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.
The Vantablack S-VIS Space Coating is engineered for space applications, where it serves as an advanced stray light suppression and blackbody coating. Suitable for use on satellite instruments, this coating helps to minimize the light reflection that can occur in space environments, thereby ensuring higher accuracy in optical measurements and instrument calibration. Vantablack S-VIS offers exceptional spectral absorption from ultraviolet through to the terahertz range, crucial for a variety of optical systems. Its lightweight and highly absorbent properties allow for more compact baffle and calibration systems without compromising performance. The coating has demonstrated reliability in space missions, offering consistent absorption over extended periods. This coating is particularly critical for optical systems that operate under the challenging conditions of space, including variations in temperature and pressure, as well as the intense radiation environment. It has been applied successfully in low earth orbit operations, enhancing the operability of instruments by reducing system complexity and improving the accuracy of optical sensors.
Altek Corporation's 3D Imaging Chip is designed to enhance three-dimensional sensing capabilities across various applications. By incorporating advanced image processing algorithms, it delivers superior depth perception and spatial awareness, making it well-suited for industries that require high precision and accuracy. This chip is particularly beneficial in robotics, automation, and surveillance, where accurate distance measurement and object tracking are critical.<br/><br/>The chip's innovative design allows for seamless integration with existing systems, optimizing performance without compromising on speed or quality. Its ability to deliver real-time processing enables dynamic interactions, providing improved user experiences in augmented and virtual reality environments. Moreover, the chip's energy-efficient construction ensures prolonged operation without excessive power consumption, making it an ideal choice for portable devices.<br/><br/>Altek's commitment to pushing the boundaries of imaging technology is evident in this 3D Imaging Chip. It combines hardware resilience with software intricacy, creating a robust solution that supports a multitude of applications, from industrial automation to healthcare equipment, enhancing operational efficiency through sophisticated visual data analysis.
This SAR ADC is meticulously engineered for high-speed, single-channel data conversion. It accomplishes a remarkable maximum sampling rate of 1 mega-sample per second (MSPS) while maintaining a 12-bit resolution. Such specifications make it suitable for applications requiring precision and speed, such as signal processing tasks where accuracy is paramount. Accompanying its high sampling rates, the ADC also offers consistent performance across diverse operating conditions, ensuring reliable functionality in varied environments. This robustness is crucial in automotive and industrial settings where stability is mandatory. Moreover, its compact design contributes towards effective power and space management in projects, aligning with modern demands for efficiency and miniaturization. In addition, the integration of advanced features enhances its usability in both simple and complex configurations, supporting a broad spectrum of systems. This flexibility, combined with its technical prowess, positions this SAR ADC as an indispensable tool in the arsenal of sophisticated electronic projects.
The C100 is designed to enhance IoT connectivity and performance with its highly integrated architecture. Built around a robust 32-bit RISC-V CPU running up to 1.5GHz, this chip offers powerful processing capabilities ideal for IoT applications. Its architecture includes embedded RAM and ROM memory, facilitating efficient data handling and computations. A prime feature of the C100 is its integration of Wi-Fi components and various transmission interfaces, enhancing its utility in diverse IoT environments. The inclusion of an ADC, LDO, and a temperature sensor supports myriad applications, ensuring devices can operate in a wide range of conditions and applications. The chip's low power consumption is a critical factor in this design, enabling longer operation duration in connected devices and reducing maintenance frequency due to less charging or battery replacement needs. This makes the C100 chip suitable for secure smart home systems, interactive toys, and healthcare devices.
