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
Designed for high-performance applications, the Metis AIPU PCIe AI Accelerator Card employs four Metis AI Processing Units to deliver exceptional computational power. With its ability to reach up to 856 TOPS, this card is tailored for demanding vision applications, making it suitable for real-time processing of multi-channel video data. The PCIe form factor ensures easy integration into existing systems, while the customized software platform simplifies the deployment of neural networks for tasks like YOLO object detection. This accelerator card ensures scalability and efficiency, allowing developers to implement AI applications that are both powerful and cost-effective. The card’s architecture also takes advantage of RISC-V and Digital-In-Memory Computing technologies, bringing substantial improvements in speed and power efficiency.
The Metis AIPU M.2 Accelerator Module is a cutting-edge AI processing unit designed to boost the performance of edge computing tasks. This module integrates seamlessly with innovative applications, offering a robust solution for inference at the edge. It excels in vision AI tasks with its dedicated 512MB LPDDR4x memory, providing the necessary storage for complex tasks. Offering unmatched energy efficiency, the Metis AIPU M.2 module is capable of delivering significant performance gains while maintaining minimal power consumption. At an accessible price point, this module opens up AI processing capabilities for a variety of applications. As an essential component of next-generation vision processing systems, it is ideal for industries seeking to implement AI technologies swiftly and effectively.
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 G-Series Controller from MEMTECH is conceived for graphics-heavy computing environments, balancing high bandwidth and low power demands. This controller supports GDDR6 devices at speeds reaching up to 18 Gbps. It incorporates dual-channel support, advanced scheduling, and error detection ensuring robust data throughput with minimal latency. Suitable for applications such as gaming, video processing, and AI, the G-Series Controller facilitates efficient integration and supports various power-saving features.
ZIA Stereo Vision (SV) represents DMP's cutting-edge depth sensing solution, engineered to offer high-precision stereo vision for various AI applications. It's designed to process stereo images for advanced depth mapping, utilizing 4K inputs to facilitate distance estimation via stereo matching algorithms like Semi-Global Matching (SGM). Through this technique, ZIA SV ensures that distance information is extracted accurately, a critical capability for applications like autonomous mobile robots or advanced imaging systems. Pre- and post-processing optimization provides the ZIA SV with the tools necessary to refine depth estimates and ensure high accuracy. It supports 8-bit greyscale inputs and outputs a disparity map with an accuracy up to 0.8%, provided by advanced filtering techniques that enhance precision while maintaining a compact form factor crucial in embedded systems. This IP core integrates smoothly into systems requiring reliable depth measurement, utilizing efficient AMBA AXI interfaces for easy integration into diverse applications. With capabilities to support a wide range of hardware platforms and favorable performance-to-size ratios, the ZIA Stereo Vision core embodies DMP's philosophy of compact, high-performance solutions for smarter decision-making in machine vision applications.
The M3000 Graphics Processor is DMP's offering for high-power 3D graphics processing designed for energy-efficient performance. It features sophisticated graphics processing capabilities based on DMP’s proprietary Musashi 3D graphics architecture. This architecture is tailored to deliver state-of-the-art graphics performance, specifically aligning with complex computation requirements found in VR and AR applications, alongside other visual computing demands. The M3000 is crafted to achieve optimal Power, Performance, and Area (PPA) metrics, supporting OpenGL ES 3.0 to ensure compatibility with cutting-edge visual processing standards. Its adaptability stems from a flexible shader cluster architecture that can be adjusted to meet varying client needs for performance and size. This flexibility extends to its implementational capacity across diverse devices such as ASICs, ASSPs, SoCs, and more. Technically, the M3000 supports outputs at resolutions reaching 4k x 2k, with interfaces like AXI 3/4 and APB for communication, suited for numerous applications ranging from IoT devices to automotive infotainment systems. This processor redefines efficiency and power in graphics acceleration, rendered for seamless integration into modern HMI systems.
The MVUM1000 features a 256-element linear ultrasound array tailored for medical imaging applications. Capitalizing on capacitive micromachined ultrasound transducers (CMUT), it offers superior sensitivity and low power consumption. The array can be integrated with front-end electronics and supports multiple imaging modes, including time-of-flight and Doppler. This versatility, combined with minimal energy requirements, makes it well-suited for advanced medical imaging, including portable and traditional ultrasound 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.
