All IPs > Graphic & Peripheral > GPU
Graphics Processing Units (GPUs) have revolutionized the way we interact with digital content, making it more immersive and visually engaging. At the core of modern graphics technology lies GPU semiconductor IPs, which are integral to delivering outstanding visual performance across a wide array of devices. Whether it’s for rendering the latest video game graphics, enhancing multimedia playback, or powering complex computational tasks, these semiconductor IPs play a crucial role.
GPU semiconductor IPs are designed to efficiently handle a myriad of operations, predominantly focusing on parallel processing. This capability allows GPUs to process multiple tasks simultaneously, making them ideal for graphics rendering, high-definition video playback, and complex simulations. This category includes essential components like shaders, compute engines, and video encoders, which work in harmony to deliver seamless graphics experience.
Products within the GPU semiconductor IP category serve a diverse range of industries. In consumer electronics, GPUs are deployed in smartphones and tablets to enhance user interfaces and enable applications like augmented reality. In high-performance computing, they are an essential part of servers and workstations for tasks such as artificial intelligence, machine learning, and big data analytics. Furthermore, the gaming industry benefits from these semiconductor IPs by providing photorealistic graphics and smooth gameplay.
Selecting the right GPU semiconductor IP can significantly impact the performance and efficiency of the final product. With the rapid advancement of display technologies and the increasing demand for richer visual content, developers and manufacturers seek the most innovative and adaptable GPU IP solutions to remain competitive. By incorporating cutting-edge semiconductor IPs, they can deliver the next generation of visually stunning and energy-efficient products.
The KL730 AI SoC is equipped with a state-of-the-art third-generation reconfigurable NPU architecture, delivering up to 8 TOPS of computational power. This innovative architecture enhances computational efficiency, particularly with the latest CNN networks and transformer applications, while reducing DDR bandwidth demands. The KL730 excels in video processing, offering support for 4K 60FPS output and boasts capabilities like noise reduction, wide dynamic range, and low-light imaging. It is ideal for applications such as intelligent security, autonomous driving, and video conferencing.
Origin E1 neural engines are expertly adjusted for networks that are typically employed in always-on applications. These include devices such as home appliances, smartphones, and edge nodes requiring around 1 TOPS performance. This focused optimization makes the E1 LittleNPU processors particularly suitable for cost- and area-sensitive applications, making efficient use of energy and reducing processing latency to negligible levels. The design also incorporates a power-efficient architecture that maintains low power consumption while handling always-sensing data operations. This enables continuous sampling and analysis of visual information without compromising on efficiency or user privacy. Additionally, the architecture is rooted in Expedera's packet-based design which allows for parallel execution across layers, optimizing performance and resource utilization. Market-leading efficiency with up to 18 TOPS/W further underlines Origin E1's capacity to deliver outstanding AI performance with minimal resources. The processor supports standard and proprietary neural network operations, ensuring versatility in its applications. Importantly, it accommodates a comprehensive software stack that includes an array of tools such as compilers and quantizers to facilitate deployment in diverse use cases without requiring extensive re-designs. Its application has already seen it deployed in over 10 million devices worldwide, in various consumer technology formats.
Designed for high-performance environments such as data centers and automotive systems, the Origin E8 NPU cores push the limits of AI inference, achieving up to 128 TOPS on a single core. Its architecture supports concurrent running of multiple neural networks without context switching lag, making it a top choice for performance-intensive tasks like computer vision and large-scale model deployments. The E8's flexibility in deployment ensures that AI applications can be optimized post-silicon, bringing performance efficiencies previously unattainable in its category. The E8's architecture and sustained performance, alongside its ability to operate within strict power envelopes (18 TOPS/W), make it suitable for passive cooling environments, which is crucial for cutting-edge AI applications. It stands out by offering PetaOps performance scaling through its customizable design that avoids penalties typically faced by tiled architectures. The E8 maintains exemplary determinism and resource utilization, essential for running advanced neural models like LLMs and intricate ADAS tasks. Furthermore, this core integrates easily with existing development frameworks and supports a full TVM-based software stack, allowing for seamless deployment of trained models. The expansive support for both current and emerging AI workloads makes the Origin E8 a robust solution for the most demanding computational challenges in AI.
