All IPs > Automotive
The automotive category of semiconductor IPs is primarily dedicated to addressing the intricacies and demands of modern automotive technology. As vehicles become increasingly sophisticated, integrating more electronic systems and sensors, the need for reliable, efficient, and safe semiconductor IP solutions has never been greater. Our diverse range of automotive semiconductor IPs is designed to meet the needs of various automotive applications, from enhancing communication between vehicle components to ensuring the utmost safety and connectivity.
One essential aspect of this category is the variety of communication protocols needed in automotive systems. This includes the classic Controller Area Network (CAN), which is a robust vehicle bus standard allowing microcontrollers and devices to communicate with each other within a vehicle without a host computer. Modern advancements in this area are represented by CAN-FD and CAN XL, which offer extended data formats and faster communication speeds, crucial for accommodating the growing complexity of in-vehicle networks. Additionally, the inclusion of FlexRay and LIN technologies provides options for higher bandwidth communication and budget-friendly local interconnect networks.
Safety is also a pivotal concern in automotive semiconductor IPs, as exemplified by Safe Ethernet technology. Safe Ethernet enables high-speed communication suitable for applications where safety is critical, such as advanced driver-assistance systems (ADAS) and autonomous driving technologies. These semiconductor IPs are integral in ensuring information is shared accurately and immediately between vital components, thus reducing the room for error and increasing overall vehicle safety.
Overall, the automotive category of semiconductor IPs offers essential tools for developing vehicles that are not only connected and efficient but also highly safe and reliable. Whether you’re working on enhancing the internal communications of a vehicle, implementing advanced safety systems, or developing new technologies for the networked, autonomous vehicles of tomorrow, our automotive semiconductor IP catalog has the resources you need to succeed.
KPIT Technologies leads in the development of Advanced Driver Assistance Systems (ADAS) and autonomous driving solutions, building systems that enhance vehicle safety, comfort, and performance. These innovations extend across various aspects of vehicle automation, leveraging AI-driven data analytics and sensor fusion technologies to enable intelligent driving functions. KPIT's ADAS offerings are designed to assist drivers in complex traffic situations, reduce collision risks, and enhance the overall driving experience through adaptive, high-precision control systems. Central to KPIT's efforts in this space is the integration of state-of-the-art technologies, including machine learning algorithms and real-time data processing capabilities. These complement their extensive industry knowledge to deliver robust, scalable, and interoperable solutions that adhere to the latest automotive safety standards. Emphasizing modular design, KPIT ensures that automakers can easily integrate these technologies into existing and new vehicle platforms. KPIT's expertise extends to collaborating with automakers on developing sophisticated autonomous systems that promise to redefine the future of personal and commercial mobility. By partnering with leading automotive companies, KPIT continues to pioneer advancements in vehicular autonomy, ensuring greater safety and efficiency on roads worldwide.
aiWare is a high-performance NPU designed to meet the rigorous demands of automotive AI inference, providing a scalable solution for ADAS and AD applications. This hardware IP core is engineered to handle a wide array of AI workloads, including the most advanced neural network structures like CNNs, LSTMs, and RNNs. By integrating cutting-edge efficiency and scalability, aiWare delivers industry-leading neural processing power tailored to automobile-grade specifications.\n\nThe NPU's architecture emphasizes hardware determinism and offers ISO 26262 ASIL-B certification, ensuring that aiWare meets stringent automotive safety standards. Its efficient design also supports up to 256 effective TOPS per core, and can scale to handle thousands of TOPS through multicore integration, minimizing power consumption effectively. The aiWare's system-level optimizations reduce reliance on external memory by leveraging local memory for data management, boosting performance efficiency across varied input data sizes and complexities.\n\naiWare’s development toolkit, aiWare Studio, is distinguished by its innovative ability to optimize neural network execution without the need for manual intervention by software engineers. This empowers ai engineers to focus on refining NNs for production, significantly accelerating iteration cycles. Coupled with aiMotive's aiDrive software suite, aiWare provides an integrated environment for creating highly efficient automotive AI applications, ensuring seamless integration and rapid deployment across multiple vehicle platforms.