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.
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.
Tower Semiconductor’s CMOS Image Sensor technology stands as an industry leader, driven by its advanced pixel design and high-end imaging solutions. This technology caters to an ever-growing demand for quality image sensing in a variety of fields including automotive, industrial, and medical applications. Utilizing innovative pixel technology, Tower Semiconductor excels in producing sensors that promise superior image sharpness and low-light performance, crucial for high-definition imaging systems. The company's CMOS Image Sensors deliver unparalleled customization capabilities, ensuring each sensor meets precise application requirements. By offering robust manufacturing processes and distinct pixel architectures, Tower Semiconductor provides customers with personalized solutions that enhance their product performance and market competitiveness. Advanced features include backside illumination and stitching technology, which cater to a variety of imaging needs from small handheld devices to large-format applications. Tower Semiconductor maintains its edge through significant R&D in sensor technology, ensuring their image sensors embody the latest technological advancements. The process is available on 8” and 12” wafers, allowing for extensive versatility in device fabrication and facilitating large-scale production for leading global markets, reinforcing their commitment to quality and innovation in imaging systems.
The HDR Core is engineered to deliver enhanced dynamic range image processing by amalgamating multiple exposures to preserve image details in both bright and dim environments. It has the ability to support 120dB HDR through the integration of sensors like IMX585 and OV10640, among others. This core applies motion compensation alongside detection algorithms to mitigate ghosting effects in HDR imaging. It operates by effectively combining staggered based, dual conversion gain, and split pixel HDR sensor techniques to achieve realistic image outputs with preserved local contrast. The core adapts through frame-based HDR processing even when used with non-HDR sensors, demonstrating flexibility across various imaging conditions. Tone mapping is utilized within the HDR Core to adjust the high dynamic range image to fit the display capabilities of devices, ensuring color accuracy and local contrast are maintained without introducing noise, even in low light conditions. This makes the core highly valuable in applications where image quality and accuracy are paramount.
MajEQ is a versatile equalization tool engineered to optimize audio outputs by precisely matching frequency response target curves. It can automatically or semi-automatically adjust to achieve the desired sound, whether for correcting loudspeaker outputs or enhancing audio playback quality across various devices. This tool is highly beneficial in both fixed installations, like venue sound systems, and dynamic settings where responsive environmental adjustments are necessary. Users can tailor sound responses in real-time, ensuring that the audio output remains balanced and high-fidelity, regardless of external factors. MajEQ is a valuable asset for audio manufacturers looking to add a layer of sophistication to their products. By improving sound quality and adaptability, this tool not only meets but often exceeds user expectations for audio performance, making it integral for high-end audio solutions and consumer electronics alike.
The RayCore MC is a state-of-the-art graphics processing unit specifically designed for real-time ray tracing and path tracing. It offers a unique combination of speed and efficiency, catering to the demands of high-quality rendering in modern digital applications. This GPU leverages advanced technology to accelerate the rendering process, allowing for realistic lighting and textures in graphics without compromising performance. Incorporating Siliconarts' proprietary ray tracing algorithms, the RayCore MC excels in delivering lifelike visuals essential for industries such as gaming, virtual reality, and film production. Its low power consumption makes it an ideal choice for devices that require high graphics performance but are constrained by power limitations. Additionally, this GPU is crucial for applications that demand real-time interactive graphics, providing developers with the tools to craft immersive visual experiences. The RayCore MC's modular design supports seamless integration into various hardware architectures, making it versatile for a wide array of products. Its technology is a testament to Siliconarts' commitment to innovation, as it continues to set the standard for GPU performance in cutting-edge digital environments.
Designed for wide-angle camera applications, the GL3004 is a comprehensive fisheye image processor that excels in distorting corrections necessary for wide-angle lenses. The processor is equipped with a sophisticated suite of dewarping modes that include spherical panorama and perspective projection, improving visual output quality significantly. The GL3004 integrates robust image signal processing capabilities, supporting input resolutions up to 3 megapixels while providing hardware functions such as wide dynamic range (WDR) and on-screen display (OSD) capabilities. It supports various output formats, making it extremely flexible for different imaging needs. This processor is suited for environments demanding high-quality image correction and clarity, such as surveillance systems or automotive cameras. It facilitates the deployment of advanced visual enhancements, ensuring realistic and sharp image outputs in dynamic scenarios.
