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.
The Ncore Cache Coherent Interconnect is designed to tackle the complexities inherent in multicore SoC environments. By maintaining coherence across heterogeneous cores, it enables efficient data sharing and optimizes cache use. This in turn enhances the throughput of the system, ensuring reliable performance with reduced latency. The architecture supports a wide range of cores, making it a versatile option for many applications in high-performance computing. With Ncore, designers can address the challenges of maintaining data consistency across different processor cores without incurring significant power or performance penalties. The interconnect's capability to handle multicore scenarios means it is perfectly suited for advanced computing solutions where data integrity and speed are paramount. Additionally, its configuration options allow customization to meet specific project needs, maintaining flexibility in design applications. Its efficiency in multi-threading environments, coupled with robust data handling, marks it as a crucial component in designing state-of-the-art SoCs. By supporting high data throughput, Ncore keeps pace with the demands of modern processing needs, ensuring seamless integration and operation across a variety of sectors.
The EW6181 GPS and GNSS solution from EtherWhere is tailored for applications requiring high integration levels, offering licenses in RTL, gate-level netlist, or GDS formats. This highly adaptable IP can be ported across various technology nodes, provided an RF frontend is available. Designed to be one of the smallest and most power-efficient cores, it optimizes battery life significantly in devices such as tags and modules, making it ideal for challenging environments. The IP's strengths lie in its digital processing capabilities, utilizing cutting-edge DSP algorithms for precision and reliability in location tracking. With a digital footprint approximately 0.05mm² on a 5nm node, the EW6181 boasts a remarkably compact size, aiding in minimal component use and a streamlined Bill of Materials (BoM). Its stable firmware ensures accurate and reliable position fixations. In terms of implementation, this IP offers a combination of compact design and extreme power efficiency, providing substantial advantages in battery-operated environments. The EW6181 delivers critical support and upgrades, facilitating seamless high-reliability tracking for an array of applications demanding precise navigation.
The Time-Triggered Protocol (TTP) is a cornerstone of TTTech's offerings, designed for high-reliability environments such as aviation. TTP ensures precise synchronization and communication between systems, leveraging a time-controlled approach to data exchange. This makes it particularly suitable for safety-critical applications where timing and order of operations are paramount. The protocol minimizes risks associated with communication errors, thus enhancing operational reliability and determinism. TTP is deployed in various platforms, providing the foundation for time-deterministic operations necessary for complex systems. Whether in avionics or in industries requiring strict adherence to real-time data processing, TTP adapts to the specific demands of each application. By using this protocol, industries can achieve dependable execution of interconnected systems, promoting increased safety and reliability. In particular, TTP's influence extends into integrated circuits where certifiable IP cores are essential, ensuring compliance with stringent industry standards such as RTCA DO-254. Ongoing developments in TTP also include tools and methodologies that facilitate verification and qualification, ensuring that all system components communicate effectively and as intended across all operating conditions.
Silvaco provides a suite of Automotive IP tailored for in-vehicle network standards and SoC designs. With support for CAN-FD, FlexRay, and LIN, these production-proven controllers are essential for automotive systems. The IP package includes subsystems and peripherals like Quad SPI, UART, and power management units, ensuring comprehensive support for system design.
eSi-ADAS is a radar IP suite designed to enhance the performance and responsiveness of automotive and unmanned vehicle systems. It includes a complete Radar co-processor engine, facilitating rapid situational awareness necessary for safety-critical applications. The scalable nature of this IP makes it adaptable for various automotive and drone-based projects.
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 RFicient chip is a cutting-edge technology designed to optimize power usage in IoT applications. This ultra-low-power receiver is ideal for environments requiring long-term battery operation, such as remote sensors in industrial IoT setups. With its efficient energy harvesting capabilities, the RFicient chip is pivotal in advancing sustainable technology solutions, reducing power consumption within the Internet of Things (IoT) framework.
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 CANsec Controller Core is crafted to cater to the emerging needs of secure in-vehicle communication systems. Adding a layer of security to the traditional Controller Area Network (CAN), this core incorporates advanced encryption and decryption capabilities, ensuring data is transmitted securely within the vehicle's network. With a rising number of electronic control units (ECUs) in vehicles, safeguarding the integrity and confidentiality of data is paramount, and CANsec excels in this domain. Emphasizing robust security protocols, the CANsec Controller Core is pivotal in protecting automotive systems from unauthorized access and cyber threats. It integrates seamlessly with existing CAN systems, allowing for an enhanced security overlay that does not compromise the network's performance or reliability. By ensuring the confidentiality and authenticity of the messages exchanged, this core addresses critical concerns in automotive cybersecurity, reinforcing trust in vehicular network communications. The versatile nature of CANsec allows it to be embedded in various ECUs, ensuring comprehensive protection across the network. As automakers increasingly rely on interconnected systems, this core supports the secure deployment of advanced features and services, enhancing consumer confidence in the safety and reliability of electronic vehicle systems.