The Dual-Drive™ Power Amplifier FCM1401 exemplifies advanced engineering in power amplification, designed specifically for extreme efficiency in wireless communication devices. Operating at a center frequency of 14 GHz, it boasts a sophisticated architecture that minimizes silicon area while enhancing performance metrics. One of the standout features of the FCM1401 is its impressive core drain efficiency, which reaches up to 62%, offering significant power savings and extended battery life for end users. Such efficiencies are particularly crucial in mobile devices, where power remains a critical resource. Moreover, this power amplifier features a dual-stage design to facilitate better signal strength and lower transmission losses. With an optimally configured supply voltage range, the FCM1401 performs without efficiency bottlenecking, crucial for systems with constrained power budgets. Its meticulous construction results in an efficiency at device output around 70%, allowing it to outperform competitors across various metrics. These enhancements not only make the FCM1401 ideal for mobile and satellite communications but also align perfectly with initiatives to lower telecommunication costs through energy-efficient technology. Supported by a drain efficiency that peaks even under full load conditions, Falcomm’s FCM1401 assures users of reliability under diverse operational scenarios. The assurance of minimal loss in complex QAM scenarios further underscores its potential for diverse communication applications. This exemplary power amplifier serves as a testament to Falcomm's commitment to innovation, combining unprecedented efficiency with practical applications in everyday technology.
Laser Triangulation Sensors are designed for precision tasks that demand non-contact methods of assessment. These sensors utilize a laser beam triangulation technique to calculate the distance to an object, offering exceptional accuracy and reliability. They are applicable in measuring displacement, dimensions, surface profiles, and even the geometry of transparent and shiny surfaces. The RF603 series, which includes universal models, high-speed variants, and specialized designs, offers a range of options with different measurement capacities and capabilities to fit diverse industrial needs. Measurement ranges for these sensors extend from 2 mm to as far as 2500 mm, depending on the model, while maintaining linearity within ±0.05% and ensuring a robust resolution of up to 0.01% of the range. The use of advanced laser diode technology ensures minimal power consumption and excellent performance across various operational conditions. These sensors are particularly noted for their compatibility with red and blue laser options, catering to specific application necessities with optimal safety ratings. The Laser Triangulation Sensors are engineered to withstand challenging environments, with IP67-rated enclosures for protection against harsh industrial settings. Their compact yet durable design allows for easy integration into existing systems, and their compatibility with various communication interfaces including RS232, CAN, and Ethernet facilitates straightforward data transfer and monitoring. These features, combined with their ability to deliver real-time measurements, make them indispensable tools in high-precision industrial processes.
The MVPM100 series sets a new standard for particulate matter sensors by miniaturizing the core functionalities of traditional particle measuring devices. These sensors provide accurate particle weight measurements while maintaining a compact footprint and low energy usage.<br><br>Developed for precision in monitoring air quality, the MVPM100 series stands out with its high accuracy and direct particle measurement ability, indispensable for applications that require reliable ambient air quality assessment.<br><br>Its multifeatured capabilities are ideal for a variety of environments, from industrial settings to consumer electronics, where maintaining air purity is crucial. The sensor's versatile communication options support integration into a wide array of systems.
eSi-Analog provides a comprehensive solution for integrating critical analog functionality within custom ASIC and SoC devices. This IP is optimized for low power consumption, which makes it highly suitable for applications spanning a variety of industry standards across multiple voltage domains. By incorporating proven silicon technology, eSi-Analog facilitates the development of analog components such as data converters, amplifiers, and sensor interfaces, tailored to meet specific project requirements. It supports a wide array of electronic environments, offering vital enhancements to system reliability and performance. This analog IP is also notable for its ability to integrate seamlessly with both standard and custom digital components, promoting a cohesive, scalable infrastructure that can easily accommodate next-generation applications. Its robustness is evident in its adaptability to diverse industry needs, from automotive electronics to industrial control systems.
The MVH4000 series offers highly precise and fully calibrated sensors for both relative humidity and temperature. Relying on proprietary Silicon Carbide MEMS technology, these sensors are built to provide exceptional long-term stability. They boast rapid response times, extremely low power consumption, and a compact design, making them ideal for applications that demand reliable and swift operation.<br><br>The sensors excel in saving energy with their minimal current consumption, significantly prolonging battery life. They also ensure superior accuracy and long-term reliability, making them a cost-effective solution for various uses. Their built-in calibration supports seamless integration for plug-and-play functionality.<br><br>Available in multiple accuracy levels and offering both digital and analog outputs, the MVH4000 sensors can be customized to meet specific operational needs. Evaluation kits help facilitate the integration and testing process for developers.
