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.
XDS serves as an all-encompassing platform for RF and microwave circuit design, unifying schematic and layout simulations across different scales. This software features extensive RF libraries and integrates linear circuit, spice, and MoM electromagnetic field solvers to handle diverse engineering needs. Its advanced technology supports automatic LC filter synthesis, optimizing the design of RF passive components. By managing third-party device libraries and facilitating efficient field-circuit simulations, XDS is a preferred choice for both preliminary and advanced stages of RF circuit development, ensuring high-precision and high-reliability results.
DenseMem offers a significant advancement in memory capacity by using CXL connectivity to double the available memory. Ideal for high-demand applications, this feature ensures data centers can manage increased workloads without compromising performance. The efficient expansion capabilities provide a remarkable increase in memory while optimizing the underlying infrastructure's energy consumption and operational costs.
The EW6181 is a cutting-edge multi-GNSS silicon solution offering the lowest power consumption and high sensitivity for exemplary accuracy across a myriad of navigation applications. This GNSS chip is adept at processing signals from numerous satellite systems including GPS L1, Glonass, BeiDou, Galileo, and several augmentation systems like SBAS. The integrated chip comprises an RF frontend, a digital baseband processor, and an ARM microcontroller dedicated to operating the firmware, allowing for flexible integration across devices needing efficient power usage. Designed with a built-in DC-DC converter and LDOs, the EW6181 silicon streamlines its bill of materials, making it perfect for battery-powered devices, providing extended operational life without compromising on performance. By incorporating patent-protected algorithms, the EW6181 achieves a remarkably compact footprint while delivering superior performance characteristics. Especially suited for dynamic applications such as action cameras and wearables, its antenna diversity capabilities ensure exceptional connectivity and positioning fidelity. Moreover, by enabling cloud functionality, the EW6181 pushes boundaries in power efficiency and accuracy, catering to connected environments where greater precision is paramount.
The Tyr Superchip is engineered to tackle the most daunting computational challenges in edge AI, autonomous driving, and decentralized AIoT applications. It merges AI and DSP functionalities into a single, unified processing unit capable of real-time data management and processing. This all-encompassing chip solution handles vast amounts of sensor data necessary for complete autonomous driving and supports rapid AI computing at the edge. One of the key challenges it addresses is providing massive compute power combined with low-latency outputs, achieving what traditional architectures cannot in terms of energy efficiency and speed. Tyr chips are surrounded by robust safety protocols, being ISO26262 and ASIL-D ready, making them ideally suited for the critical standards required in automotive systems. Designed with high programmability, the Tyr Superchip accommodates the fast-evolving needs of AI algorithms and supports modern software-defined vehicles. Its low power consumption, under 50W for higher-end tasks, paired with a small silicon footprint, ensures it meets eco-friendly demands while staying cost-effective. VSORA’s Superchip is a testament to their innovative prowess, promising unmatched efficiency in processing real-time data streams. By providing both power and processing agility, it effectively supports the future of mobility and AI-driven automation, reinforcing VSORA’s position as a forward-thinking leader in semiconductor technology.
The Advanced Flexibilis Ethernet Controller (AFEC) is an advanced IP block tailored for both FPGA and ASIC implementations, offering comprehensive Ethernet Interface solutions for networking needs. Designed for triple-speed operation (10Mbps/100Mbps/1Gbps), AFEC enhances Ethernet device communication with robust capabilities. AFEC seamlessly connects to Ethernet PHY devices through standard interfaces like MII and GMII while supporting both copper and fiber Ethernet networks. This ensures a versatile application range across devices and networking setups. It includes a dedicated DMA controller for RX and TX data handling to ease CPU processing loads, allowing less powerful processors to achieve maximum data throughput. Supporting the IEEE1588 Precision Time Protocol, AFEC allows for precise time stamping of all transmitted and received frames, vital for applications where accurate time logging is crucial. Its flexible interrupt management and configuration options make it a highly adaptable controller for complex Ethernet setups seeking enhanced performance and synchronization capabilities.
The eSi-ADAS suite is a high-performance radar processing solution primarily designed to enhance ADAS systems. It comprises a comprehensive set of radar accelerator IPs, such as FFT and CFAR engines, alongside tracking capabilities powered by Kalman filter technology. This setup facilitates real-time monitoring of diverse radar environments. Automotive and UAV sectors benefit significantly from eSi-ADAS, as it ensures precise situational awareness necessary for modern safety and collision avoidance systems. By offloading computationally intensive tasks from the central processing unit, it optimizes performance and power efficiency. This enables the handling of complex scenarios, from short-range radar operations to simultaneous tracking of numerous objects.
