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 PCIe AI Accelerator Card powered by Metis AIPU offers unparalleled AI inference performance suitable for intensive vision applications. Incorporating a single quad-core Metis AIPU, it provides up to 214 TOPS, efficiently managing high-volume workloads with low latency. The card is further enhanced by the Voyager SDK, which streamlines application deployment, offering an intuitive development experience and ensuring simple integration across various platforms. Whether for real-time video analytics or other demanding AI tasks, the PCIe Accelerator Card is designed to deliver exceptional speed and precision.
The Metis AIPU M.2 accelerator module by Axelera AI is engineered for AI inference on edge devices with power and budget constraints. It leverages the quad-core Metis AIPU, delivering exceptional AI processing in a compact form factor. This solution is ideal for a range of applications, including computer vision in constrained environments, providing robust support for multiple camera feeds and parallel neural networks. With its easy integration and the comprehensive Voyager SDK, it simplifies the deployment of advanced AI models, ensuring high prediction accuracy and efficiency. This module is optimized for NGFF (Next Generation Form Factor) M.2 sockets, boosting the capability of any processing system with modest space and power requirements.
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.
Digital Media Professionals offers ZIA Stereo Vision, a robust solution for achieving high-accuracy depth estimation through stereoscopic imaging. Suited for applications in robotics and automated systems, ZIA SV deploys a sophisticated semi-global matching algorithm to derive reliable distance measurements from stereo camera inputs. This IP core excels in pre-processing and post-processing steps to optimize depth map accuracy. By supporting grayscale images of up to 8-bit depth and providing detailed disparity maps, it forms the backbone for various machine vision tasks. Built with efficiency in mind, ZIA SV supports AMBA AXI4 interface, ensuring seamless integration within high throughput data environments. Ideal for autonomous navigation systems, ZIA SV facilitates accurate real-time depth perception. This capability, combined with its minimal resource footprint, makes it a preferred choice for compact, power-sensitive applications needing reliable stereo vision processing.
ISPido is a sophisticated Image Signal Processing Pipeline designed for comprehensive image enhancement tasks. It is ultra-configurable using the AXI4-LITE protocol, supporting integration with processors like RISCV. The ISP Pipeline accommodates procedures such as defective pixel correction, color interpolation using the Malvar-Cutler algorithm, and various statistical adjustments to facilitate adaptive control. Furthermore, ISPido incorporates comprehensive color conversion functionalities, with support for HDR processing and chroma resampling to 4:2:2/4:2:0 formats. Supporting bit depths of 8, 10, or 12 bits, and resolutions up to 7680x7680, ISPido ensures high-resolution output crucial for next-generation image processing needs. This flexibility positions it perfectly for projects ranging from low power devices to ultra-high-definition vision systems. Each component of ISPido aligns with AMBA AXI4 standards, ensuring broad compatibility and modular customization possibilities. Such features make it an ideal choice for heterogeneous electronics ecosystems involving CPUs, GPUs, and specialized processors, further solidifying its practicality for widespread deployment.
The M3000 Graphics Processor from Digital Media Professionals is designed to deliver exceptional performance in 3D graphics rendering within compact, power-efficient packages. Optimized for high-performance visual computing, the M3000 provides state-of-the-art support for OpenGL ES 3.0, ensuring top-notch graphics output for embedded devices and edge computing. Exhibiting a scalable architecture, the M3000 allows precise customization to meet diverse performance and area efficiency requirements. It stands out with its prowess in handling VR and AR applications, demanding intensive graphical calculations and rendering. Through the use of DMP’s proprietary graphics architect, Musashi, the M3000 achieves unparalleled efficiency in power, performance, and area (PPA). Aligning with current industry needs, the processor supports multiple application interfaces including IoT devices, smartphones, automotive systems, and more. Its versatility extends to customization of graphical throughput, making the M3000 a pivotal component in devices that require advanced graphics processing capabilities.
