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.
Silvaco's Automotive IP offerings provide solutions specifically designed to meet the demanding requirements of automotive applications. This suite of IP is instrumental in paving the way for innovations in the automotive industry, supporting a variety of systems that require robustness, security, and efficiency. Silvaco’s Automotive IP solutions are integrated to enhance the connectivity and processing power needed for advanced automotive electronics.\n\nThese solutions deliver high reliability and support for critical safety standards, making them suitable for a wide range of automotive applications including ADAS (Advanced Driver Assistance Systems), infotainment systems, and in-vehicle networks. Silvaco Automotive IP is developed to be resilient to the harsh automotive operating environments, ensuring that electronic subsystems operate effectively under varied conditions.\n\nWith features like automotive industry protocol compliance and secure network communications, Silvaco Automotive IP helps streamline the development process, improving the safety and functionality of next-generation vehicles. Their IP products ensure the highest level of integration with existing automotive systems, facilitating smoother transitions in technology upgrades and new implementations.
Time-Triggered Ethernet (TTEthernet) is an advanced form of Ethernet designed for applications that require high levels of determinism and redundancy, particularly evident in aerospace and space projects. TTEthernet offers an integrated solution for complex systems that mandates reliable time-sensitive operations, such as those required in human spaceflight where triple redundancy is crucial for mission-critical environments. This technology supports dual fault-tolerance by using triple-redundant networks, ensuring that the system continues to function if failures occur. It's exceptionally suited for systems with rigorous safety-critical requirements and has been employed in ventures like NASA's Orion spacecraft thanks to its robust standard compliance and support for fault-tolerant synchronization protocols. Adhering to the ECSS engineering standards, TTEthernet facilitates seamless integration and enables bandwidth efficiencies that are significant for both onboard and ground-based operations. TTTech's TTEthernet solutions have been further complemented by their proprietary scheduling tools and chip IP offerings, which continue to set industry benchmarks in network precision and dependability.
The CT25205 is a robust digital IP core designed for IEEE 802.3cg 10BASE-T1S Ethernet Physical Layer. It includes PMA, PCS, and PLCA Reconciliation Sublayer blocks, enhancing compatibility with standard IEEE MACs via the MII. Featuring a fully synthesizable Verilog design, it is deployable on standard cells and FPGAs. With integrated PLCA RS, this IP provides advanced features without necessitating additional extensions, making it a vital component for Zonal Gateways SoCs.
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.
aiWare is engineered as a high-performance neural processing unit tailored for automotive AI applications, delivering exceptional power efficiency and computational capability across a broad spectrum of neural network tasks. Its design centers around achieving the utmost efficiency in AI inference, providing flexibility and scalability for various levels of autonomous driving, from basic L2 assistance systems to complex L4 self-driving operations. The aiWare architecture exemplifies leading-edge NPU efficiencies, reaching up to 98% across diverse neural network workloads like CNNs and RNNs, making it a premier choice for AI tasks in the automotive sector. It boasts an industry-leading 1024 TOPS capability, making it suitable for multi-sensor and multi-camera setups required by advanced autonomous vehicle systems. The NPU's hardware determinism aids in achieving high ISO 26262 ASIL B certification standards, ensuring it meets the rigorous safety specifications essential in automotive applications. Incorporating an easy-to-integrate RTL design and a comprehensive SDK, aiWare simplifies system integration and accelerates development timelines for automotive manufacturers. Its highly optimized dataflow and minimal external memory traffic significantly enhance system power economy, providing crucial benefits in reducing operational costs for deployed automotive AI solutions. Vibrant with efficiency, aiWare assures OEMs the capabilities needed to handle modern automotive workloads while maintaining minimal system constraints.
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.
