All IPs > Automotive
The automotive category of semiconductor IPs is primarily dedicated to addressing the intricacies and demands of modern automotive technology. As vehicles become increasingly sophisticated, integrating more electronic systems and sensors, the need for reliable, efficient, and safe semiconductor IP solutions has never been greater. Our diverse range of automotive semiconductor IPs is designed to meet the needs of various automotive applications, from enhancing communication between vehicle components to ensuring the utmost safety and connectivity.
One essential aspect of this category is the variety of communication protocols needed in automotive systems. This includes the classic Controller Area Network (CAN), which is a robust vehicle bus standard allowing microcontrollers and devices to communicate with each other within a vehicle without a host computer. Modern advancements in this area are represented by CAN-FD and CAN XL, which offer extended data formats and faster communication speeds, crucial for accommodating the growing complexity of in-vehicle networks. Additionally, the inclusion of FlexRay and LIN technologies provides options for higher bandwidth communication and budget-friendly local interconnect networks.
Safety is also a pivotal concern in automotive semiconductor IPs, as exemplified by Safe Ethernet technology. Safe Ethernet enables high-speed communication suitable for applications where safety is critical, such as advanced driver-assistance systems (ADAS) and autonomous driving technologies. These semiconductor IPs are integral in ensuring information is shared accurately and immediately between vital components, thus reducing the room for error and increasing overall vehicle safety.
Overall, the automotive category of semiconductor IPs offers essential tools for developing vehicles that are not only connected and efficient but also highly safe and reliable. Whether you’re working on enhancing the internal communications of a vehicle, implementing advanced safety systems, or developing new technologies for the networked, autonomous vehicles of tomorrow, our automotive semiconductor IP catalog has the resources you need to succeed.
Time-Triggered Ethernet (TTEthernet) is a cutting-edge data communication solution tailored for aviation and space sectors requiring dual fault-tolerance and redundancy. Critically designed to support environments with high safety-criticality, TTEthernet embodies an evolutionary step in Ethernet communication by integrating deterministic behavior with conventional Ethernet benefits. This blend of technologies facilitates the transfer of data with precision timing, ensuring that all communications occur as scheduled—a vital feature for mission-critical operations. TTEthernet is particularly advantageous in applications requiring high levels of data integrity and latency control. Its deployment across triple-redundant network architectures ensures that even in case of component failures, the network continues to function seamlessly. Such redundancy is necessary in scenarios like human space missions, where data loss or delay is not an option. TTTech's TTEthernet offerings, which also include ASIC designs, meet the European Cooperation for Space Standardization (ECSS) standards, reinforcing their reliability and suitability for the most demanding applications. Supporting both end systems and more intricate system-on-chip designs, this technology synchronizes all data flow to maintain continuity and consistency throughout the network infrastructure.
Silvaco's Automotive IP solutions are tailored for the unique demands of in-vehicle networks, providing production-proven controllers that support FlexCAN with CAN-FD, FlexRay, and LIN standards. These solutions, which include SoC subsystems, offer comprehensive frameworks for automotive design projects. Their automotive IP includes critical components like Quad and Octal SPI, UART, and secure AHB fabric, ensuring secure and efficient subsystem integration in various automotive applications, enhancing communication and performance efficiency within vehicles.
The aiWare hardware neural processing unit (NPU) stands out as a state-of-the-art solution for automotive AI applications, bringing unmatched efficiency and performance. Designed specifically for inference tasks associated with automated driving systems, aiWare supports a wide array of AI workloads including CNNs, LSTMs, and RNNs, ensuring optimal operation across numerous applications.\n\naiWare is engineered to achieve industry-leading efficiency rates, boasting up to 98% efficiency on automotive neural networks. It operates across various performance requirements, from cost-sensitive L2 regulatory applications to advanced multi-sensor L3+ systems. The hardware platform is production-proven, already implemented in several products like Nextchip's APACHE series and enjoys strong industry partnerships.\n\nA key feature of aiWare is its scalability, capable of delivering up to 1024 TOPS with its multi-core architecture, and maintaining high efficiency in diverse AI tasks. The design allows for straightforward integration, facilitating early-stage performance evaluations and certifications with its deterministic operations and minimal host CPU intervention.\n\nA dedicated SDK, aiWare Studio, furthers the potential of the NPU by providing a suite of tools focused on neural network optimization, supporting developers in tuning their AI models with fine precision. Optimized for automotive-grade applications, aiWare's technology ensures seamless integration into systems requiring AEC-Q100 Grade 2 compliance, significantly enhancing the capabilities of automated driving applications from L2 through L4.
EW6181 is an IP solution crafted for applications demanding extensive integration levels, offering flexibility by being licensable in various forms such as RTL, gate-level netlist, or GDS. Its design methodology focuses on delivering the lowest possible power consumption within the smallest footprint. The EW6181 effectively extends battery life for tags and modules due to its efficient component count and optimized Bill of Materials (BoM). Additionally, it is backed by robust firmware ensuring highly accurate and reliable location tracking while offering support and upgrades. The IP is particularly suitable for challenging application environments where precision and power efficiency are paramount, making it adaptable across different technology nodes given the availability of its RF frontend.
