These solutions are designed to offer high power efficiency while maintaining a low quiescent current, making them perfect for portable and battery-operated devices demanding long-term operation. The bandgap references ensure consistent output under varying environmental and load conditions without requiring calibration, offering a seamless operation across a range of IC applications. Effortlessly integrating with other Omni Design IPs, including ADC and DAC solutions, these IPs support process nodes extending from 28nm to the latest FinFET designs. With configurable output currents and voltages, they can be precisely adapted to meet the specific needs of advanced cutting-edge applications like wireless communications, data centers, and automotive systems.
The FCM1401 is a high-performance Dual-Drive™ power amplifier operating at a center frequency of 14.5 GHz. This amplifier is designed to deliver outstanding efficiency and performance, surpassing conventional solutions. Its innovative architecture reduces silicon area by half, achieving a 62% core drain efficiency and a remarkable 70% efficiency at the device output. This device is optimized for modern telecommunication needs, ensuring robust signal integrity and reduced power consumption, pivotal for both space communications and wireless connectivity. The amplifier is crafted to meet future telecommunication demands effortlessly, offering superior gain and efficiency across a range of applications. Its versatility extends across various platforms, including CMOS, GaAs, GaN, and SiGe, ensuring compatibility with a wide range of semiconductor processes. Designed with a focus on minimizing power loss and enhancing output signal, it is an ideal choice for devices requiring compact yet powerful amplifier solutions. The FCM1401 ensures that wearable technology and telecommunication devices benefit from extended battery life and improved performance. Designed with precision engineering, the FCM1401 can accommodate supply voltages from 1.6V to 2.0V without sacrificing operational efficiency. This flexibility allows for seamless integration into existing systems while also paving the way for advancements in wireless communication technology.
Hermes X3D is engineered to expedite the process of RLGC extraction, which is critical for power, package, and touch panel modeling. The tool is particularly useful in scenarios demanding quick and accurate results to optimize circuit behavior, allowing designers to refine and improve system performance by addressing the nuances of resistance, inductance, capacitance, and conductance (RLGC). Its high-speed computation abilities make Hermes X3D an ideal solution for environments where time-efficient modeling is crucial. The tool's detailed extraction processes enable precise prediction of circuit parameters, supporting engineers in achieving balanced designs that optimize function and durability. Hermes X3D is indispensable for developers looking to enhance power and package design as well as those engaged in intricate touch panel circuit design. Its focused approach to simulation offers critical insights that help streamline the development process and elevate the quality and performance of electronic products.
The pPOR01 design is a specialized Power-On Reset (POR) system designed to ensure precise and reliable power-up sequences for digital circuits. With meticulous engineering, it provides robust reset functionalities crucial for preventing erratic system behaviors as power supplies fluctuate or stabilize. Compact and highly integrated, the pPOR01 suits a range of ICs needing stringent power management and reset functions. By delivering reliable reset signals, it minimizes latency and promotes seamless system restarts, making it an invaluable component in systems integrating complex, multi-stage power supplies. In essence, pPOR01 is crafted to enhance the resilience and integrity of digital systems during power fluctuations, acting as a safeguard to protect complex integrated circuits from inadvertent disruptions or inconsistencies at startup.
X-REL ICs are designed for extreme environments, capable of operating reliably in temperatures ranging from -60°C to +230°C. These ICs are particularly suited for applications in critical sectors such as aerospace, oil and gas, and industrial automation. By using robust ceramic and metal packaging, these components offer longevity and resilience in harsh conditions. X-REL products are ISO 9001 and EN 9100 certified, ensuring adherence to strict quality and reliability standards, which makes them ideal for applications requiring long-term operational stability under temperature extremes.