The Origin E2 family of NPU cores is tailored for power-sensitive devices like smartphones and edge nodes that seek to balance power, performance, and area efficiency. These cores are engineered to handle video resolutions up to 4K, as well as audio and text-based neural networks. Utilizing Expedera’s packet-based architecture, the Origin E2 ensures efficient parallel processing, reducing the need for device-specific optimizations, thus maintaining high model accuracy and adaptability. The E2 is flexible and can be customized to fit specific use cases, aiding in mitigating dark silicon and enhancing power efficiency. Its performance capacity ranges from 1 to 20 TOPS and supports an extensive array of neural network types including CNNs, RNNs, DNNs, and LSTMs. With impressive power efficiency rated at up to 18 TOPS/W, this NPU core keeps power consumption low while delivering high performance that suits a variety of applications. As part of a full TVM-based software stack, it provides developers with tools to efficiently implement their neural networks across different hardware configurations, supporting frameworks such as TensorFlow and ONNX. Successfully applied in smartphones and other consumer electronics, the E2 has proved its capabilities in real-world scenarios, significantly enhancing the functionality and feature set of devices.
Origin E6 NPU cores are cutting-edge solutions designed to handle the complex demands of modern AI models, specializing in generative and traditional networks such as RNN, CNN, and LSTM. Ranging from 16 to 32 TOPS, these cores offer an optimal balance of performance, power efficiency, and feature set, making them particularly suitable for premium edge inference applications. Utilizing Expedera’s innovative packet-based architecture, the Origin E6 allows for streamlined multi-layer parallel processing, ensuring sustained performance and reduced hardware load. This helps developers maintain network adaptability without incurring latency penalties or the need for hardware-specific optimizations. Additionally, the Origin E6 provides a fully scalable solution perfect for demanding environments like next-generation smartphones, automotive systems, and consumer electronics. Thanks to a comprehensive software suite based around TVM, the E6 supports a broad span of AI models, including transformers and large language models, offering unparalleled scalability and efficiency. Whether for use in AR/VR platforms or advanced driver assistance systems, the E6 NPU cores provide robust solutions for high-performance computing needs, facilitating numerous real-world applications.
The Chimera GPNPU series stands as a pivotal innovation in the realm of on-device artificial intelligence computing. These processors are engineered to address the challenges faced in machine learning inference deployment, offering a unified architecture that integrates matrix, vector, and scalar operations seamlessly. By consolidating what traditionally required multiple processors, such as NPUs, DSPs, and real-time CPUs, into a single processing core, Chimera GPNPU reduces system complexity and optimizes performance. This series is designed with a focus on handling diverse, data-parallel workloads, including traditional C++ code and the latest machine learning models like vision transformers and large language models. The fully programmable nature of Chimera GPNPUs allows developers to adapt and optimize model performance continuously, providing a significant uplift in productivity and flexibility. This capability ensures that as new neural network models emerge, they can be supported without the necessity of hardware redesign. A remarkable feature of these processors is their scalability, accommodating intensive workloads up to 864 TOPs and being particularly suited for high-demand applications like automotive safety systems. The integration of ASIL-ready cores allows them to meet stringent automotive safety standards, positioning Chimera GPNPU as an ideal solution for ADAS and other automotive use cases. The architecture's emphasis on reducing memory bandwidth constraints and energy consumption further enhances its suitability for a wide range of high-performance, power-sensitive applications, making it a versatile solution for modern automotive and edge computing.
GV380 provides advanced vector graphics capabilities with a focus on OpenVG 1.1 compliance. This GPU utilizes a fourth-generation architecture designed to reduce CPU load while maximizing pixel processing efficiency. GV380 targets embedded systems that require efficient and seamless vector graphics rendering, significantly reducing the processing burden on the main CPU. By delivering high pixel performance, this IP is instrumental in enabling enhanced human-machine interfaces and improving graphical user experiences on embedded platforms.
The Mixed-Signal CODEC offered by Archband Labs is engineered to enhance the performance of audio and voice devices, handling conversions between analog and digital signals efficiently. Designed to cater to various digital audio interfaces such as PWM, PDM, PCM conversions, I2S, and TDM, it ensures seamless integration into complex audio systems. Well-suited for low-power and high-performance applications, this CODEC is frequently deployed in audio systems across consumer electronics, automotive, and edge computing devices. Its robust design ensures reliable operation within wearables, smart home devices, and advanced home entertainment systems, handling pressing demands for clarity and efficiency in audio signal processing. Engineers benefit from its extensive interfacing capabilities, supporting a spectrum of audio inputs and outputs. The CODEC's compact architecture ensures ease of integration, allowing manufacturers to develop innovative and enhanced audio platforms that meet diverse market needs.
Combining 2D and 3D rendering capabilities, GV580 is engineered to optimize both OpenVG 1.1 and OpenGLES 1.1 graphics standards. This IP integrates high-performance rendering with low power consumption and minimal CPU dependency, making it suitable for embedded systems demanding advanced graphical capabilities. The IP enables immersive graphical experiences and applications that range from high-definition user interfaces to complex scenes in automotive and consumer electronics. By merging advanced graphics technology with efficient energy use, GV580 is a robust choice for multifaceted embedded graphics applications.
