All IPs > Automotive > CAN
The automotive industry relies heavily on effective communication networks to ensure the seamless operation of various vehicle systems. At the heart of these networks is the Controller Area Network (CAN), a robust vehicle bus standard that allows microcontrollers and devices to communicate with each other without a host computer. Our Automotive CAN semiconductor IP category offers specialized solutions that meet these specific communication needs, ensuring reliable and efficient data exchange in automotive environments.
CAN semiconductor IPs are essential for developing advanced driver-assistance systems (ADAS), powertrain operations, infotainment systems, and other critical automotive functions. These IPs provide designers with highly optimized core architectures that support high-speed, real-time data transfer with minimal latency and error rates. The IPs are designed to be adaptable, supporting a myriad of applications ranging from electric vehicle management systems to complex networked automotive functions.
In this category, you'll find a wide assortment of semiconductor IPs tailored for various CAN protocols, including CAN FD (Flexible Data-rate) and classical CAN networks. These IPs support features such as error handling, message prioritization, and arbitration, which are crucial for maintaining the system's integrity and operational efficiency. With advancements in automotive technology, CAN semiconductor IPs are continuously evolving to support higher data rates and enhanced security features to safeguard vehicle communication networks.
Whether you are developing new automotive systems or upgrading existing networks, our CAN semiconductor IP offerings provide the necessary tools to enhance functionality and performance. By leveraging our robust IP solutions, automotive manufacturers can achieve higher reliability and efficiency in vehicle communication, paving the way for smarter and more connected vehicles. Explore our portfolio to find the semiconductor IPs that best fit your automotive project needs.
Silvaco's Automotive IP is engineered for in-vehicle networks and covers an extensive range of controllers adhering to automotive standards like FlexCAN with CAN-FD, FlexRay, and LIN. These products are production-proven and designed to integrate seamlessly into the SoC's subsystems, ensuring reliability and a high degree of interoperability. This suite of automotive IP is packaged to simplify design processes, reduce time-to-market, and ensure compliance with industry safety standards, making it indispensable in the evolving automotive landscape.
The CT25205 is a sophisticated digital controller designed for 10BASE-T1S Ethernet communications. Compatible with IEEE 802.3cg, it integrates the PMA, PCS, and PLCA Reconciliation sublayers, making it highly suitable for standard cells and FPGA systems. This synthesizable IP core supports seamless integration into any standard IEEE CSMA/CD Clause 4 Ethernet MAC via MII, which enhances its versatility for a multitude of applications. Its embedded PLCA RS uniquely allows existing MAC implementations to adopt advanced PLCA capabilities effortlessly, ensuring an increase in functionality without hardware overhauls. In conjunction with other Canova Tech IPs, such as the CT25208 MAC controller and CT25210 topology discovery IP, it provides a complete solution for implementing 10BASE-T1S within Zonal Gateways System on Chips (SoCs) and microcontrollers. The amalgamation of these components offers a streamlined approach to developing efficient network communication protocols, paving the way for innovative uses in industrial and automotive sectors where reliable data transmission is critical. This IP is especially adept at working alongside standard OPEN Alliance 10BASE-T1S PMD interfaces, reinforcing its compatibility with established industry protocols. For those developing multi-drop Ethernet solutions, the CT25205 stands as a premier choice. Its design, which ensures adherence to IEEE standards while promoting enhanced reliability and performance, makes it an attractive option for a range of applications, from simplifying connectivity in industrial setups to fortifying communications in vehicular networks, underscoring Canova Tech’s commitment to technological advancement and innovation.
The CT25203 serves as an analog front-end module for implementing 10BASE-T1S PHY solutions, conforming to IEEE 802.3cg standards. It is an essential component for engineers and researchers focused on creating efficient Ethernet networks within industrial and automotive ecosystems. This IP core facilitates seamless communication via standard pins, ensuring optimal interaction between the physical layer and digital control counterparts. Featuring high EMC performance, it is implemented on high-voltage process technology, underscoring its reliability for robust communication solutions. The CT25203 allows the development of devices that communicate effectively over standard OPEN Alliance TC14 interfaces, bridging connections between the MAC and PHY layers while supporting various configurations that enhance data integrity and transmission efficiency across the network. This analog front-end represents a critical building block within Canova Tech’s suite of Ethernet solutions. By enabling sturdy and efficient connections in Ethernet-based systems, it directly contributes to easing the path toward modern industrial and vehicular network implementations. Whether for facilitating data flow or ensuring system stability, the CT25203 highlights Canova Tech’s dedication to delivering high-performance IP solutions tailored to complex real-world demands.
