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.
Silvaco provides comprehensive Automotive IP solutions tailored for automotive applications, ensuring high value and silicon-proven reliability. This line includes controllers for In-Vehicle Networks (IVN) such as FlexCAN with CAN-FD, high-speed FlexRay, and LIN standards. These elements are integral for the development of modern automotive systems with robust flexibility and performance.<br><br>In addition, Silvaco offers significant advancements in SoC subsystems, embodying critical cores, subsystems, and necessary peripherals to enhance SoC designs for automotive applications. These systems integrate SPI, UART, and DMA Controllers, creating streamlined pathways for data and control within automotive electronics.<br><br>Furthermore, Silvaco supports seamless integration of I3C systems, providing Advanced and Autonomous controller features for diverse automotive needs. Through comprehensive support and customization capabilities, Silvaco's IP solutions stand out in delivering reliability and efficiency required for next-generation automotive electronics.
The CT25205 is a comprehensive digital core designed for IEEE 802.3cg® 10BASE-T1S Ethernet applications, incorporating the Physical Medium Attachment (PMA), Physical Coding Sublayer (PCS), and Physical Layer Coordination (PLCA) Reconciliation Sublayers. Written in Verilog 2005 HDL, this IP core is versatile enough to be implemented in standard cells and FPGA systems. It interfaces seamlessly with IEEE Ethernet MACs through a Media Independent Interface (MII), and the PLCA RS supports legacy MACs, enhancing functionality without additional extensions. The PMA is compatible with OPEN Alliance 10BASE-T1S PMD, perfect for Zonal Gateways and MCUs in advanced network architectures.
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 CANmodule-IIIx by Inicore is an enhanced CAN controller with a design that caters to sophisticated system-on-chip requirements. It features 32 receive and 32 transmit mailboxes, offering substantial flexibility and control over CAN network traffic. This module is ideal for applications necessitating high throughput and advanced message handling. Its compliance with full CAN2.0B standards ensures wide applicability across various sectors, making it an integral part of communication systems in automotive and industrial fields. The CANmodule-IIIx delivers an excellent balance of performance and functionality.
ASPER is an advanced 79 GHz mmWave radar offering expansive 180-degree field coverage, designed to excel in park assist solutions. This radar module replaces traditional ultrasonic systems with improved accuracy, capable of extended detection ranges from 5 cm to 100 meters. Its adaptability across various vehicle classes makes it ideal for applications in automotive, transportation, and industrial environments, delivering unparalleled performance even in adverse conditions.
Inicore’s CANmodule-III is a mailbox-based CAN controller offering robust performance for system-on-chip solutions. Designed with advanced features to manage communication effectively, this controller supports a comprehensive range of CAN applications. With its scalability and ease of integration, it remains a preferred choice for industries requiring reliable CAN solutions. The CANmodule-III’s design simplicity ensures that it is a dependable component in complex electronic systems, meeting various compliance standards and providing an exceptional communication protocol foundation.
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 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.
The Time-Triggered Protocol (TTP) is a robust communication protocol designed for safety-critical applications. It provides deterministic exchange of messages between nodes in a network at pre-determined time intervals, ensuring system reliability and predictability. This makes TTP suited for environments like aerospace and automotive systems, where timing precision and fault tolerance are crucial. TTP's core feature is its ability to prioritize and synchronize communication across multiple nodes, effectively handling both normal operation and recovery from potential faults. By achieving strict temporal coordination, TTP enhances network efficiency and reduces the likelihood of message collision, contributing to overall system safety and robustness. Additionally, TTP supports modular extension, allowing designers to add functionalities without major architectural changes. This adaptability makes it an ideal choice for evolving systems that require long-term reliability and scalability. Furthermore, TTP's lightweight implementation aids in maintaining low system complexity, thereby optimizing resource utilization under various operational scenarios.
The eSi-ADAS IP suite is tailored to enhance radar processing for Advanced Driver Assistance Systems (ADAS). It includes a powerful radar co-processor engine that boosts the performance of radar systems used in automotive, drone, and UAV applications. The IP has gained adoption by prominent automotive suppliers and finds use in production vehicles, illustrating its reliability and effectiveness in real-world conditions. Key functionalities of eSi-ADAS encapsulate a wide range of radar hardware accelerators which enhance radar's performance capabilities, ensuring precise situational awareness.
