All IPs > Graphic & Peripheral > Arbiter
In the realm of graphics and peripherals, arbiter semiconductor IPs play a crucial role in managing data flow and resource allocation within integrated circuits. These IP blocks are pivotal in coordinating access to shared resources such as memory banks, buses, and other critical system pathways. An arbiter ensures that multiple components within a chip can communicate effectively without bottlenecks, prioritizing requests to maintain optimal performance, especially in systems where simultaneous data transactions are frequent.
Arbiters are essential in graphics processing units (GPUs), where intense computational tasks require efficient resource management to deliver smooth and high-performance visual outputs. Without effective arbitration, GPUs could experience delays or inefficiencies that might degrade rendering performance or increase latency, affecting user experiences in applications ranging from gaming to professional graphics design.
In addition to their role in graphics, arbiter semiconductor IPs are equally important in peripheral devices that need to manage data exchange between various components. For instance, in systems where multiple input/output operations occur simultaneously—such as USB controllers, network interfaces, or audio processors—arbiters help maintain the required bandwidth and ensure each peripheral can access the central processor or memory resources without interference.
Overall, selecting the right arbiter IP can significantly enhance the efficiency and performance of both graphics and peripheral systems. These IPs are customizable to meet the specific requirements of varied applications, providing designers with the flexibility to optimize their circuits for maximum throughput and reliability. Whether in consumer electronics, industrial applications, or embedded systems, arbiter semiconductor IPs are indispensable for achieving seamless operation and communication across diverse system components.
aiSim 5 stands as a cutting-edge simulation tool specifically crafted for the automotive sector, with a strong focus on validating ADAS and autonomous driving solutions. It distinguishes itself with an AI-powered digital twin creation capability, offering a meticulously optimized sensor simulation environment that guarantees reproducibility and determinism. The adaptable architecture of aiSim allows seamless integration with existing industry toolchains, significantly minimizing the need for costly real-world testing.\n\nOne of the key features of aiSim is its capability to simulate various challenging weather conditions, enhancing testing accuracy across diverse environments. This includes scenarios like snowstorms, heavy fog, and rain, with sensors simulated based on physics, offering changes in conditions in real-time. Its certification with ISO 26262 ASIL-D attests to its automotive-grade quality and reliability, providing a new standard for testing high-fidelity sensor data in varied operational design domains.\n\nThe flexibility of aiSim is further highlighted through its comprehensive SDKs and APIs, which facilitate smooth integration into various systems under test. Additionally, users can leverage its extensive 3D asset library to establish detailed, realistic testing environments. AI-based rendering technologies underpin aiSim's data simulation, achieving both high efficiency and accuracy, thereby enabling rapid and effective validation of advanced driver assistance and autonomous driving systems.
A2e's H.264 FPGA Encoder and CODEC Micro Footprint Cores provide a customizable solution targeting FPGAs. Known for its small size and rapid execution, the core supports 1080p60 H.264 Baseline with a singular core, making it one of the industry's swiftest and most efficient FPGA offerings. The core is compliant with ITAR, offering options to adjust pixel depths and resolutions according to specific needs. Its high-performance capability includes offering a latency of just 1ms at 1080p30, which is crucial for applications demanding rapid processing speeds. This licensable core is ideal for developers needing robust video compression capabilities in a compact form factor. The H.264 cores can be finely tuned to meet unique project specifications, enabling developers to implement varied pixel resolutions and depths, further enhancing the core's versatility for different application requirements. With a licensable evaluation option available, prospective users can explore the core’s functionalities before opting for full integration. This flexibility makes it suitable for projects demanding customizable compression solutions without the burden of full-scale initial commitment. Furthermore, A2e provides comprehensive integration and custom design services, allowing these cores to be seamlessly absorbed into existing systems or developed into new solutions. This support ensures minimized risk and accelerated project timelines, allowing developers to focus on innovation and efficiency in their video-centric applications.
ArrayNav harnesses adaptive antenna technology to enhance GNSS functionality, optimizing performance in environments with complex multichannel challenges. By leveraging various antennas, ArrayNav achieves enhanced sensitivity and coverage, significantly mitigating issues such as multipath fading. This results in greater positional accuracy even in dense urban environments known for signal interference. This adaptive approach presents an invaluable asset for automotive Advanced Driver Assistance Systems (ADAS), where high precision and rapid response times are critical. The improved antenna diversity offered by ArrayNav not only augments signal strength but also robustly rejects interference and jamming attempts, assuring consistent operation and accuracy. In terms of power efficiency, ArrayNav stands out by combining exceptional accuracy with reduced power needs, offering a flexible solution adaptable for both standalone and cloud-computing modes. This dual capability ensures that system designers have the optimal framework for developing customized solutions catering to specific application requirements. Overall, ArrayNav’s cutting-edge technology fosters improved GNSS operations by delivering enhanced sensitivity and accuracy, thereby meeting the stringent demands of modern automotive and navigation systems.
