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 by ChipCraft is a highly integrated GNSS system-on-chip (SoC) designed to bring navigation technologies to a single die. Combining a GNSS receiver with an application processor, the NaviSoC delivers unmatched precision in a dependable, scalable, and cost-effective package. Designed for minimal energy consumption, it caters to cutting-edge applications in location-based services (LBS), the Internet of Things (IoT), and autonomous systems like UAVs and drones. This innovative product facilitates a wide range of customizations, adaptable to varied market needs. Whether the application involves precise lane-level navigation or asset tracking and management, the NaviSoC meets and exceeds market expectations by offering enhanced security and reliability, essential for synchronization and smart agricultural processes. Its compact design, which maintains high efficiency and flexibility, ensures that clients can tailor their systems to exact specifications without compromise. NaviSoC stands as a testament to ChipCraft's pioneering approach to GNSS technologies.
Time-Triggered Ethernet (TTEthernet) represents a significant advancement in network technology by integrating time-triggered communication over standard Ethernet infrastructures. This technology is designed to meet the stringent real-time requirements of aerospace and industrial applications, offering deterministic data transfer alongside regular Ethernet traffic within a shared network. TTEthernet delivers seamless synchronization across all network devices, ensuring that time-critical data packets are processed with precise timing. This capability is essential for applications where simultaneous actions from multiple systems require tight coordination, such as flight control systems or automated industrial processes. The protocol's compatibility with existing Ethernet environments allows for easy integration into current systems, reducing costs associated with network infrastructure upgrades. TTEthernet also enhances network reliability through redundant data paths and failover mechanisms, which guarantee continuous operation even in the event of link failures. As a result, TTEthernet provides a future-proof solution for managing both regular and mission-critical data streams within a single unified network environment. Its capacity to support various operational modes makes it an attractive choice for industries pursuing high standards of safety and efficiency.
ISELED Technology introduces a revolutionary approach to automotive interior lighting with smart digital RGB LEDs. These LEDs facilitate dynamic lighting solutions by embedding a sophisticated driver directly with the LED, enabling unique features such as pre-calibration and independent temperature compensation. This innovation allows for significant simplification of the overall lighting system architecture as the intricate calibration tasks are handled at the LED module level. The ISELED system supports an expansive 4K address space, offering seamless integration into daisy-chained configurations and precise color control through a straightforward digital command interface. This approach not only enhances visual quality but also reduces the complexity typically associated with RGB LED configurations, eliminating the need for separate power management or additional calibration setups. ISELED’s robust design is particularly beneficial in automotive environments, where durability and dependability are crucial. The technology also extends to ILaS systems, providing interconnected networks of LEDs and sensors that are both energy-efficient and capable of rapid diagnostics and reconfiguration. In essence, ISELED technology allows automotive designers unprecedented flexibility and control over vehicle interior lighting designs.
APIX3 represents the latest evolution in high-speed data transmission modules, engineered specifically for automotive infotainment and cockpit architectures. Designed to interface seamlessly within vehicle IT landscapes, it supports transmissions up to 12 Gbps using shielded or quad twisted pair cables. APIX3 offers unique capabilities like multiple video stream handling on a single connection and supports advanced diagnostics, including cable health checks for predictive maintenance. This technology is backward compatible with APIX2, enhancing modular flexibility across previous and new vehicle designs. With support for UHD automotive display resolutions, APIX3 ensures all-in-one connectivity solutions for complex exterior and interior automotive systems. The APIX3 modules enable comprehensive networking through various serial interface protocols and are positioned as go-to solutions for future-proofing in-car data systems. Each channel within APIX3 is fine-tuned for specific needs, from video data handling to full-duplex telecommunications. Additionally, APIX3 supports Ethernet connectivity for seamless integration into the larger automotive communication network. Thanks to its efficient design, APIX3 provides stability and enhanced bandwidth support, delivering robust performance suited for both entry-level and high-end automotive systems.
