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.
Silvaco's Automotive IP solutions deliver silicon-proven elements critical for the advancing automotive market. This comprehensive suite includes controllers for In-Vehicle Networking (IVN) standards such as FlexCAN with CAN-FD, high-speed FlexRay, and LIN, ensuring robust communication protocols necessary for modern automotive electronics. Designed to facilitate system-on-chip (SoC) resilience, this IP includes essential cores and peripherals vital for integrated automotive systems. Features such as Quad and Octal SPI, UART, DMA Controllers, and Power Management Units provide the foundational elements that support the robust operation of complex automotive applications, across both electrical and mechanical subsystems. As automotive electronics continue to evolve, Silvaco's automotive solutions ensure adherence to the highest standards of reliability and compliance, promoting advancements in autonomous and connected vehicle technologies.
The CT25205 is a comprehensive digital controller designed for 10BASE-T1S Ethernet applications, providing seamless integration with Ethernet MACs and offering essential PMA, PCS, and PLCA Reconciliation Sublayer components. Crafted in Verilog 2005 HDL, this core is fully synthesizable on standard cells and FPGA systems, ensuring versatile deployment in various network architectures. The IP also supports PLCA RS, enabling advanced Ethernet features without the need for additional MAC extensions. It's developed to function with the OPEN Alliance 10BASE-T1S PMD interface, making it a robust solution for modern Ethernet-based systems.
Time-Triggered Ethernet (TTE) combines the robustness of Ethernet technology with the precision of time-triggered communication. Designed for critical applications that demand reliability and synchronized communication, TTE finds its place in aerospace and industrial sectors. TTE operates by affording secure, deterministic data transmission over Ethernet networks. It achieves this by dedicating specific time slots for high-priority traffic, ensuring latency and jitter are minimized. This segregation allows time-sensitive data to safely coexist with traditional Ethernet traffic, without sacrificing normal network operations. The protocol's architecture underlies a mixed-criticality networking environment, supporting integration with standard Ethernet devices. TTE's scheduling mechanism guarantees timely delivery of critical messages, crucial in environments where even microsecond delays can impact overall system performance. Its application ensures Ethernet networks meet the stringent requirements of real-time operations synonymous with safety-critical systems.
EW6181 is an IP solution crafted for applications demanding extensive integration levels, offering flexibility by being licensable in various forms such as RTL, gate-level netlist, or GDS. Its design methodology focuses on delivering the lowest possible power consumption within the smallest footprint. The EW6181 effectively extends battery life for tags and modules due to its efficient component count and optimized Bill of Materials (BoM). Additionally, it is backed by robust firmware ensuring highly accurate and reliable location tracking while offering support and upgrades. The IP is particularly suitable for challenging application environments where precision and power efficiency are paramount, making it adaptable across different technology nodes given the availability of its RF frontend.
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.
The CT25203 serves as a critical analog front-end for 10BASE-T1S Ethernet systems, working in conjunction with other Canova Tech IP like the CT25205 digital core for a complete solution. This product is engineered to align with the stringent OA TC14 specification, allowing seamless communication over standard 3-pin interfaces commonly used in automotive and industrial Ethernet networks. Its high-voltage process technology ensures optimal electromagnetic compatibility, critical for maintaining performance in challenging environments.
The Nerve IIoT Platform is a comprehensive solution for machine builders, offering cloud-managed edge computing capabilities. This innovative platform delivers high levels of openness, security, flexibility, and real-time data handling, enabling businesses to embark on their digital transformation journeys. Nerve's architecture allows for seamless integration with a variety of hardware devices, from basic gateways to advanced IPCs, ensuring scalability and operational efficiency across different industrial settings. Nerve facilitates the collection, processing, and analysis of machine data in real-time, which is crucial for optimizing production and enhancing operational efficiency. By providing robust remote management functionalities, businesses can efficiently handle device operations and application deployments from any location. This capacity to manage data flows between the factory floor and the cloud transitions enterprises into a new era of digital management, thereby minimizing costs and maximizing productivity. The platform also supports multiple cloud environments, empowering businesses to select their preferred cloud service while maintaining operational continuity. With its secure, IEC 62443-4-1 certified infrastructure, Nerve ensures that both data and applications remain protected from cyber threats. Its integration of open technologies, such as Docker and virtual machines, further facilitates rapid implementation and prototyping, enabling businesses to adapt swiftly to ever-changing demands.
