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 Aeonic Power series offers on-die voltage regulation tailored for high-performance integrated circuits. It features scalable architectures optimized for the energy needs of digital cores, logic blocks, and chiplets. Featuring capabilities like per-core dynamic voltage and frequency scaling (DVFS) and static IR drop mitigation, it helps in significant energy use reductions. The solutions are designed for diverse power distribution scenarios, optimizing power delivery networks with robust noise suppression and adaptability.
SkyeChip's Bandgap reference delivers a stable voltage output of 0.9V with tight tolerance and low power consumption under 500uW. With operating temperatures ranging from -40°C to 125°C, it provides a reliable reference voltage for various electronic circuits, ensuring steady performance across a wide range of conditions.
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.
Archband's Cap-less LDO Regulator is designed to offer efficient voltage regulation with minimized external components, making it ideal for compact devices. This regulator delivers a stable output voltage while maintaining low dropout, optimizing power efficiency in various end-user applications. The cap-less design significantly reduces the size and footprint on the circuit board, facilitating integration into portable and mobile devices where space is at a premium. This regulator stands out for its quick response to changes in output load and input voltage, safeguarding the performance of voltage-sensitive applications. It is suitable for a wide range of consumer electronics and industrial applications. With a focus on low power consumption and high efficiency, it aids in the design of devices that support long operational lifetimes, especially essential for battery-operated gadgets. Its robust design is suitable for the dynamically changing demands of modern electronics.
The MVPM100 Series sensors advance particulate matter detection by integrating microsystem technologies traditionally seen in larger devices, into a more compact and accurate format. Unlike conventional optical solutions, these sensors provide direct measurement of particle mass, offering precision and reliability in diverse applications, from air quality monitoring to industrial environments.
The Vantablack S-VIS coating is specifically tailored for space applications, where it serves a crucial role in suppressing stray light in optical systems and blackbody calibration of infrared camera systems. Its exceptionally high performance and spectrally flat absorption from the UV to the near-millimeter spectral range make it indispensable for ensuring accurate readings and operations in the challenging environment of space. One of the prominent applications of the S-VIS coating is in the reduction of launch weight for instruments, thanks to its ability to absorb light efficiently from all angles. This not only enhances the operation of devices like star trackers and optical calibration systems but also minimizes the overall size and complexity of these systems, offering significant cost savings. This coating has proven its reliability in harsh space conditions since its first deployment in low Earth orbit in 2015. Its capabilities in outgassing management and thermal stability are well-documented, making it a trusted solution for enhancing the operational longevity and performance of space missions.
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.
eSi-Analog delivers integrated analog solutions that enhance the performance of custom ASICs and SoCs. The IP range includes oscillators, PLLs, and sensor interfaces, critical to developing high-fidelity analog functionalities. Designed for low power consumption, these solutions are adaptable to customers' requirements, ensuring expedited time-to-market. Silicon-proven across multiple process nodes, eSi-Analog enables innovative designs in competitive, dynamic industries. With a focus on reducing integration complexity and costs while maintaining high performance, eSi-Analog serves crucial roles in various applications, such as IoT devices, wearables, and medical systems, benefiting from the reliable analog performance.
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.
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.
The MVH4000 Series offers a robust solution for measuring humidity and temperature with high accuracy. These sensors utilize a proprietary Silicon Carbide MEMS technology, promising long-term stability and durability. The rapid response time, low power usage, and compact design make this series ideal for demanding applications, providing exceptional precision in data measurement and transmission.
The mmWave PLL is a sophisticated Phase Locked Loop designed for ultra-precision wireless communications and radar applications. This fractional-N PLL synthesizer provides low phase noise performance suitable for demanding carrier and fast chirp FMCW waveforms, critical in modern communication networks. Its operational range corresponds to fundamental frequencies of 19.00-20.15 GHz, scalable to radar bands of 38-40.5 GHz and 76-81 GHz through frequency multipliers, highlighting its versatility across applications. The mmWave PLL supports a customizable frequency range from 19 GHz to 81 GHz, ensuring tailored application requirements can be achieved. Integrated design features include a built-in sequencer, calibration, and self-test capabilities, all of which contribute to the PLL's robustness. The unit is compliant with automotive standards like AEC-Q100 Grade 1, making it suitable for rigorous environments, such as automotive radar systems. Technical specifications reveal its operational proficiency with power consumption at under 120 mA and operating temperatures from -40 to +125 °C (ambient) and -40 to +150 °C (junction). This is supported by SPI control interfaces for precise manageability, ensuring integration efforts align seamlessly within varied system architectures.
