All IPs > Analog & Mixed Signal > Graphics & Video Modules
The realm of graphics and video modules within the analog and mixed signal category encapsulates a wide array of semiconductor IPs that are integral to modern multimedia technologies. These IPs are designed to enhance the performance of graphics rendering and video processing, catering to the increasing demand for high-quality visual content in various electronic devices. From mobile phones and tablets to gaming consoles and smart TVs, graphics and video modules serve as the backbone for delivering immersive and realistic experiences.
Semiconductor IP solutions in this category are crucial for managing the complex tasks associated with graphics processing units (GPUs) and video modules. They facilitate the seamless integration of high-definition video playback, 3D rendering, and image processing capabilities. Such IPs are engineered to optimize power consumption while maintaining superior performance, a critical requirement for mobile devices and other power-sensitive applications. The inclusion of analog and mixed signal technologies ensures that these modules can effectively handle analog inputs and outputs alongside digital signals, thereby providing a versatile interface for various consumer electronics.
In the graphics and video modules category, you'll find a diverse range of products such as digital-to-analog converters (DACs), analog-to-digital converters (ADCs), video encoders and decoders, and integrated circuits that support functions like video compression and decompression. These components are essential for transforming raw data into viewable content, applying corrective adjustments and enhancing picture quality. Furthermore, they support sophisticated features such as motion detection, noise reduction, and color correction, which are vital for achieving the highest visual fidelity.
As consumer expectations for video quality continue to rise, especially with the advent of 4K and 8K content, the importance of robust graphics and video modules within the semiconductor IP landscape has never been greater. These IPs not only empower manufacturers to meet industry standards for visual performance but also contribute to the innovation of new technologies and applications, such as virtual reality (VR) and augmented reality (AR), where the demand for real-time, high-resolution graphics is paramount. The integration of analog and mixed signal capabilities within these modules underscores their significance in the next generation of multimedia devices, solidifying their role as a staple in the development of future electronics.
WAVE6 represents the pinnacle of multi-standard video coding. It supports AV1 encoding, known for its efficient use of bandwidth and high compression quality. Featuring a simple architecture, it boasts a single-clock domain that synchronizes the entropy and video codec engines on the fly. The efficiency of WAVE6 is further enhanced by its power-efficient design, which minimizes consumer energy requirements through effective clock gating. It serves various sectors, including data centers and surveillance systems, operating with a remarkable performance of up to 8K60fps @ 1GHz. The integration of advanced coding techniques ensures a reduced need for external memory, thanks to the proprietary CFrame lossless compression.
Building on its predecessor, the WAVE5 series offers robust multi-standard video encoding capabilities with an established reputation within media and entertainment sectors. WAVE5 is versatile, boasting formats like HEVC and AVC, and delivers outstanding performance, with outputs like 4K240fps at 1GHz. It has been fine-tuned to handle complex multi-instance operations by efficiently managing data transfer and conversion tasks. Its ability to maintain high visual fidelity while offering low installation costs makes it a strategic choice for multiple application fields such as automotive and mobile entertainment. The use of secondary AXI ports and a fully integrated rotation and scaling mechanic add to its versatility.
The HOTLink II Product Suite from Great River Technology is tailored for high-speed data transmission in demanding aerospace environments. This solution integrates seamlessly into avionics systems, providing robust performance for data-intensive applications. Known for its efficiency and reliability, the HOTLink II suite is ideal for organizations requiring consistent and high-speed data transfer capabilities. Designed for maximum compatibility, the HOTLink II suite supports various hardware configurations and software interfaces, ensuring smooth transitions between system components. The suite offers a comprehensive array of tools that facilitate the integration and management of high-speed data links within sophisticated avionics architectures. Whether in development or deployment, the HOTLink II suite provides unparalleled support and flexibility. In addition to its core functionalities, the HOTLink II suite assists in optimizing data integrity and system robustness throughout the system's lifecycle. Its design reflects Great River Technology's expertise in data solutions, promising long-term reliability and performance in mission-critical applications.