The Ncore Cache Coherent Interconnect by Arteris addresses the multifaceted challenges of multi-core ASIC design, offering a production-ready, highly configurable coherent NoC interconnect solution. Ncore is tailored for high-performance applications, supporting a variety of protocols compatible with Arm and RISC-V processors while enhancing inter-core communication and synchronization. Ncore is designed with functional safety in mind, making it suitable for ISO 26262 certification, a crucial factor for safety-critical applications such as automotive systems. It ensures credible operation in these environments with built-in safety and reliability features, including FMEDA data and ASIL certification. The IP supports multi-protocol coherency with CHI-B, CHI-E, and ACE alongside I/O coherent agent interfaces, providing versatility and backward compatibility for diverse SoC architectures. Enhanced with unique proxy caches, Ncore lowers power requirements while maintaining high performance, offering a scalable, power-efficient interconnect fabric suitable for a wide array of system scales, from small embedded solutions to extensive multi-billion transistor designs.
aiSim is the world's first ISO26262 ASIL-D certified simulator, specifically designed for ADAS and autonomous driving validation. This state-of-the-art simulator captures the essence of AI-driven digital twin environments and sophisticated sensor simulations, key for conducting high-fidelity tests in virtual settings. Offering a flexible architecture, aiSim reduces reliance on costly real-world testing by recreating diverse environmental conditions like weather and complex urban scenarios, enabling comprehensive system evaluations under deterministic conditions. As a high-caliber tool, aiSim excels at simulating both static and dynamic environments, leveraging a powerful rendering engine to deliver deterministic, reproducible results. Developers benefit from seamless integration thanks to its modular use of C++ and Python APIs, making for an adaptable testing tool that complements existing toolchains. The simulator encourages innovative scenario creation and houses an extensive 3D asset library, enabling users to construct varied, detailed test settings for more robust system validation. aiSim's cutting-edge capabilities include advanced scenario randomization and simulation of sensor inputs across multiple modalities. Its AI-powered rendering streamlines the processing of complex scenarios, creating resource-efficient simulations. This makes aiSim a cornerstone tool in validating automated driving solutions, ensuring they can handle the breadth of real-world driving environments. It is an invaluable asset for engineers looking to perfect sensor designs and software algorithms in a controlled, scalable setting.
The DCAN XL presents an advanced CAN Bus controller capable of bridging traditional CAN FD with 100Mbit Ethernet. This innovative solution supports a wide range of data rates up to 20 Mbit/s, with specialized transceivers for bit rates both under and over 10Mbps. Designed in accordance with ISO 11898-1:2015 standards, it ensures compatibility across various automotive and industrial communication systems. By adopting cutting-edge serial communication technologies, the DCAN XL reliably enhances the network's data throughput and integrity, making it indispensable for sophisticated vehicular and machine control applications.
The CAN 2.0/CAN FD Controller by Synective Labs is a sophisticated integration option crafted for both FPGA and ASIC applications, enabling a full-featured CAN controller setup. This product adheres to the ISO 11898-1:2015 standard, accommodating traditional CAN and the advanced CAN FD protocols. Significantly, CAN FD enhances data transmission rates up to 10 Mbit/s and expands payload capacities to 64 bytes, surpassing the 8-byte limit of its predecessor. Designed to support a wide variety of FPGA devices from industry giants such as Xilinx, Intel, Lattice, and Microsemi, this controller is equipped with native system bus interfaces like AXI, Avalon, and APB, making it a versatile tool for SOC-type FPGA integration. Its architecture includes multiple advanced features tailored for diagnostics and CAN bus debugging, rendering it indispensable for devices such as data loggers. However, to achieve minimal footprint, all diagnostic features can be disabled at the time of build. In terms of system connectivity, this controller includes functionalities like adaptable transmission rates, DMA support with low-latency interrupt adaptations, and timestamps. It implements a series of operational modes like Listen Only, Auto Acknowledge, and Single Shot, ensuring comprehensive integration options. It’s optimized for systems requiring separate core and system clocks, ensuring compatibility across diverse FPGA architectures.