The Metis AIPU M.2 Accelerator Module by Axelera AI is a compact and powerful solution designed for AI inference at the edge. This module delivers remarkable performance, comparable to that of a PCIe card, all while fitting into the streamlined M.2 form factor. Ideal for demanding AI applications that require substantial computational power, the module enhances processing efficiency while minimizing power usage. With its robust infrastructure, it is geared toward integrating into applications that demand high throughput and low latency, making it a perfect fit for intelligent vision applications and real-time analytics. The AIPU, or Artificial Intelligence Processing Unit, at the core of this module provides industry-leading performance by offloading AI workloads from traditional CPU or GPU setups, allowing for dedicated AI computation that is faster and more energy-efficient. This not only boosts the capabilities of the host systems but also drastically reduces the overall energy consumption. The module supports a wide range of AI applications, from facial recognition and security systems to advanced industrial automation processes. By utilizing Axelera AI’s innovative software solutions, such as the Voyager SDK, the Metis AIPU M.2 Accelerator Module enables seamless integration and full utilization of AI models and applications. The SDK offers enhancements like compatibility with various industry tools and frameworks, thus ensuring a smooth deployment process and quick time-to-market for advanced AI systems. This product represents Axelera AI’s commitment to revolutionizing edge computing with streamlined, effective AI acceleration solutions.
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.
AndesCore Processors offer a robust lineup of high-performance CPUs tailored for diverse market segments. Employing the AndeStar V5 instruction set architecture, these cores uniformly support the RISC-V technology. The processor family is classified into different series, including the Compact, 25-Series, 27-Series, 40-Series, and 60-Series, each featuring unique architectural advances. For instance, the Compact Series specializes in delivering compact, power-efficient processing, while the 60-Series is optimized for high-performance out-of-order execution. Additionally, AndesCore processors extend customization through Andes Custom Extension, which allows users to define specific instructions to accelerate application-specific tasks, offering a significant edge in design flexibility and processing efficiency.
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.
The Ncore Cache Coherent Interconnect is designed to tackle the complexities inherent in multicore SoC environments. By maintaining coherence across heterogeneous cores, it enables efficient data sharing and optimizes cache use. This in turn enhances the throughput of the system, ensuring reliable performance with reduced latency. The architecture supports a wide range of cores, making it a versatile option for many applications in high-performance computing. With Ncore, designers can address the challenges of maintaining data consistency across different processor cores without incurring significant power or performance penalties. The interconnect's capability to handle multicore scenarios means it is perfectly suited for advanced computing solutions where data integrity and speed are paramount. Additionally, its configuration options allow customization to meet specific project needs, maintaining flexibility in design applications. Its efficiency in multi-threading environments, coupled with robust data handling, marks it as a crucial component in designing state-of-the-art SoCs. By supporting high data throughput, Ncore keeps pace with the demands of modern processing needs, ensuring seamless integration and operation across a variety of sectors.
Systems4Silicon's DPD solution enhances power efficiency in RF power amplifiers by using advanced predistortion techniques. This technology is part of a comprehensive subsystem known as FlexDPD, which is adaptive and scalable, independent of any particular hardware platform. It supports multiple radio standards, including 5G and O-RAN, and is ready for deployment on either ASICs or FPGA platforms. Engineered for field performance, it offers a perfect balance of reliability and adaptability across numerous applications, meeting broad technical requirements.
The EW6181 GPS and GNSS solution from EtherWhere is tailored for applications requiring high integration levels, offering licenses in RTL, gate-level netlist, or GDS formats. This highly adaptable IP can be ported across various technology nodes, provided an RF frontend is available. Designed to be one of the smallest and most power-efficient cores, it optimizes battery life significantly in devices such as tags and modules, making it ideal for challenging environments. The IP's strengths lie in its digital processing capabilities, utilizing cutting-edge DSP algorithms for precision and reliability in location tracking. With a digital footprint approximately 0.05mm² on a 5nm node, the EW6181 boasts a remarkably compact size, aiding in minimal component use and a streamlined Bill of Materials (BoM). Its stable firmware ensures accurate and reliable position fixations. In terms of implementation, this IP offers a combination of compact design and extreme power efficiency, providing substantial advantages in battery-operated environments. The EW6181 delivers critical support and upgrades, facilitating seamless high-reliability tracking for an array of applications demanding precise navigation.