The Ncore Cache Coherent Interconnect is designed to address the challenges of multicore ASICs by ensuring efficient inter-core communication and synchronization within SoCs. It provides a high-bandwidth interconnect fabric, supporting multiple protocols and a range of processor designs, including Arm and RISC-V architectures. This coherent interconnect leverages system scalability and integration ease, meeting the rigorous demands of safety-critical environments like those in automotive applications. Ncore is engineered to reduce complexity and optimize power usage while maintaining high-performance standards, ultimately enhancing reliability in complex multi-core system designs.
The DCAN XL presents an advanced CAN Bus controller capable of bridging traditional CAN FD with 100Mbit Ethernet. This innovative solution supports a wide range of data rates up to 20 Mbit/s, with specialized transceivers for bit rates both under and over 10Mbps. Designed in accordance with ISO 11898-1:2015 standards, it ensures compatibility across various automotive and industrial communication systems. By adopting cutting-edge serial communication technologies, the DCAN XL reliably enhances the network's data throughput and integrity, making it indispensable for sophisticated vehicular and machine control applications.
The SafeIP™ SinglePHY is Siliconally's leading solution for secure IEEE 802.3 communication. This semiconductor product provides a stable and power-efficient communication solution with its innovative safety features. Engineered for rapid system failure responses, the SinglePHY assures minimal power consumption with a compact form factor, ideally supporting a bandwidth of 100 MBit/s for a wide array of applications in the automotive and automation industries. Packed with capabilities, it supports Open Alliance TC10 Sleep/Wake cycles and offers functionalities like debug data streaming, and classification and localization of potential faults. Moreover, it employs a comprehensive suite of safety features including safety interrupts, reliability handling through safety protocols, and CRC checking to ensure data integrity. Siliconally's implementation ensures compliance with international standards, including IEEE 802.3 and Open Alliance test protocols. Designed in a 22FDX process, the SinglePHY is a practical and fully qualified solution across various automotive-grade conditions, promoting enhanced efficiency and dependability for critical communication tasks.
The Tyr AI Processor Family is a versatile line of high-performance chips designed to facilitate cutting-edge AI and autonomous vehicle applications. The family incorporates advanced scheduling and core management, allowing it to exceed standards in computational efficiency and power utilization. Capable of executing both AI and general-purpose processing tasks, Tyr chips can adapt to diverse computing needs without dependence on specific host processors. The design incorporates a multi-core architecture, enabling tiered performance capabilities – from entry-level to high-performance output. This makes the processors suitable for scaling applications from development to full deployment across various markets including automotive and industrial processing environments. Notably, Tyr processors emphasize seamless programmability using high-level coding, which allows straightforward incorporation of new AI models. Tyr’s commitment to low power consumption is evident in its technical configuration, which features a peak power consumption ranging from 10W to 60W, depending on the specific model. This, along with its modularity, ensures minimal environmental impact while achieving maximum computational output, fulfilling the growing demand for sustainable AI technology. In terms of architecture, the Tyr family supports any AI algorithm across a multitude of host processors, reflecting VSORA's vision for adaptable technology. This flexibility is crucial for handling real-time AI applications in dynamic domains like next-generation vehicular automation and intelligent systems design.
The SafeIP™ DualPHY is a versatile solution by Siliconally for 100/1000BASE-T1 communication. Ideal for automotive Ethernet applications, it balances versatility and safety, supporting high-speed data exchanges across both 100 and 1000 MBit/s bands. This dual-mode capability allows seamless switching and negotiation with communication partners, ensuring robust network performance even under varying conditions. Equipped with Siliconally's signature safety technologies, the DualPHY guarantees compliance with leading EMC protocols and offers the agility and reliability essential for contemporary automotive applications. Its architecture takes automotive-grade demands into account, focusing on efficient energy use and space-saving designs without compromising safety. The DualPHY ensures comprehensive EMC compliance, handling both conducting and radiating emissions effectively. It is constructed to accommodate the full spectrum of rigorous testing standards, affirming its status as a reliable and powerful semiconductor product for critical communication environments.
The CAN FD Full Controller is engineered to enhance the capabilities of standard CAN protocols by supporting both CAN 2.0B and extended CAN FD frames. With compliance to ISO 11898-1:2015, this controller optimizes communication reliability and data rate handling, making it suitable for modern automotive and industrial applications. Its design allows it to overcome the limitations of traditional CAN systems, facilitating improved data throughput, which is essential in sophisticated, real-time communication networks.
Genesis redefines package and PCB design with a comprehensive simulation-driven approach that optimizes the entire design process. By integrating simulations into the design workflow, Genesis allows for early detection and resolution of potential design issues in circuitry, electromagnetics, and thermal management. Its project management features enable streamlined collaboration across various design functions, ensuring that every aspect of the design is efficiently handled. Furthermore, it supports the cohesive creation of complex circuit designs and facilitates data management for diverse board-level and packaging projects. This platform enhances development efficiency and accelerates product design cycles.
