All IPs > Analog & Mixed Signal > A/D Converter
In the realm of Analog & Mixed Signal technology, A/D Converter semiconductor IPs play a critical role. These IPs, also known as Analog-to-Digital Converters, are essential components in modern electronics that convert real-world analog signals, such as sound, light, or pressure, into digital signals that can be processed by digital circuitries. This conversion is vital for various applications across several industries, including telecommunications, healthcare, consumer electronics, and automotive sectors.
The primary function of an A/D Converter semiconductor IP is to enable seamless interaction between analog input sources and digital processing units. High-quality A/D Converters ensure accurate data capture and conversion, minimizing loss of information during the transformation process. As the demand for more precise and faster data processing increases, the importance of these IPs grows, driving innovations in resolution, sampling rates, and power efficiency.
In Silicon Hub’s A/D Converter category, you'll find a diverse range of semiconductor IPs tailored to meet specific needs of system designers and engineers. Whether you require low-power solutions for battery-operated devices or high-speed converters for data-intensive applications, our catalog offers the perfect fit. Products range from delta-sigma modulators for audio applications to high-speed pipeline converters often used in video processing or RF communication systems.
Developers and manufacturers can greatly benefit from integrating these cutting-edge A/D Converter IPs into their electronic designs. They not only improve the functionality and accuracy of electronic devices but also enable the creation of innovative products that respond adeptly to the challenges of the modern digital era. Explore Silicon Hub’s collection today to find the right A/D Converter IP that matches your technical requirements and enhances the performance of your products.
The agileADC analog-to-digital converter is a traditional Charge-Redistribution SAR ADC that is referenced to VDD, VSS. The architecture can achieve up to 12-bit resolution at sample rates up to 64 MSPS. It includes a 16-channel input multiplexor that can be configured to be buffered or unbuffered, and support differential or single-ended inputs. 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 Single-Channel, 12-Bit, 1-MSPS Successive Approximation Register Analog-to-Digital Converter (SAR ADC) is a high-performance component designed for precise data conversion in a variety of applications. This ADC efficiently converts analog signals into digital data, with a resolution of 12 bits and a sampling rate of 1 million samples per second, making it ideal for applications requiring fast and accurate data processing. This ADC is specifically designed to operate in low-power environments while maintaining a high level of accuracy, making it suitable for portable and battery-operated devices. Its architecture minimizes the power consumption without compromising performance, allowing integration into systems where power availability is a concern. This flexibility makes it a favorable choice in diverse sectors like consumer electronics, medical devices, and industrial automation. The high-resolution conversion ensures precise signal processing, enabling nuanced readings of analog inputs, which is crucial for applications where detail accuracy is paramount. By providing a comprehensive solution for signal conversion, this ADC component plays a critical role in enhancing the efficiency and reliability of electronic systems. Its design is further optimized to facilitate easy integration into existing systems, offering a seamless upgrade path for enhancing performance without significant system alterations.
The LVDS/D-PHY Combo Receiver by Mixel is intended for high-throughput environments where compatibility with both LVDS and D-PHY standards is essential. It combines the benefits of a source-synchronous physical layer for MIPI D-PHY and the TIA/EIA-644 standard LVDS, offering significant versatility. Its high-performance architecture ensures rapid data provisioning with minimized energy requirements, making it ideal for use in devices where efficient power handling and robust communication interfaces are necessary.
The ADX series of continuous-time delta-sigma ADCs by SCALINX leverage advanced proprietary SCCORETM technology to deliver high-speed data conversion with low latency. These ADCs are meticulously engineered to cater to demanding applications requiring impeccable signal fidelity and minimal noise interference. Available in multiple configurations, they support wide bandwidths up to 300MHz and resolutions up to 16 bits, ensuring precise data acquisition and processing. The ADX ADCs cater to a broad spectrum of applications where accuracy and speed are paramount, such as high-performance audio systems, precision measurement instruments, and communication devices. With their silicon-proven designs, these ADCs have been validated in various process nodes, ensuring reliable operation across different semiconductor technologies. Their ability to deliver exceptional performance while maintaining energy efficiency makes them a valuable addition to any system requiring cutting-edge ADC capabilities. Built to accommodate various design environments, the ADX series ADCs integrate seamlessly into existing platforms, offering users a robust, adaptable solution for enhanced signal conversion needs.