GSHARK is a family of GPU cores targeted for embedded devices, such as digital cameras and automotive systems. Known for its high performance and low power consumption, GSHARK effectively minimizes the CPU load while maintaining outstanding graphic rendering capabilities. This solution supports high reliability, proven by millions of shipments within commercial silicon. The architecture of GSHARK adapts PC, smartphone, and console-grade graphics technologies to embedded systems, enhancing the user experience in human-machine interfaces. Its capability to handle dynamic graphics with low resource usage makes it an ideal choice for embedded systems.
DMP’s ZIA Stereo Vision solution is engineered for depth perception and environmental sensing, leveraging stereo image inputs to compute real-time distance maps. This technology applies stereo matching techniques such as Semi-Global Matching (SGM) to accurately deduce depth from 4K resolution images, paving the way for precision applications in autonomous vehicles and robotic systems. The system employs pre- and post-processing techniques to optimize image alignment and refine depth calculations, achieving high accuracy with low latency. By interfacing through the AMBA AXI4 protocol, it ensures easy integration into existing processing chains, requiring minimal reconfiguration for operation. DMP’s expertise in small footprint, high-performance IP allows the ZIA Stereo Vision to deliver industry-leading depth perception capabilities while maintaining a compact profile, suitable for embedded applications needing robust environmental mapping.
The KL630 AI SoC embodies next-generation AI chip technology with a pioneering NPU architecture. It uniquely supports Int4 precision and transformer networks, offering superb computational efficiency combined with low power consumption. Utilizing an ARM Cortex A5 CPU, it supports a range of AI frameworks and is built to handle scenarios from smart security to automotives, providing robust capability in both high and low light conditions.
Designed for sprite graphics, the GH310 IP focuses on delivering high pixel processing capabilities while maintaining a minimal gate count. This efficiency makes it an ideal solution for embedded systems where space and power efficiency are critical. With its ability to balance high performance and low resource usage, GH310 is perfect for applications that require consistent and rapid 2D image rendering. It helps maintain performance even under demanding conditions, enhancing user experiences in devices ranging from consumer electronics to automotive displays.
The Arria 10 System on Module (SoM) is designed with a focus on embedded and automotive vision applications, leveraging the robust capabilities of the Arria 10 SoC devices. Packed in a compact form factor of 8 cm by 6.5 cm, this module incorporates a multitude of interfaces, offering immense flexibility and a wide array of functionalities suitable for high-performance tasks. This SoM integrates an Altera Arria 10 FPGA with 160 to 480 KLEs along with a Cortex A9 Dual Core CPU, ensuring efficient computational performance. It features a sophisticated power management system and support for dual DDR4 memory interfaces, optimizing power distribution and memory efficiency for safety-critical applications which demand precision and reliability. The Arria 10 SoM is crafted to maximize data throughput, with capabilities such as PCIe Gen3 x8 and 10/40 GBit/s Ethernet interfaces, alongside dedicated clocking arrangements for minimized jitter. Supporting high-speed data transmissions via multiple LVDS lanes and USB interfaces, it's engineered to handle demanding operations in sophisticated systems requiring rapid processing speeds and expansive interfacing.
The GSV3100 is a robust shader architecture 3D processing unit that supports OpenGL ES 2.0 and 1.1, along with OpenVG 1.1. This powerful IP enables the integration of significant graphical processing within embedded systems, supporting advanced graphics applications such as gaming and interactive interfaces. Its comprehensive features make it suitable for both 3D and advanced vector graphics, delivering high-quality visuals while maintaining energy efficiency, thus catering to a wide array of multimedia applications.
The M3000 Graphics Processor from Digital Media Professionals is a high-performance graphics processing unit engineered for embedded devices. It combines superior efficiency with advanced scalability, making it ideal for applications requiring dynamic and intricate graphical computations like VR and AR. Utilizing DMP's Musashi architecture, this GPU achieves top standards in power, performance, and area efficiency (PPA). The design supports OpenGL ES 3.0, delivering outstanding 3D graphics through advanced compute capabilities. Its configurable shader-class structure allows customization to meet specific client performance and size requirements. The M3000 excels in resource-intensive environments, harmonizing heavyweight processing needs with minimal power consumption, thus facilitating applications from mobile devices to automotive infotainment systems. This processor illustrates DMP's commitment to providing cutting-edge graphics solutions for diverse and demanding technological landscapes.