The CANmodule-IIIx module enhances the foundation of Inicore's CAN IP offerings, supporting a substantial 32 receive and 32 transmit buffers. This controller meets the stringent requirements of the international CAN standard ISO 11898-1 and is built to accommodate demanding applications like automotive and industrial controls, where expanded message handling and prioritization are critical. The module's design utilizes technology-neutral HDL, ensuring broad compatibility with both FPGA and ASIC implementations. It benefits from on-chip SRAM utilization, optimizing memory handling processes and enabling efficient system integration with ARM-based SoCs through its AMBA 3 APB interface. This comprehensive integration support facilitates seamless integration with minimal latency and high throughput. Debugging and testing are reinforced with advanced features, including various looping modes and an error capture register, which provides insights into communication errors and message states. The mailbox-oriented architecture and provision for message filtering in the first two data bytes make the CANmodule-IIIx particularly advantageous for applications requiring reliable, high-volume data exchanges.
The CANmodule-III is a comprehensive CAN controller module that offers mailbox-based architecture. It meets the international CAN standard ISO 11898-1 and includes 16 receive buffers, each equipped with its own message filter, and 8 transmit buffers with a priority-based arbitration scheme. This configuration ensures optimal support for Higher Layer Protocols (HLP) like DeviceNet and SDC, which demand intricate application-specific features. Built with technology-independent HDL, the CANmodule-III integrates seamlessly into both ASIC and FPGA frameworks, fully utilizing on-chip SRAM structures for enhanced performance. An AMBA 3 Advanced Peripheral Bus (APB) interface simplifies the integration into ARM-based systems-on-chip (SoCs), guaranteeing zero wait-state interface performance. This module supports advanced features such as automatic remote transmission request (RTR) handling and configurable interrupt generation mechanisms. The design is fully synchronous and includes robust test and debugging capabilities—such as various loopback modes and an SRAM test mode—ensuring high reliability and ease of development. This versatile CAN controller offers a sophisticated solution for implementing reliable, high-performance CAN communications in diverse embedded systems.
The EW6181 is a cutting-edge multi-GNSS silicon solution offering the lowest power consumption and high sensitivity for exemplary accuracy across a myriad of navigation applications. This GNSS chip is adept at processing signals from numerous satellite systems including GPS L1, Glonass, BeiDou, Galileo, and several augmentation systems like SBAS. The integrated chip comprises an RF frontend, a digital baseband processor, and an ARM microcontroller dedicated to operating the firmware, allowing for flexible integration across devices needing efficient power usage. Designed with a built-in DC-DC converter and LDOs, the EW6181 silicon streamlines its bill of materials, making it perfect for battery-powered devices, providing extended operational life without compromising on performance. By incorporating patent-protected algorithms, the EW6181 achieves a remarkably compact footprint while delivering superior performance characteristics. Especially suited for dynamic applications such as action cameras and wearables, its antenna diversity capabilities ensure exceptional connectivity and positioning fidelity. Moreover, by enabling cloud functionality, the EW6181 pushes boundaries in power efficiency and accuracy, catering to connected environments where greater precision is paramount.
ASPER is a 79 GHz short-range radar sensor designed to exceed the capabilities of traditional ultrasonic parking assist technologies. With a 180-degree field of view, ASPER provides unparalleled coverage with a single module. This ensures that vehicles ranging from passenger cars to AGVs benefit from complete side coverage without blind spots. The sensor's ability to detect low-lying objects like curbs enhances safety and situational awareness for drivers across a variety of contexts. ASPER integrates seamlessly into vehicle systems, allowing for effective monitoring of front, rear, and side zones for enhanced collision avoidance and traffic awareness. Its robust design optimizes it for urban blind spot detection, providing critical alerts to drivers regarding potential hazards. This technology is crucial for improving both safety and driver confidence in busy urban environments. Designed for scalability, the ASPER radar sensor can be employed in a variety of vehicles, including motorcycles and larger transportation vehicles. Its adaptability ensures comprehensive monitoring, contributing to more effective navigation and obstacle avoidance in all weather conditions. With edge-processing technology, ASPER boasts a host of features that maximize performance while maintaining affordability.
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.