The pipelined SAR ADC offered by TechwidU is a high-performance 16-channel, 12-bit converter operating at 1.5Msps. It is engineered to deliver superior speed and accuracy, key in applications demanding high-throughput data conversion. Its sophisticated pipelined design allows for efficient conversion processes with minimal power draw. The converter, fabricated on Samsung's 65nm process, has a proven track record in commercial applications, providing reliable performance across various use cases that require rapid, multi-channel analog-to-digital conversion.
The 14-bit delta-sigma ADC spinning at 20Msps signifies an advancement in high-speed data acquisition. This component couples the best of delta-sigma conversion with enhanced data throughput, suiting applications where detail and speed are indispensable. Utilizing TSMC’s prestigious 65nm process, these converters stand out within environments requiring rapid high-resolution data processing, making them suitable for multimedia, telecommunications, and data center applications seeking robust signal integrity.
Advanced Silicon's Sensing Integrated Circuits are expertly crafted to handle a wide range of sensor requirements, from high-performance photodiode-based detectors to crystal-based photon detection arrays. These ICs are particularly advantageous for systems requiring high levels of functionality and integration, while reducing overall system size, power consumption, and cost. These designs ensure precise detection and signal processing, ideal for complex sensor applications. Their charge sensing ICs feature embedded per-channel A-to-D conversion, which greatly enhance the performance metrics like noise figures and ADC linearity for image scanning technologies. These are extensively used in cutting-edge applications like digital X-ray flat panel detectors, CT scanners, and fingerprint detectors. Meanwhile, their capacitive sensing ICs are renowned for exceptional sensitivity and interference rejection, especially in large screen and rugged touch application contexts. This suite of sensing ICs showcases Advanced Silicon’s dedication to delivering unmatched design support and leading-edge technology solutions. Their innovations facilitate advanced image capturing capabilities and enhance the reliability and efficiency of the systems they are integrated into. These ICs are versatile tools for industries seeking to implement precise sensing technologies in their devices.
Ideal for audio applications requiring precise data conversion, this Sigma-Delta ADC, built on SMIC’s 55nm technology, offers high-resolution 16-bit data processing at a speed of 16KSPS. Its flexible design supports various gain settings and microphone bias levels, delivering exceptional clarity with an SNR of 90dB. With provisions for four fully differential inputs and a versatile digital serial interface, it is tailored for seamless integration in sophisticated audio systems. Its low power consumption and extensive range of supply voltages promise efficient performance across diverse environments.
The delta-sigma ADC with an 8-bit resolution and a modest speed of 2Ksps from TechwidU has been developed with accuracy and power efficiency in mind. By implementing state-of-the-art delta-sigma modulator design on SMIC's 180nm node, the ADC achieves excellent linearity and dynamic range. This product is ideal for low-speed, high-precision applications such as sensor interfacing and low-frequency signal analysis where noise reduction is crucial.
The ADC offerings at Analog Circuit Works are tailored to exceed commodity designs by optimizing for various resolutions, sample rates, and semiconductor processes. Recognizing that a single ADC design cannot cater to all applications, the company customizes its ADC solutions to meet specific needs. These ADCs are fine-tuned across several semiconductor processes, ensuring that they meet stringent performance parameters that set them apart. Analog Circuit Works’ ADC technology focuses on creating solutions that align with distinct computing or communication requirements. Their approach involves not just meeting but surpassing the performance benchmarks of widely used off-the-shelf options. This customization extends to offering various families of ADCs, each with different resolution and sample rates, thus providing more refined digital representation of analog signals. By leveraging a comprehensive understanding of mixed-signal technology, they provide ADCs capable of integrating smoothly within complex systems-on-chip designs. The emphasis on flexibility and precision makes these converters exceptional choices for customized SoC solutions that require robust accuracy and efficient signal conversion.
