All IPs > Automotive > CAN XL
In the automotive industry, the demand for faster and more efficient communication networks has spurred the development and implementation of advanced semiconductor IPs. Among these innovations is the CAN XL (Controller Area Network Extra Long) protocol, an extension of the traditional CAN protocol, engineered to meet the evolving connectivity needs of modern vehicles. As automotive systems become more interconnected and data-driven, the need for high-speed, reliable data exchange has become crucial. CAN XL semiconductor IPs are specially designed to facilitate these requirements by offering higher data transfer rates and improved flexibility compared to their predecessors.
CAN XL is particularly attractive for its ability to support higher payload capacities, making it well-suited for applications that involve heavy data loads, such as advanced driver-assistance systems (ADAS), infotainment systems, and real-time sensor interfacing. By leveraging CAN XL semiconductor IPs, automotive manufacturers can ensure that vehicle communication systems maintain robustness and efficiency, even in high-demand scenarios. This results in improved vehicle performance and enhanced safety features, making it a key component in the modern automotive landscape.
Moreover, CAN XL semiconductor IPs offer scalability, allowing them to be seamlessly integrated into existing CAN networks within vehicles. This backward compatibility ensures that automotive manufacturers can upgrade their systems without a complete overhaul, preserving both time and cost efficiencies. The ease of integration and adaptation to varying automotive architectures underline the importance of CAN XL in facilitating the transition to more advanced vehicular technologies.
In the Silicon Hub's automotive CAN XL category, you will find a wide range of semiconductor IP solutions, including transceiver interfaces, controllers, and bridge IPs, all designed to optimize the use of CAN XL in automotive applications. These semiconductor IPs are pivotal in ensuring that the next generation of vehicles are connected, efficient, and reliable, aligning with the industry's push towards intelligent transportation systems and autonomous driving.
Silvaco's Automotive IP solutions deliver silicon-proven elements critical for the advancing automotive market. This comprehensive suite includes controllers for In-Vehicle Networking (IVN) standards such as FlexCAN with CAN-FD, high-speed FlexRay, and LIN, ensuring robust communication protocols necessary for modern automotive electronics. Designed to facilitate system-on-chip (SoC) resilience, this IP includes essential cores and peripherals vital for integrated automotive systems. Features such as Quad and Octal SPI, UART, DMA Controllers, and Power Management Units provide the foundational elements that support the robust operation of complex automotive applications, across both electrical and mechanical subsystems. As automotive electronics continue to evolve, Silvaco's automotive solutions ensure adherence to the highest standards of reliability and compliance, promoting advancements in autonomous and connected vehicle technologies.
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.
The eSi-ADAS Radar IP Suite and Co-processor Engine is at the forefront of automotive and unmanned systems, enhancing radar detection and processing capabilities. It leverages cutting-edge signal processing technologies to provide accurate and rapid situational awareness, crucial for modern vehicles and aerial drones. With its comprehensive offering of radar algorithms, eSi-ADAS supports both traditional automotive radar applications and emerging unmanned aerial vehicle (UAV) platforms. This suite is crafted to meet the complex demands of real-time data processing and simultaneous multi-target tracking in dense environments, key for advanced driver-assistance systems. The co-processor engine within eSi-ADAS is highly efficient, designed to operate alongside existing vehicle systems with minimal additional power consumption. This suite is adaptable, supporting a wide range of vehicle architectures and operational scenarios, from urban driving to cross-country navigation.
The Time-Triggered Protocol (TTP) is an advanced communication protocol designed to enable high-reliability data transmission in embedded systems. It is widely used in mission-critical environments such as aerospace and automotive industries, where it supports deterministic message delivery. By ensuring precise time coordination across various control units, TTP helps enhance system stability and predictability, which are essential for real-time operations. TTP operates on a time-triggered architecture that divides time into fixed-length intervals, known as communication slots. These slots are assigned to specific tasks, enabling precise scheduling of messages and eliminating the possibility of data collision. This deterministic approach is crucial for systems that require high levels of safety and fault tolerance, allowing them to operate effectively under stringent conditions. Moreover, TTP supports fault isolation and recovery mechanisms that significantly improve system reliability. Its ability to detect and manage faults without operator intervention is key in maintaining continuous system operations. Deployment is also simplified by its modular structure, which allows seamless integration into existing networks.
