All IPs > Automotive > CAN-FD
CAN-FD (Controller Area Network with Flexible Data-Rate) semiconductor IPs represent an evolution in the communication systems used within automotive networks. These IPs are designed to increase the data throughput and efficiency of traditional CAN networks, meeting the demands of contemporary automobile systems that require robust and fast communication protocols. As modern vehicles become more complex, integrating advanced features such as autonomous driving capabilities, real-time data processing, and enhanced infotainment systems, the need for efficient communication solutions like CAN-FD becomes imperative.
CAN-FD semiconductor IPs provide significant advantages over traditional CAN technology. With their ability to handle larger data frames and higher transmission speeds, they are essential for supporting next-generation automotive protocols. This enhanced capability ensures that automotive systems can cope with the increased volume and variety of data exchanged between electronic control units (ECUs), sensors, and actuators. This is crucial for the seamless operation of safety systems, advanced driver-assistance systems (ADAS), and other intricate vehicle functions.
In this category, you'll find a wide range of semiconductor IPs that cater to various automotive applications. These include IP cores offering various levels of compliance and configuration options to suit specific needs, from basic CAN-FD implementations to more sophisticated versions integrating additional features like cybersecurity measures or advanced error detection and correction. Designers can integrate these IPs into automotive system-on-chips (SoCs), ensuring high reliability and conformity with industry standards.
Whether you're developing new automotive architectures or upgrading existing systems, deploying CAN-FD semiconductor IPs is a crucial step towards achieving higher performance and reliability in vehicular communications. These solutions not only empower the automotive industry to implement faster and more efficient networks but also pave the way for future innovations in automotive technology. By choosing the right CAN-FD IPs, manufacturers and developers can ensure that their vehicles are equipped to handle the ever-expanding technological requirements and consumer expectations of tomorrow's automotive landscape.
Efinix's Topaz FPGA series is engineered for mass-market applications, delivering a perfect mix of efficiency and adaptability. These FPGAs encapsulate a highly efficient architecture, combined with the industry's essential features and protocols, such as PCIe Gen3, MIPI, and LPDDR4. This configuration allows users to harness substantial performance while maintaining ample room for future innovations. Topaz FPGAs are optimized for high-volume production environments where cost-effectiveness and swift integration are paramount. Their design promotes ease of implementation in various applications, spanning from automotive to deeply embedded systems, where reliability and robustness are key. Featuring a streamlined architecture, Topaz series FPGAs support modern connectivity standards and data processing capabilities. These devices are tailored for industries requiring scalable solutions that can adapt to evolving technological landscapes, ensuring that Efinix customers remain competitive in their respective fields.
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.
The CANmodule-III is a highly advanced Controller Area Network (CAN) controller designed for sophisticated applications that require full CAN2.0B compliance. This IP module optimizes communication on the CAN bus by efficiently handling message transactions with support for FIFO and mailbox-based architectures. With a focus on system reliability, the CANmodule-III ensures seamless data flow and is versatile for various industry applications such as automotive and aerospace networks. The CANmodule-III supports an expansive set of features including enhanced diagnostic capabilities, making it ideal for applications that demand high reliability and advanced fault-tolerant functionalities. Its modular design is key for dynamic environments where scalability and flexibility are paramount. By utilizing a robust design approach based on Bosch's fundamental CAN architecture, this controller ensures compatibility and conformance with international standards, streamlining integration into existing systems. Inicore's commitment to excellence is embodied in the CANmodule-III’s design, which not only simplifies the integration process but also provides users the ability to customize functionalities. Whether the need is for rapid prototyping using FPGAs or volume production with ASICs, the CANmodule-III stands out as a preferred choice owing to its proven performance and adaptability.
