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
Axelera AI has crafted a PCIe AI acceleration card, powered by their high-efficiency quad-core Metis AIPU, to tackle complex AI vision tasks. This card provides an extraordinary 214 TOPS, enabling it to process the most demanding AI workloads. Enhanced by the Voyager SDK's streamlined integration capabilities, this card promises quick deployment while maintaining superior accuracy and power efficiency. It is tailored for applications that require high throughput and minimal power consumption, making it ideal for edge computing.
The Metis M.2 AI accelerator module from Axelera AI is a cutting-edge solution for embedded AI applications. Designed for high-performance AI inference, this card boasts a single quad-core Metis AIPU that delivers industry-leading performance. With dedicated 1 GB DRAM memory, it operates efficiently within compact form factors like the NGFF M.2 socket. This capability unlocks tremendous potential for a range of AI-driven vision applications, offering seamless integration and heightened processing power.
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.
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.
ZIA Stereo Vision by Digital Media Professionals Inc. revolutionizes three-dimensional image processing by delivering exceptional accuracy and performance. This stereo vision technology is particularly designed for use in autonomous systems and advanced robotics, where precise spatial understanding is crucial. It incorporates deep learning algorithms to provide robust 3D mapping and object recognition capabilities. The IP facilitates extensive depth perception and analyzed spatial data for applications in areas like automated surveillance and navigation. Its ability to create detailed 3D maps of environments assists machines in interpreting and interacting with their surroundings effectively. By applying sophisticated AI algorithms, it enhances the ability of devices to make intelligent decisions based on rich visual data inputs. Integration into existing systems is simplified due to its compatibility with a variety of platforms and configurations. By enabling seamless deployment in sectors demanding high reliability and accuracy, ZIA Stereo Vision stands as a core component in the ongoing evolution towards more autonomous and smart digital environments.
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.
Dillon Engineering's 2D FFT Core is specifically developed for applications involving two-dimensional data processing, perfect for implementations in image processing and radar signal analysis. This FFT Core operates by processing data in a layered approach, enabling it to concurrently handle two-dimensional data arrays. It effectively leverages internal and external memory, maximizing throughput while minimizing the impact on bandwidth, which is crucial in handling large-scale data sets common in imaging technologies. Its ability to process data in two dimensions simultaneously offers a substantial advantage in applications that require comprehensive analysis of mass data points, including medical imaging and geospatial data processing. With a focus on flexibility, the 2D FFT Core, designed using the ParaCore Architect, offers configurable data processing abilities that can be tailored to unique project specifications. This ensures that the core can be adapted to meet a range of application needs while maintaining high-performance standards that Dillon Engineering is renowned for.
The M3000 Graphics Processor offers a comprehensive solution for 3D rendering, providing high efficiency and quality output in graphical processing tasks. It paves the way for enhancing visual performance in devices ranging from gaming consoles to sophisticated simulation systems. This processor supports an array of graphic formats and resolutions, rendering high-quality 3D visuals efficiently. Its robust architecture is designed to handle complex visual computations, making it ideal for industries that require superior graphical interfaces and detailed rendering capabilities. As part of its user-friendly design, the M3000 is compatible with established graphic APIs, allowing for easy integration and broad utility within existing technology structures. The processor serves as a benchmark for innovations in 3D graphical outputs, ensuring optimal end-user experiences in digital simulation and entertainment environments.
Efinix's Trion FPGAs provide an ideal solution for edge computing and IoT applications, where power efficiency, speed, and integration capabilities are critical. The Trion family, built on a 40 nm process node, offers a range of devices with logic elements between 4K to 120K, catering to both simple and complex application needs. Their comprehensive interface support, including MIPI, DDR, and LVDS, enhances their suitability for high-bandwidth applications in communication, consumer, and industrial sectors.\n\nTrion FPGAs are designed for high integration in space-constrained environments. The small package sizes, such as the WLCSP, make it feasible to integrate these FPGAs directly onto small-scale devices. The incorporation of hardened MIPI and DDR controllers further streamlines the ability to handle video and data-heavy tasks, which is increasingly relevant in today's data-centric tech landscape.\n\nWith robust I/O features, these FPGAs provide versatile connection options for a range of peripherals, fulfilling the demands of industries that rely on high-speed and reliable data transfer. The support for a variety of standards combined with their easy-to-use development environment fosters a more straightforward transition from design to deployment. Efinix ensures these products are capable of handling future advancements by committing to a longer product lifecycle, promising designers a secure investment.