Arteris's Ncore Cache Coherent Interconnect IP addresses the complex challenges of multi-core ASIC development, offering a scalable, highly configurable solution for coherent network-on-chip designs. This IP supports multiple protocols, including Arm and RISC-V, and is engineered to comply with ISO 26262 for safety-critical applications. Ncore enables seamless communication and cache coherence across varied processor cores, enhancing performance while meeting stringent functional safety standards. Its capability to automate Fault Modes Effects and Diagnostic Analysis (FMEDA) further simplifies safety compliance, proving its value in advanced SoCs where reliability and high throughput are critical.
The Advanced Flexibilis Ethernet Controller (AFEC) is a high-performance Ethernet controller IP core suitable for integration with programmable hardware and ASICs. Offering triple-speed support for 10/100/1000 Mbps Ethernet, the AFEC is designed to function as a comprehensive Ethernet Network Interface Controller alongside Ethernet Physical layer devices. Significant in reducing CPU load, the AFEC features bus master DMA transfer for both RX and TX data, while accommodating data in various fragments in memory, thanks to its RX and TX scatter-gather capability. These features enable high data throughput and efficient CPU resource management. The AFEC also supports IEEE 1588 Precision Time Protocol, providing essential time synchronization and frame timestamping. Its capability extends to implementing delayed interrupts to minimize CPU load further. Designed for efficient resource usage, AFEC is an essential component for applications necessitating reliable network interface functionality and precise timekeeping, such as industrial automation and telecommunication systems.
The Tyr AI Processor Family is designed around versatile programmability and high performance for AI and general-purpose processing. It consists of variants such as Tyr4, Tyr2, and Tyr1, each offering a unique performance profile optimized for different operational scales. These processors are fully programmable and support high-level programming throughout, ensuring they meet diverse computing needs with precision. Each member of the Tyr family features distinct core configurations, tailored for specific throughput and performance needs. The top-tier Tyr4 boasts 8 cores with a peak capability of 1600 Tflops when leveraging fp8 tensor cores, making it suitable for demanding AI tasks. Tyr2 and Tyr1 scale down these resources to 4 and 2 cores, respectively, achieving proportional efficiency and power savings. All models incorporate substantial on-chip memory, optimizing data handling and execution efficiency without compromising on power use. Moreover, the Tyr processors adapt AI processes automatically on a layer-by-layer basis to enhance implementation efficiency. This adaptability, combined with their near-theory performance levels, renders them ideal for high-throughput AI workloads that require flexible execution and dependable scalability.
The SinglePHY solution from Siliconally is designed specifically for robust and secure communication in automotive Ethernet applications. Operating at a bandwidth of 100 MBit/s, it provides ample capacity for a host of applications while maintaining a compact chip footprint and exceptionally low power usage. Its integration capabilities extend beyond standard operations, ensuring seamless data streaming, diagnostics, and error flagging, which are essential in safety-critical environments.
The ACAM is a 60 GHz millimeter-wave smart sensor that provides comprehensive in-cabin monitoring for vehicles, focusing on safety and comfort. This sensor leverages advanced NOVELIC perception software to ensure high accuracy in detecting the presence of living beings, recognizing seat occupancy, and monitoring vital signs such as respiratory rates. The sensor operates effectively without requiring a direct line of sight, preserving passenger privacy and functioning seamlessly under various lighting conditions. As regulations evolve, systems like child presence detection in vehicles are increasingly becoming standard, and the ACAM is designed to meet and exceed such standards by offering comprehensive coverage for in-cabin safety.
