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 provides comprehensive Automotive IP solutions tailored for automotive applications, ensuring high value and silicon-proven reliability. This line includes controllers for In-Vehicle Networks (IVN) such as FlexCAN with CAN-FD, high-speed FlexRay, and LIN standards. These elements are integral for the development of modern automotive systems with robust flexibility and performance.<br><br>In addition, Silvaco offers significant advancements in SoC subsystems, embodying critical cores, subsystems, and necessary peripherals to enhance SoC designs for automotive applications. These systems integrate SPI, UART, and DMA Controllers, creating streamlined pathways for data and control within automotive electronics.<br><br>Furthermore, Silvaco supports seamless integration of I3C systems, providing Advanced and Autonomous controller features for diverse automotive needs. Through comprehensive support and customization capabilities, Silvaco's IP solutions stand out in delivering reliability and efficiency required for next-generation automotive electronics.
The CT25205 is a comprehensive digital core designed for IEEE 802.3cg® 10BASE-T1S Ethernet applications, incorporating the Physical Medium Attachment (PMA), Physical Coding Sublayer (PCS), and Physical Layer Coordination (PLCA) Reconciliation Sublayers. Written in Verilog 2005 HDL, this IP core is versatile enough to be implemented in standard cells and FPGA systems. It interfaces seamlessly with IEEE Ethernet MACs through a Media Independent Interface (MII), and the PLCA RS supports legacy MACs, enhancing functionality without additional extensions. The PMA is compatible with OPEN Alliance 10BASE-T1S PMD, perfect for Zonal Gateways and MCUs in advanced network architectures.
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.
Designed for 10BASE-T1S applications, the CT25203 serves as an essential analog front-end component of Ethernet transceivers. This IP component helps connect host controllers and switches by implementing a 3-pin interface compliant with the OA TC14 specification. It ensures high EMC performance thanks to its compact 8-pin design and manufacturing on high-voltage process technology. Particularly suited for automotive and industrial use, this IP core demonstrates versatility, offering robust communication with minimal footprint.
The NaviSoC is a cutting-edge system-on-chip (SoC) that integrates a GNSS receiver and an application processor on one silicon die. Known for its high precision and reliability, it provides users with a compact and energy-efficient solution for various applications. Capable of supporting all GNSS bands and constellations, it offers fast time-to-first-fix, centimeter-level accuracy, and maintains high sensitivity even in challenging environments. The NaviSoC's flexible design allows it to be customized to meet specific user requirements, making it suitable for a wide range of applications, from location-based services to asset tracking and smart agriculture. The incorporation of a RISC-V application microcontroller, along with an array of peripherals and interfaces, introduces expanded functionality, optimizing it for advanced IoT and industrial applications. Engineered for power efficiency, the NaviSoC supports a range of supply voltages, ensuring low power consumption across its operations. The chip's design provides for efficient integration into existing systems with the support of a comprehensive SDK and IDE, allowing developers to tailor solutions to their precise needs in embedded systems and navigation infrastructures.
The 8b/10 Decoder from Roa Logic is a comprehensive implementation of the well-known 8b10b line coding scheme, utilized for achieving DC-balance and bounded disparity during serial data transmission. This system is essential for maintaining synchronization between data and clock signals, thus utilized in high-speed data transmission protocols to enable reliable data recovery. This decoder efficiently translates 10-bit encoded symbols into 8-bit data while continuously monitoring for bit errors. It adeptly recognizes and processes special comma characters, with intrinsic functionality for identifying K28.5 symbols widely used across many data communication standards. The architecture of the 8b/10 Decoder allows for cascading to support 16b20b decoding, expanding its utility in complex serial communication systems. Its design is fully synthesizable, making it versatile across different technology platforms. Roa Logic supports developers with easily accessible documentation and source materials available on GitHub, fostering straightforward adoption and integration into modern data transmission systems.
Time-Triggered Ethernet (TTEthernet) represents a significant advancement in network technology by integrating time-triggered communication over standard Ethernet infrastructures. This technology is designed to meet the stringent real-time requirements of aerospace and industrial applications, offering deterministic data transfer alongside regular Ethernet traffic within a shared network. TTEthernet delivers seamless synchronization across all network devices, ensuring that time-critical data packets are processed with precise timing. This capability is essential for applications where simultaneous actions from multiple systems require tight coordination, such as flight control systems or automated industrial processes. The protocol's compatibility with existing Ethernet environments allows for easy integration into current systems, reducing costs associated with network infrastructure upgrades. TTEthernet also enhances network reliability through redundant data paths and failover mechanisms, which guarantee continuous operation even in the event of link failures. As a result, TTEthernet provides a future-proof solution for managing both regular and mission-critical data streams within a single unified network environment. Its capacity to support various operational modes makes it an attractive choice for industries pursuing high standards of safety and efficiency.
