All IPs > Graphic & Peripheral > GPU
Graphics Processing Units (GPUs) have revolutionized the way we interact with digital content, making it more immersive and visually engaging. At the core of modern graphics technology lies GPU semiconductor IPs, which are integral to delivering outstanding visual performance across a wide array of devices. Whether it’s for rendering the latest video game graphics, enhancing multimedia playback, or powering complex computational tasks, these semiconductor IPs play a crucial role.
GPU semiconductor IPs are designed to efficiently handle a myriad of operations, predominantly focusing on parallel processing. This capability allows GPUs to process multiple tasks simultaneously, making them ideal for graphics rendering, high-definition video playback, and complex simulations. This category includes essential components like shaders, compute engines, and video encoders, which work in harmony to deliver seamless graphics experience.
Products within the GPU semiconductor IP category serve a diverse range of industries. In consumer electronics, GPUs are deployed in smartphones and tablets to enhance user interfaces and enable applications like augmented reality. In high-performance computing, they are an essential part of servers and workstations for tasks such as artificial intelligence, machine learning, and big data analytics. Furthermore, the gaming industry benefits from these semiconductor IPs by providing photorealistic graphics and smooth gameplay.
Selecting the right GPU semiconductor IP can significantly impact the performance and efficiency of the final product. With the rapid advancement of display technologies and the increasing demand for richer visual content, developers and manufacturers seek the most innovative and adaptable GPU IP solutions to remain competitive. By incorporating cutting-edge semiconductor IPs, they can deliver the next generation of visually stunning and energy-efficient products.
The KL730 is a third-generation AI chip that integrates advanced reconfigurable NPU architecture, delivering up to 8 TOPS of computing power. This cutting-edge technology enhances computational efficiency across a range of applications, including CNN and transformer networks, while minimizing DDR bandwidth requirements. The KL730 also boasts enhanced video processing capabilities, supporting 4K 60FPS outputs. With expertise spanning over a decade in ISP technology, the KL730 stands out with its noise reduction, wide dynamic range, fisheye correction, and low-light imaging performance. It caters to markets like intelligent security, autonomous vehicles, video conferencing, and industrial camera systems, among others.
The Akida 2nd Generation represents a leap forward in the realm of AI processing, enhancing upon its predecessor with greater flexibility and improved efficiency. This advanced neural processor core is tailored for modern applications demanding real-time response and ultra-low power consumption, making it ideal for compact and battery-operated devices. Akida 2nd Generation supports various programming configurations, including 8-, 4-, and 1-bit weights and activations, thus providing developers with the versatility to optimize performance versus power consumption to meet specific application needs. Its architecture is fully digital and silicon-proven, ensuring reliable deployment across diverse hardware setups. With features such as programmable activation functions and support for sophisticated neural network models, Akida 2nd Generation enables a broad spectrum of AI tasks. From object detection in cameras to sophisticated audio sensing, this iteration of the Akida processor is built to handle the most demanding edge applications while sustaining BrainChip's hallmark efficiency in processing power per watt.
The Akida IP is an advanced processor core designed to mimic the efficient processing characteristics of the human brain. Inspired by neuromorphic engineering principles, it delivers real-time AI performance while maintaining a low power profile. The architecture of the Akida IP is sophisticated, allowing seamless integration into existing systems without the need for continuous external computation. Equipped with capabilities for processing vision, audio, and sensor data, the Akida IP stands out by being able to handle complex AI tasks directly on the device. This is done by utilizing a flexible mesh of nodes that efficiently distribute cognitive computing tasks, enabling a scalable approach to machine learning applications. Each node supports hundreds of MAC operations and can be configured to adapt to various computational requirements, making it a versatile choice for AI-centric endeavors. Moreover, the Akida IP is particularly beneficial for edge applications where low latency, high efficiency, and security are paramount. With capabilities for event-based processing and on-chip learning, it enhances response times and reduces data transfer needs, thereby bolstering device autonomy. This solidifies its position as a leading solution for embedding AI into devices across multiple industries.