Dyumnin's RISCV SoC is built around a robust 64-bit quad-core server class RISC-V CPU, offering various subsystems that cater to AI/ML, automotive, multimedia, memory, and cryptographic needs. This SoC is notable for its AI accelerator, including a custom CPU and tensor flow unit designed to expedite AI tasks. Furthermore, the communication subsystem supports a wide array of protocols like PCIe, Ethernet, and USB, ensuring versatile connectivity. As for the automotive sector, it includes CAN and SafeSPI IPs, reinforcing its utility in diverse applications such as automotive systems.
PACE, or Photonic Arithmetic Computing Engine, represents a significant leap forward in computing by using optical components to perform mathematical operations. This breakthrough allows for speed and efficiency improvements that are hard to replicate with traditional electronic designs. The PACE engine is engineered to accelerate the execution of complex algorithms, essential for high-performance applications such as artificial intelligence and large-scale data processing. With its ability to process computations at the speed of light, it opens new avenues for ultra-fast data analysis, making it a pivotal tool for industries relying on rapid data processing and intelligence. Emphasizing low energy consumption, PACE leverages the inherent energy efficiency of photonic processes, minimizing the power requirements compared to electronic counterparts. This feature is crucial for sustainability, reducing the overall energy footprint of data centers and large computing facilities. The engine's design is not only focused on speed but also on operational stability, ensuring consistent performance under intensive computational loads. Integration with existing systems is seamless, as PACE is compatible with current technological infrastructures. This compatibility ensures that businesses can adopt this advanced technology with minimal disruption, enhancing their computational capabilities without the need for extensive overhauls. The photonic nature of the PACE engine ensures future scalability, aligning with the evolving demands of data-driven industries.
The MVUM1000 ultrasound sensor array from MEMS Vision revolutionizes medical imaging with its scalable 256-element architecture. Employing advanced capacitive micromachined ultrasound transducers (CMUT), it provides high sensitivity and efficient electronic integration, capitalizing on their capacitive transduction properties to achieve energy-efficient operation. Its compatibility extends to various imaging methodologies, including time-of-flight and Doppler imaging, making it a flexible tool for contemporary medical visualization. The array is suitable for both portable point-of-care uses and traditional cart-based ultrasound devices, showcasing scalability and versatility. Beyond imaging, the MVUM1000's compact linear arrangement ensures precision without compromising on detail or surface coverage, delivering a distinguished imaging experience. Its design emphasizes ease of integration with ancillary electronic systems, maximizing its applicability in diverse clinical settings and procedures.
The Universal DSP Library from Enclustra offers robust FPGA implementations for commonly used digital signal processing tasks, such as FIR and CIC filters, mixers, and function approximations. Designed to reduce development time, every component comes as VHDL source code and as a block in the AMD Vivado ML Design Suite IPI framework. This setup allows for rapid building of processing chains using either the GUI or direct VHDL instantiation. The library supports multi-channel data processing, both parallel and TDM, and is geared towards minimizing integration complexity while maximizing performance.
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 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 GL3004 fisheye image processor offers comprehensive image processing capabilities, tailored specifically for wide-angle lens applications. It delivers exceptional fisheye correction methods, allowing for versatile dewarping options from spherical panorama views to specific stitching modes. Integrated hardware ensures that images maintain high fidelity, with a focus on accurate color processing and enhanced dynamic range. Supporting inputs up to 3 megapixels, it excels in real-time processing with an integrated ISP that handles a broad spectrum of imaging functions from noise reduction to auto-exposure control. This processor ensures that every captured scene disperses real-life details efficiently, which is critical in surveillance and advanced photography contexts. Designed with multiple interfaces, such as MIPI and BT standards, the GL3004 can fit into diverse applications, offering seamless integration potential. With an onboard Cyclone-8051 CPU, it processes instructions at a high speed, with reliable PLL systems managing clock operations across varied loads, making it a solid solution for creative and technical image requirements.