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 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 TCP/UDP/IP Network Protocol Accelerator Platform (NPAP) is designed to expedite data transmission while ensuring low latency across Ethernet links. With high-bandwidth capabilities, this platform supports a range of Ethernet speeds from 1G to 100G. The solution benefits from custom hardware acceleration, offloading TCP/UDP/IP tasks to FPGAs, thus freeing up CPU resources for other computational tasks. Significant improvements in network throughput and latency reduction are achieved by integrating complete TCP/UDP/IP connectivity into FPGAs, essential for high-performance applications without using a CPU at all. The NPAP platform offers a highly modular TCP/UDP/IP stack, adaptable to various processing environments. Capable of operating at full line rates in both FPGA (70 Gbps) and ASIC (over 100 Gbps) domains, the platform features 128-bit wide bi-directional data paths and streaming interfaces. It supports scalable processing with multiple parallel TCP engines, allowing seamless operations in data centers and SmartNICs while providing deterministic performance thanks to embedded hardware processing. An additional feature of NPAP is its comprehensive integration within a remote evaluation system. Users can test the platform's capabilities remotely through a dedicated lab, aiding in rapid evaluation without the need for extensive on-site hardware setups. This makes it highly beneficial for applications such as networked storage, iSCSI systems, and automotive backbones, where high data throughput and minimal delay are critical requirements.
The Nerve IIoT Platform by TTTech Industrial is engineered to bridge the gap between real-time data and IT functionalities in industrial environments. This platform allows machine builders and operators to effectively manage edge computing needs with a cloud-managed approach, ensuring safe and flexible deployment of applications and data handling. At its core, Nerve is designed to deliver real-time data processing capabilities that enhance operational efficiency. This platform is distinguished by its integration with off-the-shelf hardware, providing scalability from gateways to industrial PCs. Its architecture supports virtual machines and network protocols such as CODESYS and Docker, thereby enabling a diverse range of functionalities. Nerve’s modular system allows users to license features as needed, optimizing both edge and cloud operations. Additionally, Nerve delivers substantial business benefits by increasing machine performance and generating new digital revenue streams. It supports remote management and updates, reducing service costs and downtime, while improving cybersecurity through standards compliant measures. Enterprises can use Nerve to connect multiple machines globally, facilitating seamless integration into existing infrastructures and expanding digital capabilities. Overall, Nerve positions itself as a formidable IIoT solution that combines technical sophistication with practical business applications, merging the physical and digital worlds for smarter industry operations.
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.
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.
The INAP590T is a cutting-edge digital multi-channel SerDes transmitter specifically crafted for high-speed infotainment applications. Found in the APIX3 suite, this component is built to ensure seamless interactions between HDMI interfaces and APIX2 technology, featuring HDCP support for secure content transmission. This transmitter facilitates a DC-balanced, low latency point-to-point link, perfect for applications requiring robust data transmission like immersive in-car entertainment systems. Capable of handling dual high-definition content streams and supporting resolutions up to 1920x1080 at 30Hz, the INAP590T is ideal for modern display technologies within vehicles. It includes multiple interface options and supports comprehensive full-duplex communication channels, allowing for flexible system design and integration. Furthermore, the robust diagnostic features ensure optimal operation and readily identify potential issues for proactive maintenance. Designed for scalability and forward compatibility, the INAP590T supports extensive bandwidth requirements and is packaged for installation convenience. The integration of Ethernet interfaces, along with GPIO configurations, enables versatile connectivity options to meet diverse automotive needs, ensuring broad applicability across current and next-generation vehicles.
The ACAM In-Cabin Monitoring Solution is a sophisticated 60 GHz mmWave radar designed to enhance vehicle safety and passenger comfort through non-intrusive monitoring. This advanced sensor facilitates comprehensive in-cabin detection, including child presence detection, seat occupancy, intrusion alerts, and vital signs monitoring. Leveraging NOVELIC's extensive software stack, ACAM ensures full interior coverage without compromising passenger privacy.
