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 is at the forefront of automotive simulation, providing a comprehensive environment for the validation and verification of ADAS and AD systems. This innovative simulator integrates AI and physics-based digital twin technology, creating an adaptable and realistic testing ground that accommodates diverse and challenging environmental scenarios. It leverages advanced sensor simulation capabilities to reproduce high fidelity data critical for testing and development. The simulator's architecture is designed for modularity, allowing seamless integration with existing systems through C++ and Python APIs. This facilitates a wide range of testing scenarios while ensuring compliance with ISO 26262 ASIL-D standards, which is a critical requirement for automotive industry trust. aiSim 5 offers developers significant improvements in testing efficiency, allowing for runtime performance adjustments with deterministic outcomes. Some key features of aiSim 5 include the ability to simulate varied weather conditions with real-time adaptable environments, a substantial library of 3D assets, and built-in domain randomization features through aiFab for synthetic data generation. Additionally, its innovative rendering engine, aiSim AIR, enhances simulation realism while optimizing computational resources. This tool serves as an ideal solution for companies looking to push the boundaries of ADAS and AD testing and deployment.
The H.264 FPGA Encoder and CODEC Micro Footprint Cores are versatile, ITAR-compliant solutions providing high-performance video compression tailored for FPGAs. These H.264 cores leverage industry-leading technology to offer 1080p60 H.264 Baseline support in a compact design, presenting one of the fastest and smallest FPGA cores available. Customizable features allow for unique pixel depths and resolutions, with particular configurations including an encoder, CODEC, and I-Frame only encoder options, making this IP adaptable to varied video processing needs. Designed with precision, these cores introduce significant latency improvements, such as achieving 1ms latency at 1080p30. This capability not only enhances real-time video processing but also optimizes integration with existing electronic systems. Licensing options are flexible, offering a cost-effective evaluation license to accommodate different project scopes and needs. Customization possibilities further extend to unique resolution and pixel depth requirements, supporting diverse application needs in fields like surveillance, broadcasting, and multimedia solutions. The core’s design ensures it can seamlessly integrate into a variety of platforms, including challenging and sophisticated FPGA applications, all while keeping development timelines and budgets in focus.
The ArrayNav Adaptive GNSS Solution ushers in an era of enhanced automotive navigation, leveraging advanced adaptive antenna technology. This solution expertly applies multiple antennas to increase antenna gain and diversity, offering substantial advancements in navigation precision and operational consistency within complex environments. By integrating array-based technology, ArrayNav is tailored to improve the sensitivity and coverage necessary for sophisticated automotive systems. ArrayNav's use of adaptive antennas translates to significant reductions in issues such as multipath fading, which often affects navigation accuracy in urban canyons. With these enhancements, the solution ensures more reliable performance, boosting accuracy even in challenging terrains or when faced with potential signal interference. This solution has been specifically engineered for applications that demand robustness and precision, such as automotive advanced driver-assistance systems (ADAS). By employing the ArrayNav technology, users can benefit from higher degrees of jamming resistance, leading to safer and more accurate navigation results across a broad range of environments.
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.
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.
The JPEG FPGA Cores, designed for high-resolution JPEG Baseline functionality, offer extensive support for true grayscale imaging. This ITAR-compliant, customizable core is geared towards FPGAs, providing a compact solution for efficient image processing across a range of resolutions and applications. These cores are adaptable, allowing customization in terms of pixel depth and image resolution to meet specific project demands, making them ideal for a variety of fields that rely on image compression. With a focus on seamless integration, these JPEG cores can be embedded into current systems without compromising performance or scalability. They are engineered to optimize both the quality and speed of image processing tasks, ensuring efficient handling of digital imaging demands with unparalleled reliability. Potential applications range from surveillance and medical imaging to industrial automation and consumer electronics, showcasing the core's versatility and capability to function across multiple domains. A low-cost evaluation license is available for developers seeking to gauge the performance and compatibility of these cores with their existing workflows, ensuring a strategic fit before committing to full deployment.
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.
The GateMate FPGA by Cologne Chip is a standout in the field of programmable logic, designed to deliver powerful performance at an affordable cost. This FPGA offers an ideal platform for a wide range of applications, driven by its highly customizable nature. Targeted at both newcomers and experienced engineers, the GateMate FPGA offers extensive integration capabilities with various applications and intellectual properties. A key highlight is its support for real-time data flow monitoring and streamlined debugging processes, made possible through features like an integrated logic analyzer. The GateMate FPGA is well supported by a robust set of development tools, including daily updated toolchains and evaluation board kits. These resources make it easier for developers to get started and enhance their design capabilities with minimal setup time. The flexibility and effectiveness of the GateMate FPGA are further demonstrated through its compatibility with the LiteX framework, allowing the creation of comprehensive FPGA-based systems. Integration with display and camera interfaces is streamlined with the GateMate FPGA's available GPIO connections, reducing the need for additional hardware. This supports a wide array of applications, from digital displays to sensor inputs, cementing the GateMate FPGA's position as a versatile tool in digital design and implementation.
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 ZIA Stereo Vision technology is crafted for applications that require depth perception and accurate distance measuring. Utilizing stereo vision algorithms, it excels in generating 3D data from dual-camera setups, which is crucial for robots, drones, and autonomous vehicles. By employing advanced disparity mapping techniques, this technology ensures high fidelity in spatial analysis, making it particularly effective in dynamic environments. Its integration optimizes tasks that need real-time 3D depth information, aiding navigation and object placement.