Introducing the CANmodule-III, a highly advanced Controller Area Network (CAN) controller that offers enhanced communication capabilities for embedded systems. This document outlines the advanced features of CANmodule-III, which includes support for multiple mailboxes and compatibility with CAN 2.0B standards. Designed with flexible interface options, it optimizes embedded communication performance in various automation and control applications. The CANmodule-III features robust data handling capabilities, making it ideal for automotive and industrial control systems where reliable data transmission is critical. With support for sophisticated error checking and message filtering, this controller ensures data integrity across complex systems. Built for integration across a wide array of systems, the CANmodule-III offers unparalleled reliability and flexibility. It is a crucial component for any application requiring robust, high-speed data exchange on a CAN bus, further enhanced by its capability to operate under varying environmental conditions.
ISELED is an innovative technology that revolutionizes automotive interior lighting by integrating all necessary hardware functions for fully software-defined lighting. It features smart RGB LEDs which are pre-calibrated by manufacturers, ensuring consistent color temperature and exceptional lighting quality. This technology simplifies the integration process by allowing users to send simple digital commands to control the color output of the LEDs without needing additional complex setups for color mixing and temperature compensation. ISELED is equipped to handle synchronous lighting displays and dynamic effects across vehicle interiors. The connectivity aspect of ISELED is enhanced by its ILaS protocol, allowing direct cable connections between lighting systems and enabling efficient power conversion. This makes it suitable for applications requiring resilience in communication, despite potential power failures on the board. With capabilities for bridging data over Ethernet, ISELED supports centralized control and synchronization from a vehicle's ECU.
CT25203 is an Analog Front-End IP core compliant with IEEE 802.3cg standard for 10BASE-T1S applications. It is part of Canova Tech's strategic offerings in analog domain, enhancing high-performance communication. The IP supports integral interoperability with digital PHYs, such as the CT25205, and is designed to operate with a high-voltage process technology, ensuring exceptional electromagnetic compatibility (EMC) performance. Its features facilitate reliable communication for industrial and automotive applications, proven in diverse 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.
The Time-Triggered Protocol (TTP) is a technology that offers deterministic communication for distributed real-time systems. This protocol is vital in applications where timing precision is crucial, such as in the aerospace industry, ensuring tasks are executed at precisely scheduled intervals. TTP is known for its reliability, configuring data communication parameters by defining send/receive slots within a network, and is adaptable for use in high-integrity systems like those found in avionics and deep space missions. This protocol underpins systems where fault-tolerance and coordination are necessary across diverse nodes within the network, offering a redundant communication pathway that safeguards against data loss. With this protocol, TTTech ensures that methodologies for verification and scheduling are incorporated into the systems, facilitating smoother qualification and certification in civil aviation projects. TTP is also SAE AS6003 compliant, meeting the stringent requirements needed for critical applications and ensuring compatibility with various forms of systems, including both integrated circuits and more complex system-on-chip arrangements. Widely acknowledged in industries demanding high reliability, TTP continues to support industry needs for robust protocol solutions.
Systems4Silicon's Digital PreDistortion (DPD) Solution is designed to significantly enhance the power efficiency of RF power amplifiers. This subsystem is complete and adaptive, providing a scalable solution that transcends the limitations typical of vendor-specific dependencies. On account of its universal compatibility, this IP core can be compiled for any ASIC or FPGA/SoC platform, serving as an all-encompassing solution suited for a diverse array of wireless communication systems such as 5G and multi-carrier setups. One of the standout features of the DPD technology is its capability to improve transmission bandwidth efficiently, offering scalability for bandwidths of up to 1 GHz or more. This positions the DPD solution as a forward-thinking technology, catering to modern demands for higher data rates and broader communication ranges. The adaptive nature of the solution ensures that it can modulate performance parameters in real-time, responding dynamically to varying operational conditions and system requirements, thereby maximizing amplifier efficiency across different setups. In operational terms, the DPD Solution is field-proven, reflecting its reliability and performance in real-world applications. It represents a versatile technology that integrates seamlessly with existing systems, delivering a robust enhancement to power amplifier efficiency while maintaining high compatibility with emerging communication standards. The flexibility of this technology makes it a vital asset in the infrastructure of contemporary wireless networks, ensuring smooth and efficient signal transmission.