The TW330 Image Warping IP utilizes advanced GPU processing technology to offer high-performance image distortion correction. It features extensive capabilities including coordinate transformation, any-shape image transformations, and supports resolutions up to 16K x 16K for both RGB and YUV formats. Ideal for digitally correcting images distorted by wide-angle or fish-eye lenses on various devices, this technology is key in fields such as automotive display systems, VR/AR devices, and high-definition projectors. It makes real-time, on-the-fly image correction feasible, elevating the quality of visual outputs for demanding applications. Through its flexible and efficient design, TW330 enables seamless integration into systems requiring dynamic and precise image modification capabilities, paving the way for developing more interactive and immersive visual experiences.
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.
ISPido is a robust and fully configurable Image Signal Processing (ISP) pipeline designed for high-end image processing needs. It is implemented in RTL and utilizes the AXI4-LITE protocol for flexibility. The pipeline is equipped with comprehensive features including defective pixel correction, color filter array interpolation, and color space conversion. It supports resolutions up to 7680×7680 and complies with AMBA AXI4 standards, addressing modern image processing challenges efficiently. This ISP handles inputs of 8, 10, or 12 bits depth, making it highly adaptable to different processing requirements. It features modules for statistics collection, auto-white balance, gamma correction, and high dynamic range (HDR) support. These enhancements enable users to achieve precise and accurate image quality with maximum efficiency. Furthermore, the ISPido pipeline supports YUV color conversion and chroma subsampling, ensuring compatibility with various output formats like 4:2:2 and 4:2:0. Its design ensures seamless integration into existing systems, optimizing resources while offering high-quality image output.
The SL-400X Mobile TV Integrated Receiver is designed for next-generation mobile digital television applications, offering a fully integrated solution that combines advanced demodulation and reception capabilities. Tailored for mobile environments, this receiver ensures seamless and reliable TV reception for portable devices under varying signal conditions. Equipped with robust software-defined processing capabilities, the SL-400X supports dynamic signal adaptation, enabling uninterrupted viewing experiences even while on the move. This makes it particularly beneficial for devices and systems that operate in fluctuating signal environments, ensuring content delivery with high quality and consistency. The compact nature of the SL-400X allows it to be embedded into various consumer electronics, providing a lightweight solution that does not compromise on performance. This integration ensures that manufacturers can offer enhanced mobile entertainment options, meeting the increasing demand for on-the-go content accessibility.
Vantablack S-VIS is a revolutionary space-qualified coating renowned for its unparalleled ability to suppress stray light. This is crucial for enhancing the performance and precision of optical instruments used in space applications. With its spectrally flat absorption capabilities extending from the UV range to the near-millimeter (THz) range, Vantablack S-VIS significantly improves light absorption, reducing interference and enhancing image quality. The coating has demonstrated exceptional performance in harsh environments, thriving under the intensity of solar, lunar, and terrestrial light in a zero-gravity context. Its deployment has resulted in lighter and smaller calibration systems and baffles, which is critical for space-bound equipment where size and weight are significant constraints. These coatings enhance emissivity across the IR spectrum, making them ideal for blackbody calibration in IR cameras and other sensitive optical systems. Since its initial deployment in low Earth orbit, the Vantablack S-VIS has amassed a significant track record of success in space missions. It possesses excellent thermal stability and is resistant to radiation and extreme vibrational forces, ensuring reliability and longevity in challenging space conditions. These attributes, coupled with its lightweight nature, make Vantablack S-VIS an optimal choice for advanced space imaging technologies.
The VIDIO 12G SDI FMC Daughter Card is an advanced development tool for those working with SDI and IP interfaces. Compatible with both AMD and Intel devices, it delivers high-quality video support for 4K resolutions via 12G SDI connections. This daughter card includes comprehensive design resources, enabling immediate use without the need for intricate configuration software. Its robust build supports rapid development cycles for new video-related products, making it ideal for broadcast and other high-performance environments.