The ADNESC ARINC 664 End System Controller is designed for high-performance avionics applications and ensures excellent data handling with support for multi-host interfaces operating up to 400 Mbit/s. Built to comply with RTCA DO-254 DAL A standards, this controller stands out for its reliability, making it ideal for critical aviation networks.
The SiFive Automotive family of processors is engineered to meet the evolving demands of the automotive industry, focusing on safety, security, and performance. These processors are compliant with the latest automotive standards, including ISO26262 for functional safety and ISO/SAE 21434:2021 for cybersecurity. Whether addressing needs in advanced driver assistance systems (ADAS), infotainment, or powertrain management, SiFive Automotive solutions provide a robust platform for automotive innovations. At the heart of the Automotive series is a portfolio that encompasses the A-Series processors, delivering top-notch applications processing capabilities. These solutions are optimized for the demands of automotive electronics, supporting both high-performance and real-time processing with low area and power consumption. Testified by leading automotive experts and partners, SiFive's automotive IP features long-term support and a roadmap designed to future-proof automotive technology. SiFive's commitment to automotive excellence is further supported by a wide ecosystem of partnerships with leading technology companies. Their processors are ready for integration into comprehensive automotive solutions, paving the way for the next generation of smart, connected vehicles. The SiFive Automotive family ensures that vehicle manufacturers can meet the high standards of safety and functionality required for modern automotive systems.
The SMPTE 2059-2 Synchronization Solution encompasses all needed logic implementation on an FPGA to generate precise audio and video alignment signals using a reference PTP time source and associated clock. This solution targets professional broadcast markets, offering high accuracy and low latency AV content alignment. The robust FPGA timestamping combined with software-driven algorithms ensures an efficient, compact product that's both easy to deploy and integrate. It comes with a management and configuration interface that provides ultimate flexibility. With an IEEE1588 compliant PTP time source, it generates alignment pulses for specified frame rates along with a timecode. The included API allows for easy configuration of both the IP core and software. The module's strong compliance with IEEE1588v2 enhances its adaptability to existing systems, making it a reliable synchronization solution for professional broadcasters. Korusys has developed this synchronization product suite capitalizing on their extensive expertise in PTP synchronization, ensuring it meets the highest standards of precision required in the broadcast industry. When coupled with its user-friendly management interface and API, this makes the SMPTE 2059-2 Solution a valuable addition to any broadcast synchronization setup.
The INAP375R receiver, functioning as a complementary device to the INAP375T transmitter, is an essential component for high-speed serial data communication in car displays and camera systems. This receiver utilizes the APIX2 technology to maintain a DC-balanced, AC-coupled low latency, point-to-point link over shielded twisted pair (STP) cables. Its physical layer can support data transfer rates up to 3 Gbps, offering low electromagnetic interference (EMI) for delicate automotive electronics. Primarily targeting automotive display applications, the INAP375R supports flexible video interfaces that can handle 1 to 2 independent video streams, managing both parallel RGB and LVDS connections with ease. The receiver is engineered with an integrated Media Independent Interface (MII) that interfaces directly with Ethernet MACs, expanding its application potential to full network capabilities. The presence of a full-duplex communication channel ensures uninterrupted, synchronized data, video, and audio transmission across system components. This device is packaged in an LQFP or aQFN format, providing robust design options to accommodate diverse automotive circuit board specifications. It also features advanced diagnostic capabilities to maximize reliability and minimal error rates, making it suitable for critical automotive applications such as infotainment systems, rear-seat entertainment setups, and driver assistance systems.
The ULYSS MCU is tailored for the demanding requirements of the automotive sector. Built upon a 32/64-bit RISC-V architecture, this microcontroller facilitates high-performance applications ranging from 120MHz up to 2GHz. It combines cost-effectiveness with cutting-edge automotive features, making it an ideal choice for modern vehicles that require robust computing capabilities. This microcontroller is engineered to support a wide array of automotive applications, providing the power and reliability needed for complex automotive systems. From advanced driver assistance systems (ADAS) to autonomous driving technologies, the ULYSS MCU ensures that automotive electronics can meet both current and future needs with minimal adjustments. By incorporating sophisticated RISC-V technology, the ULYSS MCU stands out in the competitive landscape as a powerful and flexible solution. It reflects Cortus's dedication to innovation and excellence in semiconductor design, positioning itself as a key player in the evolution of the automotive electronics industry.