The GateMate FPGA series by Cologne Chip is designed for small to medium-scale FPGA applications, offering exceptional logic capacity, energy efficiency, and compact packaging. Manufactured using GlobalFoundries' 28nm Super Low Power process, these FPGAs ensure high performance at a lower cost, making them suitable for various applications from university labs to large-scale production. This FPGA integrates CPE programmable elements alongside a clever routing engine, enabling efficient multiplier constructions and memory-intensive applications through block RAMs. Supporting 20,480 programmable elements, GateMate FPGAs feature flexible General Purpose IOs that handle a range of voltage levels and configuration options, including LVDS differential pairs. High-speed communications benefit from an available SerDes interface, while synthesis and bitstream generation involve the Yosys framework and Cologne Chip's P&R software. These FPGAs minimize the risk associated with supply chain disruptions thanks to their European manufacturing. Designed with an emphasis on low power consumption, GateMate supports multiple operation modes like low power, economy, and speed, accommodating different application requirements. Its versatility ensures it is a robust choice for new technological solutions across industry verticals.
The CAN FD Full Controller is engineered to enhance the capabilities of standard CAN protocols by supporting both CAN 2.0B and extended CAN FD frames. With compliance to ISO 11898-1:2015, this controller optimizes communication reliability and data rate handling, making it suitable for modern automotive and industrial applications. Its design allows it to overcome the limitations of traditional CAN systems, facilitating improved data throughput, which is essential in sophisticated, real-time communication networks.
The CANmodule-IIx from Inicore is a compact, advanced CAN controller module featuring enhanced message filtering and both receive and transmit buffers. Tailored for FPGA and ASIC system-on-chip integrations, it boasts a low gate-count CAN interface. A key feature is its advanced message filtering capability, which is bolstered by a transmit FIFO and high-priority transmit message buffer, catering to a diverse range of applications. The module integrates smoothly with ARM-based systems via an AMBA APB interface, ensuring hassle-free application in various environments.
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 integrates cybersecurity features into the widely adopted Controller Area Network (CAN) bus protocol. This enhancement ensures secure transmission of data between vehicle components, mitigating potential cyber threats. Designed with automotive environments in mind, it includes cryptographic modules that provide authentication and encryption, safeguarding data integrity and confidentiality. Integrating seamlessly into existing CAN infrastructure, the core supports various security algorithms while maintaining the low-latency communication that CAN networks are known for. Its design allows automotive manufacturers to update their existing systems to meet evolving security standards without significant overhauls in software or hardware. The core is compliant with the CAN in Automation (CiA) specifications and supports onboard diagnostics and other automotive functions, enhancing vehicle safety and reliability. By providing an additional layer of security, the CANsec Controller Core stands as a crucial component in the development of modern, intelligent transportation systems.
Marquee Semiconductor is adept at designing Network-on-Chip (NoC) based subsystems that skillfully interlink various chip components, enhancing both coherent and non-coherent network designs. By leveraging sophisticated integration techniques, they expertly combine these features into scalable chiplet architectures. This approach not only boosts performance but also facilitates the creation of flexible solutions tailor-made for intricate chip designs. The company employs advanced methodologies to ensure their NoC systems function efficiently, maximizing data throughput while minimizing latency. This finesse in designing NoC ecosystems provides clients with highly reliable and adaptable semiconductor solutions. Furthermore, these platforms are optimized to support a broad spectrum of applications, extending their utility across different technological domains. Marquee Semiconductor's commitment to innovation is evident in their capacity to foresee and address potential design challenges, making them a reliable partner for cutting-edge semiconductor projects. The company continues to lead the charge in developing integrated systems that push the boundaries of current technology landscapes, ensuring seamless operations and meeting high industry standards.