The ATEK367P4 functions as a versatile phase shifter component designed for RF systems working between 2 GHz to 4 GHz. This analog phase shifter provides an extensive phase range adjustable from 0 to 375 degrees, maximizing flexibility in phase alignment applications. It has a low insertion loss of 3 dB, ensuring minimal signal degradation during the shifting process. Encased in a 4×4 mm QFN package, it provides a compact footprint, enhancing its usability in space-constrained designs such as phased array antennas and electronic warfare systems. The phase shifter operates with variable control voltage, offering ease of integration with existing signal processing frameworks. ATEK367P4 is integral for applications demanding precise phase adjustments, notably in aerospace and defense communication systems where accuracy and agility are imperative. Its design facilitates seamless integration, ensuring reliability and performance consistency in complex signal processing tasks.
The DPU Networking Solution from Corigine features the Agilio family of products that focus on enhancing server-based networking. This solution is designed for data centers and service providers who require a robust platform for managing complex networking demands, including virtual network functions such as security and load balancing.<br> <br> Agilio's architecture takes full advantage of both hardware and software developments, offering significant reductions in capital expenditures by completely offloading datapaths from compute nodes using Open vSwitch. This not only restores valuable CPU resources to applications but also improves service levels and ROI. With support for up to 2 million security policies and throughput capabilities of 100Gb/s, Agilio’s SmartNICs perform efficiently while consuming minimal CPU power.<br> <br> The DPU Networking Solution is versatile, offering seamless integration with existing cloud management systems, such as OpenStack, without needing hardware updates. The solution’s commitment to innovation allows it to adapt to evolving open-source networking standards, making it an ideal choice for future-proofing network infrastructure.
The Hyperspectral Imaging System from IMEC offers an advanced portable solution for comprehensive spectral analysis. By employing cutting-edge sensor technology combined with powerful optics, it captures a broad spectrum of light. This system is instrumental in industries ranging from agriculture to healthcare. It provides precise imaging capabilities, enabling users to confidently conduct critical assessments such as plant health monitoring, mineral detection, or even advanced medical diagnostics. Hyperspectral technology bridges the gap between large-scale economic efficiency and intricate analysis, paving the way for new applications across fields by offering unprecedented spectral resolution.
xT CDx is an advanced genomic profiling solution used for comprehensive tumor and normal matched testing in oncology. With a focus on solid tumors, xT CDx leverages extensive gene coverage to aid in clinical decision-making. The system utilizes high-depth sequencing to provide actionable insights, aligning genomic findings with targeted therapy options. The platform is renowned for its substantial coverage of exons and is accredited for detecting a wide array of variants that contribute significantly to personalized medicine. As an in vitro diagnostic system, xT CDx is designed to serve as a companion diagnostic tool for oncologists, particularly in tailoring treatments that align with existing therapeutic guidelines. Its sophisticated analytical capabilities ensure that oncologists have the support they need to match patient profiles with clinical trials and approved treatments promptly. This facilitates a genomic-centric approach, integrating DNA sequencing insights into the broader clinical workflow. Incorporating both tumor and normal tissue comparisons, xT CDx is able to discern hereditary traits that might influence cancer treatment. This dual-approach testing enhances the diagnosis accuracy and optimizes treatment pathways, setting a new standard in oncology precision testing.
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 KL520 AI SoC by Kneron marked a significant breakthrough in edge AI technology, offering a well-rounded solution with notable power efficiency and performance. This chip can function as a host or as a supplementary co-processor to enable advanced AI features in diverse smart devices. It is highly compatible with a range of 3D sensor technologies and is perfectly suited for smart home innovations, facilitating long battery life and enhanced user control without reliance on external cloud services.
Korusys' Video Wall Display Management System is engineered to process and display video content across an array of monitors with high precision and flexibility. Utilizing both Display Port and HDMI inputs, the system allows the presentation of video on multiple screens, supporting configurations up to 4 outputs. This capability is particularly beneficial for digital signage and large-scale public displays. The solution offers several configuration options, including cloning, stretching and bezel compensation, to tailor the video output according to specific display arrangements. It supports high resolutions up to 3840x2400p60, ensuring sharp and clear visual presentations. Ease of use is further enhanced through a user interface that facilitates easy control and configuration. By leveraging FPGA technology, the Video Wall Display Management System exhibits low latency and reliable performance crucial for real-time display applications. Whether in commercial or public settings, such as conferences or exhibitions, this system ensures seamless synchronization across multiple screens, improving the visual experience significantly.
