All IPs > Multimedia > 2D / 3D
The 2D and 3D multimedia category within our Silicon Hub encompasses a wide range of semiconductor IPs tailored for sophisticated visual and graphic processing applications. These semiconductor IPs are integral in creating intricate and dynamic user interfaces that enhance the user experience across various digital devices. From immersive video games to high-definition media streaming, the capabilities provided by 2D and 3D multimedia semiconductor IPs are crucial in delivering superior graphics and performance.
Key applications of these semiconductor IPs include rendering realistic graphics in gaming systems, developing augmented and virtual reality environments, and supporting comprehensive user interactions on mobile devices. Products within this category are designed to optimize the rendering pipelines, enabling smoother and more intricate graphics. The focus is often on increasing frame rates, improving image processing speed, and supporting higher resolutions, all of which contribute to more lifelike and engaging digital experiences.
In addition to enhancing consumer electronics, the 2D and 3D multimedia semiconductor IPs are vital in various professional fields. Industries such as automotive, where advanced digital dashboards and infotainment systems rely on high-quality graphical interfaces, benefit significantly from these IP solutions. The medical field also utilizes these technologies for detailed imaging applications, where clarity and precision are essential.
Our selection of 2D and 3D multimedia semiconductor IPs includes state-of-the-art hardware and software solutions that meet the burgeoning demand for more efficient and innovative digital graphics. These products are designed to be scalable and adaptable, allowing developers to integrate them into a wide range of platforms efficiently. Whether you're developing next-gen gaming experiences or intricate medical imaging systems, our semiconductor IPs provide the tools necessary to bring your visual projects to life.
Overview: CMOS Image Sensors (CIS) often suffer from base noise, such as Additive White Gaussian Noise (AWGN), which deteriorates image quality in low-light environments. Traditional noise reduction methods include mask filters for still images and temporal noise data accumulation for video streams. However, these methods can lead to ghosting artifacts in sequential images due to inconsistent signal processing. To address this, this IP offers advanced noise reduction techniques and features a specific Anti-ghost Block to minimize ghosting effects. Specifications: Maximum Resolution o Image : 13MP o Video : 13MP@30fps -Input formats : YUV422–8 bits -Output formats o DVP : YUV422-8 bits o AXI : YUV420, YUV422 -8 bits-Interface o ARM® AMBA APB BUS interface for ISP system control o ARM® AMBA AXI interface for data o Direct connection to sensor stream data (DVP) Features: Base Noise Correction: AWGN reduction for improved image quality Mask Filter: Convolution-based noise reduction for still images Temporal Noise Data Accumulation: Gaussian Distribution-based noise reduction for video streams using 2 frames of images 3D Noise Reduction (3DNR): Sequential image noise reduction with Anti-ghost Block Motion Estimation and Adaptive: Suppresses ghosting artifacts during noise reduction Real-Time Processing: Supports Digital Video Port (DVP) and AXI interfaces for seamless integration Anti-Ghost Real time De-noising output
The KL730 is a sophisticated AI System on Chip (SoC) that embodies Kneron's third-generation reconfigurable NPU architecture. This SoC delivers a substantial 8 TOPS of computing power, designed to efficiently handle CNN network architectures and transformer applications. Its innovative NPU architecture significantly optimizes DDR bandwidth, providing powerful video processing capabilities, including supporting 4K resolution at 60 FPS. Furthermore, the KL730 demonstrates formidable performance in noise reduction and low-light imaging, positioning it as a versatile solution for intelligent security, video conferencing, and autonomous applications.
The Metis AIPU PCIe AI Accelerator Card offers exceptional performance for AI workloads demanding significant computational capacity. It is powered by a single Metis AIPU and delivers up to 214 TOPS, catering to high-demand applications such as computer vision and real-time image processing. This PCIe card is integrated with the Voyager SDK, providing developers with a powerful yet user-friendly software environment for deploying complex AI applications seamlessly. Designed for efficiency, this accelerator card stands out by providing cutting-edge performance without the excessive power requirements typical of data center equipment. It achieves remarkable speed and accuracy, making it an ideal solution for tasks requiring fast data processing and inference speeds. The PCIe card supports a wide range of AI application scenarios, from enhancing existing infrastructure capabilities to integrating with new, dynamic systems. Its utility in various industrial settings is bolstered by its compatibility with the suite of state-of-the-art neural networks provided in the Axelera AI ecosystem.
The Metis AIPU M.2 Accelerator Module is designed for edge AI applications that demand high-performance inference capabilities. This module integrates a single Metis AI Processing Unit (AIPU), providing an excellent solution for AI acceleration within constrained devices. Its capability to handle high-speed data processing with limited power consumption makes it an optimal choice for applications requiring efficiency and precision. With 1GB of dedicated DRAM memory, it seamlessly supports a wide array of AI pipelines, ensuring rapid integration and deployment. The design of the Metis AIPU M.2 module is centered around maximizing performance without excessive energy consumption, making it suitable for diverse applications such as real-time video analytics and multi-camera processing. Its compact form factor eases incorporation into various devices, delivering robust performance for AI tasks without the heat or power trade-offs typically associated with such systems. Engineered to problem-solve current AI demands efficiently, the M.2 module comes supported by the Voyager SDK, which simplifies the integration process. This comprehensive software suite empowers developers to build and optimize AI models directly on the Metis platform, facilitating a significant reduction in time-to-market for innovative solutions.