The SafeIP DualPHY from Siliconally supports dual ethernet modes, offering both 100 and 1000 MBit/s data transfer rates. This dual capability is essential for systems requiring versatile and resilient communication frameworks. Built with a foundation in safety and reliability, the DualPHY is equipped with advanced auto-negotiation abilities and diagnostics capabilities, making it a preferred choice for systems entrenched in dynamic and critical environments.
This product focuses on wireless energy transfer that does not rely on traditional radiative methods, allowing power to be distributed efficiently without physical connections. It utilizes high-quality resonators, harnessing magnetic coupling to transmit energy over various distances and environments. The goal is to maximize power delivery while minimizing radiated emissions, ensuring compatibility and safety in numerous applications. This method is pivotal for sectors like automotive, where reducing the dependency on physical cables is crucial for the proliferation of electric vehicles.
This system focuses on ensuring optimal alignment and compatibility between power transmitters and receivers in wireless charging setups. The technology is designed to detect misalignments and make necessary adjustments to maintain an efficient energy transfer process. By using advanced sensing and alignment methodologies, this system diminishes power losses and enhances the reliability of energy transfer chains. Such systems are critical in automotive applications, where alignment can significantly impact the efficiency and safety of vehicle charging processes.
The CANsec Controller Core is developed for secure communication in automotive networks. Building on the Controller Area Network (CAN) protocol, this core introduces enhancements for data security, ensuring that messages transmitted across the network are resistant to tampering and unauthorized interception. With the growing complexity and interconnectedness of vehicle systems, the CANsec architecture provides robust protection against emerging cybersecurity threats, making it an essential component for modern automotive designs.
PhantomBlu represents Blu Wireless's advanced mmWave solution tailored for military and defense applications. It is engineered to deliver secure, high-performance tactical communications in diverse and challenging environments. The system's low-SWAP (size, weight, and power) design is versatile, featuring configurations capable of acting as both PCP (hub) and STA (client), thereby ensuring reliable communication in dynamic and fast-moving scenarios. PhantomBlu operates without the need for traditional fiber optics or wired networks, leveraging available mmWave spectrum to facilitate seamless interoperability across legacy and new defense systems. This flexibility makes it an essential asset in modern warfare, providing data-rich, mission-critical connectivity that adapts swiftly to operational requirements. PhantomBlu's design supports stealthy, gigabit-speed communications crucial for mission efficacy and situational awareness. Emphasizing ease of integration and deployment, PhantomBlu contributes to transforming tactical communication landscapes by improving throughput and reducing latency. Its robust architecture ensures optimal performance even under demanding conditions, catering to the defense sector's growing reliance on rapid data exchange and real-time information sharing.
This technology enhances the efficiency of wireless power transfer by addressing interference issues, offering a more robust and reliable energy conduction path. It is specifically designed to deal with environments where energy pathways may be obstructed or varied. The interference enhancement capability allows for adaptive energy signaling that can navigate around barriers, making wireless power solutions more resilient and adaptable to real-world conditions. This is especially beneficial for complex industrial environments and urban settings, where maintaining a steady power flow is vital.
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.
The IMG DXS GPU represents a significant leap in safe computing, designed specifically for automotive applications. Its architecturally advanced features deliver 1.5 times the peak performance of previous models, focusing on power efficiency and functional safety. With its pioneering Distributed Safety Mechanisms, the IMG DXS GPU effectively minimizes the power, area, and performance overheads typically associated with achieving ASIL-B compliance. This GPU is engineered to meet the rigorous requirements of automotive computing systems, ensuring secure and highly efficient processing. Built to handle the computational demands of both graphics and AI simultaneously, the DXS leverages Imagination's cutting-edge parallel processing architecture. This flexibility makes it suitable for integration into next-generation automotive cockpit and infotainment systems, where reliability is paramount. The IMG DXS is part of Imagination's innovative approach to combining high performance with functionally safe processing, reflecting the company's commitment to leading the automotive GPU market. In addition to its robust safety features, the DXS GPU supports advanced automotive graphics, leading the way in enhancing visual experiences in vehicle displays. Its design and development have followed the ISO 26262 standard, underpinning its reliability and safety, making it a preferred choice for automotive manufacturers seeking cutting-edge technology that doesn’t compromise on safety or performance.
