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.
The H.264 FPGA Encoder and CODEC Micro Footprint Cores from A2e Technologies are industry-leading solutions optimized for high-speed video encoding with minimal latency. Specially tailored for FPGA applications, this core ensures compliance with the H.264 Baseline and offers configurations to suit varying performance needs, such as low-cost evaluation licenses for flexibility. These cores are noted for their exceptionally compact size and rapid processing capabilities, enabling them to achieve 1080p at 60 frames per second with remarkable efficiency. One of the project's standout features is the 1ms latency at 1080p30, which is among the fastest in the industry. This core also supports custom configurations, allowing adjustments to pixel depth, resolution, and more, making it a versatile choice for developers looking to integrate video encoding in their systems. Moreover, these cores are ITAR compliant, offering a secure and adaptable solution for high-performance FPGA design. The scalability and customization options, including support for various pixel depths and resolutions, make these H.264 cores suitable for a wide array of applications, from real-time video streaming to embedded systems in industrial automation. By leveraging this advanced technology, A2e Technologies provides a robust solution that meets stringent industry standards and addresses specific customer needs effectively.
The Vantablack S-VIS coating is specifically tailored for space applications, where it serves a crucial role in suppressing stray light in optical systems and blackbody calibration of infrared camera systems. Its exceptionally high performance and spectrally flat absorption from the UV to the near-millimeter spectral range make it indispensable for ensuring accurate readings and operations in the challenging environment of space. One of the prominent applications of the S-VIS coating is in the reduction of launch weight for instruments, thanks to its ability to absorb light efficiently from all angles. This not only enhances the operation of devices like star trackers and optical calibration systems but also minimizes the overall size and complexity of these systems, offering significant cost savings. This coating has proven its reliability in harsh space conditions since its first deployment in low Earth orbit in 2015. Its capabilities in outgassing management and thermal stability are well-documented, making it a trusted solution for enhancing the operational longevity and performance of space missions.
Roa Logic's Platform-Level Interrupt Controller (PLIC) is a highly parameterized and configurable module that adheres to the RISC-V architecture, intended to manage interrupts in various system designs comprehensively. This component is a critical part of incorporating interactivity and responsiveness in embedded systems, handling a multitude of interrupt sources efficiently. The PLIC's compliance with the RISC-V standard ensures seamless integration into systems using this architecture, enabling straightforward implementation and management of interrupt-related functionality. Its flexible design allows users to customize the number of supported interrupts according to specific needs, making it adaptable to a wide range of applications, from small embedded devices to more complex multicore systems. Overall, Roa Logic’s PLIC offers a scalable solution for systems designers, providing the necessary configurability to tailor the interrupt handling according to platform-specific requirements. Its open-access policy for non-commercial applications further encourages experimentation and innovation within the RISC-V ecosystems.
Digital Media Professionals offers ZIA Stereo Vision, a robust solution for achieving high-accuracy depth estimation through stereoscopic imaging. Suited for applications in robotics and automated systems, ZIA SV deploys a sophisticated semi-global matching algorithm to derive reliable distance measurements from stereo camera inputs. This IP core excels in pre-processing and post-processing steps to optimize depth map accuracy. By supporting grayscale images of up to 8-bit depth and providing detailed disparity maps, it forms the backbone for various machine vision tasks. Built with efficiency in mind, ZIA SV supports AMBA AXI4 interface, ensuring seamless integration within high throughput data environments. Ideal for autonomous navigation systems, ZIA SV facilitates accurate real-time depth perception. This capability, combined with its minimal resource footprint, makes it a preferred choice for compact, power-sensitive applications needing reliable stereo vision processing.