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.
The MVUM1000 Ultrasound Sensor Array is a state-of-the-art medical imaging tool utilizing CMUT technology. Its linear array of up to 256 elements allows for high sensitivity and integrability with interface electronics. Supporting various imaging modes, it is ideal for handheld and cart-based ultrasound devices, maximizing usability while minimizing power consumption for effective medical diagnostics.
The Universal DSP Library is an adaptable collection of digital signal processing components, seamlessly integrated into the AMD Vivado ML Design Suite. This library supports a variety of common DSP tasks, including filtering, mixing, and approximations, all while providing the integral logic necessary for connecting DSP systems. By minimizing development time and enabling rapid assembly of signal processing chains, the library facilitates both rapid prototyping and sophisticated design within FPGA environments. It provides raw VHDL source code and IP blocks, paired with comprehensive documentation and bit-true software models for preliminary evaluation and development. Supporting a multitude of processing types such as continuous wave and pulse processing, the library delivers significant flexibility for developers. This ranges from real and complex signal processing to accommodating multiple independent data channels. All components are designed to operate within the standardized AXI4-Stream protocol, ensuring an easy integration process with other systems. The inclusion of out-of-the-box solutions for FIR, CIC filters, and CORDIC highlights the library's capability to cover repetitive DSP tasks, allowing developers to concentrate on more project-specific challenges. The Universal DSP Library not only streamlines design with its modularity and ease of use, but it also offers solutions for optimizing performance across different application areas. Its utility spans digital signal processing, communication systems, and even medical diagnostics, underscoring its versatility and essential role in modern FPGA-based development initiatives.
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 GL3004 is a highly capable fisheye image processor designed to cater to high-performance wide-angle applications. It is equipped with multiple dewarping modes, allowing it to process and correct images from fisheye lenses effectively. The GL3004 integrates a hardware image signal processor that enhances visual quality by applying wide dynamic range techniques and real-time image corrections. Supporting input resolutions up to 3 megapixels, the GL3004 is tailored for a range of wide-angle camera applications. The integrated display engines allow for dynamic overlay, multipoint views, and customized fisheye corrections, enhancing the user experience with enriched visual presentations. This image processor also includes various input and output interfaces, such as MIPI, DVP, and BT601/656, making it highly versatile. With its advanced hardware-based ISP, the GL3004 supports essential features like auto exposure, color interpolation, and on-screen display functions, making it a robust choice for improving wide-angle imaging technology.
PACE, or the Photonic Arithmetic Computing Engine, is a revolutionary hardware designed to harness the capabilities of photonics for computational purposes. Drawing on the low latency and energy efficiency of optical technologies, PACE aims to deliver significant enhancements in computing speed. This system aligns with cutting-edge standards, promoting increased efficiency and performance across computing tasks. Capitalizing on the photonic paradigm, PACE provides a glimpse into the future of high-speed computation, emphasizing the reduction of power consumption and boosting of operational throughput.
The Cottonpicken DSP Engine is a versatile digital signal processing solution focused on image processing tasks such as Bayer pattern decoding and various matrix operations. Capable of decoding Bayer patterns into formats like YUV 4:2:2, YUV 4:2:0, and RGB, it offers programmable delays and supports YCrCb and YCoCg colorspaces. The engine is designed to handle 3x3 and 5x5 kernel filters and specific matrix operations. This DSP core operates at the full data clock, supporting pixel frequencies up to 150 MHz, depending on the platform. This capability makes it a robust choice for high-throughput applications requiring real-time image processing capabilities. The Cottonpicken DSP Engine is offered as a closed-source netlist object, part of a comprehensive development package tailored for high-performance tasks. Its efficient architecture allows seamless integration into custom designs, particularly for applications that require intense computational tasks and high-speed signal processing.