The FCM3801-BD Power Amplifier enhances Falcomm's powerful offerings in the realm of high-performance digital power amplification. Functioning at an impressive 38 GHz center frequency, this device is engineered for ultra-efficient energy solutions in the field of advanced telecommunications. With a design that underscores energy efficiency and reliability, the FCM3801-BD is a key player for telecom operators aiming to optimize power resources. This amplifier's intelligent construction ensures unwavering performance even in challenging conditions, reflecting Falcomm's commitment to sustainability and operational excellence. Ideal for applications such as high-speed data transmission and enhanced signal processing, the FCM3801-BD promises to reduce power demands while delivering high output. This enables telecom providers to pursue eco-friendlier paths in their operations without compromising on service quality or connectivity capabilities.
SystemBIST is an advanced product offering from Intellitech that provides a plug-and-play solution for flexible FPGA configuration and embedded JTAG testing. It stands out with its proprietary architecture that allows for efficient, codeless configuration of field-programmable gate arrays (FPGAs) as well as built-in system testing capabilities. SystemBIST is designed to be vendor-neutral, supporting any FPGA or CPLD compliant with the IEEE 1532 or IEEE 1149.1 standards. This design enables robust anti-tamper measures and enhances system reliability by embedding JTAG test patterns directly into PCBs.
This Voltage-mode Buck Converter offers impressive efficiency across load currents ranging from 800mA to 1.5A, making it an excellent solution for voltage regulation tasks in applications like consumer electronics and telecom equipment. It functions effectively within an input voltage range of 2.7V to 5.5V, providing an output voltage from 0.6V to 2.5V, with grounding currents under 30μA. The converter embodies high precision with a 2% accuracy in voltage regulation, ensuring smooth and efficient power conversion even in dynamic load conditions. Its voltage-mode control architecture is designed for applications that demand reliable power delivery and efficiency. Fabricated on Magna's 130nm and 180nm process nodes, it is well-suited for designs requiring robust power regulation, validated through silicon-proven reliability for enhanced performance in modern electronic devices.
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 MVDP2000 Series features differential pressure sensors that emphasize sensitivity and accuracy, thanks to a novel capacitive sensing technology. These sensors are designed to be digitally calibrated over a range of pressures and temperatures, ensuring optimal performance even in challenging environments. Their quick response and low power needs make them versatile for numerous applications, from HVAC systems to medical devices.
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.
The Dual-Drive™ Power Amplifier FCM1401 stands out for its exceptional energy efficiency and advanced two-stage architecture. Operating at a center frequency of 14 GHz, it embodies industry-leading innovation in power amplifiers by offering a significant leap in power efficiency. This product is ideal for mobile connected devices and telecommunication applications that demand lower energy consumption without sacrificing performance. With its robust design, the FCM1401 ensures that operators can enhance operational efficiency while reducing the environmental footprint of power consumption. The design caters to high-frequency applications by maximizing performance and maintaining the reliability expected in modern telecom infrastructures. It therefore offers a practical solution for enhancing device longevity with reduced operational expenses. This amplifier is tailored to support both space communications and mobile technology applications, offering unparalleled power handling capabilities. Whether enriching the battery life or scaling up the signal strength, it aligns with green energy initiatives by providing significant output without increased energy use.
The CC-100 Power Optimizer is an integral part of CurrentRF's energy harvesting technology, primarily featured in products like PowerStic and Exodus devices. This compact IC, measuring 1.4mm x 1.4mm, is designed to be embedded in the ground lead of DC-Link capacitors, offering significant energy savings. By harvesting, inverting, and recycling a portion of the normally wasted current, the CC-100 Power Optimizer effectively cancels a part of the incoming current impulse. This feedback mechanism reduces battery charging requirements, extending the driving range of electric vehicles by up to 10%, making it an economical solution for manufacturers striving to enhance efficiency without considerable expense. This IP is particularly effective in electric and hydrogen fuel cell vehicles, where it helps to alleviate deep discharges of key capacitors in the vehicle's electrical system. As a result, it aids in reducing the recharge demand, consequent battery drain, and thus extends not only the longevity of the battery system but also the range per charge. The CC-100 Power Optimizer supports manufacturers’ designs by decreasing power consumption while improving the overall eco-friendliness of vehicle technology. Its implementation is particularly advantageous in high-voltage systems, where interfacing with cable shields and disconnecting waste currents can lead to substantial performance enhancements. The CC-100 IC stands as a testament to how innovative design in power management can lead to substantial energy savings and operational improvements.
