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 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.
This ADC features a 12-bit resolution and a sampling rate up to 1 MSPS, making it suitable for precise analog-to-digital conversions in various applications. It is designed to deliver high-performance data acquisition while maintaining power efficiency. This single-channel converter supports enhanced signal processing capabilities, catering to applications that demand reliable and accurate digital representation of analog signals. The ADC integrates seamlessly into custom IC designs and can be utilized in sectors such as industrial automation and medical devices.
The AFX010x Product Family is a sophisticated lineup of analog front-end ICs designed for benchtop and portable data-acquisition systems. Each product within this family boasts up to four channels, delivering resolutions up to 16-bit and sampling rates up to 5 GS/s. A key feature is the digitally-selectable 3dB bandwidth, ranging up to 300MHz, complemented by an integrated single-to-differential amplifier and offset DAC. This family represents cutting-edge innovation, tailored for applications demanding minimal power consumption, superior signal fidelity, high sampling frequencies, broad bandwidth, and heightened integration levels. Each channel is meticulously designed, encompassing programmable input capacitance, a programmable gain amplifier (PGA) for single-ended to differential outputs, an offset DAC, an ADC, and an integrated digital processor. The compact design of these solutions, housed in a standard 12 mm × 12 mm, 196-Ball BGA package, ensures easy integration with existing systems. An integral part of these products is the SCCORETM technology, which significantly cuts down on PCB space and slashes power requirements by up to 50%. These AFEs achieve standardization with features such as an on-chip clock synthesizer and voltage reference, combined with low power usage of 425 mW per channel at peak sampling rates. They support various high-resolution data acquisition applications, enabling versatile use in USB & PC-based oscilloscopes, benchtop digital storage oscilloscopes, and more complex diagnostic tools.
The ADQ35 model is designed to provide flexible data acquisition with a two-channel configuration operating at a 5 GSPS sampling rate or a single-channel at 10 GSPS. Its programmable DC-offset capability makes this digitizer suitable for sampling unipolar signals. It boasts an open onboard Xilinx Kintex Ultrascale KU115 FPGA which accommodates real-time digital signal processing, ensuring that users can customize their operations seamlessly.
Creonic delivers advanced Polar Encoders/Decoders that offer high flexibility and efficiency for cutting-edge communications. The company’s Polar solutions capitalize on polar code technology, which is recognized for its channel capacity achievement capabilities in the field of communications. These encoders and decoders are particularly input for Ultra Reliable Low Latency Communications (URLLC), with applications extending to 5G networks and beyond. Creonic’s solution supports various coding rates and code lengths, providing a robust framework for creating customized configurations based on customer specifications. Compatibility with major FPGA platforms allows for seamless integration into existing systems, ensuring optimal performance and scalability across numerous applications. The Polar Encoder/Decoder IP is designed to handle both short and long frames, providing enhanced reliability and ensuring data is efficiently and accurately transmitted over different communication channels.
Creonic's Turbo Encoders/Decoders offer advanced error correction features for modern digital communication systems. Originating from iterative decoding theory, the turbo codes provided are known for their efficiency and performance close to Shannon’s limit. These encoders and decoders come in various configurations to suit both existing and emergent network standards such as DVB-RCS2 and 4G LTE. Engineered with scalability in mind, Creonic's Turbo solutions support a wide range of data rates and frame sizes, making them a flexible choice for operators targeting satellite or terrestrial networks. Their modular design ensures easy integration and adaptability across various digital platforms and communication technologies. The products maintain high data integrity, enabling reliable data delivery even in high-noise environments. Creonic ensures that each turbo code solution is compliant with international standards, providing a seamless interoperability experience across diverse network architectures.
