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 KL730 is a sophisticated AI System on Chip (SoC) that embodies Kneron's third-generation reconfigurable NPU architecture. This SoC delivers a substantial 8 TOPS of computing power, designed to efficiently handle CNN network architectures and transformer applications. Its innovative NPU architecture significantly optimizes DDR bandwidth, providing powerful video processing capabilities, including supporting 4K resolution at 60 FPS. Furthermore, the KL730 demonstrates formidable performance in noise reduction and low-light imaging, positioning it as a versatile solution for intelligent security, video conferencing, and autonomous applications.
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.
Altek's 3D Imaging Chip offers cutting-edge depth sensing technology, suitable for applications requiring medium to long-range recognition. This technology enhances precision in surveillance systems and transport robots. With years of experience in 3D sensing technology, the chip provides comprehensive and integrated from module to chip solutions, ensuring high accuracy. Its advanced capabilities allow for robust identification performance across diverse environments, reinforcing Altek's reputation in the imaging sector.
Laser Triangulation Sensors are cutting-edge devices designed for non-contact measurement of position and displacement across a range of applications. Operating with high precision, these sensors are ideal for tasks requiring repeatability and accuracy, especially where physical contact with the measurement target is not feasible. The use of advanced optics and enhanced laser technology allows for meticulous detection and analysis, making these sensors suitable for various industrial environments. The sensor series features models such as the RF603, RF602, and RF603HS, which boast sampling frequencies up to 160 kHz. They support a wide range of configurations—options include models utilizing blue or infrared (IR) lasers to meet specific application requirements. With measurement ranges extending from mere millimeters to several meters, these sensors are versatile across diverse sectors, from manufacturing to research facilities. Furthermore, the Laser Triangulation Sensors offer significant error minimization capabilities, allowing for high accuracy in measuring tasks. The series presents solutions for complex measurement challenges, along with the ability to tailor the sensors through various calibration and setup adjustments to fit specific operational needs. The system's adaptability makes it an invaluable tool for precision measurement applications where a holistic understanding of spatial dynamics is required, whether in quality control, automation, or R&D environments.
The C100 is a highly integrated SoC designed for IoT applications, boasting efficient control and connectivity features. It is powered by an enhanced 32-bit RISC-V CPU running at up to 1.5GHz, making it capable of tackling demanding processing tasks while maintaining low power consumption. The inclusion of embedded RAM and ROM further enriches its computational prowess and operational efficiency. Equipped with integrated Wi-Fi, the C100 facilitates seamless wireless communication, making it ideal for varied IoT applications. It supports multiple types of transmission interfaces and features key components such as an ADC and LDO, enhancing its versatility. The C100 also offers built-in temperature sensors, providing higher integration levels for simplified product designs across security systems, smart homes, toys, healthcare, and more. Aiming to offer a compact form factor without compromising on performance, the C100 is engineered to help developers rapidly prototype and bring to market devices that are safe, stable, and efficient. Whether for audio, video, or edge computing tasks, this single-chip solution embodies the essence of Chipchain's commitment to pioneering in the IoT domain.
The MVPM100 Series offers cutting-edge particulate matter sensors that excel in compactness and accuracy, designed specifically for detecting PM2.5 particles. Leveraging advanced microsystem technology, these sensors measure the mass of particles directly, a method that provides superior precision compared to conventional optical sensors. Their versatile interface options and minimal power requirements make these sensors an ideal choice for a wide array of applications, with particular utility in environments that demand reliable air quality monitoring. These sensors cater to industrial, consumer, medical, and automotive sectors, ensuring broad applicability. The MVPM100’s compact form factor and robust design mean they are suitable for integration within various systems, offering consumer and industry professionals a trusted technology for high-quality particulate detection.
The Dual-Drive™ Power Amplifier FCM1401 is engineered to deliver superior efficiency and performance, specifically designed for demanding RF and mmWave applications. This amplifier distinguishes itself with its ability to produce more RF power while minimizing heat production, making it ideal for applications that require high thermal management. Key to its performance is the patented Dual-Drive™ architecture, which enhances output power and bandwidth significantly. This results in reduced need for large cooling systems and oversized batteries, making it a lighter and more energy-efficient solution. The design is process-agnostic, silicon-proven, and features a small silicon footprint, ensuring high adaptability in various applications. The FCM1401 is built to offer a seamless integration with plug-and-play functionality, allowing for straightforward implementation in existing systems. This makes it a versatile choice for sectors like satellite communications, telecom, and defense, where robust and efficient RF power solutions are critical. The advanced design flow aligns precisely with real-world measurements to within a 2% margin, ensuring reliability and performance consistency.