Omni Design Technologies' Specialty IP solutions cater to specific functions that are critical for a variety of high-tech applications. These solutions are designed to support advanced functions such as glitch detection, latch-up detection, and precision clock receiving in sophisticated semiconductor environments. By integrating these specialty solutions, Omni Design aids in addressing complex electronic design challenges encountered in sectors like automotive, defense, and high-density telecommunications systems. Specialty IP from Omni Design includes a range of options like high-performance voltage buffers and programmable gain amplifiers that ensure efficient and reliable signal conditioning. Additionally, their LVDS I/O cells are engineered for high-speed data transmission over significant signal distances, maintaining performance integrity where precision and reliability are indispensable. These IPs are equipped to seamlessly integrate with other chip functions, assisting developers in achieving stable and efficient performance in their designs. With process compatibility extending to advanced FinFET nodes, these Specialty IP solutions help optimize system functionality across varied market segments and use cases, ensuring robust application adaptability.
This product is designed with an architectural approach focused on maximizing efficiency in Class-D driver applications across a variety of power levels. It incorporates self-determining technology to optimize operation, ensuring that the energy consumption is minimized while maintaining high performance. This innovation is crucial for applications needing efficient power management, particularly in power-sensitive environments where maximized efficiency is essential for performance and longevity.
The TakeCharge Electrostatic Discharge Solutions are specialized innovations designed to offer unparalleled protection against electrostatic discharge in advanced semiconductor processes. These solutions are compatible with the latest FinFET technology, including TSMC's 3nm node, which presents unique challenges such as narrow design windows that traditional ESD methods like ggNMOS cannot address effectively. Sofics's TakeCharge solutions provide a reliable and robust alternative, ensuring the safety and functionality of high-speed devices. The narrow margins in modern FinFET processes necessitate precision and adaptability, which is where TakeCharge shines. It is capable of safeguarding delicate electronics used across various applications, ranging from AI to data centers and beyond. The solutions in this portfolio leverage low parasitic capacitance and high voltage tolerance, maintaining performance without compromising on efficiency or footprint. In addition to their technological prowess, these solutions have been silicon-proven across multiple foundries, demonstrating their adaptability and success in real-world scenarios. TakeCharge assures interfacing reliability and protection for state-of-the-art integrated circuits, making it indispensable for modern electronic design.
The 5G Remote Radio Unit by Saankhya Labs represents a stride forward in ORAN-compliant infrastructure, designed to meet the expansive requirements of modern 5G networks. This multi-band RU is built with sophisticated analytics capabilities, allowing it to dynamically adapt and optimize the use of radio resources to enhance spectrum efficiency. Saankhya's 5G RU supports a wide array of 3gpp bands, with particular emphasis on the low and mid frequencies such as Bands 71, 29, and 40. This broad band support ensures wide applicability, from urban to rural deployments, making it suitable for a diverse set of network demands. Incorporated within it is a unique front haul compression technique which reduces operational expenses, allowing operators to scale their infrastructure cost-effectively. Its design reflects a commitment to offering a scalable, open, and flexible RAN solution that aligns with global 5G deployment strategies.
The Current-mode Buck Converter is designed for applications requiring a stable power supply with an output current of 2.5A. Featuring an input voltage range from 2.7V to 5.5V, this converter efficiently steps down voltage to an output range of 0.6V to 2.5V, with a tight accuracy of 1.5%. This robust power converter is optimized for high-performance applications, such as telecommunications and computing devices, where consistent power delivery and efficiency are critical. Its architecture supports dynamic load changes, maintaining stable operation under varying conditions. Developed on Samsung's 65nm process, this silicon-proven product ensures reliability and high efficiency, making it suitable for integration into cutting-edge electronic systems requiring reliable power conversion solutions.
Engineered for ultra-high-frequency performances, the FCM3801-BD amplifier offers unparalleled efficiency and gain at 38 GHz, marking it as a crucial component for future space and telecommunication advancements. This device capitalizes on the benefits of dual-drive architecture, offering a remarkable enhancement in performance metrics such as power-added efficiency (PAE) and overall output power. Bridging the gap between cutting-edge technology and practical application, this power amplifier facilitates reduced power demands, translating into lower operational costs for service operators and prolonged battery life for end devices. This commitment to energy efficiency helps reduce carbon emissions, aligning with global sustainability goals. Utilizing advanced semiconductor materials like GaN and GaAs among others, the FCM3801-BD is heralded for its toughness and adaptability to various environmental challenges, making it the ideal choice for rugged and demanding operational scenarios. Those in need of robust yet efficient solutions will find the FCM3801-BD to meet and exceed requirements with its groundbreaking design. Its reduced silicon footprint contributes significantly to scalability in various configurations.
