All IPs > Interface Controller & PHY > IEEE1588
The IEEE1588 Interface Controller & PHY is a crucial category of semiconductor IPs designed for applications that require high precision time synchronization across networked devices. This suite of technologies is essential for various sectors, including telecommunications, industrial automation, and data centers, where accurate time alignment can significantly improve system performance and reliability.
These semiconductor IPs facilitate precision timing protocols by enabling devices to synchronize their clocks down to nanosecond-level accuracy. IEEE1588, also known as the Precision Time Protocol (PTP), plays a vital role in timing-critical applications like financial trading systems, smart grids, and connected car infrastructures. By integrating IEEE1588 interfaces and physical layer IPs, designers can create systems capable of robust time synchronization, essential for minimizing latency and ensuring the seamless operation of networked devices.
Products within this category typically include PHY modules and interface controllers that manage the physical layer connectivity and protocol handling required for IEEE1588 compliance. These IPs support various network topologies and standards, allowing for flexible implementation across a wide range of hardware environments. This scalability is particularly beneficial for network operators who need to maintain precise timing across complex, multi-vendor networks.
Moreover, utilizing IEEE1588 Interface Controller & PHY semiconductor IPs can lead to significant improvements in system efficiency and performance. By enabling accurate and reliable clock synchronization, these technologies help reduce the likelihood of system errors, data loss, and service interruptions. For companies interested in building cutting-edge time-sensitive applications, adopting IEEE1588-compliant solutions is a strategic investment in achieving superior network performance and user satisfaction.
KPIT excels at providing AUTOSAR solutions that streamline software integration and improve vehicle architecture. The company's focus on middleware development ensures efficient application deployment and integration within both classic and adaptive AUTOSAR frameworks. KPIT's solutions enable quick software updates, robust validation processes, and cost-effective production timelines, essential for the evolving landscape of Software-Defined Vehicles (SDVs).
The MIPITM CSI2MUX-A1F operates as a sophisticated CSI2 video multiplexor designed to handle multiple camera inputs simultaneously. In compliance with CSI2 rev 1.3 and DPHY rev 1.2 standards, this multiplexor can manage inputs from up to four CSI2 cameras, consolidating them into a single comprehensive video stream. Engineered for high-efficiency video streamlining, it operates at a data rate of 4 x 1.5Gbps, ensuring real-time processing and efficient data throughput. The ability to integrate multiple video feeds into a single output makes it suitable for systems requiring complex multimedia handling and advanced video applications. This multiplexor provides solutions for systems where video data from various sources needs to be aggregated efficiently, optimizing space and resource utilization across video interfaces. Its seamless integration expands its utility across multiple paradigms, making it a staple in any comprehensive video system architecture.
Secure-IC's Secure Protocol Engines provide high-performance IP blocks aimed at offloading network and security processing tasks. These engines are designed to efficiently accelerate cryptographic operations within both FPGA and ASIC environments. They allow for seamless integration into existing security architectures, facilitating enhanced data protection and processing speed, which are essential in modern high-performance computing scenarios.
The MIPITM SVRPlus-8L-F is an advanced 8-lane second-generation serial video receiver tailored for FPGA applications. It adheres to the CSI2 rev 2.0 and DPHY rev 1.2 standards, featuring an impressive ability to handle 16 virtual channels and output 4 pixels per clock. The receiver boasts a robust calibration support mechanism coupled with comprehensive communication error statistics, making it an optimal choice for high-performance video applications. Operating at a substantial data rate of 12Gbps, the IP is designed to meet the high demands of modern video systems. Its integration ease and high functionality are supported by its detailed error-reporting capabilities, which provide invaluable insights for system improvements. This IP's architecture is ideal for ensuring seamless video data reception, maintaining integrity, and optimizing performance. Further enhancing its effectiveness, the MIPITM SVRPlus-8L-F is equipped with calibration support, offering a complete package for efficient and reliable video signal processing in varied environments.