The EW6181 is a cutting-edge multi-GNSS silicon solution offering the lowest power consumption and high sensitivity for exemplary accuracy across a myriad of navigation applications. This GNSS chip is adept at processing signals from numerous satellite systems including GPS L1, Glonass, BeiDou, Galileo, and several augmentation systems like SBAS. The integrated chip comprises an RF frontend, a digital baseband processor, and an ARM microcontroller dedicated to operating the firmware, allowing for flexible integration across devices needing efficient power usage. Designed with a built-in DC-DC converter and LDOs, the EW6181 silicon streamlines its bill of materials, making it perfect for battery-powered devices, providing extended operational life without compromising on performance. By incorporating patent-protected algorithms, the EW6181 achieves a remarkably compact footprint while delivering superior performance characteristics. Especially suited for dynamic applications such as action cameras and wearables, its antenna diversity capabilities ensure exceptional connectivity and positioning fidelity. Moreover, by enabling cloud functionality, the EW6181 pushes boundaries in power efficiency and accuracy, catering to connected environments where greater precision is paramount.
The CANmodule-IIIx by Inicore is an enhanced CAN controller with a design that caters to sophisticated system-on-chip requirements. It features 32 receive and 32 transmit mailboxes, offering substantial flexibility and control over CAN network traffic. This module is ideal for applications necessitating high throughput and advanced message handling. Its compliance with full CAN2.0B standards ensures wide applicability across various sectors, making it an integral part of communication systems in automotive and industrial fields. The CANmodule-IIIx delivers an excellent balance of performance and functionality.
ASPER is an advanced 79 GHz mmWave radar offering expansive 180-degree field coverage, designed to excel in park assist solutions. This radar module replaces traditional ultrasonic systems with improved accuracy, capable of extended detection ranges from 5 cm to 100 meters. Its adaptability across various vehicle classes makes it ideal for applications in automotive, transportation, and industrial environments, delivering unparalleled performance even in adverse conditions.
The Tyr Superchip is engineered to tackle the most daunting computational challenges in edge AI, autonomous driving, and decentralized AIoT applications. It merges AI and DSP functionalities into a single, unified processing unit capable of real-time data management and processing. This all-encompassing chip solution handles vast amounts of sensor data necessary for complete autonomous driving and supports rapid AI computing at the edge. One of the key challenges it addresses is providing massive compute power combined with low-latency outputs, achieving what traditional architectures cannot in terms of energy efficiency and speed. Tyr chips are surrounded by robust safety protocols, being ISO26262 and ASIL-D ready, making them ideally suited for the critical standards required in automotive systems. Designed with high programmability, the Tyr Superchip accommodates the fast-evolving needs of AI algorithms and supports modern software-defined vehicles. Its low power consumption, under 50W for higher-end tasks, paired with a small silicon footprint, ensures it meets eco-friendly demands while staying cost-effective. VSORA’s Superchip is a testament to their innovative prowess, promising unmatched efficiency in processing real-time data streams. By providing both power and processing agility, it effectively supports the future of mobility and AI-driven automation, reinforcing VSORA’s position as a forward-thinking leader in semiconductor technology.
Inicore’s CANmodule-III is a mailbox-based CAN controller offering robust performance for system-on-chip solutions. Designed with advanced features to manage communication effectively, this controller supports a comprehensive range of CAN applications. With its scalability and ease of integration, it remains a preferred choice for industries requiring reliable CAN solutions. The CANmodule-III’s design simplicity ensures that it is a dependable component in complex electronic systems, meeting various compliance standards and providing an exceptional communication protocol foundation.
ISELED Technology introduces a revolutionary approach to automotive interior lighting with smart digital RGB LEDs. These LEDs facilitate dynamic lighting solutions by embedding a sophisticated driver directly with the LED, enabling unique features such as pre-calibration and independent temperature compensation. This innovation allows for significant simplification of the overall lighting system architecture as the intricate calibration tasks are handled at the LED module level. The ISELED system supports an expansive 4K address space, offering seamless integration into daisy-chained configurations and precise color control through a straightforward digital command interface. This approach not only enhances visual quality but also reduces the complexity typically associated with RGB LED configurations, eliminating the need for separate power management or additional calibration setups. ISELED’s robust design is particularly beneficial in automotive environments, where durability and dependability are crucial. The technology also extends to ILaS systems, providing interconnected networks of LEDs and sensors that are both energy-efficient and capable of rapid diagnostics and reconfiguration. In essence, ISELED technology allows automotive designers unprecedented flexibility and control over vehicle interior lighting designs.
APIX3 represents the latest evolution in high-speed data transmission modules, engineered specifically for automotive infotainment and cockpit architectures. Designed to interface seamlessly within vehicle IT landscapes, it supports transmissions up to 12 Gbps using shielded or quad twisted pair cables. APIX3 offers unique capabilities like multiple video stream handling on a single connection and supports advanced diagnostics, including cable health checks for predictive maintenance. This technology is backward compatible with APIX2, enhancing modular flexibility across previous and new vehicle designs. With support for UHD automotive display resolutions, APIX3 ensures all-in-one connectivity solutions for complex exterior and interior automotive systems. The APIX3 modules enable comprehensive networking through various serial interface protocols and are positioned as go-to solutions for future-proofing in-car data systems. Each channel within APIX3 is fine-tuned for specific needs, from video data handling to full-duplex telecommunications. Additionally, APIX3 supports Ethernet connectivity for seamless integration into the larger automotive communication network. Thanks to its efficient design, APIX3 provides stability and enhanced bandwidth support, delivering robust performance suited for both entry-level and high-end automotive systems.