AndesCore Processors offer a robust lineup of high-performance CPUs tailored for diverse market segments. Employing the AndeStar V5 instruction set architecture, these cores uniformly support the RISC-V technology. The processor family is classified into different series, including the Compact, 25-Series, 27-Series, 40-Series, and 60-Series, each featuring unique architectural advances. For instance, the Compact Series specializes in delivering compact, power-efficient processing, while the 60-Series is optimized for high-performance out-of-order execution. Additionally, AndesCore processors extend customization through Andes Custom Extension, which allows users to define specific instructions to accelerate application-specific tasks, offering a significant edge in design flexibility and processing efficiency.
The CANmodule-III is an advanced CAN controller designed to efficiently manage communication over the Controller Area Network. It features a mailbox architecture with a robust 32 receive and 32 transmit mailboxes, offering full compliance with the CAN2.0B standard. This core is optimized for a variety of high-demanding applications across aerospace, automotive, and industrial sectors. In terms of integration, the CANmodule-III is crafted for seamless incorporation into systems-on-chip, adapting easily to both FPGA and ASIC designs. The architecture, originally based on Bosch’s fundamental CAN design, allows for customizable message filtering, providing flexibility in handling different communication scenarios. The integration of application-specific functions as add-ons means that the core itself remains unaffected, ensuring consistent performance. This CAN controller is also known for its efficient transaction management on the bus, making it a preferred choice for environments where reliability and precision are critical. The CANmodule-III’s system support functions and streamlined processing capabilities see it effectively used in various industry-specific applications where optimized communication is paramount.
The Time-Triggered Protocol (TTP) stands out as a robust framework for ensuring synchronous communication in embedded control systems. Developed to meet stringent aerospace industry criteria, TTP offers a high degree of reliability with its fault-tolerant configuration, integral to maintaining synchrony across various systems. This technology excels in environments where timing precision and data integrity are critical, facilitating accurate information exchange across diverse subsystems. TTTech’s TTP implementation adheres to the SAE AS6003 standard, making it a trusted component among industry leaders. As part of its wide-ranging applications, this protocol enhances system communication within commercial avionic solutions, providing dependable real-time data handling that ensures system stability. Beyond aviation, TTP's applications can also extend into the energy sector, demonstrating its versatility and robustness. Characterized by its deterministic nature, TTP provides a framework where every operation is scheduled, leading to predictable data flow without unscheduled interruptions. Its suitability for field-programmable gate arrays (FPGAs) allows for easy adaptation into existing infrastructures, making it a versatile tool for companies aiming to upgrade their communication systems without a complete overhaul. For engineers and developers, TTP provides a dependable foundation that streamlines the integration process while safeguarding communication integrity.
ISELED represents a breakthrough in automotive lighting with its integration of RGB LED control and communication in a single, smart LED component. This innovative system simplifies lighting design by enabling digital color value input for immediate autonomous color mixing and temperature adjustments, reducing both complexity and cost in vehicles. ISELED operates by implementing a manufacturer-calibrated RGB LED setup suitable for diverse applications, from ambient to functional lighting systems within vehicles. Utilizing a bidirectional communication protocol, ISELED manages up to 4,079 addressable LEDs, offering easy installation and high precision control over individual light characteristics, ideal for creating dynamic and at times synchronized lighting across the automotive interior. This technology ultimately enhances network resilience with features like DC/DC conversion from a standard 12V battery, consistent communication despite power variations, and compatibility with software-free Ethernet bridge systems for streamlined connectivity. This strong focus on reducing production and operational costs, while simultaneously broadening lighting functionality, positions ISELED as a modern solution for smart automotive lighting architectures.
The Digital PreDistortion (DPD) Solution from Systems4Silicon is a comprehensive adaptive technology aimed at improving the efficiency of RF power amplifiers. It is designed to maximize amplifier performance by allowing operation in the non-linear region while significantly reducing distortion. The solution is highly scalable, allowing for resource optimization across bandwidth, performance, and multiple antenna configurations. It is technology-agnostic, supporting various transistor technologies such as LDMOS and GaN, and can be adapted to different amplifier topologies including Doherty configurations. Benefits of the DPD technology include achieving over 50% efficiency improvements when utilized alongside the latest GaN devices, with amplifier distortion improvements of over 45 dB. This IP also supports multi-carrier and multi-standard transmissions, covering a broad array of standards such as 3G, 4G, 5G, DVB, and many more. It is compliant with the O-RAN standard for 7-2x deployments, making it a versatile solution for modern wireless communication systems. Systems4Silicon's DPD solution includes comprehensive integration and performance analysis tools, backed by expert support from experienced radio systems engineers. Designed for both FPGA/SoC and ASIC platforms, it provides a low resource footprint while ensuring maximum efficiency across diverse applications.
The eSi-ADAS suite is a specialized radar co-processor IP designed to enhance the performance and capabilities of radar systems within Advanced Driver Assistance Systems. It is particularly beneficial for applications requiring quick and responsive situational awareness like automotive radar systems, as well as drones and UAVs. This IP package includes radar hardware accelerators, FFT engines, optimized Constant False Alarm Rate (CFAR) processing, and Kalman Filters, making it a versatile and powerful solution for radar signal processing. The modular architecture supports real-time tracking of numerous objects and is optimized for low power and high efficiency.