The CANmodule-IIIx represents an evolution in CAN controller IP, offering an advanced set of features and capabilities for high-demand applications. This module builds upon the strengths of its predecessor with extended mailbox support, featuring 32 receive and 32 transmit mailboxes which enhance message handling capacity and ensure higher data throughput and reduced latency. For industries such as industrial automation and telecommunications, where complex data transactions are constant, the CANmodule-IIIx provides a robust platform capable of managing these requirements with efficiency and reliability. The IP module supports customization and can be seamlessly integrated into larger system architectures, enabling greater functionality and performance tuning for specific application needs. Designed with a focus on flexibility, this module adheres to CAN2.0B standards while offering unique enhancements for user-defined add-ons. These features allow for superior adaptability and scalability, making CANmodule-IIIx a versatile solution across various sectors requiring sophisticated CAN bus communications.
Inicore's CANmodule-IIx is a FIFO-based Controller Area Network (CAN) controller IP that provides efficient and reliable communication solutions for less complex systems that still require robust CAN functionality. With the flexibility of FIFO architecture, this module is designed for systems where message ordering and buffering are crucial yet straightforward. The CANmodule-IIx facilitates seamless data exchange over the CAN bus, ensuring that all message transactions comply with the CAN2.0B standard. This makes it particularly well-suited for automotive applications, as well as industrial systems needing basic to intermediate communication capabilities while maintaining a cost-effective footprint. As part of Inicore’s vast IP portfolio, the CANmodule-IIx is engineered with a focus on simplifying integration and reducing design complexity. Its FIFO architecture provides not only reliable communication but also enhanced data handling capabilities, allowing seamless implementation in various FPGA and ASIC environments, supporting rapid development and deployment.
Silvaco's Automotive IP solutions are designed for the rigorous demands of modern automotive systems, delivering reliability and efficiency needed for in-vehicle networks and system-on-chip (SoC) designs. These IP offerings include controllers and subsystems that adhere to industry standards like CAN-FD, FlexRay, and LIN, ensuring all facets of vehicular communication are covered. A key component of their automotive IP suite is the ability to deliver high-speed, precise communication solutions within vehicles, greatly enhancing the safety and functionality of automotive electronics. Moreover, Silvaco provides support for complex SoC designs that incorporate advanced features like secure data transmission and efficient power management. These solutions are optimized for the challenges of automotive environments, enabling designers to meet stringent requirements, such as safety and reliability. By focusing on customization and integration, Silvaco's automotive solutions empower automotive manufacturers to innovate and realize cost-effective, future-ready designs.
The Flexibilis Redundant Switch (FRS) is an advanced Ethernet Layer-2 switch IP core that offers comprehensive support for High-Availability Seamless Redundancy (HSR) and Parallel Redundancy Protocol (PRP). Designed for programmable hardware like FPGAs, it is an integral solution in industrial networks where fail-safe operation is critical. FRS is equipped with the ability to manage multiple types of ports, providing the flexibility needed for various configurations and redundancy schemes. With features that allow full-duplex operation and wire-speed forwarding, FRS ensures data packet processing is efficient and reliable. Its ability to support both end-to-end and peer-to-peer transparent clock synchronization with IEEE 1588v2 enhances its utility in environments that demand precise timing, such as in power grids and industrial automation systems. The switch can operate seamlessly across different link speeds and types, which is essential for diverse network infrastructures. FRS simplifies network architecture by removing the need for separate RedBoxes, encouraging cost-effective solutions in deploying redundant protocols. Its performance, ease of use, and scalability make it a key component in enhancing network resilience and responsiveness in automated systems across various industries.
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.
Perfect for advanced parking solutions, the ASPER radar sensor operates at 79GHz, providing superior performance compared to traditional ultrasonic systems. Designed to deliver a 180° coverage with a single module, it offers enhanced detection capabilities for both passenger and commercial vehicles. ASPER's edge processing and domain-specific features make it ideal for automotive applications like blind spot detection and tailgate protection, while ensuring accuracy unaffected by environmental conditions.