CANmodule-III is a feature-rich CAN controller designed to optimize communications in embedded systems. It supports the concept of mailboxes, offering 16 receive buffers and 8 transmit buffers, each with its own filter for precise control. The module is compliant with the ISO 11898-1 standard for CAN 2.0A/B, making it suitable for automotive and industrial applications where robust and reliable communication is critical. With an AMBA 3 APB interface, it integrates smoothly into ARM-based SoCs, while its synchronous design allows for efficient operation without waiting periods. This module's architecture includes a programmable priority arbitration mechanism, ensuring that messages with a higher priority are transmitted first, an essential feature in systems where timing is crucial. Its design is scalable, allowing for adaptation to specific system requirements, making it versatile for use in various embedded systems. The module also supports features like single-shot transmission and offers debugging support through listen-only and loopback modes. In addition to its core functionality, the CANmodule-III boasts a robust interrupt management system, capable of handling multiple error sources. This includes a locally controlled interrupt and an optional external AHB interface for broader system compatibility. All these features are designed to ensure seamless integration into larger systems, providing a comprehensive CAN controller solution that is adaptable and efficient.
CANmodule-IIIx is an advanced CAN controller core that supports a vast array of communication needs in embedded systems. This module enhances message management with 32 receive and 32 transmit buffers, each equipped with its own filter. Designed to comply with ISO 11898-1, it facilitates comprehensive CAN 2.0A/B communications, ensuring compatibility and performance across multiple applications, including automotive and robotics industries. The module includes an AMBA 3 APB interface for straightforward integration within ARM-based SoCs and is structured using technology-independent HDL, which allows it to be easily adapted to both ASIC and FPGA platforms. Its design offers robust message handling, with programmable priority arbitration that secures the timely transmission of critical messages, a crucial feature in environments demanding immediate response. Providing extensive support for higher layer protocols, the CANmodule-IIIx covers essential elements like automatic RTR response handling and generates interrupts for various message and error conditions. Debugging is also simplified through its listen-only, internal, and external loopback modes. This multibuffering system offers enhanced message management suitable for complex and critical operations.
The Network Protocol Accelerator Platform (NPAP) by Missing Link Electronics is engineered to significantly enhance network protocol processing. This platform leverages MLE's innovative patented and patent-pending technologies to boost the speed of data transmission within FPGAs, achieving impressive rates of up to 100 Gbps. The NPAP provides a robust, efficient solution for offloading processing tasks, leading to superior networking efficiency. MLE's NPAP facilitates multiple high-speed connections and can manage large volumes of data effectively, incorporating support for a variety of network protocols. The design ensures that users benefit from reduced latency and improved data throughput, making it an ideal choice for network-intensive applications. MLE’s expertise in integrating high-performance networking capabilities into FPGA environments comes to the forefront with this product, providing users with a dependable tool for optimizing their network infrastructures.
The ASPER sensor operates at a 79GHz frequency, making it a sophisticated module for automotive applications like parking assistance. This short-range radar sensor boasts a coverage of 180 degrees with a superior detection range that extends beyond other conventional technology, such as ultrasonic systems. Its application in vehicle systems allows for enhanced features, including rear and front collision warning, blind spot detection, and more. ASPER is designed to detect low-lying objects and maintain accurate function in adverse weather conditions like fog or rain, making it a versatile component for comprehensive vehicle safety and awareness systems.
The eSi-ADAS Radar IP Suite and Co-processor Engine is at the forefront of automotive and unmanned systems, enhancing radar detection and processing capabilities. It leverages cutting-edge signal processing technologies to provide accurate and rapid situational awareness, crucial for modern vehicles and aerial drones. With its comprehensive offering of radar algorithms, eSi-ADAS supports both traditional automotive radar applications and emerging unmanned aerial vehicle (UAV) platforms. This suite is crafted to meet the complex demands of real-time data processing and simultaneous multi-target tracking in dense environments, key for advanced driver-assistance systems. The co-processor engine within eSi-ADAS is highly efficient, designed to operate alongside existing vehicle systems with minimal additional power consumption. This suite is adaptable, supporting a wide range of vehicle architectures and operational scenarios, from urban driving to cross-country navigation.
The GNSS VHDL Library is a cornerstone offering from GNSS Sensor Ltd, engineered to provide a potent solution for those integrating Global Navigation Satellite System functionalities. This library is lauded for its configurability, allowing developers to harness the power of satellite navigation on-chip efficiently. It facilitates the incorporation of GPS, GLONASS, and Galileo systems into digital designs with minimum fuss. Designed to be largely independent from specific CPU platforms, the GNSS VHDL Library stands out for its flexibility. It employs a single configuration file to adapt to different hardware environments, ensuring broad compatibility and ease of implementation. Whether for research or commercial application, this library allows for rapid prototyping of reliable GNSS systems, providing essential building blocks for precise navigation capabilities. Integrating fast search engines and offering configurable signal processing capabilities, the library supports scalability across platforms, making it a crucial component for industries requiring high-precision navigation technology. Its architecture supports both 32-bit SPARC-V8 and 64-bit RISC-V system-on-chips, highlighting its adaptability and cutting-edge design.
