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.
The KL730 is a third-generation AI chip that integrates advanced reconfigurable NPU architecture, delivering up to 8 TOPS of computing power. This cutting-edge technology enhances computational efficiency across a range of applications, including CNN and transformer networks, while minimizing DDR bandwidth requirements. The KL730 also boasts enhanced video processing capabilities, supporting 4K 60FPS outputs. With expertise spanning over a decade in ISP technology, the KL730 stands out with its noise reduction, wide dynamic range, fisheye correction, and low-light imaging performance. It caters to markets like intelligent security, autonomous vehicles, video conferencing, and industrial camera systems, among others.
Designed for high-performance applications, the Metis AIPU PCIe AI Accelerator Card by Axelera AI offers powerful AI processing capabilities in a PCIe card format. This card is equipped with the Metis AI Processing Unit, capable of delivering up to 214 TOPS, making it ideal for intensive AI tasks and vision applications that require substantial computational power. With support for the Voyager SDK, this card ensures seamless integration and rapid deployment of AI models, helping developers leverage existing infrastructures efficiently. It's tailored for applications that demand robust AI processing like high-resolution video analysis and real-time object detection, handling complex networks with ease. Highlighted for its performance in ResNet-50 processing, which it can execute at a rate of up to 3,200 frames per second, the PCIe AI Accelerator Card perfectly meets the needs of cutting-edge AI applications. The software stack enhances the developer experience, simplifying the scaling of AI workloads while maintaining cost-effectiveness and energy efficiency for enterprise-grade solutions.
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
Altek's AI Camera Module integrates sophisticated imaging technology with artificial intelligence, providing a powerful solution for high-definition visual capture and AI-based image processing. This module is tailored for applications where high precision and advanced analytic capabilities are required, such as in security systems and automotive technology. The module is equipped with a broad range of functionalities, including facial recognition, motion detection, and edge computing. It harnesses AI to process images in real-time, delivering insights and analytics that support decision-making processes in various environments. By combining AI with its imaging sensors, Altek enables next-generation visual applications that require minimal human intervention. Altek's AI Camera Module stands out for its high-degree of integration with IoT networks, allowing for seamless connectivity across devices. Its adaptability to different environments and conditions makes it a highly versatile tool. The module's design ensures durability and reliability, maintaining performance even under challenging conditions, thereby ensuring consistent and accurate image capture and processing.
The Metis AIPU M.2 Accelerator Module from Axelera AI is a cutting-edge solution designed for enhancing AI performance directly within edge devices. Engineered to fit the M.2 form factor, this module packs powerful AI processing capabilities into a compact and efficient design, suitable for space-constrained applications. It leverages the Metis AI Processing Unit to deliver high-speed inference directly at the edge, minimizing latency and maximizing data throughput. The module is optimized for a range of computer vision tasks, making it ideal for applications like multi-channel video analytics, quality inspection, and real-time people monitoring. With its advanced architecture, the AIPU module supports a wide array of neural networks and can handle up to 24 concurrent video streams, making it incredibly versatile for industries looking to implement AI-driven solutions across various sectors. Providing seamless compatibility with AI frameworks such as TensorFlow, PyTorch, and ONNX, the Metis AIPU integrates seamlessly with existing systems to streamline AI model deployment and optimization. This not only boosts productivity but also significantly reduces time-to-market for edge AI solutions. Axelera's comprehensive software support ensures that users can achieve maximum performance from their AI models while maintaining operational efficiency.
The AX45MP is engineered as a high-performance processor that supports multicore architecture and advanced data processing capabilities, particularly suitable for applications requiring extensive computational efficiency. Powered by the AndesCore processor line, it capitalizes on a multicore symmetric multiprocessing framework, integrating up to eight cores with robust L2 cache management. The AX45MP incorporates advanced features such as vector processing capabilities and support for MemBoost technology to maximize data throughput. It caters to high-demand applications including machine learning, digital signal processing, and complex algorithmic computations, ensuring data coherence and efficient power usage.
The GH310 offers high-performance 2D sprite graphics capabilities with an emphasis on pixel throughput and minimal gate count. This makes it an excellent choice for applications that require rapid sprite rendering and high pixel density, such as user interfaces and gaming devices. Its optimized architecture supports efficient sprite operations, making it a versatile choice for embedded systems.