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.
Certus Semiconductor's Analog I/O solutions deliver state-of-the-art protection through ultra-low capacitance and extreme ESD protection. Designed for high-speed SerDes and RF applications, these products ensure that signal integrity and impedance matching are not compromised. The Analog I/O offerings from Certus are driven by innovation, featuring less than 50 fF capacitance solutions apt for today's advanced technological demands. These analog solutions are equipped to tolerate signal swings below ground, capable of providing robust ESD protection withstanding over 16kV HBM. In addition to these capabilities, they possess high temperature tolerance and can endure aggressive operational environments, making them an ideal fit for sectors demanding high reliability and rugged performance. The comprehensive design integrates IO, ESD, and power clamps into significant macro cells for optimal performance. Certus Semiconductor ensures that their analog solutions are adaptable, scalable, and ready to meet future demands in high-speed and high-frequency applications.
Optimized for precision voltage reference, the Band-Gap Reference delivers stable voltage outputs ranging from 0.6V to 1.2V, supporting a current operation of 25μA within a voltage range of 2.2V to 5.5V. It ensures high precision with an accuracy between 1% to 3%, depending on operational conditions, making it highly effective for calibration and biasing circuits in diverse electronic applications. The band-gap reference is critical in systems that demand a stable, low-temperature-coefficient voltage reference such as analog-to-digital converters and power management circuits. Its resilience across different temperatures and voltage supplies ensures reliable performance in varying environmental conditions. Implemented across Magna and Samsung foundries via 65nm, 130nm, and 180nm process technologies, the reference circuit is silicon-proven, demonstrating consistent and reliable operation in delivering precise voltage references for demanding electronic systems.
The BCD Technology platform enables the development of robust power management solutions. It combines the strengths of Bipolar, CMOS, and DMOS processes, allowing for efficient power handling and high voltage endurance. This technology is pivotal in creating compact, integrated solutions for power conversion and control, especially beneficial in automotive and industrial applications. BCD Technology provides a versatile foundation for designing power components that require high density and efficient thermal management. This results in components that are not only more reliable but also more energy-efficient. Utilizing this technology, designers can achieve superior performance in miniaturized form factors, meeting the stringent demands of today’s electronic applications. Through its advanced integration capabilities, BCD technology expands the possibilities for innovative power management systems. Suitable for a wide range of voltage and power conditions, it supports the creation of multifaceted designs that are both cost-effective and resource-efficient, addressing the evolving needs of global electronics markets.
The FCM2801-BD Power Amplifier from Falcomm represents a pinnacle in amplification technology, engineered to excel in ultra-efficient energy use. This power amplifier operates at a center frequency of 28 GHz, making it well-suited for high-speed wireless communications and next-generation telecom services. Its design not only prioritizes power efficiency but also durability and performance in demanding environments. The FCM2801-BD offers considerable improvements in power usage efficiency, aligning with modern demands for low-energy-consumption solutions. Thus, it caters to both commercial and industrial applications that require robust yet efficient power amplification. This product is fundamental in reducing operational costs for telecommunication providers and in advancing the performance of consumer electronics. Its precision engineering ensures it can withstand and operate efficiently in a wide range of conditions, cementing its place as a core component in innovative telecom solutions.
Novatek's Power Management Controllers play a vital role in managing the power supply for diverse electronic systems including televisions, notebooks, monitors, smartphones, and wearable devices. These controllers provide robust solutions that optimize power usage, ensuring operational efficiency while maintaining high performance. The intricate design of these controllers allows them to smartly distribute and regulate power across multiple components, significantly extending the lifespan of electronic devices. Their implementation is crucial for achieving a balance between power efficiency and functional demand in modern electronics. Novatek's commitment to innovation reflects in the versatility and dependability of their Power Management Controllers. Continued investment in R&D aids in refining these solutions, maintaining their effectiveness in a market driven by increasing demand for energy-efficient technologies.