The HUMMINGBIRD by Lightelligence is an innovative optical Network-on-Chip processor that integrates photonic and electronic dies through advanced vertically stacked packaging technologies. This architecture provides a pathway to overcome conventional digital network limitations, particularly the 'memory wall.' With a 64-core domain-specific AI processor, HUMMINGBIRD uses a cutting-edge waveguide system to propagate light-speed signals, drastically reducing latency and power requirements compared to traditional electronic networks. This high-performance device serves as the communication backbone for data centers, facilitating data management and interconnect topology innovations. HUMMINGBIRD exploits the power of silicon photonics to offer a dense all-to-all data broadcast network that enhances the performance and scalability of AI workloads. HUMMINGBIRD's robust integration into PCIe form factors allows easy deployment onto industry-standard servers, and when paired with the Lightelligence Software Development Kit, it can significantly optimize AI and machine learning processes. This integration fosters a higher utilization of computing power and alleviates complexities associated with mapping workloads to hardware.
The RayCore MC is a state-of-the-art real-time path and ray-tracing GPU that delivers high-definition, photo-realistic graphics with exceptional energy efficiency. Utilizing advanced path tracing technology, this GPU excels in rendering complex 3D images by simulating natural light behaviors such as global illumination and soft shadows. Its small form factor and low-power architecture make it ideal for mobile and embedded devices, supporting a broad range of high-end applications from gaming to augmented reality. Optimized with a MIMD (Multiple Instruction, Multiple Data) architecture, the RayCore MC supports independent parallel computation, enabling effective real-time path and ray tracing regardless of the graphic complexity. As a fully hardwired solution, it ensures linear scalability, enhancing graphics performance as it scales up in multi-core configurations. This GPU is designed to cater to the high demands of photo-realistic rendering in movies, education, simulations, and more. The RayCore MC uniquely supports immersive game environments and high-intensity virtual applications. Its sophisticated hardware design and support for advanced features facilitate cost-effective, low-power graphics solutions, making it an industry leader in cutting-edge GPU technology.
Kneron's KL530 introduces a modern heterogeneous AI chip design featuring a cutting-edge NPU architecture with support for INT4 precision. This chip stands out with its high computational efficiency and minimized power usage, making it ideal for a variety of AIoT and other applications. The KL530 utilizes an ARM Cortex M4 CPU, bringing forth powerful image processing and multimedia compression capabilities, while maintaining a low power footprint, thus fitting well with energy-conscious devices.
Digital Media Professionals' ZIA Image Signal Processing (ISP) engine is tailored for high-performance image optimization, handling a variety of image sensors and conditions. It is designed to enhance image quality while maintaining low noise levels, crucial for applications in demanding environments such as automotive and surveillance. The engine supports high dynamic range (HDR) and dynamic range compression (DRC), vital for capturing detailed images under varied lighting conditions. This ISP effectively processes signals from high-sensitivity image sensors, such as IMX390, to deliver clear images even in challenging environments featuring fog, glare, or low light. Furthermore, ZIA ISP brings versatility to modern imaging systems by providing support for advanced image processing tasks like de-mosaicing, lens correction, and color adjustments. It stands as a core component for achieving high-fidelity image recognition and scene understanding across numerous smart camera applications.
Trifecta-GPU is a pioneering family of PXIe/CPCIe GPU modules that deliver high performance computing through NVIDIA RTX A2000 Embedded GPUs. These GPUs offer substantial compute acceleration and are designed for modular Test & Measurement (T&M) and Electronic Warfare (EW) applications. The platform is easy-to-program, supporting a wide range of frameworks like MATLAB, Python, and C/C++, making it a versatile choice for demanding signal processing, AI-based signal classification, geolocation, and other advanced computing needs. The Trifecta-GPU boasts 8GB of GDDR6 DRAM and can achieve up to 8.3 FP32 TFLOPS of peak compute performance. It uses the PCIe Express 4.0 interface, ensuring robust connectivity and performance across various applications. By supporting both single and dual-slot configurations, it provides flexibility in systems with varying power and thermal dissipation constraints. With its remarkable power efficiency, the Trifecta-GPU becomes a vital component for systems requiring high signal resolution and is adept at handling complex computations needed for low probability of intercept signal detection among other tasks. This makes it an ideal choice for semiconductor and PCB testing, failure prediction, and more, under both Windows and Linux environments.
Designed for high power efficiency, the KL720 AI SoC achieves a superior performance-per-watt ratio, positioning it as a leader in energy-efficient edge AI solutions. Built for use cases prioritizing processing power and reduced costs, it delivers outstanding capabilities for flagship devices. The KL720 is particularly well-suited for IP cameras, smart TVs, and AI glasses, accommodating high-resolution images and videos along with advanced 3D sensing and language processing tasks.