Notus provides a comprehensive platform for SI/PI, thermal, and stress analysis, crucial for engineers striving to optimize electronic circuit performance under various environmental conditions. Integrating signal integrity, power integrity, and multi-physics simulation within a single tool, Notus offers unmatched analytical capabilities that ensure designs meet rigorous operational standards. Designed to tackle complex simulations, Notus helps in identifying potential problems before they become costly failures. Its detailed analyses encompass a range of scenarios, aiding in the prediction and enhancement of circuit reliability and longevity. This integrated approach supports forward-thinking design strategies that are essential in today's competitive electronics marketplace. Notus enhances productivity by simplifying the design process and reducing the need for multiple software tools, thereby accelerating time-to-market. The powerful simulations it provides are indispensable for engineers working on high-stakes projects where precision and reliability are non-negotiable.
The Voltage-mode Buck Converter is capable of supplying a significant output current of 3A, optimized for high-power applications requiring efficient energy conversion. With an input voltage span of 4.5V to 48V, and an adjustable output from 5V to 20V, it caters to a wide variety of power supply designs. Deserving attention for its power density and efficiency, this converter is tailored to support high-load applications like industrial systems and automotive electronics, where dependable power regulation is necessary. Delivering consistent performance under demanding conditions, this product is ideal for engineers designing robust power architecture. It operates using X-FAB's 180nm process technology, a testament to its durability and reliability. Silicon-proven, this converter ensures seamless integration and operation in high-power requirement scenarios.
The Cap-less LDO offers a streamlined solution for delivering a regulated current output of up to 100mA, advantageous for applications requiring minimized space and component overhead. This device supports an input voltage range from 1.7V to 5.5V and maintains a precise output with an accuracy of 2%, even with an impressively low ground current requirement under 150uA. Due to its cap-less architecture, it eliminates the need for external capacitors, which simplifies board design while saving on material costs. The suitability for battery-powered and space-limited applications makes it ideal for use in wearable technology. This LDO is available in Magna's 180nm and 130nm process nodes, with silicon-proven reliability, ensuring high-performance power regulation in a compact format. It's a perfect fit for developers looking for reliable power solutions in miniaturized electronic devices.
eSi-Analog is a portfolio of silicon-proven analog IP blocks that play a pivotal role in enabling custom ASIC and SoC designs. The offerings include a variety of critical analog functions such as oscillators, PLLs, and low-dropout regulators (LDOs), all optimized for low power consumption and high performance. These blocks are designed for easy integration across numerous process nodes, catering to diverse customer specifications in sectors ranging from wireless communication to healthcare. By incorporating advanced analog technology, eSi-Analog helps ensure that systems meet both performance and cost targets while maintaining high levels of functionality.
The Voltage-mode Buck Converter delivers regulated voltage with an output current ranging from 800mA to 1.5A, suitable for various power-intensive applications. This converter operates with an input voltage of 2.7V to 5.5V, and can deliver an output voltage between 0.6V and 2.5V, ensuring versatility across multiple electronic architectures. The converter maintains energy efficiency with a ground current below 30uA, supporting applications where power efficiency is paramount. This capability makes it well-suited for high-performance computing systems and portable devices. Manufactured with high reliability on Magna's 180nm process, this silicon-proven converter provides the necessary power management functions needed for modern electronics, facilitating optimal operation through efficient power conversion and regulation.