The RISC-V CPU IP NA Class is specialized for automotive applications, particularly where adherence to automotive safety standards like ISO 26262 is critical. Designed by Nuclei System Technology, this IP offers functional safety and supports Automotive Safety Integrity Levels (ASIL) such as ASIL-B and ASIL-D, making it suitable for systems where safety cannot be compromised. Rooted in the RISC-V open standard, the NA Class is highly configurable, allowing manufacturers to tailor solutions that meet specific automotive requirements. This includes supporting functional safety features necessary for modern automotive control systems, offering reliability and performance that stand up to rigorous industry standards. Critical for use in various automotive applications, the NA Class is engineered to be both robust and adaptable, ensuring that it can support future advancements in automotive technology. Its compliance with strict safety protocols positions it as an essential tool for developing reliable solutions within the rapidly evolving automotive industry.
FireCore is a leading solution within the domain of synthesizable IEEE-1394-2008 components, integrating both PHY and Link Layer Controller functionality in a single product. Geared to support data rates from S100 up to S3200, it seamlessly combines the data capture, verification, and analysis strengths into one robust engine. FireCore enhances flexibility through various host interface options and PIN density configurations, making it suitable for diverse applications such as avionics and multimedia. FireCore's architecture is aimed at isolating the usual issues associated with off-the-shelf silicon and providing complete control over customization and optimization in-field. This means that users can readily adapt and upgrade their systems as needed, without the usual port, speed, or version constraints typical of commercial solutions. Key features include powerful error-handling, efficient bus management, flexible host connectivity, and both isochronous and asynchronous packet types, all with fast virtual-path computations. A further advancement is the AS5643 integration, which allows the device to support highly demanding aerospace and defense systems. Through direct support for the Mil1394 protocol, FireCore can be tailored for systems that demand reliability and precision, impacting sectors needing meticulous testing and sophisticated network architecture management.
Vyapi LTE eNodeB is a robust 4G technology offering centered around indigenous development from hardware to software, aligning with the vision of Aathmanirbhar Bharat. This product facilitates the creation of secure, personal mobile broadband networks for commercial, private, and defense purposes. Optimized to provide broad area coverage, Vyapi LTE eNodeB reduces the total cost of ownership for operators. Integrated with multiple EPC vendors, it supports TDD and FDD frequency bands with RF power up to 40W, adequate for both small and macro cell coverage needs. This turnkey solution enhances deployment efficiency for green and brownfield scenarios, addressing enterprise needs with versatile network solutions.
The FireSpy Bus Analyzer series offers comprehensive solutions for IEEE-1394 bus analysis. Designed with flexibility in mind, the series provides in-depth protocol analysis, utilizing various optical and electrical modules for optimal performance. Perfectly suited for any application that demands precision and electronic control, the line is equipped to handle various IEEE-1394a and IEEE-1394b operations, offering transmission capacities ranging from S100 to S3200. By integrating Mil1394 protocol modules, these analyzers provide meticulous data capture, manipulation, and display functions, making them an essential tool for complex network maintenance and troubleshooting. The FireSpy series is grounded in the highest standards of aerospace technology, ensuring users are able to enhance connectivity and stability across their network systems. With robust diagnostics and monitoring capabilities, the series guarantees reliable data integrity and network performance monitoring. Its compatibility with a range of data protocols makes it highly versatile for complex and mission-critical environments, where rapid and consistent data flow is paramount. Furthermore, users benefit from FireSpy's sophisticated filtering capabilities that ensure precise real-time monitoring and analysis. These features, combined with user-friendly software, provide intuitive interfaces for efficient operation while retaining superior protocol compliance and meticulous testing routines, ensuring the application of rigorous standards across various sectors.
The CAN FD Controller is a versatile solution designed to implement the Controller Area Network with Flexible Data Rate (CAN FD) as specified in the ISO 11898:2015 Part 1. This IP provides robust support for both Classical and Flexible Data Rate CAN frame formats, operating at bit rates up to 1 Mbit/s for Classical CAN and up to 10 Mbit/s for CAN FD formats. It facilitates efficient real-time control in distributed network systems across high-speed networks and cost-effective multiplex wiring applications. The CAN FD Controller is developed with Design Assurance Level A, ensuring compliance with the DO-254 standard for airborne electronic hardware. This IP core has been extensively tested in accordance with ISO 16845-1:2016 standards, guaranteeing a high level of security and reliability. The Controller's design is fully synchronous, supporting standard transceiver interfaces without need for additional logic, making it a seamless component of any airborne or automotive control system. This technology-independent core can be synthesized to fit any FPGA or CPLD vendor specifications, offering flexibility and compatibility across different platforms. It also includes optional TMR coding for improved immunity to radiation-induced errors, critical for maintaining operational integrity in harsh environments.