LightningBlu is a cutting-edge solution provided by Blu Wireless, designed specifically to serve the high-speed rail industry. This technology offers consistent, on-the-move multi-gigabit connectivity between trackside and train, which ensures a reliable provision of on-board services. These services include seamless internet access, enhanced entertainment options, and real-time information, creating a superior passenger experience while traveling. Utilizing mmWave technology, LightningBlu is capable of offering carrier-grade performance, supporting Mobility applications with remarkable consistency even at speeds exceeding 300 km/h. Such capabilities promise to revolutionize the connectivity standards within the high-speed rail networks. By integrating this advanced system, railway operators can ensure uninterrupted communication channels, thus optimizing their operations and boosting passenger satisfaction. The solution primarily operates within the mmWave spectrum of 57-71 GHz, making it a future-proof choice that aligns with the expanding global demand for high-quality, high-speed railway communications. With LightningBlu, Blu Wireless is spearheading the movement towards carbon-free, robust connectivity solutions, setting a new standard in the transportation sector.
The CANmodule-III is a sophisticated full CAN controller designed to handle communication on the CAN bus with outstanding efficiency. Built upon Bosch's fundamental CAN architecture, this module is fully CAN 2.0B compliant, facilitating seamless communication transactions across the network. It is optimized for system-on-chip integrations, providing customizable options to cater to specific application requirements. The module stands out with its inherited functions which ensure uninterrupted main core operations, even when additional functionalities are layered around it. Having been deployed in various applications from aerospace to industrial control, the CANmodule-III's proven reliability makes it a preferred choice for developers seeking robust communication solutions in FPGA and ASIC technologies.
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.
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.
eSi-ADAS is a radar IP suite designed to enhance the performance and responsiveness of automotive and unmanned vehicle systems. It includes a complete Radar co-processor engine, facilitating rapid situational awareness necessary for safety-critical applications. The scalable nature of this IP makes it adaptable for various automotive and drone-based projects.
D2D® Technology, developed by ParkerVision, is a revolutionary approach to RF conversion that transforms how wireless communication operates. This technology eliminates traditional intermediary stages, directly converting RF signals to digital data. The result is a more streamlined and efficient communication process that reduces complexity and power consumption. By bypassing conventional analog-to-digital conversion steps, D2D® achieves higher data accuracy and reliability. Its direct conversion approach not only enhances data processing speeds but also minimizes energy usage, making it an ideal solution for modern wireless devices that demand both performance and efficiency. ParkerVision's D2D® technology continues to influence a broad spectrum of wireless applications. From improving the connectivity in smartphones and wearable devices to optimizing signal processing in telecommunication networks, D2D® is a cornerstone of ParkerVision's technological offerings, illustrating their commitment to advancing communication technology through innovative RF solutions.
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.
Specially engineered for the automotive industry, the NA Class IP by Nuclei complies with the stringent ISO26262 functional safety standards. This processor is crafted to handle complex automotive applications, offering flexibility and rigorous safety protocols necessary for mission-critical transportation technologies. Incorporating a range of functional safety features, the NA Class IP is equipped to ensure not only performance but also reliability and safety in high-stakes vehicular environments.
The SiGe BiCMOS technology is designed to handle demanding RF applications with optimal efficiency. This solution provides low noise figures and exceptional linearity, catering to wireless communication needs. With the inclusion of silicon-germanium, the technology leverages the benefits of reduced power consumption while maintaining high performance. In the RF domain, SiGe BiCMOS stands out due to its effective integration of high-speed bipolar and low-power CMOS transistors on the same chipset, enhancing its appeal for designers. This integration supports a wide range of frequencies, addressing the diverse needs of today's communication systems. Engineers often choose SiGe BiCMOS for applications where both analog and digital processing are required on a single platform. Its versatility and reliability make it ideal for infrastructure markets and portable devices, helping designers achieve their performance targets while streamlining manufacturing processes.
The L5-Direct GNSS Receiver by oneNav is a revolutionary solution built to leverage the advanced capabilities of L5-band satellite signals. Distinguishing itself by operating solely on the L5 frequency, this product delivers exceptional positioning accuracy and resilience, free from the interference commonly associated with legacy L1 signals. This advanced GNSS receiver is engineered to cater to a variety of professional applications that demand robust performance under challenging conditions, such as dense urban areas.\n\nLeveraging oneNav's proprietary Application Specific Array Processor (ASAP), the system provides best-in-class GPS signal acquisition and processing without compromising sensitivity or fix time. The use of an innovative single RF chain allows for optimal antenna placement, reducing the overall form factor and enabling integration into devices that require stringent size and cost constraints. This makes it an ideal choice for wearable and IoT device applications where space and energy consumptions are pivotal considerations.\n\nAdditionally, the L5-Direct GNSS Receiver incorporates machine learning algorithms to effectively mitigate multipath errors, offering unrivaled accuracy by distinguishing direct from reflected signals. The system is specifically designed to be energy efficient, offering extended operational life critical for applications such as smart wearables and asset tracking devices. Its resilience against GPS jamming and interference ensures it remains a reliable choice for mission-critical operations.