Creonic's LDPC Encoders/Decoders are engineered to deliver high throughput and low latency for communications and data applications. The exceptional performance of these encoders and decoders ensures that they are ideally suited for applications such as satellite communications, broadband wireless, and high-speed networking. Creonic provides a comprehensive range of LDPC solutions that can be customized to match various standards, including DVB-S2X, 5G NR, IEEE, and CCSDS. Each LDPC solution is robustly engineered, offering maximum flexibility to adapt to different code rates and frame sizes. These cores are implemented to ensure compatibility with diverse FPGA platforms like Xilinx and Intel. Customers benefit from a solid framework that integrates efficient encoding and decoding mechanisms, ensuring reliable data transfer across challenging communication environments. The LDPC products stand out for their superior error correction capabilities, which help in mitigating the adverse effects of signal degradation. Creonic's solutions target both existing and emerging communications standards, ensuring future-proof reliability and performance enhancement.
Eureka Technology offers a High-Resolution ADC (Analog-to-Digital Converter), renowned for its precise data conversion capabilities vital for applications requiring high accuracy, such as scientific research and industrial control systems. Known for its exceptional signal-to-noise ratio, this ADC is designed to perform in challenging environments while maintaining superior performance. Manufactured with meticulous attention to detail, the High-Resolution ADC integrates seamlessly with diverse systems, providing stable and reliable conversions over a broad range of input signals. Its robust architecture supports a variety of applications, from healthcare devices to electronic consumer products, emphasizing efficiency and reliability. Compliant with industry standards, this ADC's modular design allows for easy customization, adapting to specific project needs without compromising on performance. It ensures efficient power usage, making it an ideal choice for power-sensitive applications where precision and low power consumption are paramount.
Vantablack S-VIS is a revolutionary space-qualified coating renowned for its unparalleled ability to suppress stray light. This is crucial for enhancing the performance and precision of optical instruments used in space applications. With its spectrally flat absorption capabilities extending from the UV range to the near-millimeter (THz) range, Vantablack S-VIS significantly improves light absorption, reducing interference and enhancing image quality. The coating has demonstrated exceptional performance in harsh environments, thriving under the intensity of solar, lunar, and terrestrial light in a zero-gravity context. Its deployment has resulted in lighter and smaller calibration systems and baffles, which is critical for space-bound equipment where size and weight are significant constraints. These coatings enhance emissivity across the IR spectrum, making them ideal for blackbody calibration in IR cameras and other sensitive optical systems. Since its initial deployment in low Earth orbit, the Vantablack S-VIS has amassed a significant track record of success in space missions. It possesses excellent thermal stability and is resistant to radiation and extreme vibrational forces, ensuring reliability and longevity in challenging space conditions. These attributes, coupled with its lightweight nature, make Vantablack S-VIS an optimal choice for advanced space imaging technologies.
The ADQ35-WB is a versatile data acquisition module that offers a dual-channel configuration with a 5 GSPS sampling rate or a single-channel configuration at 10 GSPS. It features an impressive 9.0 GHz usable analog input bandwidth, making it ideal for high-frequency applications. This digitizer is equipped with an open onboard Xilinx Kintex Ultrascale KU115 FPGA, providing ample resources for custom real-time digital signal processing (DSP). Additionally, it supports peer-to-peer streaming at speeds of up to 14 Gbyte/s, enabling efficient data transfer to GPU, CPU, or SSD.
The ADQ7DC digitizer pushes the boundaries with its 14-bit, 10 GSPS performance. Designed for high-sampling rate applications, it provides improved resolution, facilitated by its DC-coupled front-end with variable DC-offset capabilities. This digitizer supports a 3 GHz analog input bandwidth and is equipped to handle a diverse array of sensors and applications, making it a reliable tool for sophisticated data acquisition needs.
