All IPs > Automotive > FlexRay
FlexRay is a high-speed, deterministic and fault-tolerant communications protocol used in advanced automotive systems. Developed to meet the demanding requirements of in-vehicle networking, FlexRay serves as a backbone for data exchange in cars, enabling reliable, high-bandwidth communication links. In our Automotive > FlexRay category, you'll find a variety of FlexRay semiconductor IPs that are crucial for building robust communication networks in modern vehicles.
These semiconductor IPs are particularly valuable for applications where safety and reliability are paramount. FlexRay provides a communication standard that supports the coordination between various electronic control units (ECUs) in a vehicle. This ensures that critical systems such as braking, steering, and engine control can interact seamlessly, fostering advancements in automotive technology like advanced driver-assistance systems (ADAS) and autonomous driving features.
Within this category, you will encounter a selection of IPs that offer features like high-speed data transfer, synchronization precision, and error detection mechanisms. These are essential for implementing systems that require exact timing and fail-safe operations. FlexRay's deterministic nature means that it can handle time-sensitive data efficiently, making it a preferred choice for manufacturers looking to enhance the electronic architecture of their automobiles.
As automotive technology continues to evolve, the demand for sophisticated communication protocols like FlexRay grows. Our collection of FlexRay semiconductor IPs provides the necessary tools for automotive engineers and designers to innovate and create vehicles that are not only smarter but also safer and more reliable. Explore our offerings to find the right IP solutions that match your automotive communication needs.
Silvaco's Automotive IP is engineered for in-vehicle networks and covers an extensive range of controllers adhering to automotive standards like FlexCAN with CAN-FD, FlexRay, and LIN. These products are production-proven and designed to integrate seamlessly into the SoC's subsystems, ensuring reliability and a high degree of interoperability. This suite of automotive IP is packaged to simplify design processes, reduce time-to-market, and ensure compliance with industry safety standards, making it indispensable in the evolving automotive landscape.
AndesCore Processors offer a robust lineup of high-performance CPUs tailored for diverse market segments. Employing the AndeStar V5 instruction set architecture, these cores uniformly support the RISC-V technology. The processor family is classified into different series, including the Compact, 25-Series, 27-Series, 40-Series, and 60-Series, each featuring unique architectural advances. For instance, the Compact Series specializes in delivering compact, power-efficient processing, while the 60-Series is optimized for high-performance out-of-order execution. Additionally, AndesCore processors extend customization through Andes Custom Extension, which allows users to define specific instructions to accelerate application-specific tasks, offering a significant edge in design flexibility and processing efficiency.
Time-Triggered Ethernet is a specialized communication protocol developed to incorporate the deterministic properties of traditional time-triggered systems within the robust and widely used Ethernet networking technology. It serves industries that require high precision and reliable data transmissions, like aerospace and automotive systems, where safety is paramount and timing is critical. This protocol extends conventional Ethernet by adding timestamping and scheduling features, enabling precise control over data transmission times. By doing so, it ensures that data packets are transmitted predictably within fixed timeslots, providing a network solution that combines the widespread adoption of Ethernet with high determinism demands. Time-Triggered Ethernet thus bridges the gap between standard Ethernet's flexibility and the strict timing requirements of critical systems. Applications of Time-Triggered Ethernet span from integrating advanced avionics systems to enabling reliable communication in autonomous vehicle networks. Its design supports modularity and scalability, allowing it to adapt as systems become more complex or requirements change, without sacrificing the precise timing and reliability essential for real-time communications in critical applications.
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 Universal NAND Flash Controller (UNFC) from IP Maker provides a complete solution for integrating NAND flash technology into enterprise storage systems. It is specifically designed to manage high data throughputs and large interconnect bandwidths, which are crucial for high reliability applications. The UNFC is compatible with ONFI 5.x specifications and supports a range of NAND technologies, including SLC, MLC, TLC, and QLC, all while maintaining low costs. The IP core is versatile, supporting AXI, Avalon, and RAM interfaces for seamless system integration. The UNFC delivers adaptive support for multiple flash modes and integrates a robust ECC configuration that aligns with vendor-specific requirements. This makes it an ideal choice for developers looking to optimize data reliability and system performance. By integrating ECC, the controller offers significant protection against data corruption, vital for safeguarding data integrity in high-performance storage environments. Equipped with flexible configuration options, developers can tailor the controller to specific project needs, ensuring an optimal fit for various NAND architectures. This controller is especially effective for reducing time-to-market for storage OEMs by allowing rapid integration of NAND flash with enterprise systems, thus enhancing IOPS performances.