FireTrac is an interface card that brings powerful enhancements for advanced MIL-STD-1394 or AS5643 data processing. It serves as a comprehensive platform that supports simulation and testing solutions, designed to handle intricate network traffic effectively. Its architecture is built to offer seamless data encapsulation and transmission, meeting specific integrative demands of aerospace systems. This card is engineered to promt seamless compatibility and superior performance in avionics applications, addressing specific protocols and data processing needs. The scale of configurability within FireTrac allows users to tailor it precisely to their system requirements, offering a degree of versatility that ensures it supports various host platforms through easy adaptation and scalability. Though built primarily for aerospace, its functionality can extend to industrial uses where precision in data handling and maintenance is crucial. The technology behind FireTrac allows for the generation and reception of real-time AS5643 signals that are vital in military and aerospace endeavors. This crucial component advocates performance reliability through robust design features and advanced AS5643 protocol support, capable of sustaining high-channel counts and ensuring precise timing even under the most demanding circumstances.
FireLink Basic, a component of the larger FireCore solution, is designed to deliver seamless transmission of up to S3200 data rates without demanding PCI-centric interfaces. It is constructed within a layout that provides simplicity and ease in adapting to various industry-specific circumstances. Capable of offering significant support for Mil1394, FireLink Basic aids in the seamless integration of AS5643 protocol needs with minimal host resource use. Its deployment extends across a wide range of industries, inclusive of aviation, military, and consumer electronics, proving its expansive reach and flexibility. Noteworthy for its stable host address and data conformity, FireLink Basic utilizes a straightforward 32-bit data/address bus system for transactions, reducing complexity through streamlined operations. Its application gauge ranges from robotics to wide-format printers, ensuring efficiency maximization when applied in environments requiring consistent data flow and real-time communication protocols.
The FireCore Extended package is tailored for applications that demand high data throughput and efficiency. Built upon the synergy of FireLink Extended with the FireGate PHY, it accommodates a host interface unification across PCI based system engagements. The core supports DMA-driven data transactions that facilitate asynchronous and isochronous packet flows, making it optimal for aerospace, defense, and high-performance media sectors. With an emphasis on scalability, FireCore Extended embodies a flexible platform enabling the addition of additional hardware components, future-proofing design itself against evolving technological landscapes. Critical enhancements such as host CPU off-loading and AS5643 protocol implementations assure that systems deliver high-performing reliable solutions with rapid processing. Built to meet demands for advanced military aviation applications, the core facilitates seamless communication and command through high-speed data channels. The comprehensive architecture integrates functional standards that are compliant with IEEE-1394b-2008, ensuring interoperability across various equipment baseline, aligning the core with industry-driven operational goals.
The Automotive Multigigabit Ethernet Switch by Broadcom integrates advanced security protocols with high-speed data transmission capabilities, tailored specifically for the automotive sector. This switch supports multi-layered security features, ensuring safe and efficient communication across the vehicle's network. Engineered for modern automotive needs, this device facilitates seamless connectivity, boasting compatibility with current and emerging automotive standards. Its multigigabit throughput capacity addresses the growing demand for in-vehicle data exchange, providing the backbone infrastructure for connected and autonomous vehicle features. Broadcom's automotive Ethernet switch offers robust performance with low latency and high reliability, critical for safety and infotainment systems. Its scalable design ensures future-proofing, allowing for integration into evolving automotive technologies while maintaining stringent security measures against cyber threats.