The D2D Technology by ParkerVision represents a pivotal advancement in the field of RF signal processing, enabling direct conversion of analog RF signals into digital data with remarkable efficiency. This innovative technology serves as a critical component in many of today's wireless devices, facilitating faster communication while reducing power consumption. D2D stands out because it consolidates multiple steps typically required in RF signal processing into a seamless direct-to-data conversion. This process not only increases efficiency but also significantly reduces the size of the accompanying hardware, paving the way for more compact and less power-intensive devices. The technology's ability to maintain high sensitivity and dynamic range is a testament to ParkerVision's commitment to quality and performance. By employing D2D Technology, device manufacturers can produce cutting-edge equipment capable of operating not just in localized networks but universally, reducing limitations associated with network incompatibility. This technology is not just a boon for consumer electronics but also has significant implications for telecommunications infrastructure, making it a cornerstone in managing and advancing global communication networks.
A high-performance Pipelined SAR ADC, this device features 16 channels, with each channel capable of 12-bit resolution and a speedy sampling rate of 1.5Msps. It is ideally suited for applications demanding efficient and swift data processing, such as advanced communication systems and high-speed data acquisition devices. Constructed in a reliable foundry environment, its silicon-proven design ensures stability and efficiency, making it a dependable choice for high-demand applications.
Our range of sensing integrated circuits caters to both photonic and capacitive detection needs. These ICs are designed to simplify the complexity of system design and minimize risks associated with their implementation. Whether dealing with basic photo-diode array detection or sophisticated low-noise photon detection solutions, our analog front ends are engineered to support a wide range of applications. Charge sensors in this series are equipped with multi-channel A-to-D conversion, setting a high bar in noise performance, ADC linearity, and resolution. These innovations are particularly beneficial in medical imaging, like digital X-ray panels, and other scanning technologies such as CT and PET scanners. Fingerprint detection and particle detection also benefit from the robust capabilities of these sensing ICs. Additionally, our capacitive sensing ICs cater to touch screen interfaces, providing high sensitivity along with excellent signal interference rejection. These features are vital for robust performance across varying screen formats and are critical in applications such as interactive digital displays and rugged touch-based systems.
The MVH4000 Series are highly precise sensors for measuring relative humidity and temperature. These sensors are engineered using advanced Silicon Carbide MEMS technology, providing excellent long-term stability and reliability. With a swift response time and minimal power consumption, they are perfect for applications requiring fast and accurate environmental monitoring. These compact sensors, ideal for critical PCB real estate, include on-chip calibration, enabling straightforward integration into existing systems. Each sensor in the series offers different accuracy grades and outputs, allowing users to select the model that best fits their needs. The sensors' digital (I2C) or analog outputs ensure compatibility with a wide range of systems. Notably, their long-term stability and accuracy contribute to lowering the total cost of ownership, making them a cost-effective choice for industrial, consumer, medical, and automotive applications. The MVH4000 Series also come in a compact form factor of 2.5 x 2.5 x 0.9 mm, making them easy to fit into space-constrained devices. Additionally, the sensors’ robust design supports a broad operating temperature range from -40 to 125°C, making them suitable for diverse environments and demanding applications.
The FaintStar Sensor-on-a-Chip exemplifies cutting-edge sensor technology. Developed to support the European Space Agency's HERA mission, this sensor demonstrates outstanding performance during planetary missions, like the Mars flyby, by capturing faint light signals under challenging conditions. Its design emphasizes high sensitivity and low noise, ensuring clear image capture even in low-light environments. Built with advanced ADCs directly on the wafer, the FaintStar system enhances readout efficiency and reliability.\n\nThis sensor is designed for applications requiring exceptional detection capabilities in the realm of space exploration. Its ability to operate efficiently in high-radiation environments further extends its usage to scientific research and space missions. By maintaining a balance between speed and operational efficiency, it supports a wide range of imaging applications, contributing to space discovery and the advancement of astrophysics.\n\nThe FaintStar Sensor-on-a-Chip also features a robust architecture tailored for high-yield volume production, which caters to the needs of imaging systems demanding outstanding throughput and precision. The sensor's architectural innovation allows it to excel in its role within space missions, where reducing size and optimizing power consumption are paramount. Additionally, its seamless integration into high-precision imaging systems makes it indispensable for scientific and exploratory endeavors.