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.
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.
This technology represents a significant innovation in the field of wireless energy transfer, allowing for the efficient transmission of power without physical connections or radiation. By leveraging magnetic resonance, this non-radiative energy transfer system can power devices over distances with high efficiency. It's designed to be safe and environmentally friendly, avoiding the pitfalls of electromagnetic radiation while maintaining a high level of power transfer efficiency. The technology finds its applications in various sectors, including consumer electronics, automotive, and industrial applications where it provides a seamless and reliable solution to power transfer needs. The system's capability to transfer power efficiently without contact makes it ideal for scenarios where traditional power connections might be impractical or inconvenient, enabling new levels of convenience and flexibility for users. Designed to integrate smoothly with existing infrastructure, this energy transfer system can significantly reduce reliance on traditional charging methods, paving the way for more innovative and sustainable energy solutions. Furthermore, the system's architecture is geared towards scalability and adaptability, making it suitable for a wide range of devices and use cases.
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.
The 8b/10 Decoder by Roa Logic is a comprehensive implementation of the 8b/10b encoding scheme developed by Widmer and Franaszek. This decoder offers a full solution that automates special comma detection and identifies K28.5 characters, which is essential for maintaining data integrity during transmission. It is designed for environments where precise data decoding is crucial, supporting seamless data transfer across various communication interfaces. This decoder ensures high accuracy in data interpretation by meticulously translating encoded bitstreams back to their original data form. Crafted with precision, it facilitates reliable data communication while reducing error rates during transmission. It is ideally suited for applications requiring error-free data exchange, where decoding accuracy is paramount. Supporting a range of protocols that utilize the 8b/10b scheme, the decoder’s robust design ensures compatibility and reliable performance. Its straightforward integration supports developers in creating efficient platforms for data handling, reinforcing the reliability of communication systems at large.
The FCM1401 is a highly efficient 14GHz CMOS power amplifier tailored for applications within the Ku-band spectrum, typically ranging from 12.4GHz to 16GHz. It excels in performance by delivering significant RF output power also characterized by a gain of 22dB. This amplifier is engineered with a power added efficiency (PAE) of 47%, making it an optimal choice for long-range communication systems where energy conservation is paramount. Additionally, it operates with a supply voltage of 1.8V, which aligns with its design for lower power consumption. This product is available in a QFN package, providing a compact solution for modern RF system designs.
ArrayNav harnesses adaptive antenna technology to enhance GNSS functionality, optimizing performance in environments with complex multichannel challenges. By leveraging various antennas, ArrayNav achieves enhanced sensitivity and coverage, significantly mitigating issues such as multipath fading. This results in greater positional accuracy even in dense urban environments known for signal interference. This adaptive approach presents an invaluable asset for automotive Advanced Driver Assistance Systems (ADAS), where high precision and rapid response times are critical. The improved antenna diversity offered by ArrayNav not only augments signal strength but also robustly rejects interference and jamming attempts, assuring consistent operation and accuracy. In terms of power efficiency, ArrayNav stands out by combining exceptional accuracy with reduced power needs, offering a flexible solution adaptable for both standalone and cloud-computing modes. This dual capability ensures that system designers have the optimal framework for developing customized solutions catering to specific application requirements. Overall, ArrayNav’s cutting-edge technology fosters improved GNSS operations by delivering enhanced sensitivity and accuracy, thereby meeting the stringent demands of modern automotive and navigation systems.
The DB9000AXI Display Controller is engineered to interface with Frame Buffer Memory through the AMBA AXI Protocol, connecting seamlessly to display panels with variable resolutions from QVGA up to full HD, with options for 4K and 8K enhancements. This versatile controller is crafted to manage a broad spectrum of display resolutions, and advanced versions integrate complex composition features like overlay windows, hardware cursor, and color space conversion. An emphasis is placed on blending and resizing, making it particularly suitable for high-definition display projects.