SiFive Automotive E6-A reflects a significant step forward for RISC-V in the automotive domain, emphasizing safety and performance. The E6-A series is designed with automotive-grade robustness, adhering to modern functional safety standards such as ISO26262 ASIL B. This series is tailored to meet the stringent demands of contemporary automotive applications, including advanced driver-assistance systems (ADAS) and infotainment. The 32-bit E6-A processors are particularly optimized for achieving balanced power and performance metrics, critical for real-time in-vehicle applications. These processors support functional safety requirements and are built to operate effectively within the constrained environments typical of automotive systems. With support for secure, deterministic processing, the E6-A series fosters enhanced security and performance in vehicles, ensuring that these processes can be executed reliably and efficiently. SiFive collaborates closely with automotive OEMs to ensure their solutions align well with the industry's future technology roadmaps.
Time-Triggered Protocol is an advanced synchronization mechanism designed for precise communication in networked systems. It establishes a highly predictable framework where data exchange is timed to occur at regular intervals, ensuring timely communication regardless of network load. This deterministic approach guarantees that information is consistently delivered at the right time, which is particularly crucial for applications that demand heightened reliability and precision. This protocol is widely adopted in applications where timing and coordination are critical. By employing a globally synchronized time base across network nodes, the Time-Triggered Protocol minimizes delays and jitter, fostering an environment of high reliability. Its design inherently supports fault-tolerant systems, increasing the dependability of networks deployed in domains such as aerospace, automotive, and industrial automation. One of the key highlights of the Time-Triggered Protocol is its ability to integrate seamlessly with various systems, maintaining synchronization and order even in complex setups. This integration capability supports scalability, allowing systems to expand without compromising the timing accuracy and integrity of communications.
The Digital PreDistortion (DPD) Solution by Systems4Silicon is a cutting-edge technology developed to maximize the power efficiency of RF power amplifiers. Known as FlexDPD, this solution is vendor-independent, allowing it to be compiled across various FPGA or ASIC platforms. It's designed to be scalable, optimizing resources according to bandwidth, performance, and multiple antennae requirements. One of the key benefits of FlexDPD is its substantial efficiency improvements, reaching over 50% when used with modern GaN devices in Doherty configurations, surpassing distortion improvements of 45 dB. FlexDPD is versatile, operating with communication standards including multi-carrier, multi-standard, and various generations from 2G to 5G. It supports both time division and frequency division duplexing, and can accommodate wide Tx bandwidths, limited only by equipment capabilities. The technology is also agnostic to amplifier topology and transistor technology, providing broad applicability across different setups, whether class A/B or Doherty, and different transistor types like LDMOS, GaAs, or GaN. This technology integrates seamlessly with Crest Factor Reduction (CFR) and envelope tracking techniques, ensuring a low footprint on resources while maximizing efficiency. With complementary integration and performance analysis tools, Systems4Silicon provides comprehensive support and documentation, ensuring that clients can maximize the benefits of their DPD solution.
EnSilica's eSi-ADAS is a comprehensive radar accelerator suite designed to enhance the capabilities and performance of radar systems. It is particularly suited for automotive, drone, and UAV applications where quick, responsive situational awareness is critical. This radar co-processor engine enables rapid data processing, contributing significantly to vehicle safety systems and providing a real-time operational advantage. It boasts efficient integration with existing systems, maximizing the benefits of advanced digital signal processing (DSP) techniques tailored to radar applications. By accelerating radar algorithm execution, this IP helps designers create more efficient detection systems and improve the operational reliability of advanced driver-assistance systems (ADAS).
Ncore Cache Coherent Interconnect from Arteris is a sophisticated NoC interconnect solution engineered to tackle the multifaceted challenges of designing modern multi-core ASICs. Ncore's architecture supports various protocols and processors, including Arm and RISC-V, to foster more efficient inter-core communication, power optimization, reliability, and safety in complex SoCs. The IP is especially lauded for its ability to maintain comprehensive coherence for cached processors and I/O coherency, adapted for accelerators and different component communications within the SoC. It also supports ISO 26262 standards for functional safety compliance, making it a prime candidate for use in safety-critical applications. Noteworthy features include true heterogeneous coherency integrated with AMBA CHI and ACE support, making it ideal for creating high-performance, flexible SoC designs that address stringent safety and power consumption concerns. Additionally, Ncore enables advanced configuration of snoop filters, quality of service management, and debugging capabilities, thereby optimizing power usage and integration complexity. The flexibility in topologies and robust support for various coherent agents make Ncore an invaluable asset for SoC developers seeking modular, scalable design options for diverse applications.