The Band-Gap Reference offers precise voltage references ranging from 0.6V to 1.2V, critical for stable system performance. It features an operating current of 25uA and maintains high accuracy between 1% to 3% across its operating range of 2.2V to 5.5V, making it suitable for a variety of analog circuits. This versatile reference is engineered for integration into applications requiring stable voltage signals despite temperature variations, such as in sensor interfacing and analog data processing. Its design ensures minimal drift and robust performance across variable environmental conditions. Manufactured utilizing Magna, Samsung, and TSMC's process nodes down to 65nm, this band-gap reference is silicon-proven to offer reliability and high precision for critical electronics where voltage stability is pivotal.
The Bioptx Biosensing Band and Platform represents a significant leap in non-invasive health monitoring technology. This platform integrates Rockley’s groundbreaking biosensing capabilities into a wearable form, utilizing short-wave infrared (SWIR) laser-based spectroscopy coupled with conventional methods. With the ability to continuously monitor key health metrics such as body temperature, hydration levels, heart rate, and blood oxygen saturation, the Bioptx platform sets new standards in real-time physiological monitoring. Built on Rockley’s photonic integrated circuit (PIC) technology, it allows for precise measurements and diverse application possibilities in both consumer health and professional medical contexts. The combination of SWIR technology with a cloud-based Developer API empowers developers to unlock further potential through seamless data integration and analysis. This innovation facilitates a holistic view of an individual's health, providing real-time insights to enhance personalized medicine approaches. The device is engineered to be wearable comfortably over extended periods, enabling the continuous collection and streaming of vital biometric data. Its portability and accuracy make it an invaluable tool for monitoring both acute and chronic health conditions, supporting wellness in everyday life and in more specialized health management settings.
Specializing in high-frequency amplification, the Dual-Drive™ Power Amplifier FCM2801-BD operates at 28 GHz and offers state-of-the-art signal amplification. It brings unprecedented efficiency to mmWave applications, perfect for 5G networks and other advanced wireless technologies. With its dual-drive architecture, this amplifier achieves a groundbreaking efficiency of 70% at the device output, solidifying its place as a leader in next-generation communication infrastructure. With a focus on delivering high output while maintaining energy efficiency, the FCM2801-BD amplifier significantly reduces both operational costs and environmental impact by minimizing energy usage. This amplifier's ability to maintain robust performance with reduced silicon area—nearly halving traditional layouts—underscores its innovative design. The high efficiency allows for extended device operation, particularly benefiting telecommunications devices that require longer battery life. Its compatibility with multiple semiconductor platforms, including GaN, GaAs, CMOS, and SiGe, further extends its versatility and application scope. This power amplifier is ideally suited for telecommunication and space communication fields, where enhancing signal range and reducing power consumption remain paramount.
Vivid Engineering's LDO designed for a 3.3 V input delivers a 1.2 V output, supporting load currents up to 100 mA without the need for an external capacitor. Key to this design is its efficiency in light load conditions, where only 2 µA of internal consumption occurs. This makes it highly suitable for low-power applications that require stability and compactness, contributing effectively to the optimization of power usage in modern electronic devices.
The Swift™ Integrated LDO ODT-LDO-28HPCT is a modern solution in power regulation, focusing on low-dropout voltage regulation to efficiently manage power delivery in integrated circuits. Utilizing advanced technologies, this LDO is designed to offer seamless transient response and excellent PSRR (Power Supply Rejection Ratio), critical for maintaining stability in high-performance environments. Built in a 28nm process, this LDO offers significant benefits in terms of space and efficiency, making it an ideal choice for compact system designs requiring reliable power management. Its integration capability with other system components emphasizes minimal energy consumption while ensuring optimal performance across varied conditions. The ODT-LDO-28HPCT showcases impressive thermal stability and precision in voltage regulation, pertinent for applications that demand consistent power quality and reliable operation, such as telecommunications and computing devices. Its adaptability across different operating scenarios makes it a versatile component for complex electronic designs.