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 ADX series encompasses Continuous-Time Delta-Sigma ADCs that are integral to high-speed data conversion. These ADCs leverage a proprietary SCCORE™ technology, facilitating resolutions up to 16-bit across various bandwidth requirements. The ADX ADCs are known for their adaptability in high-speed applications while maintaining low power dissipation and superior signal integrity. Each ADX model is precisely tuned to offer a balance between speed, resolution, and bandwidth, making them suitable for mission-critical communications. The ADCs ensure a reliable performance with enhanced dynamic range, supporting various industries such as Defense, Aerospace, and Test & Measurement. Customization is a key feature of the ADX lineup, allowing integration into diverse system environments. The blend of SCCORE™ innovations within these ADCs helps in achieving optimal signal conversion with minimal noise and distortion.
Built on a 65nm process node, this ADC offers an efficient solution for applications requiring high precision with minimal energy consumption. It operates at a 12-bit resolution and can achieve a conversion rate between 0.1MSPS to 1MSPS. The device supports a wide range of operating voltages with 8 channels that cater to single-ended inputs, providing flexibility for diverse system designs. With an excellent SFDR and SNR, coupled with a minimal power footprint, this ADC is adept at applications needing reliable performance on a constrained power budget, such as in wireless sensor networks.
The general-purpose SAR ADC from TechwidU is an impressive 8-channel, 12-bit converter with a sampling rate of 1Msps. Designed with versatility in mind, this converter offers exceptional performance and reliability. Its architecture ensures precise data conversion while maintaining low power consumption. Developed on Magna's 180nm and 130nm process nodes, it delivers silicon-proven accuracy and robust operation. The converter is particularly suited for applications requiring reliable multi-channel data acquisition, offering a manageable size-to-performance ratio essential for complex systems.
The MVWS4000 series integrates multiple sensing capabilities into a single, efficient package that includes humidity, pressure, and temperature measurements. These sensors are engineered for precision and reliability, utilizing Silicon Carbide technology to ensure high performance and low energy consumption.<br><br>Designed for fast response times, these sensors cater to time-sensitive applications, offering comprehensive environmental monitoring in battery-operated devices. They are available in different accuracy grades, allowing for flexible budgeting without compromising performance.<br><br>The compact design and low power requirements make the MVWS4000 series ideal for OEM applications, contributing to the efficiency of portable and stationary devices across industrial, consumer, and medical sectors.
The FaintStar sensor is designed to excel in detecting low-light astronomical phenomena. This advanced sensor combines large pixel architecture with high sensitivity to capture faint signals with exceptional clarity. It is engineered to provide stellar image quality despite challenging lighting conditions in space, thanks to its integrated noise-reduction technologies. With applications primarily in astronomy, the FaintStar sensor supports missions that require precise and reliable low-light imaging solutions to unlock mysteries of the cosmos.
The MVDP2000 series offers cutting-edge differential pressure sensors, built on a proprietary capacitive technology that ensures accurate and stable readings. These sensors are designed to be digitally calibrated for both pressure and temperature, providing optimum performance for portable and OEM applications.<br><br>With a focus on low power consumption and quick responsiveness, these sensors are suitable for a variety of demanding applications including respiratory equipment, gas flow instruments, and HVAC systems. Their robust design makes them highly reliable and adaptable for precision monitoring needs.<br><br>Compact in size yet versatile in functionality, the MVDP2000 sensors are optimized for seamless integration, boasting an impressive resolution and rapid response time. Customization options are available to cater to specific industrial or medical requirements.
The AFX010x Product Family serves benchtop and portable data-acquisition systems, offering up to four channels with a resolution reaching up to 16 bits. It boasts a sampling rate capability of up to 5 GSPS, supported by a digitally-selectable 3dB bandwidth extending to 300 MHz. Integrated features such as a single-to-differential amplifier and offset DAC make it a comprehensive solution for high-resolution systems. The family includes products suitable for a variety of applications, ensuring high signal integrity and power efficiency. This product line is engineered for minimal power consumption while maintaining high sampling rates and wide bandwidth. Each AFE IC encompasses four independent, highly integrated channels. These channels feature programmable input capacitance, a programmable gain amplifier (PGA), offset DAC, ADC, and a digital processor. The AFX010x products are pin-to-pin compatible in a standard package, designed for high integration and reduced PCB footprint. The product's versatility is highlighted by features such as the capability to choose different power modes, allowing adaptability to specific needs. With low power consumption and advanced on-chip technology like clock synthesizers, these products offer exceptional configurability and SWaP-C optimization. Applications extend to areas like handheld and benchtop oscilloscopes, non-destructive testing, and noise diagnostics.