Flexibilis Ethernet Switch (FES) is a triple-speed Ethernet Layer 2 switch IP designed for industrial and commercial applications requiring robust and fast networking capabilities. FES integrates precision time functionality through IEEE 1588v2 compliant implementations, providing essential support for quality time synchronization in extensive networks. With the ability to provide gigabit forwarding per port, the FES ensures high-speed data transfers across numerous network interfaces efficiently. Standard compliance with IEEE 801.3x and compatible Media Access Control allows FES to robustly manage Ethernet frames while maintaining optimal performance. FES prioritizes traffic using effective packet prioritization techniques, ensuring more critical data streams maintain low latency and reliability. This Ethernet switch IP core's modular design accommodates various network topologies and interface standards, enhancing its versatility in complex systems. Users can select from different port configurations, scaling from small networks up to larger connected systems, reinforcing its application scope in diverse environments such as industrial networks and large data centers.
The MIPITM SVRPlus2500 is an efficiently designed 4-lane video receiver that meets the challenges of contemporary video systems through its compliance with CSI2 rev 2.0 and DPHY rev 1.2 standards. This device is crafted for high-performance applications, featuring a low clock rating that facilitates easy timing closure and supports PRBS. Capable of handling 4/8/16 output pixels per clock, this receiver includes innovative calibration support and 1:16 input deserializers per lane. Its 16 virtual channels empower it to manage robust data streams, operating effectively at a data throughput of 4 x 2.5Gbps, which ensures high fidelity in video reception. The SVRPlus2500 stands as a versatile solution for diverse video processing needs, balancing performance and integration with ease. Its reliability in managing high data rates and providing seamless video reception makes it ideal for a wide array of advanced video applications.
Designed for FPGA contexts, the MIPITM SVTPlus-8L-F is a sophisticated 8-lane second-generation serial video transmitter. Adhering to the stringent requirements of the CSI2 rev 2.0 and DPHY rev 1.2 standards, this transmitter delivers data at an impressive 12Gbps. It stands out for its seamless integration into video systems, offering unparalleled data transmission capabilities and upholding the fidelity of transmitted signals. The transmitter is designed to support high data loads, ensuring that it can handle intensive video applications with ease. Its design not only facilitates robust data rates but also ensures that the transmitted signals maintain clarity and accuracy, essential for advanced video processing systems. By incorporating modern design methodologies, the MIPITM SVTPlus-8L-F ensures reliable data flow, minimal transmission errors, and enhanced system performance. This transmitter is a pivotal addition to any advanced digital video system, providing essential high-speed data transmission features.
TimeServoPTP extends the remarkable features of the TimeServo timer by complying fully with the IEEE 1588v2 PTP standards. This implementation as an ordinary clock slave for FPGA improves operational precision with synchronization mechanisms that communicate effectively with external network time sources. Supporting both one-step and two-step synchronization, TimeServoPTP facilitates accurate delay requests and enables robust timekeeping in networked environments. This IP is especially vital for applications demanding precise time distribution and synchronization, making it indispensable for systems where timing integrity is critical.
The Bluetooth Digital Clock - Levo Series is a state-of-the-art timekeeping solution that incorporates Bluetooth technology to ensure precise and reliable synchronization in diverse settings. Designed for seamless connectivity and ease of use, this digital clock series enables hassle-free integration with wireless systems, making it a go-to choice for environments where cabling is impractical or undesirable.\n\nWith a sleek and modern design, the Levo Series brings not only efficiency but also aesthetic appeal to any space. It is engineered to provide accurate time display and synchronization over Bluetooth connections, thereby offering a wireless alternative to traditional clock setups. This series effectively eliminates the complexity of network wiring, contributing to cleaner installations and more flexibility in clock placement.\n\nIdeal for institutions like schools, healthcare facilities, and office buildings, the Bluetooth Digital Clock - Levo Series offers features like easy setup, maintenance-free operation, and compatibility with various Bluetooth-enabled devices. By choosing this product, organizations benefit from a state-of-the-art solution that aligns with modern wireless communication standards, facilitating better time management and system integration.