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 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 RayCore MC is a state-of-the-art real-time path and ray-tracing graphics processing unit (GPU) designed to enhance rendering efficiency while maintaining reduced power consumption. This GPU is particularly adept at delivering highly realistic graphics through advanced ray tracing capabilities. With its low-power design, the RayCore MC is optimized for industries that require robust real-time graphics rendering, making it perfect for gaming and immersive virtual environments. Built on cutting-edge architecture, the RayCore MC accelerates the computation of complex image structures by simulating how light interacts with various surfaces. This results in enhanced graphic realism where minute details of light and shadow are vividly portrayed, greatly enriching visual experiences. By leveraging AI processing, this GPU not only improves the speed and quality of rendering but also enables innovative features that push the boundaries of current graphical capabilities. The RayCore MC has been widely recognized for its contributions to the evolution of graphic technology, earning accolades such as being listed among top HPC solutions. With its potent blend of power efficiency and high-performance rendering, it serves as a critical component for developers aiming to build next-generation graphics applications.
Designed to meet the growing demand for speed and efficiency in embedded systems, the i.MX RT700 Crossover Microcontroller Unit (MCU) combines high-performance processing with real-time operation capabilities. The RT700 MCU, currently in preproduction, is powered by five computing cores, ensuring unmatched performance in AI-driven and IoT applications. The i.MX RT700 excels with its ability to facilitate complex computations and seamless real-time data processing—a necessity for modern devices requiring quick response and accuracy. This makes it particularly beneficial for edge processing in smart tech solutions, offering a reliable backbone for AI systems and IoT infrastructures. Its comprehensive structure supports advanced multimedia applications, paving the way for innovations across various sectors by enhancing user interactions and overall device capabilities. This aligns it as a prime facilitator of cutting-edge technological growth, offering possibilities for developers to create more intuitive and powerful solutions.
The Badge 2D Graphics module is a dynamic component used extensively in graphics-intensive applications, having shipped over 5 million units. It's designed for seamless integration into multimedia systems, providing stellar performance in handling graphical data and enhancing visual displays. This graphics module supports diverse functionalities, including efficient rendering of graphics, text, and video content, making it versatile for use in a wide array of products that demand high-quality graphical outputs. The Badge 2D Graphics module is particularly beneficial for systems requiring enhanced visual interfaces while ensuring resource-efficient operation. As part of BitsimNOW's IP offerings, this module exemplifies the company's strength in high-volume, quality graphics solutions. Its capabilities make it a preferred choice for industries looking to elevate their product’s user interface experience with reliable and sophisticated graphics technology.
Himax Technologies offers a versatile range of CMOS Image Sensors designed to cater to a multitude of camera applications across industries. Their lineup emphasizes small pixel sensors that deliver high performance while maintaining low power consumption, qualities highly prized for integration into mobile and compact devices. These sensors are equipped with programmable readout modes, adjustable integration times, gain controls, and MIPI serial link interfaces for flexible integration into diverse systems.<br> <br> The Always On Sensor category under Himax stands out with its remarkable power efficiency, functioning within sub-milliwatt power ranges. These sensors enable devices to be perpetually ready to capture images, responding with unparalleled speed thanks to their autonomous operation capabilities. The emphasis on ultra-low power requirements makes them particularly suitable for battery-powered, portable devices looking to incorporate real-time sensor functionality.<br> <br> For markets demanding the highest level of system integration, Himax also offers the Image Sensor SOC line. These systems combine the sensor core with an adaptable image signal processor and control loops, simplifying the camera development process. Such innovations streamline product design, allowing developers to bring high-performance camera solutions to market with less time and complexity.
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 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.
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.