The Pipeline ADC from ASIC North is engineered to deliver high-speed and accurate analog-to-digital conversion. With its ability to handle a range of input scenarios, this ADC is ideal for designs that require rapid signal processing without sacrificing precision. The architecture leverages a pipeline structure, which allows it to simultaneously perform tasks and boosts throughput significantly. This makes it suitable for applications needing uncompromised speed and fidelity.
The FCM3801-BD extends Falcomm’s exceptional legacy in dual-drive™ power amplification, offering unparalleled efficiency and performance at a center frequency of 38 GHz. This power amplifier is engineered to deliver unprecedented amplification capabilities with a focus on reducing energy wastage. As part of Falcomm's suite of next-generation amplifiers, the FCM3801-BD empowers telecommunications with its precise and reliable performance metrics, engineered for the most sophisticated communication systems. Thanks to its unique integration of GaAs and CMOS technologies, the FCM3801-BD offers outstanding energy performance, making it an ideal choice for resource-intensive applications. Its high modularity and ease of integration allow it to seamlessly fit into existing systems while offering robust improvements in both output and operational efficiency. These characteristic enhancements are crucial for developers and engineers focused on achieving best-in-class performance in signal-intensive applications. The FCM3801-BD is engineered with an eye towards the future, accommodating the evolving demands of telecommunications, and space communication technologies. This power amplifier helps to minimize operational costs through effective energy utilization and is well-poised to meet the efficiency challenges of tomorrow's wireless devices. Falcomm’s commitment to developing such products ensures they remain at the forefront of innovation, setting new standards in power amplification across a variety of platforms.
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 Dual-Drive™ Power Amplifier FCM2801-BD represents another leap forward in Falcomm's quest to redefine power efficiency in mmWave-based devices. Centered at 28 GHz, this power amplifier emerges as a pivotal component for next-generation wireless communication technology. The architecture of the FCM2801-BD is engineered to deliver industry-leading drain efficiencies, optimizing both power consumption and performance. It is notably characterized by its robust reliability and exceptional energy management capabilities, tailored for applications where performance excellence is paramount. With a core design that exploits the potentials of GaN and SiGe technologies, the FCM2801-BD ensures superior amplification with minimized energy wastage. Its sophisticated signal processing enhances device output without significant power blowouts. The advanced manufacturing processes adopted promise reduced manufacturing footprint, making it an ideal choice for highly compact and low-footprint technology designs. Engineered for space communications, wearables, and innovative telecommunication systems, the FCM2801-BD champions Falcomm’s vision of marrying exceptional performance with eco-friendly designs. This model’s dependability in high-demand scenarios complements its capability to lower operational expenses across communication systems internationally. In conclusion, the FCM2801-BD is not only a technological marvel from Falcomm but also a commitment to the ethos of sustainability and resource efficiency.
This ADC is an 8-bit, asynchronous analog-to-digital converter specifically designed for telecommunication applications. The product offers efficient performance for data conversion tasks that require fast and reliable sampling within digital communication systems. Embedded within it is a design optimized for telecommunication environments, merging reliability with compact form factors to efficiently translate analog signals into digital data streams. This ADC is thus ideal for telecommunications applications where maintaining clear and accurate signal conversion is critical.
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 represents a leap forward in high-speed imaging, particularly valuable for scientific research that demands rapid capture rates without sacrificing detail or clarity. This sensor enhances image quality under fast-paced conditions, perfect for understanding dynamic processes in both natural and laboratory settings. Its low-noise design further supports clarity in fast imaging scenarios, making it an ideal choice for scientific experiments that necessitate temporal precision along with visual accuracy.