The Time-Triggered Protocol (TTP) is an advanced communication protocol designed to enable high-reliability data transmission in embedded systems. It is widely used in mission-critical environments such as aerospace and automotive industries, where it supports deterministic message delivery. By ensuring precise time coordination across various control units, TTP helps enhance system stability and predictability, which are essential for real-time operations. TTP operates on a time-triggered architecture that divides time into fixed-length intervals, known as communication slots. These slots are assigned to specific tasks, enabling precise scheduling of messages and eliminating the possibility of data collision. This deterministic approach is crucial for systems that require high levels of safety and fault tolerance, allowing them to operate effectively under stringent conditions. Moreover, TTP supports fault isolation and recovery mechanisms that significantly improve system reliability. Its ability to detect and manage faults without operator intervention is key in maintaining continuous system operations. Deployment is also simplified by its modular structure, which allows seamless integration into existing networks.
ISELED Technology emerges as a revolutionary solution in automotive lighting, integrating digital control of smart RGB LEDs and addressing automotive gradings. The initiative offers precisely calibrated Smart RGB LEDs, deftly facilitating color calibration at production, providing manufacturers with a streamlined implementation process. Primarily, ISELED excels in reducing complexities associated with the management of color mixing and compensation. Ideal for ambient and functional lighting, ISELED supports daisy-chain configurations of RGB LEDs, enhancing both aesthetic and functional vehicle illumination possibilities. The integrated communication protocol simplifies color adjustments through a straightforward digital interface, moving away from traditional 3-channel current control methods. These advancements promote innovation beyond aesthetics by fostering significant reductions in system cost and complexity. This comes from integrated features such as onboard calibration data storage, which removes dependency on external resources during vehicle manufacturing, making ISELED an optimal choice for next-generation automotive lighting technologies.
Arteris's Ncore Cache Coherent Interconnect IP addresses the complex challenges of multi-core ASIC development, offering a scalable, highly configurable solution for coherent network-on-chip designs. This IP supports multiple protocols, including Arm and RISC-V, and is engineered to comply with ISO 26262 for safety-critical applications. Ncore enables seamless communication and cache coherence across varied processor cores, enhancing performance while meeting stringent functional safety standards. Its capability to automate Fault Modes Effects and Diagnostic Analysis (FMEDA) further simplifies safety compliance, proving its value in advanced SoCs where reliability and high throughput are critical.
ArrayNav is a groundbreaking GNSS solution utilizing patented adaptive antenna technology, crafted to provide automotive Advanced Driver-Assistance Systems (ADAS) with unprecedented precision and capacity. By employing multiple antennas, ArrayNav substantially enhances sensitivity and coverage through increased antenna gain, mitigates multipath fading with antenna diversity, and offers superior interference and jamming rejection capabilities. This advancement leads to greater accuracy in open environments and markedly better functionality within urban settings, often challenging due to signal interference. It is designed to serve both standalone and cloud-dependent use cases, thereby granting broad application flexibility.
Dyumnin Semiconductors' RISCV SoC is a robust solution built around a 64-bit quad-core server-class RISC-V CPU, designed to meet advanced computing demands. This chip is modular, allowing for the inclusion of various subsystems tailored to specific applications. It integrates a sophisticated AI/ML subsystem that features an AI accelerator tightly coupled with a TensorFlow unit, streamlining AI operations and enhancing their efficiency. The SoC supports a multimedia subsystem equipped with IP for HDMI, Display Port, and MIPI, as well as camera and graphic accelerators for comprehensive multimedia processing capabilities. Additionally, the memory subsystem includes interfaces for DDR, MMC, ONFI, NorFlash, and SD/SDIO, ensuring compatibility with a wide range of memory technologies available in the market. This versatility makes it a suitable choice for devices requiring robust data storage and retrieval capabilities. To address automotive and communication needs, the chip's automotive subsystem provides connectivity through CAN, CAN-FD, and SafeSPI IPs, while the communication subsystem supports popular protocols like PCIe, Ethernet, USB, SPI, I2C, and UART. The configurable nature of this SoC allows for the adaptation of its capabilities to meet specific end-user requirements, making it a highly flexible tool for diverse applications.