The PLIC (Platform-Level Interrupt Controller) is a fully compliant RISC-V IP designed to manage multiple interrupt sources within a system. This feature-rich controller is configurable, allowing it to be tailored to specific system requirements while maintaining compliance with RISC-V architectural standards. Its flexibility and capability to prioritize interrupt handling ensure efficient processing, which is crucial for high-performance computing environments.
Suited for high throughput applications, the MIPITM SVTPlus2500 is a versatile 4-lane video transmitter compliant with CSI2 rev 2.0 and DPHY rev 1.2 standards. This transmitter offers seamless operation with a low clock rating, simplifying timing closure challenges, and supports PRBS and calibration for enhanced accuracy. It is designed to handle 8/16 pixel inputs per clock, offering programmable timing parameters for versatile use across different systems. With its capacity to manage 16 virtual channels and achieve data rates up to 4 x 2.5Gbps, it ensures efficient video signal transmission with minimal data loss. The SVTPlus2500's adaptability makes it ideal for sophisticated video systems, offering controlled and precise data transmission over flexible configurations. Its robust system integration capabilities are designed to meet a broad range of industry standards, enhancing overall operational efficiency.
The Advanced Flexibilis Ethernet Controller (AFEC) brings triple-speed Ethernet processing to programmable hardware environments, supporting traditional copper and modern fiber optics connections. This IP block, which functions much like a Network Interface Controller, achieves a significant efficiency by pairing DMA transfer capabilities with both receive and transmit data, thus reducing CPU load efficiently. AFEC incorporates standard MII/GMII interfaces for seamless connectivity to Ethernet PHY devices, facilitating high-speed data transfers without overwhelming moderate-caliber processors. By accommodating features like automatic CRC computation, comprehensive DMA control, and precise time stamping consistent with IEEE 1588 standards, AFEC ensures a cohesive integration into any Ethernet-based infrastructure. The AFEC's high configurability and tested Ethernet capabilities make it an excellent choice for applications spanning from telecommunications to utilities. AFEC's use of FPGA resources is optimized to minimize footprint while maximizing performance, ensuring that hardware constraints do not impede the integration of this powerful controller within complex network topologies.
The BlueLynx Chiplet Interconnect represents a pivotal development in die-to-die communication, emphasizing versatility through support for both the Universal Chiplet Interconnect Express (UCIe) and the Open Compute Project's Bunch of Wires (BoW) standards. This innovative solution is designed to integrate smoothly with on-die buses and Networks-on-Chip (NoCs), accommodating a variety of protocols such as AMBA, AXI, and ACE. This product is optimized for high-bandwidth applications, addressing the stringent power, performance, and area (PPA) requirements of modern chip designs. By utilizing a dual-mode PHY and offering extensive configurability in data rates and packaging options, the BlueLynx interconnect facilitates rapid, efficient system integration. Silicon-proven across numerous process nodes, including advanced nodes like 3nm and 4nm, BlueLynx is tailored to meet the diverse needs of the semiconductor market. Its customizable architecture ensures that each implementation maximizes bandwidth and minimizes power usage, supporting complex systems with ease.
This sophisticated piece of technology serves as a cornerstone for Ethernet networking, offering superior switching capabilities for Time-Sensitive Networking (TSN). The 1G MTSN is adept at managing network traffic with precision, supporting high-speed data transfer and low-latency communication. It embodies the robust integration of IEEE standards, such as IEEE 802.1AS and IEEE 1588 with PTPv2, ensuring precise time synchronization crucial for deterministic applications.\n\nAdditional functionalities include Quality of Service (QoS) features, VLAN tagging, and time-sharing capabilities, making it ideal for applications requiring stringent timing and lossless data transport. The design of this switch allows it to maintain seamless performance across various network configurations, catering to complex system setups across industries that depend on reliable and synchronous communication.\n\nField deployment reveals its ability to operate in highly volatile environments, where synchronization fidelity and network resilience are priority. It is also compatible with several physical layer interfaces, including RMII, MII, GMII, RGMII, and serialized configurations like SGMII and QSGMII, providing flexible connectivity options. Truly a versatile component, it is designed to support evolving standards and network topologies, keeping pace with technological advancements without necessitating hardware changes.