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.
The CANmodule-IIIx extends the functionality of the standard CANmodule-III, offering more flexibility with additional mailboxes for both transmitting and receiving messages. This allows for an even higher level of message management, making it an ideal choice for complex systems requiring extensive CAN bus communication. Specifically designed for integration into larger systems, the CANmodule-IIIx supports 32 receive and 32 transmit mailboxes, each capable of handling intricate communication tasks with ease. The architecture supports quick and efficient data handling, ensuring minimal latency in communication exchanges, which is vital for time-critical applications. Moreover, this module supports sophisticated error management and customized message filtering, enhancing the reliability of data transmission in industrial and automotive environments. The CANmodule-IIIx continues to support compliance with CAN 2.0B protocols, ensuring it fits seamlessly into existing CAN networks without requiring extensive modifications.
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.
The Ncore Cache Coherent Interconnect from Arteris provides a quintessential solution for handling multi-core SoC design complications, facilitating heterogeneous coherency and efficient caching. It is distinguished by its high throughput, ensuring reliable and high-performance system-on-chips (SoCs). Ncore's configurable fabric offers designers the ability to establish a multi-die, multi-protocol coherent interconnect where emerge cutting-edge technologies like RISC-V can seamlessly integrate. This IP’s adaptability and scalable design unlock broader performance trajectories, whether for small embedded systems or extensive multi-billion transistor architectures. Ncore's strength lies in its ability to offer ISO 26262 ASIL D readiness, enabling designers to adhere to stringent automotive safety standards. Furthermore, its coupling with Magillem™ automation enhances the potential for rapid IP integration, simplifying multi-die designs and compressing development timelines. In addressing modern computational demands, Ncore is reinforced by robust quality of service parameters, secure power management, and seamless integration capabilities, making it an imperative asset in constructing scalable system architectures. By streamlining memory operations and optimizing data flow, it provides bandwidth that supports both high-end automotive and complex consumer electronics, fostering innovation and market excellence.
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.
The Tyr family of processors brings the cutting-edge power of Edge AI to the forefront, emphasizing real-time data processing directly at its point of origin. This capability facilitates instant insights with reduced latency and enhanced privacy, as it limits the reliance on cloud-based processing. Ideal for settings such as autonomous vehicles and smart factories, Tyr is engineered to operate faster and more secure with data-center-class performance in a compact, ultra-efficient design. The processors within the Tyr family are purpose-built to support local processing, which saves bandwidth and protects sensitive data, making it suitable for real-world applications like autonomous driving and factory automation. Edge AI is further distinguished by its ability to provide immediate analysis and decision-making capabilities. Whether it's enabling autonomous vehicles to understand their environment for safe navigation or facilitating real-time industrial automation, the Tyr processors excel in delivering low-latency, high-compute performance essential for mission-critical operations. The local data processing capabilities inherent in the Tyr line not only cut down on costs associated with bandwidth but also contribute towards compliance with stringent privacy standards. In addition to performance and privacy benefits, the Tyr family emphasizes sustainability. By minimizing cloud dependency, these processors significantly reduce operational costs and the carbon footprint, aligning with the growing demand for greener AI solutions. This combination of performance, security, and sustainability makes Tyr processors a cornerstone in advancing industrial and consumer applications using Edge AI.
APIX3 technology represents the pinnacle of data communication solutions for advanced automotive infotainment and cockpit systems. It supports ultra-high definition video resolutions, facilitated by its capacity for multi-channel high-speed data transmission. The technology enables a scalable bandwidth that adapts from entry-level to luxurious, high-end automotive systems, ensuring a broad range of application compatibilities. APIX3 modules are engineered to transmit data at rates of up to 6 Gbps over a shielded twisted pair cable and up to 12 Gbps over a quad twisted pair. This makes them invaluable in systems requiring high levels of data integrity and precision, such as those found in modern, connected vehicle architectures. In addition to supporting complex video channels, APIX3 is compatible with 100 Mbps Ethernet and integrates advanced diagnostic capabilities for cable monitoring, which allows for predictive maintenance by detecting cable degradation. Its backwards compatibility with APIX2 ensures seamless integration and upgradability in existing infrastructures, reinforcing its status as a future-proof solution.