The Heimdall Toolbox is a specialized IP for low-power image processing tasks, crafted to handle rapid image interpretation and enhance efficiency in processing visual data. This toolbox facilitates the execution of custom-tailored algorithms designed for managing low-resolution images efficiently over a 64x64 pixel grid through an SPI interface. Engineered for applications that demand minimal energy consumption while maintaining effective processing capabilities, the Heimdall Toolbox supports fast data throughput and precise control over imaging processes. Its framework is optimized to deliver high-performance outcomes in embedded systems where power constraints and rapid response times are paramount. Incorporating the Heimdall Toolbox into a development project ensures that companies can manage image data processing needs adeptly while maintaining stringent power budgets. This solution is particularly advantageous for designing systems in portable or battery-powered devices where efficient resource utilization is critical.
Lightelligence's PACE is an advanced photonic computing platform that integrates a 64x64 optical matrix multiplier into a silicon photonic chip alongside a CMOS microelectronic chip. This fully integrated system employs sophisticated 3D packaging technology and contains over 12,000 discrete photonic devices. The PACE platform is designed to operate at a system clock of 1GHz, making it ideal for ultra-low latency and energy-efficient applications. The platform's architecture is powered by the Optical Multiply Accumulate (oMAC) technology, which is essential for performing optical matrix multiplications. Input vectors are initially extracted from on-chip SRAM and converted into analog values, which are then modulated optically. The resulting optical vector propagates through an optical matrix to generate an output vector, which undergoes conversion back to the digital domain after being detected by an array of photodetectors. PACE aims to tackle computational challenges, particularly in scenarios like solving Ising problems, where interactions are encoded in an adjacency matrix. The photonic processing capabilities of PACE are geared towards speeding up numerous applications, including bioinformatics, route planning, and materials research, promising significant breakthroughs in chip design and computational efficiency.
The SmartFx Audio Effects Suite is a comprehensive set of tools designed to elevate the audio experience on consumer devices. By integrating advanced audio processing capabilities, it delivers natural and fuller sound that includes enhanced bass and dynamic range control. Users can enjoy an easy-to-use graphical interface that allows real-time adjustments, making it a versatile solution for audio content enhancement. One of the standout features of SmartFx is its ability to adapt the audio output to different listening environments, providing consistent quality whether at home or on the go. The suite employs sophisticated algorithms to ensure the audio maintains intelligibility and clarity, even when faced with lossy codec challenges or data throttling. SmartFx is perfect for manufacturers looking to integrate premium sound capabilities into their products. By utilizing this suite, devices can offer improved audio fidelity, meeting the high expectations of modern consumers who demand rich, immersive sound experiences.
The COMXpress Embedded Module is a high-performance system-on-module designed using Intel's Stratix 10 SoC FPGA, recognized for its advanced processing capabilities. This SoM meets the demands of applications requiring both substantial transceiver bandwidth and robust core performance. Its integration is emphasized for the compact and industrial markets where size and efficiency are paramount. With a COM Express Basic form factor, this module is suitable for high-performance computing (HPC), data analytics, and intelligent visual processing tasks. The Stratix 10 architecture facilitates the handling of high data throughput while maintaining energy efficiency, which is vital for embedded systems constrained by space and power. The module's flexibility is enhanced by its offering of a carrier board with extended functionalities, making it adaptable to various industry requirements. Key industries employing the COMXpress Module include machine vision, medical systems, and industrial automation, where its compact design and high processing power provide a significant advantage.
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.
Akida1000 represents the front line of BrainChip’s AI solutions, offering a compact yet powerful processing platform for innovative applications. This SoC is particularly adept at executing neural network tasks, leveraging event-based processing for remarkable energy efficiency and reduced latency in AI operations. With its strong neuronal and synaptic capacity, Akida1000 processes an extensive range of AI computations independently from cloud systems, ensuring privacy and security in data handling. This autonomy is particularly advantageous in real-time scenarios where edge devices must react instantaneously without centralized processing delays. Akida1000 supports prototyping and scale-up options through its compatibility with BrainChip’s development kits. This allows developers to tailor AI solutions to specific needs, ensuring optimal design, quick integration, and efficient deployment in various intelligent systems.