ArrayNav represents a significant leap forward in navigation technology through the implementation of multiple antennas which greatly enhances GNSS performance. With its capability to recognize and eliminate multipath signals or those intended for jamming or spoofing, ArrayNav ensures a high degree of accuracy and reliability in diverse environments. Utilizing four antennas along with specialized firmware, ArrayNav can place null signals in the direction of unwanted interference, thus preserving the integrity of GNSS operations. This setup not only delivers a commendable 6-18dB gain in sensitivity but also ensures sub-meter accuracy and faster acquisition times when acquiring satellite data. ArrayNav is ideal for urban canyons and complex terrains where signal integrity is often compromised by reflections and multipath. As a patented solution from EtherWhere, it efficiently remedies poor GNSS performance issues associated with interference, making it an invaluable asset in high-reliability navigation systems. Moreover, the system provides substantial improvements in sensitivity, allowing for robust navigation not just in clear open skies but also in challenging urban landscapes. Through this additive capability, ArrayNav promotes enhanced vehicular ADAS applications, boosting overall system performance and achieving higher safety standards.
aiData introduces a fully automated data pipeline designed to streamline the workflow of automotive Machine Learning Operations (MLOps) for ADAS and autonomous driving development. Recognizing the enormous task of processing millions of kilometers of driving data, aiData employs automation from data collection to curation, annotation, and validation, enhancing the efficiency of data scientists and engineers. This crafted pipeline not only facilitates faster prototyping but also ensures higher quality in deploying machine learning models for autonomous applications. Key components of aiData include the aiData Versioning System, which provides comprehensive transparency and traceability over the data handling process, from recording to training dataset creation. This system efficiently manages metadata, which is integral for diverse use-cases, through advanced scene and context-based querying. In conjunction with the aiData Recorder, aiData automates data collection with precise sensor calibration and synchronization, significantly improving the quality of data for testing and validation. The aiData Auto Annotator further enhances operational efficiency by handling the traditionally labor-intensive process of data annotation using sophisticated AI algorithms. This process extends to multi-sensor data, offering high precision in dynamic and static object detection. Moreover, aiData Metrics tool evaluates neural network performance against baseline requirements, instantly detecting data gaps to optimize future data collection strategies. This makes aiData an essential tool for companies looking to enhance AI-driven driving solutions with robust, real-world data.
The Time-Triggered Protocol (TTP) is an advanced communication protocol designed for highly reliable and deterministic networks, primarily utilized in the aerospace and automotive sectors. It provides a framework for the synchronized execution of tasks within a network, facilitating precise timing and coordination. By ensuring that data transmission occurs at predetermined times, TTP enhances the predictiveness and reliability of network operations, making it vital for safety-critical applications. The protocol is engineered to function in environments where reliability and determinism are non-negotiable, offering robust fault-tolerance and scalability. This makes it particularly suited for complex systems such as those found in avionics, where precise timing and synchronization are crucial. The design of TTP allows for easy integration and scalability, providing flexibility that can accommodate evolving system requirements or new technological advancements. Moreover, TTP is characterized by its rigorous adherence to real-time communication standards, enabling seamless integration across various platforms. Its deterministic nature ensures that network communications are predictable and maintain high standards of safety and fault tolerance. These features are crucial in maintaining operational integrity in critical applications like aerospace and automotive systems.
ZORM is a state-of-the-art radar sensor designed for monitoring industrial zones, offering exceptional performance in detecting objects or individuals within defined safety areas. With comprehensive field disturbance capabilities, ZORM ensures maximum safety by identifying potential collision risks with high reliability, thus minimizing downtime in industrial environments. Its robust design allows for seamless integration into existing safety systems, ensuring uninterrupted operation even in challenging environments. ZORM's capability to function through obstructions like fog, rain, and total darkness makes it a perfect addition to any security system aiming for comprehensive coverage. ZORM is particularly beneficial in environments requiring smart access and safety zones monitoring. It offers a trustworthy security solution with low false alarm rates, assisting operators by concentrating on genuine alarms. Its versatility extends to various applications, including automated shutdown systems, which respond instantly to potential safety breaches, protecting both personnel and machinery.