The AX45MP is engineered as a high-performance processor that supports multicore architecture and advanced data processing capabilities, particularly suitable for applications requiring extensive computational efficiency. Powered by the AndesCore processor line, it capitalizes on a multicore symmetric multiprocessing framework, integrating up to eight cores with robust L2 cache management. The AX45MP incorporates advanced features such as vector processing capabilities and support for MemBoost technology to maximize data throughput. It caters to high-demand applications including machine learning, digital signal processing, and complex algorithmic computations, ensuring data coherence and efficient power usage.
The 2D FFT core is engineered to deliver fast processing for two-dimensional FFT computations, essential in image and video processing applications. By utilizing both internal and external memory effectively, this core is capable of handling large data sets typical in medical imaging or aerial surveillance systems. This core leverages Dillon Engineering’s ParaCore Architect utility to maximize flexibility and efficiency. It takes advantage of a two-engine design, where data can flow between stages without interruption, ensuring high throughput and minimal memory delays. Such a robust setup is vital for applications where swift processing of extensive data grids is crucial. The architecture is structured to provide consistent, high-quality transform computations that are essential in applications where accuracy and speed are non-negotiable. The 2D FFT core, with its advanced design parameters, supports the varied demands of modern imaging technology, providing a reliable tool for developers and engineers working within these sectors.
MajEQ Pro is an advanced equalization tool designed explicitly for professional audio applications, capable of achieving precise frequency response alignment. This tool allows for both static and dynamic EQ adjustments, providing users with unparalleled control over their sound systems, whether for live events or in-studio recordings. With MajEQ Pro, operators can seamlessly switch between modes, adjusting to static venue acoustics or responding dynamically to changing auditory environments in real-time. The tool supports high-frequency accuracy, essential for maintaining sound quality in diverse acoustic conditions, such as outdoor venues where frequency responses fluctuate. The implementation of MajEQ Pro in professional settings elevates the capabilities of audio systems, delivering superior sound quality and flexibility. For audio engineers and businesses involved in audio production, this tool aligns with the demands for high precision and reliability, ensuring that auditory outputs are always of the highest standard.
The KL720 is engineered for high efficiency, achieving up to 0.9 TOPS per Watt, setting it apart in the edge AI marketplace. Designed for real-world scenarios where power efficiency is paramount, this chip supports high-end IP cameras, smart TVs, and AI-enabled devices like glasses and headsets. Its ARM Cortex M4 CPU facilitates the processing of complex tasks like 4K image handling, full HD video, and 3D sensing, making it versatile for applications that include gaming and AI-assisted interactions.
ISPido represents a fully configurable RTL Image Signal Processing Pipeline, adhering to the AMBA AXI4 standards and tailored through the AXI4-LITE protocol for seamless integration with systems such as RISC-V. This advanced pipeline supports a variety of image processing functions like defective pixel correction, color filter interpolation using the Malvar-Cutler algorithm, and auto-white balance, among others. Designed to handle resolutions up to 7680x7680, ISPido provides compatibility for both 4K and 8K video systems, with support for 8, 10, or 12-bit depth inputs. Each module within this pipeline can be fine-tuned to fit specific requirements, making it a versatile choice for adapting to various imaging needs. The architecture's compatibility with flexible standards ensures robust performance and adaptability in diverse applications, from consumer electronics to professional-grade imaging solutions. Through its compact design, ISPido optimizes area and energy efficiency, providing high-quality image processing while keeping hardware demands low. This makes it suitable for battery-operated devices where power efficiency is crucial, without sacrificing the processing power needed for high-resolution outputs.
Dyumnin Semiconductors' RISCV SoC is a robust solution built around a 64-bit quad-core server-class RISC-V CPU, designed to meet advanced computing demands. This chip is modular, allowing for the inclusion of various subsystems tailored to specific applications. It integrates a sophisticated AI/ML subsystem that features an AI accelerator tightly coupled with a TensorFlow unit, streamlining AI operations and enhancing their efficiency. The SoC supports a multimedia subsystem equipped with IP for HDMI, Display Port, and MIPI, as well as camera and graphic accelerators for comprehensive multimedia processing capabilities. Additionally, the memory subsystem includes interfaces for DDR, MMC, ONFI, NorFlash, and SD/SDIO, ensuring compatibility with a wide range of memory technologies available in the market. This versatility makes it a suitable choice for devices requiring robust data storage and retrieval capabilities. To address automotive and communication needs, the chip's automotive subsystem provides connectivity through CAN, CAN-FD, and SafeSPI IPs, while the communication subsystem supports popular protocols like PCIe, Ethernet, USB, SPI, I2C, and UART. The configurable nature of this SoC allows for the adaptation of its capabilities to meet specific end-user requirements, making it a highly flexible tool for diverse applications.