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 represents BrainChip’s effort to provide a complete, event domain neural processing solution. This standalone device features comprehensive AI functionalities, supporting a vast network of 1.2 million neurons and 10 billion synapses. It is versatile in use, functioning independently or as a supportive co-processor across various applications, significantly improving edge AI deployment. BrainChip has integrated this SoC into reference development systems like Akida PCIe and Raspberry Pi, enabling working prototypes and AI system evaluations. Predominantly focused on efficient event-based computing, Akida1000 facilitates few-shot learning on-chip, which is critical for devices needing rapid personalization and adaptation without cloud reliance. Configuration flexibility allows seamless integration into diverse system architectures, backed by MetaTF tools that optimize design and deployment processes. Akida1000’s design ensures that neural processing remains power-efficient while maintaining high performance, critical for upcoming AI-driven smart device landscapes in consumer and IoT domains.
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 D/AVE 2D graphics rendering engine is designed to handle powerful image processing needs. It is exceptionally proficient in executing BLIT functions alongside vector graphics capabilities, enabling it to deliver superior performance in visual computing. This engine is optimized for ultra-low power devices, making it an ideal choice for consumer applications that require effective performance while conserving energy. Its compact architecture allows it to function within minimal resource environments, such as cost-sensitive market segments. Highly adaptable, it supports a broad spectrum of applications ranging from simple user interfaces to more complex graphical requirements on various embedded systems.
Engineered for the digital processing and enhancement of video inputs, the logiISP-UHD Image Signal Processing UltraHD Pipeline offers sophisticated processing capabilities for Ultra High Definition video, including 4K2Kp60 support. It is specifically designed for embedded systems leveraging AMD's Zynq UltraScale+ MPSoC, Zynq 7000 AP SoC, Series 7, and newer FPGA devices.<br><br>This IP core is tailored for scenarios requiring elevated image quality and real-time processing, making it indispensable in modern high-definition video environments. It is highly suitable for broadcast applications, security systems, and any system necessitating enhanced visual clarity and video fidelity.<br><br>The logiISP-UHD stands out by streamlining complex video processing tasks, providing designers with the tools needed to significantly elevate image quality within their applications. By ensuring high-quality video outputs under varying conditions, the IP core supports the creation of superior embedded video solutions.
The D/AVE 3D rendering engine brings immersive graphics capabilities to the forefront, offering full support for OpenGL ES 1.1 and OpenVG 1.01 API. This engine is developed to meet high performance demands, achieving an impressive 8 million triangles per second. Its robust architecture includes edge-based anti-aliasing, enhancing the smoothness and clarity of generated graphics. D/AVE 3D is fine-tuned for high-end graphics implementations across various industries, ensuring that even the most demanding visual applications can be rendered with superior quality and efficiency. This rendering engine is particularly optimal for automotive and consumer electronics markets that demand advanced graphical displays.
This comprehensive framework is designed for embedding multi-camera vision systems utilizing AMD's Versal Adaptive Compute Acceleration Platform (ACAP). The logiREF-ACAP-MULTICAM-ISP HDR Image Signal Processing Framework provides extensive capabilities for integrating multi-camera inputs into a cohesive video processing system.<br><br>Particularly aimed at industries requiring high-definition video input handling, this framework expedites the development of multi-camera systems in automotive, surveillance, and industrial applications. It supports HDR image processing, ensuring that each camera input is optimized for clarity and detail.<br><br>The framework's versatility and robustness make it a go-to solution for developers looking to leverage AMD's ACAP platform, promoting efficiency and innovation in advanced video processing tasks. It provides users with the tools needed to take full advantage of modern imaging technology.
The IMG DXT GPU is tailored specifically for mobile devices, delivering cutting-edge performance while managing the power constraints typical of mobile platforms. This GPU is distinguished by its ability to offer the same kind of ray tracing effects that are usually reserved for high-end desktop GPUs, but at a fraction of the area and power cost. Its architecture allows for superior scalability, enabling manufacturers to incorporate advanced lighting effects without exceeding budgetary or spatial limitations. Built with the Photon architecture, the DXT provides exceptional efficiency and versatile configurations, including multiple Ray Acceleration Clusters for tailored performance levels. This adaptability makes it suitable for a wide range of devices, from top-tier smartphones to other consumer electronics requiring high GPU performance. The DXT’s ability to integrate seamlessly across different devices while maintaining peak performance per watt sets a new benchmark in mobile graphics capabilities. Key to the DXT's performance is its efficient use of cores and memory, paving the way for mobile devices to present visuals that mirror those on larger, less power-restricted devices. This GPU essentially equips mobile developers with the tools needed to push graphics' boundaries, allowing for richer, more immersive content creation and consumption on the go.