This 8-bit Delta-Sigma ADC offers a 2Ksps sampling rate, engineered for applications that require modest resolution with minimal power consumption. Its design makes it suitable for battery-operated devices and applications where power conservation is critical. Featuring a high degree of accuracy, its silicon-proven design was realized using the robust 180nm SMIC process node.
EnSilica’s eSi-Analog suite offers a broad array of Analog IP solutions essential for integrating analog functions into custom ASIC and SoC devices. Proven across various process nodes, these solutions are renowned for their performance, power efficiency, and adaptability to customer specifications, thereby expediting time-to-market and lowering costs. With an extensive range of easy-to-integrate IPs, eSi-Analog encompasses high-performance blocks like oscillators, SMPSs, PLLs, LDOs, and more, each optimized for low power consumption and high resolution. The flexibility of this IP suite allows for adaptation to various application needs, supporting industries as diverse as automotive and healthcare with critical analog capabilities. Specialized in enabling SoC platforms with robust analog interfaces, this IP package features components like temperature sensors and ultra-low power radios. The solutions in eSi-Analog are designed to integrate seamlessly across major foundry technologies, offering a competitive edge for customers seeking to enhance system performance with reliable analog solutions.
The MVDP2000 Series showcases a line of highly sensitive differential pressure sensors designed for precision and robustness in demanding environments. These sensors apply a proprietary capacitive sensing technology that ensures digital calibration across temperature and pressure variables, thus enhancing accuracy and reliability. With a compact size and power efficiency, the MVDP2000 sensors are ideal for applications requiring fast response and low power usage, such as portable and OEM devices. Their range of use includes respiratory equipment, gas flow instruments, and pressure monitoring systems in various industries. These sensors provide quick analog and digital outputs with resolutions between 15 to 21 bit, maintaining an error band of less than 1% FS. Their broad operating range and low power draw further bolster the sensors’ applicability, catering especially to consumer and medical industries.
This advanced Delta-Sigma ADC is designed with 14-bit resolution and a rapid sampling rate of 20Msps, meeting the demands of applications requiring swift data acquisition alongside superior precision. Ideal for high-end communication systems and real-time processing devices, it demonstrates TechwidU's commitment to high-quality semiconductor solutions. The ADC undergoes a rigorous production process within the TSMC 65nm node, ensuring exceptional performance and reliability.
The 16-bit Sigma-Delta ADC from Leo LSI is built on the advanced 55nm 2P7M SMIC CMOS technology, making it suitable for precision audio applications. It features a programmable gain of up to 50 dB, allowing fine-tuning for varied input densities. Supporting a conversion rate of 16KSPS, this ADC is optimized for mono audio inputs with fully differential configurations and boasts a power-efficient design ideal for mobile devices.
The ADC solution provided by this company is designed to convert analog signals into digital ones with unparalleled precision and efficiency. Built to support low power and high accuracy requirements, these converters are ideal for applications where the conversion speed and precision are critical. The ADC offerings not only cater to the standard precision needs but are tailored for environments requiring minimal power usage, making them perfect for portable and battery-operated devices. They handle input signals with a high degree of accuracy, translating into reliable performance in various industrial applications. Moreover, these ADCs are crafted to integrate seamlessly with existing systems, offering a streamlined and efficient conversion process. This makes them suitable for integration in complex solutions where performance cannot be compromised, maintaining signal integrity throughout.
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.
The MVWS4000 Series integrates three crucial environmental sensors—humidity, pressure, and temperature—into one compact device. This all-in-one sensor solution leverages advanced Silicon Carbide technology to offer enhanced reliability and optimal performance. Designed with fast response times, these sensors are tailored for applications that demand precision and efficiency, such as battery-powered and OEM applications. They provide various accuracy grades to cater to diverse budget requirements, ensuring they are both versatile and cost-effective. Robust in construction and small in form, the MVWS4000 maintains long-term stability, boasting excellent precision with minimal power consumption. Their digital I2C and SPI output interfaces simplify incorporation into modern systems, making them an excellent choice for industrial, consumer, medical, and automotive markets.
This general-purpose Successive Approximation Register (SAR) ADC features an 8-channel, 12-bit configuration with a sampling rate of 1Msps. It is designed for versatile applications requiring precise analog-to-digital conversion. Its robustness and reliability make it suitable for various embedded and real-time systems, where quick and accurate data processing is crucial. Silicon proven, this ADC offers a balance between performance and power efficiency, with its operation supported by a renowned foundry process.
