All IPs > Automotive > Safe Ethernet
In the rapidly evolving automotive industry, the demand for reliable and secure communication systems is paramount. Safe Ethernet semiconductor IPs have become essential components in modern vehicles, facilitating high-speed and dependable data transfer within the complex network of automotive systems. These IPs are specifically designed to meet the rigorous safety standards and protocols required in the automotive sector, ensuring that all electronic control units (ECUs) communicate effectively and efficiently.
Safe Ethernet semiconductor IPs are integral to the operation of advanced driver-assistance systems (ADAS), infotainment systems, and vehicle-to-everything (V2X) communications. They provide a robust framework that supports secure data transmission while minimizing latency and maximizing data integrity. By enabling seamless connectivity across various in-vehicle networks, these semiconductor IPs enhance the overall driving experience and pave the way for autonomous vehicle technologies.
The products in this category are engineered to withstand the harsh conditions typical of automotive environments, including temperature extremes, electromagnetic interference, and vibrations. These semiconductor IPs adhere to the industry's stringent automotive Ethernet standards, such as IEEE 802.1AS and ISO 26262, ensuring that they provide safety-compliant solutions. As vehicles become more connected and automated, Safe Ethernet solutions play an increasingly critical role in maintaining the safety and reliability of these intricate systems.
Choosing the right Safe Ethernet semiconductor IP can significantly impact the performance and safety of your automotive systems. Our extensive selection offers customizable options that cater to various design requirements, making it easier for manufacturers to implement secure and efficient network solutions. Explore our comprehensive range to find the perfect match for your automotive networking needs, and stay ahead in the innovative world of vehicular technology.
The NaviSoC is a cutting-edge system-on-chip (SoC) that integrates a GNSS receiver and an application processor on one silicon die. Known for its high precision and reliability, it provides users with a compact and energy-efficient solution for various applications. Capable of supporting all GNSS bands and constellations, it offers fast time-to-first-fix, centimeter-level accuracy, and maintains high sensitivity even in challenging environments. The NaviSoC's flexible design allows it to be customized to meet specific user requirements, making it suitable for a wide range of applications, from location-based services to asset tracking and smart agriculture. The incorporation of a RISC-V application microcontroller, along with an array of peripherals and interfaces, introduces expanded functionality, optimizing it for advanced IoT and industrial applications. Engineered for power efficiency, the NaviSoC supports a range of supply voltages, ensuring low power consumption across its operations. The chip's design provides for efficient integration into existing systems with the support of a comprehensive SDK and IDE, allowing developers to tailor solutions to their precise needs in embedded systems and navigation infrastructures.
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 Flexibilis Redundant Switch (FRS) is a versatile and high-speed Ethernet Layer-2 switch IP core capable of implementing the High-availability Seamless Redundancy (HSR) and the Parallel Redundancy Protocol (PRP) across a network. This core offers triple-speed operation (10Mbps/100Mbps/1Gbps), facilitating seamless communication for mission-critical systems. FRS is uniquely designed to work in FPGA environments, providing from three to eight Ethernet ports to match various networking requirements. One key feature is its IEEE1588v2 PTP transparent clock support, which ensures precision timing and synchronization across the network for applications that cannot afford time discrepancies. Its architecture supports HSR and PRP without the need for separate RedBox implementations, integrating redundancy directly into the networked devices. The switch supports full-duplex operation and wire-speed Ethernet packet forwarding, making it a top choice for applications demanding redundancy, such as smart grid and industrial automation.
APIX3 represents Inova's third generation of high-speed data link technology, significantly improving the capabilities over previous APIX versions. Designed to meet the demanding requirements of modern vehicle infotainment and cockpit architectures, APIX3 supports data rates of up to 6 Gbps over a single shielded twisted pair cable and up to 12 Gbps using quad twisted pairs. This enhances the functionality of automotive displays, allowing multiple ultra-high-definition video channels to be transmitted over a single connection. The technology is backward compatible with APIX2, allowing integration into a range of automotive networking setups without needing extensive reconfiguration. APIX3 features advancements such as improved diagnostic tools for monitoring cable integrity and longevity, as well as built-in compensation mechanisms for cable age and temperature variations. APIX3 technology not only facilitates advanced multimedia transmission within vehicles but also ensures robust and reliable data exchange, fundamental for next-generation infotainment systems. With added Ethernet channels and wide-ranging interface support, Inova's APIX3 offers a versatile communication solution for real-time data processing, ensuring seamless connectivity across different in-car systems.