LightningBlu is designed specifically to transform the connectivity landscape of high-speed rail by providing uninterrupted, on-the-move multi-gigabit connectivity. By bridging the gap between trackside infrastructure and the train, it offers onboard services such as internet access, entertainment, and passenger information. Operating within the mmWave range, LightningBlu ensures a seamless communication experience even at high speeds, significantly enhancing the onboard experience for passengers. Integrating robust mmWave technology, the solution supports high data throughput, ensuring passengers can enjoy swift internet access and other online services while traveling. This wireless solution eliminates the need for traditional wired networks, reducing complexities and enhancing operational flexibility. With a profound ability to support high-speed data-intensive applications, LightningBlu sets a new benchmark in transportation connectivity. This platform's design facilitates smooth operation at velocities exceeding 300 km/h; coupled with its ability to maintain service over several kilometers, it is a critical component in advancing modern rail systems. LightningBlu not only meets today’s connectivity demands but also future-proofs the necessities of tomorrow's rail network implementations.
The INAP375R Receiver complements its transmitter counterpart in offering comprehensive high-speed data reception for automotive applications. It supports multiple video and audio channels, facilitating seamless data conversion and transfer for automotive entertainment systems. Designed to work effectively with up to 12 meters of cable, the receiver ensures consistent data fidelity over distance. Incorporating an advanced current mode logic, the INAP375R efficiently handles differential signals, maintaining data integrity even in demanding environments. Its capacity to deliver up to 3Gbps over a single cable ensures compatibility with various automotive applications, be it infotainment or safety-related systems. The versatile interface options of the INAP375R enable it to adapt to varying automotive standards while ensuring reliable performance. With built-in support for AShell protocol for error detection and correction, the receiver guarantees the safe and accurate transmission of critical data across automotive networks, underpinning its suitability for high-reliability applications.
aiSim 5 represents a leap forward in automotive simulation technology, underpinning the complex validation processes needed for modern autonomous driving systems. Certified to ISO26262 ASIL-D, this simulator is designed to handle the demanding requirements of advanced driver-assistance systems (ADAS) and autonomous driving technologies. By utilizing AI-driven digital twin creation and sophisticated sensor modeling, aiSim ensures high fidelity in simulations, enabling developers to conduct virtual tests across diverse scenarios that replicate real-world conditions. Featuring a physics-based rendering engine, aiSim allows for the precise simulation of varied environmental conditions like rain, fog, and sunshine, as well as complex sensor configurations. Its open architecture and modular design facilitate easy integration into existing development pipelines, ensuring compatibility with a wide range of testing and development frameworks. The simulator's deterministic simulation capabilities provide reliability and repeatability, which are crucial for validating safety-critical automotive functions. The robust architecture of aiSim extends its utility beyond basic simulations, offering tools such as aiFab for scenario randomization, which helps in exposing edge cases that may not be encountered in typical testing environments. Moreover, its ability to produce synthetic data for training improves the robustness of ADAS systems. With aiSim, the development cycle shortens significantly, allowing automotive manufacturers to bring innovative products to market more efficiently.
Bluespec's Portable RISC-V Cores offer a versatile and adaptable solution for developers seeking cross-platform compatibility with support for FPGAs from Achronix, Xilinx, Lattice, and Microsemi. These cores come with support for operating systems like Linux and FreeRTOS, providing developers with a seamless and open-source toolset for application development. By leveraging Bluespec’s extensive compatibility and open-source frameworks, developers can benefit from efficient, versatile RISC-V application deployment.