ParkerVision's Energy Sampling Technology has revolutionized the paradigm of RF signal processing with an inventive approach for frequency down-conversion. Traditionally dominated by super-heterodyne techniques, which used high L.O. power to achieve sensitivity and linearity, these were not suited for low-power CMOS applications as well as modern integrated transceivers. Energy Sampling Technology provides the highest sensitivity and dynamic range required for modern receivers while enhancing selectivity and interference rejection. By eliminating RF signal division between I and Q paths, ParkerVision's technology helps in reducing power consumption and improving demodulation accuracy. It offers a compact and cost-effective solution feasible with CMOS technologies, allowing for the development of multimode receivers compatible with advancing CMOS geometries and power levels. The benefits span various transmission standards like GSM, EDGE, CDMA, UMTS, and LTE, making it relevant for devices such as handsets and embedded modems. This technology fundamentally shifts RF signal processing by using matched-filter correlators, enhancing the overall performance capabilities of direct conversion receivers. The elimination of redundant components reduces silicon area, and improved dynamic range lessens the need for external filters. This technology paves the way for a wide array of innovative applications across contemporary wireless ecosystems, thereby facilitating rapid technological leaps in the communication field.
Tower Semiconductor provides a robust SiGe BiCMOS technology that is a game-changer for RF applications, leveraging high-frequency performance while maintaining power efficiency. This technology is pivotal in enabling products that require low noise, high gain, and broad bandwidth, crucial for telecommunications and consumer electronics. The SiGe BiCMOS platform is known for its ability to enhance system performance with minimal power consumption. By integrating the high-frequency capabilities of SiGe with the power and scalability benefits of CMOS, this technology facilitates the production of next-generation RF modules. Supported by multiple process nodes, it allows for seamless adaptation to various application-specific demands. The technology has proven capabilities for satellites, wireless communication, and high-speed data transfer applications. Additionally, the process is designed to support multiple frequency bands, catering to a wide array of devices from mobile handset components to sophisticated radar systems. Its strength lies in enabling compact designs that integrate multiple functionalities, driving advancements in RF observation and manipulation.
This 12-bit ADC utilizing Samsung's 100nm CMOS technology delivers a versatile performance across a broad operating voltage range. Supporting up to 1MSPS conversion rate, it ensures high-quality signal processing over 16 channels. The ADC demonstrates precise linearity with DNL and INL of ±1.0LSB and ±1.5LSB respectively. It provides effective power management with a typical power consumption of just 8mW at 5.0V, and the option to enter a power-down state with minimal current use. Its superior signal-to-noise ratio and effective number of bits (ENOB) make it an excellent choice for applications demanding high-precision data measurement without sacrificing efficiency.
TechwidU's delta-sigma ADC is a finely-crafted 16-bit converter operating at 28Ksps. Specially designed for applications needing high-resolution and low-speed data conversion, this ADC excels in providing detailed data accuracy with low power consumption. Developed under Samsung's 65nm technology, it features progressive delta-sigma modulation techniques to ensure the lowest noise and highest signal integrity. This ADC is in the development stages and is targeted towards scientific and industrial systems where precision measurement is paramount.
The Turbo Encoder and Decoder cores by Creonic are engineered to deliver high efficiency in error correction, catering to standards like DVB-RCS2 and 4G LTE. These cores are vital in systems where low latency and high throughput are crucial, such as mobile communications and satellite transponders. Turbo coding technology is renowned for its capacity to approach the Shannon limit, offering near-optimal performance. Creonic's Turbo solutions are meticulously designed to support a wide gamut of applications from space communications to terrestrial wireless networks. Their enhanced algorithms allow for simplified integration and operational efficiency, drastically reducing the error rate in data transmission. The cores are particularly beneficial in environments that encounter significant noise and interference. By using these Turbo Cores, businesses can optimize their communication systems, thereby minimizing the engineering challenges related to complex transmission environments. These products are a testament to Creonic’s expertise in providing robust, versatile solutions that can be tailored to meet very specific customer needs.