The KL720 AI SoC is designed for optimal performance-to-power ratios, achieving 0.9 TOPS per watt. This makes it one of the most efficient chips available for edge AI applications. The SOC is crafted to meet high processing demands, suitable for high-end devices including smart TVs, AI glasses, and advanced cameras. With an ARM Cortex M4 CPU, it enables superior 4K imaging, full HD video processing, and advanced 3D sensing capabilities. The KL720 also supports natural language processing (NLP), making it ideal for emerging AI interfaces such as AI assistants and gaming gesture controls.
The GV380 is a 2D vector graphics GPU optimized for low CPU load and enhanced pixel processing. It conforms to the OpenVG 1.1 standard, making it ideal for applications requiring high-quality vector graphics rendering. This IP enables efficient graphic processing for embedded systems, ensuring that even resource-limited environments can enjoy sophisticated graphical interfaces.
GSHARK is part of the TAKUMI line of GPU IPs known for its compact size and ability to richly enhance display graphics in embedded systems. Developed for devices like digital cameras, this IP has demonstrated an extensive record of reliability with over a hundred million units shipped. The proprietary architecture offers exceptional performance with low power usage and minimal CPU demand, enabling high-quality graphics rendering typical of PCs and smartphones.
The RayCore MC is a revolutionary real-time path and ray-tracing GPU designed to enhance rendering with minimal power consumption. This GPU IP is tailored for real-time applications, offering a rich graphical experience without compromising on speed or efficiency. By utilizing advanced ray-tracing capabilities, RayCore MC provides stunning visual effects and lifelike animations, setting a high standard for quality in digital graphics. Engineered for scalability and performance, RayCore MC stands out in the crowded field of GPU technologies by delivering seamless, low-latency graphics. It is particularly suited for applications in gaming, virtual reality, and the burgeoning metaverse, where realistic rendering is paramount. The architecture supports efficient data management, ensuring that even the most complex visual tasks are handled with ease. RayCore MC's architecture supports a wide array of applications beyond entertainment, making it a vital tool in areas such as autonomous vehicles and data-driven industries. Its blend of power efficiency and graphical prowess ensures that developers can rely on RayCore MC for cutting-edge, resource-light graphic solutions.
MajEQ Pro is an advanced equalizer tailored for professional audio applications, allowing both static and dynamic EQ adjustments to match specific frequency response targets. It handles tasks such as venue correction or adapting to atmospheric changes at live events. This tool encompasses features including high and low-pass filters with variable slopes, tone controls, and unique filter designs such as Bell or Presence filters with customizable gain, frequency, and Q.
Dyumnin's RISCV SoC is a versatile platform centered around a 64-bit quad-core server-class RISCV CPU, offering extensive subsystems, including AI/ML, automotive, multimedia, memory, cryptographic, and communication systems. This test chip can be reviewed in an FPGA format, ensuring adaptability and extensive testing possibilities. The AI/ML subsystem is particularly noteworthy due to its custom CPU configuration paired with a tensor flow unit, accelerating AI operations significantly. This adaptability lends itself to innovations in artificial intelligence, setting it apart in the competitive landscape of processors. Additionally, the automotive subsystem caters robustly to the needs of the automotive sector with CAN, CAN-FD, and SafeSPI IPs, all designed to enhance systems connectivity within vehicles. Moreover, the multimedia subsystem boasts a complete range of IPs to support HDMI, Display Port, MIPI, and more, facilitating rich audio and visual experiences across devices.
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.
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.
The MVUM1000 represents MEMS Vision's leading-edge innovation in ultrasound technology for medical imaging. This compact 256-element linear ultrasound array is designed using state-of-the-art capacitive micromachined ultrasound transducers (CMUTs), allowing for exceptional integration with interface electronics. Known for its energy efficiency and high sensitivity, the MVUM1000 delivers precise acoustic pressure detection, crucial for advanced imaging techniques. Supporting multiple imaging modes such as time-of-flight and Doppler, it is highly suited for applications ranging from point-of-care to cart-based ultrasound systems. The MVUM1000 array, with its 4.5 MHz center frequency and up to 256 elements, strikes a balance between fine resolution and powerful imaging capabilities, critical for medical diagnostics. The array's flexible design includes features like integrated front-end electronics and adjustable voltage inputs, enhancing its versatility in various contexts. Such capabilities not only improve imaging clarity but also support quick deployment in medical devices, further solidifying MEMS Vision's role in medical sensor innovation.