The Hyperspectral Imaging System developed by IMEC revolutionizes the observation capabilities of a wide spectrum of wavelengths in just one frame. This system taps into the potential of spectral imaging, advancing Earth and space exploration through its ability to capture detailed environmental data. The hyperspectral imaging system, being chip-based, ensures enhanced efficiency and precision while lowering the energy footprint compared to traditional methods. This cutting-edge technology is capable of transcending applications from Earth monitoring, where it aids in identifying and assessing natural resources, to next-generation satellite observation. By employing advanced methodologies for data acquisition and processing, the hyperspectral imaging system enhances the quality and accuracy of images captured from diverse environments. Moreover, its compact and efficient form factor makes it adaptable for integration into various imaging platforms, providing unparalleled insights with high fidelity. Furthering the realm of optical imaging, IMEC's system is designed for broad adaptability across sectors like agriculture, forestry, and urban planning, facilitating an in-depth understanding of ecological and environmental dynamics. The seamless integration with machine learning algorithms allows for the conversion of vast spectral data into actionable insights, providing users with the tools needed to make informed decisions on conservation, resource management, and urban development. Combining state-of-the-art sensor technologies with robust computing abilities, IMEC's Hyperspectral Imaging System stands as a cornerstone of modern observational science.
The mmW-IC Wireless Transceivers from Akronic are particularly tailored for high-speed communication and radar sensor applications. These transceivers support frequencies up to 120GHz, offering a versatile platform for developing complex wireless communication systems. The transceivers are optimized using cutting-edge CMOS and BiCMOS technology, ensuring superior performance in terms of bandwidth and signal clarity. These integrated transceivers enable multi-Gbps wireless connections, specifically targeting E-band link applications. They also offer robust solutions for automotive radar systems, leveraging mm-Wave technology for enhanced sensor accuracy in both short-range and long-range scenarios. The use of custom passives and sophisticated circuit topologies significantly boosts the likelihood of achieving first-silicon success and minimizing iterations. Akronic's rigorous design approach combines thorough process simulations and careful packaging with innovative circuit design strategies. This ensures that these mmW transceivers are not only cost-effective but also highly reliable in practical deployments. Their applications cover a wide range, from backhaul and fronthaul systems in telecommunication to advanced imaging and radar sensing technologies that demand precision and high-speed data transmission.
The APIX3 series represents the evolution of INOVA's Automotive Pixel Link technology, aimed at addressing the growing needs of modern automotive infotainment and cockpit systems. This latest generation supports data rates up to 6 Gbps over one shielded twisted pair and extends up to 12 Gbps using quad twisted pairs. APIX3 maintains compatibility with previous APIX2 systems while enhancing performance with features such as multiple video channel support on a single connection, active equalizers for automatic line adjustment, and advanced diagnostics for cable condition monitoring. These capabilities make APIX3 ideal for UHD car displays and complex infotainment setups.
The ISPido on VIP Board is a versatile runtime solution designed for Lattice Semiconductors' Video Interface Platform (VIP). It facilitates real-time image processing using ISPido's robust capabilities. The board supports automatic or manual configuration to optimize image sharpness and balance using advanced filtering and color correction techniques. Equipped with dual Sony IMX 214 sensors, this platform supports high-definition resolution output of 1920x1080p via HDMI. It includes a sophisticated menu interface for runtime calibration, offering dynamic adjustments to gamma tables, convolutional filters, and other image parameters through a user-friendly serial port interface. This adaptable solution enhances the capability to fine-tune imaging outputs, making it ideal for applications requiring precise image processing in varying conditions. Developers can leverage this setup to prototype, test, and deploy advanced imaging solutions efficiently.
The SMS Fully Integrated Gigabit Ethernet & Fibre Channel Transceiver Core offers a highly efficient PHY solution for high-speed data transmission. It is designed with a versatile architecture that supports gigabit Ethernet and Fibre Channel standards, focusing on achieving low latency and high data integrity. This core showcases comprehensive integrated systems, including high-speed drivers and clock recovery techniques, which are crucial for achieving optimal signal clarity and reducing jitter. A key aspect of this transceiver is its compatibility with IEEE 802.3z standards for gigabit Ethernet, making it an ideal choice for applications requiring robust connectivity solutions. The design leverages advanced phase detectors and proprietary signal processing methods to enhance performance by minimizing errors and noise in the transmission path. This core is particularly suitable for environments that demand high reliability and performance consistency, such as data centers and network infrastructure. The SMS transceiver also supports a wide range of operational conditions, thanks to its flexible interface design and low power consumption. Its modular architecture allows easy customization to meet specific application needs, ensuring it can be seamlessly integrated into larger system-on-chip (SoC) applications. This transceiver core represents a blend of cutting-edge technology and practical application design, aiding in the deployment of next-generation communication systems.