Built using 65nm technology, this ADC delivers high accuracy with a 12-bit resolution offering conversion rates from 0.1MSPS to 1MSPS. It operates efficiently with an analog supply voltage between 2.4V and 3.6V and a digital supply voltage ranging from 1.08V to 1.32V. Designed for low power applications, it is particularly suitable for wireless sensor networks and pressure sensors, ensuring reliability across diverse operational conditions.
The AFX010x Product Family is a series of advanced Analog Front Ends (AFEs) optimized for applications demanding low power consumption and high signal integrity. These AFEs feature an impressive sampling rate that can reach up to 5 GSPS, coupled with a wide bandwidth of up to 300 MHz. This makes them ideal for a range of data acquisition systems from benchtop to portable devices. Each AFX010x product consists of four independent and highly integrated channels, incorporating programmable input capacitance, a single-ended to differential-output Programmable Gain Amplifier (PGA), an offset DAC, an ADC, and a digital processor. The high level of integration is facilitated by proprietary SCCORETM technology, contributing to significant power efficiency with a reduction of up to 50% in power usage. Additionally, the AFX010x series is known for its flexibility and user adaptability, with features such as on-chip clock synthesizer and programmable gain ranges. Delivered in a compact 196-ball BGA package, these products are well-suited for high-resolution data acquisition, USB-based oscilloscopes, and other precision measurement tools.
Archband Labs' SAR ADC is optimized for precision and speed, engineered for applications in high-performance computing and complex instrumentation. Known for its low latency and high resolution, this ADC is perfect for systems needing reliable and meticulous data conversion. Designed with innovative successive approximation techniques, Archband's SAR ADC excels in environments that require fast data acquisition and processing. Its low power consumption trait ensures it can be integrated into power-sensitive devices without sacrificing performance. This ADC is highly versatile, featuring adaptable resolution settings and noise reduction capabilities, tailored to suit a wide range of application needs, from consumer electronics to industrial measurement systems. Its compact design also makes it suitable for systems constrained by space without compromising the quality and speed of data handling.
CoreVCO offers a highly customizable voltage-controlled oscillator crucial for generating precise frequencies in communication systems. With its robust design, CoreVCO ensures minimal phase noise and offers exceptional tuning capabilities, making it an indispensable component in RF and mixed-signal applications. It is tailored to support a broad frequency range, aligning with the diverse requirements of modern technological applications. The product is designed to operate efficiently across various environments, providing reliable performance in both consumer electronics and industrial settings. Its adaptability enables easy integration into complex systems, where precise frequency modulation is required. CoreVCO’s optimized power efficiency and compact form factor make it ideal for portable and space-constrained devices, demanding a balance between performance and size. By ensuring stable operation across various temperatures and conditions, CoreVCO supports mission-critical applications where consistent performance is non-negotiable. Its wideband characteristics and high linearity distinguish it as a leading choice for engineers looking to enhance signal processing capabilities in their designs.
Pipeline ADCs by ASIC North are crafted to manage rapid and precise digital conversions necessary within high-performance applications. These converters are designed to cater to industries requiring swift processing speed without compromising on accuracy, thus enhancing overall system performance. Renowned for their high sampling rates, Pipeline ADCs provide reliability and consistency across various signal processing applications. The layered approach in their architecture ensures that data conversion is conducted at optimal speed, making them the preferred choice for real-time applications needing speed and precision. These ADCs present versatility in usage, supporting applications ranging from telecommunications to advanced digital instrumentation. ASIC North’s Pipeline ADCs are equipped to handle complex data streams seamlessly, underscoring the company’s commitment to engineering quality and innovative designs.
Enosemi's analog and mixed-signal devices are designed to handle both low and high-speed electrical signals, making them integral to the implementation and operation of advanced photonic circuits. These devices play a crucial role in ensuring signal integrity and seamless integration between various components within a circuit, facilitating high-fidelity data processing and transmission. The product range includes various amplifiers, filters, and converters, each meticulously crafted to enhance performance while minimizing power consumption and signal distortion. By leveraging these devices, engineers can achieve precise control over electrical signals, enabling the efficient operation of complex photonic systems. These devices are particularly well-suited for high-performance applications where accuracy and speed are paramount. By providing reliable and versatile solutions, Enosemi ensures that its products meet the highest standards required for next-generation photonic applications, aiding clients in achieving superior performance and reliability in their designs.