The Time Sensitive Network IP Core is an advanced solution explicitly crafted to support time-critical network environments. It offers remarkable precision and fault tolerance, making it ideal for applications where timing accuracy is paramount. Capable of scaling from 1Gbps to 10Gbps, this core is engineered to provide robust anti-masquerading and babbling protection functions. Integrated with the widely adopted AXI standard, the network core facilitates easy interfacing between hardware and software, which is essential for developers looking to integrate it within diverse systems efficiently. This ease of integration is coupled with its fault tolerance capabilities, ensuring network reliability in complex deployments. Applications that significantly benefit from this IP core include industrial automation, telecommunications, and any domain requiring synchronized processing and high-reliability data exchange. The Time Sensitive Network IP Core is invaluable in enhancing system efficiencies and ensuring data integrity across demanding operational environments.
Time-Sensitive Networking (TSN) is designed to enhance standard Ethernet networks by introducing features that guarantee precise data transmission timing, particularly for real-time applications. TSN enables a high level of network determinism in environments where timing and reliability are essential, catering to industries such as industrial automation, automotive, and aerospace. TSN builds on IEEE 802.1 standards, ensuring compatibility with existing Ethernet infrastructures while providing enhanced capabilities for data traffic management. This ensures that time-critical data is prioritized, allowing for the time-sensitive exchange of information alongside regular network traffic. The technology is essential in systems where real-time data transfer is a necessity, such as control systems in manufacturing or advanced driver-assistance systems in vehicles. By supporting both predictable and high-speed data transmission, TSN is integral to networks that require a mix of determinism and flexibility. It provides the necessary framework for developing sophisticated and scalable networks that can adapt to increased data loads and complex system architectures, thus supporting innovation in various technological fields.
Deterministic Ethernet provides a communication protocol designed to ensure predictable and reliable data transmission over Ethernet networks, making it ideal for applications requiring stringent timing and synchronization. It is particularly suited to environments where data must be transferred within precise timing constraints, such as those found in aerospace and industrial automation. This protocol maintains the broad compatibility of Ethernet while incorporating features that enhance determinism. This makes it suitable for safety-critical applications where any delay or data loss could be detrimental. Deterministic Ethernet achieves this by prioritizing time-critical data over standard data, ensuring seamless real-time communication. In practice, Deterministic Ethernet is instrumental in integrating complex systems, such as aircraft avionic systems or industrial automation processes, offering a reliable and scalable communication solution. The protocol’s ability to manage data traffic effectively without compromising on timing precision makes it essential for next-generation technologies that demand both reliability and high performance.
The SMS OC-3/12 Transceiver Core addresses the high-speed demands of optical data communications within SONET/SDH specifications. Built to handle 155 Mbps (OC-3) and 622 Mbps (OC-12) transmission rates, it supports a variety of telecom applications. This core integrates critical components such as clock synthesis, clock recovery, and wave shaping functions, ensuring compliance with ITU-T and ANSI standards. A standout feature of the transceiver is its innovative use of a deep sub-micron single poly CMOS process, which guarantees low power consumption and high integration density. The design incorporates advanced signal processing for jitter management, meeting Bellcore and ITU-T specifications, which is crucial for reliable network performance. This core supports various integration scenarios, including the use of reusable building blocks for multi-port applications. Moreover, its architecture facilitates process migration, making it adaptable for emerging telecom technologies. The integration-ready LVPECL and LVDS interfaces simplify external connections to optical units, reinforcing its use in complex system-on-chip designs.