The Analog to Digital Converter IP from Omni Design Technologies is crafted to meet the rigorous demands of cutting-edge digital processing systems. This family of high-speed and ultra-low-power converters is essential for applications like 5G wireless communications, automotive Ethernet, and advanced imaging systems such as LiDAR and RADAR. The ADC solutions are built on the innovative Swift™ technology, which emphasizes efficiency and dynamic performance. Available in resolutions ranging from 6 to 14 bits and with sampling rates that extend over 100 Gsps, these converters handle high-speed data environments with ease. Their configuration as I/Q ADCs or multi-channel systems offers flexibility, allowing seamless integration operational enhancements within complex systems. Integrated calibration mechanisms ensure consistency, automatically adjusting for both static and dynamic conditions without impacting system throughput. Omni Design’s ADC IPs represent a critical junction between analog inputs and digital systems. They manage the direct IF conversion of signals in RF systems and support advanced computational structures, such as data centers and AI platforms. By minimizing noise and distortion, these converters enhance clarity and integrity in digital signal processing applications, proving indispensable in high-performance devices.
The KL730 AI SoC is equipped with a state-of-the-art third-generation reconfigurable NPU architecture, delivering up to 8 TOPS of computational power. This innovative architecture enhances computational efficiency, particularly with the latest CNN networks and transformer applications, while reducing DDR bandwidth demands. The KL730 excels in video processing, offering support for 4K 60FPS output and boasts capabilities like noise reduction, wide dynamic range, and low-light imaging. It is ideal for applications such as intelligent security, autonomous driving, and video conferencing.
The LVDS Serializer from Mixel is a high-efficiency component designed for converting parallel data streams into serial data format. With capabilities that maximize data rates up to 5Gbps, it serves high-performance applications needing efficient data transmission over minimal wiring. Implemented using digital CMOS technology, this serializer works over four channels, allowing smooth integration into systems demanding high throughput with reduced electromagnetic interference. Its adaptations make it well-suited for data-intensive environments such as high-speed data acquisition systems or video transmission interfaces.
Mixel’s LVDS/D-PHY Combo Transmitter is a versatile component tailored for high-speed data transmission. It integrates a MIPI D-PHY with a robust LVDS transmitter, creating a platform capable of handling the diverse requirements of modern telecommunications. This combo allows seamless interfacing between components using different signaling standards, enhancing system compatibility. Through its energy-efficient architecture, the transmitter is suited for applications that prioritize reduced power consumption without compromising on speed, such as in mobile or portable devices.
The 4.25 Gbps Multi-Standard SerDes is a high-speed serializer/deserializer block capable of supporting data rates up to 4.25 Gbps. Its multi-standard capability allows for integration into a variety of architectures, enhancing both data throughput and system interoperability. Built using robust digital CMOS technology, it efficiently manages high-bandwidth tasks while maintaining low power consumption. This SerDes is particularly useful in applications requiring extensive data channels, such as complex communication networks and multimedia interfaces.
The ADQ35 is a high-performance digitizer offering remarkable capabilities for applications demanding precision and speed. It features a two-channel configuration, each delivering a sampling rate of 5 GSPS, or alternatively, a single-channel mode at 10 GSPS. This flexibility ensures that users can tailor its use to specific needs. The digitizer's DC-coupled front-end, with up to 2.5 GHz bandwidth, is well-suited for dynamic signal environments. One of the standout features of the ADQ35 is its open FPGA architecture, which supports custom real-time digital signal processing. Users can benefit from its programmable DC-offset, accommodating a range of signal types for enhanced accuracy. With 8 Gbytes of onboard memory, it supports substantial data storage and processing capabilities. Its peer-to-peer streaming capability allows for seamless data transfer at rates up to 14 Gbyte/s to either a host PC or GPUs. Suitable for cutting-edge applications such as Swept-Source Optical Coherence Tomography and LiDAR, the ADQ35's advanced hardware triggering and GPIO facilitate robust data acquisition setups. Its PCIe form factor ensures it integrates easily into existing systems, offering a comprehensive tool for scientific instruments and testing environments.