The AI Camera Module from Altek is a versatile, high-performance component designed to meet the increasing demand for smart vision solutions. This module features a rich integration of imaging lens design and combines both hardware and software capacities to create a seamless operational experience. Its design is reinforced by Altek's deep collaboration with leading global brands, ensuring a top-tier product capable of handling diverse market requirements. Equipped to cater to AI and IoT interplays, the module delivers outstanding capabilities that align with the expectations for high-resolution imaging, making it suitable for edge computing applications. The AI Camera Module ensures that end-user diversity is meaningfully addressed, offering customization in device functionality which supports advanced processing requirements such as 2K and 4K video quality. This module showcases Altek's prowess in providing comprehensive, all-in-one camera solutions which leverage sophisticated imaging and rapid processing to handle challenging conditions and demands. The AI Camera's technical blueprint supports complex AI algorithms, enhancing not just image quality but also the device's interactive capacity through facial recognition and image tracking technology.
Chimera GPNPU is engineered to revolutionize AI/ML computational capabilities on single-core architectures. It efficiently handles matrix, vector, and scalar code, unifying AI inference and traditional C++ processing under one roof. By alleviating the need for partitioning AI workloads between different processors, it streamlines software development and drastically speeds up AI model adaptation and integration. Ideal for SoC designs, the Chimera GPNPU champions an architecture that is both versatile and powerful, handling complex parallel workloads with a single unified binary. This configuration not only boosts software developer productivity but also ensures an enduring flexibility capable of accommodating novel AI model architectures on the horizon. The architectural fabric of the Chimera GPNPU seamlessly blends the high matrix performance of NPUs with C++ programmability found in traditional processors. This core is delivered in a synthesizable RTL form, with scalability options ranging from a single-core to multi-cluster designs to meet various performance benchmarks. As a testament to its adaptability, the Chimera GPNPU can run any AI/ML graph from numerous high-demand application areas such as automotive, mobile, and home digital appliances. Developers seeking optimization in inference performance will find the Chimera GPNPU a pivotal tool in maintaining cutting-edge product offerings. With its focus on simplifying hardware design, optimizing power consumption, and enhancing programmer ease, this processor ensures a sustainable and efficient path for future AI/ML developments.
The KL630 is a pioneering AI chipset featuring Kneron's latest NPU architecture, which is the first to support Int4 precision and transformer networks. This cutting-edge design ensures exceptional compute efficiency with minimal energy consumption, making it ideal for a wide array of applications. With an ARM Cortex A5 CPU at its core, the KL630 excels in computation while maintaining low energy expenditure. This SOC is designed to handle both high and low light conditions optimally and is perfectly suited for use in diverse edge AI devices, from security systems to expansive city and automotive networks.
The KL520 marks Kneron's foray into the edge AI landscape, offering an impressive combination of size, power efficiency, and performance. Armed with dual ARM Cortex M4 processors, this chip can operate independently or as a co-processor to enable AI functionalities such as smart locks and security monitoring. The KL520 is adept at 3D sensor integration, making it an excellent choice for applications in smart home ecosystems. Its compact design allows devices powered by it to operate on minimal power, such as running on AA batteries for extended periods, showcasing its exceptional power management capabilities.
The KL530 represents a significant advancement in AI chip technology with a new NPU architecture optimized for both INT4 precision and transformer networks. This SOC is engineered to provide high processing efficiency and low power consumption, making it suitable for AIoT applications and other innovative scenarios. It features an ARM Cortex M4 CPU designed for low-power operation and offers a robust computational power of up to 1 TOPS. The chip's ISP enhances image quality, while its codec ensures efficient multimedia compression. Notably, the chip's cold start time is under 500 ms with an average power draw of less than 500 mW, establishing it as a leader in energy efficiency.
The PDM-to-PCM Converter from Archband Labs leads in transforming pulse density modulation signals into pulse code modulation signals. This converter is essential in applications where high fidelity of audio signal processing is vital, including digital audio systems and communication devices. Archband’s solution ensures accurate conversion, preserving the integrity and clarity of the original audio. This converter is crafted to seamlessly integrate with a wide array of systems, offering flexibility and ease-of-use in various configurations. Its robust design supports a wide range of input frequencies, making it adaptable to different signal environments. The PDM-to-PCM Converter also excels in minimizing latency and reducing overhead processing times. It’s engineered for environments where precision and sound quality are paramount, ensuring that audio signals remain crisp and undistorted during conversion processes.
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.
