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 AI SoC is an advanced powerhouse, utilizing third-generation NPU architecture to deliver up to 8 TOPS of efficient computing. This architecture excels in both CNN and transformer applications, optimizing DDR bandwidth usage. Its robust video processing features include 4K 60FPS video output, with exceptional performance in noise reduction, dynamic range, and low-light scenarios. With versatile application support ranging from intelligent security to autonomous driving, the KL730 stands out by delivering exceptional processing capabilities.
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 16-bit Sigma-Delta ADC operates with exceptional precision and versatility, leveraging 55nm SMIC CMOS technology. It offers programmable gain ranging from 0 to 50dB, catering to a variety of audio applications. The ADC features four fully differential inputs and integrated microphone biasing options to enhance its applicability in mono audio systems. This ADC supports a conversion rate of 16KSPS and is equipped with a digital serial interface, enabling seamless integration with diverse digital systems using PDM, I2S, or TDM protocols. It's designed to minimize power consumption while maintaining a strong signal-to-noise ratio of 90dB. The ADC is optimized for audio applications and its robust design includes power-down modes that reduce current to less than 1uA, ensuring efficiency without sacrificing performance.
The 3D Imaging Chip is designed to enhance the capabilities of devices requiring advanced 3D sensing and imaging technology. With an emphasis on precision, this chip supports a myriad of applications ranging from security and surveillance systems to autonomous machinery. It integrates seamlessly not only into varied machine vision systems but also into devices used in different fields that rely on accurate depth perception. This 3D imaging solution underscores Altek's commitment to producing high-performance technology that aids in intricate environment analysis and decision-making processes. This chip employs cutting-edge algorithms to improve the depth perception capabilities of devices, ensuring that it can operate effectively in diverse environments from short to long range. By integrating seamlessly into complex systems, this product strengthens overall functionality, making it an indispensable component in robotics and automated systems. Its robust capacity to handle various environmental conditions also highlights its versatility in usage across different industries. Moreover, this imaging technology is meticulously crafted to reduce energy consumption while maintaining high processing speeds, which are critical in time-sensitive and energy-conscious applications. The sophistication of this chip lies in its ability to combine high-resolution data capture with fast data processing, providing users with the assurance of accuracy and efficiency in real-time operational settings. This positions it as a pivotal development for industries looking to adopt smarter and more efficient technological solutions.
Laser Triangulation Sensors are cutting-edge devices designed for precise non-contact measurement and position verification. These sensors are engineered to offer unmatched accuracy, operating within a range from 2 mm to 2.5 meters with a minimal measuring error of ±1 µm. They utilize both BLUE and IR laser bases, providing a sampling frequency of 160 kHz to ensure rapid and reliable data capture. The robust and versatile nature of these sensors makes them ideal for a wide range of industrial applications, offering superior performance in dynamic environments. The sensors are part of the RF603, RF602, RF603HS, RF600, RF605, RF609, and RF60i series. They are meticulously designed to function effectively in harsh industrial settings, maintaining efficiency and precision without physical contact. The Triangulation Sensors form an integral part of automation processes, where precise position checking and measuring are pivotal. Equipped with blue and infrared lasers, they offer high adaptability, allowing them to cater to various measurement needs across multiple disciplines. Whether for ensuring the correct positioning of components on assembly lines or verifying measurements within quality assurance processes, these sensors deliver reliable performance and adaptability.
The Chipchain C100 is a pioneering solution in IoT applications, providing a highly integrated single-chip design that focuses on low power consumption without compromising performance. Its design incorporates a powerful 32-bit RISC-V CPU which can reach speeds up to 1.5GHz. This processing power ensures efficient and capable computing for diverse IoT applications. This chip stands out with its comprehensive integrated features including embedded RAM and ROM, making it efficient in both processing and computing tasks. Additionally, the C100 comes with integrated Wi-Fi and multiple interfaces for transmission, broadening its application potential significantly. Other notable features of the C100 include an ADC, LDO, and a temperature sensor, enabling it to handle a wide array of IoT tasks more seamlessly. With considerations for security and stability, the Chipchain C100 facilitates easier and faster development in IoT applications, proving itself as a versatile component in smart devices like security systems, home automation products, and wearable technology.