Digital PreDistortion (DPD) technology is pivotal for enhancing the efficiency of RF power amplifiers. Systems4Silicon's DPD offering, known as FlexDPD, is a comprehensive adaptive linearization subsystem. This solution is vendor-independent, allowing for seamless compilation whether targeting ASICs, FPGAs, or SoC platforms. It is engineered to boost radio transmission efficiency dramatically.\n\nFlexDPD is adaptable to evolving market needs, supporting multi-standard, multi-carrier wireless systems like 5G and O-RAN networks. Its field-proven scalability ensures it can manage transmission bandwidths exceeding 1 GHz, making it apt for various applications with high data throughput demands. The technology has been crafted to align with the growing complexity and performance expectations of modern wireless networks.\n\nThe solution enhances the power efficiency by effectively linearizing amplifiers, thus mitigating distortions and optimizing output. It ensures systems run at optimal power levels, crucial for energy savings and overall operational efficiency within high-frequency communication environments. Systems4Silicon provides extensive support services, ensuring smooth implementation and ongoing optimization for FlexDPD users.
The APIX3 transmitter and receiver modules represent Inova Semiconductors' cutting-edge advancement in automotive multimedia innovation. Highlighting its versatility, APIX3 is developed to meet the rigorous demands of modern infotainment systems and premium cockpit architectures, supporting data rates up to 12 Gbps when utilizing quad twisted pair cabling. This provides high-resolution display connections, ideal for ultra-high-definition video applications within vehicles. Engineered for future scalability, APIX3 modules enable multiple video channels to traverse a singular connection, adhering to cost-effective implementations while maintaining high-performance standards. Compatibility extends to Ethernet technologies, ensuring seamless integration into existing vehicle communication systems and infrastructures, fostering more connected and smarter vehicles. The APIX3 infrastructure also features advanced diagnostic capabilities which foresee potential cable issues, accommodation through active equalizers that automatically adjust to transmission paths, and temperature adaptations. Such features significantly reduce maintenance needs, avoiding unplanned service interruptions, and contributing to safe, reliable data transmission.
ParkerVision's Direct-to-Data (D2D) Technology marks a transformative development in RF communication, significantly enhancing the performance of modern smartphones and wireless devices. This innovative technology replaces the century-old super-heterodyne downconverter with a new RF downconverter that operates efficiently within CMOS architectures. D2D allows RF receivers to connect more seamlessly across global bands while processing high data rates essential for today's media and communication needs. D2D RF receivers built on ParkerVision technology minimize power usage while delivering fast data speeds, substantially contributing to the functionality and efficiency of modern smartphones. These receivers are capable of handling a wide spectrum of data rates from streaming video to large data transfers, thanks to their high-performance design capable of managing a range of signal strengths from various distances with cellular towers. This patented technology plays a crucial role in the smartphone revolution, with its incorporation leading to smarter, faster devices. These developments are enabled by a precise downconversion mechanism that transforms high-frequency RF signals into data-efficient formats. The D2D technology reduces the traditional noise and signal loss, making it a cornerstone in the advancement of mobile and IoT device communication strategies.
The Advanced Flexibilis Ethernet Controller (AFEC) is a high-performance Ethernet controller IP core suitable for integration with programmable hardware and ASICs. Offering triple-speed support for 10/100/1000 Mbps Ethernet, the AFEC is designed to function as a comprehensive Ethernet Network Interface Controller alongside Ethernet Physical layer devices. Significant in reducing CPU load, the AFEC features bus master DMA transfer for both RX and TX data, while accommodating data in various fragments in memory, thanks to its RX and TX scatter-gather capability. These features enable high data throughput and efficient CPU resource management. The AFEC also supports IEEE 1588 Precision Time Protocol, providing essential time synchronization and frame timestamping. Its capability extends to implementing delayed interrupts to minimize CPU load further. Designed for efficient resource usage, AFEC is an essential component for applications necessitating reliable network interface functionality and precise timekeeping, such as industrial automation and telecommunication systems.
The PCD03D Turbo Decoder is adept at handling multiple state decoding for standards such as DVB-RCS and IEEE 802.16 WiMAX. Its core design features an 8-state duobinary decoding structure, facilitating precise and quick signal deconstruction. Additionally, the optional inclusion of a 64-state Viterbi decoder enhances versatility and performance in various environments. This decoder is tailored for applications where agility and high data throughput are critical, making it an invaluable asset in wireless communication infrastructures. The decoder’s architecture supports expansive VHDL core integration, providing durable solutions across FPGA platforms.