RAIV represents Siliconarts' General Purpose-GPU (GPGPU) offering, engineered to accelerate data processing across diverse industries. This versatile GPU IP is essential in sectors engaged in high-performance computing tasks, such as autonomous driving, IoT, and sophisticated data centers. With RAIV, Siliconarts taps into the potential of the fourth industrial revolution, enabling rapid computation and seamless data management. The RAIV architecture is poised to deliver unmatched efficiency in high-demand scenarios, supporting massive parallel processing and intricate calculations. It provides an adaptable framework that caters to the needs of modern computing, ensuring balanced workloads and optimized performance. Whether used for VR/AR applications or supporting the back-end infrastructure of data-intensive operations, RAIV is designed to meet and exceed industry expectations. RAIV’s flexible design can be tailored to enhance a broad spectrum of applications, promising accelerated innovation in sectors dependent on AI and machine learning. This GPGPU IP not only underscores Siliconarts' commitment to technological advancement but also highlights its capability to craft solutions that drive forward computational boundaries.
The KL720 AI SoC is designed for optimal performance-to-power ratios, achieving 0.9 TOPS per watt. This makes it one of the most efficient chips available for edge AI applications. The SOC is crafted to meet high processing demands, suitable for high-end devices including smart TVs, AI glasses, and advanced cameras. With an ARM Cortex M4 CPU, it enables superior 4K imaging, full HD video processing, and advanced 3D sensing capabilities. The KL720 also supports natural language processing (NLP), making it ideal for emerging AI interfaces such as AI assistants and gaming gesture controls.
The GH310 offers high-performance 2D sprite graphics capabilities with an emphasis on pixel throughput and minimal gate count. This makes it an excellent choice for applications that require rapid sprite rendering and high pixel density, such as user interfaces and gaming devices. Its optimized architecture supports efficient sprite operations, making it a versatile choice for embedded 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.
The RayCore MC is a revolutionary real-time path and ray-tracing GPU designed to enhance rendering with minimal power consumption. This GPU IP is tailored for real-time applications, offering a rich graphical experience without compromising on speed or efficiency. By utilizing advanced ray-tracing capabilities, RayCore MC provides stunning visual effects and lifelike animations, setting a high standard for quality in digital graphics. Engineered for scalability and performance, RayCore MC stands out in the crowded field of GPU technologies by delivering seamless, low-latency graphics. It is particularly suited for applications in gaming, virtual reality, and the burgeoning metaverse, where realistic rendering is paramount. The architecture supports efficient data management, ensuring that even the most complex visual tasks are handled with ease. RayCore MC's architecture supports a wide array of applications beyond entertainment, making it a vital tool in areas such as autonomous vehicles and data-driven industries. Its blend of power efficiency and graphical prowess ensures that developers can rely on RayCore MC for cutting-edge, resource-light graphic solutions.
The GV380 is a 2D vector graphics GPU optimized for low CPU load and enhanced pixel processing. It conforms to the OpenVG 1.1 standard, making it ideal for applications requiring high-quality vector graphics rendering. This IP enables efficient graphic processing for embedded systems, ensuring that even resource-limited environments can enjoy sophisticated graphical interfaces.
GSHARK is part of the TAKUMI line of GPU IPs known for its compact size and ability to richly enhance display graphics in embedded systems. Developed for devices like digital cameras, this IP has demonstrated an extensive record of reliability with over a hundred million units shipped. The proprietary architecture offers exceptional performance with low power usage and minimal CPU demand, enabling high-quality graphics rendering typical of PCs and smartphones.
The ISPido on VIP Board is tailored specifically for Lattice Semiconductor's Video Interface Platform (VIP) and is designed to achieve clear and balanced real-time imaging. This ISPido variant supports automatic configuration options to provide optimal settings the moment the board is powered on. Alternatively, users can customize their settings through a menu interface, allowing for adjustments such as gamma table selection and convolutional filtering. Equipped with the CrossLink VIP Input Bridge, the board features dual Sony IMX 214 image sensors and an ECP5 VIP Processor. The ECP5-85 FPGA ensures reliable processing power while potential outputs include HDMI in YCrCb 4:2:2 format. This flexibility ensures users have a complete, integrated solution that supports runtime calibration and serial port menu configuration, making it an extremely practical choice for real-time applications. The ISPido on VIP Board is built to facilitate seamless integration and high interoperability, making it a suitable choice for those engaged in designing complex imaging solutions. Its adaptability and high-definition support make it particularly advantageous for users seeking to implement sophisticated vision technologies in a variety of industrial applications.