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.
The XRS7000 Series Switches are specialized integrated circuits (ICs) designed for enhancing Ethernet networks with High-availability Seamless Redundancy (HSR) and Parallel Redundancy Protocol (PRP) capabilities. These switches serve as a versatile solution for adding time synchronization functionality to both new and existing applications. The XRS7000 Series is recognized as a pioneering off-the-shelf HSR/PRP Ethernet chip in the market, offering robust redundancy and reliability without any single point of failure. Ideal for industrial automation, motion control, substation automation, and vehicle communication, the XRS7000 Series supports IEEE 1588 for precision time protocol applications. These chips are part of the Arrow Electronics SpeedChips product family, reinforcing their reliability and availability for comprehensive network solutions. The XRS7000 devices are available for purchase on the Arrow site, facilitating wide accessibility and integration into existing systems. The chips come in two versions, XRS7003 and XRS7004, offering three and four ports, respectively. They support RGMII ports with varying functionalities in different network configurations, such as HSR RedBoxes. The series offers features like cut-through and store-and-forward operation, VLAN tagging, and MAC address-based authenticating methods, making them robust and versatile components for dynamic network environments.
The Automotive Multigigabit Ethernet Switch with Multilayer Security is an advanced networking solution designed to meet the rigorous demands of modern automotive systems. Incorporating high-speed data transfer capabilities and robust security features, this switch facilitates seamless connectivity across vehicle networks. Its multigigabit capability ensures that it can handle today’s data-heavy applications ranging from infotainment to advanced driver-assistance systems (ADAS). Security is a cornerstone of this switch's design, featuring multilayer protection that guards against unauthorized access and data breaches, which are critical in automotive applications. The switch’s architecture is optimized for low latency and high robustness, ensuring seamless integration with various automotive-grade Ethernet interfaces, thereby enhancing the overall vehicular communication system. Additionally, the switch offers scalability options that support future upgrades and technology integrations, making it a forward-compatible platform. Its compliance with industry standards guarantees interoperability and reliability across various automotive applications, further enhancing its appeal to manufacturers looking for dependable long-term solutions for in-vehicle networking.
Trimension UWB stands as a hallmark of NXP's advancements in Ultra-Wideband technology, aimed at achieving superior precision and accuracy for spatial awareness applications. It leverages UWB's exceptional timing capabilities to ensure accurate distance measurement and positioning. The integration of Trimension UWB in automotive applications facilitates high-level security and convenience, supporting secure keyless entry and precise vehicle positioning, which are critical for enhanced user experiences. This technology aligns with the growing demand for more intelligent, responsive vehicle systems. Beyond automotive, Trimension UWB's precision finds application in industrial settings, where accurate localization and tracking of assets are essential. This capability not only boosts operational efficiency but also significantly reduces logistical overhead, positioning it as an invaluable tool for a myriad of industrial uses.
DCAN XL redefines data communication by bridging the performance gap between CAN FD and 100Mbit Ethernet, setting a new benchmark in high-speed, flexible connectivity. With data rates up to 20 Mbit/s and payloads reaching 2048 bytes, it delivers unprecedented throughput—far beyond traditional CAN standards. Engineered for versatility, DCAN XL supports advanced protocol layering and Ethernet frame tunneling, making it an ideal choice for future-proof automotive, industrial, and IoT applications. It retains the robustness and reliability of the CAN protocol while offering full backward compatibility with Classical CAN, CAN FD, and CAN XL—ensuring effortless integration into existing systems. For physical layer connectivity, DCAN XL interfaces seamlessly with standard CAN transceivers (sub-10Mbps) and CAN SIC XL transceivers (above 10Mbps), providing flexibility without compromise. It’s not just evolution—it’s the next revolution in controller area networking.
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