LightningBlu is a sophisticated mmWave connectivity solution explicitly designed for high-speed rail environments. This advanced system offers continuous, on-the-move multi-gigabit connectivity between trackside infrastructure and trains, ensuring seamless internet access, entertainment services, and real-time updates for passengers. Operating within the 60 GHz spectrum and compliant with IEEE 802.11 ad and ay standards, LightningBlu provides robust and efficient wireless communication for the rail industry. The LightningBlu system's standout feature is its ability to maintain reliable service even at speeds of over 300 km/h, enhancing the passengers' travel experience with fast and dependable connectivity. Its architecture allows for dynamic interaction between train-mounted and trackside units, facilitating uninterrupted data transfer essential for modern transport needs. This product not only addresses current connectivity requirements but also positions itself as a future-proof solution adaptable to evolving technological landscapes. Adopting a highly functional design, LightningBlu effectively eliminates the dependency on cabled infrastructure, making it an ideal choice for upgrading existing rail systems or deploying in new corridors. By supporting innovative services and enhancing passenger contentment, LightningBlu contributes significantly to modernizing the rail sector, aligning with the increasing push towards digital transformation in mass transit.
Bluespec's Portable RISC-V Cores offer a versatile and adaptable solution for developers seeking cross-platform compatibility with support for FPGAs from Achronix, Xilinx, Lattice, and Microsemi. These cores come with support for operating systems like Linux and FreeRTOS, providing developers with a seamless and open-source toolset for application development. By leveraging Bluespec’s extensive compatibility and open-source frameworks, developers can benefit from efficient, versatile RISC-V application deployment.
The TSN Switch for Automotive Ethernet is an innovative solution designed to meet the stringent requirements of automotive applications. Time-sensitive networking (TSN) ensures that data packets are transmitted within precise time constraints, which is crucial in automotive networks for aligning with other critical system functions. This switch supports automotive Ethernet standards, allowing seamless integration into existing network architectures. It's engineered to handle low-latency and high-reliability data transmission, ensuring safe and efficient communication across vehicle systems.
The Tyr AI Processor Family is designed around versatile programmability and high performance for AI and general-purpose processing. It consists of variants such as Tyr4, Tyr2, and Tyr1, each offering a unique performance profile optimized for different operational scales. These processors are fully programmable and support high-level programming throughout, ensuring they meet diverse computing needs with precision. Each member of the Tyr family features distinct core configurations, tailored for specific throughput and performance needs. The top-tier Tyr4 boasts 8 cores with a peak capability of 1600 Tflops when leveraging fp8 tensor cores, making it suitable for demanding AI tasks. Tyr2 and Tyr1 scale down these resources to 4 and 2 cores, respectively, achieving proportional efficiency and power savings. All models incorporate substantial on-chip memory, optimizing data handling and execution efficiency without compromising on power use. Moreover, the Tyr processors adapt AI processes automatically on a layer-by-layer basis to enhance implementation efficiency. This adaptability, combined with their near-theory performance levels, renders them ideal for high-throughput AI workloads that require flexible execution and dependable scalability.
The INAP590T is tailored for APIX3 technology, augmenting vehicular infotainment with high-speed data communication capabilities. Possessing robust support for HDMI video interfaces and diverse audio channels, this transmitter deftly manages bandwidth needs of contemporary cockpit systems, broadcasting data over shielded twisted-pair cables ensuring stability and efficiency. Addressing the requirements of modern automotive multimedia applications, the INAP590T underpins duplex communication channels while supporting industry-standard Ethernet connectivity. This synergy caters to advanced cockpit systems where multiple UHD screens coexist, demanding unhindered signal accuracy amid stringent automotive environments. With its scalable bandwidth support, this transmitter aligns with next-generation vehicle setups, maintaining backward compatibility with prior APIX2 platforms. Connections via HDMI, supplemented by sophisticated on-chip diagnostics, reinforce its application in robust vehicular communications, positioning it as a premier choice for facilitating dynamic in-car audio-visual experiences.