The CAN Controller IP Core is designed for automotive applications that require efficient real-time data transmission. Offering support for both standard and extended frames, this IP core is suitable for a range of automotive applications. It provides reliable data throughput, supports error detection and is compliant with the CAN 2.0A/B standard, allowing integration into diverse vehicle networks.
The DCAN XL is a cutting-edge CAN bus controller that bridges the capabilities of CAN FD with those of 100Mbit Ethernet. This innovation supports data rates reaching 20 Mbit/s, facilitating both CAN transceivers for lower bitrates and CAN SIC XL transceivers for higher bitrates above 10Mbps. Designed for advanced network systems, the DCAN XL ensures dependable data integrity across large-scale communications. As a future-ready controller, it aligns with the evolving requirements of industrial and automotive applications, ensuring seamless data exchange and integration across complex systems.
aiSim 5 stands out as the first ISO26262 ASIL-D certified simulator tool designed for validating ADAS (Advanced Driver-Assistance Systems) and AD (Automated Driving) technologies. This simulator offers an unparalleled environment for testing automated driving systems, utilizing a highly optimized sensor simulation framework which ensures robust performance in runtime. Its advanced rendering engine produces realistic and deterministic environments, bypassing limitations typically found in game engine simulators. This tool is pivotal for car manufacturers as it enhances the reliability and safety of automated driving solutions. aiSim 5 boasts a flexible architecture that integrates smoothly with existing toolchains, encouraging a reduction in costly real-road testing. It focuses significantly on multi-sensor simulation, supporting diverse weather conditions and complex driving scenarios, which are essential for developing adaptive driving systems. This simulation environment allows for high mileage tests, vital for understanding and improving the effectiveness of driving systems in various settings. Additionally, aiSim 5 supports the creation of digital twin 3D environments that replicate real-world locations accurately. This enables a high-fidelity simulation of operational design domains, from highways to urban settings. aiSim's capability to simulate adverse scenarios such as snowstorms or heavy rain showcases its comprehensive approach to ensuring that AD systems are tested under every possible real-world condition.
The Flexibilis Redundant Card (FRC) is designed as a PCIe Network Interface Card that expertly incorporates High-Availability Seamless Redundancy (HSR) and Parallel Redundancy Protocol (PRP) standards. This card ensures continuity of Ethernet communications with clock synchronization capabilities vital for critical operations. Its robust design allows it to handle high-stakes communication traffic seamlessly, maintaining zero-loss data transmission through redundancy on the Ethernet layer. FRC functions as an open, interoperable solution adhering to key IEEE standards, making it a dependable choice for power grid systems and industries where clock precision is paramount. It integrates closely with Flexibilis's own Redundant Switch technology to offer precise IEEE 1588 PTP time synchronization, ensuring network nodes are in harmony down to sub-microsecond precision. Supporting full-speed, non-blocking network operations, the FRC delivers high performance and reliability, further enhanced by its ease of use. It can be managed through a GUI or NETCONF, simplifying deployment in existing infrastructures. The card features multiple RJ45 ports, adaptable to varied network designs, and operates efficiently under strenuous environmental conditions, ensuring long-term, reliable network performance.
The Glasswing Ultra-Short Reach SerDes represents a pioneering development in chip-to-chip communication, leveraging Chord Signaling to provide exceptional bandwidth and energy efficiency. By using CNRZ-5 signaling, Glasswing can deliver twice the bit rate of traditional NRZ solutions while consuming significantly less power. Glasswing is designed for high-performance applications such as AI, machine learning, and complex semiconductor systems, offering a high degree of flexibility and reliability. It supports high-density multi-chip modules (MCMs), making it ideal for integrating complex designs with multiple dies. The product's innovative design reduces the overall footprint and increases yield by eliminating the need for silicon interposers. This PHY solution is equipped with advanced diagnostics like EyeScope for real-time signal monitoring, ensuring robust data throughput and minimized error rates. With its superb diagnostics and bandwidth delivery, Glasswing is a definitive choice for technology leaders aiming to push the boundaries of chip interconnect performance.
