All IPs > Automotive > LIN
Automotive Local Interconnect Network (LIN) semiconductor IPs are vital components in modern vehicle communication systems. These low-cost, reliable solutions are designed to enhance in-vehicle networking by facilitating communication between different elements of an automotive electronic system. LIN protocols are crucial for non-critical communication networks in vehicles, enabling effective interconnection of various electronic components such as sensors, actuators, and controllers.
The primary application of LIN semiconductor IP is in the automotive industry, specifically designed to support body electronics such as door modules, seat controls, and climate systems. As automobiles continue to integrate more electronic systems, the demand for efficient, cost-effective, and easily implementable communication solutions like LIN is growing. LIN IPs offer a low-cost alternative to more complex networks, ensuring smooth, reliable operation for non-mission-critical automotive functions.
Within this category, you'll find semiconductor IPs that include LIN transceivers, LIN controllers, and integrated LIN controllers with transceivers. These components simplify the development process by providing ready-to-implement solutions that meet automotive industry standards. They are designed to support the robust requirements of automotive environments, including temperature ranges, voltage levels, and signal integrity.
Overall, Automotive LIN semiconductor IPs are indispensable for manufacturers aiming to optimize vehicle performance and reliability while managing costs. By utilizing these IPs, manufacturers can ensure that their vehicles maintain seamless internal communication for secondary systems, enhancing both functionality and user experience.
Time-Triggered Ethernet (TTEthernet) is a pioneering development by TTTech that offers deterministic Ethernet capabilities for safety-critical applications. This technology supports real-time communication between network nodes while maintaining the standard Ethernet infrastructure. TTEthernet enables reliable data delivery, with built-in mechanisms for fault tolerance that are vital for spaces like aviation, industrial automation, and space missions. One of the key aspects of TTEthernet is its ability to provide triple-redundant communication, ensuring network reliability even in the case of multiple failures. Licensed for significant projects such as NASA's Orion spacecraft, TTEthernet demonstrates its efficacy in environments that require dual fault-tolerance. As part of the ECSS engineering standard, the protocol supports human spaceflight standards and integrates seamlessly into space-based and terrestrial networks. The application of TTEthernet spans across multiple domains due to its robust nature and compliance with industry standards. It is particularly esteemed in markets that emphasize the importance of precise time synchronization and high availability. By using TTEthernet, companies can secure communications in networks without compromising on the speed and flexibility inherent to Ethernet-based systems.
aiSim 5 stands as a cutting-edge simulation tool specifically crafted for the automotive sector, with a strong focus on validating ADAS and autonomous driving solutions. It distinguishes itself with an AI-powered digital twin creation capability, offering a meticulously optimized sensor simulation environment that guarantees reproducibility and determinism. The adaptable architecture of aiSim allows seamless integration with existing industry toolchains, significantly minimizing the need for costly real-world testing.\n\nOne of the key features of aiSim is its capability to simulate various challenging weather conditions, enhancing testing accuracy across diverse environments. This includes scenarios like snowstorms, heavy fog, and rain, with sensors simulated based on physics, offering changes in conditions in real-time. Its certification with ISO 26262 ASIL-D attests to its automotive-grade quality and reliability, providing a new standard for testing high-fidelity sensor data in varied operational design domains.\n\nThe flexibility of aiSim is further highlighted through its comprehensive SDKs and APIs, which facilitate smooth integration into various systems under test. Additionally, users can leverage its extensive 3D asset library to establish detailed, realistic testing environments. AI-based rendering technologies underpin aiSim's data simulation, achieving both high efficiency and accuracy, thereby enabling rapid and effective validation of advanced driver assistance and autonomous driving systems.
Silvaco provides a suite of Automotive IP tailored for in-vehicle network standards and SoC designs. With support for CAN-FD, FlexRay, and LIN, these production-proven controllers are essential for automotive systems. The IP package includes subsystems and peripherals like Quad SPI, UART, and power management units, ensuring comprehensive support for system design.