ELFIS2 is a sophisticated visible light imaging ASIC designed to deliver superior performance under the extreme conditions typical in space. Known for its radiation hard design, it withstands both total ionizing dose (TID) and single event effects (SEU/SEL), ensuring dependable operation even when exposed to high radiation levels in outer space. This image sensor features HDR (High Dynamic Range) capabilities, which allow it to capture clear, contrast-rich images in environments with varying light intensities, without motion artifacts thanks to its Motion Artifact Free (MAF) technology. Additionally, its global shutter ensures that every pixel is exposed simultaneously, preventing distortion in high-speed imaging applications. Utilizing back-side illumination (BSI), the ELFIS2 achieves superior sensitivity and quantum efficiency, making it an ideal choice for challenging lighting conditions. This combination of advanced features makes the ELFIS2 particularly well-suited for scientific and space-based imaging applications requiring exacting standards.
The Mixed-Signal CODEC offered by Archband Labs integrates advanced analog and digital audio processing to deliver superior sound quality. Designed for a variety of applications such as portable audio devices, automotive systems, and entertainment systems, this CODEC provides efficiency and high performance. With cutting-edge technologies, it handles complex signal conversions with minimal power consumption. This CODEC supports numerous interface standards, making it a versatile component in numerous audio architectures. It's engineered to offer precise sound reproduction and maintains audio fidelity across all use cases. The integrated components within the CODEC streamline design processes and reduce the complexity of audio system implementations. Furthermore, the Mixed-Signal CODEC incorporates features that support high-resolution audio, ensuring compatibility with high-definition sound systems. It's an ideal choice for engineers looking for a reliable and comprehensive audio processing solution.
The TW330 distortion correction IP is tailored for use in applications requiring dynamic image transformations, such as VR headsets and automotive HUDs. Utilizing GPU-powered technologies, it offers real-time coordinate transformations, distortion corrections, and other modifications up to a resolution of 16K x 16K in both RGB and YUV formats. This IP is crucial for enhancing visual accuracy and display adaptability across varied markets.
The Universal DSP Library is designed to simplify digital signal processing tasks within FPGA systems. This extensive collection of DSP algorithms and functions allows for efficient development and deployment of signal processing applications. Users can leverage this library to handle complex computations swiftly, making it perfect for industries requiring real-time processing power. It streamlines development by offering pre-tested routines that developers can integrate into their systems without extensive customization.
The Trifecta-GPU offers cutting-edge graphics processing capabilities designed for high-efficiency computing needs. This PXIe/CPCIe module excels in handling intensive tasks across various applications, including signal processing, modular test and measurement, and electronic warfare systems. Built to deliver robust performance, it incorporates advanced GPU technology to ensure rapid data throughput and high computational capability. With a focus on versatility, the Trifecta-GPU seamlessly integrates with existing hardware setups, aiding in the enhancement of system performance through its powerful data handling skills. It is particularly well-suited for environments that demand precise data analysis and execution speed, such as AI and machine learning inference tasks. Its inclusion in RADX's product lineup signifies its importance in providing comprehensive solutions tailored for demanding industrial and research applications. Moreover, this module supports various applications, empowered by its substantial memory bandwidth, and possesses innovative architecture designed to optimize processing power. The Trifecta-GPU is an integral component within RADX’s lineup designed to offer flexibility and power efficiency in equal measure, making it well-suited for future-tech applications that necessitate high-performance standards.
The Hyperspectral Imaging System developed by Imec is designed to capture images across numerous wavelengths, enabling detailed analysis of spectral information beyond conventional imaging. This hyperspectral imaging technology is pivotal in extracting valuable insights in fields such as precision agriculture, environmental monitoring, and industrial inspection. With its versatile applications, it offers enhanced capabilities in material identification, chemical analysis, and quality control processes. This system incorporates state-of-the-art sensors that capture data with high spectral and spatial resolution, providing a comprehensive spectral fingerprint of the imaged scene. It excels in distinguishing subtle differences in material properties by analyzing the light reflected from different surfaces across various spectral bands. By using this advanced imaging system, users can perform complex analyses such as vegetation monitoring, pollution detection, and mineral mapping with unprecedented precision. It allows for non-destructive testing, which is crucial for industries like food safety, pharmaceutical production, and environmental science.