Trion FPGAs by Efinix are engineered for the fast-paced edge and IoT markets. Built on a 40 nm process, these FPGAs offer a wide range of logic density from 4K to 120K logic elements. They bring power-performance-area advantages for general-purpose custom logic applications, including mobile and IoT markets, while also enhancing computing capabilities in emerging technologies such as deep learning and edge computing. The Trion family is known for its small packages, which enable its deployment in highly integrated systems. Features such as the DDR DRAM Controller and MIPI CSI-2 Controller are hardened into the architecture, ensuring smooth data management and transfer in applications that demand real-time processing. This makes Trion FPGAs an excellent choice for various industrial, medical, and consumer applications where space and power efficiency are critical. With a focus on longevity, Efinix supports Trion FPGAs with a stable product lifecycle, aligning with market requirements for dependable, production-ready solutions. These FPGAs are versatile enough to serve applications in edge computing, video processing, industrial automation, and more, offering a complete system solution with their embedded interfaces and soft processor systems.
The PACE Photonic Arithmetic Computing Engine from Lightelligence represents a paradigm shift in computing technologies. By utilizing photonic processes, this product significantly boosts computing speeds while maintaining energy efficiency. PACE is designed to leverage the inherent capabilities of photonics to perform high-speed arithmetic calculations, which are essential for complex data processing tasks. It's an ideal solution for industries demanding rapid and intensive computational power without the typical energy overhead.<br> <br> This advanced engine is central to the development of next-generation computing environments, where performance metrics exceed traditional expectations. By converting light signals into computing potential, PACE ensures that intensive processes such as AI computations, data analyses, and real-time processing are handled more efficiently. This product is tailored for enterprises seeking to minimize latency and enhance throughput across various applications.<br> <br> PACE not only meets the requirements of current computational demands but also sets the stage for future innovations in the field. It's a promising tool for developers and researchers aiming to explore the unexplored realms of digital capabilities, fostering an era of optical computing that's faster and more efficient than ever before. This makes PACE an indispensable component in both current and upcoming technological advancements.
The MVUM1000 ultrasound sensor array is an advanced medical imaging module that incorporates 256 linear capacitive micromachined ultrasound transducers (CMUTs). This makes it highly suitable for modern medical applications, offering superior versatility and integration.<br><br>Its capacitive transduction mechanism enhances the sensor's power efficiency while maintaining high sensitivity to acoustic pressure, essential for precise imaging. The device supports various imaging modes, broadening its applicability in complex medical diagnostics.<br><br>The design accommodates advanced interface electronics for streamlined integration into point-of-care and hand-held ultrasound devices, as well as traditional cart-based ultrasound systems. Built to accommodate compact and energy-conscious operations, it is available with customizable features to meet specific medical requirements.
The Universal DSP Library offers a comprehensive suite of digital signal processing components optimized for FPGA implementations. This library integrates seamlessly with the AMD Vivado ML Design Suite, providing essential components such as FIR filters, CIC decimating filters, mixers, and CORDIC function approximations. It includes tools that facilitate the connection of DSP systems together, allowing for rapid assembly of signal processing chains using Vivado’s GUI or direct VHDL instantiation. Each component within the library is accessible in both raw VHDL code and as an AMD Vivado ML Design Suite IPI block. This dual availability enables quick development and simulation of processing chains before moving to FPGA implementation. The Universal DSP Library is equipped with bit-true software models for each DSP block, allowing developers to evaluate and optimize systems in software to ensure precise functioning when deployed on hardware. Key features include support for multiple data channels, continuous wave, and pulse processing, as well as real and complex signal support. It utilizes the AXI4-Stream protocol, providing a standardized interface that simplifies integration and enhances the development of specific DSP solutions. The library is suitable for applications ranging from software-defined radio and communication systems to robotics and medical diagnostics, showcasing its versatility in various high-tech fields.
The Camera ISP Core is designed to optimize image signal processing by integrating sophisticated algorithms that produce sharp, high-resolution images while requiring minimal logic. Compatible with RGB Bayer and monochrome image sensors, this core handles inputs from 8 to 14 bits and supports resolutions from 256x256 up to 8192x8192 pixels. Its multi-pixel processing capabilities per clock cycle allow it to achieve performance metrics like 4Kp60 and 4Kp120 on FPGA devices. It uses AXI4-Lite and AXI4-Stream interfaces to streamline defect correction, lens shading correction, and high-quality demosaicing processes. Advanced noise reduction features, both 2D and 3D, are incorporated to handle different lighting conditions effectively. The core also includes sophisticated color and gamma corrections, with HDR processing for combining multiple exposure images to improve dynamic range. Capabilities such as auto focus and saturation, contrast, and brightness control are further enhanced by automatic white balance and exposure adjustments based on RGB histograms and window analyses. Beyond its core features, the Camera ISP Core is available with several configurations including the HDR, Pro, and AI variations, supporting different performance requirements and FPGA platforms. The versatility of the core makes it suitable for a range of applications where high-quality real-time image processing is essential.