The logiVIEW MultiView 3D Video Transformation Engine is an innovative IP core that extends beyond simple video processing by offering advanced image compensation, including fish-eye lens distortion corrections, arbitrary homographic transformations, and video texturing on curved surfaces. Additionally, it supports image stitching from multiple video inputs, enhancing its utility in complex video systems.<br><br>Focused on providing rich visual transformation capabilities, logiVIEW is crafted for applications needing high-quality video output and transformation precision. Its abilities make it a valuable asset in fields like advanced driver-assistance systems (ADAS) and sophisticated surveillance technologies, where video clarity and detail accuracy are paramount.<br><br>Engineers and designers will find its implementation straightforward within systems that demand meticulous video management and modification. Overall, the logiVIEW engine efficiently handles intricate video tasks, facilitating versatile and creative application integrations.
The logiREF-ACAP-VDF is a complete IP design framework that supports the development of embedded multi-camera vision systems using AMD Versal Adaptive SoC. It is tailor-made to work with the logiVID-ACAP-6CAM vision kit, providing a pre-verified reference design that significantly reduces project development time.<br><br>Ideal for applications in advanced driver assistance systems (ADAS), robotics, and machine vision, the framework helps users focus on vision-specific areas rather than starting from scratch. The framework also includes display and LIDAR visualization capabilities, enhancing its utility in complex vision systems.<br><br>With the logiREF-ACAP-VDF framework, users can achieve a higher degree of integration efficiency, ensuring that advanced vision systems are developed swiftly, aligning with modern technological demands and project timelines.
BTREE's 3DNR Image Processing IP is essential for enhancing image clarity through advanced three-dimensional noise reduction techniques. This technology is integral in removing visual noise while preserving important details in images or video streams. The platform's sophisticated algorithms analyze temporal and spatial information to distinguish noise from the actual signal, significantly improving visual quality. Primarily utilized in video applications, this IP is beneficial in situations with low-light conditions or where high frame rates are necessary. With the ability to operate efficiently in real-time processing, BTREE's 3DNR ensures consistency and clarity in each frame, making it suitable for security systems, video conferencing technologies, and mobile computing devices. Efficiency is a core advantage of this IP, as it focuses on delivering high-quality outputs with minimal energy use, supporting a wide range of camera and digital media applications. Its implementation not only reduces motion distortion but also enhances the overall image performance, enabling sharper and clearer visual displays.
MPEG-H Audio System is a cutting-edge audio technology designed for the immersive experiences of modern television and virtual reality platforms. Recognized as a groundbreaking audio system, Fraunhofer IIS developed it to provide an interactive and enveloping audio environment, transforming the way viewers and gamers experience sound in multimedia contexts. Tailored for the demands of both VR and broadcast TV, the system supports a comprehensive 3D sound experience that makes use of state-of-the-art audio encoding. At its core, MPEG-H Audio System allows users to position sound elements freely in a three-dimensional space, enabling an unprecedented level of realism. Whether it's the dramatic soundscapes in film or the all-encompassing audio required for virtual reality games, MPEG-H offers flexibility and precision that cater to a wide audience ranging from everyday users to professional creators. The audio system’s compatibility with the next generation TV standards and its adaptability to various playback environments make it particularly advantageous. Its design seamlessly integrates into existing deployment frameworks, providing dynamic and rich audio experiences without the complexity of previous systems. As such, MPEG-H Audio is poised to redefine the standards of digital audio, making its impact felt across entertainment and content production industries worldwide.