The High-Resolution ADC or Analog-to-Digital Converter by Eureka Technology is designed to offer superior digital conversion accuracy for high precision applications. This ADC ensures minimal error rates, making it ideal for use in rigorous data acquisition tasks and instrumentation. It integrates advanced digital processing capabilities to efficiently translate analog signals into precise digital data. Designed to cater to sophisticated design requirements, it offers customizable features that enhance performance metrics in specific applications. These attributes make it adaptable for use in scientific research domains, telecommunication systems, and complex sensor networks. The ADC stands out for maintaining signal integrity while enhancing operational ease across a range of input conditions. Optimized for efficient digital transformation, the High-Resolution ADC plays a crucial role in developing reliable and high-performance computing systems. By ensuring seamless integration with existing semiconductor frameworks, Eureka's ADC addresses both standard and custom application needs.
Mixel’s LVDS Deserializer is engineered to convert high-speed serial data streams back to parallel data format. Implemented with digital CMOS technology, it supports up to 5Gbps data rate over multiple channels, enabling efficient data handling in data-centric systems. This component ensures reliable data integrity and quick adaptation to different data transmission needs, making it particularly suited for applications such as image processing, high-definition video decoding, and other systems where data precision and speed are critical.
The 65nm low-power ADC delivers 12-bit resolution across eight channels, making it exceedingly suitable for systems demanding accurate signal processing along with power efficiency. Operating reliably over an analog supply range of 2.4V to 3.6V and a digital supply from 1.08V to 1.32V, it fits well into systems where stability across varying voltages is critical. Its high spurious-free dynamic range (SFDR) of 88dB assures unadulterated signal fidelity, essential for both industrial and medical solutions. With a variable conversion rate from 0.1MSPS to 1MSPS, the device permits flexible deployment depending on throughput and power constraints. This adaptability makes it ideal for data acquisition systems, particularly in environments where quick, precise readings are mandatory yet power conservation cannot be overlooked, such as in battery-powered devices. Capable of enduring a broad operating temperature range from -40°C to 125°C, the ADC is robust enough for harsh environments. Its power-down mode, consuming less than 0.1uA, helps prolong device life in energy-sensitive applications while maintaining readiness to perform promptly as needed. This combination of attributes aligns with needs for efficient and comprehensive data handling in embedded control systems, especially in engineering and scientific instrumentation applications.
The Delta-Sigma ADC provides a striking 14-bit resolution paired with a rapid 20Msps sampling rate, setting it apart in high-speed, high-precision conversions. It's engineered to support demanding applications, where accurate signal conversion is crucial, such as wireless communications and advanced instrumentation. The ADC employs delta-sigma modulation, which results in minimal signal distortion and enhanced dynamic range. This high-performance solution aids in capturing pure signals, eliminating detrimental noise components effectively. Manufactured with TSMC's 65nm process node, this silicon-proven ADC is ready for integration into sophisticated electronic systems, offering reliability and advanced technology to address modern industry challenges in data conversion.
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.
The ADQ7DC sets a high standard in digitization technologies, offering a sophisticated solution with a sampling rate of up to 10 GSPS and a 14-bit vertical resolution. This high-resolution mode can be adjusted between single-channel (10 GSPS) or dual-channel (5 GSPS) configurations, accommodating a wide variety of high-speed data acquisition requirements. Designed for flexibility and performance, the ADQ7DC features a DC-coupled front end with a 3 GHz input bandwidth, coupled with a programmable digital noise-reduction filter that enhances signal clarity and precision. Its comprehensive firmware options simplify setup and drastically shorten time-to-operation, delivering real-time features without needing significant FPGA programming expertise. Ideal for advanced scientific applications, including imaging flow cytometry and particle physics, the ADQ7DC excels in environments requiring meticulous data capture and analyses. Additionally, it offers robust connectivity through multiple form factors, such as PCIe and USB3.0, ensuring compatibility with a broad range of systems.
Engineered for low power and high performance, the 55nm 8-channel 12-bit ADC provides 1MSPS rates with impressive energy efficiency, crucial for battery-powered and low-power sensor networks. Its design supports an analog power supply of 2.4V to 3.6V and digital supplies from 1.08V to 1.32V, ensuring broad application flexibility in variable environments. The analog input range, defined between REFB and REFT, accommodates diverse signal magnitudes, enhancing integration in mixed-signal systems. This ADC’s outstanding power efficiency, with a typical consumption of just 1.1mA, positions it as an optimal choice for applications focusing on energy conservation without sacrificing processing speed. Such characteristics enable its deployment in wireless sensor networks and pressure sensor arrays where power conservation is critical. Enhanced by its DNL of ±1.0 LSB and INL of ±2.0 LSB, it ensures precise signal conversion, which is vital for accurate data acquisition. Designed for sectors requiring reliability, such as industrial automation and portable medical devices, the ADC ensures seamless and accurate data monitoring. With a small core footprint of 0.1mm², it is ideal for compact designs, allowing integration without compromising on board real estate. It’s these features that make it a fundamental component for scalable and efficient electronic systems aimed at precision sensing and monitoring.