The ADQ35 is a high-throughput digitizer designed for critical signal processing applications. Known for its 12-bit accuracy and high sampling rates, it stands out in delivering up to 10 GSPS, supporting single or dual-channel data streams. This ensures data integrity and speed for applications that demand precision and reliability, such as telecommunications and high-speed imaging. Equipped with enhanced processing capabilities, the ADQ35 ensures superior handling of complex datasets, making it suitable for scientific research and advanced electronics projects. Its robust design caters to the needs of modern digital systems, allowing for a seamless integration into existing infrastructure to facilitate expansive projects. This device also features streaming capabilities that provide a continuous flow of high-quality data, excelling in applications that require constant monitoring and data analysis. The ADQ35 digitizer is an excellent choice for industries that rely on swift and accurate data interpretation, enhancing overall system performance and technical output.
The FCM1401 is a 14GHz CMOS Power Amplifier tailored for Ku-band applications, operating over a frequency range of 12.4 to 16 GHz. This amplifier exhibits a gain of 22 dB and a saturated output power (Psat) of 19.24 dBm, ensuring optimal performance with a power-added efficiency (PAE) of 47%. The architecture enables reduction in battery consumption and heat output, making it ideal for satellite and telecom applications. Its small silicon footprint facilitates integration in space-constrained environments.
The MVPM100 series represent an innovative leap in particulate matter detection, tailored to meet precise measurement requirements of airborne particles in the PM2.5 class. These sensors leverage microsystem technologies to condense the capabilities of extensive gravimetric sensors into a more manageable format. Unlike traditional particle sensors that typically rely on optical methods, the MVPM100 sensors provide actual weight measurements of particles, ensuring higher precision in varying environments. Designed for versatility, they cater to multiple industries, maintaining a compact yet powerful configuration, imperative for contemporary air quality management solutions. Ideal for both portable and stationary applications, these sensors combine accu
ASIC North's Pipeline ADCs are designed to offer high-resolution, fast sampling, making them ideal for applications requiring precision and speed. These converters feature a pipeline architecture that enhances throughput and reduces latency, ensuring data integrity in high-performance applications. They are particularly suited for use in communications, imaging, and audio processing where maintaining signal fidelity is critical. ASIC North's expertise in mixed-signal processes ensures these ADCs deliver exemplary performance across a range of settings.
D2D® Technology, developed by ParkerVision, is a revolutionary approach to RF conversion that transforms how wireless communication operates. This technology eliminates traditional intermediary stages, directly converting RF signals to digital data. The result is a more streamlined and efficient communication process that reduces complexity and power consumption. By bypassing conventional analog-to-digital conversion steps, D2D® achieves higher data accuracy and reliability. Its direct conversion approach not only enhances data processing speeds but also minimizes energy usage, making it an ideal solution for modern wireless devices that demand both performance and efficiency. ParkerVision's D2D® technology continues to influence a broad spectrum of wireless applications. From improving the connectivity in smartphones and wearable devices to optimizing signal processing in telecommunication networks, D2D® is a cornerstone of ParkerVision's technological offerings, illustrating their commitment to advancing communication technology through innovative RF solutions.
Advanced Silicon's Sensing Integrated Circuits are engineered for exceptional performance in diverse sensor systems, ranging from photo-diode based detectors to low-noise pixel arrays for photon detection. These ICs leverage multi-channel configurations with integrated per channel analog-to-digital conversion, providing superb noise specs, ADC linearity, and resolution. This makes them ideal for use in digital X-ray systems, CT and PET scanners, particle detectors, and even fingerprint detection solutions. By enhancing integration and performance while minimizing size and power consumption, these products empower highly efficient and advanced sensor applications.
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.
The Ncore Cache Coherent Interconnect from Arteris provides a quintessential solution for handling multi-core SoC design complications, facilitating heterogeneous coherency and efficient caching. It is distinguished by its high throughput, ensuring reliable and high-performance system-on-chips (SoCs). Ncore's configurable fabric offers designers the ability to establish a multi-die, multi-protocol coherent interconnect where emerge cutting-edge technologies like RISC-V can seamlessly integrate. This IP’s adaptability and scalable design unlock broader performance trajectories, whether for small embedded systems or extensive multi-billion transistor architectures. Ncore's strength lies in its ability to offer ISO 26262 ASIL D readiness, enabling designers to adhere to stringent automotive safety standards. Furthermore, its coupling with Magillem™ automation enhances the potential for rapid IP integration, simplifying multi-die designs and compressing development timelines. In addressing modern computational demands, Ncore is reinforced by robust quality of service parameters, secure power management, and seamless integration capabilities, making it an imperative asset in constructing scalable system architectures. By streamlining memory operations and optimizing data flow, it provides bandwidth that supports both high-end automotive and complex consumer electronics, fostering innovation and market excellence.