The Matchstiq™ X40 is a high-performance software-defined radio (SDR) engineered with a low size, weight, and power (SWaP) design. This SDR is optimized for edge computing, particularly suited for artificial intelligence (AI) and machine learning (ML) applications. It integrates a robust RF front end with multi-channel digital transceivers, providing access to frequencies up to 18GHz and a bandwidth of 450MHz. It features a Nvidia Orin NX 16G for advanced data processing and an AMD Zynq Ultrascale+ FPGA for signal integration. The small form factor, with precise dimensions and modest weight, offers advantages in space-constrained deployments such as unmanned aerial systems (UxS) and ALE payloads. The Matchstiq™ X40 facilitates superior performance in frequency agility, ideal for spectrum management and complex signal detection tasks. The SDR's architecture supports numerous interface options including USB 3.0 and 1 GbE networking, complemented by serial port connectivity. This device is designed to leverage the libsidekiq API for seamless API integration, making it an indispensable tool for rapid prototyping, testing, and field deployment.
The 10G TSN Ethernet Switch is engineered to handle massive data throughput and high-speed network demands. Tailored for time-sensitive applications, it excels in environments requiring tight synchronization and robust data handling capabilities. Incorporating the IEEE 802.1 series standards, it facilitates precision Time-Sensitive Networking (TSN) with comprehensive QoS and synchronization features.\n\nWith support for a plethora of communication interfaces, including RMII, MII, GMII, and RGMII, and spanning port speeds from 10M to 10G, this switch flexibly adapts to various network architectures. The inclusion of advanced VLAN management and Spanning Tree Protocols enhances its ability to manage data flow efficiently and securely across expansive networks.\n\nThe switch is highly suited for industries reliant on high-speed deterministic communication, such as automation, audio-visual broadcasting, and critical infrastructure. Its robust design ensures adaptability to current and future network demands, making it a sustainable choice for maintaining infrastructure longevity.
The Flexibilis Redundant Switch (FRS) is a versatile triple-speed Ethernet Layer-2 switch IP core designed to integrate High-availability Seamless Redundancy (HSR) and the Parallel Redundancy Protocol (PRP) into a single solution. Known for its exceptional performance, FRS can handle full-duplex gigabit speeds across multiple ports, making it one of the most robust hardware options for ensuring redundant network communication. FRS eliminates the need for separate RedBoxes by allowing devices to be connected directly, thereby reducing costs and complexity in deployment. Its FPGA-based design provides a flexible implementation with port customization capabilities, enabling it to operate under various network configurations and speed requirements. Additionally, FRS supports the IEEE1588 Precision Time Protocol (PTP), ensuring accurate time synchronization across network nodes, a critical function for network stability in time-bound communication environments. Available in customizable configurations ranging from 3 to 8 ports, FRS can be adapted to specific user needs. Its robust support for wire-speed Ethernet packet forwarding, coupled with transparent clock processing, makes it ideal for applications demanding high reliability and precision like industrial networks, smart grid solutions, and any infrastructure where seamless communication is imperative.
The "CPU-less IEEE 1588v2 Slave Clock" is tailored for applications where compact yet precise timing solutions are necessary. It operates as a hardware-only solution, implemented entirely in VHDL, to act as a PTP slave clock that can synchronize networked devices to a master time source with sub-microsecond accuracy.\n\nPrimarily suited for environments where space and power savings are as critical as precision, this product supports multiple PTP profiles, making it adaptable to various network layers and topologies. It integrates seamlessly with a range of Ethernet interfaces, including MII, GMII, RGMII, and serialized connections such as SGMII and QSGMII.\n\nWith event timestamping, alarm detection, and optional IRIG-B master output, it provides a comprehensive solution for synchronization needs in sectors like telecommunications, financial network infrastructures, and power utilities. Its deployment ensures accurate and stable timing across all devices, optimizing network performance and reliability.