GNSS Sensor Ltd offers the GNSS VHDL Library, a powerful suite designed to support the integration of GNSS capabilities into FPGA and ASIC products. The library encompasses a range of components, including configurable GNSS engines, Viterbi decoders, RF front-end control modules, and a self-test module, providing a comprehensive toolkit for developers. This library is engineered to be highly flexible and adaptable, supporting a wide range of satellite systems such as GPS, GLONASS, and Galileo, across various configurations. Its architecture aims to ensure independence from specific CPU platforms, allowing for easy adoption across different systems. The GNSS VHDL Library is instrumental in developing cost-effective and simplified system-on-chip solutions, with capabilities to support extensive configurations and frequency bandwidths. It facilitates rapid prototyping and efficient verification processes, crucial for deploying reliable GNSS-enabled devices.
Tyr AI Processor Family is engineered to bring unprecedented processing capabilities to Edge AI applications, where real-time, localized data processing is crucial. Unlike traditional cloud-based AI solutions, Edge AI facilitated by Tyr operates directly at the site of data generation, thereby minimizing latency and reducing the need for extensive data transfers to central data centers. This processor family stands out in its ability to empower devices to deliver instant insights, which is critical in time-sensitive operations like autonomous driving or industrial automation. The innovative design of the Tyr family ensures enhanced privacy and compliance, as data processing stays on the device, mitigating the risks associated with data exposure. By doing so, it supports stringent requirements for privacy while also reducing bandwidth utilization. This makes it particularly advantageous in settings like healthcare or environments with limited connectivity, where maintaining data integrity and efficiency is crucial. Designed for flexibility and sustainability, the Tyr AI processors are adept at balancing computing power with energy consumption, thus enabling the integration of multi-modal inputs and outputs efficiently. Their performance nears data center levels, yet they are built to consume significantly less energy, making them a cost-effective solution for implementing AI capabilities across various edge computing environments.
The Network Protocol Accelerator Platform (NPAP) is engineered to accelerate network protocol processing and offload tasks at speeds reaching up to 100 Gbps when implemented on FPGAs, and beyond in ASICs. This platform offers patented and patent-pending technologies that provide significant performance boosts, aiding in efficient network management. With its support for multiple protocols like TCP, UDP, and IP, it meets the demands of modern networking environments effectively, ensuring low latency and high throughput solutions for critical infrastructure. NPAP facilitates the construction of function accelerator cards (FACs) that support 10/25/50/100G speeds, effectively handling intense data workloads. The stunning capabilities of NPAP make it an indispensable tool for businesses needing to process vast amounts of data with precision and speed, thereby greatly enhancing network operations. Moreover, the NPAP emphasizes flexibility by allowing integration with a variety of network setups. Its capability to streamline data transfer with minimal delay supports modern computational demands, paving the way for optimized digital communication in diverse industries.
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.
Bluespec's Portable RISC-V Cores are designed to bring flexibility and extended functionality to FPGA platforms such as Achronix, Xilinx, Lattice, and Microsemi. They offer support for operating systems like Linux and FreeRTOS, making them versatile for various applications. These cores are accompanied by standard open-source development tools, which facilitate seamless integration and development processes. By utilizing these tools, developers can modify and enhance the cores to suit their specific needs, ensuring a custom fit for their projects. The portable cores are an excellent choice for developers looking to deploy RISC-V architecture across different FPGA platforms without being tied down to proprietary solutions. With Bluespec's focus on open-source, users can experience freedom in innovation and development without sacrificing performance or compatibility.
aiSim 5 represents a pivotal advancement in the simulation of automated driving systems, facilitating realistic and efficient validation of ADAS and autonomous driving components. Designed to exceed conventional expectations, aiSim 5 combines high-fidelity sensor and environment simulation with an AI-based digital twin concept to deliver unparalleled simulation accuracy and realism. It is the first simulator to be certified at ISO 26262 ASIL-D level, offering users the utmost industry trust.\n\nThe simulated environments are rooted in physics-based sensor data and cover a wide spectrum of operational design domains, including urban areas and highways. This ensures the simulation tests AD systems under diverse and challenging conditions, such as adverse weather events. aiSim 5's modular architecture supports easy integration with existing systems, leveraging open APIs to ensure seamless incorporation into various testing and continuous integration pipelines.\n\nNotably, aiSim 5 incorporates aiFab's domain randomization to create extensive synthetic data, mirroring real-world variances. This feature assists in identifying edge cases, allowing developers to test system responsiveness in rare but critical scenarios. By turning the spotlight on multi-sensor simulation and synthetic data generation, aiSim 5 acts as a powerful tool to accelerate the development lifecycle of ADAS and AD technologies, fostering innovation and development efficiency.\n\nThrough its intuitive graphical interface, aiSim 5 democratizes access to high-performance simulations, supporting operating systems like Microsoft Windows and Linux Ubuntu. This flexibility, coupled with the tool’s compatibility with numerous standards such as OpenSCENARIO and FMI, makes aiSim an essential component for automotive simulation projects striving for precision and agility.