The Time-Triggered Protocol (TTP) is a cornerstone of TTTech's offerings, designed for high-reliability environments such as aviation. TTP ensures precise synchronization and communication between systems, leveraging a time-controlled approach to data exchange. This makes it particularly suitable for safety-critical applications where timing and order of operations are paramount. The protocol minimizes risks associated with communication errors, thus enhancing operational reliability and determinism. TTP is deployed in various platforms, providing the foundation for time-deterministic operations necessary for complex systems. Whether in avionics or in industries requiring strict adherence to real-time data processing, TTP adapts to the specific demands of each application. By using this protocol, industries can achieve dependable execution of interconnected systems, promoting increased safety and reliability. In particular, TTP's influence extends into integrated circuits where certifiable IP cores are essential, ensuring compliance with stringent industry standards such as RTCA DO-254. Ongoing developments in TTP also include tools and methodologies that facilitate verification and qualification, ensuring that all system components communicate effectively and as intended across all operating conditions.
Designed to ensure reliable communication in automotive networks, the TSN Switch for Automotive Ethernet orchestrates robust timing and synchronization across multiple network components. It leverages Time-Sensitive Networking (TSN) standards to guarantee real-time performance and low latency, which are critical in vehicular communication systems. This switch is pivotal for managing complex data flows in automobiles, supporting advancements in autonomous vehicle technologies by enabling the seamless integration of various data streams. The switch is engineered to align with the increasing demands for high-speed connectivity in modern automobiles. With a focus on enhancing safety and operational efficiency, it allows for precise control over packet transmission, minimizing the risk of data collisions and ensuring that high-priority information is accurately transmitted through the network. This focus on precise data management makes the TSN Switch vital for deploying advanced driver-assistance systems (ADAS) and infotainment solutions. By incorporating TSN protocols, this switch enhances the reliability of vehicle networks, thereby facilitating a safer and more interconnected driving experience. It supports the integration and coordination of sensors, processors, and communication networks within the vehicle, making it an indispensable component in the development of next-generation smart transportation solutions.
The RISCV SoC - Quad Core Server Class is engineered for high-performance applications requiring robust processing capabilities. Designed around the RISC-V architecture, this SoC integrates four cores to offer substantial computing power. It's ideal for server-class operations, providing both performance efficiency and scalability. The RISCV architecture allows for open-source compatibility and flexible customization, making it an excellent choice for users who demand both power and adaptability. This SoC is engineered to handle demanding workloads efficiently, making it suitable for various server applications.
The RFicient chip is a cutting-edge technology designed to optimize power usage in IoT applications. This ultra-low-power receiver is ideal for environments requiring long-term battery operation, such as remote sensors in industrial IoT setups. With its efficient energy harvesting capabilities, the RFicient chip is pivotal in advancing sustainable technology solutions, reducing power consumption within the Internet of Things (IoT) framework.
ISELED represents an avant-garde approach to automotive interior lighting, integrating smart RGB LEDs with advanced drivers into a single unit. This technology supports instantaneous color calibration and temperature management, vastly improving lighting quality without the need for complex external controls. Designed for seamless integration into vehicle interiors, ISELED offers low power consumption and adaptability through its digital communication protocol, enabling precise control and coordination of lighting arrays for enhanced aesthetic and functional applications in automotive settings.
Serving as a counterpart to the INAP375T, the INAP375R receives high-speed data over a single cable with similar capabilities. This receiver can handle video and audio data without errors, owing to its implementation of the error-correction protocol AShell. It supports flexible connectivity options, adapting to different video interfaces and data configurations required in modern infotainment systems within cars. The robust design ensures compatibility with older APIX devices, thereby delivering seamless integration in automotive communication networks.
InPsytech's Automotive IP Suite encompasses a comprehensive range of interfaces and controllers tailored for the automotive industry. These IPs are engineered to address unique automotive requirements such as reliability, safety, and performance, ensuring that automotive electronics meet regulatory standards and consumer expectations. The suite includes interfaces for common automotive communication protocols and specialized controllers for managing sensor inputs, power distribution, and data handling. By integrating these components, automotive manufacturers can enhance vehicle functionality and connectivity, paving the way for smarter, more secure vehicles. Given the industry's move towards autonomous and connected vehicles, InPsytech's automotive solutions prioritize scalability and compatibility with emerging technologies. Together, these features ensure that manufacturers can meet evolving demands, from electric vehicle support systems to advanced driver assistance applications.