The SMPTE ST 2059 core facilitates precise timing and synchronization across diverse broadcast and AV equipment. Utilizing IEEE 1588 Precision Time Protocol (PTP), this IP ensures accurate time alignment signals for video and audio systems, allowing for seamless integration and coordination of media devices, both traditional and network-based. The core is network speed independent, capable of supporting Ethernet networks ranging from 1G to 100G, which guarantees compatibility with contemporary network architectures.
The SMPTE 2059-2 Synchronization Solution from Korusys integrates sophisticated FPGA logic to align video and audio signals precisely using a reference PTP time source. Designed with the professional broadcast industry in mind, this solution uses the IEEE1588v2 protocol to provide low-latency synchronization essential for modern AV systems. The integration is further simplified by an intuitive management interface that allows users to configure and manage the system with ease. Featuring software-driven algorithms and precise FPGA timestamping, the product ensures accurate video and audio alignment across IP networks. Engineers can deploy this technology seamlessly, benefiting from its flexibility and customization options to meet specific broadcast requirements. By adopting a modular approach, this solution becomes not only effective but also highly adaptable for a range of applications. Deployed in professional settings, the SMPTE 2059-2 Synchronization Solution facilitates the handling of AV content with high accuracy, making it invaluable in environments where precise timing of media content is critical. Whether for live broadcasts or other broadcast media, this powerful tool optimizes synchronization every step of the way.
The Flexibilis Redundant Card (FRC) is a PCIe Network Interface Card uniquely developed to provide High-availability Seamless Redundancy (HSR) and Parallel Redundancy Protocol (PRP) standards compliant networking capabilities. FRC excels in facilitating redundant communication for critical traffic, ensuring systems remain operational even during network failures, a critical feature for essential services such as power utility automation. FRC card balances traditional Ethernet network functionalities with specialized redundancy capabilities, all while integrating seamlessly with existing infrastructures. The card is designed to offer precision synchronized events via its IEEE1588-2008 compliant Precision Time Protocol, achieving sub-microsecond accuracy vital for time-sensitive applications. This standalone solution harnesses the sophisticated features of Flexibilis's Redundant Switch technology, presenting itself as a comprehensive system on a PCIe form factor. Hence, it provides a flexible solution to enhance commercial Ethernet environments, offering intuitive management via graphical interfaces or standard protocols like NETCONF.
The Nerve IIoT Platform crafted by TTTech Industrial Automation offers a comprehensive framework for machine builders, embedding cutting-edge edge computing capabilities. By seamlessly connecting hardware, protocols, and operating systems, it provides a robust software backbone for industrial setups. This platform advances digital transformation by allowing businesses to scale and manage operations without disruption. Nerve integrates cloud-managed services with a focus on openness, security, and flexibility. Its salient features include Docker and CODESYS compatibility, and it supports running virtual machines which empower users to choose their preferred systems for device management and application deployment. The platform’s emphasis on security ensures IEC 62443-4-1 certification, safeguarding data and operations within the edge environments. The real-time capabilities of Nerve facilitate instantaneous machine data processing, allowing for immediate action and optimization, thus improving productivity and operational efficiency. Moreover, the platform’s ability to handle multiple applications on standard industrial hardware enhances resource utilization and opens new avenues for digital services.
The PoE Analog Clock - Traditional Series is a cutting-edge synchronization solution that leverages Power over Ethernet (PoE) technology to provide an efficient and reliable timekeeping system. This clock series caters to the needs of various industries by integrating seamlessly with existing Ethernet networks, thereby reducing additional wiring and installation costs. It is especially beneficial in environments that require precise time synchronization across different locations.\n\nThe traditional design of this clock ensures it can blend into any setting without disrupting the visual harmony. It utilizes advanced PoE technology, which simplifies power and data transmission through a single Ethernet cable, enhancing ease of deployment and flexibility. This feature-rich series is constructed to ensure high durability and performance consistency, making it an ideal choice for schools, hospitals, and corporate environments.\n\nThe PoE Analog Clock - Traditional Series also supports easy integration with central time management systems, allowing for real-time monitoring and automated adjustments as required. By automating time synchronization, organizations can ensure operational efficiency and compliance with time-critical tasks. This product underscores IPclock’s commitment to merging traditional design aesthetics with modern technology innovations.