The Ncore Cache Coherent Interconnect from Arteris is engineered to overcome challenges associated with multicore SoC designs. It delivers high-bandwidth, low-latency interconnect fabric enhancing communication efficiency across various SoC components and multiple dies. Designed to ensure reliable performance and scalability, this coherent NoC addresses complex tasks by implementing heterogeneous coherency, and it is scalable from small embedded systems to extensive multi-die designs. Ncore promotes effective cache management, providing full coherency for processors and I/O coherency for accelerators. It supports various coherency protocols including CHI-E and ACE, and comes with ISO 26262 certification, meeting stringent safety standards in automotive environments. The inherent AMBA support allows seamless integration with existing and new SoC infrastructures, enhancing data handling efficiency. By offering automated generation of diagnostic analysis and fault modes, Ncore aids developers in creating secure systems ready for advanced automotive and AI applications, thereby accelerating their time-to-market. Its configurability and extensive protocol support position it as a trusted choice for industries requiring flexible and robust system integration solutions.
Dyumnin's RISCV SoC is a versatile platform centered around a 64-bit quad-core server-class RISCV CPU, offering extensive subsystems, including AI/ML, automotive, multimedia, memory, cryptographic, and communication systems. This test chip can be reviewed in an FPGA format, ensuring adaptability and extensive testing possibilities. The AI/ML subsystem is particularly noteworthy due to its custom CPU configuration paired with a tensor flow unit, accelerating AI operations significantly. This adaptability lends itself to innovations in artificial intelligence, setting it apart in the competitive landscape of processors. Additionally, the automotive subsystem caters robustly to the needs of the automotive sector with CAN, CAN-FD, and SafeSPI IPs, all designed to enhance systems connectivity within vehicles. Moreover, the multimedia subsystem boasts a complete range of IPs to support HDMI, Display Port, MIPI, and more, facilitating rich audio and visual experiences across devices.
A trailblazer in high-speed rail connectivity, LightningBlu offers a groundbreaking, track-to-train multi-gigabit mmWave solution. This technology is renowned for its seamless integration with train networks, providing stable and fast connections crucial for high-speed transport. LightningBlu operates efficiently over a rail-friendly frequency range from 57-71 GHz and delivers an impressive data throughput of up to 3.5 Gbps. The system comprises both trackside and train-top nodes, each featuring innovative two-sector radios to ensure continuous, dynamic connection between the train and the trackside infrastructure. The design includes components qualified for rugged rail environments, promising extended service life and low maintenance needs. The solution significantly boosts operational efficiency for rail networks, being deployed in key infrastructures like South Western Railways and Caltrain in Silicon Valley. Versatile and resilient, LightningBlu adapts to varied complexities found in high-speed transport contexts. It communicates data faster than 5G while maintaining lower power consumption than traditional mobile networks, ensuring a superior commuter experience through its reliability and speed.
The L5-Direct GNSS Receiver from oneNav, Inc. is a revolutionary product designed to engage directly with L5-band signals, a step away from the reliance on older L1 signals. This GNSS receiver captures signals directly in the L5-band, providing a superior solution that addresses the growing issue of GPS signal jamming, creating significant value for users including defense agencies and OEMs. It boasts unique features such as multi-constellation support, which allows users to access over 70 satellite signals from major constellations like GPS, Galileo, QZSS, and BeiDou. The L5-Direct technology integrates a single RF chain, simplifying design and improving efficiency, making it ideal for applications where space and cost are critical. The technology employs machine learning algorithms to mitigate multipath errors, an innovative approach that elevates accuracy by differentiating between direct and reflected signals in challenging terrains. This level of precision and independence from legacy signals captures the essence of what oneNav stands for. Additionally, the receiver's power efficiency is unmatched, thanks to the Application Specific Array Processor (ASAP), which manages processing speed to conserve energy. Its design is particularly advantageous for wearables, IoT devices, and systems requiring constant location tracking, ensuring a minimal power footprint while delivering consistent, accurate data. The L5-Direct GNSS Receiver is also built to withstand disruptions, with significant resilience to jamming and improved consistency in GPS-challenged environments.
The Advanced Flexibilis Ethernet Controller (AFEC) is a sophisticated Ethernet controller IP that offers triple-speed operation for 10/100/1000 Mbps Ethernet networks. Capable of integrating seamlessly with programmable hardware and ASICs, the controller is ideal for crafting Ethernet Network Interface Controllers that require high-speed data handling and minimal CPU workload. AFEC employs advanced features like bus master DMA transfer and scatter-gather capabilities to optimize data transactions, significantly reducing the processing demands on host CPUs. This feature set enables gigabit data transfer while using less powerful CPUs, broadening its application scope across various industrial and commercial sectors. Additional functionalities include full-duplex operation, time stamping of packets, and support for both copper and fiber Ethernet connections, enhancing its utility in precise network setups. Built-in IEEE 1588 Precision Time Protocol support ensures accurate time synchronization, making AFEC a valuable tool for network applications needing rigorous timing precision.
The TSN Switch for Automotive Ethernet is designed to facilitate real-time data transmission across automotive networks. It supports the latest standards for time-sensitive networking, ensuring minimal latency and maximum data throughput. The switch integrates seamlessly into existing automotive infrastructure, providing reliable and efficient connectivity solutions for modern vehicles. Enhancing the communication framework, this switch is optimized for vehicular environments, accommodating complex data streams and ensuring robustness even in harsh conditions. Its design is meticulously detailed to support advanced automotive protocols, providing a stable platform for future automotive innovations. The switch enables safe and synchronized data exchange, vital for the growing demands of connected vehicles. With a focus on cost-efficiency and deployment flexibility, it is an essential component for building the next generation of intelligent transportation systems.