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.
The MVDP2000 series introduces differential pressure sensors built on advanced capacitive sensing technology, delivering high sensitivity and stability. Calibrated to provide precise pressure and temperature data, these sensors are crafted for low power needs and rapid data feedback, ideal for situations demanding quick response. An essential component for OEM and portable devices like respiratory equipment and gas flow instruments, these sensors fulfill requirements for accuracy and energy efficiency. Their digital configuration eases integration, supporting applications in various environments with reliable performance. The sensors' specifications include a wide measurement range and a digital interface. They offer detailed data resolution aligned to 15-to-21 bits, with a compact DFN package making them suitable for space-constrained applications.
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 MVH4000 series provides highly precise measurements of both humidity and temperature, making it ideal for applications that require dual environmental readings. Utilizing advanced Silicon Carbide MEMS technology, these sensors are known for their remarkable stability over time, quick response rates, and minimal energy use. The compact design allows for integration into various systems, especially where space and energy efficiency are critical. Offering low current consumption starting as low as 0.62 µA, these sensors are optimized for systems where battery life is crucial. Their performance remains consistent with a long-term stability of 0.1% RH per year. They come in a convenient small form factor of 2.5 x 2.5 x 0.9 mm, making it easier to allocate on PCBs. Accuracy is a prime feature, with humidity measurement accuracy up to ±1.5%RH and temperature accuracy within ±0.2°C, that aids in precise environmental monitoring. The pre-calibrated sensors simplify installation and support immediate implementation in various industries such as industrial, consumer, medical, and automotive sectors.
This high-performance single-channel SAR ADC offers a resolution of 12 bits and operates at a speed of 1 MSPS. It is designed for precision and efficiency, ideally suited for applications requiring rapid data acquisition and conversion in real time. Its architecture provides excellent accuracy and repeatability, critical for high-fidelity signal processing. This ADC is versatile enough to be integrated into a wide variety of electronic systems, making it an essential component for designers needing reliable data conversion solutions.
eSi-Analog integrates critical analog functionality into custom ASIC and SoC devices using leading foundry processes. It is optimized for low-power usage, ensuring efficiency and adaptability across a range of applications. This IP has been silicon-proven to meet custom specifications, providing reliability and performance in various high-demand sectors.
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.
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.
ELFIS2 is a cutting-edge sensor designed to meet the evolving requirements of space and scientific imaging applications. With its state-of-the-art architecture, the sensor is optimized for capturing high-resolution images in environments where precision and clarity are of utmost importance. It offers remarkable performance in capturing intricate details necessary for scientific exploration and research. This sensor is engineered with advanced features, including a high dynamic range and exceptional noise reduction capabilities, ensuring clarity and accuracy in every image captured. Such traits make it suitable for use in both terrestrial and extraterrestrial scientific endeavors, supporting studies that require detailed image analysis. ELFIS2 is perfectly suited for integration into scientific instruments, offering a robust solution that withstands the harsh conditions often encountered in space missions. Its adaptability and reliable performance make it an essential component for projects aiming to unlock new insights in scientific imaging, supporting endeavors from basic research to complex exploratory initiatives.
The MVWS4000 series encapsulates a trio of sensors in a single package, measuring humidity, pressure, and temperature. Crafted with sophisticated Silicon Carbide technology, these sensors are renowned for their accuracy and efficiency, presenting exceptionally fast sampling rates to serve precise, real-time environmental assessments. Designed for robustness, these units feature various grades of precision to accommodate different financial and operational requirements, ensuring high performance for sensitive applications. Their ultra-low energy needs and reliability position them as ideal candidates for OEM products and battery-powered devices. With their compact size yet comprehensive capabilities, the MVWS4000 series lends itself well to sectors including, but not limited to, industrial settings, the consumer marketplace, healthcare, and automotive systems.
This low-power, 12-bit ADC from Leo LSI is intended for applications that need reliable conversion with minimal energy use. Constructed on a 65nm process node, the ADC offers conversion speeds from 0.1MSPS up to 1MSPS, accommodating a variety of signal processing needs. Operating within an analog supply range of 2.4V to 3.6V and a digital range from 1.08V to 1.32V, this ADC can easily fit into compact and power-sensitive devices. Its low current requirement of just 1.1mA ensures minimal energy impact on systems. The ADC is designed to handle diverse sensor inputs efficiently, making it particularly useful for integration in power-conscious and space-limited devices like portable data acquisition systems and remote sensors.