The ADNESC ARINC 664 End System Controller by IOxOS is a versatile solution developed to meet the stringent requirements of avionic systems. Engineered in compliance with RTCA DO-254 standards and implemented using generic VHDL code, this controller supports high-performance multi-host interface operations for data networks. Capable of sustaining data transfer rates up to 400 Mbit/s, it is equipped with embedded SRAM, ensuring efficient data handling within demanding environments. Its platform-agnostic design guarantees seamless integration, allowing it to function across various systems without hardware dependencies. Ideal for avionics applications, the ADNESC controller is built to facilitate next-gen avionic data networks, offering enhanced interoperability and a robust framework to support evolving aeronautic infrastructure and testing environments.
The TSN Switch for Automotive Ethernet is an advanced solution designed for the modern automotive network environment, supporting Time-Sensitive Networking (TSN) capabilities to ensure low-latency and reliable data transmission across automotive systems. This switch technology is critical for enabling real-time communication, an essential requirement for new-age automotive applications such as autonomous driving and complex onboard diagnostics. Through TSN, data traffic can be transmitted with precise timing, which is crucial in maintaining the seamless operation of safety-critical features. At its core, the TSN Switch integrates functionalities that allow for the prioritization and scheduling of network traffic, ensuring vital data is delivered on time under various conditions. This feature is important for managing the extensive array of data exchanged in modern vehicles, where different subsystems must communicate effectively to maintain overall vehicle performance and safety. In addition to its primary applications in vehicles, the TSN Switch is designed with versatility in mind, allowing it to be adapted for other industries that require robust and timely communication, such as industrial automation and control systems. The modular approach to its design enables future updates and upgrades, ensuring the switch remains relevant as technology progresses. This adaptability underscores its strategic importance in both the automotive and broader industrial contexts.
The Advanced Flexibilis Ethernet Controller (AFEC) offers robust Ethernet connectivity through its triple-speed IP block, enhancing network interface capabilities for FPGAs and ASICs. This controller supports both copper and fiber interfaces and is equipped with IEEE 1588 support for precise time synchronization. AFEC reduces CPU load with features like DMA transfer and adjustable interrupt delay, contributing to efficient processor utilization. Its versatility makes it suitable for various high-performance network applications, ensuring flexibility and performance in complex network environments.
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.
Designed specifically for high-speed automotive data communication, the INAP590T transmitter handles demanding data loads effectively. This device supports robust video data transmission and is innovatively tailored for automotive environments, ensuring high levels of integration and performance. The INAP590T is built with features that accommodate HDMI and DSI interfaces, ensuring seamless adaptability. Its capacity for managing dual video channels highlights its applicability in complex automotive infotainment systems. The INAP590T also supports AShell channels and Ethernet functionalities, underscoring its versatility in handling comprehensive automotive data transmission requirements. Notably, the transmitter supports dual-port communication, enhancing its utility in modern automotive networking. With its focus on high-fidelity data transfer and the ability to handle diverse formats, it represents a pivotal component in advancing vehicle connectivity and infotainment solutions.
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.
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 Siliconally GmbH's cornerstone solution, pioneering advancements in reliable communication for critical applications. This product underpins the efficient handling of data transmission with a remarkable bandwidth of 100 MBit/s and is built to fit into systems with stringent space and power requirements, boasting minimal chip size and ultralow power consumption. Its robust design ensures high reliability in numerous industries such as automotive and aerospace, featuring superior capabilities like sleep/wake functions, comprehensive diagnostic tools, and fault detection mechanisms. Engineered using the advanced 22FDX technology from GlobalFoundries, the SinglePHY demonstrates unmatched electrical compliance with Open Alliance's stringent specifications. This enhanced communication module guarantees superior performance in real-time data transmission while supporting a wide array of system states and monitoring functionalities. Key interfaces include Media Independent Interface (MII) and Media Dependent Interface (MDI), making it adaptable for diverse applications and straightforward to integrate into existing infrastructure. The SinglePHY's compact footprint, coupled with a typical power consumption of only 34mW, highlights its energy efficiency, especially critical in today's environmentally-conscious design paradigms. This advanced PHY solution is distinguished by its rapid error detection and reporting, ensuring that communication networks maintain integrity even under stress. Equipped with extensive compliance and diagnostic features, it provides an unparalleled level of safety and operational security, essential for modern industry requirements.