ArrayNav is a groundbreaking GNSS solution utilizing patented adaptive antenna technology, crafted to provide automotive Advanced Driver-Assistance Systems (ADAS) with unprecedented precision and capacity. By employing multiple antennas, ArrayNav substantially enhances sensitivity and coverage through increased antenna gain, mitigates multipath fading with antenna diversity, and offers superior interference and jamming rejection capabilities. This advancement leads to greater accuracy in open environments and markedly better functionality within urban settings, often challenging due to signal interference. It is designed to serve both standalone and cloud-dependent use cases, thereby granting broad application flexibility.
Tower Semiconductor's SiGe BiCMOS technology is designed to enhance radio frequency (RF) performance, featuring low noise and low power consumption which are crucial for high-frequency applications. This technology supports the production of advanced RF components that are widely used in wireless communication systems, ensuring efficiency and reliability. The BiCMOS technology effectively combines Bipolar and CMOS processes, allowing for high-speed capability alongside low power operation. This makes it particularly appealing in the development of RF circuits where both precision and power management are of concern. Its scalability across various process nodes also contributes to tailored solutions across diverse applications. SiGe BiCMOS demonstrates excellence in RF signal processing, making it indispensable for next-generation wireless and broadband multimedia devices. Its adaptability to integrate with other process technologies further highlights its strategic role in advancing semiconductor solutions for comprehensive communication infrastructures.
The CAN 2.0/CAN FD Controller offered by Synective Labs is a comprehensive CAN controller suitable for integration into both FPGAs and ASICs. This controller is fully compliant with the ISO 11898-1:2015 standard, supporting both traditional CAN and the more advanced CAN FD protocols. The CAN FD protocol enhances the original CAN capabilities by transmitting payloads at increased bitrates up to 10 Mbit/s and accommodating longer payloads of up to 64 bytes compared to the standard 8 bytes. This controller integrates seamlessly with a variety of FPGA devices from leading manufacturers such as Xilinx, Altera, Lattice, and Microsemi. It supports native bus interfaces including AXI, Avalon, and APB, making it versatile and highly compatible with various processing environments. For those deploying System on Chip (SOC) type FPGAs, the controller offers robust processor integration options, making it an ideal choice for complex applications. A standout feature of this IP is its focus on diagnostics and CAN bus debugging, which makes it particularly beneficial for applications like data loggers. These diagnostic features can be selectively disabled during the build process to reduce the controller's footprint for more traditional uses. With its low-latency DMA, interrupt rate adaptation, and configurable hardware buffer size, this CAN controller is engineered for high efficiency and flexibility across different applications.
hellaPHY Positioning Solution is an advanced edge-based software that significantly enhances cellular positioning capabilities by leveraging 5G and existing LTE networks. This revolutionary solution provides accurate indoor and outdoor location services with remarkable efficiency, outperforming GNSS in scenarios such as indoor environments or dense urban areas. By using the sparsest PRS standards from 3GPP, it achieves high precision while maintaining extremely low power and data utilization, making it ideal for massive IoT deployments. The hellaPHY technology allows devices to calculate their location autonomously without relying on external servers, which safeguards the privacy of the users. The software's lightweight design ensures it can be integrated into the baseband MCU or application processors, offering seamless compatibility with existing hardware ecosystems. It supports rapid deployment through an API that facilitates easy integration, as well as Over-The-Air updates, which enable continuous performance improvements. With its capability to operate efficiently on the cutting edge of cellular standards, hellaPHY provides a compelling cost-effective alternative to traditional GPS and similar technologies. Additionally, its design ensures high spectral efficiency, reducing strain on network resources by utilizing minimal data transmission, thus supporting a wide range of emerging applications from industrial to consumer IoT solutions.
Focused on automotive applications and certified for ISO 26262 Functional Safety, the RISC-V CPU IP NA Class is a specialized offering for high-stakes environments such as vehicular systems. Its design is tailored to meet the rigorous safety standards required in the automotive industry, supporting ASIL-B and ASIL-D safety levels. The NA Class IP combines robust functionality with advanced safety measures, providing a reliable solution for implementing safety-critical tasks in next-generation automotive designs. With scalability at its core, it supports advanced RISC-V extensions and user-defined instruction sets, ensuring the adaptability of the IP to meet evolving industry standards and custom specifications. Through its comprehensive support of safety and performance features, the NA Class stands as a reliable building block for developers focusing on creating secure, high-performance automotive systems. Its cutting-edge design ensures it can handle the sophisticated demands of modern vehicles, from engine management to advanced driver-assistance systems (ADAS).
The 8b/10b Decoder from Roa Logic is an intricate implementation of the 8b10b encoding/decoding standard developed by Widmer and Franaszek. This decoder is equipped with features like automatic comma detection and the capability to recognize K28.5 code groups, making it a robust choice for error-checking applications where data integrity is of paramount importance.