The logiCVC-ML is a compact multilayer video controller tailored for advanced display control of TFT LCD displays, offering resolutions up to 2048x2048. It is particularly optimized for implementation within AMD Zynq 7000 AP SoC and FPGA platforms. This IP core supports multiple operating systems, including Linux, Android, and Windows Embedded Compact 7, thereby fostering a versatile application landscape for system designers.
The DB9000AXI Display Controller is engineered to interface with Frame Buffer Memory through the AMBA AXI Protocol, connecting seamlessly to display panels with variable resolutions from QVGA up to full HD, with options for 4K and 8K enhancements. This versatile controller is crafted to manage a broad spectrum of display resolutions, and advanced versions integrate complex composition features like overlay windows, hardware cursor, and color space conversion. An emphasis is placed on blending and resizing, making it particularly suitable for high-definition display projects.
The Origin E1 is a compact yet powerful neural processing unit (NPU) designed for low-power applications in home appliances, smartphones, and security cameras. Specially tailored for always-on functions, the E1 offers unmatched power efficiency by utilizing Expedera's innovative packet-based architecture. This allows it to execute multiple layers in parallel, ensuring the optimal balance of performance and resource utilization. Engineered to operate with minimal to no external memory, the Origin E1 is ideal for cost-effective and area-sensitive designs. The LittleNPU processor within it is fine-tuned for sophisticated neural networks needed in always-sensing applications, maintaining privacy by keeping data on-board. This makes the E1 a robust choice for devices requiring dedicated AI processing without the penalty of high power consumption or large silicon area. In terms of technical specifications, the Origin E1 boasts a performance efficiency of up to 18 TOPS per Watt, with the capability to run various network types such as CNNs, RNNs, and DNNs. Its adaptability allows clients to customize features to meet specific needs, guaranteeing efficient deployments across numerous devices. The E1 leverages a full TVM-based software stack for seamless integration, further endorsing its versatility and effectiveness.
Focusing on the efficient management of power supply across various electronic devices, Novatek’s power management controllers are designed for TVs, notebooks, monitors, smartphones, and wearable products. These controllers help regulate energy consumption, enhancing the longevity and sustainability of the devices they support. By optimizing power use and reducing wastage, they play a crucial role in supporting environmentally conscious electronic design practices. Their adaptive power control strategies contribute significantly to improving device performance and operational efficiency.
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 Cyclone V FPGA with Integrated PQC Processor by ResQuant is a specialized product that comes pre-equipped with a comprehensive NIST PQC cryptography suite. This FPGA is tailored for applications requiring a robust proof-of-concept for quantum-safe implementations. It ensures seamless integration into existing systems, providing a practical platform for testing and deployment in quantum-secure environments. This product is available at a competitive price and represents an ideal starting point for entities looking to explore and adopt quantum-resilient technologies. Its configuration allows for straightforward implementation in diverse hardware infrastructures while offering a reliable option for organizations aiming to stay ahead in the evolving cyber security landscape. By incorporating the latest in cryptographic standards and ensuring vendor independence, the Cyclone V FPGA with Integrated PQC Processor by ResQuant effectively bridges current hardware technologies and future-proof security needs. It supports industry-wide applications, from IoT and ICT to automotive and military sectors, underscoring ResQuant's versatility in hardware security solutions.
The Crest Factor Reduction (CFR) technology from Systems4Silicon is designed to optimize power amplifier efficiency by managing the peaks of signal envelopes. Known as FlexCFR, this IP core solution works independently of communication standards, making it adaptable to any target ASIC, FPGA, or SoC. This highly configurable technology is particularly effective at increasing power efficiency in complex RF systems, such as those found within multi-carrier and multi-user environments. By focusing on tailoring the signal envelope, FlexCFR ensures robust performance and system efficiency.