InPsytech's ADC solutions include SAR, Pipeline, and SigmaDelta converters, catering to a variety of precision and high-speed conversion needs. These converters are integral in converting analog signals to digital form in a range of applications, from consumer electronics to high-precision instruments. The ADC solutions are designed to deliver accurate, fast results, essential for detailed signal processing tasks.
The aLFA-C is a versatile interfacing ASIC specifically engineered for infrared ROICs typically utilized in space applications. This device significantly replaces traditional front-end electronics infrastructure by incorporating advanced features. Designed to operate with minimal power requirements, it leverages on-chip LDOs and regulators, allowing the device to function on a single unregulated power supply. User-friendly interfaces such as SpaceWire enhance connectivity, while a fully programmable ROIC sequencer with multiple levels of nesting allows dynamic reprogramming.\n\nThe aLFA-C accommodates a wide range of input and output configurations with its 32 programmable digital outputs and 16 digital inputs, supporting differential and single-ended formats in CMOS or LVDS. It integrates a robust SPI interface alongside comprehensive analog acquisition capabilities through its numerous ADC channels. The device ensures precise control and measurement with its programmable gain and offset features, complemented by current biasing adjustments.\n\nThis ASIC is targeted towards critical environments offered by its resilience to radiation and extreme temperatures, facilitating reliable operations from deep cryogenic to high-temperature environments. With features tailored for adaptability, the aLFA-C proves indispensable in mission-critical sensor applications, enabling high precision and integration in space technology systems.
The 8-bit Delta-Sigma ADC, with a sampling rate of 2Ksps, is optimized for low-frequency, high-precision applications. By leveraging delta-sigma modulation, it ensures excellent noise shaping and high dynamic range, making it an ideal choice for environments where signal integrity is paramount. This ADC is versatile and designed for low power consumption, thus being suitable for portable and battery-powered devices. Its architecture allows for effective filtering of out-of-band noise, reinforcing its ability to deliver precise digital representations of analog signals. This silicon-proven product is available in SMIC's 180nm process, making it a reliable choice for applications such as environmental monitoring instruments and low-speed data logging systems where accuracy and efficiency are crucial.
The General-purpose SAR ADC, featuring 8 channels, 12-bit resolution, and a sampling rate of 1Msps, is designed for versatile applications requiring precise digital conversion of analog signals. It stands out with its robust performance and low power consumption, making it ideal for battery-operated and space-constrained systems. This SAR ADC operates efficiently at a supply voltage of 3.3V, ensuring high accuracy and stability. Suitable for a wide range of industrial and commercial applications, this ADC supports a sampling rate of 1Msps, allowing it to quickly and accurately capture and process analog signals. Its multi-channel architecture ensures the capability to handle diverse input signals simultaneously, providing flexibility in various system configurations. Enhanced with silicon-proven reliability, this ADC is available in process nodes provided by Magna, utilizing both 180nm and 130nm technologies. Its proven track record in silicon adds a layer of confidence for engineers seeking performance consistency in demanding environments.
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.
MeasureExpert is engineered for automated measurement and analysis, providing detailed insights essential for maintaining quality and performance in electronic products. By automating tests and measurements, this tool enables large-scale data management and quick iteration, streamlining the verification phase of electronic design. The tool's capability to handle multiple testing scenarios simultaneously makes it invaluable in ensuring that a product meets the specified requirements before production. MeasureExpert assists engineers by simplifying the testing process, reducing the potential for human error and increasing the efficiency of the quality assurance stage. MeasureExpert's automation prowess supports the production of high-reliability electronic systems, offering detailed analytical feedback that helps refine designs and confirm their readiness for market launch. It is a crucial component of any design cycle focused on high standards of precision and efficiency.