The Advanced Flexibilis Ethernet Controller (AFEC) is a versatile triple-speed Ethernet controller IP block ideal for programmable hardware and ASIC applications. AFEC, in conjunction with Ethernet PHY devices, delivers comprehensive Ethernet Network Interface Controller functionality. It features an MII/GMII interface for seamless Ethernet PHY device connection, supporting gigabit transfer rates. AFEC's design reduces CPU workload by employing DMA transfers and scatter-gather techniques for efficient data management, while providing timestamping capabilities with IEEE 1588 support. Standard AFEC components include triple-speed operation, direct SFP module integration, and CRC error handling, making it ideal for diverse networking applications.
The PCD03D Turbo Decoder is adept at handling multiple state decoding for standards such as DVB-RCS and IEEE 802.16 WiMAX. Its core design features an 8-state duobinary decoding structure, facilitating precise and quick signal deconstruction. Additionally, the optional inclusion of a 64-state Viterbi decoder enhances versatility and performance in various environments. This decoder is tailored for applications where agility and high data throughput are critical, making it an invaluable asset in wireless communication infrastructures. The decoder’s architecture supports expansive VHDL core integration, providing durable solutions across FPGA platforms.
The Digital PreDistortion (DPD) Solution by Systems4Silicon is a cutting-edge technology developed to maximize the power efficiency of RF power amplifiers. Known as FlexDPD, this solution is vendor-independent, allowing it to be compiled across various FPGA or ASIC platforms. It's designed to be scalable, optimizing resources according to bandwidth, performance, and multiple antennae requirements. One of the key benefits of FlexDPD is its substantial efficiency improvements, reaching over 50% when used with modern GaN devices in Doherty configurations, surpassing distortion improvements of 45 dB. FlexDPD is versatile, operating with communication standards including multi-carrier, multi-standard, and various generations from 2G to 5G. It supports both time division and frequency division duplexing, and can accommodate wide Tx bandwidths, limited only by equipment capabilities. The technology is also agnostic to amplifier topology and transistor technology, providing broad applicability across different setups, whether class A/B or Doherty, and different transistor types like LDMOS, GaAs, or GaN. This technology integrates seamlessly with Crest Factor Reduction (CFR) and envelope tracking techniques, ensuring a low footprint on resources while maximizing efficiency. With complementary integration and performance analysis tools, Systems4Silicon provides comprehensive support and documentation, ensuring that clients can maximize the benefits of their DPD solution.
aiData introduces a fully automated data pipeline designed to streamline the workflow of automotive Machine Learning Operations (MLOps) for ADAS and autonomous driving development. Recognizing the enormous task of processing millions of kilometers of driving data, aiData employs automation from data collection to curation, annotation, and validation, enhancing the efficiency of data scientists and engineers. This crafted pipeline not only facilitates faster prototyping but also ensures higher quality in deploying machine learning models for autonomous applications. Key components of aiData include the aiData Versioning System, which provides comprehensive transparency and traceability over the data handling process, from recording to training dataset creation. This system efficiently manages metadata, which is integral for diverse use-cases, through advanced scene and context-based querying. In conjunction with the aiData Recorder, aiData automates data collection with precise sensor calibration and synchronization, significantly improving the quality of data for testing and validation. The aiData Auto Annotator further enhances operational efficiency by handling the traditionally labor-intensive process of data annotation using sophisticated AI algorithms. This process extends to multi-sensor data, offering high precision in dynamic and static object detection. Moreover, aiData Metrics tool evaluates neural network performance against baseline requirements, instantly detecting data gaps to optimize future data collection strategies. This makes aiData an essential tool for companies looking to enhance AI-driven driving solutions with robust, real-world data.
ArrayNav represents a significant leap forward in navigation technology through the implementation of multiple antennas which greatly enhances GNSS performance. With its capability to recognize and eliminate multipath signals or those intended for jamming or spoofing, ArrayNav ensures a high degree of accuracy and reliability in diverse environments. Utilizing four antennas along with specialized firmware, ArrayNav can place null signals in the direction of unwanted interference, thus preserving the integrity of GNSS operations. This setup not only delivers a commendable 6-18dB gain in sensitivity but also ensures sub-meter accuracy and faster acquisition times when acquiring satellite data. ArrayNav is ideal for urban canyons and complex terrains where signal integrity is often compromised by reflections and multipath. As a patented solution from EtherWhere, it efficiently remedies poor GNSS performance issues associated with interference, making it an invaluable asset in high-reliability navigation systems. Moreover, the system provides substantial improvements in sensitivity, allowing for robust navigation not just in clear open skies but also in challenging urban landscapes. Through this additive capability, ArrayNav promotes enhanced vehicular ADAS applications, boosting overall system performance and achieving higher safety standards.