The CAN FD Controller is designed to seamlessly integrate into systems requiring Control Area Network (CAN) communication as defined by ISO 11898-1:2015. This controller supports both Classical CAN and Flexible Data Rate (FD) CAN frame formats. With capabilities that allow for data rates up to 1 Mbit/s for Classical CAN and up to 10 Mbit/s for CAN FD, it offers enhanced performance and flexibility for modern automotive and industrial applications. Developed according to the DO-254 DAL A standard, it ensures high reliability and safety-critical performance, making it suitable for rigorous airborne and automotive systems. The core’s ability to handle flexible data rates and classical frame formats make it adaptable for various applications, allowing for upgraded communication systems without significant hardware changes. Built-in error detection and correction methodologies are also supported to enhance data integrity in practical deployments. Developers working on systems that demand robust data communication protocols will find this IP core integral to achieving robust, high-speed data transfers that meet contemporary communication standards. Furthermore, SafeCore provides comprehensive certification kits with their CAN FD controller, facilitating the compliance process for avionics and aerospace applications. These kits ensure that all necessary lifecycle documentation to meet DO-254 objectives is accessible, simplifying the certification process for clients.
Designed specifically for single channel advanced driver-assistance systems (ADAS), the SFA 250A focuses on providing reliable data processing for automotive applications. It processes a range of inputs from vehicle sensors, allowing precise and timely responses critical for safe driving. The solution integrates seamlessly with existing vehicular systems to enhance safety through intelligent data analysis and robust real-time processing capabilities.
The XRS7000 Series Switches are pivotal in facilitating High-Availability Seamless Redundancy (HSR) and Parallel Redundancy Protocol (PRP) within industrial applications. These integrated circuits are the first of their kind, allowing users to implement HSR, PRP, and time synchronization with ease. Ideal for industrial automation, motion control, and substation automation, the XRS7000 series ensures zero-loss redundancy and reliability with no single failure points, critical for maintaining stable and secure network operations. Each switch in the series, including models like the XRS7003 and XRS7004, offers multiple Gigabit Ethernet ports and supports both HSR and PRP, providing advanced time and frequency sync through IEEE 1588-2008 Precision Time Protocol v2. With options for various operational ports, these switches can adapt to specific application needs, ensuring robust network configurations. Additionally, the XRS7000 switches are compatible with existing Ethernet infrastructures, offering low-latency, non-blocking switching capabilities. Featuring essential functionalities like port-based VLAN tagging and Quality of Service (QoS) management, they are crucial for enterprise networks that demand high availability and mission-critical reliability.
The CAN FD Full Controller is an advanced CAN bus controller core that supports both traditional CAN 2.0B and emerging CAN FD frames. This enhances flexibility in automotive communications, with full compliance to ISO 11898-1:2015 standards. The core enables higher data rates and offers superior error-handling capabilities, providing robust networking solutions across critical automotive applications. Its versatility ensures seamless transition and interoperability between older CAN protocols and newer systems, securing future-ready application designs.
The GateMate FPGA is designed to offer exceptional flexibility and adaptability for a wide range of applications. FPGAs, known for their configurability post-manufacturing, enable users to tailor designs to specific needs. GateMate FPGAs are particularly suited for industries such as telecommunications, automotive, aerospace, and industrial sectors, where adaptability and parallel processing are crucial. GateMate FPGAs employ the latest technology, ensuring users benefit from high-speed processing and superior connectivity options. This makes them ideal for applications that require real-time data processing and parallel task execution. Their utility extends across diverse applications, from advanced driver-assistance systems in automotive to complex image processing tasks in medical devices. Manufactured using GlobalFoundries' proven 28nm process node, GateMate FPGAs strike a perfect balance between performance and power efficiency. This manufacturing detail ensures high-quality standards and a reliable supply chain, delivering FPGAs that meet both economic and technical demands.