Key ASIC's Analog IP solutions offer an expansive range of components designed to enhance electronic systems with precise analog functionality. These IPs include diverse codecs, such as high-fidelity audio codecs with Sigma Delta modulation, supporting multiple bit depths to accommodate different audio quality requirements. The product lineup also comprises voice codecs, sophisticated ADCs and DACs, featuring varying resolutions and frequencies, some reaching up to 200 MHz. Moreover, these IP components include advanced features like programmable gain amplifiers (PGAs) and robust power management options, composing bandgap references, voltage regulators, and DC-DC converters. These elements are pivotal in maintaining efficient power distribution within circuits, thus bolstering the overall performance and reliability of the end devices. The versatility of Key ASIC's Analog IP fosters its application across numerous fields such as audio processing, sensor interfacing, and more conventional electronics. With high accuracy and low noise characteristics, this IP suite ensures a dependable analog-to-digital conversion, vital for applications requiring seamless data transmission and processing in dynamic environments.
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 Dukosi Cell Monitoring System (DKCMS) is at the forefront of revolutionizing the monitoring of battery systems at the cell level. This system is meticulously designed for high-performance batteries, integrating a DK8102 Cell Monitor on each cell which meticulously gathers precise voltage and temperature data. These monitors employ Dukosi's proprietary C-SynQ® protocol for seamless communication, transmitting data to a System Hub through a single bus antenna via near-field RF technology. Placed typically on the same PCB as the BMS host processor, the System Hub interfaces via the DKCMS library ensuring robust and power-efficient operations. The distinctive value of DKCMS lies in its scalable architecture. Capable of integrating with up to 216 cells, it supports the formation of expansive battery packs and allows for flexibility at the cell level without necessitating a comprehensive redesign. This intrinsic flexibility makes it a versatile system that can cater from the nuances of electric vehicle applications to utility-scale energy storage systems, providing improved uptime and a streamlined assembly process. By ensuring reliable and deterministic communication within safety-critical environments, DKCMS maintains advanced levels of efficiency and safety performance. Additionally, the system's ability to manage the complexity of communication between numerous nodes securely amplifies its utility, making it a cornerstone of future-proof and sustainable battery technologies.
The Current-mode Buck Converter is engineered to support a load current of up to 2.5A, ideal for power-intensive applications such as computer peripherals and industrial electronics. It effectively manages input voltage ranges between 2.7V to 5.5V, with an adjustable output voltage stretching from 0.6V to 2.5V, and operates with grounding currents under 30μA. It features current-mode control, providing superior speed responses and improved stability in the face of input voltage or output load changes. This converter maintains a precise voltage regulation with an accuracy of 1.5%, enhancing efficiency and performance in complex operating environments. The converter is silicon-proven over Samsung's 65nm technology, attesting to its high performance and reliability. Its robustness and efficiency make it a versatile choice for systems demanding meticulous power management solutions.
SiliconIntervention's Fractal-DTM Amplifier represents a cutting-edge architectural solution designed to enhance the efficiency of Class-D drivers across a spectrum of power levels. This innovative amplifier boasts a self-determining capability, allowing it to optimize efficiency dynamically throughout its operational range. The approach taken by SiliconIntervention involves a deep integration of architectural planning to address real-world challenges faced by Class-D amplifiers, achieved through groundbreaking analog signal processing methods. The Fractal-DTM Amplifier uniquely positions itself by utilizing sophisticated techniques that allow it to adapt its operational modes, ensuring superior performance at any given power setting. This adaptability is a testament to SiliconIntervention's commitment to leveraging the "New Analog" approach, propelling analog signal processing into territories traditionally dominated by digital counterparts. Through this product, SiliconIntervention not only highlights the potential of analog-based solutions in modern electronics but also sets a precedent for future developments in the field, where power efficiency and adaptability are increasingly critical.