The PCD03D Turbo Decoder is adept at handling multiple state decoding for standards such as DVB-RCS and IEEE 802.16 WiMAX. Its core design features an 8-state duobinary decoding structure, facilitating precise and quick signal deconstruction. Additionally, the optional inclusion of a 64-state Viterbi decoder enhances versatility and performance in various environments. This decoder is tailored for applications where agility and high data throughput are critical, making it an invaluable asset in wireless communication infrastructures. The decoder’s architecture supports expansive VHDL core integration, providing durable solutions across FPGA platforms.
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.
The INAP590T is an advanced transmitter module in Inova’s APIX3 series, engineered to provide robust data transmission capabilities tailored for automotive infotainment systems. This component allows for the delivery of uncompressed video and audio data across single cables, accommodating high data bandwidth requirements inherent to modern vehicle architectures. Incorporating features from its APIX3 lineage, the INAP590T supports full duplex communication and provides added resilience through advanced data integrity protocols. The module integrates seamlessly with existing system infrastructures, offering ease of deployment without extensive hardware modifications. It also supports HDCP for enhanced content protection, ensuring secure transmission of sensitive multimedia content. The transmitter’s design accounts for diverse automotive conditions, employing adaptive equalization to compensate for cable aging and variability. This ensures consistent performance and reliability, aligning with automotive industry standards for quality and durability. The INAP590T represents a notable advancement in automotive networking, enhancing in-car user experiences through superior multimedia output options.
The Network Protocol Accelerator Platform (NPAP) is a high-performance solution that accelerates TCP/UDP/IP protocols within FPGA- and ASIC-based systems. Developed alongside the Fraunhofer Heinrich-Hertz-Institute, this platform offers customizable high-bandwidth and low-latency communication capabilities essential for Ethernet links ranging from 1G to 100G. It's designed for various hardware applications, providing turnkey solutions and integrates synthesizable HDL codes capable of being implemented directly into FPGAs. At its core, NPAP enhances CPU performance by handling TCP/UDP/IP processing within programmable logic, thereby boosting network throughput while minimizing latency. The platform's modular architecture supports full line-rate processing up to 70 Gbps in FPGAs and over 100 Gbps in ASICs. It features bi-directional data paths supporting multiple, parallel TCP engines designed for scalable network processing. Its utility extends to FPGA-based SmartNICs, networked storage such as iSCSI, and even high-speed video transmissions. The NPAP can be evaluated via a Remote Evaluation System, allowing potential users to conduct a hands-on assessment through a remote connection to MLE's lab, providing flexibility and saving integration time.
Bluespec's Portable RISC-V Cores offer a versatile and adaptable solution for developers seeking cross-platform compatibility with support for FPGAs from Achronix, Xilinx, Lattice, and Microsemi. These cores come with support for operating systems like Linux and FreeRTOS, providing developers with a seamless and open-source toolset for application development. By leveraging Bluespec’s extensive compatibility and open-source frameworks, developers can benefit from efficient, versatile RISC-V application deployment.
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.
ACAM is a cutting-edge automotive in-cabin monitoring radar platform utilizing 60 GHz mmWave technology for detecting and monitoring living beings inside a vehicle. This sensor system provides comprehensive coverage of the vehicle's interior, ensuring safety and comfort for all passengers. By detecting child presence, seat occupancy, and intrusions, ACAM can drastically enhance the security and usability of any vehicle. Boasting a multifunctional design, ACAM detects vital signs like respiratory rates without requiring direct line of sight. This non-invasive monitoring system respects passenger privacy, providing a seamless user experience while maintaining high standards of safety and efficiency. Its capacity to function unaffected by vehicle interior obstacles makes it an indispensable tool for modern vehicles. In alignment with Euro NCAP requirements, ACAM supports vehicle manufacturers in achieving high safety ratings. It simplifies upgrades, providing easy integration that helps meet stringent safety compliance standards. Drivers and passengers benefit from peace of mind knowing that the ACAM solution adds an extra layer of safety by preventing potential harm through early detection and actionable alerts.