The Cottonpicken DSP Engine is a versatile digital signal processing module developed by section5, designed to enhance image and video processing applications. At its core, the DSP engine includes microcoded elements capable of executing complex operations such as Bayer pattern decoding and YUV conversions across multiple formats including YUV 4:2:2 and RGB.\n\nOne of the key highlights of the Cottonpicken DSP Engine is its ability to perform real-time image processing in a highly efficient manner, supporting pixel clocks up to 150 MHz, though actual performance is dependent on the specific platform. This engine's microcoded DSP system facilitates operations like specific matrix transformations and programmable delays, essential for high-speed image analytics.\n\nFocusing on compatibility and tailored use, the Cottonpicken is provided as a closed-source netlist object, included within a comprehensive development package from section5. Designed for those needing high-performance DSP solutions, it is particularly well-suited for applications requiring rapid and accurate image transformations, taking advantage of its programmable structure and supported operations.
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.
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 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.
Himax Technologies offers a cutting-edge range of CMOS image sensors tailored for diverse camera applications. These sensors boast small pixel sizes, enabling them to deliver exceptional imaging performance while being energy efficient. Integrating these sensors into devices has proven to enhance image quality significantly, making them a preferred choice among leading global device manufacturers. The sensors operate in an ultra-low power range, which is crucial for battery-dependent devices that require long life and reliability. Their autonomous operational capabilities paired with low latency performance ensure that images are captured seamlessly and efficiently without draining power unnecessarily. Himax's CMOS image sensors also feature programmable readout modes and integration time, offering flexibility in various applications. These sensors are pivotal in enabling always-on cameras that are crucial for security and IoT devices, highlighting their versatility across different sectors. Coupled with MIPI serial link interface, they provide a streamlined design ideal for integration in compact and complex devices, reinforcing Himax's role in advancing imaging solutions.
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 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.
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.
Badge 2D Graphics offers a high-efficiency graphics solution, designed to support a variety of visual applications through its robust rendering capabilities. This system leverages FPGA technology to deliver fast and efficient 2D graphics processing, tailored for systems requiring stable and reliable graphical outputs. It is particularly suitable for integration into environments where extensive graphical assistance is needed, offering resourceful features for text and video rendering. With its widespread deployment in products surpassing five million units, Badge 2D Graphics demonstrates its reliability and performance in real-world applications, proving essential for industries ranging from automotive to consumer electronics. The system is optimized for use with Xilinx FPGA platforms, ensuring seamless integration with various digital environments. Its design promotes enhanced image quality and reduced rendering times, fostering a smooth user experience in applications that depend on crisp and precise graphical outputs. Through adaptable configuration settings, Badge 2D Graphics supports the needs of different applications by offering customizable output options. Its versatile architecture supports a variety of requirements, making it an indispensable component for systems focused on delivering superior 2D graphics processing.
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.
The Akida1000 Reference SoC is a complete neural processing device designed for integration into AI systems, featuring 1.2 million neurons and 10 billion synapses. This SoC is configurable as a standalone embedded AI accelerator or can be paired with an MCU or CPU for enhanced performance. The Akida1000 uses event-based processing optimized for real-time neural network tasks, gaining efficiency from its large SRAM and scalable neural processing units, which are fully configurable to meet application-specific needs. It supports fully integrated networks, eliminating the need for frequent weight swaps between memory systems, thus enhancing throughput and reducing power consumption.
The D/AVE 3D offers GPU capabilities with support for OpenGL ES 1.1 and OpenVG 1.01 APIs, facilitating high-performance 3D graphics on FPGAs and microprocessors. This technology provides texture compression and edge-based anti-aliasing, accommodating resolutions of up to 2048 x 2048 pixels. With a robust design of around 1200k gates and 200-400kBits of memory requirement, the D/AVE 3D is optimized for platforms requiring precise graphics rendering and is compatible with Linux environments.
The logiREF-ACAP-MULTICAM-ISP HDR ISP Framework is designed for multi-camera applications requiring high definition real-time processing using the Versal ACAP platform. This complete HDR ISP video processing framework is capable of handling parallel streams from three UHD automotive video cameras. Xylon has optimized this solution for environments demanding robust image processing, with a focus on enhancing image quality in various lighting conditions—an essential capability for automotive and surveillance applications. The design framework integrates seamlessly with existing systems, utilizing the framework's capabilities to enhance image signal processing pipelines. This innovative framework serves as a powerful tool for developers aiming to harness the latest in image processing technologies, ensuring rapid deployment and optimized performance for high-bandwidth video streams.
The D/AVE 2D is a fixed-function vector graphics rendering engine tailored for integration in microcontrollers, microprocessors, and FPGAs. It excels in applications requiring precise edge anti-aliasing and supports a maximum resolution of 2048 x 2048 pixels. Designed for efficiency, the D/AVE 2D optimizes size with less than 100k gates and requires under 35kBits of memory. It manages a pipeline of one pixel per cycle, supporting a variety of operating systems including bare metal, RTOS, and Linux.