The RISC-V CPU IP NA Class is tailored for automotive applications, particularly focusing on the ISO26262 Functional Safety Automotive standards. Built for performance and compliance, the NA Class aims to address the increasingly stringent safety requirements in automotive electronics. This processor class is adept at integrating functional safety features standardized for automotive applications, ensuring compliance with ASIL (Automotive Safety Integrity Level) standards. Through these features, the NA Class supports the robust and reliable operation of automotive systems, essential for modern vehicular technologies. The NA Class is fortified with a suite of safety and security elements, making it an ideal candidate for powering automotive systems that require rigorous reliability testing. Its tailored development tools, including SDKs and simulation environments, facilitate efficient development cycles and integration into automotive platforms.
The ARINC 429 Receiver IP Core from SafeCore is designed according to the specifications of the ARINC Specification 429 Part 1-17. It is an essential component in avionics, providing a standardized way of receiving data from various parts of an aircraft. This core is built to ensure accurate and reliable data transmission over the ARINC 429 bus, which remains a critical communication standard within the aerospace industry. Primarily used in aviation electronics, the ARINC 429 protocol enables transmission across simplex wired pair links in both bit-oriented format and label sequence manner. This receiver core captures these data streams and processes them for display and interfacing within the avionics systems, ensuring seamless communication between different subsystems within an aircraft. The ARINC 429 Receiver IP is specially tailored to work under the constriction of harsh airborne operational environments. Its robustness ensures that data integrity is preserved even under conditions of high interference, providing high reliability for vital aircraft systems. SafeCore also supplies this core with adequate certification documentation, aiding integration into safety-critical avionics systems.
SafeCore's ARINC 429 Transmitter IP Core is designed to provide seamless and efficient transmission of data according to the ARINC Specification 429 Part 1-17. This core facilitates reliable data dispatch within avionics systems, crafting a dedicated solution for aircraft communication infrastructure, where consistent and error-free data transfer is critical. The transmitter core operates over the ARINC 429 bus, employing a simplex method of transmission which is traditional in aviation for interconnecting various aircraft synchronized systems. The core supports the clock and data signal synchronization necessary for maintaining data fidelity across extensive distances within the craft. SafeCore ensures that this transmitter meets the demands of high-performance environments typical for aerospace and avionics, offering advanced features for error correction and data integrity assurance. Accompanied by a complete certification kit, this transmitter core can be seamlessly integrated into advanced airborne systems demanding reliable performance under stringent regulatory compliance standards.
Renowned for its precision and reliability, the ARINC 429 IP by Logic Design Solutions enables seamless integration of ARINC 429 protocols into FPGA systems, which is crucial for aviation and aerospace communication systems. Designed to meet industry standards, this IP offers a reliable interface for data communication according to the ARINC 429 specifications, which is vital for avionics systems and ensuring compliant and efficient communication between systems. The IP facilitates streamlined communication by integrating robust error-checking and data validation features to ensure the integrity and correctness of information being sent across aviation systems. Its flexible architecture allows for customization to specific system requirements, providing developers with the tools to tailor the IP for diverse applications in aerospace environments. Its deployment greatly enhances communication capabilities in aeronautic systems, offering robust support for interfacing and connectivity that adheres to the demanding standards of the aviation industry. By using ARINC 429 IP, developers can ensure their communication systems are equipped with the necessary functionality and reliability needed to support complex and crucial flight operations.
The XR7 Redundancy Supervision software is an essential component for managing HSR and PRP networks reliably. Offering a fully compliant IEC 62439-3:2016 stack, it transmits, receives, and processes HSR and PRP supervision frames, maintaining network integrity across multiple nodes. Written in C, the XR7 Redundancy Supervision is compatible with Linux-based systems and easily ported to other environments through its abstraction layer design. It maintains a NodesTable, essential for detailed network management, by recording active components in the network based on the supervision frames received, thus helping ensure high network reliability. This supervision solution can be integrated with Flexibilis’ hardware offerings such as the Redundant Switch, improving network reliability through automated redundancy management. With adjustable supervision frame transmission and efficient timer settings, XR7 fits into various applications from industrial automation to communication networks requiring meticulous redundancy management.
The CCE4511 IO-Link Master Controller is engineered for high-speed data communication, particularly in industrial automation environments. This controller facilitates seamless integration and communication across various devices, ensuring high reliability and real-time data transfer. By supporting multiple IO-Link devices, it simplifies network architecture and enhances system interoperability for improved productivity.
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