The ARKT28HPCP_LDO100 Voltage Regulator is designed for applications requiring a stable and precise power source for digital and analog circuits. Operating within a narrow input voltage range of 1.62V to 1.98V, this LDO regulator delivers a fixed output of 0.9V with an impressive accuracy of 3%. It can support load currents up to 100mA, making it suitable for low-power applications where efficiency is crucial. Manufactured using TSMC's 28nm process technology, this regulator is currently under development, promising advanced integration for modern electronic designs. The compact design and high performance of the ARKT28HPCP_LDO100 ensure that it meets the stringent voltage regulation needs of different system architectures. Ideal for use in battery-powered devices, communication systems, and portable electronics, the ARKT28HPCP_LDO100 offers reliable power management solutions. As part of Arkchips' innovative product lineup, it represents a significant step forward in low dropout regulation technology.
Vivid Engineering provides a bandgap reference block designed to deliver a stable reference voltage across a range of environmental conditions. This essential component is engineered for high precision, featuring trimmable reference voltage and bias currents. It also includes over- and under-temperature alerts and a power-on reset function. Ideally suited for use in systems that demand consistent voltage references regardless of temperature variations, this block is a vital asset in complex electronic systems requiring reliable voltage stability.
The LDO offered by Vivid Engineering for a 5V input is a robust solution for voltage regulation, providing a 1.8 V output and capable of sustaining a 20 mA load without requiring an external capacitor. This design includes features for safe operation down to 1.6 V input in saturation, making it particularly impactful in power management systems where reliability is a priority. It is suitable for applications requiring minimal external components, thus optimizing space and cost in electronic designs.
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.
Tower Semiconductor's BCD technology offers an innovative approach for power management solutions by integrating bipolar, CMOS, and DMOS transistors. This combination is tailored to enhance performance in high-voltage applications, focusing on motor drivers, DC-DC converters, and battery management systems. Renowned for its high power density, this technology provides significant reliability and efficiency for industrial and consumer electronics, ensuring superior thermal and electrical performance. BCD technology is adaptable across varied process nodes and wafer sizes, allowing manufacturers to meet diverse voltage and power requirements efficiently. It supports applications up to 700V and leverages high-speed LDMOS, which ensures low on-resistance and excellent isolation. The integration possibilities this technology offers are vast, enabling sophisticated power solutions adaptable to the automotive and industrial landscapes. Moreover, BCD technology provides immense design flexibility, offering an array of standard and custom IPs, such as embedded memory and ESD protection cells, to meet specific customer needs. The technology’s inherent modularity allows for scalability in device integration, which effectively reduces the time-to-market for power electronic products.
This General-purpose LDO is designed to supply a regulated output current ranging from 150mA to 450mA, maintaining high precision with an output voltage accuracy of up to 2%. It offers broad input voltage ranges from 1.7V to 5.5V, suitable for a variety of systems requiring stability and low output noise in their power supplies. Engineered for efficiency, the LDO's ground current is kept under 20uA, making it an excellent choice for battery-powered devices where power conservation is critical. The potential applications include consumer electronics, where reliability and precision in voltage regulation are necessary to ensure device performance and longevity. Developed on Magna's 180nm and 130nm process nodes, this silicon-proven LDO offers a trusted solution for numerous electronic circuit designs, catering to different operational requirements while ensuring high efficiency and low power operation.
Designed to meet the rigorous demands of modern electronics, Advanced Silicon's High-Voltage Integrated Circuits are pivotal in applications involving complex switching devices. These ICs include versatile drivers and DACs that are essential for interfacing with thin-film technologies such as TFT and MEMS devices. They ensure precise voltage control over various capacitive loads, making them indispensable for applications such as flat-panel displays and complex X-ray detectors. The high-voltage line drivers are known for their adaptability across a multitude of display technologies, including LCD, OLED, and micro-LED systems, while maintaining robust radiation-hardness qualities crucial for specific industrial applications. Available in high pin counts, these ICs can support up to hundreds of output channels, a necessary feature for advanced display and detection systems. By providing DACs with extensive resolution options, these ICs facilitate the digital-to-analog conversion crucial for handling large and delicate pixel arrays, ensuring exact voltage application across panels. These capabilities establish Advanced Silicon’s High-Voltage ICs as an integral component of cutting-edge display and detection technology, contributing significantly to the efficiency and accuracy of electronic systems.