The XRS7000 series are advanced integrated circuits designed to add High-availability Seamless Redundancy (HSR), Parallel Redundancy Protocol (PRP), and time synchronization capabilities to both existing and novel applications. As part of the SpeedChips family, these chips provide market-leading redundancy in Ethernet networks, ensuring zero data loss without any single point of failure. The series offers high reliability and availability, fundamental for sectors like industrial automation and vehicle communication, as well as substation automation. XRS7000 devices are versatile with distinct models like XRS7003 and XRS7004, each featuring multiple ports for flexible deployment. The XRS7003 version is apt for HSR and PRP endpoints, whereas the XRS7004 version supports both endpoint and RedBox functions, enabling broader connectivity across network nodes. Their integration simplifies the implementation of sophisticated networking systems by providing ready-made IC options that combined, form a more expansive redundancy structure. These chips support features such as cut-through and store-and-forward operation, quality of service (QoS) with priority tagging, as well as time and frequency synchronization via IEEE1588-2008, ensuring not only reliability but also precision in data transmission across networks. The XRS7000 series, by coupling functionality with robust design, effectively enhances communication networks for diverse industrial applications.
The FireLink Basic IP core has been developed to enhance data transmission in IEEE-1394-2008 networks, providing up to S3200 transmission capability. It is tailored for non-PCI systems, offering an upgrade path to IEEE-1394-2008 Beta for general markets, including aerospace, industrial robotics, and consumer electronics. This IP core supports AS5643 protocol as an option, optimizing performance and reducing host resources in data-intensive applications.
Designed to deliver high-speed, low-latency communication between processors and various accelerators, the CXL Controller stands out with its superior performance metrics. Crafted to meet the demands of modern data centers, this controller minimizes latency, thereby improving throughput across AI and computing tasks. By leveraging Compute Express Link technology, it facilitates efficient memory expansion and device connectivity, supporting vast arrays of servers and computational devices. The CXL Controller ensures that data coherence across interconnected systems is maintained, which is pivotal for resource-intensive applications like AI and cloud-based computing. The controller's architecture supports various devices, from subsystems to accelerators, resulting in more flexible and dynamic resource usage that boosts overall system efficiency. One of the key features of this CXL Controller is its integration capacity across a wide range of devices. This adaptability enables it to unify computing operations, delivering substantial improvements in operational cost and efficiency. In particular, its application in AI environments underscores its capacity to reduce data traffic and streamline performance, ultimately facilitating more robust and expansive computing environments.
The Korusync IEEE1588 PCIe Card offers precision timing solutions essential for high-frequency trading, telecoms, and industrial applications. Utilizing cutting-edge IEEE1588v2 synchronization technology, the card delivers unparalleled time accuracy to server environments, crucial for sectors requiring stringent timing specifications. Supported by a suite of software tools, the card replaces the standard system clock with a sophisticated, low-latency alternative, enhancing the performance and timing precision of server-based applications. Its oven-controlled oscillator and specialized algorithms ensure robust time accuracy, even in high network load scenarios, achieving precision within 100 nanoseconds. Designed for integration in both Linux and other server architectures, the card's single-slot, full-height PCIe configuration facilitates straightforward deployment. Its capabilities extend to providing accurate timestamps for system events, thus allowing for effective monitoring and performance optimization in trading and other time-sensitive operations.
The IEEE1588 Precision Time Protocol Solution by Korusys offers a robust and adaptable implementation of the IEEE1588v2 standard. This product comprises multiple plug-and-play interfaces, including a high-performance line rate master capable of supporting up to 4000 subordinate devices. Its architecture is designed to integrate seamlessly with existing network infrastructures, making it a versatile choice for precision time dissemination. Capable of managing extensive networks with high data throughput, the solution employs sophisticated timing recovery algorithms for superior performance. Users also have access to simulation tools for network and algorithm testing, enabling the evaluation of real-world network scenarios. With comprehensive support for simulation and deployment, it ensures that timing precision is maintained even under heavy network load. Korusys' solution is customizable, allowing for tailoring to the specific needs of various industries. The combination of advanced PTP capabilities with simulation features makes it ideal for telecommunications and data networks where accurate time synchronization is paramount. This finely-tuned offering ensures enterprises can achieve precise coordination across networked devices.