FireCore Basic offers a blended solution combining FireGate PHY IP with FireLink Basic LLC IP for an integrated IEEE-1394-2008 component. Its primary focus lies in achieving a transparent transition towards higher data transfer rates while maintaining a compact footprint amid minimizing resource utilization. Catering specifically to applications in Aerospace, Defense, and Industrial sectors, it supports implementation for remote nodes, routers, and more. The design equips users with options for various host connectivity solutions, ensuring compatibility and integration ease across multiple platforms. It significantly reduces the computational burden on host devices by offering direct support and enhanced timing for Mil1394 functionalities, distinguishing it as the first choice for space-limited or cost-sensitive environments. By combining robust isochronous and asynchronous data streaming capabilities with reduced overheads, it assures that comprehensive data processing demands are met without compromising on speed or reliability. FireCore Basic shines in its ability to empower wider industrial applications such as robotics and wide-format digital printing, in addition to its military roots, proving it’s a versatile solution that effectively scales with evolving technological requirements.
FireCore GPLink serves as a prime replacement for general-purpose IEEE-1394 Link Layer chips, providing an expansive suite of functional blocks aimed at varied industrial and defense applications. It offers support for transfer rates from S100 to S400 and features a highly scalable architecture. The integration of FireLink GPLink with FireGate allows for easy adoption in applications requiring extensive data handling. Its primary use is seen in robotics, automated printing platforms, or multidimensional imaging technologies, with a unique attribute of datamover interface that simplifies high-speed transmission of isochronous data. FireCore GPLink ensures seamless interfacing with popular microcontroller technologies, delivering a low-overhead and cost-effective solution for ecosystems demanding performance and adaptability. Constructed to offer configurability in the number of supported PHY ports, ranging up to 16, FireCore GPLink presents a solution adaptable to specific project requirements, ensuring connection integrity and compliance. This versatile component ensures networking precision in complex project environments, aligning with IEEE-1394b standards while emphasizing simplified deployment across FPGA platforms.
CAST's CAN-CTRL is a versatile CAN bus controller core that comprehensively supports the CAN 2.0, CAN FD, and CAN XL protocols. Designed for broad compatibility, the core integrates easily with various systems thanks to its flexible buffering scheme and configurable interrupt and data rate settings. The controller suits applications demanding reliable high-speed communication on the CAN bus, such as automotive and industrial control systems. It ensures effective management of signal integrity and data exchange, fostering robust and efficient communication channels in demanding environments.
FireLink GPLink is designed as a substitute for generic Link Layer chips, tailored to handle common industry tasks while offering Mil1394 enhancements for a wide array of systems. Configured to enable seamless interaction with a host of network protocols, it works with asynchronous and isochronous data operations. The cornerstone of this component is its integration power while maintaining simplicity and effectiveness across general-purpose designs. Its build guarantees a glueless interface connection with some of the most common microprocessor models, incorporating the ability to fine-tune the number of instances deployed per FPGA, ensuring unmatched resource management and expansion capability. Highly suitable for multiple industry deployments, FireLink GPLink makes use of IEEE-1394b standards, lending its operational strengths particularly to projects with sophisticated command and data handling platforms. This level of adaptability as a core system part guarantees a robust solution that equates to superior real-time communication within varied engineering environments.
FireLink Extended broadens the reach of the FireCore family with more advanced functionality tailored to high-bandwidth environments. It features DMA-driven data transactions and can interface through non-PCI, PCI, and PCIe buses with seamless architecture benefits, serving industries ranging from Aerospace and Defense to Industrial sectors. Emphasizing the architectural benefits of DMA mechanisms, FireLink Extended becomes an excellent choice for data-intensive applications where rapid cycle transactions significantly affect operational dynamics. Its capability to interface with standard OHCI configurations assures comprehensive throughput optimization and minimal latency within extensive datasets. Primarily aimed at applications benefiting from high-capacity communication links, this component sustains highly efficient packet processing with support for AS5643 enhancements. FireLink Extended integrates profound protocol management, serving industries that demand rigorous data handling and accuracy within defined aerospace frameworks.