The Universal DSP Library is a versatile and comprehensive solution designed to simplify digital signal processing tasks in FPGA applications. It provides a robust framework for handling complex signal processing requirements, enabling developers to integrate advanced DSP functionalities efficiently into their systems. This library is crafted to offer flexibility and adaptability, supporting a wide range of applications in various industries. This DSP library stands out for its ability to handle diverse signal processing operations with ease. By offering pre-built functions and modules, it reduces the complexity traditionally associated with DSP implementation in FPGA designs. Developers can leverage this library to accelerate their development cycles, ensuring quicker time-to-market for their products. Incorporating the Universal DSP Library into an FPGA design allows for enhanced performance and efficiency, as it optimizes the processing power of FPGAs to manage demanding signal processing tasks. Its design enables seamless integration with existing systems, providing scalable solutions that can adapt to future needs. Overall, this library is an invaluable asset for any project involving digital signal processing on FPGA platforms.
Featuring a shader architecture, the GSV3100 supports OpenGL ES 2.0 and 1.1, as well as OpenVG 1.1, for powerful 3D graphical processing. This IP is ideal for complex rendering tasks in applications requiring sophisticated graphics and animation. It efficiently integrates hardware processing pipelines to handle demanding graphics loads without compromising on performance or energy efficiency.
Combining 2D vector and 3D rendering capabilities, the GV580 is designed for high performance and low power consumption. It supports both OpenVG 1.1 and OpenGLES 1.1 standards, bringing together advanced rendering features suitable for a wide range of graphical applications. This GPU IP is perfect for enhancing device displays with dynamic graphics without overloading the CPU.
NMFx is a specialized audio effect that enhances listening experiences in environments where sound level control is essential. Its principal function is to maintain speech intelligibility even at low volumes, ensuring that dialogue remains clear without the need to overly amplify softer sounds. Concurrently, it suppresses loud noises, such as explosions in movie tracks, to prevent disturbance to others in proximity, like an adjacent room or apartment. This dual functionality makes NMFx ideal for late-night listening or when maintaining a quiet environment is crucial. It strategically balances the audio output, offering listeners a pleasant experience without losing the dynamics of the original sound, thereby making it popular among home entertainment users.
The JPEG XS Encoder/Decoder from Techno Mathematical Co., Ltd. is designed to offer visually lossless, ultra-low latency performance suitable for next-generation 5G applications. This innovative technology supports both still images and real-time video streams, making it ideal for high-quality, large-screen displays and bandwidth-efficient transmission over networks. Its mezzanine compression capabilities are particularly important for minimizing latency without sacrificing image quality, thus serving well in applications where high-speed, high-fidelity data handling is required, such as in broadcasting and professional media production.
The logiCVC-ML is an advanced display controller that supports resolutions up to 2048x2048, tailored for TFT LCD displays. Optimized for AMD's Zynq 7000 AP SoC and FPGAs, this IP core is equipped with software drivers compatible with Linux, Android, and Windows Embedded Compact 7. This versatility ensures the logiCVC-ML can be implemented across a wide array of applications demanding high-resolution display capabilities. With a strong focus on integrating with existing systems, the logiCVC-ML offers multilayer video capabilities, making it ideal for complex display needs in various industries. Its support extends beyond simple display output, accommodating sophisticated graphics operations that enhance user experiences across diverse platforms. The IP core's efficient use of resources ensures minimal impact on overall system performance, allowing developers to allocate resources to other critical functions. The logiCVC-ML thus represents a blend of high performance and resource efficiency, making it a valuable component in any high-resolution display application.
The Prodigy Universal Processor by Tachyum Inc. is a revolutionary advancement in computing technology, seamlessly integrating the functionalities of CPUs, GPUs, and TPUs into a singular, cohesive architecture. This innovative processor is engineered to deliver unparalleled performance, energy efficiency, and space optimization to meet the increasingly demanding needs of AI, high-performance computing, and hyperscale data centers. The Prodigy processor architecture supports up to 18.5x higher performance and 7.5x better performance per watt compared to its competitors, addressing prevalent challenges like excessive power consumption and server inefficiencies in existing data center frameworks. By offering various SKUs, the Prodigy processor can be tailored to a wide array of market needs, facilitating diverse applications and workloads, from high-end HPC to big AI analytics. A standout feature of the Prodigy is its versatile emulation capabilities, allowing seamless integration and evaluation in existing systems with minimal adjustments. The Prodigy provides essential tools for developers, enabling straightforward adaptation of existing applications, which can run on the Prodigy instruction set architecture without modification. This comprehensive approach not only enhances operational efficiency but also accelerates the transition to advanced computing infrastructures.