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.
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.
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.
CoreVCO stands as a versatile voltage-controlled oscillator design, optimized for high performance in RF and mixed-signal environments. Known for its rapid switching capabilities and wide frequency range, it's ideal for applications that require agile frequency control. This VCO maintains low phase noise and a high tuning linearity, ensuring stable outputs across variable conditions. Its design emphasizes compactness and power efficiency, making it suitable for portable and space-constrained devices. The robust output power and phase noise characteristics make CoreVCO particularly appealing for high-fidelity electronic systems. CoreVCO is engineered to integrate seamlessly into a range of electronic applications, enhancing the functionality and reliability of RF transceivers, signal generators, and phase-locked loops. Its adaptability allows customization to meet specific project demands, supporting diverse technologies across various sectors.
The AFX010x Product Family by SCALINX is a leading-edge range of Analog Front Ends designed for both benchtop and portable data-acquisition systems. These AFEs offer up to four channels, each with up to a 16-bit resolution and a high sampling rate reaching 5 GSps. Additionally, they come with a digitally-selectable 3dB bandwidth, which can range up to 300MHz, and feature an integrated single-to-differential amplifier and offset DAC. These AFEs are known for their low power consumption and high signal integrity. This makes them suitable for high sampling rate and wide bandwidth requirements, ensuring a high level of integration. The package includes programmable input capacitance, a programmable gain amplifier (PGA), an offset DAC, an ADC, and a digital processor within each channel, all within a standard 12mm × 12mm, 196-Ball BGA. The AFX010x family uses SCALINX’s proprietary SCCORE™ technology, which reduces the PCB footprint and cuts power consumption by up to 50%. This results in products that are pin-to-pin compatible across different AFX010x variants, providing users with flexibility in terms of power modes and performance configurations.
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.
ParkerVision's Energy Sampling Technology is a state-of-the-art solution in RF receiver design. It focuses on achieving high sensitivity and dynamic range by implementing energy sampling techniques. This technology is critical for modern wireless communication systems, allowing devices to maintain optimal signal reception while consuming less power. Its advanced sampling methods enable superior performance in diverse applications, making it a preferred choice for enabling efficient wireless connectivity. The energy sampling technology is rooted in ParkerVision's expertise in matched filter concepts. By applying these concepts, the technology enhances the modulation flexibility of RF systems, thereby expanding its utility across a wide range of wireless devices. This capability not only supports devices in maintaining consistent connectivity but also extends their battery life due to its low energy requirements. Overall, ParkerVision's energy sampling technology is a testament to their innovative approach in RF solutions. It stands as an integral part of their portfolio, addressing the industry's demand for high-performance and energy-efficient wireless technology solutions.
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.
This 12-bit ADC features advanced CMOS technology to deliver a wide operating range and speedy conversion rate, ideally clocked at 1MSPS. With AVDD spanning from 2.7V to 5.5V, it provides flexibility and robustness for various applications. The converter is engineered with 16-channel single-ended inputs, maximizing its versatility for multi-signal environments. The ADC's power-efficient design sets it apart, drawing minimal power (8.0mW at 5.0V supply) while maintaining high performance. It also supports power-down modes, reducing current consumption to less than 0.1uA, making it ideal for battery-powered devices. The device offers excellent data precision with an effective number of bits (ENOB) up to 11.3 bits and a strong signal-to-noise ratio (SNR) of 70.7dB, suitable for applications in data acquisition and sensor networks.
The FCM3801-BD is designed for those requiring 39GHz CMOS Power Amplification within the 5G mmWave range. It supports frequencies from 32 to 44 GHz, featuring a 19 dB gain and a Psat of 18.34 dBm. With a PAE of 45%, this amplifier is engineered for high-power applications where efficiency and thermal management are crucial. It's particularly suited for modern telecom environments requiring minimal energy use and weight savings.