This low-power ADC is optimized for precision and efficiency, engineered using 55nm technology. It features a 12-bit resolution with a conversion rate ranging from 0.1MSPS to 1MSPS, ensuring high-quality data acquisition over its eight channels. The device operates between 2.4V to 3.6V on the analog side and 1.08V to 1.32V digitally, providing flexibility in various applications. Its superior dynamic performance is highlighted by an SFDR of 89dB and an SNR of 72dB, while maintaining minimal power use, making it suitable for battery-powered and portable systems.
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.
The Successive Approximation Register (SAR) ADC developed by ASIC North caters to high-resolution data acquisition systems. It excels in delivering precise conversion rates suitable for applications where accuracy and low latency are critical. The design incorporates a compact form factor and low power consumption, making it optimal for portable and embedded systems. Its efficient architecture supports a range of industrial applications, enhancing signal accuracy and systemic performance.
The ADC-12-35M-TJ employs a 12-bit architecture, delivering a 35 MS/s (mega samples per second) conversion rate suitable for a wide range of high-speed applications. Based on the TowerJazz process, this pipeline ADC is designed to provide excellent linearity and minimal power consumption, making it a prime candidate for precision-driven electronic infrastructures. Crafted for applications that demand high-speed data conversion, the ADC-12-35M-TJ stands out for its ability to process analog signals with great accuracy and efficiency, thanks to its pipeline structure. This architecture allows the ADC to handle large amounts of data seamlessly, enabling enhanced performance in systems requiring rapid data throughput. Its robust design ensures that it can operate efficiently in varied conditions, making it perfect for use in telecommunications, audio, and signal processing systems. The ADC's precise conversion capabilities ensure it can support detailed and diverse signal input types with minimal distortion.
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 Blazar Bandwidth Accelerator Engine is a cutting-edge solution for enhancing the performance of FPGA-based systems. This IC specializes in in-memory compute capabilities, enabling the acceleration of functions while providing high capacity, low latency memory for demanding applications. With bandwidth capabilities reaching an impressive 640 Gbps, this engine manages 5 billion reads per second, ideal for high-speed data environments. Incorporating optional RISC cores for enhanced computation, the Blazar Bandwidth Accelerator Engine supports dual port memory configurations and comes with 576Mb or 1Gb of embedded memory. These features make it well-suited for applications like SmartNIC & SmartSwitch, metering and statistics, and 5G UPF and BNG offload. Blazar's integration into systems allows for efficient serial link aggregation and simplifies the sub-system design for high-performing network infrastructures. The design focus on in-memory compute makes it a powerful tool for modern communication and data processing needs.
Creonic offers a comprehensive range of LDPC Encoder and Decoder cores, expertly engineered for high-speed data throughput. These cores cater to numerous standards such as DVB-S2X and CCSDS, providing flexible, robust solutions for error correction in digital communication systems. They are designed to maximize performance in demanding environments, supporting varied applications from satellite communications to next-generation mobile networks. Key products like the 5G-NR LDPC and DVB-S2X LDPC/BCH cores exemplify sophisticated designs that deliver exceptional data integrity and throughput. Each specific LDPC product aligns with industry-standard protocols, ensuring compatibility and ease of integration into existing infrastructures. The modular design provides adaptability to different use cases, particularly in the rapidly evolving 5G infrastructure landscape. LDPC technology is critical for high-efficiency error correction, and Creonic's offerings are designed to minimize latency while maximizing reliability. These cores play an integral role in maintaining the integrity and performance standards of modern communication systems, ensuring that data is transmitted accurately over various channels.