The NMFx Night Mode Effect is tailored to improve the intelligibility of quiet sounds, such as speech, while suppressing loud sounds that can disrupt neighboring spaces. This mode is especially applicable in nighttime settings where maintaining a peaceful environment is crucial. It provides an enhanced audio experience by balancing the volume output without losing clarity of essential sounds. The NMFx employs sophisticated signal processing algorithms to dynamically manage audio levels, ensuring that vital sounds, like dialogue, are boosted even when the overall soundscape is hushed. It’s an ideal solution for consumer electronics like televisions and sound systems, designed to prevent disruptions in shared living spaces. This effect is a boon for users who prefer a balanced soundscape that won’t disturb others, while still allowing full engagement with the media content. Incorporating NMFx into products can significantly improve consumer satisfaction, especially in apartments or other shared living environments.
The RayCore MC Ray Tracing GPU is a cutting-edge GPU IP known for its real-time path and ray tracing capabilities. Designed to expedite the rendering process efficiently, this GPU IP stands out for its balance of high performance and low power consumption. This makes it ideal for environments requiring advanced graphics processing with minimal energy usage. Capitalizing on world-class ray tracing technology, the RayCore MC ensures seamless, high-quality visual outputs that enrich user experiences across gaming and metaverse applications. Equipped with superior rendering speed, the RayCore MC integrates sophisticated algorithms that handle intricate graphics computations effortlessly. This GPU IP aims to redefine the norms of graphics performance by combining agility in data processing with high fidelity in visual representation. Its real-time rendering finesse significantly enhances user interaction by offering a flawless graphics environment, conducive for both immersive gaming experiences and professional metaverse developments. The RayCore MC GPU IP is also pivotal for developers aiming to push the boundaries of graphics quality and efficiency. With an architecture geared towards optimizing both visual output and power efficiency, it stands as a benchmark for future GPU innovations in high-demand industries. The IP's ability to deliver rapid rendering with superior graphic integrity makes it a preferred choice among developers focused on pioneering graphics-intensive applications.
The Akida1000 Reference SoC is a fully functional silicon solution designed to demonstrate the capabilities of BrainChip's neuromorphic AI technology. Built to showcase the potential of the Akida architecture, this SoC integrates the neural processor with a variety of connectivity options and memory interfaces, allowing for comprehensive evaluation in real-world settings.\n\nThis reference chip is ideal for developers and businesses looking to explore AI's vast applications at the edge, offering a seamless way to prototype and build AI systems without cloud dependency. The Akida1000 is engineered to function as either an embedded accelerator or a standalone AI coprocessor, supporting a breadth of use cases requiring efficient on-device data processing.\n\nAkida1000's flexibility and high performance make it suitable for diverse industries including automotive, healthcare, and industrial sectors, facilitating predictive analytics and complex problem-solving where traditional processors might struggle. Its design includes standard interfaces like PCIe, USB, and various I/O options, making it easily integrable into existing infrastructures.
The GL3004 stands out as a high-performance fisheye image processor dedicated to enhancing wide-angle visuals through advanced image correction techniques. Designed for an array of image sensors and fisheye lenses, it employs sophisticated correction methods, such as customized fisheye correction and spherical panorama dewarping, to deliver exceptional viewing experiences. With a built-in hardware image signal processor, the GL3004 achieves superior color processing and includes features like wide dynamic range and on-screen display functions. The processor supports input resolutions up to 3 megapixels, ensuring quality output across various wide-angle imaging applications. Enhanced with multiple dewarping modes and robust ISP capabilities, the GL3004 is engineered for environments demanding real-time processing of wide-angle views. Its integration of multiple input and output interfaces, along with low power dissipation, makes it an ideal solution for digital cameras and surveillance systems, especially where detailed image correction is paramount.
The HDR Core is engineered to deliver enhanced dynamic range image processing by amalgamating multiple exposures to preserve image details in both bright and dim environments. It has the ability to support 120dB HDR through the integration of sensors like IMX585 and OV10640, among others. This core applies motion compensation alongside detection algorithms to mitigate ghosting effects in HDR imaging. It operates by effectively combining staggered based, dual conversion gain, and split pixel HDR sensor techniques to achieve realistic image outputs with preserved local contrast. The core adapts through frame-based HDR processing even when used with non-HDR sensors, demonstrating flexibility across various imaging conditions. Tone mapping is utilized within the HDR Core to adjust the high dynamic range image to fit the display capabilities of devices, ensuring color accuracy and local contrast are maintained without introducing noise, even in low light conditions. This makes the core highly valuable in applications where image quality and accuracy are paramount.