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.
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.
SiGe BiCMOS technology is tailored for RF applications, delivering excellent performance for high-frequency communications. This technology supports low noise figures and high linearity, vital for advanced communication systems. In the growing landscape of RF solutions, this process technology allows for enhanced integration and miniaturization of components, driving innovations in wireless communication. High precision transistors in this technology facilitate the development of superior RF transceivers, suitable for complex and demanding applications. It's well-suited for use in infrastructure systems where robust and reliable RF signal processing is crucial. By integrating both bipolar and CMOS transistors, this platform offers the best of both worlds, combining high-speed performance with power efficiency. Designed for versatility, the SiGe BiCMOS technology simplifies the design of RF circuits by allowing adaptability in circuit design and process options. This feature is particularly beneficial for designers working on next-generation wireless devices, pushing boundaries in speed and functionality.
This product provides high-accuracy hardware synchronization for video equipment over IP networks, essential for generating precise timing signals crucial for audio and video systems. It is compliant with IEEE1588v2 and supports both 2059-1 and 2059-2 standards. The synchronization system combines both software and hardware elements to offer a versatile solution for industries reliant on synchronized media equipment.
The SafeIP™ DualPHY by Siliconally GmbH represents a robust solution designed for applications requiring both 100 and 1000 MBit/s bandwidths. This versatile product supports automatic negotiation between these two modes, offering enhanced communication flexibility. It integrates seamlessly into systems with high demands for data integrity and operational safety, making it ideal for automotive and industrial applications. Incorporating cutting-edge 22FDX technology, the DualPHY offers advanced diagnostics and cable fault localization, conforming to the Open Alliance standards. Its energy footprint is notably efficient, with a typical power consumption of 250mW. The DualPHY's build ensures resilience, meeting compliance for automotive grade standards which are essential for system-critical environments. The design focuses on providing seamless transitions between operational states, facilitated by its unique communication technology. With its strategic multi-interface implementation, DualPHY ensures wide-ranging compatibility and adaptability, simplifying integration across diverse platforms. This makes the DualPHY a strategic choice for enhancing safety and performance in complex systems.
The Complete RF Transceiver designed for frequencies 433, 868, and 915 MHz is compliant with IEEE 802.15.4-2015. This solution is versatile, suiting applications requiring robust RF communication over these specific frequency bands. The transceiver is engineered to facilitate data rates accommodating 1.2 kbps to 500 kbps, allowing excellent adaptability in various systems. Its support extends to GFSK, BPSK, and O-QPSK modulation techniques, enhancing compatibility across different implementations. A vital feature of this transceiver is its comprehensive design, integrating PLL and RF front-end components. This high level of integration simplifies system design by removing the need for external RF components. Its performance is further exemplified by a TX power range from -20 to +8 dBm, ensuring significant transmission capability while maintaining efficient power use. This makes it ideal for long-distance communication without the complexities often associated with higher frequency bands and complex protocols. Further enhancing its versatility, the transceiver IP includes built-in voltage regulators and a bandgap reference, optimizing integration into various system-on-chip (SoC) architectures. These features are crucial for companies seeking to create wireless systems with minimal external dependencies, ensuring efficient use of space and resources on silicon. This makes it a preferable choice for global deployment where robust RF performance is a priority.
The Flexibilis Redundant Switch (FRS) offers triple-speed Ethernet switching with an IP core that supports High-availability Seamless Redundancy (HSR), Parallel Redundancy Protocol (PRP), and IEEE 1588 Precision Time Protocol (PTP). This switch is designed to provide seamless redundancy for Ethernet networks, supporting configurations from 3 to 8 ports. It is highly versatile, allowing the setup of end-node, RedBox, and other network topologies. FRS eliminates the need for a separate RedBox in many situations, providing a cost-effective and streamlined solution for ensuring network resilience and performance.