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 Swift™ ADC ODT-ADP-14B1P2G-28 represents a leap in data conversion technology, providing a low-power, high-speed solution for a wide array of applications. Designed in a 28nm standard CMOS process, this Analog to Digital Converter is part of Omni Design's renowned Swift™ series, which is synonymous with performance and efficiency. Its architecture is optimized for managing high data throughput while maintaining minimal power consumption, crucial for modern telecommunications and data processing environments. This ADC employs a pipelined design, allowing it to efficiently handle rapid data conversions at high frequencies, essential for applications in wireless communication and high-speed internet technologies. Its robust design integrates seamlessly into SoCs, providing superior performance metrics without compromising on energy efficiency. Equipped with an advanced calibration mechanism, the Swift™ ADC ODT-ADP-14B1P2G-28 ensures precision and reliability under varying conditions, making it a prime choice for critical applications requiring stable and consistent operational output. This makes the ADC a key component in enabling next-gen electronic systems that demand high accuracy and low power consumption.
This system focuses on ensuring proper alignment and compatibility for wireless power transfer. By employing advanced sensing techniques, it identifies and corrects misalignment issues, thus maintaining efficient power transfer and reducing the risk of performance degradation. This technology is particularly valuable in dynamic environments such as automotive systems where precise positioning and stable connections are critical for operational reliability.
Brite Semiconductor's YouADC solutions deliver robust Analog-to-Digital Converter (ADC) capabilities, adaptable to a wide spectrum of industrial and consumer applications. These devices are engineered to perform with high precision, facilitating accurate signal conversion in various environments. Special emphasis is placed on ensuring minimal signal distortion and high sampling rates, meeting the needs of fast-paced signal processing applications. YouADC's configurable architecture allows for customization to meet specific project demands, making it an integral component for systems requiring precise analog-to-digital conversion. The YouADC series supports seamless integration within larger system architectures, ensuring potent performance while maintaining energy efficiency. Its versatility serves applications ranging from consumer electronics to industrial automation, providing essential functionalities in signal analysis and data processing tasks.
Vantablack S-VIS is a state-of-the-art material specifically engineered for use in space applications. It is distinguished by its ability to significantly reduce stray light in optical instruments, enhancing the calibration of IR camera systems. Vantablack S-VIS coatings provide a high-performance solution with spectrally flat absorption capabilities that range from the ultraviolet to near-millimeter spectral areas. In the challenging environment of space, these coatings help streamline instrument design by reducing size and weight while maintaining exceptional light absorption and high emissivity.
This technology involves the transfer of energy without using wires, utilizing resonant magnetic fields. It's a key innovation for wireless charging, offering convenience and efficiency without the usual conductive cables. Ideal for applications where physical connectivity is impractical, this type of energy transfer supports multiple devices and configurations, ensuring adaptability across various platforms.
XPLM is an innovative solution for managing simulation processes and data in the ever-evolving field of electronic design. This tool provides a centralized platform for storing, organizing, and accessing large volumes of data, ensuring that design teams can operate efficiently and effectively. By integrating data management into the design process, XPLM reduces the complexity associated with handling vast amounts of information, thereby streamlining workflows and enhancing productivity. It supports engineers in maintaining version control and collaboration across different projects, helping manage resources and timelines more effectively. XPLM's comprehensive data handling capabilities make it indispensable for organizations committed to maintaining a competitive edge in the semiconductor industry. By simplifying the intricacies of data management, XPLM helps transform simulation insights into actionable strategies, driving design innovation and operational excellence.
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.
SnpExpert is a dedicated platform designed for in-depth S-parameter analysis, which is vital in understanding the behavior of RF and high-speed digital circuits. By providing an unparalleled view of network parameters, this tool helps engineers ensure that designs will perform as expected across different frequencies and scenarios. The precision and clarity offered by SnpExpert simplify the analysis of complex interactions within electronic systems, allowing for efficient troubleshooting and optimization. This feature is particularly valuable when modifications are needed to enhance circuit performance, enabling refined design choices that foster innovation and reliability. SnpExpert's robust analytical capabilities make it an essential tool for tackling the intricate challenges associated with RF design and testing. Its insights into S-parameter metrics enable designers to achieve the optimal performance required in today's demanding technological landscape.
Xinglian-500 represents StarFive's intricate design of an interconnect fabric supporting memory coherence across multiple CPU and SoC platforms. This solution underscores high bandwidth and efficient data transfer among interconnected components, essential for multi-core and sophisticated SoC architectures. By integrating Xinglian-500, devices benefit from a coherency maintained NoC that ensures latency minimal attributed operations crucial for modern computing demands. The architecture facilitates seamless data flow between CPU clusters, I/O devices, and DDR memory solutions. This connectivity competence underpins robust performance, making it integral to device structure seeking to maximize resource utilization across expansive computational tasks. Designed to enhance performance metrics in SoC domains, Xinglian-500 supports high-speed communication required for advanced processors and peripheral integrations. It embodies StarFive's commitment to advancing scalable and efficient interconnect solutions, vital for both contemporary and emerging technological landscapes.