The Cottonpicken DSP Engine is an advanced digital signal processing core that features micro-coded capabilities suitable for a variety of image processing functions. Designed for high throughput, it can manage Bayer pattern decoding into multiple formats like YUV 4:2:2, YUV 4:2:0, and RGB. Additionally, the engine includes support for specific matrix operations that are cascadeable, providing flexibility in handling complex signal processing tasks. Characterized by its capability to run at a full data clock rate up to 150 MHz, the Cottonpicken DSP Engine is optimal for applications requiring immediate data handling and processing. This core functions as part of a development package, delivered as a closed-source netlist object, ensuring easy integration into larger systems. Its robust architecture is capable of performing detailed filter kernel operations such as 3x3 and 5x5 convolution, essential for high-precision tasks in various imaging solutions. Furthermore, with YUV conversion capacities supporting formats like YCrCb and YCoCg, this DSP engine ensures adaptable performance across various platforms requiring precise digital image manipulation. Given its strong performance profile, the Cottonpicken DSP Engine is ideally suited for embedded systems, where processing speed and accuracy are critical.
The SmartFx Audio Effects Suite is an integrated audio enhancement package that combines several key features aimed at elevating sound output in consumer devices. It provides enhanced sound quality characterized by richer bass, dynamic range control, and a more natural sound experience. The SmartFx suite is highly user-friendly, featuring an intuitive real-time graphical user interface (GUI) that makes sound customization accessible to users of all technical levels. This suite is particularly beneficial for devices requiring dynamic audio adjustments to enhance the listening environment.
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 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 D/AVE 2D core is tailored for delivering optimized 2D graphics performance across a broad range of devices. It supports essential 2D operations such as line drawing, shape filling, and image blitting, making it ideal for applications requiring crisp, clear visuals. This core is highly optimized for low power consumption, making it suitable for battery-operated devices. Moreover, its design ensures scalability, allowing for performance enhancement through additional features or integration with existing systems. The D/AVE 2D core is particularly beneficial for devices such as handhelds, tablets, and industrial equipment requiring robust graphical output with efficient resource use. Built for flexibility, it can integrate seamlessly with different hardware platforms, supporting various interfaces and display types.
The i.MX RT700 Crossover MCU is a powerful preproduction microcontroller designed for AI-enabled edge devices. It harnesses the strength of five computing cores, making it exceptionally well-suited for high-compute tasks and applications requiring significant processing power in compact, efficient designs. This MCU integrates robust security features, ensuring that intelligent edge applications maintain integrity and resilience against potential threats. Its architecture supports diverse functionalities, from real-time processing to advanced signal handling, facilitating a seamless frontier for developing complex, responsive systems. The versatility of the i.MX RT700 makes it ideal for a range of applications, from automotive edge computing environments to smart consumer electronics. Its advanced processing power and flexible architectural design allow developers to push the limits of innovation, delivering smarter solutions with rapid response capabilities.
Korusys's Video Wall System transforms conventional display management with versatile video processing capabilities for large format displays. Featuring support for HDMI and DisplayPort inputs, it allows videos to be displayed across multiple monitors, achieving stunning visual configurations. With the ability to clone, stretch, or independently configure outputs, it is highly adaptable for digital signage and public displays. The Video Wall System integrates EDID parsing for seamless resolution management and includes a comprehensive software API paired with a GUI for effortless system control. Its modular design ensures flexibility, allowing integration into existing AV infrastructures or scalable deployment for larger screens through linking multiple FPGAs.
MajEQ offers a highly adaptable equalization tool aimed at achieving precise frequency response matching. It provides options for both semi-automated and fully automated tuning, which is beneficial for specific applications such as loudspeaker correction. This tool can either be used in a static mode, for fixed audio setups, or a dynamic mode, which continually adjusts for optimal performance in variable acoustic environments.
The IPMX Core represents a next-generation solution tailored for Professional AV use, relying on the ST 2110 standards combined with NMOS control. It supports comprehensive audio and video streaming, including compressed and uncompressed formats, with exceptionally low latency. Compatible with a variety of network and hardware configurations, this core empowers AV professionals to deliver high-quality, interoperable IP-based media using contemporary network speeds and advanced encryption protocols for secure content distribution.