The eSi-ADAS IP suite is tailored to enhance radar processing for Advanced Driver Assistance Systems (ADAS). It includes a powerful radar co-processor engine that boosts the performance of radar systems used in automotive, drone, and UAV applications. The IP has gained adoption by prominent automotive suppliers and finds use in production vehicles, illustrating its reliability and effectiveness in real-world conditions. Key functionalities of eSi-ADAS encapsulate a wide range of radar hardware accelerators which enhance radar's performance capabilities, ensuring precise situational awareness.
ParkerVision's D2D® Technology revolutionizes RF communication by enabling direct conversion from RF signals to digital data, bypassing traditional intermediate frequency stages. This technology is instrumental in streamlining signal processing, enhancing speed and efficiency of data handling in various wireless communication devices. The D2D technology supports a broad spectrum of applications, including mobile phones, wireless internet, and IoT devices, delivering high performance and adaptability for current and forthcoming technological needs. D2D® shines in its ability to sustain high data rates necessary for modern applications like 4G and 5G networks, bolstering the capabilities of RF integrated circuits with its advanced conversion techniques. Furthermore, this technology is central to facilitating seamless integration across different communication standards, allowing devices to operate over multiple frequency bands without compromising on data quality or speed. The intellectual property surrounding D2D® is robustly protected with a comprehensive patent portfolio, ensuring its exclusivity and opening avenues for strategic partnerships and licensing. By harnessing this technology, devices gain enhanced power efficiency and broader operational capabilities while lowering manufacturing costs and conserving energy, making it a pivotal innovation for evolving communication landscapes.
The Network Protocol Accelerator Platform (NPAP) is a high-performance solution that accelerates TCP/UDP/IP protocols within FPGA- and ASIC-based systems. Developed alongside the Fraunhofer Heinrich-Hertz-Institute, this platform offers customizable high-bandwidth and low-latency communication capabilities essential for Ethernet links ranging from 1G to 100G. It's designed for various hardware applications, providing turnkey solutions and integrates synthesizable HDL codes capable of being implemented directly into FPGAs. At its core, NPAP enhances CPU performance by handling TCP/UDP/IP processing within programmable logic, thereby boosting network throughput while minimizing latency. The platform's modular architecture supports full line-rate processing up to 70 Gbps in FPGAs and over 100 Gbps in ASICs. It features bi-directional data paths supporting multiple, parallel TCP engines designed for scalable network processing. Its utility extends to FPGA-based SmartNICs, networked storage such as iSCSI, and even high-speed video transmissions. The NPAP can be evaluated via a Remote Evaluation System, allowing potential users to conduct a hands-on assessment through a remote connection to MLE's lab, providing flexibility and saving integration time.
The Time-Triggered Protocol (TTP) is a robust communication protocol designed for safety-critical applications. It provides deterministic exchange of messages between nodes in a network at pre-determined time intervals, ensuring system reliability and predictability. This makes TTP suited for environments like aerospace and automotive systems, where timing precision and fault tolerance are crucial. TTP's core feature is its ability to prioritize and synchronize communication across multiple nodes, effectively handling both normal operation and recovery from potential faults. By achieving strict temporal coordination, TTP enhances network efficiency and reduces the likelihood of message collision, contributing to overall system safety and robustness. Additionally, TTP supports modular extension, allowing designers to add functionalities without major architectural changes. This adaptability makes it an ideal choice for evolving systems that require long-term reliability and scalability. Furthermore, TTP's lightweight implementation aids in maintaining low system complexity, thereby optimizing resource utilization under various operational scenarios.
The INAP590T is a cutting-edge digital multi-channel SerDes transmitter specifically crafted for high-speed infotainment applications. Found in the APIX3 suite, this component is built to ensure seamless interactions between HDMI interfaces and APIX2 technology, featuring HDCP support for secure content transmission. This transmitter facilitates a DC-balanced, low latency point-to-point link, perfect for applications requiring robust data transmission like immersive in-car entertainment systems. Capable of handling dual high-definition content streams and supporting resolutions up to 1920x1080 at 30Hz, the INAP590T is ideal for modern display technologies within vehicles. It includes multiple interface options and supports comprehensive full-duplex communication channels, allowing for flexible system design and integration. Furthermore, the robust diagnostic features ensure optimal operation and readily identify potential issues for proactive maintenance. Designed for scalability and forward compatibility, the INAP590T supports extensive bandwidth requirements and is packaged for installation convenience. The integration of Ethernet interfaces, along with GPIO configurations, enables versatile connectivity options to meet diverse automotive needs, ensuring broad applicability across current and next-generation vehicles.