The ELFIS2 Image Sensor stands at the forefront of modern imaging technology, designed to deliver superior performance across a variety of demanding applications. This sensor excels in environments where precision and low noise are paramount, making it an invaluable asset in fields such as space exploration and scientific imaging. Its advanced architecture ensures that the ELFIS2 can accurately capture detailed images even under challenging conditions, demonstrating outstanding sensitivity and resilience.\n\nIncorporating state-of-the-art technology, the ELFIS2 Image Sensor offers remarkable noise reduction and enhanced image clarity, which are essential for capturing critical data in low-light scenarios. Its robust design supports high-speed imaging processes, providing users with the ability to conduct thorough analysis and deliver critical insights in real-time. This sensor is particularly suitable for applications within scientific research, offering a reliable solution for projects that require precision and accuracy in data acquisition.\n\nThe ELFIS2's architecture is built to support a wide range of imaging needs, facilitating use in both terrestrial and space-based applications. Whether utilized in laboratory environments or onboard spacecraft, this sensor provides consistent, high-quality imaging, establishing it as a go-to solution for researchers and engineers alike. Its versatility and reliability make it an essential component in the toolkit of those engaged in cutting-edge scientific and technological exploration.
ParkerVision's Energy Sampling Technology is a state-of-the-art solution in the realm of RF receiver designs. This technology emphasizes the efficient conversion of RF signals with enhanced sensitivity and dynamic range. By applying matched filter concepts, it enables high-quality RF performance, suitable for wireless communication devices that demand precision and efficiency. These enhancements allow devices to consume less power, extend battery life, and minimize heat generation, making them ideal for modern mobile technologies. The technology is constructed on a foundation of advanced patents that cover energy sampling techniques and high-efficiency power transmission. ParkerVision's approach in RF waveform transfer addresses a wide range of wireless connectivity needs, ensuring reliable and robust performance. The energy sampler's ability to convert direct-to-data seamlessly allows for the integration into varying communication devices, thus broadening its applicability. Utilized globally in a multitude of devices, ParkerVision's Energy Sampling Technology is integral in helping manufacturers design more compact and efficient devices. As the need for enhanced communication technologies grows, this technology stands to support future advancements, catering to the burgeoning demands of 5G and beyond, while maintaining low energy consumption and extended device longevity.
The 5th Generation Power Metering solution by Dolphin Semiconductor is a cutting-edge IP offering, designed for single or three-phase detection with a strong focus on energy efficiency and accuracy in power metering applications. This advanced platform leverages a 24-bit ADC for high-precision energy measurements, ensuring low noise at low frequencies, minimal offset, and high total harmonic distortion (THD) performance. Developed to simplify and accelerate design processes while supporting scalability across multiple power metering solutions, this IP optimizes cost and complexity. It includes integrated power computation algorithms that streamline operations, supported with optional power and energy computation engines requiring minimal computational resources from a supporting MCU SoC. The IP offers significant benefits such as error measurement well below 0.1% over a 1/7000 range, making it ideal for smart energy applications. Additionally, it features synchronized channels with phase shifting calibration, eliminating the need for input DC blocking capacitors. Compatible with process nodes from 180nm down to 40nm, this power metering solution offers a flexible, cost-effective IP robust for contemporary semiconductor applications.
Kamaten's Telecommunication ADC is an 8-bit asynchronous analog-to-digital converter designed to meet the demands of modern telecommunication systems. It enables the conversion of analog signals into digital form at a high data throughput, supporting up to 1.2 Gbps. This ADC is particularly optimized for telecommunication applications that require rapid data acquisition and processing. The ADC utilizes TSMC’s 28HPC technology, offering a high level of integration with modern digital and mixed-signal systems. Its asynchronous nature allows the converter to operate efficiently without relying on a clock signal, making it a flexible solution for variable-rate data acquisition scenarios where adaptability to different signal conditions is critical. With its architecture designed to minimize latency and enhance signal integrity, the Telecommunication ADC is suitable for a wide range of applications beyond telecom, including data acquisition systems in industrial and consumer electronics. Offering a compact solution with high reliability, this ADC is an essential tool for engineers requiring precise analog-to-digital conversion capabilities.
This 12-bit 1MSPS ADC leverages Samsung's 100nm LF6 CMOS technology, providing a wide operating range for diverse electronic applications. With conversion rates up to 1MHz at standard voltage levels (3.6V to 5.5V), it's designed for high performance in environments demanding consistent accuracy. The converter features a broad input range from analog ground to AVDD, accommodating varied design needs seamlessly.