The Polar Encoder and Decoder solutions from Creonic are at the forefront of communication technology, aiming to optimize data transmission reliability. Adhering to numerous standards, these Polar Codes are especially effective in environments with fluctuating signal integrity, commonly seen in mobile networks and data communications. Designed with modern algorithms, Creonic’s Polar solutions offer superior performance by utilizing a method of encoding data that facilitates easier error detection and correction. This approach ensures reduced processing times and lower error rates, making it highly suitable for next-generation wireless communication systems. These Polar Cores are ideal for businesses aiming to enhance data handling and improve error resiliency, offering a versatile, adaptive solution suitable for high-performance contexts. The cores streamline the flow of information, ensuring that communication lines remain clear and efficient even under significant load conditions and disturbances.
The Mixed-Signal Front-End offered by Global Unichip Corp. is engineered to enhance analog signal processing capabilities, critical in various electronics industries. This technology provides a bridge between analog and digital domains, enabling precise signal processing and data conversion. The front-end is designed to work in tandem with complex silicon systems, leveraging cutting-edge mixed-signal IP to ensure optimal signal fidelity and resolution. This IP is particularly valuable in fields like telecommunications, automotive electronics, and consumer electronics, where analog signals must be accurately converted and processed within digital systems. The seamless integration into SoC structures offers flexibility and scalability for designers looking to enhance their chip capabilities without compromising on performance or efficiency. Moreover, Global Unichip's Mixed-Signal Front-End stands out with its robust customization capabilities, allowing for adaptations to specific needs and applications. This adaptability makes it a preferred choice for companies aiming to innovate within the confines of precise analog-digital interaction, ensuring that their systems can handle the rapid shifts in data inherent in modern electronics applications.
Designed for high-speed and high-precision conversion, the Column A/D Converter is a vital component in modern image sensors. It offers unparalleled accuracy and speed, turning analog signals from image sensors into digital outputs that are ready for processing. This converter supports various resolutions and conversion rates, giving designers the flexibility to choose configurations that match their specific needs. The converter's architecture leverages advanced algorithms for low power consumption while maintaining high performance, making it an ideal choice for battery-powered and portable devices. Its compact design not only saves space but also integrates efficiently into existing sensor arrays, facilitating quick and straightforward deployment. Due to its scalability, the Column A/D Converter can be implemented across a variety of platforms and applications, from consumer digital cameras to industrial imaging systems. Its ability to deliver high frame rates without compromising quality is particularly advantageous in fast-paced environments where precision and speed are of the essence.
YouADC provides high-quality analog-to-digital conversion solutions, crucial for processing signals in a variety of electronic systems. Leveraging advanced technology, it facilitates precise data conversion, ensuring that input signals are accurately transformed to usable digital data for further processing.
This ADC is designed using Magnachip's 0.18um CMOS technology and is equipped with a 12-bit resolution at a conversion rate of 1MSPS. Its analog voltage ranges from 4.5V to 5.5V, while digital voltage supports 1.62V to 1.98V. The device boasts DNL of ±1LSB and INL of ±2LSB, ensuring precise measurements. Additionally, it operates efficiently over a temperature span of -40°C to 85°C with a current consumption of just 2mA, making it ideal for applications requiring reliable data conversion.
The Magnetic Hall Sensor developed at SystematIC Design is engineered to perform reliably across extended temperature ranges from -40°C to 110°C, offering an exceptional degree of sensitivity and precise current sensing capabilities. It operates with a 5.0 V single power supply, ensuring efficient energy consumption without compromising on performance. A standout feature of this sensor is its minimal magnetic hysteresis combined with low offset and thermal coefficients (TC), enhancing the accuracy of measurements. Designed to handle high dynamics, the sensor maintains operational stability even under substantial common-mode transients greater than 25kV/µs, which is crucial for industrial environments characterized by high electromagnetic interference. Moreover, the device provides a typical bandwidth of 80 kHz, making it an optimal choice for dynamic applications requiring swift response and reliable detection with minimal total output error, typically around ±1.5%. The robust design is further validated by certifications such as UL and CSA, ensuring high isolation voltage up to 3 kV RMS for one minute. With capabilities to accurately measure current ranges from ±10 A to ±30 A, this sensor proves indispensable for integration into applications demanding high precision and stability under rigorous conditions.
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