The TSN Switch for Automotive Ethernet is designed to enhance the performance reliability of Ethernet networks in automotive environments. Utilizing Time-Sensitive Networking (TSN) standards, it ensures low-latency data transmission critical for real-time automotive applications. This switch is instrumental in supporting the next generation of automotive systems, handling the increasing data demands from different vehicle sensors and actuators efficiently. The implementation of TSN enables precise control over data flow, helping to synchronize various data streams across diverse domains, from infotainment to safety-critical systems. The switch's architecture supports various IEEE 802.1 TSN standards, guaranteeing robust and synchronized data transmission, critical for the high-speed demands in modern-day vehicles. Beyond its hardware prowess, this switch integrates seamlessly within automotive electronic control units (ECUs), offering flexibility and scalability in performance. Its modular design allows it to adapt to future enhancements in vehicle design, making it a pivotal component in the connectivity ecosystem of smart, connected cars.
PhantomBlu, specifically engineered for military applications, offers sophisticated mmWave technology for secure, high-performance communications across various tactical environments. This product is designed for strategic defense communications, enabling connectivity between land, sea, and air vehicles. PhantomBlu excels in supporting IP networking on robust anti-jam resistant mesh networks, ensuring communication security and reliability. Its configurable and adaptable design makes PhantomBlu suitable for diverse military scenarios, from convoys on the road to high-altitude surveillance operations. The system is distinguished by its stealth capabilities like low probability of interception (LPI) and detection (LPD), as well as its highly efficient data transmission rate, which exceeds that of Wi-Fi and 5G technologies. PhantomBlu's deployment requires no dependency on fiber networks, featuring a quick setup process suited for mobile and tactical requirements. Its design supports long-range communications, effective up to 4 km and allows seamless integration with existing defense infrastructure, making it a future-proof solution for all modern military communications needs. The product is licensed for operations over 57-71 GHz, offering scalable and high-data rate networks essential for today's demanding defense operations.
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.
Time-Sensitive Networking (TSN) is an innovative suite of Ethernet standards developed to enhance multi-faceted communication networks with deterministic capabilities. TSN allows time-critical and regular traffic to coexist on the same network, ensuring that essential operations receive priority bandwidth and timeliness without sacrificing performance for other applications. This technology offers precise timing synchronization, crucial for sectors like automotive, aerospace, and industrial automation where control systems need to interact seamlessly. By guaranteeing that data packets are transmitted and received in a timely and predictable manner, TSN minimizes latency and jitter, significantly improving network stability and performance. TSN's flexible architecture supports a variety of quality of service (QoS) levels, enabling users to tailor network behavior to specific operational needs. It is designed for scalability and interoperability with existing Ethernet standards, allowing industries to prioritize safety and efficiency simultaneously with minimal infrastructure changes. Overall, TSN empowers systems with the communication reliability necessary for advanced automation and control applications, setting the stage for the next generation of smart, interconnected devices.
Deterministic Ethernet is a pioneering technology that extends the capabilities of standard Ethernet to support precise and reliable real-time communications. Engineered for industries requiring stringent network performance, such as aviation, automotive, and industrial automation, it guarantees that critical data packets are delivered within fixed time constraints. This technology integrates various deterministic capabilities like Time-Triggered protocol techniques, providing both scheduled and unscheduled message delivery, which is pivotal for applications where timing precision and data integrity are paramount. Deterministic Ethernet is configured to handle both real-time control messages and regular data traffic over the same network infrastructure, optimizing resource utilization while maintaining efficiency. One of the standout features of Deterministic Ethernet is its ability to offer Quality of Service (QoS) enhancements, ensuring that time-sensitive information is prioritized through the network. This prioritization helps in reducing delays and improves data throughput reliability, which is especially crucial in complex systems demanding consistent operational continuity. By providing a unified communication solution that merges reliability with flexibility, Deterministic Ethernet facilitates the deployment of cutting-edge automation and control systems across varied environments. Its adaptability to existing network setups makes it a cost-effective solution for entities looking to future-proof their data communication frameworks.