Featuring a shader architecture, the GSV3100 supports OpenGL ES 2.0 and 1.1, as well as OpenVG 1.1, for powerful 3D graphical processing. This IP is ideal for complex rendering tasks in applications requiring sophisticated graphics and animation. It efficiently integrates hardware processing pipelines to handle demanding graphics loads without compromising on performance or energy efficiency.
SMPTE ST 2110 is a sophisticated protocol designed to facilitate the transport of media over IP networks, commonly used in broadcast and professional AV settings. This IP solution enhances the ability to transmit a variety of media types such as video, audio, and ancillary data via IP, leveraging the modularity to achieve optimal resource efficiency. Supporting an array of sub-standards, including uncompressed video (ST 2110-20) and compressed video (ST 2110-22), this IP bolsters transmission quality and reliability, ensuring consistent system timing and seamless traffic shaping. With its robust support for both gateway and synthetic essence operations, SMPTE ST 2110 enables effective integration with legacy systems and ensures a future-ready setup for the transmission of high-quality media content over IP. The core is highly configurable, allowing users to tailor features according to specific broadcast requirements while maintaining resource efficiency. By utilizing only necessary RTL logic, it minimizes overhead while offering a versatile solution for both professional AV equipment and broadcast systems. Integrated into an ecosystem of proven interoperable standards, this IP ensures smooth transitions between digital and traditional workflows, establishing itself as a pivotal component in AV-over-IP infrastructures. The design includes capabilities to handle various media types, making it adaptable to different operational needs. Nextera’s SMPTE ST 2110 IP is supported by a comprehensive reference design project, inclusive of necessary drivers and control software, enabling rapid system prototyping and deployment. Customers benefit from a well-documented setup that fosters swift development cycles and reduces time-to-market, underpinned by Nextera's emphasis on sustained performance and innovation within IP media experiences.
Engineered by A2e Technologies, the JPEG FPGA Cores are designed to provide high-resolution JPEG Baseline functionality on FPGA platforms, capturing complexity in image compression with notable efficiency. These licensable cores are particularly adaptable for projects that require ITAR compliance and support true grayscale imagery, making them remarkably versatile for various visualization and imaging applications. Whether it's precision imaging or standard visualization, these cores optimize for clarity and performance. The JPEG FPGA Cores offer both encoding and decoding capabilities, expanding the range of use cases they can accommodate. This adaptability is pivotal for developers seeking to integrate robust image processing functionalities into their FPGA-based systems. With the offer of a low-cost evaluation license, A2e Technologies allows potential clients to assess capabilities and performance before full-scale adoption, ensuring the core meets project requirements. Additionally, A2e Technologies offers comprehensive support and integration services, empowering users to integrate these cores into existing designs seamlessly. This level of service minimizes risk and accelerates development timelines, enabling projects to scale efficiently and effectively according to unique needs.
The VIDIO 12G SDI FMC Daughter Card is an advanced development tool targeted at professionals aiming to harness the latest capabilities in broadcast video technology. This versatile card supports resolutions up to 4Kp60 and integrates seamlessly with a variety of AMD/Xilinx and Intel/Altera development boards, making it indispensable for high-performance video applications. Designed with scalability in mind, VIDIO addresses the need for multiple SDI and IP interfaces, operating at high data rates including 12G SDI. Its build quality, featuring top-notch components from Texas Instruments and robust connectors, ensures reliable performance even under demanding conditions. Moreover, the card's compatibility with various hardware platforms allows developers to engage with both SDI and Ethernet seamlessly, facilitating designs in applications such as IP Gateways, Format Converters, and Signal Extenders. A highlight of this product is its plug-and-play functionality, with no necessary software installation to get started, thus simplifying the development process. This card is key for field testing and proof-of-concept projects, with Intel selecting it for its reference designs. As a robust tool for video solutions development, the VIDIO SDI FMC Daughter Card stands out as a leading choice for engineers and developers alike.
The Heimdall platform is engineered for applications requiring low-resolution image processing and quick interpretation. It integrates image signal processing capabilities into a compact design, perfect for IoT applications where space and power consumption are constraints. The platform supports various image-related tasks including object detection and movement tracking. With a core image sensor of 64x64 pixels, Heimdall is optimized for environments where minor details are less critical. This makes it ideal for motion sensing, smart lighting, and automation systems where the understanding of space occupancy or movement is essential. The platform's energy-efficient design, capable of integrating energy-harvesting technology, ensures sustainable operation in remote and hard-to-reach locations. By providing rapid image interpretation, Heimdall supports quick decision-making processes crucial for smart infrastructure and security applications.