Engineered for precise data conversion, this Delta-Sigma ADC offers 16-bit resolution with a sampling frequency of 28Ksps. It is tailored for applications emphasizing high precision and minimal noise, often found in professional audio equipment and high-fidelity data logging systems. Developed in a state-of-the-art foundry, this ADC ensures robust performance through its sophisticated and silicon-proven architecture, ideal for integrators demanding rigorous quality measures.
SiGe BiCMOS Technology for RF from Tower Semiconductor is engineered for the RF communication domain, providing a high-performance solution suitable for various applications. By leveraging silicon-germanium technology, this technology offers enhanced speed and efficiency that is vital for wireless and broadband communication systems. Its precision and low noise capabilities make it an ideal choice for high-frequency, high-speed data transmission requirements. The technology facilitates seamless signal processing, which is crucial for maintaining the quality and integrity of communications. This makes it distinctly important in applications requiring reliable performance under challenging conditions. This technology also emphasizes its adaptability to a broad range of operating environments, ensuring consistent performance across diverse applications. With proven reliability, it bridges traditional RF limitations with the innovative prowess of BiCMOS technology, offering robust solutions for modern communication challenges.
Designed at 55nm, this 8-channel 12-bit ADC offers a range of 0.1MSPS to 1MSPS, optimized for applications requiring low power consumption and minimal size. With an analog power supply range of 2.4V to 3.6V and a digital power supply range from 1.08V to 1.32V, it efficiently manages power resources while maintaining superior resolution and accuracy. Ideal for battery-powered systems and data acquisition solutions.
The SAR ADC developed by ASIC North stands out for its precision and power efficiency. Short for Successive Approximation Register Analog-to-Digital Converter, this ADC is designed for applications that blend the need for high resolution with fast data conversion. Particularly beneficial for environments demanding multiple channel operations, the SAR ADC delivers consistent performance with precision-centric architecture. With design innovations focused on minimizing power consumption while maximizing data throughput, it supports a multitude of use cases where accuracy cannot be compromised. The flexible integration capabilities of this SAR ADC make it an asset for diverse applications, from industrial instruments to consumer electronics. By enhancing analog signal processing to digital outputs effectively, it ensures seamless data flow and enhanced operational efficiency, underscoring ASIC North's commitment to exceptional quality and design expertise in digital conversion processes.
The Heimdall platform is engineered for applications requiring low-resolution image processing and quick interpretation. It integrates image signal processing capabilities into a compact design, perfect for IoT applications where space and power consumption are constraints. The platform supports various image-related tasks including object detection and movement tracking. With a core image sensor of 64x64 pixels, Heimdall is optimized for environments where minor details are less critical. This makes it ideal for motion sensing, smart lighting, and automation systems where the understanding of space occupancy or movement is essential. The platform's energy-efficient design, capable of integrating energy-harvesting technology, ensures sustainable operation in remote and hard-to-reach locations. By providing rapid image interpretation, Heimdall supports quick decision-making processes crucial for smart infrastructure and security applications.
The ADC-12-35M-TJ is a high-performance Pipeline Analog-to-Digital Converter (ADC) notable for its 12-bit resolution and 35MS/s sampling rate. It is positioned as a key component in systems requiring efficient conversion from analog to digital signals with precision and speed, such as in communication and signal processing applications. By employing a pipeline architecture, this ADC ensures that input signals are rapidly processed into accurate digital formats, vital for maintaining high fidelity in signal reproduction. This capability is particularly critical in applications where data throughput and integrity are paramount, allowing for seamless data transmission and interpretation. Further enhancing its appeal, the ADC-12-35M-TJ integrates well within complex systems and is well-suited for demanding operational environments. This product exemplifies reliability and performance, attributes that make it a preferred choice for developers seeking dependable ADC solutions to drive their digital applications forward.
The Blazar Bandwidth Accelerator Engine serves as a pivotal component for boosting FPGA applications. This engine is specifically engineered to enhance in-memory compute capabilities, thus enabling high-bandwidth activities with reduced latency. Each Blazar device integrates in-memory computation, facilitating operations at unprecedented speeds required for modern high-demand applications.\n\nWith features such as 640 Gbps bandwidth and support for dual-port memory, the Blazar Engine is apt for applications that require mass data processing at a rapid pace. Moreover, the optional inclusion of 32 RISC cores amplifies its computational capacity, making it exceptionally versatile for tasks such as SmartNIC and SmartSwitch metering. These engines are indispensable for environments where efficient data aggregation and processing are crucial, such as in network infrastructure and communication systems.\n\nThe Blazar Engine's architecture not only supports vast read/write operations but also enhances system efficiency by minimizing the external commands required for memory operations. This reduces the overall load on FPGA resources, thereby streamlining processes and accelerating time-to-market for new technologies. Its design speaks to the needs of cutting-edge 5G and Next-Gen communication systems that strive for high throughput at lower capital investment.