The ADNESC ARINC 664 End System Controller by IOxOS Technologies is a high-performance solution tailored for avionic data networks. With full compliance to the RTCA DO-254 DAL A standards, this controller underscores IOxOS's commitment to delivering airworthiness and reliability. It is crafted using generic VHDL code, thus maintaining a device-independent architecture which ensures broad compatibility and ease of integration across various platforms. Capable of supporting multi-host interfaces with speeds up to 400 Mbit/s, the ADNESC controller handles complex communication protocols efficiently, making it an ideal component within data-intensive aerospace environments. The embedded SRAM further enhances its performance, providing swift data processing and reduced latency, which are critical in high-stakes operational settings. Designed with the foresight that aligns with the demands of modern aviation, this controller plays a crucial role in crafting resilient network backbones. Not only does it facilitate robust communication pathways, but it also delivers enhanced system reliability essential for mission-critical applications. Its integration into existing systems supports the development of next-generation avionic platforms tailored to meet the efficiency and scalability demands of future air travel.
PhantomBlu by Blu Wireless is engineered for defense applications, focusing on delivering high-speed, secure, and reliable tactical communications. This mmWave networking solution is designed to be independent of conventional fibre optic or cabled networks, granting greater flexibility and range. With the capability to easily integrate with both legacy platforms and upcoming technological assets, PhantomBlu ensures interoperability and robust connectivity in demanding environments. The mmWave technology used in PhantomBlu allows for multi-gigabit data transmission over significant distances, catering to the dynamic needs of military operations. It can be configured to function as a PCP (hub) or STA (client), enhancing its adaptability in tactical scenarios. This flexibility is vital for mission-critical communications, ensuring data-rich, secure connections even in highly contested environments. By employing low Probability of Detection (LPD) and Low Probability of Interception (LPI) techniques, PhantomBlu provides stealthy communication capabilities, significantly reducing the risks of detection and interference by adversaries. This advanced technology strengthens the defense sector's communication arsenal, providing reliable gigabit connectivity that supports strategic and operational superiority on the battlefield.
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.
InPsytech's Automotive IP Suite encompasses a comprehensive range of interfaces and controllers tailored for the automotive industry. These IPs are engineered to address unique automotive requirements such as reliability, safety, and performance, ensuring that automotive electronics meet regulatory standards and consumer expectations. The suite includes interfaces for common automotive communication protocols and specialized controllers for managing sensor inputs, power distribution, and data handling. By integrating these components, automotive manufacturers can enhance vehicle functionality and connectivity, paving the way for smarter, more secure vehicles. Given the industry's move towards autonomous and connected vehicles, InPsytech's automotive solutions prioritize scalability and compatibility with emerging technologies. Together, these features ensure that manufacturers can meet evolving demands, from electric vehicle support systems to advanced driver assistance applications.
The ASPER Radar Sensor is a cost-effective 79 GHz short-range mmWave radar. This innovative sensor is optimized for mobility applications and is an excellent alternative to ultrasonic park assist sensors, offering a 180° field of view with a single module. With its cutting-edge technological features, it enables superior detection of obstacles and supports multiple functionalities including gesture recognition and collision warnings. These features make it suitable for comprehensive vehicle awareness and assist systems.
The ACAM (Automotive In-Cabin Monitoring) is a 60 GHz mmWave radar sensor designed for monitoring within a vehicle's cabin. It features comprehensive coverage, detecting the presence of people without requiring a direct line of sight, which maintains passenger privacy. This system offers critical functionalities like child presence detection, seat occupancy information, and alerts for intrusion or proximity. Its compliance with the upcoming Euro NCAP 2025 protocol positions it as a leader in ensuring automotive safety and comfort.
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 XA035 Automotive Sensor Platform stands as a versatile and high-performance solution tailored for automotive applications. This IP is crafted using X-FAB's advanced CMOS technology to deliver precise sensor functions that meet the automotive industry's stringent standards. The platform facilitates robust integration within vehicular systems, aiding in the development of reliable and accurate automotive components that are critical under varying operational conditions. Designed to endure the demanding environments of automotive applications, the XA035 platform excels in adapting to temperature fluctuations, vibrations, and other environmental stresses, ensuring consistent performance of automotive electronics. It is pivotal for executing tasks such as pressure sensing, temperature monitoring, and other crucial vehicle diagnostics that contribute to enhanced safety and efficiency on the road. The XA035 platform also supports customization, enabling automotive manufacturers to tailor the sensors to specific requirements, thereby optimizing vehicle performance and fuel efficiency. It underscores X-FAB's dedication to innovation in the automotive sector, providing reliable semiconductor solutions that drive next-generation vehicular technology.
XH035 Sensor and High-Voltage Platform has been meticulously developed to cater to high-voltage and sensor integration needs, common in industrial and power applications. This high-performance platform blends the robustness of sensor technologies with the versatility of high-voltage handling, providing a dual advantage to manufacturers needing reliable and scalable solutions. The XH035 platform proficiently manages high-voltage operations while maintaining precise sensor data acquisition, making it ideal for a wide span of industrial applications, from automation to energy management. Its ability to handle high-voltage applications ensures operational consistency and reliability under extreme conditions, proving indispensable for sectors prioritizing durability and performance. Additionally, the platform's adaptability makes it suitable for custom developments, allowing engineers to design applications that meet specific technological needs. This capability reflects X-FAB's commitment to driving innovation and providing industries with semiconductor solutions that enhance operational efficiencies and application responses.
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