The Ncore Cache Coherent Interconnect by Arteris addresses the multifaceted challenges of multi-core ASIC design, offering a production-ready, highly configurable coherent NoC interconnect solution. Ncore is tailored for high-performance applications, supporting a variety of protocols compatible with Arm and RISC-V processors while enhancing inter-core communication and synchronization. Ncore is designed with functional safety in mind, making it suitable for ISO 26262 certification, a crucial factor for safety-critical applications such as automotive systems. It ensures credible operation in these environments with built-in safety and reliability features, including FMEDA data and ASIL certification. The IP supports multi-protocol coherency with CHI-B, CHI-E, and ACE alongside I/O coherent agent interfaces, providing versatility and backward compatibility for diverse SoC architectures. Enhanced with unique proxy caches, Ncore lowers power requirements while maintaining high performance, offering a scalable, power-efficient interconnect fabric suitable for a wide array of system scales, from small embedded solutions to extensive multi-billion transistor designs.
The Nerve IIoT Platform by TTTech Industrial Automation is a sophisticated edge computing solution that bridges the gap between industrial environments and digital business models. Designed for machine builders, it supports real-time data exchange, offering a robust infrastructure that connects physical machines directly with IT systems. The platform optimizes machine performance by allowing for remote management and software deployment. Nerve's architecture is highly modular, making it adaptable to specific industrial needs. It features cloud-managed services that enable seamless application deployments across multiple devices, straight from the cloud or on-premises infrastructure. By supporting various hardware, from simple gateways to industrial PCs, the platform is scalable and capable of growing with business demands. Security is a pivotal aspect of Nerve, offering both IEC 62443 certification for safe deployment and regular penetration tests to ensure integrity and protection. Its integration capabilities with protocols like OPC UA, MQTT, and others allow for enhanced data collection and real-time analytics, promoting efficiency and reducing operational costs through predictive maintenance and system optimization.
Dyumnin's RISCV SoC is built around a robust 64-bit quad-core server class RISC-V CPU, offering various subsystems that cater to AI/ML, automotive, multimedia, memory, and cryptographic needs. This SoC is notable for its AI accelerator, including a custom CPU and tensor flow unit designed to expedite AI tasks. Furthermore, the communication subsystem supports a wide array of protocols like PCIe, Ethernet, and USB, ensuring versatile connectivity. As for the automotive sector, it includes CAN and SafeSPI IPs, reinforcing its utility in diverse applications such as automotive systems.
The WiseEye2 AI solution by Himax represents a significant leap forward in AI-enhanced sensing for smart devices. Designed for low-power operation, this solution integrates a specialized CMOS image sensor with the HX6538 microcontroller to deliver high-performance AI capabilities with minimal energy consumption. This makes it ideal for battery-powered devices that require continual operation, facilitating a new generation of always-on AI solutions without the typical drain on battery life. Thanks to its ARM-based Cortex M55 CPU and Ethos U55 NPU, WiseEye2 offers robust processing while maintaining a compact profile. Its multi-layer power management architecture not only maximizes energy efficiency but also supports the latest advancements in AI processing, allowing for faster and more accurate inference. Additionally, its industrial-grade security features ensure that data remains protected, catering particularly well to applications in personal computing devices. By enhancing capabilities such as user presence detection and improving facial recognition functionalities, WiseEye2 helps devices intelligently interact with users over various scenarios, whether in smart home setups, security domains, or personal electronics. This blend of smart functionality with energy conscientiousness reflects Himax's commitment to innovating sustainable technology solutions.
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 DCAN XL presents an advanced CAN Bus controller capable of bridging traditional CAN FD with 100Mbit Ethernet. This innovative solution supports a wide range of data rates up to 20 Mbit/s, with specialized transceivers for bit rates both under and over 10Mbps. Designed in accordance with ISO 11898-1:2015 standards, it ensures compatibility across various automotive and industrial communication systems. By adopting cutting-edge serial communication technologies, the DCAN XL reliably enhances the network's data throughput and integrity, making it indispensable for sophisticated vehicular and machine control applications.
The ACAM In-Cabin Monitoring Solution is a sophisticated 60 GHz mmWave radar designed to enhance vehicle safety and passenger comfort through non-intrusive monitoring. This advanced sensor facilitates comprehensive in-cabin detection, including child presence detection, seat occupancy, intrusion alerts, and vital signs monitoring. Leveraging NOVELIC's extensive software stack, ACAM ensures full interior coverage without compromising passenger privacy.
aiSim is the world's first ISO26262 ASIL-D certified simulator, specifically designed for ADAS and autonomous driving validation. This state-of-the-art simulator captures the essence of AI-driven digital twin environments and sophisticated sensor simulations, key for conducting high-fidelity tests in virtual settings. Offering a flexible architecture, aiSim reduces reliance on costly real-world testing by recreating diverse environmental conditions like weather and complex urban scenarios, enabling comprehensive system evaluations under deterministic conditions. As a high-caliber tool, aiSim excels at simulating both static and dynamic environments, leveraging a powerful rendering engine to deliver deterministic, reproducible results. Developers benefit from seamless integration thanks to its modular use of C++ and Python APIs, making for an adaptable testing tool that complements existing toolchains. The simulator encourages innovative scenario creation and houses an extensive 3D asset library, enabling users to construct varied, detailed test settings for more robust system validation. aiSim's cutting-edge capabilities include advanced scenario randomization and simulation of sensor inputs across multiple modalities. Its AI-powered rendering streamlines the processing of complex scenarios, creating resource-efficient simulations. This makes aiSim a cornerstone tool in validating automated driving solutions, ensuring they can handle the breadth of real-world driving environments. It is an invaluable asset for engineers looking to perfect sensor designs and software algorithms in a controlled, scalable setting.