The Xinglian-500 Interconnect Fabric is a self-developed solution by StarFive that focuses on providing consistent memory coherence in multicore CPU and SoC implementations. This IP solution is pivotal in constructing multicore systems by connecting various CPU clusters, I/O devices, and DDR, ensuring efficient data management and communication within high-performance systems. It introduces a network-on-chip (NoC) mechanism that supports multiple CPU clusters, enhancing the overall system performance through streamlined communication paths. The Xinglian-500 is engineered to maintain memory coherence across the SoC environment, making it an invaluable component for developers looking to optimize multicore processing solutions. Due to its scalable architecture, the Xinglian-500 offers flexibility in configuration, readily adapting to the growing demands of computational efficiency. It is designed to support both consumer and enterprise-level applications, enabling lengthy and complex operations with enhanced bandwidth management and reduced latency.
Presto Engineering offers a comprehensive range of foundational and platform-specific semiconductor IPs designed to meet diverse application needs. The Foundation IP includes a wide array of vital circuit blocks, such as high-accuracy sensors, digital controllers, and interface blocks. These fundamental IPs aim to reduce ASIC development risks by leveraging proven components like secure encryption blocks with low power consumption or analog front ends with enhanced specific capabilities. The Platform IPs, on the other hand, provide extensive customization options from functional design to optimized power efficiency. Users can expect specialized analog front ends tailored to demanding specifications such as high-dynamic optical handling, ultra-low-power motion ISP, and MCU integration. Moreover, RFID/NFC/UHF/ISM connectivity solutions are part of this lineup, all of which contribute to efficient energy management and harvesting applications. Presto Engineering's semiconductor IP offerings are geared towards enabling rapid development and ensuring cost-effective project realization, which in turn helps firms achieve faster market entry. By providing validated and efficiently designed IPs, Presto supports clients in overcoming both technical hurdles and market competition, facilitating successful product integration and implementation.
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.
The Advanced Electrolyte Model (AEM) is an advanced simulation tool designed to revolutionize the optimization of electrolyte chemistry. Created by Dr. Kevin Gering at Idaho National Laboratory and distributed by Ridgetop Group, this molecular simulation tool acts as a virtual laboratory, enabling comprehensive exploration of electrolyte properties at a genome level. Using advanced theoretical models like Nonprimitive, Nonrestricted Associated Mean Spherical Approximation and an ion-solvation equation of state, AEM offers precise predictions with an impressive average deviation within only 5-10% from lab data. AEM's robust database of over 50 solvents and 30 salts offers diverse options for users wanting to explore electrolyte properties. Its impact goes beyond providing scientific insights; it accelerates the shift to electric transportation and broader adoption of grid-scale battery systems by enhancing battery research and development. The goal is to achieve a cleaner, sustainable energy future, all at reduced costs and time investments. AEM ultimately serves as a catalyst for change, allowing the international battery research community to drive forward innovative solutions in green energy storage.
The aLFA-C product is an advanced interfacing ASIC designed for space applications, specifically for infrared readout ICs (ROICs) and other image sensors. It integrates much of the typical front-end electronics infrastructure in a single solution, offering versatility through features such as operation on a single unregulated supply using onboard LDOs and regulators, and compatibility with external clocks or crystal oscillators. Communication with external devices is achieved via a SpaceWire interface, and a programmable sequencer with 8 levels of nesting enhances the control towards the ROIC. Capable of handling 32 programmable digital outputs, the aLFA-C also allows the customization of input thresholds and output formats, supporting CMOS, LVDS, and CML. Its analog acquisition system includes 32 signal channels plus 4 reference channels, each with differential or single-ended input capability and 16-bit ADC resolution. The ADCs are equipped with features like calibration and post-correction, supporting various configurations for enhanced speed and performance. Additionally, the aLFA-C provides several programmable voltage sources and current outputs, accompanied by measurement capabilities for resistance, voltage, and current, making it extremely flexible for a wide range of applications. Its design is robust against radiation, exhibiting tolerance against TID, SEU, and SEL, and operates efficiently in temperatures from 35K to 330K, making it ideal for the harsh environments of space.