RegSpec by Dyumnin is an innovative control configuration and status register generator designed to streamline the design process for complex systems. RegSpec supports a range of input data formats such as SystemRDL, IP-XACT, CSV, Excel, XML, or JSON. It can generate comprehensive output including Verilog RTL, System Verilog UVM, SystemC header files, and detailed documentation in HTML, PDF, RTF, Word, and Frame formats. This flexibility allows designers to address complex synchronization, interrupt, and pulse generation features with ease.\n\nFurthermore, RegSpec is equipped to handle advanced CCSR register design edge cases, making it the only tool of its kind that fully supports such comprehensive features industry-wide. It also simplifies the verification process by generating UVM-compatible code and RALF file formats, while also offering C/C++ header file generation for firmware and advanced system modeling.\n\nRegSpec enhances interoperability with other CSR tools by supporting the standard import/export of SystemRDL and IP-XACT formats, while also accommodating XML, CSV, and Excel custom formats. It also saves its data in a JSON format, facilitating easy integration with custom scripts. Its multifaceted capabilities make it a key asset for designers seeking efficient, comprehensive register specification solutions.
The ATEK552 is a high-power Gallium Nitride (GaN) Power Amplifier with exceptional output capabilities. Operating within the range of 3 GHz to 17 GHz, this amplifier delivers a notable output power of 6 watts. With a gain of 21 dB, the ATEK552 is crafted to boost signal levels efficiently in demanding RF environments. Deprecated for its robust performance, the ATEK552 can adapt seamlessly into various applications due to its flexible power supply requirements, with Vdd set at 28V and a current draw of 510 mA. Its die-based construction facilitates easy integration into larger systems, making it a suitable choice for bands requiring high power amplification. This power amplifier is ideal for use in telecommunications, defense systems, and aerospace applications, where dependable amplification and high power are crucial. Its solid performance metrics ensure reliability and efficiency, supporting advanced communications infrastructure and secured data transmission.
The RAIV is a flexible and high-performing General Purpose GPU (GPGPU), fundamental for industries experiencing rapid transformation due to the fourth industrial revolution—autonomous vehicles, IoT, and VR/AR sectors. Built with a SIMT (Single Instruction Multiple Threads) architecture, the RAIV enhances AI workloads with high-speed processing capabilities while maintaining a low-cost construct. This semiconductor IP supports diverse machine learning and neural network applications, optimizing high-speed calculations across multiple threads. Its high scalability allows tailored configurations in core units, effectively balancing performance with power efficiency dependent on application needs. The RAIV is equipped to handle 3D graphics processing and AI integration for edge computing devices, reinforcing its place in advanced technological development. Additionally, the RAIV's support for OpenCL offers compatibility across various heterogeneous computing platforms, facilitating versatile system configurations. Its optimal performance in AI tasks is further extended for use in metaverse applications, presenting a comprehensive solution that unifies graphics acceleration with AI-enhanced computational operations.
Catalyst-GPU is a line of NVIDIA-based PXIe/CPCIe GPU modules designed for cost-effective compute acceleration and advanced graphics in signal processing and ML/DL AI applications. The Catalyst-GPU leverages the powerful NVIDIA Quadro T600 and T1000 GPUs, offering compute capabilities previously unavailable on PXIe/CPCIe platforms. With multi-teraflop performance, it enhances the processing of complex algorithms in real-time data analysis directly within test systems. The GPU's integration facilitates exceptional performance improvements for applications like signal classification, geolocation, and sophisticated semiconductor and PCB testing. Catalyst-GPU supports popular programming frameworks, including MATLAB, Python, and C/C++, offering ease-of-use across Windows and Linux platforms. Additionally, the Catalyst-GPU's comprehensive support for arbitrary length FFT and DSP algorithms enhances its suitability for signal detection and classification tasks. It's available with dual-slot configurations, providing flexibility and high adaptability in various chassis environments, ensuring extensive applicability to a wide range of modern testing and measurement challenges.
InPsytech's Display Interface IP supports a wide range of display technologies, including DP 1.4, HDMI, and LVDS. These interfaces are vital for high-definition visual data transmission, catering to applications in consumer electronic devices and professional displays. The Display Interface solutions emphasize quality, ensuring crisp, clear image rendering and reliable connectivity.
Granite SemiCom's Sensor Interface Boards are crafted to enhance connectivity with various sensor types. These boards are compatible with small-board computers like the Beagle-Bone Black and Raspberry Pi, facilitating integration of 24-bit A/D converters, temperature/humidity sensors, and accelerometers via I2C and SPI interfaces. Each board includes essential components such as real-time clocks and EEPROMs, with customization options for specific applications. Their compatibility with a wide range of sensors makes them an invaluable asset for monitoring applications requiring precision and adaptability.