Badge 2D Graphics offers an advanced solution for 2D graphical displays, suitable for systems requiring comprehensive graphical representations. These graphics are developed for seamless integration into platforms such as Xilinx, showcasing exceptional versatility and reliability with more than 5 million units shipped. The product is highly adaptable, enabling varied graphical tasks and delivering consistent performance across applications. This graphics solution is engineered to support a multitude of functionalities, including video display, textual representation, and multimedia interfacing. It stands out in delivering high-performance visual processing, making it a preferred choice for systems where graphical display quality is essential. Designed with the flexibility to adapt to a variety of multimedia needs, Badge 2D Graphics ensures that visual representation in platforms is both vivid and contextually relevant. The robustness of this solution allows it to integrate smoothly with diverse operational architectures, enhancing the visual display capabilities of embedded systems and consumer products.
The INAP375R Receiver is a component of the APIX2 technology suite, tailored to meet the stringent demands of automotive infotainment systems. It supports bi-directional, high-speed data transfer over a single twisted pair cable, up to distances of 12 meters, offering flexibility for complex vehicle architectures. The receiver integrates advanced error correction protocols and supports RGB and LVDS video interfaces, making it ideal for high-definition display applications in vehicles.
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.
The INAP590T is a transmitter module embedded within the APIX3 framework, delivering unparalleled data transfer capabilities for high-resolution automotive display systems. It supports HDMI 1.4a video interface and integrates seamlessly with existing in-car networks. This module offers advanced features such as scalable bandwidth, cable adaptability, and error correction, making it a reliable choice for next-generation infotainment architectures.
HES-DVM is a hybrid verification and validation environment specifically crafted for complex SoC and ASIC designs. This sophisticated system supports designs up to 633 million ASIC gates and is capable of accelerating simulation at bit-level with features such as SCE-MI 2.1 transaction emulation, hardware prototyping, and virtual modeling. By leveraging the latest co-emulation technologies, HES-DVM allows designers to explore robust emulation strategies that dramatically improve verification speed without sacrificing detail or accuracy. The product provides a fully scriptable environment, enabling automation of various verification tasks, which is vital for managing large-scale projects efficiently. Its integration capabilities with multiple hardware platforms allow seamless connectivity between design tools and physical prototypes, fostering a fluid and dynamic design process. HES-DVM also plays a critical role in supporting hardware scalability and flexibility. This aids designers in adjusting their approach as projects evolve, addressing shifting demands without a total overhaul of the verification strategy. This adaptability ensures HES-DVM remains a cornerstone tool for leading-edge design verification workflows.
IMG DXS GPU is engineered to meet the needs of automotive and industrial applications where functional safety is paramount. Built on efficient PowerVR architecture, it ensures high-performance graphics rendering with a focus on reduced power consumption. The DXS technology supports comprehensive safety suites, catering to ADAS and digital cockpit applications, thereby addressing stringent automotive safety standards.
The INAP375T Transmitter is a high-speed data transmission solution specifically designed for the automotive industry. It employs the second generation APIX2 technology, which delivers high-speed differential data through a single twisted pair cable, supporting data rates up to 3Gbps. This transmitter can handle complex multimedia data like video and audio while maintaining robust error correction through the AShell protocol, ensuring reliable data communication within vehicles.
The Racyics® ABX Platform is a powerful technology cornerstone designed to enhance performance and reliability in integrated circuits operating at ultra-low voltages. Leveraging Adaptive Body Biasing (ABB), this platform supports operation down to 0.4V, ensuring device efficiency even under challenging process, voltage, and temperature variations. Particularly adept for automotive applications, it offers significant improvements such as up to 75% reduction in leakage power and enhancement of performance by up to 9X. This makes it an ideal solution for high-performance needs, providing reliable and predictable operation across diverse conditions.<br><br>Racyics® ABX FBB (Forward Body Biasing) optimizes the operation of devices by substantially improving performance metrics, offering a comprehensive solution for ultra-low voltage applications. Furthermore, its RBB (Reverse Body Biasing) functionality excels in minimizing power consumption, notably providing substantial benefits in automotive environments where power efficiency is paramount.<br><br>The platform is backed by a robust design flow that integrates seamlessly with various advanced technology nodes, supported by an expansive library of ABB-enabled standard cells and SRAM IPs. This ensures easy adoption and adaptability, promoting enhanced timing and power predictability across applications. Its proven silicon track record underscores its capability as a reliable turnkey solution that meets stringent automotive-grade requirements.
MIPS Act Real-Time Compute Solutions empower precise motor control and greater efficiency for robotics and physical AI systems. Designed to provide ultra-low latency control, these solutions are essential for real-time computing across various sectors including automotive and industrial automation. The Act line excels in executing closed-loop control for tasks demanding meticulous precision and reliability. This empowers seamless operation of actuators and motors, paving the way for smoother and more efficient autonomous activities. By delivering profound improvements in motor control and system efficiency, Act solutions significantly reduce operational costs and enhance performance, positioning them at the forefront of technological advancements in control systems for AI and robotics.
The Lotus 1 microcontroller centers around versatility and efficiency, representing a key offering from Cortus for a wide array of consumer markets. Built on a RISC-V architecture, Lotus 1 combines ultra-low power consumption with a compact form factor, making it a cost-effective solution for high-demand scenarios such as home appliances and smart consumer devices. It seamlessly integrates a suite of peripheral options, allowing developers to tailor its capabilities towards specific application requirements. One of the standout features of Lotus 1 is its adaptability across a diverse range of consumer electronics, underscoring its role as a multi-purpose microcontroller. This product is particularly beneficial for applications that necessitate a blend of performance and energy efficiency, enabling devices to operate longer and more autonomously without frequent recharging or maintenance. Moreover, the design of Lotus 1 places strong emphasis on interoperability, facilitating smooth embedding into existing systems and infrastructures. This makes it not only a powerful tool for new product developments but also an upgrade path for current technologies, ensuring longevity and relevance in the fast-evolving consumer electronics landscape.
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.
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