The i.MX RT700 Crossover MCU is a part of NXP's dynamic series of microcontrollers, characterized by its high performance and integrated feature set, designed specifically for AI-enabled edge devices. It carries the distinction of having five computing cores, contributing to its robust handling of intensive processing tasks. Within automotive and IoT domains, the i.MX RT700 excels by providing unprecedented computing power and integration. This crossover microcontroller balances the needs of hardware functionality with seamless software integration, which is vital for deploying advanced smart systems. Ideal for situations that demand optimal interaction between various components, the RT700 facilitates AI processes, driving forward features like voice and speech recognition, which are increasingly being integrated into consumer electronics. Its features make it indispensable for innovative edge devices aiming to push technological boundaries.
The WDR Core provides an advanced approach to wide dynamic range imaging by controlling image tone curves automatically based on scene analysis. This core is adept at ensuring that both shadows and highlights are appropriately compensated, thus maintaining image contrast and true color fidelity without the reliance on frame memory. Automatic adjustments extend the dynamic range of captured images, providing detailed correction in overexposed and underexposed areas. This capability is vital for environments with variable lighting conditions where traditional gamma corrections might introduce inaccuracies or unnatural visual effects. The core focuses on enhancing the user experience by delivering detailed and balanced images across diverse scenarios. Its versatility is particularly useful in applications like surveillance, where clarity across a range of light levels is critical, and in consumer electronics that require high-quality imaging in varying illumination.
The Video Wall Display Management System is a flexible solution using FPGA technology, designed for high-quality image processing and output across multiple displays. It handles input from HDMI or Display Port sources, delivering processed video synchronized on up to four individual screens. This system is ideal for setups requiring intricate video configurations, such as digital signage or multi-display environments. It supports resolutions up to 3840x2400p60 for input and up to 1920x1200p60 for outputs, providing excellent image clarity and synchronization. Its flexibility is enhanced by supported configuration modes including Stretch, Cloned, and Independent outputs, with customizable bezel compensation. A software API facilitates easy configuration and control, ensuring seamless management of video outputs. The Video Wall System is continually being refined, with future developments aiming at greater support for larger display setups through linked FPGA units. This system provides a robust solution for customizable, high-quality video display management, catering to diverse application needs.
The Cottonpicken DSP Engine is a sophisticated micro-coded digital signal processor designed to handle complex data conversion tasks efficiently. Developed in-house, this DSP engine offers versatility in pixel data manipulation, including Bayer pattern decoding and YUV conversion. It supports various formats such as YUV 4:2:2 or RGB and is capable of processing filter kernels up to 5x5, making it suitable for a wide range of image processing applications. Capable of operating at clock speeds up to 150 MHz, this engine provides high-speed data processing applicable to real-time video conversion and multimedia tasks. The architecture is designed to facilitate the seamless translation of raw pixel data into formats suitable for further processing or display. Given its powerful matrix operations and programmable delay configurations, the Cottonpicken DSP Engine is ideal for real-time image conversion tasks where flexibility and speed are critical. This DSP core, available as a closed-source netlist, emphasizes section5's ability to deliver high-performance solutions tailored to specific customer needs. By incorporating advanced matrix operations and various color space conversions, the Cottonpicken engine offers an all-inclusive solution for developers looking to implement advanced digital signal processing in their products while maintaining high throughput and precision.
MajEQ is a versatile equalization tool engineered to optimize audio outputs by precisely matching frequency response target curves. It can automatically or semi-automatically adjust to achieve the desired sound, whether for correcting loudspeaker outputs or enhancing audio playback quality across various devices. This tool is highly beneficial in both fixed installations, like venue sound systems, and dynamic settings where responsive environmental adjustments are necessary. Users can tailor sound responses in real-time, ensuring that the audio output remains balanced and high-fidelity, regardless of external factors. MajEQ is a valuable asset for audio manufacturers looking to add a layer of sophistication to their products. By improving sound quality and adaptability, this tool not only meets but often exceeds user expectations for audio performance, making it integral for high-end audio solutions and consumer electronics alike.
The SmartFx Audio Effects Suite is a comprehensive set of tools designed to elevate the audio experience on consumer devices. By integrating advanced audio processing capabilities, it delivers natural and fuller sound that includes enhanced bass and dynamic range control. Users can enjoy an easy-to-use graphical interface that allows real-time adjustments, making it a versatile solution for audio content enhancement. One of the standout features of SmartFx is its ability to adapt the audio output to different listening environments, providing consistent quality whether at home or on the go. The suite employs sophisticated algorithms to ensure the audio maintains intelligibility and clarity, even when faced with lossy codec challenges or data throttling. SmartFx is perfect for manufacturers looking to integrate premium sound capabilities into their products. By utilizing this suite, devices can offer improved audio fidelity, meeting the high expectations of modern consumers who demand rich, immersive sound experiences.