FireGate is an advanced PHY interface that grounds itself in compatibility and complete standard compliance with IEEE-1394b-2008 Beta and AS5643 requirements. It supports a data range from S100 through S3200, ensuring resilient communication channels in critical sectors like aerospace and defense. FireGate's architecture allows customization per requirements, optimizing several aspects related to the PHY cable environment, ranging from PHY ports scalability to the enhanced handling of multi-speed support settings. The ability to configure front-end architecture ensures adaptability across a variety of series and connection environments, benefiting sectors that demand meticulous process controls. With an aim to combine PHY and Link Layer developments, FireGate elevates performance by resolving common silicon issues with tailored in-field revisions. The IP's robust design aids projects requiring stability and performance confidence integrated within mission-critical applications, establishing it as a technologically advanced and economically feasible layer solution.
The CAN Controller by Inicore is designed to integrate seamlessly into system-on-chip solutions, adhering to the CAN2.0B standard. These modules efficiently manage communication on the CAN bus while supporting application-specific features as add-ons. The architecture, derived from Bosch's basic CAN design, allows for flexibility and optimization to suit diverse applications. The CAN Controller modules have been deployed in various fields such as aerospace, automotive, and industrial control since its launch in 1994, underlining their reliability across different industry standards.
VibroSense for Tire Monitoring is an innovative ultra-low-power chip designed to address the gap in current vehicle safety by providing real-time monitoring of tire-road friction. Integrated with standard TPMS systems, this chip enhances ADAS systems by making dynamic road condition feedback possible without relying on indirect and inaccurate friction estimations. By processing data at the sensor level, VibroSense reduces wireless communication overhead, allowing for efficient use of standard battery power or energy harvesting solutions. This chip acts as the missing component in comprehensive vehicle safety, greatly improving the in-tire detection of friction changes, which is critical for maintaining vehicle stability and safety. The precise monitoring of peak friction coefficients allows vehicles equipped with ADAS to respond quicker to road surface changes, contributing to shorter stopping distances and better overall handling. Beyond traditional tire pressure monitoring, VibroSense offers additional functionalities such as tire tread wear analysis and wheel imbalance and loose nut detection. These capabilities make it a vital component in next-generation smart tire solutions, offering vehicle manufacturers a strong competitive advantage in safety and reliability innovations.
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 D68HC11E is a synthesizable SOFT Microcontroller IP Core, fully compatible with the Motorola 68HC11E industry standard. It can be used as a direct replacement for: 68HC11E Microcontrollers and older 68HC11E versions: 68HC11A and 68HC11D In a standard configuration of the core, major peripheral functions are integrated on-chip. An asynchronous serial communications interface (SCI) and separate synchronous serial peripheral interface (SPI) are included. The main 16-bit, free-running timer system contains input capture and output- compare lines and a real-time interrupt function. An 8-bit pulse accumulator subsystem can count external events or measure external periods. Self-monitoring and on-chip circuitry is included to protect the D68HC11E against system errors. The Computer Operating Properly (COP) watchdog system protects against software failures. An illegal opcode detection circuit provides a non-maskable interrupt if an illegal opcode is detected. Two software-controlled power- saving modes – WAIT and STOP are available to preserve additional power. These modes make the D68HC11E IP Core especially attractive for automotive and battery-driven applications. The D68HC11E Microcontroller Core can be equipped with an ADC Controller, which allows using an external ADC Controller with standard ADC software. The ADC Controller makes external ADCs visible as internal ADCs in original 68HC11E Microcontrollers. The D68HC11E is fully customizable – it is delivered in the exact configuration to meet your requirements. There is no need to pay extra for unused features and wasted silicon. The D68HC11E comes with a fully automated test bench and a complete set of tests, allowing easy package validation at each stage of the SoC design flow. Each DCD’s D68HC11E Core has built-in support for DCD’s Hardware Debug System called DoCD™. It is a real-time hardware debugger that provides debugging capability of a whole System-on-Chip (SoC). Unlike other on-chip debuggers, the DoCD™ allows non-intrusive debugging of a running application. It can halt, run, step into or skip an instruction, and read/write any contents of the microcontroller, including all registers, and SFRs, including user-defined peripherals, data, and program memories. All DCD’s IP cores are technology agnostic, ensuring 100% compatibility with all FPGA and ASIC vendors.
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