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 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.
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 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.
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 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.
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 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 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.
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 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 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.
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.
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.
The IMG DXS GPU is designed to meet the safety and performance demands of automotive applications with a focus on advanced driver assistance systems (ADAS). Featuring a multi-core architecture with built-in functional safety mechanisms, it allows for efficient handling of mixed-criticality workloads. Its distributed safety mechanisms enable significant reductions in silicon area and power consumption, making it ideal for safety-critical environments. This GPU excels in providing high-performance visuals for in-car systems like digital instrument clusters and heads-up displays. With ISO 26262 functional safety certification, it meets stringent automotive industry standards, ensuring reliability even in fault scenarios. The IMG DXS GPU supports a wide range of graphical applications, from infotainment to vital safety systems, with hardware-accelerated graphics rendering capabilities. It is engineered for seamless integration into automotive systems, offering robust performance while maintaining energy efficiency.
This innovative system is designed to enhance the user experience of wireless power transfer applications by ensuring precise alignment and compatibility between power transmitters and receivers. It includes mechanisms for detecting the positioning of a device relative to a charging source, optimizing the alignment process to ensure efficient energy transfer. The system's compatibility detection capabilities allow it to recognize and adapt to various device specifications and charging standards, reducing the risk of charging errors and improving overall system reliability. With this system, users can achieve optimal alignment automatically, making the process of wireless charging simpler and more intuitive. The technology is particularly beneficial in scenarios where positioning is critical for energy transfer efficiency, such as in automotive or portable device applications. It addresses common challenges in wireless power systems, such as alignment drift and signal path obstructions, ensuring that power is delivered smoothly and consistently.
The XRS7000 Series Switches integrate High-Availability Seamless Redundancy (HSR) and Parallel Redundancy Protocol (PRP) capabilities in one compact solution, supporting industrial grade Ethernet applications. These switches facilitate seamless data communication over Ethernet, ensuring that there is uninterrupted redundancy in network setups. It's engineered for optimal operation in demanding environments such as industrial automation, substation automation, and vehicle communication systems, where reliability and time synchronization are key. The XRS7000 Series stands out with its integrated circuits (ICs) which support the IEEE 1588 standard, providing precise time synchronization essential for high-performance applications. These devices are designed to eliminate any single points of failure, thus safeguarding network availability and data integrity in critical infrastructures. Furthermore, they accommodate both cut-through and store-and-forward operation modes, ensuring high flexibility and adaptability in network configurations. With features like multi-gigabit data forwarding, VLAN tagging, and quality of service controls, the XRS7000 series ensures prioritized data transmission and minimizes latency, thereby enhancing network performance. The switches' compatibility with both copper and fiber Ethernet interfaces further broadens their applicability across various industrial contexts.
Incorporating advanced interference management techniques, this wireless energy transfer solution enhances the efficiency and reliability of power transmission over the air. By dynamically adjusting to environmental factors that typically cause interference, this technology ensures a stable power transfer even in challenging conditions. Employing sophisticated algorithms, the system manages power distribution to minimize interference, optimizing the performance and enabling it to power multiple devices simultaneously without conflicts. This advancement is particularly relevant in urban and industrial settings where electromagnetic interference is common, significantly improving energy transfer capabilities in such environments. The system’s ability to maintain high power transfer efficiency amidst potential sources of disruption expands its applicability in both consumer and industrial domains. It integrates seamlessly with existing wireless power infrastructure, offering a robust solution that can adapt to a multitude of environments and requirements. This technology provides distinct advantages for applications requiring high reliability and uninterrupted power delivery, positioning it as a vital component in the evolution of wireless power systems.
The Rad-Hard eFPGA by QuickLogic is specifically engineered for mission-critical operations that demand ruggedness and resilience. This rad-hard technology is tailored for strategic environments requiring resilience to radiation and capability in extreme conditions, thus making it ideal for aerospace and defense applications. QuickLogic’s Rad-Hard eFPGA solutions incorporate advanced features that ensure the sound performance of electronic systems even amidst disturbances or radiation exposure. Designed to work under severe environmental constraints, these FPGAs address the pressing needs for reliability and longevity in space and military technologies. This dedicated product line emphasizes ensuring operational integrity while meeting specific requirements like Size, Weight, Power, and Cost (SWaP-C). QuickLogic’s extensive experience in rugged environments informs its approach to delivering unwavering performance while minimizing risks associated with implementation in high-demand sectors.
The Automotive Multigigabit Ethernet Switch with Multilayer Security epitomizes advanced networking capabilities designed specifically for automotive cybersecurity needs. This high-performing Ethernet switch is engineered to support multigigabit data transfer rates essential for connected vehicle technologies. Built with inherent security layers, the switch emphasizes robust cybersecurity measures, ensuring data integrity and secure communications essential in the context of modern vehicular networks. It supports real-time data processing required for next-generation automotive systems, offering seamless connectivity while assuring high-speed data handling. This switch is particularly valuable in automotive scenarios, providing a critical infrastructure for connected and autonomous vehicle applications. It underscores the growing convergence of automotive and IT sectors, providing secure and efficient networking solutions necessary for advanced vehicular operations.
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.
The CAN-CTRL is a comprehensive bus controller IP core designed to support multiple CAN protocol standards, including CAN, CAN FD, and CAN XL. This IP core is particularly advantageous for automotive and industrial applications, where communication robustness and protocol compliance are critical. The CAN-CTRL facilitates high-efficiency data transfer across networked environments, accommodating varying data rates and ensuring effective message delivery. Its architecture is compliant with ISO 26262, making it an ideal choice for systems where functional safety is non-negotiable. The controller's advanced features include support for Time-Triggered CAN (TTCAN), enhancing its versatility for complex hierarchies. Engineers benefit from its flexible configuration options, allowing for cost-effective customization suitable for a variety of applications. Its robustness is further highlighted by extensive error handling capabilities and a dedicated interface for seamless integration into existing architectures.
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