ArrayNav represents a significant leap forward in navigation technology through the implementation of multiple antennas which greatly enhances GNSS performance. With its capability to recognize and eliminate multipath signals or those intended for jamming or spoofing, ArrayNav ensures a high degree of accuracy and reliability in diverse environments. Utilizing four antennas along with specialized firmware, ArrayNav can place null signals in the direction of unwanted interference, thus preserving the integrity of GNSS operations. This setup not only delivers a commendable 6-18dB gain in sensitivity but also ensures sub-meter accuracy and faster acquisition times when acquiring satellite data. ArrayNav is ideal for urban canyons and complex terrains where signal integrity is often compromised by reflections and multipath. As a patented solution from EtherWhere, it efficiently remedies poor GNSS performance issues associated with interference, making it an invaluable asset in high-reliability navigation systems. Moreover, the system provides substantial improvements in sensitivity, allowing for robust navigation not just in clear open skies but also in challenging urban landscapes. Through this additive capability, ArrayNav promotes enhanced vehicular ADAS applications, boosting overall system performance and achieving higher safety standards.
ParkerVision's D2D® Technology revolutionizes RF communication by enabling direct conversion from RF signals to digital data, bypassing traditional intermediate frequency stages. This technology is instrumental in streamlining signal processing, enhancing speed and efficiency of data handling in various wireless communication devices. The D2D technology supports a broad spectrum of applications, including mobile phones, wireless internet, and IoT devices, delivering high performance and adaptability for current and forthcoming technological needs. D2D® shines in its ability to sustain high data rates necessary for modern applications like 4G and 5G networks, bolstering the capabilities of RF integrated circuits with its advanced conversion techniques. Furthermore, this technology is central to facilitating seamless integration across different communication standards, allowing devices to operate over multiple frequency bands without compromising on data quality or speed. The intellectual property surrounding D2D® is robustly protected with a comprehensive patent portfolio, ensuring its exclusivity and opening avenues for strategic partnerships and licensing. By harnessing this technology, devices gain enhanced power efficiency and broader operational capabilities while lowering manufacturing costs and conserving energy, making it a pivotal innovation for evolving communication landscapes.
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 CAN 2.0/CAN FD Controller is a comprehensive CAN controller designed for straightforward integration into FPGAs and ASICs. Compliant with the ISO 11898-1:2015 standard, it supports both traditional CAN and the new CAN FD protocols. CAN FD enhances the original CAN by allowing a higher bitrate of up to 10 Mbit/s and expands the payload to 64 bytes, providing greater flexibility and efficiency in communication. This product is particularly versatile, designed to be compatible with numerous FPGA devices from major manufacturers like Xilinx, Intel (Altera), Lattice, and Microsemi. It supports native bus interfaces such as AXI, Avalon, and APB, facilitating seamless processor integration within SoC-type FPGAs. This makes it an ideal choice for applications requiring robust communication with quick integration into existing systems. The design incorporates a plethora of features aimed at enhancing diagnostic capabilities and CAN bus debugging, which is particularly beneficial for data logger implementations. Despite its extensive feature set, adjustments can be made at the build stage to reduce its footprint for more standard applications. This IP allows for precise control and adaptability, ensuring effective and efficient operation across various deployments.
The DCAN XL presents an advanced CAN Bus controller capable of bridging traditional CAN FD with 100Mbit Ethernet. This innovative solution supports a wide range of data rates up to 20 Mbit/s, with specialized transceivers for bit rates both under and over 10Mbps. Designed in accordance with ISO 11898-1:2015 standards, it ensures compatibility across various automotive and industrial communication systems. By adopting cutting-edge serial communication technologies, the DCAN XL reliably enhances the network's data throughput and integrity, making it indispensable for sophisticated vehicular and machine control applications.
hellaPHY Positioning Solution is an advanced edge-based software that significantly enhances cellular positioning capabilities by leveraging 5G and existing LTE networks. This revolutionary solution provides accurate indoor and outdoor location services with remarkable efficiency, outperforming GNSS in scenarios such as indoor environments or dense urban areas. By using the sparsest PRS standards from 3GPP, it achieves high precision while maintaining extremely low power and data utilization, making it ideal for massive IoT deployments. The hellaPHY technology allows devices to calculate their location autonomously without relying on external servers, which safeguards the privacy of the users. The software's lightweight design ensures it can be integrated into the baseband MCU or application processors, offering seamless compatibility with existing hardware ecosystems. It supports rapid deployment through an API that facilitates easy integration, as well as Over-The-Air updates, which enable continuous performance improvements. With its capability to operate efficiently on the cutting edge of cellular standards, hellaPHY provides a compelling cost-effective alternative to traditional GPS and similar technologies. Additionally, its design ensures high spectral efficiency, reducing strain on network resources by utilizing minimal data transmission, thus supporting a wide range of emerging applications from industrial to consumer IoT solutions.