ShortLink offers a powerful and comprehensive RF Transceiver IP for 433, 868, and 915 MHz frequency bands, which is compliant with the IEEE 802.15.4-2015 standard. With features like data rates ranging from 1.2 k to 500 kbps, it provides a robust solution for diverse low-power wireless network applications. The transceiver handles both transmission and reception at various bands, making it suitable for worldwide deployment. The integration is simplified with built-in voltage regulators, bandgap references, and bias generation. The flexible design of this RF transceiver supports different modulation techniques, including GFSK, BPSK, and O-QPSK, catering to a wide range of communication needs. The configurable architecture ensures compatibility with custom protocols beyond standard applications, providing adaptability for unique project requirements. Built for reliability, the IP showcases RX sensitivity down to -106 dBm and TX power ranging from -20 to +8 dBm, ensuring long-distance communication capabilities and excellent power efficiency. The inherent compliance with standard wireless communication protocols eliminates the need for external radio chips, streamlining the integration process into various SoC designs.
The hellaPHY Positioning Solution from PHY Wireless is crafted to optimize IoT deployments across various environments using 5G networks. It melds advanced algorithms with cutting-edge edge computing capabilities to deliver stunningly accurate and efficient location services. The technology, by leveraging existing cellular infrastructures, achieves superior accuracy akin to GNSS systems but at a fraction of the power and data cost, making it ideal for environments where traditional systems falter. What distinguishes hellaPHY is its ability to independently estimate locations within the device, preserving user privacy by avoiding external storage or cloud computation of location data. This self-sufficiency not only ensures data security but also dramatically reduces network congestion, furthering its utility in dense IoT networks. The hellaPHY solution boasts adaptability to existing infrastructure, providing operators with unprecedented spectral efficiency. It allows seamless integration into various devices with minimal impact on current setups, providing a compelling reason for firms to employ this breakthrough technology for boosting IoT scalability and performance.
The ARINC 664 (AFDX) End System DO-254 IP core is crafted to implement the Avionics Full-Duplex Switched Ethernet (AFDX) network as specified in ARINC 664 Part 7. This IP core provides a reliable solution for aerospace applications demanding robust network communications. Integrating this IP core ensures compliance with the industry standards for data exchange over AFDX networks, crucial for maintaining synchronization and coordination among multiple avionics systems. It supports full-duplex operations, enabling simultaneous send-and-receive capabilities critical for real-time communications. The AFDX End System core's architecture supports enhanced safety and fault-tolerance measures, catering to the rigorous demands of avionics networks. Its deployment enhances the efficiency of communication systems, ensuring that safety-critical operations are consistently managed and data integrity is maintained.
Time-Sensitive Networking (TSN) represents TTTech's continued leadership in the field of data communication standards. Particularly beneficial in sectors requiring high bandwidth and interoperability, TSN facilitates the establishment of networks where timing precision and control over data traffic are critical. TSN supports synchronization across devices, using a strict traffic scheduling system that ensures data packets are transmitted in a timely manner. TSN's versatile architecture allows it to be adopted in various industries, such as automotive, industrial automation, and information technology. As a bridge between operational technology and information technology domains, TSN enables seamless data flow, fostering a more connected ecosystem. Its implementation ensures not only enhanced performance but also the incorporation of advanced features such as redundancy for reliability and the prioritization of critical data streams. Designed for modern network requirements, TSN technologies developed by TTTech come with extensive tools and resources that aid in the configuration and deployment of networks. By aligning with IEEE standards, TSN protocols promote interoperability across numerous platforms, thereby supporting the convergence of diverse network systems into a single, cohesive architecture.
The TSP1 Neural Network Accelerator by Applied Brain Research is a groundbreaking AI chip engineered to enhance processing power and efficiency for time series data. Utilizing state-of-the-art neural network capabilities, it facilitates natural voice interfaces and advanced bio-signal classification within compact battery-powered devices. The TSP1 ensures fully self-contained processing across multiple network setups, handling diverse voice and sensor signal applications with low power consumption. This chip is revolutionary in its ability to perform high-efficiency neural network operations while sustaining ultra-low energy usage. The integrated DC-DC supply supports a range of power options, ensuring adaptability across various applications like wearables and smart home technologies. Moreover, its architecture offers robust AI inference with minimal latency, making it a prime choice for those aiming to incorporate efficient AI processing into edge devices. Technically, the TSP1 supports up to four stereo audio inputs and features secure on-chip storage, empowering devices to execute complex AI functions with great fidelity. Its compact packaging options make it suitable for a host of applications, ensuring seamless integration in environments where space and power efficiency are critical. This AI chip stands out in the market for its ability to offer comprehensive AI capabilities while remaining highly efficient and low-cost, promising transformative impacts across multiple sectors.