Power Conversion and Management Systems offered by SystematIC are designed to handle various power regulation tasks. This includes linear regulators, DC-DC converters, and LDOs, which optimize power usage within electronic devices. These systems also incorporate elements like class-D amplifiers and charge pumps which are fundamental in maintaining power efficiency across different load conditions. They provide solutions for energy-sensitive applications where low quiescent current and noise are crucial. These power systems are embedded in consumer electronics, enhancing battery life and performance under diverse operational scenarios. Their modular nature allows for flexible integration, catering to the demands of rapidly evolving power supply designs. Embedded with advanced features like HV switching and 3kV regulation, they are suited for high-stakes applications in competitive markets like automotive and industrial sectors. These systems are built with compliance in mind, ensuring they adhere to rigorous standards while delivering enhanced energy modulation across applications.
The Bandgap Voltage Reference is a critical component for stable voltage regulation in various electronic circuits. It utilizes the bandgap principle to deliver a constant voltage output, regardless of variations in temperature, power supply levels, or circuit loading. This precision reference is crucial for applications requiring consistent performance, such as in power management systems or analog signal processing circuits. Its robust design ensures minimal drift and maximum efficiency in delivering stable voltage across diverse environmental conditions.
The High-Performance Photonic Interconnect is designed to facilitate rapid data transfer across optical interconnections. This makes it ideal for high-speed networking environments where low latency and high bandwidth are critical. By utilizing advanced photonic technologies, the interconnect achieves exceptional data rates while maintaining energy efficiency, essential for data centers and telecommunication networks. It aims to optimize optical data links, providing improved performance over traditional electronic interconnects. Its integration into systems is seamless, offering compatibility with existing infrastructure. Adaptable to varying requirements, it supports a range of configurations to suit specific needs in data-intensive applications. The interconnect’s design emphasizes modularity and scalability, making it a future-proof solution capable of evolving alongside emerging technologies. Whether in cloud computing, enterprise environments, or telecommunication applications, the High-Performance Photonic Interconnect offers an unmatched blend of speed, reliability, and efficiency.
The VR-3V3-1V2-1-55-U voltage regulator is an ultra-low-power design, adeptly converting a 3.3V input to a stable 1.2V output. Utilizing UMC's advanced 0.06 μm technology, this regulator can handle up to 1mA of output current, making it optimal for applications requiring stringent power efficiency and stability. With its high precision and efficiency, the VR-3V3-1V2-1-55-U caters to a variety of power-sensitive applications, ensuring consistent performance even under dynamic conditions. The regulator's Power Supply Rejection Ratio (PSRR) of 40 dB ensures minimal output voltage noise, making it especially valuable in noise-sensitive environments. The compact form factor of this voltage regulator, combined with its robust performance features, makes it ideal for integration into portable and miniaturized electronic systems. Its low quiescent current guarantees prolonged battery life, thus supporting the longevity and reliability of the electronic systems it powers.
The Digital Pre-Distortion (DPD) technology is pivotal in optimizing RF Power Amplifiers' efficiency. By compensating for the inherent non-linearities generated by these amplifiers, DPD ensures signal integrity, enhancing output performance and reliability. This technology is crucial for the efficient functioning of RF systems, minimizing distortions and improving overall signal quality. Faststream's DPD solution is engineered to counteract the memory effects seen in power amplifiers, providing a cleaner, more accurate signal output. Employing advanced algorithms, this technology adjusts the input signal, pre-distorting it to anticipate and negate the effects of amplifier-induced distortions. This not only improves the signal clarity but also extends the amplifier's lifespan by reducing stress. By enhancing the power efficiency of RF amplifiers, DPD contributes to reduced energy consumption, thus promoting sustainable practices in wireless communications. Faststream's implementation of DPD stands out for its precision and effectiveness in maintaining high-quality signal transmission across various applications.