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.
The G-Series Controller from MEMTECH is designed for applications requiring high memory bandwidth, such as graphics processing, AI video processing, and gaming. This GDDR6 solution supports dual 16-channel configurations with speeds reaching up to 20 Gbps, making it an ideal solution for compute-intensive tasks that demand swift data handling and processing. Advanced scheduling engines enhance its efficiency by optimizing throughput, while hardware auto-initialization and comprehensive error correction modes ensure error-free operation and data integrity. G-Series Controllers boast a DFI 5.0 interface, allowing easy integration with memory systems and reducing development complexities. G-Series Controllers are crafted to meet high-performance computing and graphics needs within tight power budgets, delivering enhancements in latency and speed without requiring a large footprint. As a fully optimized controller, it provides exceptional performance for advanced computing environments where power and space are precious resources.
IMG DXT GPU stands out as an exemplary solution for mobile devices requiring advanced visual performance coupled with high energy efficiency. Built on the cutting-edge Photon architecture, it supports ray tracing capabilities that allow mobile devices to render highly realistic images, enhancing the user experience with rich details and smooth gameplay in graphics-intensive applications. Incorporating a flexible architecture, the DXT series is designed to accommodate various configurations, providing options for single, dual, triple, and quad-Ray Acceleration Cluster (RAC) settings. This flexibility offers manufacturers the ability to tailor the performance capabilities of their devices according to market needs, ensuring optimal balance between processing power and cost-effectiveness. The DXT GPU is adept in maintaining high performance within power-constrained environments, making it suitable for mobile applications where energy efficiency is as critical as processing power. Its architectural enhancements enable significant improvements in power management and computational efficiency, emphasizing its role in propelling forward the next generation of mobile visual technologies.
MPEG-H Audio, pioneered by Fraunhofer IIS, is an advanced audio solution tailored for the evolving demands of television and virtual reality (VR) environments. It enhances user experiences by delivering immersive 3D soundscapes and providing greater interactivity through personalizable features. For broadcasters, MPEG-H Audio offers a remarkably flexible setup, allowing for seamless integration with existing broadcasting systems while ensuring compatibility with various formats and platforms. One of its standout features is the ability to adapt audio output to specific environments or user preferences, such as adjusting the volume of commentary during a sports broadcast or enhancing dialogue clarity in films. This is achieved through the system's object-based audio technology, enabling precise sound positioning and dynamic adjustments in real-time. MPEG-H Audio also supports a wide range of operating environments, from high-definition TVs to intricate VR setups, including headsets and specialized sound systems. It is designed with forward compatibility in mind, which means it is well-prepared for integration with future audio advancements and standards. Across the globe, MPEG-H Audio is recognized as a key component for delivering high-quality audio experiences, emphasizing Fraunhofer IIS's leadership in audio technology innovation.
The HPC Platform by SEMIFIVE is engineered to support high-performance computing solutions requiring substantial processing power and speed. It is designed for applications that demand high data throughput, such as cloud computing, scientific simulations, and advanced analytics. This platform incorporates highly optimized silicon IPs that are essential for executing complex computations at high speed and low latency. The HPC Platform ensures efficient performance scaling and energy efficiency, making it ideal for use in modern computational workloads that demand significant processing resources. Its sophisticated architecture supports large-scale data processing and includes state-of-the-art CPU and memory interfaces. Moreover, the HPC Platform's ready-to-deploy solutions reduce development time and enhance business capabilities by providing a comprehensive and reliable computing environment. These features, combined with robust support for emerging technologies, make the HPC Platform well-suited for leading-edge computing demands.
TicoRAW FPGA/ASIC IP Cores are at the forefront of RAW image compression, offering exceptional efficiency for handling high-resolution image and video data. Ideal for use with next-generation image sensors, these IP cores maximize image quality while minimizing the bandwidth required for data transmission and storage. The distinctive feature of TicoRAW is its ability to maintain the highest levels of detail and color integrity across the luminance and chrominance spectrum, making it perfectly suited for high-dynamic-range imaging and high frame rate environments. This performance is critical in industries such as digital cinema, broadcasting, and surveillance, where preserving RAW data quality is paramount. Additionally, TicoRAW enables real-time processing with low power consumption, making it an excellent choice for portable and embedded applications. It supports a wide range of resolutions and frame rates, up to 200 megapixels, ensuring compatibility with various modern imaging devices. The ability to integrate seamlessly into existing workflows makes it a staple for professionals looking to advance their imaging capabilities significantly.