Enosemi's analog and mixed-signal devices are engineered for seamless integration into advanced photonic circuits, enabling high-speed data processing and signal conversion. These devices leverage cutting-edge technologies to offer both low and high-speed functionalities, catering to a wide range of applications, including telecommunications and data communications. The IP is silicon-verified, which ensures reliability and reduces integration times, offering a cost-effective solution for complex photonic systems.
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.
The Pipelined SAR ADC with 16 channels offers a 12-bit resolution and a sampling rate of 1.5Msps, making it suitable for applications needing high-speed and high-resolution data acquisition. This advanced ADC employs a pipelined architecture, which enhances its throughput while maintaining accuracy and low latency. Engineered for precision, the ADC operates at a supply voltage of 5.0V, providing robust performance across varying conditions. The architecture is designed to efficiently handle large datasets, making it suitable for data-intensive applications. Its ability to manage multiple channels simultaneously adds to its versatility. The device is silicon-proven with Samsung, operating on a 65nm process node, which ensures reliability and integration ease for complex systems. Its superior performance characteristics make it ideal for automotive, industrial, and communications applications where high data integrity and speed are critical.
The Telecommunication ADC is an 8-bit, asynchronous analog-to-digital converter optimized for high-speed telecommunication applications. Its design is calibrated for operation within TSMC’s 28HPC process, aiming to achieve swift data conversion rates of up to 1.2 Gbps. This high-speed capability supports advanced telecommunication systems, improving signal integrity and noise reduction. Engineered for performance and efficiency, this ADC remains asynchronous, allowing flexible application where clock alignment is critical. The converter's asynchronous nature also aids in managing power consumption, making it viable for integration into portable telecommunication devices where battery-life optimization is essential. A continued focus on reliability and precision marks this ADC as a top contender for today's digital communication needs. With promising capabilities designed to meet the evolving telecommunication standards, it supports clear and precise signal conversion essential for modern telecommunication infrastructures.
The ADC-12-35M-TJ is a robust pipeline analog-to-digital converter that delivers 12-bit resolution at speeds of up to 35 MS/s. Utilizing TowerJazz's 0.18 μm technology, it is designed for high-speed signal processing applications that demand precision and efficiency. This ADC's enhanced noise performance and linearity make it well-suited for use in communication systems, data acquisition instruments, and medical devices. Characterized by its high effective number of bits, the ADC-12-35M-TJ provides superior dynamic range and low jitter, ensuring that it can handle a wide variety of signals with minimal distortion. Moreover, its power-efficient design contributes to reduced thermal output, making it suitable for compact systems. With its superior digital output accuracy, this ADC is particularly beneficial for applications that require accurate data representation and minimal error. Its ability to maintain performance across variable conditions makes it an appealing option for advanced signal processing systems.
SystematIC provides a comprehensive collection of analog converters and amplifiers designed for sensor array applications. Capable of converting and amplifying signals from diverse sensors, these components are integral for precision measurement systems. These converters employ techniques such as Sigma-Delta modulation to achieve high-resolution data conversion, necessary for sophisticated sensor applications. These components are a part of intricate systems where precise analog-to-digital conversion and signal amplification are necessary, catering to varied measurement tasks including temperature, pressure, and ambient light assessments. Tailored for high accuracy and low noise, the converters and amplifiers assist in capturing and interpreting fine signal details essential in scientific and industrial applications. They support different integration levels, including photodiode and temperature sensor readouts, proving essential in applications requiring exact measurements. Their ability to support multiple sensor inputs with accurate analog amplification makes them a go-to choice in complex electronic assemblies that demand reliable performance under various conditions.