Designed for the latest graphics processing applications, the G-Series Controller supports GDDR6 memory, delivering remarkable throughput necessary for demanding multimedia tasks. Its architecture allows for data speeds up to 18 Gbps per pin and supports dual-channel implementation. The G-Series Controller integrates with a standard DFI 5.0 interface, offering hardware auto-initialization and robust error detection and correction capabilities for maintaining data integrity under heavy loads.
ZIA Stereo Vision is designed to offer superior depth perception and object detection by employing advanced stereo vision algorithms. This system enhances the capabilities of autonomous vehicles and drones, providing precise imaging for real-time decision-making applications. Built with a focus on accuracy and computational efficiency, it supports a range of stereoscopic camera systems, enabling better navigation and environmental interaction.
The MPEG-H Audio System brings a new dimension to audio experiences in TVs and Virtual Reality (VR), offering users an immersive and interactive sound environment. Known for its advanced capabilities, this system allows for personalized audio adjustments which enable listeners to modify elements of the sound to their liking, such as changing the volume of dialogues or commentary. This customization ensures that the audio experience can be tailored to fit personal preferences, leading to enhanced viewer engagement and satisfaction. The MPEG-H Audio System is crucial for the next generation of broadcast services, being particularly adept at delivering high-quality, multi-dimensional sound over a range of devices. This readiness for future audio trends aligns perfectly with modern media consumption needs, where immersive experiences are increasingly demanded. In terms of functionality, the MPEG-H system supports not only traditional stereo and surround sound but also advanced setups through headphones, soundbars, and television speakers, accommodating varying listener environments. Another significant aspect of the MPEG-H Audio System is its integration into various international broadcast standards, underscoring its versatility and wide applicability. It brings unrivaled clarity and dynamics to television broadcasts and VR simulations, pushing the boundaries of sound technology and augmenting the audio-visual narrative of both everyday and cinematic content. Its implementation heralds a shift toward more engaging and personalized media consumption experiences.
SINR is designed to effectively minimize background noise, ensuring that the main audio content is both clear and intelligible. It operates efficiently by focusing on reducing unwanted noise, thus improving the user's overall listening experience. This feature is especially vital in settings where clear communication is essential, and noise pollution needs to be significantly reduced.
VoxBoost is engineered to enhance speech clarity within an audio mix, elevating the prominence of spoken words against background sounds. This technology is particularly beneficial in noisy environments where distinguishing speech is critical, such as in public address systems or portable devices used in crowded settings.
The Akida1000 Reference SoC combines BrainChip's acclaimed Akida IP into a ready-to-implement System-on-Chip solution that serves as a perfect platform for rapid deployment of AI applications. This reference SoC is tailored to facilitate the integration of BrainChip's technology into a broad spectrum of devices ranging from mobile gadgets to high-performance AI edge servers. The SoC includes all essential components enabling seamless deployment, including memory integration, connectivity options, and comprehensive development support. By leveraging Akida1000, companies can accelerate the adoption of AI by reducing development time and costs associated with custom SoC design. This platform maintains all the pioneering features of the Akida IP, such as energy efficiency, real-time processing, and local data analysis, ensuring optimal performance in varied environments. Its robust framework supports various AI models, particularly those requiring real-time decision-making capabilities, such as in smart home ecosystems, security systems, and in-car infotainment applications.
The SHA-3 Crypto Engine offers a robust hardware acceleration solution for cryptographic hashing functions. Its design prioritizes high throughput and efficient resource utilization, complying with NIST’s FIPS 202 standards. The core supports various SHA-3 hash functions including SHA-3-224, SHA-3-256, SHA-3-384, and SHA-3-512, alongside Extendable Output Functions (XOF) like SHAKE-128 and SHAKE-256. This comprehensive support makes it a versatile tool for ensuring data integrity and authentication in a multitude of applications. A key feature of the SHA-3 Crypto Engine is its protection against timing-based side channel attacks, offering a secure cryptographic environment. Fully synchronous in design, it operates within a single clock domain, ensuring stability and reliability across different platforms. Its applications span various domains such as secure boot engines, IPsec and TLS/SSL protocol engines, and even blockchain technologies. The core has been extensively verified and includes features such as automatic byte padding, making it an adaptable solution across a wide range of applications. It’s designed to be implemented on both FPGAs and ASICs, ensuring flexibility and adaptability in various deployment scenarios.