The SFA 350A targets quad-channel advanced driver-assistance systems (ADAS) applications, integrating multiple sensor inputs to enhance vehicle safety systems. It offers sophisticated processing capabilities, supporting simultaneous data handling from several sources to ensure timely and accurate vehicular responses. This comprehensive solution is pivotal for advancements in automotive technology, rendering vehicles more response-capable under diverse conditions.
The CAN 2.0/CAN FD Controller from Synective Labs offers a comprehensive implementation of a CAN controller, designed for seamless integration into FPGAs and ASICs. This advanced controller adheres to the ISO 11898-1:2015 standard, effectively supporting both the traditional CAN and the enhanced CAN FD protocol. The latter facilitates higher bitrate transmission up to 10 Mbit/s and can handle payloads up to 64 bytes, compared to the 8 bytes in standard CAN systems. This IP is adaptable for a variety of FPGA devices, including those from Xilinx, Altera, Lattice, and Microsemi, and it supports common bus interfaces like AXI, Avalon, and APB. It is particularly beneficial for data logging and bus diagnostic tasks because of its extensive debugging features, though these can be minimized to save space in more conventional applications. Designed for flexibility, the IP can be configured with varying hardware buffer sizes and incorporates features like low-latency DMA, transmit rate adaptation, and multiple mode operations. With capabilities such as listen-only mode, auto-acknowledge, and single-shot mode, this controller ensures versatility across different applications. It also supports SOC-type FPGAs for processor integration, effectively making it suitable for complex and varied system architectures.
The VectorPath S7t-VG6 accelerator card is developed to accelerate and simplify the deployment of high-performance computing and data-processing tasks across a variety of environments. This card is particularly beneficial for applications in AI, machine learning, networking, and data center operations, providing essential boosts to computational efficiency and processing speed. Equipped with Achronix's Speedster7t FPGAs, the VectorPath accelerator card ensures high bandwidth and low-latency performance. This integration supports tasks like real-time data analytics, rapid processing of large datasets, and advanced algorithm executions crucial in modern tech applications. It is specifically engineered to speed up time-to-market for companies seeking scalable and effective acceleration solutions. The card’s design focuses on maximizing the throughput and reducing overheads typically seen in high-volume data environments. With the VectorPath accelerator, developers can create tailored solutions that address specific workload requirements, supported by Achronix's robust software suite. This makes the VectorPath card a versatile tool for organizations aiming to enhance their data processing capabilities efficiently.
The DCAN XL IP Core by Digital Core Design redefines connectivity by seamlessly integrating CAN FD with Ethernet functionalities. Supporting data rates up to 20 Mbit/s, it provides flexibility with CAN transceivers for low-rate and high-speed CAN SIC XL applications. This core propels automotive and industrial networking designs into a new realm of performance and safety, bridging communication standards for advanced system integration.
Aimed at the automotive industry, the NA Class from Nuclei encompasses the ISO 26262 functional safety standards critical for vehicle electronics. Designed with a focus on automotive safety, this IP ensures that safety-critical applications perform reliably under all conditions. It supports advanced driver-assistance systems (ADAS) and communication protocols necessary for modern vehicular technology. Its adaptability extends through its Verilog coding format and extensive configurability, meeting specific industry requirements with precision and dependability, thus making it a leading choice for automotive implementers.
Harnessing the power of FPGA technology, CetraC offers tailored solutions for embedded systems. Their FPGA customization service is designed to meet the unique demands of various industries, ensuring high performance and reliability. Leveraging FPGA's inherent flexibility allows for rapid customization and efficient deployment, making them ideal for critical applications with demanding specifications. This service is particularly beneficial for clients needing a robust implementation framework within distributed system architectures.\n\nThe customization process involves comprehensive support from initial design to deployment. CetraC's FPGA solutions enable enhancements in data processing, system responsiveness, and overall functionality. The adaptability of FPGA designs ensures optimal performance in dynamic environments, supporting protocol conversions, advanced data filtering, and aggregation capabilities.\n\nCetraC's solutions are deeply embedded in industries where rapid data throughput and precision are crucial. By customizing FPGA applications, they offer valuable insights and data-driven decision-making capabilities. The solutions increase efficiency by minimizing latency and supporting a robust data processing framework across diverse protocol environments.