The ELFIS2 is an advanced visible light image sensor notable for its radiation hardening, making it highly reliable in challenging environments. This sensor is engineered with a true high dynamic range, ensuring superior image quality across varying lighting conditions without suffering from motion artifacts. It features a global shutter technology combined with backside illumination, enhancing the capture of moving subjects and ensuring precise image reads.\n\nDesigned for durability, the ELFIS2 withstands high levels of radiation, making it suitable for use in aerospace and other environments exposed to high radiation levels. The sensor provides outstanding image clarity and fidelity, thanks to its architecture that minimizes noise and maximizes the dynamic range capabilities. This enables the sensor to perform exceedingly well in both low-light and high-contrast settings, making it ideal for scientific and industrial imaging applications.\n\nThe global shutter feature is pivotal in eliminating geometric distortion effects while its backside illumination maximizes light collection efficiency, vital for applications requiring stringent image quality. This makes ELFIS2 apt for scenarios demanding precise and error-free image capture, confirming its application in intricate research and development projects.
This is a finely tuned 12-bit Analog to Digital Converter (ADC) known for its ultra-low power consumption and high efficiency, ideal for portable devices and IoT applications. It supports rapid sampling rates and provides exceptional data conversion with minimal power requirements.
The Analog to Digital (ADC) IP from Analog Circuit Works is designed to cater to diverse application needs, including varying resolutions and sample rates. Unlike standard ADCs, these solutions are meticulously optimized for particular use cases, ensuring superior performance. They offer a broad range of semiconductor process compatibility, pushing the limits of what traditional designs can achieve, often far surpassing common commodity offerings.\n\nTheir ADC IP can be tailored for specific market demands, offering different family types with unique resolutions and sample rates that are optimized for various process technologies. This flexibility ensures that each application benefits from a high level of customization, maintaining a balance between power efficiency and high performance.\n\nBy choosing the ADC IP from Analog Circuit Works, customers can achieve a significant technological advantage, leveraging cutting-edge design that promises not only enhanced functionality but also superior integration capabilities, thereby facilitating the creation of more robust and efficient electronic systems.
This technology revolves around ParkerVision's revolutionary approach to RF receivers using energy-sampling techniques. Historically, super-heterodyne technology was the cornerstone for handset receivers, characterized by multiple down-conversion steps employing traditional mixers. These demanded high local oscillator power, a hindrance in low-power-CMOS applications. ParkerVision innovated by developing RF energy sampling techniques, producing practical matched-filter correlators for frequency down-conversion. This innovation achieves unmatched sensitivity, bandwidth, and dynamic range for direct-conversion receivers, while enhancing selectivity and interference rejection. By eliminating RF signal splitting between I and Q paths, ParkerVision's technology reduces power consumption and improves demodulation precision. The technology's compact and cost-effective nature supports low silicon area usage, thanks to fewer resonant structures and the elimination of many external filters. Widely applicable, the technology is adept at integrating into devices like handsets, modems, and tablets across various standards (GSM, EDGE, CDMA, UMTS, LTE), enabling increased device functionality with reduced footprint and cost.
SiGe BiCMOS technology by Tower Semiconductor is crafted to support high-frequency applications such as RF and mmWave communications. It combines bipolar and CMOS transistors on a single die, offering high-speed performance and low noise, crucial for applications in wireless infrastructure, high-speed communications, and automotive sectors. These solutions are especially designed to enhance signal integrity and system efficiency with minimized footprint, enabling advanced RF applications. The cornerstone of this technology is its pioneering approach in integrating silicon-germanium heterojunction bipolar transistors (HBT) with CMOS, enabling superior switching speeds and reduced power consumption. This allows designers to achieve complex analog and mixed-signal systems' integration, which serves to benefit high-frequency signal processing demands significantly. Moreover, the technology supports a comprehensive suite of IPs that are customizable according to specific industry needs. One of the notable aspects of SiGe BiCMOS technology is its compatibility with existing design flows and infrastructure, providing a smooth transition for redesigns or enhancements of existing products. The extensive design kits ensure that systems can be conceived rapidly, with a high likelihood of first-pass success in prototyping stages. Emphasizing its versatility, Tower Semiconductor's technology extends to numerous markets, enhancing wireless, automotive, and consumer products' capabilities.
This technology utilizes enhancements to manage interference, ensuring efficient energy transfer even in environments with potential electromagnetic disturbances. By refining the way energy is transferred, this solution maximizes efficiency while maintaining high levels of safety and performance. It is particularly beneficial in complex settings where multiple devices or systems could potentially interfere with each other.