The CAN 2.0/CAN FD Controller offered by Synective Labs is a comprehensive CAN controller suitable for integration into both FPGAs and ASICs. This controller is fully compliant with the ISO 11898-1:2015 standard, supporting both traditional CAN and the more advanced CAN FD protocols. The CAN FD protocol enhances the original CAN capabilities by transmitting payloads at increased bitrates up to 10 Mbit/s and accommodating longer payloads of up to 64 bytes compared to the standard 8 bytes. This controller integrates seamlessly with a variety of FPGA devices from leading manufacturers such as Xilinx, Altera, Lattice, and Microsemi. It supports native bus interfaces including AXI, Avalon, and APB, making it versatile and highly compatible with various processing environments. For those deploying System on Chip (SOC) type FPGAs, the controller offers robust processor integration options, making it an ideal choice for complex applications. A standout feature of this IP is its focus on diagnostics and CAN bus debugging, which makes it particularly beneficial for applications like data loggers. These diagnostic features can be selectively disabled during the build process to reduce the controller's footprint for more traditional uses. With its low-latency DMA, interrupt rate adaptation, and configurable hardware buffer size, this CAN controller is engineered for high efficiency and flexibility across different applications.
The ARINC 429 Transmitter Core is designed in alignment with ARINC Specification 429 Part 1-17, ensuring robust and reliable data transmission for avionics systems. This core plays a critical role in transmitting information across avionics networks, adhering to stringent industry standards for safety and performance. With its capability to handle avionics protocols specifically designed for the aerospace sector, the transmitter is a key element in facilitating efficient communication between aircraft systems. Its design ensures the integrity and accuracy of data sent across ARINC 429 buses, providing a dependable solution for avionics communications. The transmitter efficiently converts data into formats compatible with the ARINC 429 standard before transmission, enabling harmonized communications across various subsystems within an aircraft. Its deployment in aircraft systems supports critical operations where timely and precise data exchange is paramount.
The SMS OC-3/12 Transceiver Core is engineered for SONET/SDH applications, providing comprehensive support for OC-3 and OC-12 data rates. This core is designed with a deep sub-micron single poly CMOS architecture to ensure compliance with ANSI, Bellcore, and ITU-T specifications for jitter tolerance and generation.\n\nFeaturing innovative architecture, this transceiver core integrates high-frequency PLLs with on-chip loop filters, reducing external component requirements and simplifying design processes. Proprietary advanced signal processing techniques enhance signal integrity, mitigating external and PCB noise issues that commonly affect traditional transceiver designs.\n\nThe core is optimized for multiport SOC designs, allowing for easy process migration and adaptability for new application domains. It includes custom configurable serializer-deserializer (SERDES) options, further enhancing its suitability for complex system integrations and high-performance requirements in networking infrastructure.
CANmodule-IIIx represents a cutting-edge CAN controller featuring post-modern enhancements for high-performance communication. This advanced controller, while fully adhering to CAN 2.0B standards, boasts 32 receive and 32 transmit mailboxes. Tailored for streamlined integrations, it ensures flexibility and innovation be it an FPGA or an ASIC system. By preserving the core's fundamental function while allowing added wrapping features, the CANmodule-IIIx provides unmatched adaptability without compromising on performance. The module has demonstrated its efficiency in sectors like automotive and telecommunications, ensuring swift data transactions and system reliability across various operational environments.
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.
This innovative system is designed to enhance the user experience of wireless power transfer applications by ensuring precise alignment and compatibility between power transmitters and receivers. It includes mechanisms for detecting the positioning of a device relative to a charging source, optimizing the alignment process to ensure efficient energy transfer. The system's compatibility detection capabilities allow it to recognize and adapt to various device specifications and charging standards, reducing the risk of charging errors and improving overall system reliability. With this system, users can achieve optimal alignment automatically, making the process of wireless charging simpler and more intuitive. The technology is particularly beneficial in scenarios where positioning is critical for energy transfer efficiency, such as in automotive or portable device applications. It addresses common challenges in wireless power systems, such as alignment drift and signal path obstructions, ensuring that power is delivered smoothly and consistently.