The ADNESC ARINC 664 End System Controller is designed for the next generation of avionic networks, offering unmatched performance and reliability. Fully compliant with the RTCA DO-254 DAL A airworthiness standards, this controller ensures the highest level of safety for critical aerospace systems. Through its high-performance multi-host interface, supporting data throughput up to 400 Mbit/s, it addresses the demanding requirements of modern avionics. The controller's design leverages generic VHDL code, allowing it to be device-independent, which improves compatibility and integration across different systems. Thanks to its embedded SRAM and robust architecture, the ADNESC ARINC 664 becomes an integral part of advanced avionic data networks, paving the way for enhanced communication and system performance across aerospace applications.
LightningBlu is an innovative track-to-train solution, delivering a world-first, multi-gigabit, rail-qualified mmWave connectivity platform. Designed for operational efficiency with low maintenance needs, this system is deployed trackside in 1km intervals, seamlessly bridging wireless links between trains and a trackside fiber network. The lightweight train-top node is engineered for on-train installation, featuring two-sector radios that maintain a 3 Gbps aggregate throughout. This solution greatly enhances operational performance, previously deployed successfully across South Western Railways and Caltrain, driving connectivity advancements in high-speed transport. By utilizing Blu Wireless's mmWave technology, LightningBlu offers unmatched connectivity for on-board services such as internet access and entertainment, boasting data speeds significantly faster than conventional 5G mobile communications. This ensures a dramatically improved commuter experience with robust, reliable connectivity over long distances. Meeting stringent environmental standards, LightningBlu operates at 57-71 GHz, in compliance with international radio regulations, offering continuous service and high-speed link management without the extensive power requirements associated with 4G and 5G mobile networks. Technical capabilities include full environmental rail certification, ensuring robustness against stringent rail standards, and a Mobile Connection Manager to facilitate wireless link management. Supporting all six IEEE 802.11ad channels, LightningBlu maximizes throughput, guaranteeing strong connectivity for data-hungry railway applications, heralding a new age of rail travel with unprecedented speed and efficiency.
The PCE04I Inmarsat Turbo Encoder is engineered to optimize data encoding standards within satellite communications. Leveraging advanced state management, it enhances data throughput by utilizing a 16-state encoding architecture. This sophisticated development enables efficient signal processing, pivotal for high-stakes communication workflows. Furthermore, the PCE04I is adaptable across multiple frameworks, catering to diverse industry requirements. Innovation is at the forefront with the option of integrating additional state Viterbi decoders, tailoring performance to specific needs and bolstering reliability in communications.
The SafeIP™ SinglePHY is Siliconally's leading solution for secure IEEE 802.3 communication. This semiconductor product provides a stable and power-efficient communication solution with its innovative safety features. Engineered for rapid system failure responses, the SinglePHY assures minimal power consumption with a compact form factor, ideally supporting a bandwidth of 100 MBit/s for a wide array of applications in the automotive and automation industries. Packed with capabilities, it supports Open Alliance TC10 Sleep/Wake cycles and offers functionalities like debug data streaming, and classification and localization of potential faults. Moreover, it employs a comprehensive suite of safety features including safety interrupts, reliability handling through safety protocols, and CRC checking to ensure data integrity. Siliconally's implementation ensures compliance with international standards, including IEEE 802.3 and Open Alliance test protocols. Designed in a 22FDX process, the SinglePHY is a practical and fully qualified solution across various automotive-grade conditions, promoting enhanced efficiency and dependability for critical communication tasks.
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 CAN 2.0/CAN FD Controller is a comprehensive CAN controller designed for straightforward integration into FPGAs and ASICs. Compliant with the ISO 11898-1:2015 standard, it supports both traditional CAN and the new CAN FD protocols. CAN FD enhances the original CAN by allowing a higher bitrate of up to 10 Mbit/s and expands the payload to 64 bytes, providing greater flexibility and efficiency in communication. This product is particularly versatile, designed to be compatible with numerous FPGA devices from major manufacturers like Xilinx, Intel (Altera), Lattice, and Microsemi. It supports native bus interfaces such as AXI, Avalon, and APB, facilitating seamless processor integration within SoC-type FPGAs. This makes it an ideal choice for applications requiring robust communication with quick integration into existing systems. The design incorporates a plethora of features aimed at enhancing diagnostic capabilities and CAN bus debugging, which is particularly beneficial for data logger implementations. Despite its extensive feature set, adjustments can be made at the build stage to reduce its footprint for more standard applications. This IP allows for precise control and adaptability, ensuring effective and efficient operation across various deployments.