The CANsec Controller Core serves as a cybersecurity enhancement for controller area networks used in various applications. This core provides essential cryptographic functions for protecting messages transmitted via the CAN bus, mitigating risks associated with unauthorized data access and manipulation. Its architecture allows for seamless integration with existing CAN infrastructures, providing an upgrade path for enhancing security without overhauling legacy systems. This feature-rich core is tailored for industries where data integrity and confidentiality are paramount, ensuring robust protection of sensitive communications. Optimized for performance, the CANsec Controller Core balances high security with low latency, enhancing the reliability of secure message transmission across networked devices.
The XR7 PTP Time Synchronization Stack is an IEEE 1588-2008 compatible protocol developed for achieving precise clock synchronization over packet-based networks. Designed in C-language, the stack is optimized for deployment in Linux systems, with an abstraction layer ensuring straightforward adaptation to varied hardware setups. This robust protocol stack is recognized for its interoperability and has undergone extensive testing at international symposia. The stack includes comprehensive functionalities such as Best Master Clock selection and adaptive message transmission intervals, making it a versatile solution for time-sensitive applications across diverse fields. Employing the XR7 PTP stack allows industries to achieve nanosecond-level accuracy, critical for applications demanding exact timing coordination, such as telecommunications, power utilities, and financial services. The stack is a vital asset in any scenario where precise system-wide synchronization is required, streamlining the process and ensuring uniform timekeeping across complex networks.
XR7 Redundancy Supervision is a highly specialized software suite developed to manage and monitor HSR and PRP supervision protocols. Compliant with IEC 62439-3:2016 standards, it functions by generating and processing crucial supervision frames within a network, ensuring nodes are continuously aware of the network topology and operational status. This C-language based implementation is designed for ease of integration into Linux environments, offering an abstraction layer for simplified portability across different systems. It actively maintains a NodesTable to store information about other nodes, which can be leveraged by network management systems for enhanced monitoring and management. The suite supports both standard and customizable transmission intervals, with built-in interfaces for reading nodal data. These capabilities make XR7 an essential tool in environments where stringent supervision and timely network information processing are mission-critical, such as in automated industrial systems and large-scale data networks.
The S32M2 Integrated Solution is engineered specifically for 12V motor control applications, offering a comprehensive system-in-package design. It blends high-voltage analog capabilities, such as MOSFET gate pre-drivers and physical communication interfaces, with a robust embedded MCU Core from the S32K Arm® Cortex®-M4/M7 series. This integration ensures not only high performance but also adherence to functional safety standards up to ISO 26262 ASIL B. A defining feature of the S32M2 series is its platform-based approach, which streamlines the creation of motor control edge nodes, significantly shortening time-to-market. It also boasts advanced data analysis tools, diagnostic capabilities for inverters and motors, and innovative algorithms to reduce in-cabin noise. The solution facilitates seamless firmware updates via over-the-air methods, encouraging software reuse and flexibility, all while maintaining cost efficiency. The S32M2 also reduces overall system component count by incorporating voltage regulators, pulse-width modulators, analog to digital converters, timers, and non-volatile memory. Packaged in a 64-pin LQFP-EP format, this solution supports automotive applications like advanced exterior lighting and motor drives, while also being applicable to industrial settings such as HVAC systems.
The logiCAN controller adapts the Controller Area Network (CAN) 2.0B protocol for AMD FPGAs, providing the backbone for efficient communication within various automotive and industrial networks. This core is integral in systems where robust and reliable data transmission is required. Its design caters to the demanding conditions of automotive and industrial settings, where CAN connectivity remains crucial for effective network management and data integrity. Through easily accessible development tools, logiCAN simplifies deployment across multiple applications, making it a versatile asset. A swath of licensing options provides flexibility, enabling developers to integrate logiCAN in cost-effective ways. This IP core stands as a testament to Xylon's prowess in delivering industry-standard solutions rooted in communication excellence and reliability.