CurrentRF's PowerPad Dynamic Power Reduction is a groundbreaking IP designed to significantly reduce power consumption in integrated circuits without increasing area usage. By overlaying power and ground bondpads, the PowerPad enhances the energy efficiency of ICs by dynamically adjusting power flow, effectively harvesting unused dynamic power and channeling it back into the circuit. This results not only in saving significant kilowatt-hours of energy but also in extending system and battery life. Integrated into existing structures with almost zero area expansion, the PowerPad sets a benchmark for energy conservation in chip design, making it particularly advantageous for applications where space is a constrained resource. It is particularly tailored for use in environments such as data centers and cloud computing where power efficiency correlates directly with operational cost savings and environmental impact. The technology inherent to the PowerPad also supports the enhancement of signal integrity by reducing EMI effects and thus bolstering the overall reliability of digital systems. This dual capability of reducing costs while increasing performance ensures its standing as a vital component in the toolkit of power-conscious designers.
These High-Voltage Integrated Circuits (ICs) from Advanced Silicon are crafted to manage high-pin counts and multi-channel output drivers specifically for thin film technologies. Designed to provide a broad range of voltage drive capabilities, these ICs can handle detailed digital-to-analog conversion with various DAC resolutions and multiple channels. This product range encompasses foundational two-level drivers as well as precise DACs, which possess a remarkable capability in turning on or off thin film switching devices by driving the gate electrode in technologies like amorphous Silicon, Low-Temperature Poly-Silicon, and IGZO. Additionally, these ICs are suited for accurately driving analog components in MEMs devices and capacitive loads like those of ITO. Especially popular in flat panel displays like LCD, OLED, and even large formats like digital flat panel X-ray detectors, these line drivers hold up to 512 output channels and utilize a COF package. The DAC drivers, on the other hand, offer DACs with resolution capabilities reaching up to 1024 output voltage levels, making them apt for precise pixel capacitive loads.
The pPOR01 is a Power-On Reset module designed by Perceptia Devies Australia, providing reliable initialization for digital integrated circuits. Essential in ensuring proper startup, this module resets the system whenever the power supply returns to predefined operational values, thus safeguarding the system from unpredictable behavior due to brownouts or power fluctuations. The pPOR01 module is deployed in various applications where robust and consistent resetting capabilities are necessary. Designed for easy integration, it supports a host of standard flows, simplifying the process of embedding this functionality into broader chip designs. Perceptia has engineered the pPOR01 with a focus on effectiveness and dependability, maintaining a compact size while delivering a seamless user experience. Its implementation helps manage critical startup sequences, ensuring that downstream components receive a stable signal to verify a system's state post power-up.
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.
The Cap-less Low Dropout Regulator (LDO) is designed to offer efficient power management for low-current applications, with a load current capacity of 100mA. Its cap-less design negates the need for an external capacitor, simplifying device integration and saving on PCB space, making it highly suitable for compact and efficient designs. Operating with an input voltage range from 1.7V to 5.5V and delivering an output voltage between 0.8V and 4V, the regulator exhibits a grounding current of less than 150μA. It's built to present a voltage regulation precision of 2%, ensuring stable power supply across variable loads. The Cap-less LDO's silicon-proven design on Magna's 130nm and 180nm nodes underlines its reliability and adaptability in devices where board real estate and component count are primary concerns.
Designed for high-power delivery, the Voltage-mode Buck Converter is capable of handling currents up to 3A, tailored for use in applications such as power supply modules and automotive electronics. The device operates over an extensive input voltage range of 4.5V to 48V, delivering an output voltage between 5V and 20V, ensuring broad utility across varied voltage requirements. This voltage-mode buck converter maintains high efficiency and power density, benefiting from a tightly controlled regulation which assures power stability and performance in high-load scenarios. It is particularly suited for applications where high input voltages need efficient down-conversion. The converter is developed using X-FAB's 180nm process node, reflecting its robust design and silicon-proven efficacy, equipped to tackle the demands of high-voltage applications while ensuring energy efficiency and performance.
The BG-1V2-U is a meticulously crafted ultra-low power Bandgap Reference Circuit that delivers consistent and precise voltage reference. It is designed to provide a stable 1.2V reference voltage, making it highly suitable for applications where power efficiency and reliability are critical. Manufactured using UMC's advanced 0.13 µm technology, it fits perfectly into modern electronic systems demanding precision and stability. This reference circuit exhibits impressive power-saving features, characterized by its zero power supply current, to support extended battery life in portable electronics. Its compact design ensures minimal space requirements, yet it does not compromise on performance, thanks to its sophisticated layout that minimizes thermal errors and offsets. Ideal for integration in a wide array of circuits, the BG-1V2-U's performance excels in both digital and analog designs. The circuit is particularly advantageous for use in voltage-sensitive devices like ADCs, DACs, and other precision electronic applications, ensuring optimal operation and minimal drift over varying conditions.