The Akida1000 Reference SoC is BrainChip's foundational AI processor, tailored to provide a complete event-based neural processing solution. Engineered to operate as an embedded accelerator, Akida1000 performs a diverse range of AI computations at the edge, removing the necessity for cloud interaction. With capabilities for both standalone operations and as an adjunct processor, the SoC caters to multiple application scenarios. Featuring 1.2 million neurons and 10 billion synapses, the Akida1000 SoC is robust, allowing real-time AI operations across various edge devices. Its design facilitates seamless integration into existing systems, ensuring efficient data-to-event conversion and neural network execution without saturating CPU resources. Compatible with a broad array of hardware, including PCIe and Raspberry Pi development kits, Akida1000 promotes rapid prototyping and deployment. This strategic compatibility, combined with on-chip learning capabilities, positions the Akida1000 SoC as a pivotal component for developers aiming to future-proof their edge AI applications.
Creonic specializes in high-performance Demodulation IP Cores designed to serve the most demanding communication environments. These demodulators are equipped to handle various standards, including DVB-S2X and CCSDS, optimized for applications ranging from satellite communications to high-frequency trading networks. Each demodulation core is engineered for high efficiency, supporting wide bandwidths and offering robust interference resistance. This makes them particularly suitable for complex communication systems where signal integrity can be threatened by bandwidth limitations and noise. The cores are built with MIMO detection capabilities, ensuring high data throughput and spectral efficiency. Creonic’s expertise ensures that these demodulation solutions are easily integrable with existing network infrastructures, supporting both current and future communication protocols effectively.
Badge 2D Graphics is a robust graphics solution that has been adopted in over five million devices worldwide. The IP is versatile, used extensively in displays for appliances and automotive systems. It delivers high-quality text and video graphics integration, which is ideal for embedded systems needing superior graphics capabilities without consuming large amounts of processing power. This IP has been fundamental in enhancing the visual displays in multiple applications from consumer electronics to industrial systems.
Himax's CMOS Image Sensors provide cutting-edge solutions for a diverse range of applications. Their sensors are designed with small pixel technology, delivering high-resolution imaging capabilities ideally suited for smart devices and camera applications. The CMOS sensors exhibit ultra-low power consumption, making them highly suitable for battery-powered devices that require always-on operation. These sensors cater to the fast-growing demands of mobile and consumer electronics, providing enhanced image quality with programmable readout modes, adjustable gain, and integration time. With 10-bit data output enabled through a MIPI serial link, they ensure rapid data transfer and processing efficiency vital for camera technologies. The ARM-based signal processing architecture of Himax's CMOS sensors allows for high adaptability and integration with image signal processors. Their cost-effective design and scalable features have made Himax a trusted supplier for leading device manufacturers, affirming their place at the forefront of imaging sensor technology.
The HPC Platform from SEMIFIVE focuses on high-performance computing applications, offering architectural and computational rigor needed for data-intensive tasks. This platform is tailored for processing big data, enabling quick data analytics, and supporting hyperscale data centers. With advanced SoC designs that integrate high-speed interfaces and accelerators, the HPC Platform is capable of supporting the most demanding computational environments. It prioritizes efficiency, scalability, and reliability, ensuring seamless performance in both cloud and edge environments.
MajEQ Pro is an advanced equalization tool designed explicitly for professional audio applications, capable of achieving precise frequency response alignment. This tool allows for both static and dynamic EQ adjustments, providing users with unparalleled control over their sound systems, whether for live events or in-studio recordings. With MajEQ Pro, operators can seamlessly switch between modes, adjusting to static venue acoustics or responding dynamically to changing auditory environments in real-time. The tool supports high-frequency accuracy, essential for maintaining sound quality in diverse acoustic conditions, such as outdoor venues where frequency responses fluctuate. The implementation of MajEQ Pro in professional settings elevates the capabilities of audio systems, delivering superior sound quality and flexibility. For audio engineers and businesses involved in audio production, this tool aligns with the demands for high precision and reliability, ensuring that auditory outputs are always of the highest standard.