The XRS7000 series switches are cutting-edge integrated circuits designed to add High-availability Seamless Redundancy (HSR) and Parallel Redundancy Protocol (PRP) functionality to devices. These chips provide zero-loss redundancy and are crucial for applications in industrial automation and networking equipment where reliability is key. Supporting both HSR and PRP, these switches ensure that no single point of failure can interrupt Ethernet communication. Leveraging the IEEE1588-2008 Precision Time Protocol, the XRS7000 series also facilitates precise time synchronization across networked devices. This capability not only enhances the reliability of Ethernet networks but also plays a pivotal role in applications requiring synchronized operations over multiple devices. The series includes different models like the XRS7003 and XRS7004, offering various port configurations to suit specific network requirements. These devices support robust protocols, quality of service features, and are compatible with gigabit Ethernet, providing an optimal balance of performance and redundancy for modern networking demands.
Designed for secure in-vehicle networking, the CANsec Controller Core is a cutting-edge solution for enhancing the security aspects of Controller Area Network (CAN) communications. This core integrates cryptographic protocols to safeguard automotive data transmissions from potential cyber threats, ensuring privacy and data integrity. Apart from boosting security, it also maintains the legacy CAN protocol’s simplicity and robustness, making it suitable for a wide range of automotive applications. This flexibility allows automotive manufacturers to upgrade existing systems with state-of-the-art security without necessitating a complete redesign. The CANsec Controller Core exemplifies Fraunhofer IPMS’s innovative approach to intertwining security with traditional automotive frameworks, ultimately leading to more secure and trustworthy in-vehicle communication systems.
The IMG DXS GPU is a versatile and scalable graphics processing unit engineered to manage both graphics and compute tasks adeptly. Especially optimized for automotive use, it supports advanced safety requirements while delivering high performance and power efficiency. This GPU includes unique safety mechanisms that allow it to achieve functional safety certifications without the typical trade-offs in power and area efficiency. With the advent of the DXS GPU, Imagination Technologies sets a new standard for automotive applications by integrating innovative safety features that maintain peak performance. The GPU's architecture is designed to handle a variety of workloads, from infotainment systems to autonomous driving visuals, making it an ideal choice for future-proof automotive applications. Its distributed safety mechanisms are particularly noteworthy, ensuring that even in the event of faults, the system can maintain operational integrity. Enhancements in this GPU not only raise the bar for secure graphic processing in vehicles but also provide developers with a robust foundation for creating applications that require both reliability and performance under stringent conditions. As the auto industry gravitates towards higher autonomous levels, the DXS GPU is poised to play a pivotal role in delivering next-gen in-car experiences.
NXP's Trimension UWB offering establishes itself as a key player in the realms of secure and precise short-range communication. This technology extends far beyond conventional wireless communication solutions by enabling high-precision location tracking and secure data exchanges, benefiting sectors like automotive, logistics, and various industrial applications. By leveraging ultra-wideband technology, Trimension UWB ensures that devices can communicate with pinpoint accuracy, accommodating scenarios that require fast and reliable location data. This characteristic is especially advantageous in applications such as autonomous vehicle navigation, smart logistics, and industrial automation, where precise communication is crucial. Furthermore, its adaptability across a wide range of devices makes it an essential component in the creation of smart, interconnected ecosystems. From improving operational efficiency to bolstering system security, Trimension UWB meets the demands of contemporary digital infrastructures, facilitating the development of tomorrow's intelligent solutions.
The CAN-CTRL controller core supports standard, extended, and CAN FD/XL specifications. It's renowned for its flexibility and integration efficiency in automotive and industrial networks. Designed with support for AUTOSAR and J1939, this core can be easily deployed across varied physical layers, ensuring reliable data transmission. Its small form factor and comprehensive interrupt and buffering features make it a suitable choice for modern vehicle network systems.
Broadcom's Automotive Multigigabit Ethernet Switch, known for its robust multilayer security features, is designed to revolutionize in-car networking. Integrating cutting-edge security technologies such as MACsec, this Ethernet switch enhances automotive network reliability by encrypting data transmitted over Ethernet lines, offering robust protection against cyber threats. The switch boasts a sophisticated array of multigigabit connectivity options, enabling it to support the latest automotive Ethernet standards. This functionality ensures seamless data exchanges between various electronic systems within a vehicle, facilitating advanced automotive technologies such as ADAS (Advanced Driver Assistance Systems) and autonomous driving platforms. Built to meet AEC-Q100 standards, it is ideally suited for automotive environments, where reliability and performance are non-negotiable. The integration of ARM Cortex M7 programmability allows further customization and capability expansion, making it a vital component in the burgeoning field of connected vehicle technology.
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