The SinglePHY solution from Siliconally is designed specifically for robust and secure communication in automotive Ethernet applications. Operating at a bandwidth of 100 MBit/s, it provides ample capacity for a host of applications while maintaining a compact chip footprint and exceptionally low power usage. Its integration capabilities extend beyond standard operations, ensuring seamless data streaming, diagnostics, and error flagging, which are essential in safety-critical environments.
aiSim 5 is a premier simulation tool tailored for ADAS (Advanced Driver Assistance Systems) and automated driving validations. As the world's first ISO26262 ASIL-D certified simulator, aiSim 5 employs state-of-the-art AI-based digital twin technology. This enhances its capability to simulate complex driving scenarios with high precision, making it an ideal environment for testing AD systems. The simulator boasts a proprietary rendering engine that provides a deterministic and high-fidelity virtual reality where sensor simulations can cover diverse climatic and operational conditions, such as snow, rain, and fog, ensuring results are reproducible and reliable.\n\naiSim 5's architecture is designed for flexibility, allowing seamless integration with existing development toolchains, and thus minimizing the need for expensive real-world testing. It features a comprehensive 3D asset library that includes detailed environments, vehicles, and scenarios, which can be customized to generate synthetic data for testing. The solution supports multi-sensor simulations, providing a rich testing ground for developers looking to refine and validate their software stacks.\n\nThanks to its modular C++ and Python APIs, aiSim 5 can be easily deployed within any System under Test (SuT) and CI/CD pipeline, enhancing its adaptability across various automotive applications. Additionally, its open SDK facilitates developer customizations, ensuring aiSim 5 remains adaptable and user-friendly. With built-in scenario randomization, users can efficiently simulate a wide array of driving conditions, making aiSim 5 a powerful tool for ensuring automotive system safety and accuracy.
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.
The Flexibilis Redundant Switch (FRS) is a robust Ethernet Layer-2 switch IP core supporting High-availability Seamless Redundancy (HSR) and Parallel Redundancy Protocol (PRP). Designed for seamless redundancy in Ethernet networks, FRS integrates IEEE 1588v2 Precision Time Protocol (PTP) capabilities, making it ideal for applications requiring both network reliability and precise time synchronization. FRS is adaptable to various network configurations, offering features like triple-speed operation, from 10 Mbps to 1 Gbps, across all ports. This makes FRS applicable in settings ranging from gigabit to slower 100 Mbps rings, thus catering to diverse industrial and utility applications. The FRS IP core eliminates the need for separate RedBoxes, allowing devices to connect directly, which enhances cost-effectiveness and deployment efficiency. Furthermore, FRS supports both cut-through and store-and-forward operations, enhancing its flexibility in managing network traffic. By providing prioritization and packet filtering, FRS ensures optimal performance even in congested networks. Its compatibility with different Ethernet interface types, including both copper and fiber options, makes it a versatile solution for high-reliability networking requirements.
GateMate FPGA is a highly versatile and cost-effective Field-Programmable Gate Array designed to cater to a wide array of applications, from telecommunications to industrial purposes. Utilized in applications where flexibility and adaptability are critical, the GateMate FPGA shines with its reprogrammable architecture. Engineers appreciate the ability to tailor the device post-manufacturing to suit specific needs, providing an edge in scenarios demanding rapid technological adaptability. The GateMate FPGAs are noted for their power efficiency and broad multi-node portfolio, accommodating both low- and mid-range applications. This FPGA stands out for its impressive balance of price, performance, and reliability. Manufactured using the GlobalFoundries 28nm node process, it ensures durability and a consistent supply chain. Industries leveraging the GateMate FPGAs benefit from its robust performance in areas such as signal processing, data transmission, and complex algorithm acceleration. It plays a crucial role in enabling real-time data flows and tasks that demand parallel processing, especially evident in sectors like automotive and aerospace where the ability to evolve rapidly with industry needs is indispensable.
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.
Designed to form part of an advanced digital serial link, the INAP375R receiver is built to complement the INAP375T transmitter for display and camera applications in automotive environments. Operating at a bandwidth of up to 3 Gbps, the device ensures data preservation over shielded twisted pair (STP) cables. The receiver supports dual independent video outputs, featuring interfaces like parallel RGB and LVDS for versatile display configurations. Its robustness in handling different video formats makes it adaptable for complex automotive entertainment and information systems. Incorporated AShell protocol functionality provides error correction and data re-transmission, enhancing the reliability of video data streams. For comprehensive system integration, the INAP375R also includes a Media Independent Interface (MII) offering direct connectivity to Ethernet networks, which simplifies network setups and expands system capabilities. Its audio path allows precise synchronization of multiple stereo channels, catering to high-end entertainment applications seen in rear-seat setups. The receiver is also highly compatible with diverse automotive display standards, supporting rich and vibrant visual outputs.