The C100 represents an advanced integration of wireless microcontroller capabilities for Internet of Things (IoT) applications. Built around a powerful 32-bit RISC-V CPU operating at speeds up to 1.5GHz, this chip delivers high-efficiency processing and data handling. Embedded with RAM and ROM, the C100 is designed to maintain high performance while minimizing power usage. Complementing its processing power, the C100 integrates extensively with wireless functionalities including Wi-Fi, and supports a multitude of transmission interfaces. Additionally, it includes an Analog-to-Digital Converter (ADC), Low Dropout Regulator (LDO), and a temperature sensor, allowing it to cater to diverse application needs swiftly and efficiently. Its design seeks to offer seamless application development that is broad in range yet simple and fast, making it a perfect choice for developers focused on creating robust IoT solutions. The C100's strength lies not just in its integrated components but also in its ability to adapt to secure, high-performance environments, making it useful for smart home systems, healthcare devices, and more.
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 an innovative power amplifier that showcases the company's patented Dual-Drive™ technology. This technology sets the standard for power amplifier efficiency in the market, validated on a CMOS SOI platform and adaptable across other silicon formations like GaAs, GaN, and SiGe. The FCM1401 efficiently operates at 14.5 GHz, offering both high performance and reduced silicon area requirements, ensuring substantial efficiency gains for wireless communication devices. The core of the FCM1401 boasts a dual-drive architecture that permits unmatched power efficiency, with a significant improvement over traditional designs. It delivers a PAE of up to 53% in a two-stage setup and maintains a high drain efficiency, even under demanding conditions, making it an excellent choice for space communications and other high-frequency applications. With reductions in size and improvements in output, this amplifier meets rigorous demands for modern telecommunication standards. Engineered for a supply voltage ranging from 1.6V to 2.0V, the FCM1401 manages to sustain efficiency without compromise. It is designed to increase the range and reduce power consumption, which is crucial in minimizing environmental impact and promotes longer battery life in mobile devices and other portable technology.
The eSi-Analog portfolio is crafted to integrate vital analog functions into custom ASICs and SoCs, optimized for a variety of applications. This low-power and silicon-proven technology adapts to meet specific project requirements, blending seamlessly with leading foundry processes. The analog IPs can include amplifiers, A/D and D/A converters, and other critical components. These IPs are fully flexible, adaptable, and provided with significant configurability, ensuring that custom specifications can be met with precision. This tailored approach supports a range of sectors from automotive to healthcare, enabling critical analog functionalities in compact and power-efficient designs.
InPsytech's ADC IPs are designed to convert analog signals into digital data efficiently, offering various architectures such as SAR (Successive Approximation Register), Pipeline, and SigmaDelta. These ADCs are tailored for high precision and low power operation, suitable for a broad range of applications. By providing accurate analog-to-digital conversion, these IPs enhance the performance of electronic devices that require precise data acquisition from real-world signals. The ADCs are optimized for use in high-performance computing, communications, and control systems, where signal fidelity and conversion speed are paramount. InPsytech's ADCs are ideal for applications that demand high-resolution data and low noise, ensuring that devices operate effectively in diverse environments and various applications.
The Bandgap Reference Block provided by VivEng is a crucial component in many analog and digital circuits, known for its stability and precision. This block generates a stable voltage reference, which is vital for the consistent operation of other circuit elements such as ADCs and DACs. The block is equipped with features like trimmable reference voltage, bias currents, and alerts for over and under temperature conditions. Additionally, it includes a power-on reset feature, ensuring that it operates reliably under various environmental conditions and power supply fluctuations.