The SMPTE ST 2110 set of IP cores enables broadcast and professional AV equipment to transmit or receive professional media across IP networks. The suite includes components that facilitate system timing, uncompressed active video transmission, traffic shaping, and compression management. The modular and configurable design minimizes resource use by employing only necessary RTL logic. ST 2110 standards, such as -10, -20, -21, -22, -30, -31, and -40, cover everything from managing system timing to handling ancillary data, providing robust support for gateways and synthetic essence operations. The suite's flexibility ensures media flows smoothly in IP environments, allowing for seamless media exchanges. Proven efficient and industry-standard, these IP cores help create a baseline for video-over-IP operations, continuing to promote interoperability and integration in networked media systems.
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.
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 Universal Drive Controller is an innovative IP core tailored for comprehensive motor control, offering functionality for DC, brushless, and stepper motors, including trajectory planning. Designed to eliminate the need for additional drive controller chips, this IP significantly reduces both the project bill of materials and the time to market. With support for various motor types, the Universal Drive Controller achieves autonomous control with minimal CPU load, thanks to its integrated control loops. Key features include the ability to manage up to eight drives per controller and the option to run multiple PID control loops for each drive at high frequencies. This adaptability ensures precise motor management across diverse applications. The IP core simplifies development with its industry-standard AXI-4 interface, enabling smooth integration with existing vendor tools. Applications extend into various sectors including robotics, medical diagnostics, and automation, where reliable motion control is critical. The Universal Drive Controller's modular nature supports reconfigurability and offers multiple customization options, further underlining its utility and relevance across different industries.
The VibroSense AI Chip is a cutting-edge solution designed for vibration analysis in Industrial IoT applications. It is based on the Neuromorphic Analog Signal Processor, which preprocesses raw sensor data, significantly reducing the amount of data to be stored and transmitted. This chip is particularly beneficial in predictive maintenance applications, where it helps in the early detection of potential machinery failures by analyzing vibrations generated by industrial equipment. VibroSense excels in overcoming the traditional challenges linked to data processing for condition monitoring systems. By performing data preprocessing at the sensor level, it minimizes data volumes by a thousand times or more, making it feasible to conduct condition monitoring over narrow-bandwidth communications and at lower operational costs. This ensures industrial operations can identify issues like bearing wear or imbalance effectively, ultimately extending equipment life and improving safety. The implementation of VibroSense's neural network architecture enables it to handle complex vibration signals with high accuracy. It supports energy-efficient designs, providing a compelling solution for industries aiming to optimize maintenance operations without increasing their OPEX. Its ease of integration with standard sensor nodes and support for energy harvesting applications further enhances its market appeal.
The Badge 2D Graphics module is a dynamic component used extensively in graphics-intensive applications, having shipped over 5 million units. It's designed for seamless integration into multimedia systems, providing stellar performance in handling graphical data and enhancing visual displays. This graphics module supports diverse functionalities, including efficient rendering of graphics, text, and video content, making it versatile for use in a wide array of products that demand high-quality graphical outputs. The Badge 2D Graphics module is particularly beneficial for systems requiring enhanced visual interfaces while ensuring resource-efficient operation. As part of BitsimNOW's IP offerings, this module exemplifies the company's strength in high-volume, quality graphics solutions. Its capabilities make it a preferred choice for industries looking to elevate their product’s user interface experience with reliable and sophisticated graphics technology.
VeriSyno's Digital Systems and Security Solutions focus on ensuring high-performance operations within digital frameworks while emphasizing secure data management. These solutions cover a vast array of applications, from memory controller interfaces and network solutions to advanced security protocols. The goal is to provide digital systems that are not only efficient but also robust against modern security challenges. These digital IP components, including network IP solutions like vMAC, attend to contemporary issues by integrating AI and authentication technologies. Such innovations are designed to meet the security demands of today’s digital landscape, empowering enterprises with reliable solutions that safeguard data while optimizing performance. By offering these advanced digital components, VeriSyno empowers industries such as finance, healthcare, and IT with crucial IP that enhances data processing capabilities and secures operational integrity. Their security solutions are instrumental in facilitating secure and efficient operations in a variety of digital environments.