The SFA 300 is designed for scalable quad-channel video and data processing, allowing for the high-capacity handling of multiple data streams simultaneously. Its scalable nature makes it suitable for diverse applications ranging from advanced multimedia systems to complex data analytics, ensuring steady data throughput and optimal performance. The architecture supports the simultaneous processing of video and data, making it ideal for high-demand environments such as video surveillance and multimedia streaming.
Himax offers an extensive range of display drivers specially designed for large-sized panels, catering to a diverse set of applications from monitors to large-screen TVs. Their products facilitate exceptional control over screen elements, enhancing picture quality and viewer experience. The drivers integrate various functionalities like timing control and signal processing, ensuring seamless synchronization of screen refresh rates and vivid color rendering. By offering a consolidated solution with features like source drivers, gate drivers, and operational amplifiers, Himax's display drivers support both analog and digital displays. These features are crucial for achieving high-resolution output that modern consumers expect. The drivers are highly integrated to enable efficient power management and cost-effective manufacturing. The large-scale application of these drivers in consumer electronics and automotive displays showcases their versatility and adaptability. Himax continues to innovate to meet modern display demands, emphasizing energy efficiency and superior graphical performance.
IMST's wireless solutions cater to the demand for customized radio modules, a critical component in modern communication systems. These solutions are developed to meet the specific needs of clients, offering flexibility from the initial design phase through to manufacturing. The custom radio modules provide seamless incorporation into various device architectures. With expertise in critical areas such as RF hardware, digital components, and communication software, IMST ensures that each module is tailored for its unique application, delivering both performance and efficiency. These bespoke solutions facilitate innovations in consumer electronics, telecommunication infrastructures, and more, enabling enhanced connectivity and operational effectiveness. IMST's dedication to quality and precision in their radio systems offers clients a reliable partner in navigating the complexities of modern wireless communication demands.
The mobile handset display drivers by Himax are engineered to bring top-tier performance to small and medium displays found in smartphones and portable devices. These drivers are crucial in providing vivid color reproduction and high refresh rates, ensuring an optimal user experience for mobile applications. They combine multiple functions like source driving, gate control, and timing management into a compact design, tailored for mobile handsets. Built with integration in mind, these display drivers incorporate essential circuitry such as frame buffers and DC-DC converters to help manage power efficiently while maintaining clarity and continuity in display outputs. The compact integration supports the current demands for thinner, more energy-efficient mobile devices that still deliver superior screen performance. Additionally, their adaptable design allows manufacturers to easily incorporate the drivers into various handset models, supporting a wide range of operating conditions and ensuring compatibility with different display technologies. This adaptability signifies Himax's commitment to staying at the cutting edge of mobile technology and enhancing user interface solutions.
The D/AVE 2D graphics engine from TES Electronic Solutions is a versatile rendering IP core capable of supporting a wide range of 2D graphics applications. Designed with efficiency in mind, this IP core delivers high-performance rendering suited for devices requiring rich graphical interfaces, such as automotive dashboards, consumer electronics, and industrial controls. Equipped with comprehensive BLIT functions and vector graphics support, the D/AVE 2D ensures enhanced graphical output with minimal resource consumption, making it highly suitable for systems with stringent power and performance requirements. Its modular design allows for customization, enabling users to adjust the IP parameters to better fit their application challenges. The D/AVE 2D's highly adaptable architecture ensures flexibility and ease of integration into existing systems, providing scalability options for various performance needs. As a proven solution in the graphics IP domain, it excels in enhancing user interfaces by delivering smooth and high-quality rendering across diverse application areas.
EMPIRE XPU is an advanced 3D electromagnetic simulation tool designed for solving complex electromagnetic field challenges. It focuses on time-domain modeling which makes it particularly efficient for antennas, microwave circuits, and integrated chip designs. This powerful tool is known for its speed and accuracy, allowing users to tackle intricate problems that traditional techniques would take significantly longer to solve. One of the standout features of EMPIRE XPU is its ability to produce reliable results in a fraction of the time of comparable software. It employs cutting-edge algorithms that leverage parallel processing, making it an invaluable asset in high-stakes environments like the automotive or electronics industries. The tool is a critical asset for engineers working on innovative projects that require precise electromagnetic field analysis. With applications spanning across industries, from mobile communications to satellite systems, EMPIRE XPU ensures engineers can achieve optimal performance and compliance in their designs. Its robust simulation capabilities make it essential for those looking to push the boundaries of electromagnetic applications.