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 ADX series of continuous-time Delta-Sigma ADCs from SCALINX represents a pinnacle of precision and flexibility, leveraging the advantages of fast sampling and high bit resolution for diverse signal conversion challenges. This series boasts varying configurations, including 80MS/s with a 16-bit resolution and a 40MHz bandwidth, as well as a 1.25GS/s speed at 10-bit resolution handling a 300MHz bandwidth. Such flexibility allows designers to match ADC specifications closely with system requirements, optimizing performance across different applications. At the core, the ADX series is powered by proprietary SCCORETM Technology, ensuring high-speed data processing capabilities coupled with efficient noise filtering and signal fidelity improvements. This makes them ideal for applications in a wide array of sectors, including telecommunications, instrumentation, and high-speed data acquisition systems. With variations supporting different foundries and process nodes, the ADX series provides designers with an adaptable solution across multiple technology platforms. Additionally, these ADCs bring advantages in terms of system integration due to their silicon-proven status, ensuring reliability and performance consistency. The programmability inherent in the design structure supports diverse operating conditions, making them suitable for tasks that range from simple data acquisition tasks to more complex multi-channel signal processing setups.
The FCM3801-BD represents peak innovations in power amplifier technology developed by Falcomm. Operating at 38 GHz, this power amplifier utilizes the Dual-Drive™ technology to facilitate superior performance metrics, aligning with modern high-frequency communication needs. It is crafted to enhance signal strength while minimizing power consumption, which is quintessential for space communications and wearable devices. This power amplifier capitalizes on proprietary advancements to ensure high power-added efficiency, maintaining structural and operational integrity even at elevated frequency operations. Such advancements integrate well with telecommunication technologies, providing a pathway for enhanced communication efficiency and reduced energy expenses. Suited for compact and space-conscious designs, the FCM3801-BD is designed to support a supply voltage range from 1.6V to 2.0V. It delivers elevated performance with remarkable power savings, aligning with the environmental goals of reduced carbon footprints. This amplifier's design encourages longer-lasting device operation between charges, appealing to telecommunications providers focusing on efficiency and sustainability.
ADC solutions from Analog Circuit Works are crafted to meet individually-tailored application needs, surpassing the capabilities of generic designs. Distinctly optimized for a range of resolutions and sample rates, these ADCs excel in various semiconductor processes. The company's expertise ensures that every ADC is fine-tuned to deliver high performance in its respective application. Notably, three families of ADCs are offered, showcasing a diversity of resolutions and sample rates that align with diverse industry demands. Tailored to fit specific industrial requirements, these ADC solutions from Analog Circuit Works redefine what precision and performance mean in the world of integrated circuits.
The Telecommunication ADC is designed for asynchronous operations within telecommunication applications, providing efficient data conversion capabilities that are crucial in robust communication systems. With an 8-bit resolution, this ADC ensures accurate signal conversion, maintaining the integrity of telecommunication data streams. Fabricated using the TSMC 28HPC process, this component is engineered to support data throughput at speeds reaching 1.2 Gbps, ensuring rapid data processing capabilities ideal for high-bandwidth applications. It embodies a design that emphasizes both performance and precision, critical for maintaining the fidelity of transmitted data. This ADC distinguishes itself with its capability to handle asynchronous data, making it suitable for a varied range of telecommunication contexts. It's designed to cater to the advanced needs of modern digital communication systems, ensuring compatibility with various industry standards and enhancing overall system performance.
SystematIC's expertise in analog converters and amplifiers is evident in its sensor array solutions. Designed for optimal signal integrity and noise performance, these converters and amplifiers are integral in sensor interfacing applications where precision is paramount. Leveraging high-resolution AD conversion and low-noise front-end designs, these solutions facilitate accurate and reliable data collection from various sensors. This IP offers a suite of integrated signal processing capabilities, crucial for developing complex sensor systems requiring seamless analog-to-digital transitions and enhanced signal clarity.
Analog IPs from Key ASIC are designed to handle various analog functionalities within integrated circuits, ensuring precision and efficiency in signal management.