Crest Factor Reduction (CFR) technology is essential for managing power amplifier demands by minimizing peak-to-average power ratios. This reduction aids in easing power supply design constraints and cuts down peak power needs, ensuring more efficient power amplifier operations. CFR is indispensable in modern communication systems where maintaining signal integrity and reducing power consumption are paramount. Faststream Technologies’ CFR solution is structured to streamline power amplifier requirements, enabling more efficient power usage and enhancing system reliability. By adjusting the signal’s amplitude distribution, CFR effectively diminishes the peaks that would otherwise lead to power inefficiencies or potential overloads. Utilizing CFR, communication systems can achieve improved power efficiency, reduce operational costs, and extend the life of their hardware components. This technology supports high-performance signal processing, ensuring that systems remain robust under variable load conditions, all while maintaining optimal performance metrics.
The AC LED Driver IC by SystematIC is tailored for controlling multiple LED strings efficiently directly from AC mains. This highly configurable IC caters to varied LED applications and is compatible with TRIAC dimmers, ensuring broad usage potential. It requires minimal additional components, making it a cost-effective solution for LED lamp systems. Delivering a streamlined development process, this IC supports direct mains operation, handling up to 400 V, and is capable of driving up to 6 LED branches with dual IC. Programmable features include analog dimming and temperature control, which suppliers integrated lighting solutions tailored to consumer and industrial needs. This driver is designed within a high-voltage CMOS process, highlighting its robust design for high-performance requirements. It supports both bare-die and packaged versions, establishing its versatility in end-user applications. The customer-centric development process ensures this IC meets specific criteria for optimal performance and flexibility.
The OSCONIQ P 3737 is a high-power LED tailored for horticultural applications, leveraging cutting-edge chip technology from ams OSRAM. It offers robust performance with extended lifespan, crucial for both greenhouse-based and vertical farm settings. The LED comes in multiple color options including Hyper Red, Deep Blue, and Far Red, supporting a tailored spectrum to meet diverse plant cultivation requirements.
The GS61008P is a high-performance GaN transistor, specifically engineered for applications demanding high power density and efficiency. By utilizing state-of-the-art enhancement mode GaN technology, this transistor operates with lower gate charge and faster switching speeds compared to traditional silicon-based devices, offering significant improvements in system performance. Its robust design supports a wide range of applications, from consumer electronics to industrial systems, where efficiency and compact form factor are critical. Technically, the GS61008P boasts an impressive current rating while minimizing on-resistance, which translates to reduced conduction losses and enhanced thermal performance. This makes it particularly suited for power supply designs and motor control applications that benefit from reduced heat generation and improved reliability. Part of a broader family of GaN products, the GS61008P integrates seamlessly into designs where space and thermal management are at a premium. Its advanced features not only simplify the design process but also contribute to more environmentally friendly and energy-efficient end products.
KeyASIC's Fundamental IP offerings include a versatile hybrid standard cell library specifically crafted for IoT and battery-efficient applications. This comprehensive collection comprises both foundry-sponsored memory IPs and general-purpose I/O options such as LVCMOS and programmable 5V-tolerant interfaces. For more specialized applications, users can utilize special-purpose I/Os like SSTL, HSTL, PCI, and others. To ensure robust power management, this IP suite features various regulators, low-dropout (LDO) regulators, cap-less LDOs, and other power components like DC-DC converters, PLLs for frequency synthesis, and crystal and RTC oscillators. This foundational set of IPs supports a wide range of applications, and all components are optimized for high efficiency, making them suitable for diverse commercial and industrial uses.
The PowerPad represents CurrentRF's dedication to optimizing power use in electronic systems. It integrates seamlessly into IC designs by replacing traditional power and ground bondpads. This innovation significantly reduces power consumption without meaningfully increasing IC area, demonstrating a near-zero footprint addition. Specifically crafted for power-conscious applications, the PowerPad is pivotal for devices that require substantial dynamic power savings. Its unique design ensures minimal system power wastage, enhancing device efficiency and promoting longer battery life by efficiently leveraging energy that would otherwise be lost.