The Nerve IIoT Platform by TTTech Industrial Automation is a sophisticated edge computing solution that bridges the gap between industrial environments and digital business models. Designed for machine builders, it supports real-time data exchange, offering a robust infrastructure that connects physical machines directly with IT systems. The platform optimizes machine performance by allowing for remote management and software deployment. Nerve's architecture is highly modular, making it adaptable to specific industrial needs. It features cloud-managed services that enable seamless application deployments across multiple devices, straight from the cloud or on-premises infrastructure. By supporting various hardware, from simple gateways to industrial PCs, the platform is scalable and capable of growing with business demands. Security is a pivotal aspect of Nerve, offering both IEC 62443 certification for safe deployment and regular penetration tests to ensure integrity and protection. Its integration capabilities with protocols like OPC UA, MQTT, and others allow for enhanced data collection and real-time analytics, promoting efficiency and reducing operational costs through predictive maintenance and system optimization.
The ADNESC ARINC 664 End System Controller is designed for the next generation of avionic networks, offering unmatched performance and reliability. Fully compliant with the RTCA DO-254 DAL A airworthiness standards, this controller ensures the highest level of safety for critical aerospace systems. Through its high-performance multi-host interface, supporting data throughput up to 400 Mbit/s, it addresses the demanding requirements of modern avionics. The controller's design leverages generic VHDL code, allowing it to be device-independent, which improves compatibility and integration across different systems. Thanks to its embedded SRAM and robust architecture, the ADNESC ARINC 664 becomes an integral part of advanced avionic data networks, paving the way for enhanced communication and system performance across aerospace applications.
SiFive's Automotive solutions offer the latest in high-end applications and deterministic real-time processors. These processors are optimized for modern vehicle requirements, providing industry-leading performance with a focus on minimal area and optimized power consumption. SiFive Automotive products are designed to meet stringent automotive standards, including ISO26262 for functional safety and ISO/SAE 21434 for cybersecurity compliance. The Automotive family includes a range of RISC-V safety processors qualified for ADAS/AD, infotainment, body control, and powertrain applications. With features such as Safety Islands and compliance to ASIL B and D standards, the SiFive Automotive processors are tailored to meet critical safety and performance needs of modern vehicles, addressing the industry's demand for reliable and secure solutions in software-defined vehicles. Moreover, SiFive collaborates with industry leaders to ensure robust support across the automotive ecosystem. Whether it's through partnerships to enhance trace and debug solutions or collaborations to leverage robust development tools, SiFive Automotive solutions emphasize ease of integration and comprehensive support, making them a preferred choice for next-generation automotive applications.
The SMPTE 2059-2 solution by Korusys integrates accurately with video and audio signal alignment requirements using a precision PTP time source. This system is optimized for professional broadcast applications, offering high accuracy and low latency for aligning audio and visual content. The FPGA-based module comes complete with software-driven algorithms and timestamping capabilities, ensuring efficient deployment and integration. With a configurable and simple interface, the solution is tailored for seamless broadcast operations.
The INAP375R receiver is designed for high-speed data reception in automotive telematics, part of Inova's APIX2 technology suite. Utilizing a robust physical layer structure based on current mode logic, the receiver efficiently processes data carried over single twisted pair cables up to 3 Gbps. It supports multiple data formats such as video, audio, and GPIO, and has proven to be highly adaptable for a wide range of in-car applications, from infotainment systems to advanced driver assistance systems. With support for two video channels and dynamic configuration options, the INAP375R allows for flexible deployment in various automotive scenarios. One of its defining features is the ability to ensure the integrity of the data transmission by incorporating sophisticated error detection and correction protocols. Moreover, the receiver is compatible with existing automotive network setups, ensuring seamless integration and operation. The INAP375R also features capabilities for additional data connections through SPI and I²C interfaces, adaptability for cable length and quality variations, and an automatically configured adaptive equalizer for maintaining signal quality even as cables age. This receiver is not only crucial for video and audio distribution across the vehicle but also facilitates enhanced functionality through advanced APIX2 protocols.
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.
The Time-Sensitive Networking (TSN) Switch is engineered specifically for automotive ethernet networks, aiming to deliver low-latency, high-reliability communications essential for modern vehicles. This switch's design focuses on providing deterministic data transmission, a critical feature for real-time applications and increasing the data throughput required in today's connected cars. By employing TSN standards, this switch enhances the efficiency of in-car networks, ensuring seamless data flow between a multitude of automotive components. Furthermore, its robust architecture and compliance with automotive standards make it an ideal choice for Original Equipment Manufacturers (OEMs) looking to improve network resilience and reliability within their vehicle platforms. With such technology, automakers can foster safer, more efficient, and interconnected vehicles that meet the dynamic demands of future mobility. This innovation underscores Fraunhofer IPMS's commitment to advancing automotive technologies with cutting-edge solutions.