The 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.
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.
SlimPort DisplayPort to MIPI-DSI Controllers, such as the ANX7538/39, are integral components for next-generation 4K AR/VR head-mounted displays. These controllers enable the smooth integration of DisplayPort inputs into MIPI-DSI outputs, offering up to 120FPS for immersive experiences in AR/VR. With their low power consumption and high performance, these controllers are ideal for compact and demanding devices, ensuring outstanding visual quality and interface compatibility. These products are optimized for virtual and augmented reality display technology, providing the necessary output characteristics required to support dual MIPI outputs crucial for high fidelity, wide-view displays. The controllers incorporate features to ensure low power usage while handling complex video signal conversions efficiently, making them practical for mobile and immersive applications. The controllers are specifically designed for use in the latest VR headsets and other cutting-edge visual display devices, supporting configurations that include dual-mode capabilities for supporting diverse signal formats. Their ability to maintain high-resolution outputs without excessive power drain is a unique advantage for developers in the AR/VR field, enhancing the end-user experience with detailed visuals and quick refresh rates.
Truechip’s NoC Coherent Crossbar Silicon is designed for efficient integration of various protocol bus supportive devices, with a focus on reducing latency, power, and spatial requirements. The IP supports hardware cache coherence, vital for maintaining synchronization across connected devices. It offers comprehensive protocol support and diverse configuration capabilities, ensuring it meets the demands of high-performance semiconductor designs. The IP is provided with user-friendly integration tools, complemented by significant customer support to streamline its adoption in multiple applications.
The Video Input Controller is designed to streamline video capture processes for a variety of applications. It supports a wide set of input standards, ensuring seamless integration with different video sources and devices. This IP specializes in handling high-bandwidth video streams, providing efficient video decoding and processing to meet the demanding needs of modern video applications. Whether it's part of a consumer electronics setup or used in professional video equipment, the Video Input Controller offers dependability and performance for high-quality video handling.
The MPEG-H Audio System offers users an immersive audio experience perfect for both television broadcasts and virtual reality environments. It delivers high-quality 3D soundscapes that enhance user interaction by adjusting to different audio preferences and spatial arrangements. The system is remarkably flexible, accommodating a wide array of audio configurations and delivering exceptional clarity and localization accuracy, which greatly enhances the viewer's engagement and sense of presence.
Vivante GPUs are designed to provide high-performance graphics processing capabilities for a wide range of applications, from mobile devices to automotive displays. These GPUs are equipped with advanced features that support 2D and 3D graphics, ensuring smooth and efficient rendering of complex visuals. With flexibility in configuration, they cater to diverse market demands, optimizing power efficiency and performance. The Vivante GPU series is known for its compatibility with various graphics APIs, making it a versatile choice for developers looking to create immersive experiences. It includes support for high-definition visuals and enhanced mathematical processing for better visual analytics and simulations. The architecture is scalable, ensuring it meets the requirements of different devices, providing outstanding graphics quality without compromising on power consumption. Engineered to balance performance with energy efficiency, these Vivante GPUs are ideal for next-generation devices. They offer extensive configurability options, allowing developers to tailor the GPUs to specific needs, whether it's for a handheld gaming device or a high-resolution automotive interface. The aim is to deliver an impeccable visual journey to end-users, positioning Vivante as a pioneer in graphics processing technology.
The logiREF-DFX-IDF presents a dynamic function exchange design framework for AMD's programmable SoC/FPGA chip environments. This framework leverages DFX technology to enable feature swapping, offering developers the ability to reconfigure parts of a continuously operational chip. It provides a unique approach to the modular customization of FPGA functions, supporting advanced system capabilities without downtime. This functionality is key in evolving infrastructures where adaptability is crucial, such as aerospace systems and advanced communications, where dynamic feature adjustments can be necessary for optimized operation. logiREF-DFX-IDF allows for efficient resource management within FPGA systems, supporting the ever-changing technological landscape. As part of Xylon's strategic offerings, this framework advances the scope of FPGA design, providing developers with the tools to innovate in real-time, blending flexibility with advanced technological demands.