Bringing forth a new era of cost-efficient FPGA technology, the GateMate FPGA is designed for low- to mid-range applications. It stands out for its power efficiency and versatile application across industries such as telecommunications and automotive sectors. The GateMate FPGA utilizes a 28nm node process supplied by GlobalFoundries, ensuring quality and reliability in every unit. This FPGA is equipped to meet diverse application requirements, from advanced driver-assistance systems in the automotive industry to complex signal processing tasks in telecommunications. Its flexibility allows users to reconfigure the device according to evolving system demands, providing an adaptable and future-proof solution. With comprehensive toolchain support, the GateMate FPGA ensures ease of use for developers, offering daily builds and extensive resources for configuration and testing. This makes it an excellent choice for both industrial applications and educational purposes, backed by a supportive community and robust documentation.
Serving as a counterpart to the INAP375T, the INAP375R receives high-speed data over a single cable with similar capabilities. This receiver can handle video and audio data without errors, owing to its implementation of the error-correction protocol AShell. It supports flexible connectivity options, adapting to different video interfaces and data configurations required in modern infotainment systems within cars. The robust design ensures compatibility with older APIX devices, thereby delivering seamless integration in automotive communication networks.
The Platform-Level Interrupt Controller (PLIC) by Roa Logic is a comprehensive solution for managing interrupt signals in sophisticated and large-scale computing environments. Compatible with RISC-V platforms, it is fully parameterised and offers an efficient means to handle and prioritize multiple interrupt sources. The PLIC's design emphasizes scalability and flexibility, allowing developers to adapt the module for a wide range of system requirements. The PLIC supports a configurable number of interrupt sources, each with customizable priority levels. This enables a tailored approach to the handling of critical interrupts, ensuring that high-priority tasks receive immediate attention. It serves as an essential building block for systems that demand precise and reliable interrupt management, making it indispensable in complex processor environments. With its easy integration into existing RISC-V platforms, the PLIC provides a seamless upgrade to traditional interrupt controllers. Its high level of adaptability ensures that it can be calibrated to complement specific system architectures, enhancing performance in varied operational scenarios.
Badge 2D Graphics from BitSimNOW is a cutting-edge graphics module designed for Xilinx platforms. Boasting over 5 million units shipped, this graphics solution is recognized for its robustness and efficiency in handling 2D graphics rendering. It seamlessly manages graphics, text, and video applications, making it a versatile asset in the development of user interfaces and multimedia applications. This module is engineered to provide high-quality visuals in embedded systems, offering smooth rendering and vivid imagery that enhances user experience. Its lightweight and compact design ensure that it can be effortlessly integrated into various applications without burdening the system's resources. Developers leveraging Badge 2D Graphics benefit from its reliability and performance, ensuring that their applications deliver engaging and visually appealing user experiences across diverse platforms and devices.
The RegSpec tool is a sophisticated register specification utility designed to streamline the specification and implementation of register architecture. Typically utilized in the automation of CSR (Control Status Register) generation, RegSpec enhances workflow efficiency by providing an intuitive interface for managing and generating register files. This tool aids engineers in defining precise and compliant registers, crucial for a variety of development projects. By facilitating accurate implementation of register definitions, RegSpec supports consistent architecture specifications, thereby reducing development time and errors.
Active-HDL is a powerful Windows-based environment for FPGA design creation and simulation. It is tailored for team-centric development, providing an integrated design suite complete with HDL and graphical design tools. Supporting rapid design verification and debugging, Active-HDL ensures a smooth and efficient workflow for designers.
HES-DVM offers a comprehensive environment for hybrid verification and validation of SoC and ASIC designs, capable of handling up to 633 million ASIC gates. It supports bit-level simulation acceleration, hardware prototyping, and virtual modeling through advanced co-emulation. This platform is integral for developers requiring scalability and flexibility in design validation.
The INAP590T combines advanced transmission capabilities with cutting-edge security features like HDCP support. It facilitates the secure transmission of video and audio data, supporting high-definition multimedia interfaces. Aimed primarily at automotive infotainment systems, this transmitter offers scalable bandwidth options, ensuring that even with the transmission of multiple video streams, data integrity and speed are not compromised. Its ability to adapt to various transmission setups makes it a core component in the latest infotainment architectures.
The Racyics ABX Platform is an innovative solution designed to enhance ultra-low voltage operations using Adaptive Body Biasing (ABB) technology. By enabling operation at voltages as low as 0.4V, the platform helps compensate for variations in process, supply voltage, and temperature, ensuring efficient performance and energy usage. This platform is particularly suited for automotive applications, where it can achieve up to a 75% reduction in leakage power at high temperatures. Engineered to maximize performance, the ABX Platform leverages features such as standard cells and SRAM IP to deliver up to nine times the performance under ultra-low voltage operations. These technologies are underpinned by a robust implementation process that improves Power-Performance-Area (PPA) and guarantees reliable output. Moreover, the ABX Platform is silicon-proven and provides a straightforward turnkey solution that fits seamlessly into existing design flows. Its capabilities are backed by a user-friendly evaluation kit, enabling designers to achieve their required outcomes with minimal effort and high yield.