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 Ceva-XC22 is a cutting-edge DSP core tailored for 5G and 5G-Advanced workloads, offering unprecedented processing capabilities and flexibility for demanding communications applications. This DSP core supports simultaneous processing tasks with high utilization rates, ensuring superior performance across multiple data channels and spectral layers.\n\nCeva-XC22 is built on a dual-threaded architecture with a dynamic scheduled vector processor, which provides extensive processing power for increasingly complex 5G applications. The system also includes a vector computation unit for enhanced arithmetic operations and data handling.\n\nBy leveraging its advanced execution model, Ceva-XC22 delivers significant performance improvements over its predecessors, making it ideal for a range of infrastructure applications, from massive MIMO to core network processing.
The INAP375T transmitter is a vital component of the second-generation APIX2 technology, which focuses on high-speed data transmission in automotive applications. Utilizing a physical layer based on current mode logic, this transmitter can drive data over a single twisted pair cable up to 12 meters, supporting data rates up to 3 Gbps. The INAP375T is engineered to manage multiple types of data, such as video, audio, and GPIO signals, making it ideal for infotainment systems. Its flexible configuration ensures it can adapt to varying signal characteristics, optimizing data integrity for different automotive environments. APIX2 transmitters, like the INAP375T, play a critical role in reducing the complexity of in-car network systems by providing full-duplex data communication channels and enabling error-free data transmission using advanced protocols. Its daisy-chaining ability allows for the expansion of data channels without compromising performance. Configurations such as remote configuration capabilities make it possible to manage changes without physical access, promoting easier maintenance and upgrades. The robust architecture of the INAP375T ensures high-performance communication between various car components. It integrates seamlessly with the vehicle's existing communication protocols, thereby enhancing the performance of rear seat entertainment systems and other multimedia interfaces. The physical flexibility of this transmitter sets it apart, allowing it to handle different cable types and compensate for age-related cable deterioration.
The Flexibilis Redundant Card (FRC) is a sophisticated PCIe Network Interface Card engineered to deliver uncompromised Ethernet network redundancy through its implementation of the High-availability Seamless Redundancy (HSR) and Parallel Redundancy Protocol (PRP). This card is essential for mission-critical applications where seamless communication continuity is a necessity. FRC's design incorporates IEEE 1588 Precision Time Protocol for high-accuracy clock synchronization, making it a vital component in environments like power grid systems where precise timing is crucial. By integrating the features of the Flexibilis Redundant Switch (FRS) in a convenient PCIe form factor, the FRC simplifies the deployment of redundant networking across existing infrastructures. With its superior full-speed non-blocking performance, the card is tailored for high-performance networks, ensuring data delivery even under severe network conditions. The FRC is equipped as a convenient solution for professionals seeking to upgrade system reliability without extensive infrastructure modification.
The XRS7000 series switches are cutting-edge integrated circuits designed to add High-availability Seamless Redundancy (HSR) and Parallel Redundancy Protocol (PRP) functionality to devices. These chips provide zero-loss redundancy and are crucial for applications in industrial automation and networking equipment where reliability is key. Supporting both HSR and PRP, these switches ensure that no single point of failure can interrupt Ethernet communication. Leveraging the IEEE1588-2008 Precision Time Protocol, the XRS7000 series also facilitates precise time synchronization across networked devices. This capability not only enhances the reliability of Ethernet networks but also plays a pivotal role in applications requiring synchronized operations over multiple devices. The series includes different models like the XRS7003 and XRS7004, offering various port configurations to suit specific network requirements. These devices support robust protocols, quality of service features, and are compatible with gigabit Ethernet, providing an optimal balance of performance and redundancy for modern networking demands.
The Trimension NCJ29D6 enhances ultra-wideband (UWB) applications with its superior ranging capabilities in dense environments. This device is specifically created for high-performance communication in applications that require utmost precision and reliability, such as indoor navigation and high-level asset management. The NCJ29D6 integrates seamlessly into smart systems, offering improved interaction through sophisticated signal processing and transmission techniques. Its design is focused on providing accurate and secure communication channels, which are vital for operations in environments with heavy electronic interference. Additionally, the NCJ29D6 supports a vast range of communication frameworks, making it highly adaptable to various technological ecosystems. Whether facilitating precise localization in medical facilities or enhancing security in large complexes, its ability to deliver reliable, real-time data is unmatched.