The SMPTE 2059-2 Synchronization Solution encompasses all needed logic implementation on an FPGA to generate precise audio and video alignment signals using a reference PTP time source and associated clock. This solution targets professional broadcast markets, offering high accuracy and low latency AV content alignment. The robust FPGA timestamping combined with software-driven algorithms ensures an efficient, compact product that's both easy to deploy and integrate. It comes with a management and configuration interface that provides ultimate flexibility. With an IEEE1588 compliant PTP time source, it generates alignment pulses for specified frame rates along with a timecode. The included API allows for easy configuration of both the IP core and software. The module's strong compliance with IEEE1588v2 enhances its adaptability to existing systems, making it a reliable synchronization solution for professional broadcasters. Korusys has developed this synchronization product suite capitalizing on their extensive expertise in PTP synchronization, ensuring it meets the highest standards of precision required in the broadcast industry. When coupled with its user-friendly management interface and API, this makes the SMPTE 2059-2 Solution a valuable addition to any broadcast synchronization setup.
The SiFive Automotive family of processors is engineered to meet the evolving demands of the automotive industry, focusing on safety, security, and performance. These processors are compliant with the latest automotive standards, including ISO26262 for functional safety and ISO/SAE 21434:2021 for cybersecurity. Whether addressing needs in advanced driver assistance systems (ADAS), infotainment, or powertrain management, SiFive Automotive solutions provide a robust platform for automotive innovations. At the heart of the Automotive series is a portfolio that encompasses the A-Series processors, delivering top-notch applications processing capabilities. These solutions are optimized for the demands of automotive electronics, supporting both high-performance and real-time processing with low area and power consumption. Testified by leading automotive experts and partners, SiFive's automotive IP features long-term support and a roadmap designed to future-proof automotive technology. SiFive's commitment to automotive excellence is further supported by a wide ecosystem of partnerships with leading technology companies. Their processors are ready for integration into comprehensive automotive solutions, paving the way for the next generation of smart, connected vehicles. The SiFive Automotive family ensures that vehicle manufacturers can meet the high standards of safety and functionality required for modern automotive systems.
The GateMate FPGA series by Cologne Chip is designed for small to medium-scale FPGA applications, offering exceptional logic capacity, energy efficiency, and compact packaging. Manufactured using GlobalFoundries' 28nm Super Low Power process, these FPGAs ensure high performance at a lower cost, making them suitable for various applications from university labs to large-scale production. This FPGA integrates CPE programmable elements alongside a clever routing engine, enabling efficient multiplier constructions and memory-intensive applications through block RAMs. Supporting 20,480 programmable elements, GateMate FPGAs feature flexible General Purpose IOs that handle a range of voltage levels and configuration options, including LVDS differential pairs. High-speed communications benefit from an available SerDes interface, while synthesis and bitstream generation involve the Yosys framework and Cologne Chip's P&R software. These FPGAs minimize the risk associated with supply chain disruptions thanks to their European manufacturing. Designed with an emphasis on low power consumption, GateMate supports multiple operation modes like low power, economy, and speed, accommodating different application requirements. Its versatility ensures it is a robust choice for new technological solutions across industry verticals.
The Tyr AI Processor Family is a versatile line of high-performance chips designed to facilitate cutting-edge AI and autonomous vehicle applications. The family incorporates advanced scheduling and core management, allowing it to exceed standards in computational efficiency and power utilization. Capable of executing both AI and general-purpose processing tasks, Tyr chips can adapt to diverse computing needs without dependence on specific host processors. The design incorporates a multi-core architecture, enabling tiered performance capabilities – from entry-level to high-performance output. This makes the processors suitable for scaling applications from development to full deployment across various markets including automotive and industrial processing environments. Notably, Tyr processors emphasize seamless programmability using high-level coding, which allows straightforward incorporation of new AI models. Tyr’s commitment to low power consumption is evident in its technical configuration, which features a peak power consumption ranging from 10W to 60W, depending on the specific model. This, along with its modularity, ensures minimal environmental impact while achieving maximum computational output, fulfilling the growing demand for sustainable AI technology. In terms of architecture, the Tyr family supports any AI algorithm across a multitude of host processors, reflecting VSORA's vision for adaptable technology. This flexibility is crucial for handling real-time AI applications in dynamic domains like next-generation vehicular automation and intelligent systems design.
The INAP375R receiver, functioning as a complementary device to the INAP375T transmitter, is an essential component for high-speed serial data communication in car displays and camera systems. This receiver utilizes the APIX2 technology to maintain a DC-balanced, AC-coupled low latency, point-to-point link over shielded twisted pair (STP) cables. Its physical layer can support data transfer rates up to 3 Gbps, offering low electromagnetic interference (EMI) for delicate automotive electronics. Primarily targeting automotive display applications, the INAP375R supports flexible video interfaces that can handle 1 to 2 independent video streams, managing both parallel RGB and LVDS connections with ease. The receiver is engineered with an integrated Media Independent Interface (MII) that interfaces directly with Ethernet MACs, expanding its application potential to full network capabilities. The presence of a full-duplex communication channel ensures uninterrupted, synchronized data, video, and audio transmission across system components. This device is packaged in an LQFP or aQFN format, providing robust design options to accommodate diverse automotive circuit board specifications. It also features advanced diagnostic capabilities to maximize reliability and minimal error rates, making it suitable for critical automotive applications such as infotainment systems, rear-seat entertainment setups, and driver assistance systems.