LightningBlu is an innovative track-to-train solution, delivering a world-first, multi-gigabit, rail-qualified mmWave connectivity platform. Designed for operational efficiency with low maintenance needs, this system is deployed trackside in 1km intervals, seamlessly bridging wireless links between trains and a trackside fiber network. The lightweight train-top node is engineered for on-train installation, featuring two-sector radios that maintain a 3 Gbps aggregate throughout. This solution greatly enhances operational performance, previously deployed successfully across South Western Railways and Caltrain, driving connectivity advancements in high-speed transport. By utilizing Blu Wireless's mmWave technology, LightningBlu offers unmatched connectivity for on-board services such as internet access and entertainment, boasting data speeds significantly faster than conventional 5G mobile communications. This ensures a dramatically improved commuter experience with robust, reliable connectivity over long distances. Meeting stringent environmental standards, LightningBlu operates at 57-71 GHz, in compliance with international radio regulations, offering continuous service and high-speed link management without the extensive power requirements associated with 4G and 5G mobile networks. Technical capabilities include full environmental rail certification, ensuring robustness against stringent rail standards, and a Mobile Connection Manager to facilitate wireless link management. Supporting all six IEEE 802.11ad channels, LightningBlu maximizes throughput, guaranteeing strong connectivity for data-hungry railway applications, heralding a new age of rail travel with unprecedented speed and efficiency.
The PCE04I Inmarsat Turbo Encoder is engineered to optimize data encoding standards within satellite communications. Leveraging advanced state management, it enhances data throughput by utilizing a 16-state encoding architecture. This sophisticated development enables efficient signal processing, pivotal for high-stakes communication workflows. Furthermore, the PCE04I is adaptable across multiple frameworks, catering to diverse industry requirements. Innovation is at the forefront with the option of integrating additional state Viterbi decoders, tailoring performance to specific needs and bolstering reliability in communications.
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.
PhantomBlu serves as Blu Wireless's sophisticated mmWave solution for defense and military operations. It offers advanced tactical connectivity between vehicles and platforms whether on land, air, or sea. The system is designed to support high-performance applications and provides secure, mobile IP networking via a tactical, anti-jam resistant mesh network. PhantomBlu delivers superior data handover capabilities, ensuring low probability of interception and detection, essential for critical military communications. This system is crafted to be highly scalable and customizable, making it suitable for diverse defense needs, from securing critical infrastructure to enhancing vehicular and airborne communication capabilities. Its design supports a range of operational environments and provides robust communications over expansive areas, utilizing innovative integration with electronic warfare systems and cyberspace operations. PhantomBlu elevates defense communications by eliminating dependency on fixed infrastructure such as fiber optics, ensuring rapid setup and high resilience. PhantomBlu integrates advanced networking capabilities that rival and surpass conventional fiber optics, offering a flexible, high-bandwidth system perfectly aligned with modern C4ISR needs. The platform supports long-range connections and boasts rigorous encryption to safeguard tactical data. Its mesh network is tailor-made for interoperability, facilitating cross-domain data sharing efficiently. PhantomBlu embodies the future of military communications, offering dynamic scalability and thrilling operational advantages for defense forces worldwide.
The ARDSoC Embedded DPDK is an innovative FPGA IP core that extends the functionality of DPDK into ARM-based systems. Designed to bypass traditional Linux network stacks, it saves precious ARM processor cycles by directly linking to data processing components. This core brings cutting-edge datacenter capabilities to embedded environments, enhancing performance in low-SWaP (Size, Weight, and Power) applications. ARDSoC excels in reducing total cost of ownership, power consumption, and latency, especially when compared to legacy x86 solutions. The core supports packet vector and container-aware applications, making it ideal for edge devices employing protocols like CCIX, RDMA, and NVMe-oF. With seamless cross-compilation to ARM and significant power and latency reductions, it provides a substantial performance boost in datacenter settings. Designed for Xilinx platforms, the core supports plug-and-play operability with Yocto Linux and Xilinx Vivado. This allows developers to quickly transition applications from prototype to production while maintaining high throughput—up to 64 Gbps—without packet loss. Its harmonized interaction between ARM processors and data structures is a hallmark of Atomic Rules' engineering expertise.