The Korusync IEEE1588 PCIe Card delivers telecom-grade synchronization to a range of sectors including high-frequency trading, telecom, and industrial markets. It integrates seamlessly with PC and server infrastructures, using the IEEE1588-2008 protocol for precise time distribution. This card, adorned with high precision timing recovery algorithms and an onboard oven-controlled oscillator, ensures time synchronization with remarkable accuracy - better than 100ns. Software tools provided enhance the card's utility, offering applications for clock management and event timestamping. Engineered for integration, the PCIe card facilitates nanosecond-accurate timing for applications within connected systems. It supports telecom-specific profiles to boost its synchronization capabilities and can deliver ultra-precise time information directly into server applications, ensuring high-performance operation across diverse high-demand sectors.
The INAP375T transmitter provides a high-speed digital serial link specifically designed for display and camera applications in automotive environments. Utilizing APIX2 technology, it supports DC-balanced, AC-coupled low latency connections over shielded twisted pair (STP) cables, facilitating data transfer with a bandwidth reaching up to 3 Gbps. This transmitter offers a flexible video interface that can accommodate one or two independent video streams, integrating seamlessly with video resolutions such as 1600x600 pixels at refresh rates up to 100Hz. Notably, the device supports comprehensive full-duplex communication channels, reinforcing connectivity for diverse automotive applications. With its sophisticated AShell protocol, the INAP375T ensures error-detection and seamless data transmission. Connectivity extends further through a Media Independent Interface (MII), which allows direct pairing with an Ethernet media access controller, ensuring robust network capabilities. Moreover, the inclusion of a built-in audio path permits synchronous transmission of multiple stereo audio channels, contributing to enhanced multimedia experiences inside vehicles. Featuring a versatile LQFP or aQFN package, the INAP375T is engineered to support backward compatibility with APIX1 technology, offering substantial flexibility across legacy and modern systems. Its sophisticated configuration options, accessed via interfaces like SPI, further bolster its position as an integral component in advanced driver assistance and infotainment systems in the automotive industry.
The logiREF-ACAP-MULTICAM-ISP HDR ISP Framework is designed for multi-camera applications requiring high definition real-time processing using the Versal ACAP platform. This complete HDR ISP video processing framework is capable of handling parallel streams from three UHD automotive video cameras. Xylon has optimized this solution for environments demanding robust image processing, with a focus on enhancing image quality in various lighting conditions—an essential capability for automotive and surveillance applications. The design framework integrates seamlessly with existing systems, utilizing the framework's capabilities to enhance image signal processing pipelines. This innovative framework serves as a powerful tool for developers aiming to harness the latest in image processing technologies, ensuring rapid deployment and optimized performance for high-bandwidth video streams.
The IEEE1588 Precision Time Protocol (PTP) Solution from Korusys is crafted to offer a versatile, high-performance system aligned with the IEEE1588v2 standard. It features multiple plug-and-play modules, including a Line Rate Master capable of managing up to 4000 slaves. The solution supports full software network stacks, network simulation tools, and is customizable to specific user needs. The flexible architecture of this PTP solution means it can be tailored to suit varied operational requirements, whether as a Line Rate Master, compliant slave, or with network simulation capabilities. The focus is on delivering high performance, with the Master handling packets at gigabit line rates, maintaining seamless operation even under heavy demand. This solution emphasizes precision and adaptability, providing tools for extensive timing recovery analysis and network load simulation, all within an intuitive framework. Users benefit from bespoke IP offerings, precision timing tools, and simulation options, all designed to integrate efficiently into existing networks.