The ULYSS MCU is tailored for the demanding requirements of the automotive sector. Built upon a 32/64-bit RISC-V architecture, this microcontroller facilitates high-performance applications ranging from 120MHz up to 2GHz. It combines cost-effectiveness with cutting-edge automotive features, making it an ideal choice for modern vehicles that require robust computing capabilities. This microcontroller is engineered to support a wide array of automotive applications, providing the power and reliability needed for complex automotive systems. From advanced driver assistance systems (ADAS) to autonomous driving technologies, the ULYSS MCU ensures that automotive electronics can meet both current and future needs with minimal adjustments. By incorporating sophisticated RISC-V technology, the ULYSS MCU stands out in the competitive landscape as a powerful and flexible solution. It reflects Cortus's dedication to innovation and excellence in semiconductor design, positioning itself as a key player in the evolution of the automotive electronics industry.
The SafeIP™ DualPHY is a versatile solution by Siliconally for 100/1000BASE-T1 communication. Ideal for automotive Ethernet applications, it balances versatility and safety, supporting high-speed data exchanges across both 100 and 1000 MBit/s bands. This dual-mode capability allows seamless switching and negotiation with communication partners, ensuring robust network performance even under varying conditions. Equipped with Siliconally's signature safety technologies, the DualPHY guarantees compliance with leading EMC protocols and offers the agility and reliability essential for contemporary automotive applications. Its architecture takes automotive-grade demands into account, focusing on efficient energy use and space-saving designs without compromising safety. The DualPHY ensures comprehensive EMC compliance, handling both conducting and radiating emissions effectively. It is constructed to accommodate the full spectrum of rigorous testing standards, affirming its status as a reliable and powerful semiconductor product for critical communication environments.
ZORM is engineered for high-performance zone monitoring in industrial settings, offering reliable detection in harsh conditions. This radar sensor is perfect for applications requiring robust motion detection and area surveillance, operating seamlessly in environments where visibility may be compromised. Providing critical safety and security features, ZORM integrates easily with existing infrastructure to enhance automated processes and safeguard human-machine interactions.
The CAN FD Full Controller is engineered to enhance the capabilities of standard CAN protocols by supporting both CAN 2.0B and extended CAN FD frames. With compliance to ISO 11898-1:2015, this controller optimizes communication reliability and data rate handling, making it suitable for modern automotive and industrial applications. Its design allows it to overcome the limitations of traditional CAN systems, facilitating improved data throughput, which is essential in sophisticated, real-time communication networks.
Time-Sensitive Networking (TSN) is an innovative suite of Ethernet standards developed to enhance multi-faceted communication networks with deterministic capabilities. TSN allows time-critical and regular traffic to coexist on the same network, ensuring that essential operations receive priority bandwidth and timeliness without sacrificing performance for other applications. This technology offers precise timing synchronization, crucial for sectors like automotive, aerospace, and industrial automation where control systems need to interact seamlessly. By guaranteeing that data packets are transmitted and received in a timely and predictable manner, TSN minimizes latency and jitter, significantly improving network stability and performance. TSN's flexible architecture supports a variety of quality of service (QoS) levels, enabling users to tailor network behavior to specific operational needs. It is designed for scalability and interoperability with existing Ethernet standards, allowing industries to prioritize safety and efficiency simultaneously with minimal infrastructure changes. Overall, TSN empowers systems with the communication reliability necessary for advanced automation and control applications, setting the stage for the next generation of smart, interconnected devices.
The Ceva-XC22 is a cutting-edge DSP core tailored for 5G and 5G-Advanced workloads, offering unprecedented processing capabilities and flexibility for demanding communications applications. This DSP core supports simultaneous processing tasks with high utilization rates, ensuring superior performance across multiple data channels and spectral layers.\n\nCeva-XC22 is built on a dual-threaded architecture with a dynamic scheduled vector processor, which provides extensive processing power for increasingly complex 5G applications. The system also includes a vector computation unit for enhanced arithmetic operations and data handling.\n\nBy leveraging its advanced execution model, Ceva-XC22 delivers significant performance improvements over its predecessors, making it ideal for a range of infrastructure applications, from massive MIMO to core network processing.
The Time Sensitive Network IP Core is an advanced solution explicitly crafted to support time-critical network environments. It offers remarkable precision and fault tolerance, making it ideal for applications where timing accuracy is paramount. Capable of scaling from 1Gbps to 10Gbps, this core is engineered to provide robust anti-masquerading and babbling protection functions. Integrated with the widely adopted AXI standard, the network core facilitates easy interfacing between hardware and software, which is essential for developers looking to integrate it within diverse systems efficiently. This ease of integration is coupled with its fault tolerance capabilities, ensuring network reliability in complex deployments. Applications that significantly benefit from this IP core include industrial automation, telecommunications, and any domain requiring synchronized processing and high-reliability data exchange. The Time Sensitive Network IP Core is invaluable in enhancing system efficiencies and ensuring data integrity across demanding operational environments.
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