Rafael Micro's 24-bit Sigma-Delta Analog-to-Digital Converter (ADC) with Analog Front-End (AFE) is designed for high-precision signal conversion tasks. This mixed-signal IP integrates a 24-bit ADC, making it ideal for applications that require high dynamic range and low noise. Incorporating a sophisticated AFE, it offers a seamless interface for sensing and measurement systems. With its advanced design, this ADC is suitable for a variety of sectors, particularly in precision instrumentation and audio processing equipment. The AFE adds versatility, allowing for easier integration into complex systems that handle analog signal conditioning pre-conversion. Its high-resolution capabilities make it a preferred choice for engineers aiming for detailed data acquisition and performance optimization. The IP is notable for its efficiency in converting analog inputs into high-resolution digital outputs, leveraging Sigma-Delta technology to enhance precision. This makes it especially beneficial in applications requiring stringent accuracy and fidelity, such as medical devices, industrial controls, and consumer electronics.
The 5V 16-channel 12-bit 1MSPS ADC by Leo LSI is designed using Magnachip's 0.18um 1P4M CMOS technology. It offers a 12-bit resolution and works with a 1MHz conversion rate, crucial for applications requiring precise and quick signal conversion. Operating within an analog voltage range of 4.5V to 5.5V and a digital voltage range from 1.62V to 1.98V, the device is versatile enough to fit into a variety of electronic systems.
The mixed-signal front-end IP from GUC is crafted to handle analog signal processing tasks efficiently. Tailored for applications in AI, HPC, and major networking functions, this IP ensures seamless integration with digital components. By utilizing GUC's proprietary design techniques, it offers enhanced precision and reduced noise, making it a vital component of modern integrated circuit systems.
The Column A/D Converter for Image Sensors is an essential element within the digital imaging pipeline, facilitating the conversion of analog signals from image sensors into digital data that can be processed effectively. This converter is particularly tailored for use within CMOS image sensor architectures, offering precise and rapid conversion capabilities crucial for high-quality image capture. It supports multiple A/D conversion methods, including Single Slope and Warp Walk algorithms, which are optimized for both fast conversion rates and high-resolution outputs. This ensures that the converter can handle varying levels of image complexity with ease, providing high fidelity in low-light conditions and maintaining excellent dynamic range. Ideal for use in digital cameras, smartphones, and industrial imaging systems, this A/D converter efficiently manages noise levels and enhances signal clarity. Its design focuses on conserving energy without sacrificing conversion accuracy, making it a desirable choice for applications where power efficiency and compact design are paramount. The converter's sophisticated techniques ensure consistent image quality, reinforcing its role as a cornerstone component in cutting-edge digital imaging solutions.
EMI Flex Filters are advanced electromagnetic interference solutions tailored for critical applications. These filters are engineered to combat EMI challenges, ensuring high-performance signal clarity and reducing error rates in complex environments. Built with a flexible, ultra-thin form factor, they adapt seamlessly to various surfaces and tight enclosures, providing exceptional EMI attenuation while minimizing signal loss. These filters excel in supporting high-speed data communication, compatible with frequencies up to 50 GHz, making them ideal for 5G and radar applications. The EMI Flex Filters are designed to meet stringent military and aerospace standards, ensuring long-term reliability even in harsh conditions. They are customizable, allowing for tailored solutions specific to the requirements of diverse devices, including IoT and medical technology. These filters are trusted by top defense and tech industries, recognized for their proven track record in enhancing signal integrity and operational security. Applications span multiple sectors, including military, aerospace, telecommunications, and automotive, where secure communication and operational security are paramount. Their use in IoT devices prevents EMI disruptions in densely packed settings, while their role in automotive systems supports high-frequency power operations.