The ant200 Vector Graphics Processor from Digital Media Professionals specializes in providing efficient vector graphics solutions tailored for compact and energy-constrained devices. It utilizes DMP's advanced graphics processing techniques to furnish high-quality vector rendering that is both rapid and efficient. This processor supports a wide range of vector tasks, optimizing performance while minimizing power consumption, a perfect fit for mobile and embedded systems striving for enhanced graphical representation. With a focus on scalability, it caters to diverse use cases from digital signage to wearable devices. DMP has embedded significant flexibility into the ant200, which supports current vector graphics standards, thereby enabling smooth integration into existing graphical ecosystems while paving the path for future technological developments.
The xF+ Liquid Biopsy Panel by Tempus is specifically designed for the analysis of circulating tumor DNA (ctDNA) in solid tumor applications. By employing next-generation sequencing techniques, this panel offers an extensive coverage of regions that are pivotal in monitoring disease progression and treatment response. This non-invasive test is crucial for patients where traditional tissue biopsies may be impractical. The panel includes robust analytical capabilities that provide oncologists with valuable data on genetic mutations critical to treatment planning. With deep sequencing coverages and sophisticated genomic insights, xF+ is instrumental in navigating complex oncology cases, especially for its precision in pinpointing clinically relevant alterations that influence treatment choices. Featuring a unique methodology that emphasizes sensitivity and specificity, the xF+ Liquid Biopsy Panel plays an essential role in ongoing patient management. Its capability to analyze ctDNA provides critical insights into tumor dynamics over time, assisting healthcare professionals in evaluating therapy effectiveness and potential genomic mutations that could predict disease recurrence or progression.
This TV tuner is crafted for multi-standard, multiband applications, accommodating a variety of broadcast standards. Its direct-conversion architecture simplifies the signal path, enhancing both performance and efficiency. The tuner supports diverse frequency bands, offering versatility for global application in regions with varying standards. With advanced signal processing techniques, it ensures clear reception, minimizing noise and interference for an optimal viewing experience. The design is tailored to be low-power and compact, making it an excellent choice for modern digital TV devices.
DMP's ant100 Mobile GPU is engineered for lightweight devices requiring efficient, high-performance graphics processing. Designed to operate under tight power constraints, it facilitates comprehensive graphics capabilities without excessive energy consumption, ideal for mobile gadgets and portable electronics. This GPU boasts support for a wide array of graphics standards, ensuring compatibility with modern mobile applications requiring augmented reality or gaming graphics. Its architecture strikes a perfect balance between power consumption and graphic output quality, vital for sustaining prolonged device use without frequent charging. The ant100 stands as a crucial component in fostering rich visual experiences on mobile platforms, maintaining performance levels necessary for immersive application interfaces while operating within limited power budgets.
The ant300 GPU by Digital Media Professionals represents the pinnacle of performance in compact, efficient graphics processing for embedded systems. It is built on the firm's proprietary technology to deliver a robust solution for rendering complex 3D visuals with minimal power draw, tailored to meet the stringent demands of portable and battery-powered devices. This GPU accommodates a variety of graphical tasks by supporting OpenGL ES standards, enabling developers to create rich, interactive applications without compromise on speed or visual fidelity. Its small-form factor allows easy integration into systems with limited space while offering scalable graphics performance that can be adapted to different device capabilities. Designed for the future, the ant300 facilitates low-power consumption without sacrificing output quality, maintaining DMP's legacy of pushing technological limits and pioneering new avenues in the graphics domain.
Himax's CMOS image sensors are renowned for their application across a variety of camera-based technologies, catering to both consumer electronics and professional-grade devices. Their sensors are designed to support ultra-low-power operations, allowing continuous image capturing capabilities with minimal power draw. These sensors excel in delivering high-resolution image quality, benefiting from features that include programmable readout modes and sophisticated integration of signal processing functions. By offering a simplified integration process, these sensors greatly enhance camera development efficiency for manufacturers. Strategically used in devices requiring always-on capabilities, Himax’s image sensors are celebrated for their low latency and autonomous operation, providing an effective solution for surveillance and IoT devices. Through continuous advancements, Himax underscores its leadership in the image sensor market with products that cater to versatile imaging needs.
Digital Media Professionals' K3000 Vector Graphics Processor is designed to deliver robust vector graphics computation to a multitude of devices. This processor integrates seamlessly into existing platforms, providing enhanced graphics capabilities suitable for both consumer electronics and industrial applications. Built to harness DMP's extensive experience in graphic technologies, the K3000 offers exceptional rendering performance by optimizing processing throughput for vector graphics. Its compatibility with leading graphics standards ensures that it supports contemporary creative and enterprise applications effectively. This vector GPU amalgamates high-speed processing with energy-efficient operations, allowing it to function as the backbone for advanced visual displays across diverse technological ecosystems. The K3000 stands as a testament to DMP's innovative approach to maximizing vector graphics potential in next-generation devices.