The Laser Triangulation Sensors by RIFTEK are designed for non-contact mobile measurement applications. These sensors are versatile, measuring a wide range of parameters including position, displacement, and deformation. With operating ranges from 2 to 1250 mm, they offer high precision with measuring errors as low as ±1 µm. These sensors provide essential feedback for liquid and solid material level measurements and exhibit robustness in sorting and profiling tasks. The platform supports both Blue and Infrared laser technologies, ensuring adaptability to various operating environments.
This power-efficient ADC operates with an impressive 12-bit resolution, with sampling rates ranging from 0.1MSPS to the full 1MSPS. Using a 2.4V to 3.6V analog supply, and a 1.08V to 1.32V digital supply, it is designed for low power consumption while delivering high precision. Featuring 8 single-ended input channels, this ADC is ideal for battery-powered systems, ensuring prolonged use with minimal current draw. The ADC also offers excellent linearity with DNL/INL characteristics of ±1.0/±2.0 LSB, meeting the demands of a wide array of digital sensor networks.
This integrated solution combines a 24-bit sigma-delta ADC with an analog front-end (AFE), designed for high-precision data conversion with minimal signal distortion. Such a configuration excels in applications that demand high-fidelity audio processing or precise sensor data acquisition. The sigma-delta architecture of the ADC ensures excellent resolution and accuracy, which is vital for capturing subtle changes in the input signal. Meanwhile, the integrated AFE allows for flexible interfacing with a variety of sensor types, reducing the complexity and cost of external circuitry.
The ADC-12-35M-TJ is a high-performance 12-bit pipeline ADC capable of sampling rates up to 35 megasamples per second (MS/s). Developed using TowerJazz 0.18 µm technology, this ADC combines precision with speed, making it a preferred choice for applications requiring rapid data conversion with minimal latency. The ADC-12-35M-TJ's design focuses on maintaining a high effective number of bits (ENOB) of 10.5, which is essential for applications that require exacting precision. It serves well in situations where high-throughput, low-latency data conversion is crucial, such as in communication systems, instrumentation, and high-speed data acquisition setups. This Analog-to-Digital Converter stands out due to its impressive mix of resolution and speed, offering designers an efficient pathway to convert analog signals into digital form with high fidelity. The ADC-12-35M-TJ is particularly beneficial in applications that must maintain signal integrity and quality when shifting from analog to digital domains.
The ADQ35-PDRX digitizer is engineered for pulse data systems, offering a single 5 GSPS channel. It incorporates a 3.5-bit dynamic range extension through built-in dual-gain channel combination, enhancing functionality to match that of a 16-bit digitizer at higher speeds. This product utilizes an onboard FPGA for real-time signal processing, allowing it to combine signals from different paths to achieve remarkable accuracy and precision.
The FCM2801-BD is a dual-drive power amplifier developed to cater to the high demands of modern and future wireless communication technologies. Designed for operation at 28 GHz, it leverages Falcomm's Dual-Drive™ technology to achieve record efficiencies in space-sensitive environments, making it ideal for telecommunications and wearable device applications. This power amplifier surpasses typical market offerings in its class by delivering outstanding power efficiency and maintaining minimal silicon area usage. The FCM2801-BD offers a core efficiency that contributes significantly to reducing power consumption, providing an eco-friendly solution designed to enhance device durability by extending battery life. With advanced capabilities for increasing signal range, it is well-suited to intensive applications where energy conservation and performance are key. The FCM2801-BD is also characterized by its consistent drain efficiency across varying supply voltages, offering operational stability between 1.6 and 2.0 volts without impacting its efficiency negatively. The product provides a robust answer to the challenges of next-generation telecommunication devices, ensuring environmental benefits alongside technological advancements.
Utilizing a 65nm process, this low power ADC features an effective 12-bit resolution with conversion rates up to 1MSPS. It is powered by a range of 2.4V to 3.6V for the analog component and 1.08V to 1.32V for digital purposes. The versatile eight-channel input design allows this ADC to function efficiently in various settings, from data systems to network communications. Noteworthy specs include a ±1.0/±2.0 LSB for DNL/INL, delivering accurate and reliable data conversion essential for sensor applications.