The RFicient chip stands out for its ultra-low power consumption and remarkable efficiency, making it particularly suitable for Internet of Things (IoT) applications. This chip is designed to operate in energy-constrained environments, delivering high performance while maintaining minimal energy usage. It is engineered to facilitate long-term, maintenance-free operations in IoT devices, which are often deployed in remote or hard-to-reach locations. With a focus on sustainability, the RFicient chip significantly reduces energy consumption, extending the battery life of IoT devices. Its compact and robust design allows for seamless integration into various IoT systems, from smart homes to industrial IoT networks, providing reliable connectivity and data transmission under diverse environmental conditions. This chip not only supports the efficient gathering and processing of IoT data but also furthers ecological goals by reducing the carbon footprint associated with IoT deployments.
The PCD03D Turbo Decoder is adept at handling multiple state decoding for standards such as DVB-RCS and IEEE 802.16 WiMAX. Its core design features an 8-state duobinary decoding structure, facilitating precise and quick signal deconstruction. Additionally, the optional inclusion of a 64-state Viterbi decoder enhances versatility and performance in various environments. This decoder is tailored for applications where agility and high data throughput are critical, making it an invaluable asset in wireless communication infrastructures. The decoder’s architecture supports expansive VHDL core integration, providing durable solutions across FPGA platforms.
The SafeIP SinglePHY is a leading-edge solution for the development of Safe Communication Technology, specifically designed with a data rate of 100 MBit/s. Its small footprint and ultra-low power consumption make it ideal for a wide range of applications. This product is equipped with capabilities such as Open Alliance TC10 Sleep/Wake, streaming of debug data, and transmission interruption to ensure safety states. This innovative solution also flags potential safety violations via a safety interrupt and supports CRC calculation. Furthermore, it establishes an Ethernet physical layer link-up and transmits Ethernet data efficiently between MII and MDI interfaces. The SafeIP SinglePHY can diagnose cable faults and offers a Logic Built-In Self Test (LBIST) for assurance, with EMC compliance according to Open Alliance standards. The architecture supports Automotive Grade 1 and is built on 22FDX technology. The product is optimized with Media-Independent Interface (MII) and APB interfaces, alongside support for IEEE 1500, reinforcing its reliability. Typical power consumption is a remarkably low 34mW, making it both secure and efficient for industries demanding robust safety measures.
Specializing in Network-on-Chip (NoC)-based SoC integration, this IP leverages coherent and non-coherent NoC subsystems, crucial for building scalable multi-chip solutions. By integrating several NoC platforms, it offers a robust framework for developing SoCs with enhanced connectivity and performance.
This Complete RF Transceiver is engineered to operate efficiently within the 433, 868, and 915 MHz ISM bands, making it ideal for industrial IoT and smart metering applications. The transceiver supports extensive data rates ranging from 1.2 k to 500 kbps, adapting to various communication requirements. Built to comply with IEEE 802.15.4-2015 standards, it offers robust wireless communication with minimal interference. The transceiver is designed using low-power technology to ensure long-lasting performance in battery-operated devices, providing competitive advantage in energy-sensitive applications.
This technology represents a significant innovation in the field of wireless energy transfer, allowing for the efficient transmission of power without physical connections or radiation. By leveraging magnetic resonance, this non-radiative energy transfer system can power devices over distances with high efficiency. It's designed to be safe and environmentally friendly, avoiding the pitfalls of electromagnetic radiation while maintaining a high level of power transfer efficiency. The technology finds its applications in various sectors, including consumer electronics, automotive, and industrial applications where it provides a seamless and reliable solution to power transfer needs. The system's capability to transfer power efficiently without contact makes it ideal for scenarios where traditional power connections might be impractical or inconvenient, enabling new levels of convenience and flexibility for users. Designed to integrate smoothly with existing infrastructure, this energy transfer system can significantly reduce reliance on traditional charging methods, paving the way for more innovative and sustainable energy solutions. Furthermore, the system's architecture is geared towards scalability and adaptability, making it suitable for a wide range of devices and use cases.
The ARINC 664 (AFDX) End System is a specialized module developed to implement an Avionics Full-Duplex Switched Ethernet (AFDX) network. Conforming to ARINC 664 Part 7 specifications, this system is pivotal in avionics communication, offering reliable full-duplex communication. The system is designed to enhance data throughput and ensure deterministic transmission, critical for real-time avionic applications. It is an essential solution for platforms requiring robust data exchange across aviation networks, leveraging high fault-tolerance and redundancy.
Time-Sensitive Networking (TSN) is designed to address the ever-growing needs of modern industrial and automotive digital ecosystems. Leveraging precise time synchronization and deterministic data delivery, TSN ensures that data packets are transmitted with minimal latency and maximum reliability. This technology is particularly beneficial for industries where real-time operations and data accuracy are paramount, such as automotive and industrial automation sectors. TTTech's TSN capabilities include a comprehensive range of chip designs that can be incorporated into microcontrollers and sophisticated systems-on-chip (SoC). These designs are compatible with IEEE standards for features such as frame preemption and redundancy, allowing for sophisticated network constructs that meet specific industry needs. With hundreds of consumer and enterprise products integrated with TSN technology, TTTech maintains a leading position in standardizing and implementing this forward-looking networking framework. Beyond its operational reliability, TSN offers significant advantages in scalability and flexibility, making it suitable for evolving technology landscapes. The compatibility of this technology with existing infrastructures enhances the adoption process, providing seamless integration and reducing potential system disruptions. By supporting various industry-standard features, TTTech’s TSN solutions ensure continuous, precise, and effective data management across connected industrial systems.