Omni Design's Analog to Digital Converter IP utilizes Swift™ technology to offer a range of high-performance, low-power ADCs. These converters feature resolutions ranging from 6 to 14 bits and sample rates extending up to over 100 Gsps, making them ideal for advanced communications and imaging technologies. The ADCs effectively bridge the gap between digital processing and sensor elements, crucial for RF systems, AI-driven data centers, and complex computing environments. Leveraging small footprints and exemplary efficiency metrics, these converters operate effortlessly within intricate data economies, proving indispensable in ensuring signal integrity and minimizing distortion across high-speed networks. By incorporating built-in calibration and digital down converters, Omni Design guarantees optimal system interface, performance flexibility, and reliability. Depending on deployment conditions, ADC solutions are available as individual components or complete data acquisition modules, ensuring their utility in scalable systems.
An analog front-end component designed for applications in energy metering. This 24-bit sigma-delta ADC offers a sampling rate of 128K samples per second, suitable for high-precision measurement tasks. Developed using SMIC's 180nm technology, it enhances measurement accuracy, making it ideal for systems requiring precise energy monitoring and control. Its design focuses on delivering consistent performance even in dynamic or variable conditions, crucial for accurate energy billing and management systems.
This ADC component specializes in serving low power sensor applications with its 24-bit architecture and 19.2K samples per second sampling capability. Developed with SMIC's 180nm technology, it is particularly useful in environments where power efficiency accompanies precision. The ADC is tailored to support extensive sensor networks by delivering reliable data conversion while minimizing energy consumption, ideal for battery-operated or portable devices that require longevity and exactness in data acquisition.
EMI Filter Modules are integral components engineered to provide high-performance electromagnetic interference (EMI) suppression across various devices and applications. These advanced modules streamline EMI management by embedding sophisticated filtering technology directly within a compact plug-and-play design. This integration not only simplifies system assembly and reduces complexity but also guarantees exceptional signal clarity and continuity. Offering superior attenuation of high-frequency interference, EMI Filter Modules are built for rugged durability, ensuring they withstand extreme environmental conditions like temperature shifts, vibration, and mechanical stress. They offer frequency range flexibility, operating effectively across a broad spectrum up to 50 GHz, to accommodate next-generation wireless networks and communications. These modules are customizable, tailored to meet specific system requirements, underscoring Mobix Labs' commitment to delivering robust, customized solutions. The modules are well-suited for critical applications across military and defense, aerospace, telecommunications, and medical sectors, where secure, interference-free signal and radar communication are essential.
The SAR ADC with integrated temperature sensor is engineered to provide high precision in voltage and temperature monitoring applications. Featuring a 12-bit Successive Approximation Register architecture, the ADC provides fast, reliable measurements with a sampling rate of up to 20 kSPS. This mixed-signal ADC is ideal for applications requiring low frequency and DC measurements, such as environmental monitoring and industrial controls. Operational from -40°C to +125°C, the ADC includes a sophisticated temperature sensor capable of delivering accurate temperature readings within 0.1°C resolution. Moreover, the design includes a bandgap reference voltage, which facilitates easy integration by reducing the need for external components and enabling more compact system layouts. Built on an 180nm high-voltage process, the ADC leverages ShortLink's expertise in high-performance mixed-signal designs, thus ensuring reliability and accuracy. With process nodes adaptable to 40nm or other desired technologies upon request, its versatile design can suit a broad range of applications across various industries. Its user-friendly calibration and integration features make this ADC an attractive choice for both established and emerging sectors requiring precise environmental monitoring systems.
Omni Design's Swift™ Low Power Data Converter IP family offers a comprehensive suite of high-speed, ultra-low power analog to digital converters (ADCs). Leveraging advanced FinFET process nodes and an extensive reach across advanced applications, these converters excel in high-frequency domains such as 5G wireless communications, automotive ethernet, and advanced imaging systems. The Swift™ ADC line allows seamless integration of multi-channel ADC solutions with integrated calibration, ensuring energy-efficient performance and endurance across diverse operating conditions. Designed for cutting-edge direct-IF conversion in RF systems and high-resolution imaging, Omni Design's ADC solutions achieve unparalleled state-of-the-art figures of merit for conversion efficiency. Small in footprint and rich in features, these data converters are engineered to excel in high-performance markets. Available as individual IP blocks or arrayed solutions inclusive of AFEs and digital logic, Omni Design seamlessly harmonizes communication systems—mitigating frequency components and delivering greater capacity while maintaining spectral fidelity. In addition to technical innovations, the Swift™ data converters incorporate Omni Design's bandgap reference and voltage regulation technologies, enabling greater system integration. Configurable as I/Q conversions, these solutions present unmatched capability in performing under dynamic applications, indicating a vital component for future technologies.
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