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 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.
Archband Labs' SAR ADC is a standout technology for applications requiring precision in analog-to-digital conversion. Known for its efficiency, the Successive Approximation Register (SAR) design is ideal for projects demanding low power consumption, making it an excellent fit for portable and battery-operated devices. Its design architecture allows it to deliver rapid conversions, which is crucial for real-time applications where speed and accuracy are paramount. This ADC is particularly useful in consumer electronics, automotive systems, and various industrial applications, where consistent performance and reliability are critical. The ADC supports a wide range of inputs, from simple analog signals to more complex waveforms, providing flexibility and versatility to engineers. Its cutting-edge performance plays a vital role in enhancing the overall functionality of devices, underpinning superior quality in signal processing tasks.
ELFIS2 is a versatile image sensor designed to cope with challenging environments, with its high reliance on radiation-hardened features. This sensor is characterized by its true high dynamic range (HDR) capabilities, making it optimal for applications requiring accurate light detection across a broad range of intensities. The ELFIS2 features motion artifact-free (MAF) operation, a critical attribute for high-fidelity imaging. Built with a global shutter and back-side illumination (BSI), the sensor ensures all pixels capture light simultaneously, which is vital for sharp images devoid of motion blur. The BSI technology further enhances its sensitivity by allowing more light to reach the photodiode, a crucial feature for low-light conditions or fast imaging demands. With its SEL/SEU radiation-hardened design, the ELFIS2 is tailored for environments exposed to high radiation levels, like space or certain industrial settings. This resiliency, coupled with its innovative design, makes ELFIS2 suitable for complex imaging tasks, capturing high-quality images without compromising performance.
Tower Semiconductor offers a sophisticated SiGe BiCMOS technology specifically designed for radio frequency (RF) applications. Known for achieving exceptional high-speed and low-noise performance, this technology is pivotal in the development of RF circuits. It supports scalable production for a variety of communications technologies, ensuring high linearity and low power consumption. The platform enables a comprehensive range of frequencies, making it ideal for consumer, infrastructure, and automotive applications demanding rapid data processing capabilities. The SiGe BiCMOS technology integrates both bipolar and CMOS processes, allowing for superior device performance and greater design flexibility. This integration supports applications like wireless communications, providing designers with a versatile toolkit to meet difficult design challenges. The technology is supported by extensive Tower Semiconductor fabrication facilities, ensuring high yield and superior quality manufacturing. Key applications include integration in power management systems, RF amplifiers, and high-speed analog signal processing units. Designed to be robust and efficient, The SiGe BiCMOS platform is well-cross-qualified across multiple geographic locations, ensuring uninterrupted global supply and adaptable manufacturing capabilities. Tower Semiconductor continues to enhance this technology to enable advanced RF design solutions, boosting development opportunities for cutting-edge technology systems in modern automotive and communication infrastructures.
The Xinglian-700 Interconnect Fabric extends the capabilities of its predecessor by offering high scalability and exceptional performance tailored for extensive multicore systems. Supporting up to 256 CPU cores, this fabric IP is pivotal in building high-density computational infrastructures capable of handling intensive data processing tasks across various domains such as AI, analytics, and enterprise computing. Engineered to facilitate rapid connectivity and improved throughput, the Xinglian-700 enhances system efficiency by ensuring consistent data flow between CPU clusters, I/O, and DDR components. This interconnect fabric employs a sophisticated network-on-chip (NoC) approach that prioritizes memory coherence and system reliability, even under heavy load conditions. The fabric's design allows it to support a wide array of technological applications, from large-scale data centers to AI-driven analysis, making it a versatile tool for enterprises aiming to scale their processing capabilities. By optimizing data paths and reducing latency, the Xinglian-700 sets a benchmark for interconnect systems, bolstering the efficiency of complex computational environments.