The ADNESC ARINC 664 End System Controller is engineered for high-performance avionic networks, providing robust, reliable interfaces essential for next-gen avionic data systems. It is fully compliant with RTCA DO-254 DAL A standards, ensuring utmost reliability and safety in critical flight operations. Using generic VHDL code, the controller is target device independent, offering flexibility across various hardware deployments. This solution supports high-speed multi-host interfaces with data rates up to 400 Mbit/s, underscoring its ability to manage intense data flows in complex network scenarios. Embedded SRAM adds to its efficiency, enabling swift data storage and retrieval in demanding environments. The ADNESC is optimized to serve intricate avionic systems requiring meticulous data management and communication continuity. An ideal fit for aerospace applications, the controller's development processes ensure adherence to stringent regulatory standards, making it suitable for diverse avionic operational contexts. It enables networking solutions that are both cost-effective and future-proof, safeguarding investments through enduring compatibility and performance.
The ACAM is a 60 GHz millimeter-wave smart sensor that provides comprehensive in-cabin monitoring for vehicles, focusing on safety and comfort. This sensor leverages advanced NOVELIC perception software to ensure high accuracy in detecting the presence of living beings, recognizing seat occupancy, and monitoring vital signs such as respiratory rates. The sensor operates effectively without requiring a direct line of sight, preserving passenger privacy and functioning seamlessly under various lighting conditions. As regulations evolve, systems like child presence detection in vehicles are increasingly becoming standard, and the ACAM is designed to meet and exceed such standards by offering comprehensive coverage for in-cabin safety.
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 SafeIP DualPHY from Siliconally supports dual ethernet modes, offering both 100 and 1000 MBit/s data transfer rates. This dual capability is essential for systems requiring versatile and resilient communication frameworks. Built with a foundation in safety and reliability, the DualPHY is equipped with advanced auto-negotiation abilities and diagnostics capabilities, making it a preferred choice for systems entrenched in dynamic and critical environments.
The SMPTE 2059-2 Synchronization Solution encompasses all needed logic implementation on an FPGA to generate precise audio and video alignment signals using a reference PTP time source and associated clock. This solution targets professional broadcast markets, offering high accuracy and low latency AV content alignment. The robust FPGA timestamping combined with software-driven algorithms ensures an efficient, compact product that's both easy to deploy and integrate. It comes with a management and configuration interface that provides ultimate flexibility. With an IEEE1588 compliant PTP time source, it generates alignment pulses for specified frame rates along with a timecode. The included API allows for easy configuration of both the IP core and software. The module's strong compliance with IEEE1588v2 enhances its adaptability to existing systems, making it a reliable synchronization solution for professional broadcasters. Korusys has developed this synchronization product suite capitalizing on their extensive expertise in PTP synchronization, ensuring it meets the highest standards of precision required in the broadcast industry. When coupled with its user-friendly management interface and API, this makes the SMPTE 2059-2 Solution a valuable addition to any broadcast synchronization setup.
ZORM is an industrial-grade radar sensor primarily designed for challenging environments that require high reliability. It is equipped with both hardware and software components for stand-alone operation and offers essential data for smart access and safety systems. This radar solution excels in scenarios demanding high-performance sensing, like robotics and industrial safety zones, by accurately detecting human presence and potential hazards, enhancing productivity and safety compliance.
The CANmodule-IIx is a compact and efficient CAN controller ideal for integration in FPGA and ASIC designs, supporting full CAN capabilities with enhanced message handling features. It includes a robust filtering system and a FIFO-based structure for both receiving and transmitting messages, which helps in managing data flow efficiently. Tailored for applications that require a low gate-count CAN interface, this module offers full compliance with the CAN 2.0A/B standard and ISO 11898-1 compatibility, making it suitable for automotive and industrial use. Its ability to interface seamlessly with ARM-based SoC architectures through an AMBA APB interface allows it to be integrated into broader system designs without compatibility issues. Equipped with both receive and transmit FIFOs, the CANmodule-IIx ensures streamlined communication by supporting high-priority message processing, which is critical for systems that operate under tight timing requirements. Additional features include multiple clock domain support and extensive interrupt capabilities for easier error management and debugging.
This product focuses on wireless energy transfer that does not rely on traditional radiative methods, allowing power to be distributed efficiently without physical connections. It utilizes high-quality resonators, harnessing magnetic coupling to transmit energy over various distances and environments. The goal is to maximize power delivery while minimizing radiated emissions, ensuring compatibility and safety in numerous applications. This method is pivotal for sectors like automotive, where reducing the dependency on physical cables is crucial for the proliferation of electric vehicles.
This system focuses on ensuring optimal alignment and compatibility between power transmitters and receivers in wireless charging setups. The technology is designed to detect misalignments and make necessary adjustments to maintain an efficient energy transfer process. By using advanced sensing and alignment methodologies, this system diminishes power losses and enhances the reliability of energy transfer chains. Such systems are critical in automotive applications, where alignment can significantly impact the efficiency and safety of vehicle charging processes.