The GDP-XL Design Management System by IC Manage is a high-performance, global solution designed for seamless design and IP management. It excels in providing a robust framework for collaboration across single and multiple design sites, integrating teams in different locations securely and efficiently. This system is particularly valued for its ability to support rigorous control over databases, ensuring the accuracy and consistency required for critical RFIC design processes. With GDP-XL, companies can manage their design data more reliably, addressing challenges commonly faced in semiconductor design environments. It offers enhanced productivity through unrivaled scalability and flexibility, allowing organizations to adapt to ever-changing design requirements without compromise. The system's advanced capabilities are leveraged by top-tier semiconductor companies to maintain a competitive edge in a fast-paced industry. As the industry's leading design data and IP management system, GDP-XL also supports innovative collaboration patterns, enabling seamless sharing and revision control among global teams. Its robust architecture facilitates the integration of various methodologies, aiding companies in efficiently navigating complex designs and maintaining meticulous tracking of their IP assets.
ARDSoC is a pioneering embedded DPDK solution tailored for ARM-based SoCs, specifically engineered to enhance ARM processor performance by bypassing the traditional Linux network stack. This solution brings the efficiencies of DPDK, traditionally reserved for datacenter environments, into the embedded and MPSoC sphere, extending DPDK functionalities to a broader range of applications. The architecture of ARDSoC allows users to minimize power consumption, decrease latency, and reduce the total cost of ownership compared to conventional x86 solutions. This IP product facilitates packet processing applications and supports various technologies such as VPP, Docker, and Kubernetes, ensuring hardware-accelerated embedded network processing. Designed for integration across Xilinx Platforms, ARDSoC also offers high flexibility with the ability to run existing DPDK programs with minimal modification. It is optimized for performance on ARM A53 and A72 processors, ensuring that data structures are efficiently produced and consumed in hardware, thereby providing robust and reliable network data handling capabilities.
The CANsec Controller Core is crafted to cater to the emerging needs of secure in-vehicle communication systems. Adding a layer of security to the traditional Controller Area Network (CAN), this core incorporates advanced encryption and decryption capabilities, ensuring data is transmitted securely within the vehicle's network. With a rising number of electronic control units (ECUs) in vehicles, safeguarding the integrity and confidentiality of data is paramount, and CANsec excels in this domain. Emphasizing robust security protocols, the CANsec Controller Core is pivotal in protecting automotive systems from unauthorized access and cyber threats. It integrates seamlessly with existing CAN systems, allowing for an enhanced security overlay that does not compromise the network's performance or reliability. By ensuring the confidentiality and authenticity of the messages exchanged, this core addresses critical concerns in automotive cybersecurity, reinforcing trust in vehicular network communications. The versatile nature of CANsec allows it to be embedded in various ECUs, ensuring comprehensive protection across the network. As automakers increasingly rely on interconnected systems, this core supports the secure deployment of advanced features and services, enhancing consumer confidence in the safety and reliability of electronic vehicle systems.
FireCore provides a robust solution integrating both PHY and Link layers, necessary for high-performance IEEE-1394 and AS5643 applications. Supporting transmission speeds up to S3200, it leverages precise timing controls and enhanced data encapsulation features. This IP core ensures compatibility with existing systems, enabling easy upgrades from older implementations. Its design allows for flexible configurations tailored to specific system needs, making it suitable for deployment in complex avionics environments.
The ARINC 429 Receiver Core is engineered to comply with the ARINC Specification 429 Part 1-17, facilitating reliable data reception in avionics systems. This core is pivotal in aerospace communications, supporting the one-way communication standard used extensively in commercial and regional aircraft systems. As a fundamental building block in avionics, the ARINC 429 Receiver processes messages at a high reliability level, ensuring that critical data are accurately and consistently received and interpreted. The receiver's robust architecture ensures that it operates efficiently in demanding environments, meeting stringent aviation standards. Its adaptability allows for seamless integration into existing systems, providing a vital link in the data transmission chain within aircraft. This receiver is particularly suited for use in safety-critical applications, where precision and reliability cannot be compromised.