VoxBoost is a highly effective tool designed to enhance speech intelligibility by elevating the volume of speech frequencies relative to background sounds. This feature is crucial in scenarios where listener comprehension is a priority, such as in multimedia presentations, voice interactions, and during streamed or broadcasted content. By employing advanced DSP techniques, VoxBoost adjusts audio outputs so that speech components are clearly heard over ambient noise or music. This effect is advantageous in echolocation challenges posed by complex auditory environments, enabling clearer, more understandable speech delivery. VoxBoost is particularly valuable for devices used in noisy environments, ensuring communication remains clear and effective. It acts as a robust facilitator for manufacturers aiming to improve voice clarity in their products, from consumer electronics to professional audio systems, heightening the overall user experience through well-defined sound clarity.
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.
D/AVE 2D is an advanced graphics IP core designed for smooth rendering of 2D graphics. It boasts a highly efficient architecture that ensures fast processing speeds and high-performance graphics output, making it ideal for a wide range of display and rendering applications. The core is optimized for low power consumption, which is suited for portable and embedded systems such as handheld devices and automotive displays.
The IMG DXT GPU is tailored for the mobile device market, offering a unique blend of high efficiency and cutting-edge technology, including ray tracing capabilities. Utilizing Imagination's Photon architecture, the DXT promises enhanced performance for mobile visual applications, introducing ray tracing in various configurations to cater to different performance needs while keeping silicon costs in check. This GPU is adaptable, providing manufacturers with the option to integrate ray tracing in a cost-effective manner without sacrificing the mobile experience. With offerings that range from single to quad-RAC configurations, the DXT provides manufacturers the flexibility to choose setups that match their device specifications and performance benchmarks, making it a versatile choice for mobile technology companies. By providing realistic lighting effects in mobile devices, the IMG DXT GPU paves the way for unprecedented graphics quality in smartphones and tablets. It supports broader API coverage, including Vulkan and OpenGL, which ensures it can smoothly run a wide array of mobile applications, making it highly compatible with both existing and emerging technologies in the mobile graphics space.
The D/AVE 3D graphics processor is developed to handle complex 3D rendering tasks with high efficiency. It provides exceptional graphics performance with features supporting rich texture mapping and shading effects. This processor is designed to accelerate graphics applications in consumer electronics, offering robust performance while maintaining energy efficiency in high-demand scenarios.
Conceived for high bandwidth and intense data throughput requirements, the G-Series Controller by MEMTECH is at the forefront of graphics and AI compute solutions. This controller offers exceptional support for GDDR6 memory types, which are pivotal in enhancing graphics performance for gaming, advanced driver assistance systems, and other highly demanding applications. The G-Series Controller's design integrates dual-channel support and interfaces seamlessly with existing infrastructure, offering speeds up to 18 Gbps per pin, a vital feature for cutting-edge graphic and AI tasks. Its sophisticated error management system and automatic retry mechanisms ensure operational continuity and data integrity, pivotal in environments where performance cannot be compromised. Beyond functionality, MEMTECH focuses on creating a controller that aligns with market demands for power efficiency. This product stands as a testament to their innovative approach, meshing high-performance needs with the energy-conscious strategies that modern technologies demand.
The SINR Single Input Noise Reduction technique offers an efficient approach to minimizing background noise in audio content, thereby enhancing clarity and reducing distractions for listeners. Particularly useful in settings with high ambient noise, this feature ensures that the primary audio source remains the focal point. SINR employs sophisticated algorithms to isolate and suppress non-essential noise, allowing the main audio track, such as speech or music, to retain its quality and intelligibility. This feature is crucial for improving listener experience in environments like public transport, bustling offices, and home settings where background noise is prevalent. The implementation of SINR in electronic devices provides a competitive edge for manufacturers, as it heightens the overall quality of audio playback and communication, making it an attractive feature for consumer electronics, professional audio systems, and personal communication devices.
SEMIFIVE's HPC Platform is engineered to support the development of high-performance computing environments such as cloud servers and hyperscale data centers. Built on Samsung's advanced 5nm process, this platform incorporates quad-core Cortex A53 CPUs, high-speed GDDR6 memory, and PCIe Gen5 for maximum robustness in computing tasks. With its focus on high-performance AI acceleration and network processing, the HPC Platform is well-adapted to address the demanding tasks of hyperscale data centers and high performance AI projects. The design supports extensive interface capabilities, ensuring optimal connectivity and data throughput. By employing cutting-edge FinFET technology, SEMIFIVE ensures reduced power consumption without sacrificing performance, contributing to environmentally sustainable computing solutions. This platform provides a holistic development environment, complete with design, implementation, evaluation boards, and software, accelerating the deployment of complex computing infrastructure.