The Mali-G78 GPU is a high-performance graphics processor designed to deliver immersive digital displays in mobile and consumer applications. Built on Arm's Valhall architecture, this GPU pushes boundaries with advanced machine learning capabilities, making it perfect for augmented reality and high-fidelity gaming experiences. It offers asynchronous top-level integration for power savings and to enhance battery life while delivering realistic graphics for next-generation devices.
D/AVE NX delivers advanced 3D GPU capabilities tailored for MCUs, MPUs, and FPGAs, leveraging a shader-programmable architecture. This GPU supports OpenGL ES 2.0 and features Multi-Sample Anti Aliasing and FP32 ALUs for comprehensive 32bit Integer support. With a maximum resolution of 4096 x 4096 pixels, D/AVE NX is highly configurable, allowing performance tuning from 1 to 4 shader units, containing up to 128 ALUs. Its design requires around 700k ASIC gates and offers a pipeline density of 2 FP32 FLOPS per ALU per cycle, suitable for use in bare metal, RTOS, and Linux operating systems.
The logiADAK-VDF-ZU is a comprehensive IP design framework tailored for multi-camera vision applications utilizing the Xylon logiVID-ZU vision kit. Based on the AMD Zynq UltraScale+ MPSoC, it is equipped with pre-verified camera-to-display reference designs. This reduces design time, enabling users to concentrate on specific vision-based components of applications such as advanced driver-assistance systems (ADAS), machine vision, and guided robotics. Engineers can quickly deploy this framework to leverage the power of AMD's adaptive SoCs, ensuring efficient handling of demanding vision tasks. The seamless integration of multiple camera data streams into a unified system highlights its capability to handle complex vision processing. With this IP, Xylon provides tools that allow for rapid prototyping and development, making it ideal for those looking to innovate in the field of embedded vision without the overhead of developing from scratch.
The Akida1000 is a sophisticated reference chip that showcases the full potential of BrainChip's neural processing capabilities. It is engineered specifically for low-power, high-efficiency AI computation both as a standalone solution or a co-processor to augment existing systems. Emphasizing event-based processing, this chip comprises numerous configurable neural processing engines that enable it to perform complex neural tasks directly on-device. Its architecture allows for seamless integration into various technologies while providing a comprehensive package including RTL, development tools, and documentation to facilitate its adoption and use in diverse application areas.
The TM7606/7 Series is a sophisticated low-latency video transmission system optimized for use over general communication networks like the Internet or mobile infrastructures. This system accommodates two-channel video transmission and is equipped with features such as visibility enhancement and SRT functions, making it an ideal solution for remote control operations and diverse monitoring tasks. Compatible with SDI and HDMI inputs and outputs, the system achieves a low latency of 0.1 seconds, ensuring seamless and high-quality video transmission. Its compact design, weighing under 2.1 lbs and measuring only 1.69 x 5.12 x 6.69 inches, offers portability without compromising performance. The encoder supports dual 3G-SDI input channels with dual encoding capabilities, allowing for the simultaneous compression of video streams with different quality settings. The decoder offers dual HDMI outputs, delivering flexibility in playback. Moreover, the advanced visibility enhancement functionality corrects image issues such as blackouts and whiteouts, enhancing clarity even under challenging conditions. The system's SRT capability mitigates packet loss, crucial for maintaining video integrity during transmission. The TM7606/7 is supported by TMC's proprietary codec, ensuring data security and compatibility with other TMC systems.
Vivante GPU technology by VeriSilicon is designed to provide efficient, high-performance graphics capabilities within compact silicon frameworks. It supports scalable and robust architectures tailored to meet the diverse requirements of modern multimedia applications. The Vivante GPUs feature advanced power management capabilities to optimize performance-to-power ratios, making them optimal for energy-sensitive applications.
Swissbit's Security Upgrade Kit is specifically engineered to enhance the security of embedded systems, providing a reliable retrofit solution, particularly for Linux-based environments. The kit includes a Security Level 2 microSD card, which plays a pivotal role in safeguarding critical data such as configuration credentials, licenses, and external data from being unauthorizedly accessed or altered. It ensures secure boot processes and application integrity while facilitating unique hardware-based access control, making it an indispensable tool for protecting embedded systems.
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