The HEIMDALL IP platform is engineered for smart low-resolution image processing, specifically designed for rapid image interpretation. It finds applications in object detection, motion interpretation, and is suitable for integration in IoT and industrial scenarios. HEIMDALL features low image resolution processing capabilities merged with advanced image signal processing to classify content efficiently. Its compact design facilitates adoption in an array of smart technologies that require ambient light detection and energy-efficient operation.
Engineered for the digital processing and enhancement of video inputs, the logiISP-UHD Image Signal Processing UltraHD Pipeline offers sophisticated processing capabilities for Ultra High Definition video, including 4K2Kp60 support. It is specifically designed for embedded systems leveraging AMD's Zynq UltraScale+ MPSoC, Zynq 7000 AP SoC, Series 7, and newer FPGA devices.<br><br>This IP core is tailored for scenarios requiring elevated image quality and real-time processing, making it indispensable in modern high-definition video environments. It is highly suitable for broadcast applications, security systems, and any system necessitating enhanced visual clarity and video fidelity.<br><br>The logiISP-UHD stands out by streamlining complex video processing tasks, providing designers with the tools needed to significantly elevate image quality within their applications. By ensuring high-quality video outputs under varying conditions, the IP core supports the creation of superior embedded video solutions.
This comprehensive framework is designed for embedding multi-camera vision systems utilizing AMD's Versal Adaptive Compute Acceleration Platform (ACAP). The logiREF-ACAP-MULTICAM-ISP HDR Image Signal Processing Framework provides extensive capabilities for integrating multi-camera inputs into a cohesive video processing system.<br><br>Particularly aimed at industries requiring high-definition video input handling, this framework expedites the development of multi-camera systems in automotive, surveillance, and industrial applications. It supports HDR image processing, ensuring that each camera input is optimized for clarity and detail.<br><br>The framework's versatility and robustness make it a go-to solution for developers looking to leverage AMD's ACAP platform, promoting efficiency and innovation in advanced video processing tasks. It provides users with the tools needed to take full advantage of modern imaging technology.
The logiREF-ACAP-VDF is a complete IP design framework that supports the development of embedded multi-camera vision systems using AMD Versal Adaptive SoC. It is tailor-made to work with the logiVID-ACAP-6CAM vision kit, providing a pre-verified reference design that significantly reduces project development time.<br><br>Ideal for applications in advanced driver assistance systems (ADAS), robotics, and machine vision, the framework helps users focus on vision-specific areas rather than starting from scratch. The framework also includes display and LIDAR visualization capabilities, enhancing its utility in complex vision systems.<br><br>With the logiREF-ACAP-VDF framework, users can achieve a higher degree of integration efficiency, ensuring that advanced vision systems are developed swiftly, aligning with modern technological demands and project timelines.
The logiHOG employs advanced HOG/SVM techniques for multiple object detection within video streams, providing effective and accurate real-time image classification capabilities suited for surveillance and security systems.
The logiHDR High Dynamic Range Pipeline is designed to enhance camera image quality by extracting maximum detail from high-contrast scenes, such as objects illuminated by direct sunlight or placed in extreme shadow. Supporting Ultra High Definition (UHD) video, including 4K2Kp60, this pipeline is tailored for applications requiring superior image quality in challenging lighting conditions.<br><br>It excels in scenarios where image detail accuracy is critical, making it ideal for advanced photography, cinematography, and industrial imaging where visual precision significantly impacts outcomes. The logiHDR pipeline is an asset for any high-end video processing application that values detail and dynamic range.<br><br>By facilitating exceptional image capturing capabilities, the logiHDR pipeline enables users to maintain high performance and image quality, even in environments where lighting variations can affect visual clarity. The technology ensures that every scene is captured with the richness and nuance required for professional-grade imaging.