FireCore amalgamates both PHY and Link Layer capabilities into a singular, powerful IP offering designed for IEEE-1394 and AS5643 applications. Engineered to support data rates from S100 to S3200, FireCore delivers high-speed data transmission essential for aerospace and defense sectors. Notably featuring patented enhancements for Mil1394 support, FireCore provides extensive configurability for both PHY ports and link layer operations, ensuring optimal performance and integration in various system environments.
The PRBS Generator, Checker, and Error Counter is a versatile IP solution encompassing high-performance capabilities for testing and verifying data integrity and transmission. Designed to handle PRBS orders 7, 15, and 31, it boasts a high data rate and accurate error counting capabilities. Featuring compact design and differential CMOS data/clock input and output, it is ideal for reducing power consumption with a dedicated power-down mode. The device is compatible with the TSMC 28HPC process, showcasing adaptability across various applications with a focus on precision and reliability. With support for data rates up to 36 Gbps and low power consumption at around 80 mA, it is engineered to scale efficiently with data rates. Its availability is projected for May 2024, which highlights its future-ready design catering to evolving technological demands. Embodying cutting-edge design, this tool addresses the needs of modern technological landscapes, offering a balanced trade-off between performance and energy efficiency. Its compact dimensions, notably 67×142µm, emphasize its suitability for space-constrained environments, while the differential input-output features ensure robust and resilient communication links.
FireCore Extended is crafted for applications needing extensive data transmission and high throughput, supporting rates up to 3200Mbps. It combines the advantages of OHCI-compliant DMA engines, making it ideal for systems requiring high bandwidth. Found across diverse sectors, from aerospace command systems to medical imaging, it ensures robust support for Mil1394 enhancements, enabling efficient offloading of data processing tasks from the host, thus optimizing system performance.
Designed to replace commercially available general-purpose Link Layer chips, FireLink GPLink IP Core is tailored for aerospace and defense sectors, offering flexible and cost-effective solutions. It supports S100-S400 transfer rates and provides robust functionality for typical aerospace needs, like remote device interfacing. Its adaptability to various FPGA platforms makes it a valuable asset in creating scalable designs.
The FireTrac AS5643 Interface Card line is engineered for advanced data processing in aerospace systems, particularly those using the Mil1394 standard. It provides robust simulation and testing capabilities, allowing precise control and analysis of Mil1394 networks. The FireTrac cards integrate seamlessly into existing systems, offering unparalleled data throughput and processing accuracy, critical for aerospace applications that demand high reliability and performance.
FireLink Extended is suited for environments demanding high data throughput and reliable IEEE-1394b-2008 compliance, integrating OHCI standards with enhanced DMA engines. Ideal for PCI-equipped systems, it significantly reduces processor load while delivering high-efficiency data streams. Its support for AS5643 protocol enables unique configurations in aerospace command systems and other high-tech sectors needing superior data handling capabilities.
The FireCore Basic solution is a specialized IP core designed to meet the demands of high-speed data transmission in IEEE-1394-2008 environments. Optimized for applications from aerospace to industrial cameras, it ensures seamless support for high data transfer rates up to S3200, offering a minimal footprint solution. The core integrates Mil1394 protocol support, enhancing timing and efficiency, crucial for command and control systems across various high-tech sectors.
Targeted at applications requiring a plug-and-play replacement for off-the-shelf general purpose Link Layer chips, FireCore GPLink provides an integrated solution with all necessary A&D functional blocks. It supports data rates from S100 to S400, offering a flexible, economical alternative to existing solutions, while maintaining the robustness needed for demanding environments such as aerospace and defense, industrial machinery, and consumer electronics.