This General-purpose Low Dropout Regulator (LDO) is engineered to offer a variable load current output of 150mA, 300mA, or 450mA. It is designed for applications demanding efficient power regulation with low quiescent current requirements, which is crucial in portable and battery-operated devices. The LDO supports an input voltage range from 1.7V to 5.5V and provides a regulated output between 0.8V and 4V with a grounding current of less than 20μA, enabling high-efficiency operation across a wide load spectrum. It integrates high precision, maintaining an accuracy of 2% in voltage regulation, making it ideal for sensitive applications that require stable power. Manufactured using Magna's 130nm and 180nm process technologies, it ensures consistent performance and reliability. Its proven silicon capability further solidifies its suitability for diverse electronics needing robust voltage regulation.
X-REL, a division of EASii IC, focuses on designing, manufacturing, and marketing high-reliability integrated circuits suitable for the most challenging environments. These chips are engineered to operate reliably at extreme temperatures ranging from -60°C to +230°C, catering to applications in oil and gas, aerospace, automotive, energy, and industrial sectors. The X-REL product line includes components like power management units, logic interfaces, transceivers, and more. Products in the XTR series are available in ceramic, metal, or die packaging for temperatures up to +230°C, whereas the XER series offers plastic packaging for environments up to +175°C. These components ensure long-term reliability over their operational life, reducing the overall system cost throughout the product lifecycle. X-REL's collaboration with globally recognized subcontractors guarantees unmatched quality and reliability, supported by ISO9001 and EN9100 certifications.
The CC-100IP RF by CurrentRF is engineered to tackle RF emissions and improve EMI characteristics in integrated circuits. It acts as an on-chip solution to reduce electromagnetic interference, targeting power grids on chips where digital dynamic currents are a concern. This IP forms the lowest impedance point in an IC power grid, significantly enhancing on-chip supply filtering capabilities. The CC-100IP RF notably trims down digital dynamic currents by up to 40%, effectively reducing unsought emissions and improving circuit performance. Emphasizing its cybersecurity benefits, this IP enhances on-chip security by cultivating a more controlled electromagnetic environment, minimizing potential points of attack that could be exploited through RF emissions. With applications extending to various digital and mixed-signal environments, it supports the intricate balance of maintaining low emissions while safeguarding data integrity. The design prowess of the CC-100IP RF showcases substantial improvements, achieving up to a 600-fold increase in reservoir capacitance, allowing for more efficient power management. The IP thus becomes indispensable in applications where energy efficiency and RF emission management are central goals, such as in consumer electronics and automotive sectors where demand for lower power consumption and heightened security is persistent.
The VR-3V3-1V2-1-55-U is a highly efficient ultra low power voltage regulator designed to step down an input voltage of 3.3V to an output voltage of 1.2V. Suited for low-power applications, this regulator stands out with its extremely low current consumption of just 1.8 µA, making it ideal for battery-powered devices where power conservation is crucial. The voltage regulator's architecture is built on UMC's 0.06 μm process node, providing a compact and efficient design conducive to integration in space-limited applications. With its robust performance, the VR-3V3-1V2-1-55-U supports a wide range of portable electronics, delivering consistent power output with minimal heat dissipation. Particularly beneficial for devices that require constant power regulation, this voltage regulator will ensure operational stability across varying input conditions. It's an invaluable component in the design of sensors, mobile devices, and other power-sensitive technologies, allowing for enhanced battery life and fewer power-related interruptions.
The 16mA 4V Voltage Regulator is engineered to deliver stable voltage regulation up to 16mA, ensuring efficient power management in electronic circuits. This regulator operates with a singular supply voltage of 5V alongside a precision reference voltage, tailored to accommodate various applications requiring stable power delivery. It is silicon-proven within XFAB's XT018 technology, though it can be transferred to other technology platforms on demand. The device is particularly well-suited for applications needing reliable voltage regulation under varying operational conditions, enhancing circuit performance and longevity.