The ADQ35-PDRX digitizer distinguishes itself with a unique dual-gain architecture, allowing for an extended dynamic range by effectively boosting it by 3 bits. This feature is crucial in pulse data systems where capturing both low-amplitude signals and high peaks without saturation is essential. Operating at a 5 GSPS sampling rate, it functions with a single-channel configuration that splits the input signal for optimized performance. The digitizer's DC-coupled design supports bandwidths up to 2 GHz, tailored for high-resolution measurements with a 1 Vpp input range. An onboard FPGA facilitates advanced real-time signal processing, and the device is set up for seamless integration with PCIe for efficient data connectivity and transfer. Well-suited for applications such as time-of-flight mass spectrometry and LiDAR, the ADQ35-PDRX is advantageous for scenarios demanding quick system integration and high-speed data capabilities. It inherits all the robust features of the ADQ35 while providing additional enhancements for specific pulse measurement environments.
Xinglian-700 builds upon its predecessor with refined scalability and performance, adept at handling extensive interconnect needs presented by numerous core CPU architectures and SoC structures. This advanced interconnect fabric articulates a NoC solution that sustains extensive data paths and memory consistency, crucial in configurations that push performance limits. StarFive's design supports up to 256 CPU cores, I/O, and DDR connections, a hallmark of its superior scalability. The comprehensive architecture aims at eliminating bottlenecks in data transmission, enabling devices to achieve peak operational efficiencies. Xinglian-700 is instrumental in structures demanding synchronized and high-throughput data circulation. Purposefully created for high-performance applications, this offering positions itself as a cornerstone for contemporary SoC and CPU models that require a reliable, scalable interconnect solution that caters to complex data handling requirements. Its robustness is vital for harnessing the full potential of current technological advancements in various sectors.
Akronic specializes in designing state-of-the-art analog and mixed-signal integrated circuits. Their extensive experience covers all essential building blocks used in modern telecom and radar transceiver radios. Akronic's portfolio includes low-pass filters, often utilizing Leapfrog, OPAMP, or Gm-C architectures. These incorporate sophisticated configurations like Chebyshev or Butterworth to achieve high cut-off frequencies exceeding 1GHz. Their ICs also encompass base-band functions such as bandgap voltage references and gain-control operations, ensuring precise signal management. The company's expertise extends to high-speed signal converters, featuring both switched-capacitor and current-source DACs, along with advanced ADC designs like successive-approximation and time-interleaved architectures. Additionally, Akronic's frequency synthesis capabilities embody both fractional and integer-N PLL technologies, complete with multi-modulus prescalers and loop filters. Their focus on minutiae extends through aspects like VCO design, including innovative drivers and multiplexing solutions, making their analog and mixed-signal ICs a hallmark of advanced integrated design. Akronic integrates power-efficient designs with meticulous attention to signal integrity and stability. They provide linear-in-dB or stepped gain-control mechanisms and boast advanced AGC and ALC loop designs. Their emphasis on advanced compensation techniques, like LO leakage control, ensures optimal real-world performance, reinforcing Akronic’s authority in analog and mixed-signal innovation.
The Delta-Sigma ADC is a high-resolution data converter offering 16-bit precision at a sampling rate of 28Ksps. Utilizing delta-sigma modulation, this ADC is crafted for applications requiring high accuracy and low power consumption over slower signal bandwidths. Its high dynamic range and noise modulation capabilities make it particularly suitable for high-fidelity audio and precision measurement applications. Operating at various process nodes, the ADC's design focuses on minimizing power usage while maximizing output accuracy. It demonstrates a high degree of linearity and precision across its conversion range, thanks to its state-of-the-art modulation techniques. The ADC's under-development status with Samsung at a 65nm process node suggests cutting-edge advancements in ADC technology, offering future-ready solutions for evolving technological needs in sectors like instrumentation and consumer electronics.
SystematIC's Magnetic Hall Sensor is engineered for isolated current sensing in DC and low-frequency applications. Utilizing Hall effect technology, this sensor fully integrates sensor elements with readout electronics within standard CMOS technology. The sensor is notable for its accuracy and high bandwidth, catering to rigorous industrial standards. It features a wide operational temperature range from -40°C to 110°C, accommodating variations in environmental conditions. This sensor operates with a single supply of 5.0 V and offers a typical bandwidth of 80 kHz, making it highly efficient for diverse applications. The design is particularly commendable for its low offset, low thermal coefficient, and minimal magnetic hysteresis. With rigorous isolation properties, this sensor is UL and CSA certified, boasting a high common-mode transient immunity of greater than 25 kV/μs and an isolation voltage of 3 kVRMS for one minute. These features ensure that the sensor can reliably operate in high-voltage and electromagnetically noisy environments.