The logiHOG employs advanced HOG/SVM techniques for multiple object detection within video streams, providing effective and accurate real-time image classification capabilities suited for surveillance and security systems.
The logiREF-MULTICAM-ISP HDR ISP Framework provides a comprehensive platform for developing multi-camera systems with HDR capabilities. Designed to manage the full spectrum of Ultra HD video inputs, it supports applications ranging from entry-level AMD Artix FPGAs to advanced AMD Versal adaptive devices.<br><br>The framework's main aim is to simplify and optimize the complicated process of managing multiple camera inputs, specifically emphasizing image signal processing and HDR enhancements. This makes it suitable for automotive, industrial, and surveillance systems that require advanced input handling and video fidelity.<br><br>Leveraging this IP framework enables developers to streamline the integration of multi-camera setups into their systems, ensuring efficient and reliable operation of high-definition video environments. It represents a key tool for those seeking to push the boundaries of traditional video processing solutions.
The logi3D Scalable 3D Graphics Accelerator is a high-performance IP core crafted for AMD's Versal Adaptive SoC and Zynq 7000 SoCs. It enhances graphics processing capabilities for systems that require advanced 3D rendering, supporting industry-standard APIs and ensuring maximum compatibility across different platforms.<br><br>Ideal for gaming, simulation, and professional visualization applications, the logi3D core delivers scalable graphics processing power, effectively handling complex 3D graphics and ensuring smooth rendering and visual fidelity. It is particularly suited for applications where real-time rendering and high-quality 3D graphics are pivotal.<br><br>By providing significant improvements in graphics acceleration, the logi3D core empowers designers and developers to create rich, interactive visual experiences. It offers the scalability needed for a range of applications, ensuring that systems can be developed effectively within chosen platforms.
TicoRAW provides an innovative approach to managing raw imaging data, prioritizing efficiency and quality in sensor data processing. This solution is particularly adapted for high-resolution image capture systems, ensuring minimal latency while maintaining image integrity. It is crafted to support high-bandwidth, high-resolution lines, effectively reducing the processing demands on supporting hardware. Integrating TicoRAW into your systems means leveraging a codec that preserves the fullest detail in raw image data, suitable for both professional and consumer-grade cameras. This ensures that users can benefit from the richness of the raw sensor data, with all the nuanced quality intact, while significantly lowering the data bandwidth required. The technology minimizes power consumption, which is crucial for mobile and embedded applications. Known for its adaptability, TicoRAW can handle advanced image processing tasks, executing everything from the capturing phase to real-time data analysis, recording, and streaming. Its flexibility allows it to interface with a range of imaging sensors and is perfect for fast-paced, high-resolution environments such as medical imaging, satellite surveillance, broadcast, and beyond. By simplifying the interfacing with camera systems, TicoRAW represents the next step in efficient video data handling, facilitating improved image processing pipelines and sensor applications.
The logiBITBLT is a high-efficiency Bit Block Transfer (BLT) 2D graphics accelerator designed for AMD's FPGA and Zynq 7000 AP SoCs. It alleviates computational burdens from the system CPU by handling intensive graphics tasks, enabling enhanced and effective graphic creation.<br><br>This IP core is targeted at applications seeking to deliver engaging visual experiences, such as consumer electronics interfaces and media-rich devices, where rendering speed and quality are essential. It effectively complements the hardware, offering a solution that enhances overall visual performance.<br><br>Incorporating the logiBITBLT accelerator results in smoother operations and heightened graphics capabilities, setting new standards for 2D graphical processing in embedded systems. It empowers system designers to generate sophisticated graphics without sacrificing system performance.
The logiBMP is an advanced graphics accelerator IP core optimized for AMD FPGAs, designed to expedite operations involving bitmaps while supporting perspective accurate renderings for 2.5D graphics scenes. This makes it ideal for rendering dynamic and interactive user interfaces.