The PCE04I Inmarsat Turbo Encoder is engineered to optimize data encoding standards within satellite communications. Leveraging advanced state management, it enhances data throughput by utilizing a 16-state encoding architecture. This sophisticated development enables efficient signal processing, pivotal for high-stakes communication workflows. Furthermore, the PCE04I is adaptable across multiple frameworks, catering to diverse industry requirements. Innovation is at the forefront with the option of integrating additional state Viterbi decoders, tailoring performance to specific needs and bolstering reliability in communications.
The SafeIP DualPHY is designed to cater to both 100 and 1000 MBit/s bandwidth requirements, dynamically engaging with these modes through autonegotiation with partner devices. Known as a customer favorite, this product assures safety in communication technologies implemented in automotive applications, equipped with advanced EMC compliance. The DualPHY operates on a typical power consumption of 250mW with a macro size of 1.800mm by 0.850mm, suited for demanding environments requiring robust and efficient operation. It implements functionalities such as Open Alliance TC10 Sleep/Wake, and advanced diagnostic features to detect cable defects. Offering compliance with Automotive Grade 1 DRC, this IP ensures the delivery of two media-dependent interfaces tailored with distinct capabilities while maintaining a single media-independent interface for effective communication. Through its stability in safety-critical environments, the DualPHY reinforces Siliconally’s commitment to pushing the safety envelope in communication solutions.
The GDP-XL Design Management System by IC Manage is a high-performance, global solution designed for seamless design and IP management. It excels in providing a robust framework for collaboration across single and multiple design sites, integrating teams in different locations securely and efficiently. This system is particularly valued for its ability to support rigorous control over databases, ensuring the accuracy and consistency required for critical RFIC design processes. With GDP-XL, companies can manage their design data more reliably, addressing challenges commonly faced in semiconductor design environments. It offers enhanced productivity through unrivaled scalability and flexibility, allowing organizations to adapt to ever-changing design requirements without compromise. The system's advanced capabilities are leveraged by top-tier semiconductor companies to maintain a competitive edge in a fast-paced industry. As the industry's leading design data and IP management system, GDP-XL also supports innovative collaboration patterns, enabling seamless sharing and revision control among global teams. Its robust architecture facilitates the integration of various methodologies, aiding companies in efficiently navigating complex designs and maintaining meticulous tracking of their IP assets.
Korusys offers a state-of-the-art SMPTE 2059-2 solution designed to provide precise synchronization of video and audio signals using an FPGA platform. This system is engineered for professional broadcast environments requiring high accuracy and low latency AV content alignment over IP networks. By leveraging IEEE1588v2 compliant software, the solution guarantees exact timing alignment and timecode generation for seamless integration into the broadcast workflow. The system's adaptability allows it to cater to varying framerate requirements, supported by a comprehensive API for configuration and control. With its compact design, it is easy to deploy and integrate, making it an essential tool for modern broadcasting operations.
The CANsec Controller Core offers a secure and robust solution for Controller Area Network (CAN) communications. Built with advanced security protocols, it ensures the protection of data within automotive systems. This core supports both traditional and new-generation CAN and CAN FD protocols, providing flexibility and enhanced functionality in vehicle networks. Designed to meet stringent automotive safety standards, the controller core integrates seamlessly with existing systems, adding an additional layer of security. Engineers can easily implement this solution to guard against malicious intrusions and data tampering, ensuring reliable communication paths in automotive environments. Its architecture supports high-speed data processing while maintaining low power usage, vital for modern applications that demand efficiency and reliability. Automotive developers will find this core an invaluable asset in creating secure, interconnected vehicle systems.
The Korusync IEEE1588 PCIe Card from Korusys is specifically manufactured for high-precision synchronization tasks in telecommunication networks. Compliant with PTPv2 and telecom profiles, this card offers an Ethernet port and SMA connectivity for enhanced accuracy. It generates a software clock with exceptionally accurate timing, providing precise synchronization ideal for time-critical applications. Although the product is now limited in availability for small purchases, it remains an invaluable tool for large-scale operations seeking dependable synchronization solutions.
The SMS OC-3/12 Transceiver Core is engineered for SONET/SDH applications, providing comprehensive support for OC-3 and OC-12 data rates. This core is designed with a deep sub-micron single poly CMOS architecture to ensure compliance with ANSI, Bellcore, and ITU-T specifications for jitter tolerance and generation.\n\nFeaturing innovative architecture, this transceiver core integrates high-frequency PLLs with on-chip loop filters, reducing external component requirements and simplifying design processes. Proprietary advanced signal processing techniques enhance signal integrity, mitigating external and PCB noise issues that commonly affect traditional transceiver designs.\n\nThe core is optimized for multiport SOC designs, allowing for easy process migration and adaptability for new application domains. It includes custom configurable serializer-deserializer (SERDES) options, further enhancing its suitability for complex system integrations and high-performance requirements in networking infrastructure.