The Cortex-A710 Processor, forming part of the Arm v9 "big" CPU designs, offers notable improvements in both performance and energy efficiency, particularly suited for mobile and computing devices like smartphones and tablets. This processor stands out with enhancements in architecture that boost overall computing capabilities while ensuring secure execution through integrated security features. Its design achieves a 30% boost in energy efficiency, making it essential for modern, high-demand mobile applications.
The Cortex-A725 Processor is a high-efficiency, out-of-order CPU designed to elevate consumer devices like gaming consoles and smart TVs. Utilizing the latest Armv9.2 architecture, it provides enhanced performance within a constrained power envelope. It offers advanced support for AAA gaming, ensuring smooth operation in power-limited environments while providing sustained performance. Ideal for devices requiring a fine balance between computing power and energy efficiency.
Gazzillion Misses™ is a unique technology developed by Semidynamics designed to overcome latency issues in memory-intensive applications. Embedded within the company's RISC-V processor cores, this technology allows multiple outstanding memory requests simultaneously, bypassing traditional pipeline stalls caused by cache misses. This enables processors to continue executing instructions rather than waiting for data retrieval, significantly reducing idle cycles. By handling up to 128 simultaneous requests, Gazzillion Misses™ significantly boosts system performance and is highly beneficial in big data, HPC, and AI environments where bandwidth is critical. This technology effectively increases memory throughput, making it ideal for applications with extensive data stream requirements, such as machine learning models and complex algorithms in data centers. Moreover, its implementation allows for more straightforward software development processes, easing complexity by providing an efficient framework to sustain high memory bandwidth. It ensures that the processor's compute capabilities are fully utilized, enhancing overall system response and efficiency. This makes Gazzillion Misses™ a keystone in modern architecture for high-performance computing solutions.
Developed to meet stringent automotive safety standards, Vantablack Vision ADAS Coating plays a critical role in minimizing unwanted light reflections in Advanced Driver Assistance Systems (ADAS). This nanomaterial-free coating is particularly beneficial in shielding cameras and enhancing performance by eliminating stray light effects that can degrade sensor accuracy. Under harsh driving conditions, this coating maintains optimal performance, ensuring safety and reliability. Vantablack Vision is tailored to meet the growing demand for superior stray-light management in optical sensors, benefiting applications such as lane departure warnings, traffic sign recognition, and head-up displays. Its advanced formulation prevents fogging or outgassing even at elevated temperatures, making it suitable for prolonged use in vehicles. It allows for a seamless integration into existing designs without compromising on functionality. The application of Vantablack Vision to glare shields in cameras and HUDs results in significantly improved contrast ratios and reduced visual artifacts. This makes it an economical solution that not only enhances the aesthetic experience but also ensures that automotive safety requirements are consistently met. The deployment of this coating technology is supported across various global locations, underscoring its versatility and adaptability.
The ARINC 664 (AFDX) End System is designed to implement an Avionics Full-Duplex Switched Ethernet (AFDX) Network, compliant with ARINC 664 Part 7. It supports multiple physical interfaces including MII, RMII, GMII, and SGMII, capable of handling data transmission at 10 Mbps, 100 Mbps, or 1000 Mbps efficiently. This IP core enables robust communication between avionics systems, utilizing AXI interfaces for host control, status management, and message transactions. The core employs internal buffering to handle message loads without requiring external memory, improving system performance and reliability. This optimization is pivotal in sustaining efficient data flow and minimizing latency in avionics applications. Developed to Design Assurance Level A standards per DO-254 guidelines, it also includes a Certification Kit to support regulatory compliance efforts for its users. Enhanced with optional radiation-hardened configurations, the ARINC 664 (AFDX) End System is built to endure rigorous conditions, making it ideal for in-flight and other high-security communication environments. The IP's modular design ensures it can be easily incorporated into a variety of system architectures, further broadening its applicability across the aviation industry.
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.
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