APIX3 stands as the third generation of Inova’s APIX technology, engineered to elevate the capacity and functionality of automotive infotainment systems. APIX3 enables the transmission of UHD video over singular or multiple channels, reaching speeds of up to 12 Gbps with quad twisted pair cables. This latest version maintains backwards compatibility with APIX2 and includes advanced diagnostic tools to monitor cable integrity. Its advanced features offer enhanced Ethernet and serial protocol support, meeting a broad spectrum of automotive communication needs.
The I2C Master/Slave Controller from Digital Blocks provides robust interfacing solutions via AMBA bus systems, managing complex communication between microprocessors and I2C bus components. It supports standard, fast-mode, and high-speed protocols, ensuring responsiveness to modern I2C connectivity requirements. This controller is integral to systems needing reliable communication in both high-speed and power-efficient environments.
The INAP590T combines advanced transmission capabilities with cutting-edge security features like HDCP support. It facilitates the secure transmission of video and audio data, supporting high-definition multimedia interfaces. Aimed primarily at automotive infotainment systems, this transmitter offers scalable bandwidth options, ensuring that even with the transmission of multiple video streams, data integrity and speed are not compromised. Its ability to adapt to various transmission setups makes it a core component in the latest infotainment architectures.
The ULYSS MCU is an automotive microcontroller tailored for high-performance automotive applications. Built on the robust RISC-V architecture, it offers both 32-bit and 64-bit configurations. The MCU can achieve operating speeds from 120MHz up to 2GHz, making it ideal for use in body control, chassis and safety, and advanced driver-assistance systems (ADAS). It aims to provide a cost-effective and scalable solution with extensive peripheral integration, intended to meet the varied demands of the automotive industry, while supporting high-speed data processing and connectivity features.
The ACAM (Automotive In-Cabin Monitoring) is a 60 GHz mmWave radar sensor designed for monitoring within a vehicle's cabin. It features comprehensive coverage, detecting the presence of people without requiring a direct line of sight, which maintains passenger privacy. This system offers critical functionalities like child presence detection, seat occupancy information, and alerts for intrusion or proximity. Its compliance with the upcoming Euro NCAP 2025 protocol positions it as a leader in ensuring automotive safety and comfort.
The INAP375T is a feature-rich transmitter designed for high-speed differential data transmission. It uses APIX2 technology, enabling efficient data transfer over a single twisted pair (STP) cable at speeds up to 3Gbps. This transmitter supports flexible frame configurations filled with video, audio, and data, adaptable to various automotive applications. The device incorporates advanced protocols such as AShell for safety-critical data transmission and offers backward compatibility with previous APIX versions, making it versatile for integrated into existing and new systems.
The SiFive Automotive portfolio is dedicated to delivering robust and high-performing solutions tailored specifically for the automotive industry. With features designed for the evolving needs of modern vehicles, these processors combine high efficiency with safety and security standards, including ISO 26262 and ISO/SAE 21434 compliance. This suite includes a variety of processors catering to automotive applications such as Advanced Driver Assistance Systems (ADAS), in-vehicle infotainment, powertrain, and central computing. Each processor is designed to provide exceptional performance in real-time environments with low power and minimal area requirements, supporting automakers in achieving optimal functionality while adhering to stringent safety standards. Moreover, SiFive Automotive solutions emphasize functional safety with ASIL A-D standards and split-lock certification, ensuring reliability in mission-critical automotive environments. By focusing on safety and performance, SiFive Automotive offers a comprehensive suite of solutions poised to support the next generation of automotive technology.
The AVB/Automotive Ethernet Switch is specialized for automotive and AVB networking solutions requiring precise timing and reliable data transfer. Targeting automotive applications, it fully supports Audio Video Bridging (AVB) standards to provide synchronized media streaming over Ethernet. This switch boasts capabilities like traffic shaping and queue prioritization to ensure consistent data flow, crucial in automotive environments with critical safety requirements. The integration of IEEE 802.1AS and IEEE 1588 standards ensures that synchronization across devices is achieved with sub-microsecond level accuracy. Advanced VLAN support and security protocols further enhance its applicability in networked vehicle systems, ensuring seamless interoperability and high reliability. Customization features enable it to be fine-tuned for specific automotive applications, making it a highly adaptable and future-proof solution for the industry.