Genesis redefines package and PCB design with a comprehensive simulation-driven approach that optimizes the entire design process. By integrating simulations into the design workflow, Genesis allows for early detection and resolution of potential design issues in circuitry, electromagnetics, and thermal management. Its project management features enable streamlined collaboration across various design functions, ensuring that every aspect of the design is efficiently handled. Furthermore, it supports the cohesive creation of complex circuit designs and facilitates data management for diverse board-level and packaging projects. This platform enhances development efficiency and accelerates product design cycles.
Designed for secure in-vehicle networking, the CANsec Controller Core is a cutting-edge solution for enhancing the security aspects of Controller Area Network (CAN) communications. This core integrates cryptographic protocols to safeguard automotive data transmissions from potential cyber threats, ensuring privacy and data integrity. Apart from boosting security, it also maintains the legacy CAN protocol’s simplicity and robustness, making it suitable for a wide range of automotive applications. This flexibility allows automotive manufacturers to upgrade existing systems with state-of-the-art security without necessitating a complete redesign. The CANsec Controller Core exemplifies Fraunhofer IPMS’s innovative approach to intertwining security with traditional automotive frameworks, ultimately leading to more secure and trustworthy in-vehicle communication systems.
The Trimension SR200 leverages ultra-wideband (UWB) technology to deliver unprecedented accuracy in real-time location systems. Its advanced performance metrics cater to a variety of applications, such as fleet management and complex logistics networks, where precise positional data is critical. By pushing the boundaries of traditional location services, the SR200 offers enhanced range and accuracy, allowing for seamless integration into digital frameworks that require extensive tracking and communication capabilities. It's particularly suitable for dynamic environments that demand rapid data exchange and robust operational efficacy. With an emphasis on high-precision and reliability, the Trimension SR200 supports the development of innovative IoT applications. Its flexibility ensures it can readily adapt to changing technological needs, playing a crucial role in crafting interconnected and responsive industrial systems.
The Trimension SR100 stands out in the ultra-wideband (UWB) domain with its exceptional ability to enable highly accurate and timely data transmissions. It reliably supports various applications that benefit from precise localization and synchronization, making it an asset for environments like emergency response systems and smart city infrastructure. Equipped with advanced processing capabilities, the SR100 facilitates enhanced signal integrity and low-latency communication, thereby boosting reliability and throughput. Its design proves functional for sophisticated setups that require robust and consistent performance in varied conditions. Beyond just localization, the SR100's adaptability allows it to thrive in diverse operational contexts, offering companies flexible solutions to meet their dynamic requirements. This makes it a preferred choice for those wanting to incorporate cutting-edge technology into their smart ecosystem structures.
Designed to redefine location-based services, the Trimension SR040 leverages ultra-wideband (UWB) technology to deliver high performance in positioning and asset tracking applications. Its refined accuracy allows for precise localization, which is crucial in environments like smart agriculture and automated industry, where pinpoint accuracy can significantly impact operational efficiency. With its advanced signal processing capabilities, the Trimension SR040 ensures reliable performance across a wide range of devices and conditions. This makes it an ideal choice for companies looking to enhance their IoT ecosystems through spatially-aware technology. The SR040 supports intricate communication systems, facilitating secure data exchange and interaction across different platforms. This adds a layer of functional safety and reliability, making it a key player in the deployment of next-generation smart systems.
The Trimension SR250 represents a sophisticated advancement in ultra-wideband (UWB) technology, specifically engineered for precise ranging and secure location-based applications. Designed with automotive and industrial environments in mind, it provides robust performance through its exceptional measurement accuracy and resilience in challenging conditions. This makes the SR250 ideal for implementations that demand high precision and security, such as in vehicle-to-everything (V2X) communication and asset tracking. This UWB solution shifts paradigms by integrating cutting-edge ranging capabilities with innovative short-range radar functionalities. By doing so, the SR250 enhances the reliability and security of industrial IoT applications, offering manufacturers and developers the tools to create smarter and more autonomous systems. Whether used independently or within larger embedded ecosystems, the Trimension SR250 empowers a wide range of systems to function efficiently with enhanced safety features and connectivity, forming a cornerstone for future-proof technological landscapes.
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.
NXP's Trimension UWB offering establishes itself as a key player in the realms of secure and precise short-range communication. This technology extends far beyond conventional wireless communication solutions by enabling high-precision location tracking and secure data exchanges, benefiting sectors like automotive, logistics, and various industrial applications. By leveraging ultra-wideband technology, Trimension UWB ensures that devices can communicate with pinpoint accuracy, accommodating scenarios that require fast and reliable location data. This characteristic is especially advantageous in applications such as autonomous vehicle navigation, smart logistics, and industrial automation, where precise communication is crucial. Furthermore, its adaptability across a wide range of devices makes it an essential component in the creation of smart, interconnected ecosystems. From improving operational efficiency to bolstering system security, Trimension UWB meets the demands of contemporary digital infrastructures, facilitating the development of tomorrow's intelligent solutions.