The Mali-G78 GPU brings top-tier graphics performance to a wide array of mobile and immersive applications. It is finely tuned to handle intensive workloads such as high-fidelity gaming and advanced machine learning tasks. Built on the innovative Valhall architecture, the Mali-G78 ensures unmatched visuals with significant improvements in energy efficiency and processing power. This GPU offers adaptable scalability, making it a powerful asset for various devices, from flagship smartphones to cutting-edge smart TVs. The design improvements within the Mali-G78 extend to better asynchronous top-level efficiency, enhancing battery life and overall energy management.
Truechip's NoC Coherent Crossbar Silicon IP delivers advancements for chip designers focused on multi-protocol connectivity with reduced latency and chip area. By integrating hardware cache coherency with software-driven maintenance, it streamlines operations within complex network structures. With support for layered and parallel NoC architectures, this IP optimizes data routes, ensuring efficient transfers through customizable memory maps and protocol interfaces, enhancing overall performance and reducing the need for extensive hardware support.
The logiBAYER IP core provides real-time conversion of monochrome Bayer-pattern video from camera CMOS sensors into full-color RGB video. Designed for AMD programmable logic devices, this core facilitates high-quality color processing in camera systems.
TES's Video Input Controller is engineered to handle a variety of input video sources, providing seamless integration into broader electronic systems. Its primary function is to convert incoming video signals into formats suitable for further processing, ensuring minimal latency and maintaining high integrity of video data. The controller's architecture allows extensive compatibility with different video standards, enabling its deployment in diverse applications where video input management is critical. It is ideal for use in industries ranging from consumer entertainment to professional video broadcasting, where reliable and high-quality video input handling is essential.
The D/AVE NX graphics processing unit caters to the highest echelons of graphical rendering, fully compliant with OpenGL ES 2.0 standards and ready for expansion to OpenGL ES 3.x. This GPU is engineered to deliver superior graphics on displays as large as 4k x 4k, making it a prime candidate for advanced visual applications. Its scalability is one of its core strengths, enabling the configuration of shader units and arithmetic logic units (ALUs) per shader unit, finely balancing performance and footprint. This engine is also primed for safety-critical deployments, supporting OpenGL SC 2.0, ensuring reliability in mission-critical applications. Its adaptable nature makes it particularly well-suited for FPGAs and compact microprocessor units, providing customization abilities to meet unique client specifications.
This design framework is optimized for the Xylon logiVID-ZU vision kit, which is based on AMD's Zynq UltraScale+ MPSoC. The logiADAK-VDF-ZU framework provides a thorough solution for engineers developing multi-camera vision applications, leveraging pre-verified camera-to-display reference designs.<br><br>By focusing on vision-specific components of complex applications like driver assistance, machine vision, and robotics, the framework minimizes design time and effort. It is particularly advantageous for projects where rapid development and deployment are crucial.<br><br>Developers of this framework enjoy streamlined processes that integrate numerous cameras into cohesive systems. By using the logiADAK-VDF-ZU, projects can swiftly progress from concept to execution, maximizing both efficiency and adaptation to specific application requirements.
The Warping Engine by TES is designed for applications requiring advanced image processing capabilities, particularly in graphics and video adjustment. This engine efficiently manipulates input visual data, transforming it to accommodate different display requirements and solve unique presentation challenges. Its powerful processing capabilities maintain high-quality visual output, essential for sophisticated video editing and presentation tasks. The engine is highly suitable for use in the automotive industry, consumer electronics, and other sectors where high-precision image tailoring and manipulation are necessary for optimal end-user experiences.
The logiVDET represents advanced capabilities in object classification to detect vehicles accurately within video streams, thus becoming an essential component for traffic management and surveillance systems, enhancing vehicular detection accuracy and system response times.
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