Badge 2D Graphics offers an advanced solution for 2D graphical displays, suitable for systems requiring comprehensive graphical representations. These graphics are developed for seamless integration into platforms such as Xilinx, showcasing exceptional versatility and reliability with more than 5 million units shipped. The product is highly adaptable, enabling varied graphical tasks and delivering consistent performance across applications. This graphics solution is engineered to support a multitude of functionalities, including video display, textual representation, and multimedia interfacing. It stands out in delivering high-performance visual processing, making it a preferred choice for systems where graphical display quality is essential. Designed with the flexibility to adapt to a variety of multimedia needs, Badge 2D Graphics ensures that visual representation in platforms is both vivid and contextually relevant. The robustness of this solution allows it to integrate smoothly with diverse operational architectures, enhancing the visual display capabilities of embedded systems and consumer products.
The HPC (High-Performance Computing) Platform by SEMIFIVE is constructed to meet the demands of advanced computational tasks in hyperscale data centers and cloud server environments. Embracing leading-edge process nodes, this platform is optimized for high throughput, low latency operations essential for AI, network processors, and other intensive applications. Featuring top-tier processor arrangements, such as ARM's quad-core Cortex-A53 and enhanced memory interfaces such as GDDR6, the platform is built to support demanding processing tasks. It also offers PCIe Gen5 connectivity, enhancing data transfer rates and bolstering infrastructure capabilities for handling big data and complex computations. With design flexibility and efficiency, SEMIFIVE's HPC Platform allows organizations to maximize their computational resources, facilitating the development and deployment of next-generation computing solutions. By reducing barriers to high-performance infrastructure deployment, it empowers businesses to stay ahead in a data-driven world.
D/AVE 3D is designed to bring powerful 3D graphic capabilities to an array of consumer and industrial devices. This core supports essential 3D rendering functions such as transformations, lighting, shading, and texture mapping. It is engineered for low power operations, making it suitable for portable and embedded devices where energy efficiency is crucial. The design of the D/AVE 3D ensures compatibility with various graphics APIs, thereby enabling easy integration into existing graphical frameworks. Ideal for applications ranging from consumer electronics to automotive displays, this module can handle intensive graphic processing tasks with ease. Its adaptability and robustness make it a popular choice for developers aiming to implement advanced visual experiences in their products.
The M3000 Graphics Processor is engineered for high-demand 3D graphics tasks found in today's digital environments. It achieves superior graphical performance with efficient power consumption, driven by its support for sophisticated shading models and 3D rendering capabilities. The M3000 excels in providing immersive visual experiences, making it a critical component in gaming consoles, multimedia platforms, and high-end automotive displays where precise and rapid graphic rendering is needed.
The v-MP6000UDX Visual Processing Unit is a highly versatile processor featuring a unified processing architecture. This unit specializes in enabling real-time execution of the most intensive neural network tasks with exceptional power efficiency and a minimal silicon footprint. It supports a broad array of processing needs, effectively integrating deep learning, computer vision, image processing, and video compression on a single architecture. Designed to meet the rigorous demands of modern applications, the v-MP6000UDX offers unparalleled performance with its single software-programmable platform. Developers benefit from reduced development complexity, faster speed to market, and increased product lifespans. The processor can efficiently map and execute all layers of neural networks, easing the burden on software engineers and allowing seamless transitions across different machine learning frameworks. The versatility and high efficiency of the v-MP6000UDX make it an ideal choice for industries such as automotive, gaming, and mobile devices. Its ability to seamlessly integrate into system-on-chip designs further broadens its appeal, offering enhanced optimization opportunities for developers and significantly reducing integration overhead.
The H.264 Encoder from VISENGI stands as one of the market's most rapid solutions, capable of processing greater than 4K resolution at 60 frames per second, even on mid-range FPGA devices. This encoder is engineered for high-efficiency video compression, crucial for applications requiring the transmission or storage of high-quality video while minimizing bandwidth use. Its design ensures minimal delay and supports a wide array of devices, making it versatile for various digital video applications. This IP core is specifically optimized for performance across diverse hardware configurations, including both FPGA and ASIC setups. The architecture of the encoder includes advanced features that facilitate reduced power consumption while maintaining peak operational efficiency. This makes it an ideal choice for mobile and embedded systems where resources may be limited but high-quality video processing is required. Another significant advantage of VISENGI's H.264 Encoder is its scalability and flexibility. Whether used in a live broadcast setting or during complex post-production editing, its robust construction ensures consistent performance. The encoder integrates seamlessly with existing video infrastructures, providing an essential tool for professionals aiming to deliver high-definition media content.