The SoC Management technology by Sondrel is a comprehensive suite dedicated to the oversight of system start-up processes, along with clock and reset control, and handling of power domains. Central to this suite is the Power Management Unit (PMU) which oversees the SoC's initialisation, allowing for dynamic software-controlled power-ups and shutdowns of digital domains. It is proficient in reset management and addresses system faults by deploying preventive measures like shifting the system to 'Safe-Mode' during functional safety anomalies. Another component, the Universal Reset Generator (URG), serves an essential role in reset management tailored to the intricate logic systems within an SoC. The URG is designed to be lightweight yet scalable, facilitating multiple instances across multi-power-domain SoCs for intricate reset control. Its adaptable design leads to effective reset sequencing without compromising on complexity handling, stemming from a variety of hardware and software-driven events. Complementing these is the Universal Clock Generator (UCG), tasked with the meticulous management of on-chip clock systems. Accommodating numerous clock sources, the UCG enables the independent configuration of up to 128 clocking channels. It includes mechanisms for design safety and reliability, enabling fault detection in clock sources to maintain system stability. By incorporating such nuanced and flexible technologies, Sondrel's SoC Management suite stands as an integral solution for managing complex chip architecture systems.
The CM1713ff Li-Ion Battery Charger presents an efficient, linear charging solution for Lithium-Ion batteries. Capable of fast charging currents up to 1500mA, it stands out for delivering compact integration scalable across various applications. Designed to operate on a 0.18µm BCD process, its role in power management is crucial in maintaining battery health through built-in protections and +/-1% voltage accuracy, vital for maximizing Lithium-Ion battery lifespan and reliability. Featured for its high charging precision, the CM1713ff is useful in powering devices from consumer electronics to industrial applications. The charger reduces thermal impact and enhances charge cycle efficiency, ensuring that devices maintain functionality over extensive use. With a proven track record in production environments, this IP is designed to streamline design pathways for manufacturers needing dependable, long-life power solutions. Its compatibility and robust design ensure it fits within diverse ecosystem setups, contributing to a broad range of product designs.
MosChip's Mixed-Signal IP Solutions merge the functionalities of both digital and analog domains to provide efficient, high-performance semiconductor components. These IPs are crafted to handle complex design requirements, delivering seamless integration of analog and digital circuits. Ideal for a broad spectrum of applications, these solutions offer the flexibility and efficiency necessary for today’s intricate electronic environments. Leveraging MosChip’s extensive expertise in mixed-signal engineering, these IPs include data converters, power management units, and various interface modules that collectively enhance the performance of electronic systems. They are meticulously designed to ensure optimal power efficiency and signal fidelity, crucial for maintaining the integrity of signal processing in higher-level applications. The versatility of MosChip's Mixed-Signal IPs makes them suitable for industries ranging from telecommunications to consumer electronics and industrial automation. Designed to accelerate deployment and minimize development risks, these IPs have become a staple in semiconductor product strategies, aiding businesses in achieving faster time-to-market and cost-effective production.
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.
Rezonent Corporation's Energy Recycling System represents a substantial leap forward in reducing the power footprint of semiconductor chips. This technology focuses on capturing energy typically lost during device operation, such as heat dissipated from high-frequency components, and recycling it back into the system. Utilizing an innovative combination of RF analog methods and digital switching, this system effectively recaptures and re-utilizes wasted energy across critical chip components such as Clock, Data, and Memory circuits. The Energy Recycling System is at the intersection of performance enhancement and sustainability. By allowing chips to operate with significantly reduced power requirements, it supports longer device operation cycles and diminishes overall energy consumption. The system's integration into contemporary chip designs is straightforward, enabling manufacturers to incorporate these energy-efficient features without extensive redesigns, achieving over 30% reduction in power usage, and thereby aligning with both public and private sector initiatives targeting carbon footprint reduction. Moreover, the system not only benefits energy profiles at the chip level but also transforms broader applications, from consumer electronics to massive data centers, which deal with escalating power demands. Through its implementation, devices can achieve 'next node' performance, offering increased speed and efficiency akin to stepping up to the subsequent iteration of semiconductor technology, making Rezonent Corporation pivotal in the evolution towards sustainable technological progress.
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.
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