The MPEG-H Audio System revolutionizes audio experience by offering immersive sound capabilities tailored for TV and virtual reality environments. This next-level audio system allows for an interactive and personalized listening experience, enabling users to adjust audio settings such as dialogue level, enabling a more tailored and enriched auditory experience. Supporting advanced audio features, it delivers a three-dimensional sound experience by utilizing object-based audio technologies. MPEG-H Audio is designed to adapt to various broadcasting standards worldwide, making it a versatile solution for broadcasters aiming to enhance their listener's engagement. It provides a seamless mixing of different audio objects, allowing the audio scene to be dynamically recreated according to user preference and environmental settings. Additionally, MPEG-H Audio has been adopted as a mandatory audio system for certain regions’ next-gen TV technology. This indicates its significant role in future-proofing broadcast environments and enhancing audio output quality. The MPEG-H Audio System stands out as a compelling solution for broadcasters, technology developers, and AV enthusiasts seeking to enhance audio quality and user experience across media platforms.
The 5G ORAN Base Station IP is designed to revolutionize the mobile networking industry by significantly increasing wireless data capacity and offering new opportunities for various wireless applications. As 5G technology advances, this IP enables enhanced connectivity, supporting the massive throughput requirements necessitated by the increasing demand for high-speed internet and data transfer. It supports interoperability with current and future network infrastructures, ensuring a seamless transition to next-generation technologies. This IP integrates advanced antenna technologies to support multiple input, multiple output (MIMO) systems, thus contributing to improved spectral efficiency. The 5G ORAN Base Station is optimized for assorted use cases, from urban high-density environments to rural locales, facilitating expansive mobile coverage while meeting the rigorous demands of modern telecommunication standards. As a result, it functions effectively across varied geographical and operational conditions. The implementation of this IP within telecommunications infrastructure promises reduced latency and increased reliability of wireless communications, paving the way for innovative applications in smart cities, autonomous vehicles, and real-time video streaming. Overall, the 5G ORAN Base Station IP serves as a comprehensive solution for building scalable and future-proof mobile networks.
The AL-H264D-4KI422-HW decoder is designed for high-resolution medical imaging, broadcast, enterprise, and industrial applications. It emphasizes minimal latency and high video quality, leveraging the H.264 High-422 profile at Level 5.1 for intra-coded frames. This advanced solution is particularly valuable for applications requiring rigorous color accuracy and sharpness, such as micro-surgery video processing and film production broadcasts. Featuring support for 10-bit YUV 4:2:2 video, the decoder maintains significant detail without introducing banding artifacts, making it ideal for precise medical imaging needs. It implements a macroblock-line level pipelined architecture that offers latency as low as 0.3 milliseconds. This architecture, when paired with the Atria Logic AL-H264E-4KI422-HW encoder, achieves a remarkable glass-to-glass latency of approximately 0.6 milliseconds, ideal for live video applications. The decoder is efficiently integrated into a Xilinx Zynq-7000 XC7Z045 SoC, utilizing just 38% of logic resources, and is equipped with GB Ethernet MAC for IP-based streaming capability. Such features make the decoder versatile for both FPGA or ASIC implementations, supporting various use cases from medical fields to industrial manufacturing environments with exceptional performance and scalability.
The AL-H264E-4KI422-HW is an advanced H.264 UHD Hi422 Intra encoder optimized for low-latency and high-quality video applications. Targeted at fields requiring high precision like medical imaging and live broadcasting, this encoder supports the High-422 profile with 10-bit color depth, ensuring that visual details remain intact without color banding. Designed to work seamlessly with Atria Logic's AL-H264D-4KI422-HW decoder, it ensures an end-to-end low-latency transmission setup, which is crucial for real-time broadcasting and interactive applications such as robotic surgery assistance. The encoder's intuitive architecture achieves sub-frame latency, making it suitable for environments where time synchronization is critical. Implemented on a Xilinx Zynq-7000 series SoC, this encoder leverages FPGA resources efficiently, maintaining high video quality suitable for broadcasting over HDBaseT or through computer-connected displays. It not only supports variable and constant bit rate encoding but also integrates an Ethernet MAC for streamlined IP streaming. By offering comprehensive support for UHD encoding with high flexibility, the encoder fits diverse applications, including industrial machinery monitoring and dynamic broadcasting environments.
The TM7606/7 Series FHD Low Latency IP Transmission System is poised for providing efficient full HD video transmission with minimal latency, serving the needs of modern broadcasting and media transmission tasks. This system supports dual-channel video feeds, enhancing both versatility and functionality for professionals in the field. Incorporating advanced visibility enhancement and Secure Reliable Transport (SRT) functions, this system ensures that high-resolution video streams are transmitted with consistency and reliability. It's particularly suited for scenarios demanding robust data transmission solutions, such as live sports or event coverage, where real-time video delivery is essential. Compact and integrated for easy deployment, the TM7606/7 series aligns with the demands of today's dynamic broadcasting environment, ensuring users benefit from a seamless streaming experience with reduced latency and heightened clarity.
D/AVE NX is a versatile graphics processor designed for both 2D and 3D applications, offering superior performance in rendering and display tasks. It features advanced graphics capabilities that cater to a wide array of applications in consumer electronics, automotive, and other sectors requiring high-quality visual outputs. This processor ensures optimal power performance balance, making it a suitable option for energy-conscious designs.
