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 EW6181 GPS and GNSS Silicon is an advanced semiconductor solution specifically engineered for high-efficiency, low-power applications. This digital GNSS silicon offers a compact design with a footprint of approximately 0.05mm2, particularly when applied in 5nm semiconductor technology. Designed for seamless integration, the EW6181 combines innovative DSP algorithms and multi-node licensing flexibility, enhancing the overall device performance in terms of power conservation and reliability. Featuring a robust architecture, the EW6181 integrates meticulously calibrated components all aimed at reducing the bill of materials (BoM) while ensuring extended battery life for devices such as tracking tags and modules. This strategic component minimization directly translates to more efficient power usage, addressing the needs of power-sensitive applications across various sectors. Capable of supporting high-reliability location tracking, the EW6181 comes supplemented with stable firmware, ensuring dependable performance and future upgrade paths. Its adaptable IP core can be licensed in RTL, gate-level netlist, or GDS forms, adaptable to a wide range of technology nodes, assuming the availability of the RF frontend capabilities.
Ncore Cache Coherent Interconnect is designed to tackle the multifaceted challenges in multicore SoC systems by introducing heterogeneous coherence and efficient cache management. This NoC IP optimizes performance by ensuring high throughput and reliable data transmission across multiple cores, making it indispensable for sophisticated computing tasks. Leveraging advanced cache coherency, Ncore maintains data integrity, crucial for maintaining system stability and efficiency in operations involving heavy computational loads. With its ISO26262 support, it caters to automotive and industrial applications requiring high reliability and safety standards. This interconnect technology pairs well with diverse processor architectures and supports an array of protocols, providing seamless integration into existing systems. It enables a coherent and connected multicore environment, enhancing the performance of high-stakes applications across various industry verticals, from automotive to advanced computing environments.
The Time-Triggered Protocol (TTP) designed by TTTech is an advanced communication protocol meant to enhance the reliability of data transmission in critical systems. Developed in compliance with the SAE AS6003 standard, this protocol is ideally suited for environments requiring synchronized operations, such as aeronautics and high-stakes energy sectors. TTP allows for precise scheduling of communication tasks, creating a deterministic communication environment where the timing of data exchanges is predictable and stable. This predictability is crucial in eliminating delays and minimizing data loss in safety-critical applications. The protocol lays the groundwork for robust telecom infrastructures in airplanes and offers a high level of system redundancy and fault tolerance. TTTech’s TTP IP core is integral to their TTP-Controller ASICs and is designed to comply with stringent integrity and safety requirements, including those outlined in RTCA DO-254 / EUROCAE ED-80. The versatility of TTP allows it to be implemented across varying FPGA platforms, broadening its applicability to a wide range of safety-critical industrial systems.
The eSi-ADAS suite from EnSilica is a tailored collection of radar accelerator IPs designed to enhance automotive, drone, and UAV systems through advanced radar co-processing capabilities. This IP facilitates superior performance and enhanced situational awareness, crucial for applications requiring rapid and responsive decision-making. It merges cutting-edge radar technology with automotive standards, providing a robust platform for developing state-of-the-art driver assistance systems.\n\nThe suite’s radar co-processor engine is integral to improving radar system capabilities, ensuring that all signals are processed efficiently and accurately. This not only boosts the overall performance of radar systems but also aids in minimizing integration risks, streamlining the development process.\n\nFurthermore, eSi-ADAS supports various radar applications, enhancing safety and automation within the automotive sector. Its adaptability to UAV and drone designs also marks it as a versatile solution for unmanned systems, where responsiveness and precision are key.
The RFicient chip is designed to revolutionize the Internet of Things with its ultra-low power consumption. It enables devices to operate more sustainably by drastically reducing energy requirements. This is particularly important for devices in remote locations, where battery life is a critical concern. By leveraging energy harvesting and efficient power management, the RFicient chip significantly extends the operational life of IoT devices, making it ideal for widespread applications across industrial sectors.
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.
This specialized solution is designed specifically for enhancing communication safety within complex systems. The 100BASE-T1 PHY operates on GlobalFoundries' 22FDX platform, providing 100 MBit/s bandwidth while maintaining a compact chip size and very low power consumption, ensuring that safety-critical events are handled with precision. Key features include advanced debugging capabilities, transmission stop functions to reach a safe state, and elaborate diagnostics for cable faults. Its design is tailored to meet automotive grade standards, making it well-suited for the automotive sector's stringent requirements.
The CANsec Controller Core is an advanced security solution specifically tailored for the Controller Area Network (CAN) bus protocols commonly used in automotive applications. This core enhances the integrity and confidentiality of CAN network communications through robust encryption mechanisms, safeguarding against potential cyber threats. Designed for high compatibility, the CANsec Controller integrates smoothly into existing CAN infrastructures without the need for extensive reconfiguration. This adaptability allows automotive manufacturers to retrofit older models with contemporary security standards, thereby extending the lifecycle and safety of vehicles across all market segments. With its high-speed encryption and decryption processes, the CANsec Controller ensures real-time communications are not compromised. This efficiency is crucial in maintaining the latency constraints necessary for vehicle operations, especially as industries move towards more autonomous functionalities. The core's ability to secure internal communications helps manufacturers address growing cybersecurity concerns in today's connected vehicle landscape, ensuring secure data exchange within vehicular networks.