The ANX7412 USB Type-C Port Controller is a versatile interface device designed to handle the complexities of USB-C connectivity, including the latest USB-C (r1.2) and USB-PD v3.0 (r1.0) specifications. This controller facilitates seamless communication across USB interfaces, supporting power delivery and allowing high-speed data transfer up to 10Gbps. Exceptional for devices needing high-performance USB interfaces, the ANX7412 supports alternate modes and power delivery functions necessary for modern applications such as laptops, tablets, and docking stations. This controller not only manages data integrity but also ensures adequate power supply routing, which is critical for USB-C enabled devices that require charging and power management features. With integrated circuitry that helps detect, configure, and manage USB connections, the ANX7412 serves as a key component in developing robust, versatile, and future-proof connectivity solutions. By supporting multiple data and power roles, it enhances device compatibility and functionality for extensive multimedia applications.
The FireSpy Bus Analyzer series offers comprehensive solutions for monitoring and analyzing IEEE-1394 buses, with support for a range of bus configurations from single to triple bus systems. Tailored for the aerospace and defense sectors, FireSpy analyzers provide essential insight into bus activities, aiding in the diagnostics and maintenance of complex systems. The fourth-generation FireSpy models, with expanded capabilities, serve as indispensable tools ensuring compatibility and compliance with industry standards.
The XR7 PTP stack is meticulously crafted for precise time synchronization over IP and Ethernet networks, adhering to the exact standards set by IEEE 1588-2008. This solution is highly portable, written in pure C language, ensuring seamless integration into diverse systems, predominantly utilizing the Linux OS but easily adaptable to others. At the heart of XR7 PTP is the facilitation of nanosecond-class synchronization accuracy, an achievement maintained even amidst packet-based network transfers. This precision makes it ideal for critical systems where timing is everything, including energy systems and telecommunications. XR7 PTP supports a range of operational modes, including master, slave, and boundary clock configurations, along with functionalities such as one-step and two-step clocks for better synchronization. The PTP stack features a time adjustment interface that allows fine-tuning of local oscillators, enhancing the accuracy of synchronization beyond the standard. Licensing the XR7 PTP stack also opens doors to consistent technical support and optimized performance setups that cater to specific industrial requirements, ensuring reliability and longevity in network management execution.
XR7 Redundancy Supervision is a critical implementation supporting the dual protocols of High-availability Seamless Redundancy (HSR) and Parallel Redundancy Protocol (PRP), critical for uninterrupted network communications. It ensures supervision and integrity of the network by handling supervision frames and maintaining a comprehensive NodesTable. This implementation, crafted in C language, is versatile for integration into various system environments, particularly Linux-based systems. It efficiently updates and processes information concerning network nodes, beneficial for management and monitoring systems. The XR7 Redundancy Supervision does not directly utilize the data it gathers, instead prioritizing providing a reliable data framework for other system components. Licensing XR7 Redundancy Supervision allows leveraging its robust frame processing capabilities to guarantee mission-critical data is efficiently and reliably synchronized across nodes. By ensuring the timely dissemination of supervision data, it sustains high resilience in network operations, making it invaluable for industries dependent on steady communication like energy and automation.
The MiPi D-PHY V1.2 supports high-performance data transmission, with a data rate of 80Mbps to 1.5Gbps per lane and up to 2.5Gbps with clock skew calibration. It is designed for both high-speed and low-power modes and supports up to a 4-lane architecture. This PHY includes a built-in loopback capability that enhances testability and reliability in various applications. Its comprehensive feature set makes it ideal for modern communication protocols requiring high data transfer speeds with precision.
The Sub-LVDS Transmitter PHY supports data rates of up to 700Mbps and operates with dual power supply options, either from 1.2V or 1.8V. It includes features like power-down modes for minimal energy usage and delay controls for precise clock-to-data alignment. With selectable channel outputs, this PHY is perfectly suited for applications requiring robust low-voltage data transmission and efficient, high-speed delivery.
FireGate acts as a sophisticated IEEE-1394b PHY core, engineered to seamlessly support data rates from S100 through S3200 in compliance with AS5643 standards. It integrates configurable PHY front-end capabilities, allowing for extensive customization based on system requirements. This core is essential for environments requiring high-speed data transmission and robust interoperability with standard PHY devices, ensuring precision and reliability in data-heavy applications.