The NoC Coherent Mesh Silicon IP from Truechip enables seamless connectivity for devices supporting various bus protocols, with an added advantage of reduced latency, power, and area. It maintains hardware coherency, simplifying the integration process by minimizing the need for extensive wiring. This IP is developed in Verilog RTL, ensuring clean synthesis and comprehensive code coverage through expert verification. It supports multiple levels of interconnections and diverse protocol configurations, paired with a straightforward GUI for efficient configuration.
The logiBITBLT is a dedicated 2D graphics accelerator that excels in reducing CPU load and enhancing the generation of effective computer graphics through AMD FPGAs and Zynq 7000 AP SoCs. This core provides a platform for developing visually appealing graphics without overwhelming the system's processing resources. Its primary focus is on executing rapid bit block transfers, integral to producing high-quality graphics displays suitable for various applications, including gaming consoles, industrial machines, and multimedia devices. The increased efficiency offered by logiBITBLT makes it an attractive option for developers looking to optimize graphics processing. Xylon supports this IP core with comprehensive resources and integration pathways, facilitating easy adoption into existing systems and allowing for enhanced visual output with reduced system burden.
Optimized for the AMD Versal Adaptive SoC and AMD Zynq 7000 SoC, the logi3D Scalable 3D Graphics Accelerator provides developers with the tools needed to implement high-quality 3D graphics in their applications. It supports standard industry APIs, allowing integration into a broad range of existing systems that rely on sophisticated 3D rendering. The scalability feature of logi3D makes it adaptable for various project needs, ensuring precise and efficient graphics processing that aligns with the project's scope. Whether in gaming, simulation, or real-time visualization, this core enhances every project's graphic performance, providing unparalleled visual experiences. Backed by its compatibility with AMD development tools, the logi3D enhances the productivity of development teams by allowing them to focus on creative tasks without struggling with technical compatibility issues. This valuable IP core is an ideal choice for any project requiring outstanding 3D graphics capabilities.
The logiVIEW MultiView 3D Video Transformation Engine is a sophisticated video and image processing IP core designed to handle a range of complex visual effects. This core addresses the compensation of fisheye lens distortions, performs arbitrary homographic transformations, and textures videos on curved surfaces, making it invaluable for advanced video and graphics projects. Ideal for applications requiring precise image adjustments, logiVIEW also offers capabilities for stitching images from multiple video sources, enhancing its utility across various fields such as automotive, surveillance, and entertainment sectors. Its comprehensive functionalities facilitate high-quality visual transformations essential for modern multimedia applications. As part of Xylon's logicBRICKS offerings, the logiVIEW core is supported by extensive documentation and support, enabling quick integration and efficient use within embedded systems. This robust IP core is tailored to deliver versatile video processing across AMD's FPGA and SoC product lines, providing unmatched flexibility and performance.
This IP core, logiBMP, is tailored to fast-track bitmap operations providing optimized 2.5D graphics scenes. Designed for AMD FPGAs, it enhances operational speed through perspective correct renderings, vital for applications that require dynamic visual interactivity such as user interfaces for smart devices or advanced gaming. Its capacity for speedy and accurate rendering makes it crucial in systems where visual performance directly impacts user experiences. Developers can leverage the core’s powerful graphics manipulations to deliver high-standard graphical outputs. With the backing of Xylon’s extensive support framework, the logiBMP is easily integrated into various systems, providing dynamic rendering capabilities that enhance any project requiring sophisticated graphics solutions.
Specialized for the AMD Zynq 7000 AP SoC, the logiFDT is a face tracking engine that identifies and follows facial features within video sequences in real-time. It offers a comprehensive range of data including full 3D head pose, gaze direction, and facial expressions, valuable for dynamic video-based monitoring applications. This IP core is essential in developing advanced augmented reality applications, interactive gaming environments, and security systems where facial analysis is pivotal. Its real-time processing capabilities ensure that systems built around it are both responsive and accurate in data capture. Although the logiFDT has been succeeded by the ARTIEYE suite, it represents a key component within Xylon's portfolio that addresses face tracking and detection needs, laying the groundwork for further innovations in visual data analysis.