Time-Sensitive Networking (TSN) represents a suite of Ethernet specifications designed to support deterministic real-time communication. TSN is increasingly important in sectors like industrial automation, automotive, and aerospace, offering innovative solutions for applications requiring synchronized data communication. TTTech's TSN technology enhances interoperability across network devices through standardization and ensures precise timing management necessary for networks in mission-critical applications. This technology incorporates synchronizing mechanisms like the IEEE 802.1AS for time synchronization and IEEE 802.1Qbv for scheduling, which improve network efficiency by allowing time-aware queue management. By facilitating bandwidth-intensive operations and accommodating dynamic network changes, TSN enables real-time communications over IEEE 802-style wired networks. TTTech's robust TSN solutions are utilized in end systems and complex system-on-chips, where bandwidth and redundancy are critical, reinforcing its presence in high-demand networking solutions.
ZIA SV represents a state-of-the-art stereo vision IP core geared towards precise distance measurement through stereo imaging, critical for applications involving autonomous navigation and distance sensing. By harnessing images from dual cameras, ZIA SV utilizes semi-global matching (SGM) algorithms to accurately estimate disparities and distances. The core is optimized through various pre- and post-processing techniques to enhance performance and precision. These processes include alignment, stereo rectification, sub-pixel interpolation, and disparity image denoising, ensuring unparalleled accuracy in distance estimation. Equipped with a scalable architecture, DMP’s ZIA SV supports integration with AMBA AXI4 interface, ensuring compatibility with numerous processor architectures. The versatility and precision of this IP make it suitable for use in robots and drones requiring advanced stereo vision capabilities.
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.
The 8b/10b Decoder is a complete implementation of the Widmer and Franaszek encoding scheme, designed to ensure reliable data transmission by correcting bit errors in high-speed communication systems. This decoder detects special comma characters and automatically processes K28.5 characters to maintain data integrity. Its application is crucial in systems where error-free data communication is paramount, such as in telecommunications and data centers. By incorporating this decoder, systems can achieve high levels of performance and accuracy, reducing the risk of data loss or transmission errors. The 8b/10b Decoder is integral to maintaining the robustness of data communication networks, supporting the high demands of modern digital systems.
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.
PhantomBlu is a milestone in tactical communications, providing high-performance, data-rich connectivity solutions tailored for defence environments. Delivering on-the-move gigabit connectivity capabilities, it is designed to support demanding applications in mission-critical scenarios. With independently configurable options as PCP (hub) or STA (client), this solution excels in providing high-speed tactical communications over extensive ranges, making it indispensable in strategic defence operations. The platform leverages Blu Wireless’s advanced mmWave technology to ensure low SWAP (size, weight, and power) features, crucial for mobile and portable military applications. This adaptability and lack of reliance on cabled networks ensure PhantomBlu is not only agile but also highly effective across diverse operational environments. Through meticulous design, PhantomBlu supports interoperability with existing and future military assets, thereby extending the life and usability of defence communications infrastructure. By enabling high-bandwidth networks and low-latency communications, it stands as a cornerstone for modern defence strategies, allowing rapid data exchange vital for decision-making in fast-evolving tactical circumstances.
The CANsec Controller Core is engineered to enhance the security of CAN networks by integrating robust cryptographic protocols and mechanisms that protect data integrity and confidentiality. This cutting-edge solution is tailored for automotive applications, providing an extra layer of security to combat the rising threats in vehicle systems as they increasingly connect to broader networks and the internet. CAN networks, widely used in vehicular communications, were originally designed without security in mind. This leaves them vulnerable to potential cyber-attacks, which is where the CANsec Controller Core comes into play. It bolsters the data transmission network by encrypting messages and authenticating commands, thus significantly mitigating the risk of interception or malicious tampering. With its seamless integration capabilities, the CANsec Controller Core can be adopted without major modifications to existing network infrastructures, making it an ideal choice for gradual implementation in both new and legacy systems. Its flexibility and robust security features make it an invaluable tool for manufacturers aiming to enhance the security resilience of their automotive technologies while adhering to evolving industry standards.