Combining 2D vector and 3D rendering capabilities, the GV580 is designed for high performance and low power consumption. It supports both OpenVG 1.1 and OpenGLES 1.1 standards, bringing together advanced rendering features suitable for a wide range of graphical applications. This GPU IP is perfect for enhancing device displays with dynamic graphics without overloading the CPU.
Designed for smaller scale transformations, the TW220/240 IP handles tasks such as distortion correction, scaling, and rotation for images up to 4K x 4K resolution. It supports RGB and YUV formats, offering vital capabilities for applications needing precision in image processing at lower resolutions. Its applications span from consumer digital products to professional imaging equipment.
StreamDSP's MIPI Video Processing Pipeline offers a comprehensive solution for integrating video streams into FPGA-based environments. Supporting Avalon and AXI-4 Streaming protocols, it is highly adaptable to different sensor video formats and frame rates, extending capability to 4K resolutions at 60fps. The pipeline is adept at handling complex processing tasks, including Bayer demosaicing and gamma correction, designed to enhance video output while maintaining minimal latency through optional frame buffering.
The Tentiva FMC board is a robust platform designed for superior video processing capabilities. Featuring a modular setup, it supports extensive customization and application-specific configuration with dual modular PHY slots tailored for flexible expansions. This design facilitates effortless connection with various PHY cards, granting users the adaptability needed for a broad spectrum of video communication applications. Supporting data rates up to 20 Gbps, the Tentiva board is equipped to handle high-speed communication, ensuring smooth and efficient video data processing. Its compatibility with myriad FPGA development boards courtesy of a standard FMC header, further accentuates its usability in diverse operational contexts. From video transmission to intricate processing tasks, the Tentiva board ensures quality and reliability across all video endeavors. The availability of specialized PHY cards, including DisplayPort and HDMI interfaces, enables unparalleled customization options, allowing developers to address precise project needs with ease. As a resource for advanced video applications, Tentiva exemplifies Parretto’s innovative approach to impactful, scalable technology solutions.
The Prodigy FPGA-Based Emulator from Tachyum is designed to facilitate a range of evaluation, testing, and development activities crucial for assessing the performance and compatibility of the Prodigy Universal Processor. This emulator provides an infrastructure that mimics the capabilities of the Prodigy processor, enabling assessment under realistic workloads and evaluation of the software's interaction with the hardware. It stands as a pivotal tool for developers aiming to refine their applications to operate seamlessly on Prodigy's architecture. Constructed with multiple FPGA and IO boards interconnected by cables within a rack, the emulator allows for extensive emulation of processor cores. This includes support for both vector and matrix fixed and floating-point processing units, offering developers a comprehensive environment for application testing and debugging. By simulating core functionalities, it facilitates a hands-on experience in optimizing software for Prodigy's architecture. Importantly, the emulator empowers users to start transitioning their high-performance and low-power-demanding applications onto Prodigy processors. With its rich array of features, including interface emulation and performance measurement capabilities, it supports the iterative process of development, ensuring that software runs optimally on Prodigy, thus amplifying its operation efficiency and performance metrics.
Targeting high-performance demands, the Origin E8 is built for sectors requiring robust AI capabilities, such as data centers and autonomous driving. It accommodates demanding applications for real-time processing tasks, offering up to 128 TOPS in a single core configuration. The E8 expedites complex AI workloads with its advanced packet-based architecture that enhances efficiency through concurrent multi-layer execution. The scalable design of the Origin E8 enables its use in diverse contexts, managing multiple AI networks simultaneously with minimal latency. Expedera's solution addresses the architectural needs of sectors where performance, area, and power efficiency are paramount, providing competitive advantages through optimal configuration. Including a comprehensive suite of development tools like a compiler, scheduler, and quantizer, the Origin E8 facilitates straightforward integration and adaptation to various AI models, thereby ensuring it can meet a broad range of application scenarios.
Engineered for medical imaging, the MVUM1000 ultrasound sensor array incorporates 256 elements, utilizing CMUT technology to ensure high integration with electronic interfaces. This design supports low power usage with high sensitivity, accommodating multiple imaging modes. Its compact form factor and advanced functionality make it ideal for point-of-care and portable ultrasound applications.