Designed with flexibility and performance in mind, the DualPHY offers 100/1000BASE-T1 mode capabilities on the robust GlobalFoundries 22FDX technology. This product caters to the automotive and industrial sectors, facilitating communication speeds of 100 MBit/s and 1 GBit/s. The advanced autonegotiation capabilities enhance its versatility, while maintaining high standards of EMC compliance required for both automotive and industrial applications. Dual PHY provides a flexible communication link with enhanced safety features bridging the gap between current and future needs of high-speed data transmission in sophisticated networks.
PhantomBlu by Blu Wireless represents a cutting-edge advancement in tactical defense communications. This mmWave technology solution is expertly constructed to deliver stealthy, gigabit-level connectivity on the move, supporting high-speed tactical operations. PhantomBlu's low SWAP (Size, Weight, and Power) tactical solutions, configurable as PCP (hub) or STA (client), align with dynamic defense needs by providing dependable communications at range. The system capitalizes on spectrum availability and equipment flexibility, offering interoperability for both legacy systems and future assets without dependence on traditional networks. This capability makes PhantomBlu an invaluable tool for military forces requiring swift, secure, and adaptable communications to maintain operational efficacy in complex environments. The PhantomBlu system plays a pivotal role in transforming how modern military operations are conducted by seamlessly integrating with existing communications bases and enhancing mission-based applications. The flexibility of the configurable options supports high-performance execution, ensuring that military communication networks are responsive and robust in the face of evolving tactical demands.
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.
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.
IMG DXS GPU is engineered to meet the needs of automotive and industrial applications where functional safety is paramount. Built on efficient PowerVR architecture, it ensures high-performance graphics rendering with a focus on reduced power consumption. The DXS technology supports comprehensive safety suites, catering to ADAS and digital cockpit applications, thereby addressing stringent automotive safety standards.
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 Tyr Superchip represents the pinnacle of Edge AI innovation, bringing unrivaled intelligence closer to the action. This powerful chip achieves impressive AI processing capabilities with up to 1600 Tflops, making it suitable for environments that demand immediate data analysis and decision-making, such as smart factories and autonomous vehicles. It performs local AI model processing, reducing dependency on cloud services, resulting in lower latency, preserved bandwidth, and enhanced data security. This product is ideal for real-time applications, offering substantial improvements in speed and safety, while maintaining operational efficiency. The Tyr Superchip supports various applications where Edge AI is crucial, minimizing costs and reducing environmental impact through sustainable AI deployment. As part of VSORA's innovative approach, the Tyr Superchip delivers data center-like computation at the edge, transforming how industries such as manufacturing and autonomous systems utilize AI for enhanced decision-making and process optimization.
The Automotive Multigigabit Ethernet Switch with Multilayer Security is crafted to support advanced in-vehicle networking solutions, providing automotive manufacturers with an infrastructure capable of handling today's demanding data and connectivity needs. This highly integrated switch supports multiple gigabits of communication within the vehicle network, ensuring swift and efficient data transfer. Security is a paramount feature of this Ethernet switch, with multilayer protection mechanisms ensuring data integrity and network safety. It incorporates advanced cryptographic technologies to guard against potential threats, ensuring that vehicle communication remains uncompromised and secure. Engineered for automotive-grade reliability, this switch boasts robust design features tailored to withstand the rigors of the automotive environment, including temperature variability and electromagnetic interference. By adopting this switch, automotive manufacturers can enhance vehicle safety systems, entertainment, and connectivity, promoting a more integrated and secure driving experience.
APIX3 Technology expands upon previous generations by providing up to 12Gbps data transfer over simple shielded twisted pair or advanced quad twisted pair cables. This capability supports multiple high-definition video streams for advanced infotainment and cockpit applications. It enhances flexibility and performance in automotive networking through backward compatibility, full duplex communication, and advanced diagnostic and cable monitoring features.
The XH035 platform merges sensor and high-voltage technology into a robust 350 nm process. It features a 3.3 V core module that prioritizes ultra-low noise and is complemented by an optional 5 V dual gate module. Designed for durability, the platform supports high operating temperatures and integrates a mix of digital, analog, high-voltage, and non-volatile memory technologies. This adaptability makes it ideal for sensor and sensor interface applications, especially in challenging environments. Its comprehensive PDK support across major EDA vendors ensures seamless implementation in diverse design environments.
XA035 is a versatile 350 nm platform designed for automotive sensor applications, featuring a 3.3 V ultra-low noise process with extensions up to 5 V. It maintains robust performance in harsh environments, supporting a wide temperature range of -40 to 175°C compliant with AEC-Q100 grade 0. The platform integrates digital, analog, HV, and NVM elements within a single process. It is well-suited for sensor interfaces and actuator controls in automotive systems, with high-reliability non-volatile memory solutions. The XA035’s versatility is underscored by its comprehensive PDK support, ensuring ease of integration across various EDA tools.
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