The logiREF-MULTICAM-ISP HDR ISP Framework provides a comprehensive platform for developing multi-camera systems with HDR capabilities. Designed to manage the full spectrum of Ultra HD video inputs, it supports applications ranging from entry-level AMD Artix FPGAs to advanced AMD Versal adaptive devices.<br><br>The framework's main aim is to simplify and optimize the complicated process of managing multiple camera inputs, specifically emphasizing image signal processing and HDR enhancements. This makes it suitable for automotive, industrial, and surveillance systems that require advanced input handling and video fidelity.<br><br>Leveraging this IP framework enables developers to streamline the integration of multi-camera setups into their systems, ensuring efficient and reliable operation of high-definition video environments. It represents a key tool for those seeking to push the boundaries of traditional video processing solutions.
The logiBITBLT is a high-efficiency Bit Block Transfer (BLT) 2D graphics accelerator designed for AMD's FPGA and Zynq 7000 AP SoCs. It alleviates computational burdens from the system CPU by handling intensive graphics tasks, enabling enhanced and effective graphic creation.<br><br>This IP core is targeted at applications seeking to deliver engaging visual experiences, such as consumer electronics interfaces and media-rich devices, where rendering speed and quality are essential. It effectively complements the hardware, offering a solution that enhances overall visual performance.<br><br>Incorporating the logiBITBLT accelerator results in smoother operations and heightened graphics capabilities, setting new standards for 2D graphical processing in embedded systems. It empowers system designers to generate sophisticated graphics without sacrificing system performance.
The logiVDET represents advanced capabilities in object classification to detect vehicles accurately within video streams, thus becoming an essential component for traffic management and surveillance systems, enhancing vehicular detection accuracy and system response times.
The HiSpeedKit-HS Platform is designed to facilitate the verification of high-speed interfaces within systems on chips (SoCs). This platform aids in ensuring that SoCs can efficiently manage high-speed data transmission across various interfaces, thus enhancing the devices' overall performance. By incorporating robust testing environments, HiSpeedKit-HS verifies the reliability and efficiency of these high-speed connections, enabling engineers to address potential integration challenges proactively. This platform not only accelerates the development process but also significantly reduces the time to market by ensuring final product reliability.
The logiFDT IP core is an advanced face detection and tracking engine that performs real-time facial recognition, tracking head position, gaze direction, and other key facial features. Optimized for the AMD Zynq 7000 SoC, this versatile core provides comprehensive data ideal for applications in security, user interface enrichment, and interactive systems, enabling sophisticated face-driven controls and interactions. By implementing logiFDT, systems can analyze and respond to user presence and engagement with precision.
The logiDROWSINE is a cutting-edge computer vision IP core designed for detecting driver drowsiness through facial movement analysis in vehicle environments. Optimized for AMD platforms, it is a foundational component in developing advanced driver monitoring systems. This innovative technology utilizes camera data to monitor drivers' attention levels and fatigue, providing real-time alerts and interventions to enhance road safety.
VibroSense for Tire Monitoring is an innovative ultra-low-power chip designed to address the gap in current vehicle safety by providing real-time monitoring of tire-road friction. Integrated with standard TPMS systems, this chip enhances ADAS systems by making dynamic road condition feedback possible without relying on indirect and inaccurate friction estimations. By processing data at the sensor level, VibroSense reduces wireless communication overhead, allowing for efficient use of standard battery power or energy harvesting solutions. This chip acts as the missing component in comprehensive vehicle safety, greatly improving the in-tire detection of friction changes, which is critical for maintaining vehicle stability and safety. The precise monitoring of peak friction coefficients allows vehicles equipped with ADAS to respond quicker to road surface changes, contributing to shorter stopping distances and better overall handling. Beyond traditional tire pressure monitoring, VibroSense offers additional functionalities such as tire tread wear analysis and wheel imbalance and loose nut detection. These capabilities make it a vital component in next-generation smart tire solutions, offering vehicle manufacturers a strong competitive advantage in safety and reliability innovations.
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!