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.
ParkerVision's Energy Sampling Technology is built on its revolutionary RF receiver solutions, which are pivotal in transforming traditional super-heterodyne approaches to more efficient direct conversion methodologies. This technology is designed to offer exceptional sensitivity, bandwidth, and dynamic range while minimizing the need for RF signal division. As a result, it reduces power consumption and improves demodulation accuracy. The technology's compact design is well-suited for integration into CMOS technologies, enabling further miniaturization and cost reduction of RF components. The use of energy sampling allows for more precise signal processing, which is crucial for maintaining high data rates and robust operation under varying environmental conditions. Technologies utilizing this approach can efficiently operate across a broad spectrum of signal strengths, which is ideal for devices moving between different network zones. Given its adaptability, the Energy Sampling Technology is applicable in various sectors, including mobile handsets, modems, and tablets, supporting multiple standards like GSM, EDGE, CDMA, UMTS, and LTE. By pioneering a matched-filter correlator for frequency down-conversion, ParkerVision's technology provides unparalleled performance in selectivity and interference rejection. The removal of redundancy in signal processing pathways facilitates a reduction in silicon area used, further optimizing costs and efficiency in the design of modern wireless devices, making it indispensable for next-generation communication products.
The Magnetic Hall Sensor from SystematIC Design is crafted through extensive experience in Hall sensor technology. It is developed for isolated current sensing applications at DC and low frequencies, leveraging Hall sensing that integrates sensor elements and readout electronics into standard CMOS. The sensor boasts high accuracy and bandwidth, featuring a compact die design that includes magnetic field sensors with programmable readout amplifiers. This fully integrated current sensor maintains low offset and excellent isolation properties, ensuring minimal magnetic hysteresis and high performance across various applications.
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.
This versatile ADC is built on Samsung's 100nm LF6 CMOS technology, providing a wide operating range suitable for various applications. With an input range from the analog ground to the supply voltage, this ADC is ideal for dynamic environments. It supports a conversion rate of 1 MHz at supply voltages between 3.6V and 5.5V, scaling down to 400 kHz at lower supply levels. This ADC also features 16-channel single-ended inputs and delivers exceptional signal integrity with an SFDR of 83.6dB.
This Sigma-Delta ADC offers precise 16-bit resolution and is implemented in SMIC's 55nm 2P7M CMOS technology. It supports a programmable gain range from 0 to 50dB and selectable microphone biases, making it adaptable for a range of audio processing applications. This ADC offers distinct analog and digital interfaces, with a PDM/I2S/TDM serial output, and consumes minimal current, enhancing its suitability for portable audio applications. With a notable 90dB SNR, it is capable of delivering high-fidelity audio outputs, crucial for advanced sound systems.
The Analog/Mixed-Signal IC from Akronic is designed to meet the evolving demands of modern telecommunication and radar systems. This product excels in integrating various signal conversion and frequency synthesis functions, which are crucial for high-capacity data transmission and precise signal modulation. The IC employs sophisticated low-pass filters like Chebyshev and Butterworth to ensure optimal signal integrity and minimal distortion across a wide range of frequencies. Akronic's Analog/Mixed-Signal IC is notable for its versatile performance in base-band functions such as voltage references and gain-control operations. This versatility is underpinned by advanced components like power detectors and RSSI AGC loops, which contribute to maintaining consistent signal quality. The IC is also adept at handling high-speed ADCs and DACs, with a focus on achieving high cut-off frequencies exceeding 1GHz. One of the defining features of this IC is its frequency synthesis capability, supported by both fractional and integer-N PLLs and various reference divide and multiplier configurations. The IC's design incorporates multi-modulus prescalers, MASH, PFDs, and sophisticated loop filters, alongside highly stable VCOs and advanced ALC mechanisms. With these features, Akronic offers a robust solution for applications requiring precise frequency control and modulation.