The intricacies of building a robust SoC lie in having a well-integrated network-on-chip framework. Marquee Semiconductor stands out in developing both coherent and non-coherent NoC-based subsystems and platforms. By integrating various components, these implementations create scalable chiplets that optimize and enhance the performance of complex systems. This setup enables efficient handling of increasing data and device interconnections, ensuring seamless integration within modern SoCs.
Deterministic Ethernet, a hallmark of TTTech's technological expertise, offers a stable and predictable network environment for industrial and mission-critical applications. Unlike standard Ethernet, Deterministic Ethernet incorporates time constraints into its data transmission processes, ensuring precise delivery schedules and synchronized communication. This is crucial for automation and control tasks where timing accuracy is non-negotiable. Incorporated across a range of TTTech networks, this technology guarantees that network behavior can be predicted and controlled, enhancing safety and dependability. Whether used in sophisticated vehicular systems, aerospace applications, or industrial controls, Deterministic Ethernet always assures that data packets are delivered as expected, adhering to strict timeframes and reducing latency issues. Deterministic Ethernet integrates seamlessly with various network technologies, facilitating its adoption in environments necessitating robust communication protocols. Its standards compliance supports worldwide interoperability and paves the way for future innovations in networking technologies. By providing deterministic communication paths, systems employing this technology can meet rigorous industry requirements for reliability and precision.
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 SMPTE 2059-2 Synchronization Solution by Korusys is engineered for synchronizing video and audio signals over IP networks. This involves using an FPGA to implement the necessary logic to align signals with a reference PTP time source and associated clock. The solution is designed for professional broadcast environments, promising high accuracy, low latency synchronization, and ease of integration. It employs advanced software algorithms alongside precise FPGA timestamping, providing a flexible, small footprint solution that is easy to deploy. An API adds further configuration ease, supporting various framerates and timecode generation upon receiving a PTP time source.
The ADNESC ARINC 664 End System Controller by IOxOS Technologies is a high-performance solution tailored for avionic data networks. With full compliance to the RTCA DO-254 DAL A standards, this controller underscores IOxOS's commitment to delivering airworthiness and reliability. It is crafted using generic VHDL code, thus maintaining a device-independent architecture which ensures broad compatibility and ease of integration across various platforms. Capable of supporting multi-host interfaces with speeds up to 400 Mbit/s, the ADNESC controller handles complex communication protocols efficiently, making it an ideal component within data-intensive aerospace environments. The embedded SRAM further enhances its performance, providing swift data processing and reduced latency, which are critical in high-stakes operational settings. Designed with the foresight that aligns with the demands of modern aviation, this controller plays a crucial role in crafting resilient network backbones. Not only does it facilitate robust communication pathways, but it also delivers enhanced system reliability essential for mission-critical applications. Its integration into existing systems supports the development of next-generation avionic platforms tailored to meet the efficiency and scalability demands of future air travel.
The FireSpy Bus Analyzer line by DapTechnology offers a comprehensive range of tools designed for the analysis of IEEE-1394 and AS5643 protocols. They form the backbone of many aerospace and defense programs, ensuring accurate simulation and debugging with protocol decoding, timing analysis, and more. FireSpys are invaluable from early design studies and technology evaluations to system development and aircraft checkouts, handling up to nine-bus configurations for thorough monitoring and analysis across multiple application phases.
PhantomBlu by Blu Wireless is engineered for defense applications, focusing on delivering high-speed, secure, and reliable tactical communications. This mmWave networking solution is designed to be independent of conventional fibre optic or cabled networks, granting greater flexibility and range. With the capability to easily integrate with both legacy platforms and upcoming technological assets, PhantomBlu ensures interoperability and robust connectivity in demanding environments. The mmWave technology used in PhantomBlu allows for multi-gigabit data transmission over significant distances, catering to the dynamic needs of military operations. It can be configured to function as a PCP (hub) or STA (client), enhancing its adaptability in tactical scenarios. This flexibility is vital for mission-critical communications, ensuring data-rich, secure connections even in highly contested environments. By employing low Probability of Detection (LPD) and Low Probability of Interception (LPI) techniques, PhantomBlu provides stealthy communication capabilities, significantly reducing the risks of detection and interference by adversaries. This advanced technology strengthens the defense sector's communication arsenal, providing reliable gigabit connectivity that supports strategic and operational superiority on the battlefield.
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