Time-Sensitive Networking (TSN) is an integral part of industrial Ethernet, providing real-time streaming capabilities to support innovative digital automation systems. Emerging from IEEE standards, TSN components work seamlessly to ensure timely packet delivery in dynamic and harsh industrial environments. TSN distinguishes itself by enabling precise synchronization of devices within a network, facilitating coordinated actions across distributed systems. Through prioritization and scheduling, TSN maintains high-quality streams over Ethernet, making it amenable for applications that include autonomous machines and complex robotics. By investing in TSN's capabilities, industries can merge traditional and real-time networking requirements into a single seamless solution. This reduces infrastructure costs and streamlines maintenance while ensuring high performance and predictability across industrial systems
The FireCore PHY & Link Layer Solutions encompass a range of synthesizable IP cores targeted at the IEEE-1394b-2008 and AS5643 standards. These solutions combine link and physical layers into a cohesive package aimed at ensuring seamless data transmission and high-speed communication across avionics networks. Featuring capabilities for bit error injection and comprehensive bit error rate testing, the FireCore solutions facilitate precise system diagnostics and maintenance. They are designed to support S100 to S3200 data transfer speeds, addressing industry demands for rapid and reliable data throughput. This adaptability makes them a suitable choice for diverse aerospace applications requiring robust data handling capabilities. Incorporating advanced patented technologies, FireCore solutions improve bus management through features such as expanded hardware filtering and enhanced isochronous data streaming. These tools are indispensable in supporting reliable and efficient data processing in contemporary avionics systems, contributing significantly to the stability and performance of aerospace communication networks.
PhantomBlu represents Blu Wireless's advanced mmWave solution tailored for military and defense applications. It is engineered to deliver secure, high-performance tactical communications in diverse and challenging environments. The system's low-SWAP (size, weight, and power) design is versatile, featuring configurations capable of acting as both PCP (hub) and STA (client), thereby ensuring reliable communication in dynamic and fast-moving scenarios. PhantomBlu operates without the need for traditional fiber optics or wired networks, leveraging available mmWave spectrum to facilitate seamless interoperability across legacy and new defense systems. This flexibility makes it an essential asset in modern warfare, providing data-rich, mission-critical connectivity that adapts swiftly to operational requirements. PhantomBlu's design supports stealthy, gigabit-speed communications crucial for mission efficacy and situational awareness. Emphasizing ease of integration and deployment, PhantomBlu contributes to transforming tactical communication landscapes by improving throughput and reducing latency. Its robust architecture ensures optimal performance even under demanding conditions, catering to the defense sector's growing reliance on rapid data exchange and real-time information sharing.
The CANsec Controller Core is developed for secure communication in automotive networks. Building on the Controller Area Network (CAN) protocol, this core introduces enhancements for data security, ensuring that messages transmitted across the network are resistant to tampering and unauthorized interception. With the growing complexity and interconnectedness of vehicle systems, the CANsec architecture provides robust protection against emerging cybersecurity threats, making it an essential component for modern automotive designs.
Deterministic Ethernet enhances traditional Ethernet with capabilities required for deterministic and time-critical networking. Used within industries where timing precision is imperative, such as in aeronautics and automotive systems, it enables the network to handle high-bandwidth, time-sensitive data traffic effectively. The technology achieves determinism by integrating time-triggered protocols alongside Ethernet standards. These enhancements allow user-configurable schedules, ensuring not only that data is transported predictably, but also avoiding congestion within the network. Such performance is vital where consistent data transfer rates and minimal latency are non-negotiable. Deterministic Ethernet provides a scalable solution, easily integrating into various system architectures and maintaining flexibility to adapt to evolving network demands while ensuring high reliability. These attributes present it as an indispensable tool for next-generation network infrastructures seeking to balance traditional Ethernet advantages with future-forward, time-determined communication capabilities.
The Korusync IEEE1588 PCIe Card delivers telecom-grade synchronization to a range of sectors including high-frequency trading, telecom, and industrial markets. It integrates seamlessly with PC and server infrastructures, using the IEEE1588-2008 protocol for precise time distribution. This card, adorned with high precision timing recovery algorithms and an onboard oven-controlled oscillator, ensures time synchronization with remarkable accuracy - better than 100ns. Software tools provided enhance the card's utility, offering applications for clock management and event timestamping. Engineered for integration, the PCIe card facilitates nanosecond-accurate timing for applications within connected systems. It supports telecom-specific profiles to boost its synchronization capabilities and can deliver ultra-precise time information directly into server applications, ensuring high-performance operation across diverse high-demand sectors.
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