The Keccak Hash Engine is a versatile IP core known for its role in guaranteeing data security through a variety of cryptographic operations. This core is not just limited to hashing functions but extends its capabilities to include authentication, encryption, and pseudo-random number generation. Fundamental to its design is the use of the sponge construction and the innovative Keccak-f cryptographic permutation. This IP core stands out for its flexibility, allowing for customization in hash output lengths and security levels. Standardized under widely recognized protocols like NIST's FIPS 202, the Keccak Hash Engine has undergone thorough scrutiny ensuring its robustness. The design is optimized for seamless integration into existing systems, operating efficiently within a single clock domain. The Keccak Hash Engine’s applications extend across various sectors, providing essential security functions for systems like blockchain, PRNG, and more. Its configurability means it can adapt to numerous scenarios, maintaining high security standards as required by different applications.
The D/AVE NX IP is an advanced graphics module designed to deliver unparalleled performance for next-generation visual applications. Its capability to manage both 2D and 3D graphics processing from a single engine distinguishes it from traditional solutions, offering a unified approach to high-density graphics tasks. The D/AVE NX supports a wide range of graphics operations such as advanced shader techniques, anti-aliasing, and detailed texture mapping, making it suitable for sophisticated visual computing requirements. This IP ensures optimized hardware utilization, enabling developers to achieve higher precision graphics with minimal power consumption. Its modular architecture allows for significant customization, making it adaptable to specific application needs while providing seamless integration with diverse hardware platforms. Used extensively in high-demand areas like gaming, virtual reality, and automotive displays, the D/AVE NX harmonizes performance with efficiency.
The logiVIEW is a versatile video and image processing core tailored to address fish-eye lens distortion, perform arbitrary homographic transformations, and apply video texturing on curved surfaces. It is crucial for image stitching multiple video inputs into a coherent visual output, making it a preferred choice for applications needing advanced visual processing capabilities. Designed to integrate into a range of systems, the logiVIEW core allows for significant enhancements in visual presentation by correcting distortions and transforming videos to desired formats. Its power is especially relevant in automotive, security, and media applications, where visual clarity and accuracy are paramount. With its ability to handle complex visual scenarios, the logiVIEW positions itself as an indispensable tool for any project focused on elevating video output quality and versatility. Its advanced processing capabilities ensure seamless integration into modern multimedia projects, transforming visual data with efficiency and precision.
Silhouse offers a suite of rapid machine vision solutions that enhance automation processes across multiple industries. By incorporating advanced image processing and AI technologies, it improves the accuracy and efficiency of industrial systems, enabling faster decision-making and operational efficiencies. This solution is pivotal in transforming how visual data is processed and utilized, facilitating tasks such as automated inspection, object recognition, and quality control. By employing robust algorithms, Silhouse can handle complex data sets, providing comprehensive analysis and insights for optimizing industrial functions. Industries employing Silhouse benefit from reduced operational costs and improved production quality, as it minimizes human error and maximizes precision in automated tasks. Its versatility makes it adaptable across a range of sectors, including manufacturing, logistics, and smart city implementations, underscoring its essential role in modern industrial ecosystems.
The Warping Engine from TES is engineered to provide flexible image transformation capabilities across various electronic devices. It focuses on advanced geometric corrections, including rotation, scaling, and perspective adjustments, allowing for precise alignment and representation of visual data. This engine is particularly useful in display systems where image distortions must be corrected for clarity and accuracy, such as in projectors and camera systems. Optimized for efficiency, the Warping Engine ensures minimal resource consumption while maintaining high-quality output. Its integration into devices where visual integrity is critical greatly enhances system functionality and user satisfaction. By offering detailed control over image presentation, the Warping Engine supports innovative applications that demand exceptional visual standards.
Join the world's most advanced semiconductor IP marketplace!
It's free, and you'll get all the tools you need to discover IP, meet vendors and manage your IP workflow!
No credit card or payment details required.
Join the world's most advanced AI-powered semiconductor IP marketplace!
It's free, and you'll get all the tools you need to advertise and discover semiconductor IP, keep up-to-date with the latest semiconductor news and more!
Plus we'll send you our free weekly report on the semiconductor industry and the latest IP launches!