The logi3D accelerator is engineered to meet industry standards for use in AMD Versal Adaptive SoCs and similar platforms. This IP core provides a robust solution for 3D graphics acceleration, facilitating development in applications needing high-quality graphic rendering. Its design is focused on delivering scalability and compatibility with industry-standard APIs, essential for developers working on sophisticated 3D visual tasks.
Designed to offload graphical processing from the main CPU, the logiBITBLT is a 2D graphics accelerator optimized for AMD FPGAs and Zynq 7000 AP SoCs. It enables the creation of engaging graphics while reducing system strain, ensuring efficient rendering of 2D visual elements. This IP core is pivotal for applications requiring high-performance graphics with minimal processing overhead.
Truechip's NoC Coherent Crossbar Silicon provides a high-performance framework designed to optimize data management across chip designs. This silicon IP is tailored to support multiple communication protocols, offering bespoke configurations for master and slave ports in sophisticated network structures. The coherent crossbar architecture it implements allows for efficient data routing, ensuring high bandwidth and consistency across various processing tasks. Key features include the ability to manage multiple data paths concurrently, addressing complex computational needs through dynamic resource allocation and protocol adaptation. It's crafted to support the rigorous demands of modern chip designs, enabling high levels of integration and data coherence vital for cutting-edge applications in AI, HPC, and other high-demand fields. Offering a combination of configurability and scalability, this NoC Coherent Crossbar Silicon IP is integral for designs that necessitate robust data processing capabilities and minimal latency.
Creonic presents an advanced suite of Demodulation IP cores, expertly crafted to address the demands of modern communication systems. These cores include support for various standards like DVB-S2X and CCSDS, thus ensuring compatibility across a wide array of applications. Demodulators transform received channel symbols into data streams, crucial for accurate signal interpretation in both satellite and terrestrial networks. The lineup features highly efficient designs, including DVB-S2X Wideband Demodulators that facilitate high-speed data transmission and reception, integral for satellite broadcasting and radio transceivers. These demodulators optimize the signal reception process, paving the way for enhanced performance and reduced noise interference. Creonic's demodulation technology is crafted to seamlessly integrate into existing infrastructures, ensuring that systems operate at peak performance. Whether for use in cutting-edge broadcast systems or reliable communication links, these cores offer unmatched performance and scalability, tailored to meet the rigorous demands of the telecommunications industry.
Enhance bitmap graphics processing with the logiBMP IP core designed for AMD FPGAs. This 2.5D graphics accelerator supports perspective-correct rendering, facilitating smooth and accurate display of bitmap-based scenes. It's ideal for graphics-demanding applications where real-time rendering is critical, offering robust performance in visual processing tasks.
The Video Input Controller is specialized in managing incoming video signals with high accuracy and reliability, optimizing the video streams for processing. It is engineered to support various video input formats and resolutions, making it an essential component for multimedia systems and devices that require seamless video data management.
The Warping Engine is a specialized video processing core designed to enable complex video transformations. It allows for real-time adjustments and alignment, ensuring high-quality video outputs suited for advanced display applications. Its capabilities are especially beneficial for sectors requiring precise visual rendering and video data manipulation.
The NoC Coherent Mesh Silicon is an innovative solution designed by Truechip to provide a complete and efficient mesh structure within Network on Chip (NoC) designs. It features a fully coherent crossbar architecture capable of handling complex data exchanges across multiple computing cores. This capability is essential for high-performance applications that require seamless data integration across various components, such as in multi-core processors or advanced SoC environments. The NoC Coherent Mesh Silicon supports a range of configurable options for data paths, enabling optimized data transmission with minimal latency and maximal throughput. With features like flexible address mapping and support for diverse communication protocols, this silicon IP offers a robust framework for developers aiming to build scalable and efficient system architectures. Its design allows for simultaneous data flow across all nodes, enhancing bandwidth and reducing bottlenecks, which is crucial for maintaining system performance in demanding computational tasks.
The N-channel Multiplexed FIR Filter offers an efficient filtering solution for complex signal processing applications. By multiplexing multiple inputs through a shared filter architecture, this design significantly reduces the computational resources required compared to running independent filters for each channel. This makes it ideal for dual-channel inputs such as I/Q signals in communications systems. Easy to integrate within broad DSP applications, this filter's flexibility and resource efficiency makes it a valuable tool in signal processing workflows, where performance and economy are paramount.
Swissbit's Security Upgrade Kit is a vital addition to embedded systems, providing a microSD card solution with Security Level 2 for safeguarding critical data against theft, duplication, and unauthorized access. Perfected with state-of-the-art encryption, it facilitates secure boot and ensures the integrity of vital applications and firmware. Designed for Linux-based environments, the kit offers seamless integration, enhancing existing infrastructures with dependable hardware security features.
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