Korusys' Video Wall Display Management System is a sophisticated solution for managing multiple video outputs from a single source. Designed to support digital signage and public information displays, it processes HDMI or Display Port video inputs and synchronizes their display across up to four monitors. The system is customizable and scalable, allowing for various configurations like cloning or spanning inputs across multiple outputs. This flexibility, combined with bezel compensation and EDID parsing, ensures flawless display arrangement and resolution support, making it ideal for both large-scale and small-scale video wall applications.
BTREE's Camera ISP for HDR is designed to enhance image processing by delivering superior high dynamic range capabilities. This product plays a crucial role in capturing more detailed and nuanced visual information, even in challenging lighting conditions, making it an ideal solution for applications requiring exceptional image clarity. It integrates seamlessly with modern camera systems, ensuring a significant improvement in image quality. The Camera ISP for HDR leverages advanced algorithms to process images efficiently, reducing noise while preserving detail and color accuracy. This allows for a more realistic representation of real-world scenes, enhancing the overall user experience. As such, this product is particularly valuable for applications in photography, surveillance, and any other industry where high-quality imagery is paramount. Furthermore, the ISP's flexible architecture allows for easy integration and adaptation to various hardware setups. It is designed to optimize performance while minimizing power consumption, making it suitable for a wide range of devices from high-end cameras to compact consumer electronics. The Camera ISP for HDR is a testament to BTREE's commitment to pushing the boundaries of imaging technology.
Catalyst-GPU is a robust graphics processing unit tailored for environments requiring high-performance computation and data visualization. This PXIe module stands at the core of RADX’s high-tech solutions, engineered for the streamlined execution of intensive tasks associated with modern computing needs, including AI, DSP, and EW applications. By leveraging cutting-edge GPU technology, the Catalyst-GPU raises the bar in computational speed and efficiency, accommodating the increasing data demands of contemporary applications. Its architecture supports seamless integration, allowing for straightforward upgrades and enhancements to existing systems, ensuring minimal disruption and maximum throughput. With a primary focus on delivering rapid processing power, the Catalyst-GPU is crafted to meet the evolving challenges in data-driven markets. Whether in research or industrial settings, its capability to handle large datasets swiftly and accurately makes it indispensable for modern computing tasks that demand high fidelity and real-time processing.
The Origin E2 NPU is engineered for power-sensitive devices requiring on-device AI processing. Suitable for smartphones and edge nodes, it supports various AI models and balances performance with low power consumption. By utilizing Expedera's packet-based architecture, the E2 achieves high efficiency and effective resource utilization, facilitating parallel execution across multiple layers to enhance computational throughput. The E2 is highly adaptable, supporting a broad performance range from 1 to 20 TOPS, making it well-suited for running neural networks like RNN, LSTM, CNN, and DNN without the need for hardware-specific modifications. This ensures seamless integration for customers looking to leverage their existing trained models. Equipped with a full TVM-based software stack, the Origin E2 simplifies network deployment while offering excellent customization capabilities to meet specific application requirements. Its design emphasizes field-proven reliability with its inclusion in over 10 million consumer devices globally.
The SMS Fully Integrated Gigabit Ethernet & Fibre Channel Transceiver Core is an advanced solution designed for high-speed data transmission applications. This core incorporates all necessary high-speed serial link blocks, such as high-speed drivers and PLL architectures, which enable precise clock recovery and signal synchronization.\n\nThe transceiver core is compliant with IEEE 802.3z for Gigabit Ethernet and is also compatible with Fibre Channel standards, ensuring robust performance across a variety of network settings. It features an inherently full-duplex operation, providing simultaneous bidirectional data paths through its 10-bit controller interface. This enhances communication efficiency and overall data throughput.\n\nParticularly suited for networks requiring low jitter and high-speed operation, this transceiver includes proprietary technology for superior jitter performance and noise immunity. Its implementation in low-cost, low-power CMOS further provides a cost-effective and energy-efficient solution for high-speed networking requirements.