The FlexNoC Interconnect is engineered as a physically-aware network-on-chip (NoC) IP that serves as the backbone of semiconductor solutions in high-demand markets. It assists SoC developers in creating quick, reliable network setups with minimal power consumption. By incorporating top-grade algorithms and a user-friendly interface, FlexNoC facilitates flexible and efficient interconnect designs for both small and large-scale SoCs. Featuring robust support for comprehensive topologies, FlexNoC is highly advantageous in navigating the complexities of long interchip pathways using virtual channels and synchronous communications. It supports multi-channel memory such as HBMx, ensuring outstanding bandwidth and seamless off-chip memory access. The IP’s physical awareness advances timing closure processes and reduces interconnect area, contributing to reduced power usage and enhanced scalability. Designed for wide application across automotive, consumer electronics, and industrial sectors, FlexNoC offers standard protocol interoperability and advanced power management with state-of-the-art security measures. The IP’s ability to maintain high frequencies and lower latencies while ensuring compact die areas makes it indispensable for projects aiming for time-efficient delivery and market distinction.
SiGe BiCMOS technology is tailored for RF applications, delivering excellent performance for high-frequency communications. This technology supports low noise figures and high linearity, vital for advanced communication systems. In the growing landscape of RF solutions, this process technology allows for enhanced integration and miniaturization of components, driving innovations in wireless communication. High precision transistors in this technology facilitate the development of superior RF transceivers, suitable for complex and demanding applications. It's well-suited for use in infrastructure systems where robust and reliable RF signal processing is crucial. By integrating both bipolar and CMOS transistors, this platform offers the best of both worlds, combining high-speed performance with power efficiency. Designed for versatility, the SiGe BiCMOS technology simplifies the design of RF circuits by allowing adaptability in circuit design and process options. This feature is particularly beneficial for designers working on next-generation wireless devices, pushing boundaries in speed and functionality.
The 12-bit, 8-channel ADC from Leo LSI is engineered for low-power performance with impressive accuracy. Using a 55nm process, this ADC excels in data acquisition systems, offering conversion rates from 0.1MSPS to 1MSPS. Its analog input range spans from REF-B to REF-T, adapting to multiple sensor and signal requirements. Operating with an analog power supply from 2.4V to 3.6V, and a digital power supply range of 1.08V to 1.32V, this ADC is designed to fit perfectly in environments demanding low voltage and high precision. It's noted for consuming merely 1.1mA under typical conditions, making it exceptionally efficient. This ADC is well-suited for integration into systems requiring precise data conversion with minimal power, such as battery-operated and wireless sensor networks. It also boasts a power-down current of less than 0.1uA, providing significant energy savings.
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 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 SAR ADCs from ASIC North deliver precise analog-to-digital conversion with an emphasis on efficiency and speed. Incorporating a successive approximation register (SAR) architecture, these converters are finely tuned for balancing resolution and conversion time, crucial for real-time data processing applications such as portable medical devices and industrial control systems. Their ability to provide stable and accurate conversions is attributed to ASIC North's meticulous design practices and process expertise.
The FCM2801-BD is a 28GHz CMOS Power Amplifier, specifically designed for applications in the 5G mmWave spectrum. It operates across a frequency range of 23 to 36 GHz and delivers a gain of 22 dB with a Psat of 19.55 dBm. Boasting a PAE of 53%, this amplifier suits high-frequency telecommunications, offering improved range and reduced energy consumption. The design minimizes thermal output, which further aids in reducing system maintenance costs.
The Blazar Bandwidth Accelerator Engine is designed to provide in-memory computing capabilities alongside high capacity and low latency memory solutions for applications demanding extreme data processing speeds. With embedded compute features and capacities reaching up to 1Gb, this engine supports applications that require fast and high-volume data handling, such as network processing and large-scale data analytics. This cutting-edge product integrates advanced in-memory functions such as burst and read-modify-write (RMW) operations, which are specifically designed to execute faster than conventional memory processes. These functions allow for efficient data manipulation and movement, enabling systems to achieve higher throughput and reduced operational commands. Additionally, the Blazar engine supports dual-port memory configurations which can handle simultaneous data read and write operations, optimizing data flow and reducing latency. The inclusion of optional RISC cores augments computing capabilities, providing a versatile platform for handling complex algorithms and real-time data requirements. Highly applicable for smart network interface cards (NICs) and high-performance computing environments, the Blazar Accelerator Engine is built to enhance the data processing abilities of modern IT infrastructure significantly. It represents a leap forward in memory architecture, supporting applications that are foundational to advancing fields like 5G rollouts, cloud computing, and advanced analytics.