The INAP375T is a feature-rich transmitter designed for high-speed differential data transmission. It uses APIX2 technology, enabling efficient data transfer over a single twisted pair (STP) cable at speeds up to 3Gbps. This transmitter supports flexible frame configurations filled with video, audio, and data, adaptable to various automotive applications. The device incorporates advanced protocols such as AShell for safety-critical data transmission and offers backward compatibility with previous APIX versions, making it versatile for integrated into existing and new systems.
The MIPS Act offerings emphasize enabling real-time control scenarios critical for robotics and efficient vehicle systems. These compute solutions bring enhanced motor control capabilities, promoting efficiency through more compact, lighter motors that operate with increased responsiveness and precision. This line of processors offers a distinct advantage in robotic articulation and motor control by minimizing latency in control loops, ensuring precise movements essential for today’s automated systems. This product line supports digital power conversion, heightening energy efficiency through advanced power algorithms intended to maximize utilization and minimize loss within diverse motor-driven applications. Adding to the applications in energy management, the MIPS Act solutions include features to accurately manage and monitor battery usage, essential for enhancing the longevity and reliability of power systems. The Act Real-Time Compute Solutions focus on delivering unparalleled precision and efficiency with each function, ensuring that power-oriented systems manage operations effectively while integrating seamlessly with existing infrastructures. This is crucial for organizations seeking innovative ways to boost system performance and energy integrity within their automation endeavors.
TySOM Boards are a series of embedded system prototyping boards, featuring FPGAs at the core, including Xilinx Zynq and Microchip PolarFire SoC options. The boards support a wide range of industry-standard interfaces, making them versatile for rapid application development in areas like automotive, artificial intelligence, machine learning, and industrial automation.
HES Proto-AXI is a software package that, when combined with HES prototyping boards, provides a robust environment for rapid design prototyping or algorithm accelerator development. It offers a seamless design and testing framework that supports the rapid integration of designs, ensuring quick time-to-market for new products.
Designed to alleviate processing burdens from the CPU, the logiBITBLT provides a powerful 2D graphics acceleration solution, boosting graphic generation capabilities within AMD FPGA and Zynq 7000 SoC environments. It enables the development of visually appealing graphics while optimizing system performance, integral for modern graphical interfaces.
The GW5AS Motor Control solution from GOWIN Semiconductor stands out with its advanced current-loop control IP, ideal for implementing a field-oriented control (FOC) scheme for permanent magnet synchronous motors. This design leverages the GW5AS-25K FPGA solution, which integrates a high-performance Arm Cortex-M4 processor running at up to 288MHz coupled with a 25K LUT Arora-V FPGA. This union provides precise torque and speed control, making it well-suited for applications in CNC machinery, robotics, and various industrial sectors. The GW5AS system is distinguished by its multi-motor control capabilities and ultra-fast current-loop calculations, which result in exceptional real-time performance. The design showcases GOWIN Semiconductor's commitment to bringing industry-leading, high-performance motor control solutions to a variety of industrial applications.
The logiFDT integrates a configurable face tracking engine that identifies and tracks faces and features within video sequences in real-time. Offering full 3D head pose and gaze direction, this IP core is essential for applications in surveillance, automotive safety, and other systems requiring precise facial recognition and tracking capabilities.
The logiDROWSINE utilizes computer vision to detect driver drowsiness by analyzing facial movements through a camera. Optimized for AMD Zynq 7000 All Programmable SoC, this IP core provides crucial safety measures in automotive systems, identifying signs of fatigue to prevent potential accidents on the road.
The Eclipse Test Development Environment offers a holistic solution for the test, debug, and configuration of complex PCB systems utilizing JTAG standards. Designed to streamline the testing pipeline, it automates the generation of test patterns and supports in-system device programming and configuration tasks. Eclipse features an intuitive GUI, supporting schematic-based debugging and comprehensive digital fault coverage, thus shortening development cycles and reducing costs in system bring-up and manufacturing.
Join the world's most advanced semiconductor IP marketplace!
It's free, and you'll get all the tools you need to discover IP, meet vendors and manage your IP workflow!
No credit card or payment details required.
Join the world's most advanced AI-powered semiconductor IP marketplace!
It's free, and you'll get all the tools you need to advertise and discover semiconductor IP, keep up-to-date with the latest semiconductor news and more!
Plus we'll send you our free weekly report on the semiconductor industry and the latest IP launches!