The logiUART is a programmable Universal Asynchronous Receiver-Transmitter capable of LIN network integrations. Primarily tailored for automotive ECUs, it allows seamless communication across Local Interconnect Network (LIN), enhancing in-vehicle networking capabilities for AMD FPGA designs.
The logiVDET IP core provides advanced object classification for vehicle detection in video systems, crucial for enhancing driver assistance and surveillance applications. It employs sophisticated algorithmic processing to identify vehicles within data streams accurately, supporting robust automotive safety systems.
The XA035 Automotive Sensor Platform stands as a versatile and high-performance solution tailored for automotive applications. This IP is crafted using X-FAB's advanced CMOS technology to deliver precise sensor functions that meet the automotive industry's stringent standards. The platform facilitates robust integration within vehicular systems, aiding in the development of reliable and accurate automotive components that are critical under varying operational conditions. Designed to endure the demanding environments of automotive applications, the XA035 platform excels in adapting to temperature fluctuations, vibrations, and other environmental stresses, ensuring consistent performance of automotive electronics. It is pivotal for executing tasks such as pressure sensing, temperature monitoring, and other crucial vehicle diagnostics that contribute to enhanced safety and efficiency on the road. The XA035 platform also supports customization, enabling automotive manufacturers to tailor the sensors to specific requirements, thereby optimizing vehicle performance and fuel efficiency. It underscores X-FAB's dedication to innovation in the automotive sector, providing reliable semiconductor solutions that drive next-generation vehicular technology.
XH035 Sensor and High-Voltage Platform has been meticulously developed to cater to high-voltage and sensor integration needs, common in industrial and power applications. This high-performance platform blends the robustness of sensor technologies with the versatility of high-voltage handling, providing a dual advantage to manufacturers needing reliable and scalable solutions. The XH035 platform proficiently manages high-voltage operations while maintaining precise sensor data acquisition, making it ideal for a wide span of industrial applications, from automation to energy management. Its ability to handle high-voltage applications ensures operational consistency and reliability under extreme conditions, proving indispensable for sectors prioritizing durability and performance. Additionally, the platform's adaptability makes it suitable for custom developments, allowing engineers to design applications that meet specific technological needs. This capability reflects X-FAB's commitment to driving innovation and providing industries with semiconductor solutions that enhance operational efficiencies and application responses.
The NRC79A1 is a mmWave radar front end used for applications requiring detailed environmental monitoring and data acquisition. With its 1Tx-1Rx structure, this radar front end is designed for precision and efficiency, ensuring accurate capture and analysis of radar signals. Its application scope spans across numerous industries, making it a staple for organizations that need to harness accurate real-time data for decision-making processes. This all-encompassing capability supports seamless integration into complex technological frameworks.
The NRC60A2 offers a sophisticated mm-Wave radar front end with a 2Tx and 4Rx configuration designed for versatile applications in modern radar technology. This radar front end is tailored for higher precision and enhanced coverage, facilitating its use in advanced detection and monitoring systems. Its robust architecture supports enhanced data gathering and processing requirements, making it ideal for integration in systems where expansive and accurate surveillance is crucial.
The NRC60A1 radar is a compact mmWave radar solution designed for nuanced applications in surveillance and short-range detection. Operating at 60 GHz, it incorporates both transmission and reception capabilities within a single integrated unit. This radar is widely applicable in scenarios necessitating discreet and efficient data collection and transmission, providing a foundation for further processing and analysis in complex monitoring systems. Its minute form and versatile application opportunities make it a key component in modern technological interfaces.
The logiDROWSINE utilizes computer vision to detect driver drowsiness by analyzing facial movements through a camera. Optimized for AMD Zynq 7000 All Programmable SoC, this IP core provides crucial safety measures in automotive systems, identifying signs of fatigue to prevent potential accidents on the road.
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