The ADQ7DC high-throughput digitizer is equipped with an impressive 14-bit resolution and can achieve speeds up to 10 GSPS. Catering to both single and dual-channel configurations, this digitizer supports a wide range of high-performance applications requiring rapid and precise data processing and acquisition. Its robust architecture ensures seamless operation, whether in research-focused environments or advanced technological applications like telecommunications. The precision and speed of the ADQ7DC make it a cornerstone for projects that rely on high-frequency data measurements and comprehensive signal analysis. Moreover, the digitizer's quality input range, reaching up to 3 GHz, equips it to manage signals effectively, maintaining integrity and performance under diverse conditions. This adaptability extends to various fields, supporting signal analysis efforts across numerous research and development initiatives.
The ADQ35-WB is a high-performance RF digitizer engineered to capture and process RF signals with unprecedented precision. It boasts a remarkable sampling rate that can reach up to 10 GSPS, and is capable of streaming data at an impressive 14 Gbyte/s. This digitizer is adept at handling single or dual-channel configurations, making it versatile for a range of applications that demand high fidelity and speed. Designed to facilitate pulse detection, it features a 12-bit resolution that is optimized to deliver the equivalent of 16-bit Effective Number Of Bits (ENOB). The ADQ35-WB’s design accommodates rigorous signal processing tasks, ensuring high-speed acquisition without compromising on quality. This makes it an ideal candidate for usage in applications like wide-band signal analysis, where both accuracy and speed are critical. With its sophisticated signal processing capabilities, the ADQ35-WB enables smoother digital performance enhancement. It supports a range of applications in fields such as research, telecommunications, and electronic warfare, attesting to its versatility and robustness in managing complex signal environments.
The analog IP products encompass a vast range of components crucial for audio and signal processing applications. Offerings include audio codecs capable of handling 16/18/24-bit Sigma Delta conversion, which is essential for high-fidelity audio applications. The product line also features voice codecs suitable for communication devices, alongside a selection of ADC and DAC components ranging from 6-bit to 12-bit capabilities and operating at frequencies from 48 KHz to over 100 MHz. These products are designed to meet the stringent requirements of modern multimedia and communication applications. Additionally, there are integrated solutions such as 3-channel ADCs and DACs with high-speed capabilities up to 200 MHz, crucial for advanced audio and video processing systems.
Creonic's Turbo encoders and decoders are meticulously designed to support error correction in both satellite and terrestrial communication applications. The turbo coding process enhances data reliability and efficiency, making it indispensable in digital communication systems where bandwidth and power efficiency are paramount. These IP cores are aligned with leading standards such as DVB-RCS2 and LTE, ensuring they meet the rigorous demands of high-performance systems. The Turbo technology employed by Creonic optimizes for high throughput while maintaining low error rates, making these IP cores vital for communication networks where performance consistency is critical. Commercial and military users alike benefit from the robust error correction capabilities these encoders and decoders provide, as they improve signal reliability over varying transmission conditions. This consistent reliability translates to a reduction in retransmissions and improved overall communication efficiency. Moreover, the flexibility and configurability of Creonic's Turbo IP cores allow for tailored solutions across different platforms, including both FPGA and ASIC. This adaptability ensures that the cores can be embedded effectively across a variety of hardware architectures, thereby broadening the scope of applications they can support.
The 24-bit Sigma-Delta ADC with Analog Front End (AFE) from Rafael Micro provides precision and accuracy in signal conversion processes. This IP is built to support a broad range of applications that demand high-resolution audio and signal processing capabilities, making it an ideal choice for advanced audio systems and precision instrumentation. This ADC features a robust architecture designed to handle significant dynamic range and low noise floor, ensuring signal integrity in various usage scenarios. The inclusion of an AFE optimizes the analog input path, enhancing the overall performance by maintaining signal fidelity from input to digitization. Rafael Micro's ADC solutions are recognized for their low power consumption and superior performance metrics, suitable for devices in need of efficient yet capable signal processing. This technology is a testament to Rafael Micro's commitment to delivering high-quality semiconductor solutions that facilitate superior end-user experiences across multiple electronic products.
IPGoal's Data Converter is designed to bridge the gap between analog and digital signals, offering high precision and performance. This technology is pivotal for applications that require accurate data representation and conversion, such as in control systems and digital signal processing. With cutting-edge architecture that ensures minimal conversion errors and high linearity, the Data Converter from IPGoal stands out in delivering high-frequency data conversion with efficiency and reliability. This makes it ideally suited for applications in sectors like telecommunications and consumer electronics. The converter's flexibility to adapt to different operational requirements makes it a versatile solution capable of meeting various customer-specific demands. Its design prioritizes low power consumption while maintaining superior performance, reflecting IPGoal’s commitment to innovation in semiconductor technology.
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