The Trimension OL23D0 is a next-generation ultra-wideband (UWB) device aimed at enhancing the accuracy and reliability of short-range communication in critical applications. Tailored for environments demanding precise tracking capabilities, it excels in sectors such as automotive safety and smart infrastructure. Offering state-of-the-art technology, the OL23D0 integrates advanced sensing mechanisms with robust communication pathways, ensuring seamless interaction among connected components. This allows systems to function with enhanced precision, accommodating complex tasks such as high-speed data synchronization and secure communication. Its versatile nature supports a variety of networking frameworks, making it a highly adaptable tool in the implementation of future-ready solutions. Whether within autonomous vehicles or industrial machinery, the Trimension OL23D0 drives innovation by facilitating more intelligent and efficient operations.
Designed with CAN 2.0B compatibility, the logiCAN IP core facilitates robust networking for automotive and industrial applications, providing seamless device communication. It integrates easily within AMD FPGAs and supports comprehensive communication requirements for modern vehicular networks.
The Trimension SR150 is a versatile ultra-wideband (UWB) solution tailored for applications that require detailed localization capabilities. With its robust construction and adaptive architecture, the SR150 serves industries ranging from automotive to industrial automation, providing a reliable foundation for real-time location services and secure communications. One of the key features of the SR150 is its ability to offer precise location data through its sophisticated ranging capabilities, making it a preferred choice for those looking to integrate advanced tracking and positioning systems. This flexibility ensures it can be adapted to various environmental settings, ensuring consistent performance irrespective of the surrounding conditions. Utilizing UWB technology, the SR150 enhances the functionality of connected devices by facilitating seamless communication and coordination. Its compatibility with other smart systems makes it an indispensable component in the development of smarter, more streamlined operational infrastructures.
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.
This sophisticated RF transceiver IP supports Wi-Fi 6 (802.11ax) and Bluetooth 5.4, along with 15.4 standards for high-end applications. It is capable of concurrent dual-band operations in the 2.4 GHz and 5 GHz bands, designed to meet the demands of advanced wireless communications. The system integrates crucial components, including linear power amplifiers, Rx/Tx switches, and analog channel filters with adjustable bandwidth. A notable feature is its RF reference clock oscillator, optimizing bias conditions for varied use cases. This transceiver IP ensures high performance and adaptability in wireless communication, making it ideal for applications like VR, augmented reality, and smart homes. Its ability to support IEEE 802.11a/b/g/n/ac/ax standards and 1024 QAM, along with bandwidth channels of 20/40/80 MHz, enhances the data transfer rates and efficiency required for demanding tasks. Technical capabilities include fractional-N synthesizers with loop filters, ADCs for calibration, and a scalable architecture. This makes it suitable for application in diverse MIMO configurations for enterprise networks, gaming, and industrial automation.
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 CAN-CTRL controller core supports standard, extended, and CAN FD/XL specifications. It's renowned for its flexibility and integration efficiency in automotive and industrial networks. Designed with support for AUTOSAR and J1939, this core can be easily deployed across varied physical layers, ensuring reliable data transmission. Its small form factor and comprehensive interrupt and buffering features make it a suitable choice for modern vehicle network systems.
VibroSense for Tire Monitoring is an innovative ultra-low-power chip designed to address the gap in current vehicle safety by providing real-time monitoring of tire-road friction. Integrated with standard TPMS systems, this chip enhances ADAS systems by making dynamic road condition feedback possible without relying on indirect and inaccurate friction estimations. By processing data at the sensor level, VibroSense reduces wireless communication overhead, allowing for efficient use of standard battery power or energy harvesting solutions. This chip acts as the missing component in comprehensive vehicle safety, greatly improving the in-tire detection of friction changes, which is critical for maintaining vehicle stability and safety. The precise monitoring of peak friction coefficients allows vehicles equipped with ADAS to respond quicker to road surface changes, contributing to shorter stopping distances and better overall handling. Beyond traditional tire pressure monitoring, VibroSense offers additional functionalities such as tire tread wear analysis and wheel imbalance and loose nut detection. These capabilities make it a vital component in next-generation smart tire solutions, offering vehicle manufacturers a strong competitive advantage in safety and reliability innovations.
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