DapTechnology's FireCore solutions offer sophisticated support for both PHY and Link Layer functionalities of the IEEE-1394b-2008 and AS5643 standards. Engineered for adaptability, these solutions integrate seamlessly into various FPGA families, supporting custom configurations tailored to specific operational requirements. FireCore was developed to handle transmission speeds from S100 to S3200, ensuring high performance across numerous industrial contexts. A notable feature of FireCore solutions is their customizable nature, allowing for precise adaptation to unique system needs. This flexibility extends to the configuration of PHY ports, host interface compatibility, as well as advanced error monitoring capabilities. The solutions also include key enhancements for real-time data handling such as Bit Error Injection and Bit Error Rate Testing. The robust configuration options offered by FireCore ensure that users can effectively streamline data encapsulation and transmission processes, minimizing latency and maximizing data integrity. These solutions are particularly valuable for users aiming to expedite their data processing capabilities while maintaining rigorous compliance with industry standards.
Wireless non-radiative energy transfer technology developed by WiTricity offers a breakthrough in delivering power over distance without the need for physical connectors. This system utilizes magnetic resonance to enable efficient energy transfer between a source and a receiver, ensuring robust power delivery across varying distances. Critical to this technology's success is its ability to maintain high efficiency despite the presence of obstacles and misalignment of the power receiving and transmitting devices. The system's non-radiative nature implies that the power transfer does not rely on traditional wireless methods such as electromagnetic radiation, which can suffer from inefficiencies and regulatory constraints. Instead, it leverages resonant induction principles to facilitate energy flow over an essentially unbroken space, mitigating typical power loss associated with long-range energy transfer. WiTricity's wireless non-radiative technology is also adaptable across various environments and applications, including electric vehicle charging and industrial automation. It is designed with a focus on minimizing environmental impact while enhancing the user experience, making it an ideal solution for the future of wireless energy distribution.
SiFive Automotive solutions provide cutting-edge automotive processors designed for high reliability and performance in modern vehicles. With a focus on industry-leading efficiency, safety, and a minimal physical footprint, the SiFive Automotive family supports requirements from infotainment systems to central computing. Each processor in this family is tailored for automotive usage, implementing critical safety standards like ISO 26262 ASIL D, to ensure compliance with the world's most stringent safety regulations. Capable of managing advanced driver assistance systems (ADAS) and developing autonomous vehicle technologies, these solutions are fortified for upcoming challenges in automotive electronics. Besides impressive safety and performance metrics, SiFive Automotive processors are designed with an eye towards cybersecurity and functional safety, ensuring comprehensive protection and optimal operation in demanding automotive conditions. This makes SiFive's offerings an essential part of modern automotive solutions, blending innovative technology with top-tier safety features for the autos of the future.
The RISC-V CPU IP NA Class from Nuclei is purpose-built for the automotive industry, focusing on ISO26262 FuSa standards to ensure functional safety. This processor IP is designed with automotive-specific features and flexibility, employing a 64-bit architecture to handle complex computations necessary in advanced driver assistance systems (ADAS) and other automotive applications. Developed using Verilog, the NA Class prioritizes readability, which aids in debugging and optimizing performance, power efficiency, and area measurements. With substantial configurability, the NA Class allows for integration in a wide range of systems by leveraging RISC-V extensions and user-defined instruction capabilities. Its comprehensive security suite, including TEE support and physical security packages, ensures the integrity and protection of automotive systems from cyber-threats. Furthermore, the NA Class is aligned with ASIL-B and ASIL-D safety protocols, providing the necessary assurance for automotive safety and reliability standards. In conclusion, Nuclei's NA Class is set to meet the high demands of automotive applications requiring safety and security. It offers robust features that address the specific needs of the automotive scene, showcasing Nuclei’s dedication to innovation and safety in the automotive sector.
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.
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