The M3000 Graphics Processor by DMP is a prominent 3D graphics processing solution designed for high-demand visuals. At its core, it utilizes the Musashi 3D graphics architecture, enabling unparalleled Power/Performance/Area (PPA) efficiency. The processor supports OpenGL ES 3.0, facilitating the development of cutting-edge graphics for VR, AR, and complex 3D rendering applications. Designed to meet the rigorous demands of visual computing, the M3000 offers expansive compatibility with various application interfaces, making it a versatile choice for a range of devices from IoT products to entertainment systems and automotive interfaces. Its architecture supports high-definition resolutions up to 4K, fostering an immersive experience with precise detail and vibrant colors. This processor stands as a testament to DMP's ongoing efforts in advancing graphical performance, offering scalability and flexibility for diverse deployment scenarios while maintaining minimal power consumption, making it suitable for devices that require robust yet efficient graphics processing solutions.
The v-MP6000UDX Visual Processing Unit is a powerhouse of the Videantis portfolio, offering extensive capabilities for handling deep learning, computer vision, and video coding across a singular architecture. This unit brings prowess in processing tasks that require real-time performance and energy efficiency, making it pivotal for next-generation intelligent devices. Designed to support multiple computational requirements, the v-MP6000UDX processes deep learning models efficiently, acting as a unified platform that negates the need for disparate hardware accelerators. This processor's architecture is optimized for running complete neural networks swiftly and at low power, facilitating applications that demand rapid computing power with minimal energy constraints. Boasting a sophisticated memory hierarchy and high-bandwidth interfaces, the processor ensures efficient data handling and processing. Its enhanced memory architecture paired with a network-on-chip design fosters an environment where high-performance computations are achieved seamlessly. This makes the v-MP6000UDX suitable for deployment in complex systems such as autonomous vehicles, mobile technology, and industrial automation, where proficient data processing and precision are critical. Incorporating the latest design principles, the v-MP6000UDX unit integrates seamlessly into devices that require extensive video processing capabilities, benefiting from a vast library of codecs and support for emerging standards in video compression. This processing unit is indispensable for businesses aiming to enhance their product offerings with cutting-edge technology.
The 3DNR Image Processing solution is engineered to reduce noise in images, thus delivering a cleaner, clearer output. This technology is pivotal for enhancing image quality across various lighting conditions, ensuring that even low-light environments produce detailed visuals. BTREE's 3DNR technology stands out due to its advanced processing capabilities, which effectively minimize visual noise without compromising key details within the image. Designed with modern imaging needs in mind, the 3DNR Image Processing solution helps to maintain the integrity and vibrancy of colors, contributing to a more natural appearance of the image. This makes it well-suited for applications such as security systems, automotive imaging, and consumer electronics, where clarity and detail are essential. Additionally, BTREE has optimized their 3DNR solution to integrate seamlessly with existing imaging architectures, enhancing its versatility. The technology's efficiency in processing ensures minimal latency, providing real-time noise reduction capabilities that make it an ideal choice for a wide range of applications that depend on swift and accurate image processing.
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 Wireless Baseband IP from Low Power Futures is a sophisticated solution designed for small, ultra-low-power devices in IoT applications. It comprises a baseband processor hardware IP, the link layer or medium access control layer firmware, and integrated security features. This product is specifically optimized to ensure a minimal code size, while providing power and area efficiency. The Wireless Baseband IP supports standard compliance and can be easily integrated into systems on chips (SoCs). It is validated on FPGA platforms, making it a robust solution for developers aiming to leverage low-power IoT networks. This IP is versatile, finding applications in smart homes, smart city infrastructures, and connected audio systems. Its customizable nature allows for easy adaptation to various embedded processors, enabling seamless integration in different environments. The IP's design emphasizes efficient resource use, crucial for IoT devices that demand long battery life and low operational cost.
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.
Designed for edge inference applications, the Origin E6 NPU offers a state-of-the-art solution supporting both traditional and generative AI models. With performance scaling from 16 to 32 TOPS, the E6 is tailored to meet the sophisticated demands of next-gen smartphones, AR/VR devices, and automotive applications. Expedera's packet-based architecture facilitates parallel operations, ensuring efficient resource use and reducing latency. The E6 is highly customizable, supporting a wide range of AI models and enabling seamless deployments across diverse hardware environments without the need for extensive hardware-specific tuning. Expedera offers the Origin E6 with a complete software stack that promotes ease of integration and supports advanced features like multiple job APIs and quantization options. By achieving up to 90% processor utilization, the E6 maximizes performance while minimizing dark silicon waste, positioning it as a leading choice for AI chip architects seeking power efficiency and scalability in their designs.
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