This ARINC 429 Receiver facilitates the reliable acquisition of data transmitted across ARINC 429 compliant bus systems. Implemented according to the stringent ARINC 429 Specification, it is a cornerstone for ensuring accurate data transfer in avionics applications. The receiver's robust design manages high-speed data streams effectively, thus maintaining communication integrity across various aviation systems. By providing seamless integration into existing infrastructures, this receiver aids in sustaining resilient and precise data reading crucial for aeronautical operations.
ZIA Stereo Vision is designed to offer superior depth perception and object detection by employing advanced stereo vision algorithms. This system enhances the capabilities of autonomous vehicles and drones, providing precise imaging for real-time decision-making applications. Built with a focus on accuracy and computational efficiency, it supports a range of stereoscopic camera systems, enabling better navigation and environmental interaction.
Flexibilis Redundant Switch (FRS) is an innovative Layer-2 Ethernet switch IP core, supporting both High-Availability Seamless Redundancy (HSR) and Parallel Redundancy Protocol (PRP). This triple-speed switch operates on a gigabit full-duplex mode across all ports, making it a high-performing solution for Ethernet redundancy demands in industrial automation environments. The FRS IP core integrates transparent clock functionality based on the IEEE 1588 Precision Time Protocol (PTP), essential for time-sensitive networking. As an FPGA implementation, FRS can be utilized in both gigabit and 100Mbps rings without the need for separate RedBox devices, which allows for streamlined and cost-effective setup. It supports various Ethernet interface types, including copper and fiber, and provides packet forwarding at wire-speed with advanced filtering and prioritization capabilities. FRS can be employed in multitude configurations—from three to eight ports—suitable for diverse applications ranging from simple end-node connections to more complex network architectures. Its adaptability makes it an ideal choice for enhancing network reliability where time synchronization and redundancy are critical.
PhantomBlu represents Blu Wireless's state-of-the-art mmWave technology tailored for military and defense use. This advanced solution supports tactical communication between vehicles, whether on land, sea, or air, by leveraging a stealthy mesh network capable of running applications and IP networking over an anti-jam resistant infrastructure. The PhantomBlu network offers flexibility and scalability to meet various operational demands within defense environments, from securing critical infrastructure to enabling convoy communications and integrating airborne systems. Its ability to provide high bandwidth in real-time ensures communication is reliable and secure, even in complex and hostile environments. With features like 10x data rates compared to Wi-Fi and 5G, reduced size, weight, and power requirements, and future-proof scalability, PhantomBlu is built for seamless integration with existing military systems. The solution further offers long-range communication up to 4km, incorporating advanced features like antenna beamforming for improved signal processing, making it a robust component for military networks.
The ARINC 429 Transmitter is engineered to handle data transmission within ARINC 429 bus networks efficiently. Aligning with ARINC standards, this transmitter ensures the precise conveyance of avionics data crucial to the functioning of complex aircraft systems. Its design focuses on reliably interfacing with various ARINC 429 systems, maintaining high communication integrity. It is essential for manufacturers and integrators looking to enhance data interaction within aviation platforms, offering a robust solution for critical operability.
For aviation and space applications, TTTech offers Deterministic Ethernet technology that ensures reliable and predictable data flow in safety-critical environments. A significant feature of this technology is its ability to offer certifiable Ethernet chip designs that are versatile and applicable across various platforms. As part of its adaptability, the technology complies with industry standards such as ARINC 664 part 7, supporting Time-Triggered Ethernet (TTEthernet) and Time Sensitive Networking (TSN) connectivity. Suitable for use in highly demanding environments, this solution maintains critical system functions under stringent conditions while ensuring a high level of performance and safety. In addition to its application in aviation, Deterministic Ethernet is well-suited for harsh environments where reliability is paramount. Utilizing TTEthernet, it incorporates triple-redundant network frameworks that cater to dual fault-tolerance requirements necessary for human spaceflight missions. Notably, this technology has been successfully implemented in the NASA Orion spacecraft, highlighting its capability and significance in critical aerospace operations. TTTech's Deterministic Ethernet can be integrated into various end systems or more complex configurations, aligning with the Time-Triggered Ethernet ECSS engineering standard. Given its integration efficacy, this technology supports seamless use across multiple platforms, enhancing both legacy systems and new infrastructures. For operators in aerospace and heavy industries, it allows for effective and comprehensive data exchange even in the most extreme conditions.
ARDSoC extends the capabilities of DPDK to ARM-based SoCs, enabling efficient packet processing that bypasses the traditional Linux network stack. This IP core saves valuable ARM processor cycles and integrates smoothly with distributed network applications, especially those relying on containers and embedded protocol bridges. The key benefit of ARDSoC is its ability to drastically reduce power consumption, latency, and the overall TCO when transitioning from x86 architectures. This is achieved by optimizing the ARM CCI-400 Cache performance and utilizing zero copy DPDK coherent memory structures. The IP supports popular ARM architectures like A53 and A72 and can achieve up to 64 Gbps throughput under nominal operating conditions. ARDSoC is particularly useful for cloud-edge devices requiring robust network processing capabilities. Its compatibility with existing DPDK programs ensures developers can easily migrate and integrate their applications with minimal modifications, supported by Atomic Rules' commitment to innovation and real-world application needs.
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