Designed for high-energy efficiency, the second-generation Cortex-A725 processor unlocks the potential for advanced consumer experiences in demanding applications, such as AAA gaming and web browsing. As part of the Armv9.2 architecture, this CPU balances power and performance suitable for devices operating under constrained power envelopes. The Cortex-A725 allows for configurations tailored to cost-sensitive markets, making it versatile in its deployment across various technology segments.
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 Cortex-A710 Processor offers a sophisticated balance of performance and energy efficiency, delivering enhanced consumer device experiences. As part of the Armv9 architecture, it introduces improvements in security and performance, optimizing devices like smartphones and smart TVs for modern demands. The architecture supports advanced workloads while being energy-conservative, ensuring longer device battery life and responsiveness in interactive applications.
The S32J Ethernet Switches are a cornerstone in NXP's vehicular networking solutions, uniquely equipped to handle the growing demands of connected vehicle systems. They afford automotive designers the versatility and precision needed to support the development of secure, scalable, and efficient vehicle networks. These premier switches provide high-quality Ethernet connectivity that supports a variety of modern vehicular applications. By facilitating communication within vehicle systems, they enhance both the safety and functionality of connected vehicles, creating a robust framework for advanced automotive technology solutions. Thanks to comprehensive support for various vehicular protocols, the S32J Ethernet Switches enable seamless data transmission across complex systems. This allows for the integration of emerging technologies, such as autonomous driving aids and multimedia systems, thus solidifying their pivotal role in developing next-generation automotive infrastructures.
Powering the next generation of motor control systems, the S32M2 Integrated Solution is tailored for 12V automotive environments, offering a sophisticated blend of analog and digital capabilities. It's engineered to serve as a foundational element for vehicles that demand efficient motor control paired with precise power distribution. This scalable solution adeptly addresses the complexities of modern-day motor functionality within vehicles, such as managing power-intensive operations while ensuring safety and performance. Its integrated approach allows for seamless control over essential vehicular systems, optimizing energy use and minimizing power losses. By facilitating advanced control and operational efficiency, the S32M2 enables manufacturers and developers to design systems that are not only high-performing but also eco-friendly. It stands at the forefront of automotive innovation, equipping vehicles with the necessary tools to meet current and future demands for reduced emissions and enhanced driving experiences.
The AVB/Automotive Ethernet Switch is tailored for automotive and professional audio/video bridging applications that require precise synchronization and low-latency data transfer. This technology enables seamless integration into complex network architectures while maintaining high-performance levels critical for automotive systems and AV environments. This switch supports key protocols including Audio Video Bridging (AVB) and Ethernet Audio Video Bridging (AVB), which are essential for maintaining the quality of service in multimedia communications. With its robust design, it facilitates the real-time transmission of audio and video streams without compromising on data integrity or timing accuracy. Designed to work with multiple network standards, the AVB/Automotive Ethernet Switch delivers flexible networking solutions that can be adapted for a wide range of applications in the automotive and AV domains. This adaptability, combined with robust synchronization capabilities, makes it an ideal choice for environments demanding high data throughput and precision timing.
Manufactured for secure ranging applications, the Trimension NCJ29D5 harnesses ultra-wideband (UWB) technology to redefine spatial accuracy and security. It is particularly advantageous in IoT ecosystems and automated industrial settings where connectivity and precision are paramount. The NCJ29D5 offers robust localization, distinguished by its ability to maintain high accuracy even in electromagnetically noisy surroundings. Its advanced features provide reliable communication, making it suitable for integration into existing and emerging smart systems. Engineered for versatility, this device not only facilitates meticulous positioning but also supports diverse communication protocols, enriching IoT networks and enhancing industrial automation processes. It serves as a keystone in building safer, smarter, and more efficient digital environments.
The XRS7004E Switch is a high-performance integrated solution designed to incorporate the HSR and PRP protocols for robust network redundancy. Tailored for industrial applications, this switch provides essential network synchronization via the IEEE1588 standard, ensuring that all connected devices remain perfectly in sync for seamless operations. The XRS7004E supports multiple gigabit Ethernet ports with its integrated RGMII interfaces, allowing it to handle high data throughput efficiently. Its advanced feature set includes cut-through and store-and-forward operations, which optimize packet delivery and network efficiency while minimizing latency. Additionally, the device is equipped with comprehensive VLAN tagging, quality of service features, and priority queuing systems to ensure data packets are handled and prioritized effectively. This makes the XRS7004E ideal for complex industrial environments requiring high-speed data processing alongside redundancy and time synchronization capabilities.
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