Designed for high-performance image warping, the TW220/240 IP offers distortion correction and various transformations such as scaling and rotation. It supports resolutions up to 4K x 4K in RGB and YUV formats, facilitating high-quality image outputs. This IP is particularly suited for compact, but high-resolution processing needs found in automotive, VR, and digital camera applications. With GPU-accelerated processing, it ensures efficient alteration of images in real-time, meeting the demands of modern visual technologies. Whether for innovation in automotive mirror systems or in enhancing VR headset displays, TW220/240 stands as an essential asset. It provides the technical prowess required to handle intricate image processing with accuracy and speed.
The ATOM one is a compact Full HD camera designed with Dual 3G-SDI outputs, leveraging Sony's IMX174 image sensor. It is renowned for delivering exceptional image quality and supports a multi-matrix feature that allows for diverse color grading and image adaptation needs. Its design focuses on providing high-resolution video capture in a minimalistic form factor, making it ideal for applications where space and weight are a constraint, such as in broadcast and mobile environments.
The CTAccel Image Processor (CIP) on Intel Agilex FPGA offers a high-performance image processing solution that shifts workload from CPUs to FPGA technology, significantly enhancing data center efficiency. Using the Intel Agilex 7 FPGAs and SoCs F-Series, which are built on the 10 nm SuperFin process, the CIP can boost image processing speed by 5 to 20 times while reducing latency by the same measure. This enhancement is crucial for accommodating the explosive growth of image data in data centers due to smartphone proliferation and extensive use of cloud storage. The Agilex FPGA's advanced features include transceiver rates up to 58 Gbps, versatile DSP blocks supporting both fixed-point and floating-point operations, and high-performance cryptographic capabilities. These features facilitate substantial performance improvements in image transcoding, thumbnail generation, and image recognition tasks, reducing total cost of ownership by enabling data centers to maintain higher compute densities with lower operational costs. Moreover, the CIP's support for mainstream image processing software such as ImageMagick and OpenCV ensures seamless integration and deployment. The FPGA's capability for remote reconfiguration allows it to adapt swiftly to custom usage scenarios without server downtimes, enhancing maintenance and operational flexibility.
The SMPTE ST 2110 media transport core facilitates the transmission of professional audio-visual signals over IP networks. This core supports uncompressed and compressed video, PCM digital audio, and data streams, making it a comprehensive solution for modern broadcasting needs. With modularity and configurability at its core, the solution optimizes FPGA resources and supports both gateway and synthetic essence operations, enabling efficient deployment in various environments.
ZIA Image Signal Processing (ISP) sets the standard for compact image signal processing solutions, integrating seamlessly into AI camera systems. This ISP excels in handling high sensitivity image sensors like Sony's IMX390, providing superior noise reduction and adaptable dynamic range control in challenging lighting conditions. ZIA ISP's capabilities include handling HDR through its sophisticated noise reduction techniques to maintain image clarity and adaptability even in adverse weather, making it highly reliable for safety-critical high dynamic environments. Leveraging advanced integration techniques, ZIA ISP achieves top-notch performance through pre-processing, ensuring that any image input undergoes rigorous enhancement before analysis. The model enhances pedestrian detection and tracking by maintaining identification post light adjustments, illustrating its resilience and adaptability in dynamic lighting scenarios. Technical specifications of ZIA ISP include support for IMX390 image sensors at full HD 1920 x 1080 30fps, with a dynamic range of 120dB, achieving exceptional clarity in video output. It brings together proprietary image enhancement capabilities, such as automatic white balance correction and scalable output formats, ensuring a complete signal processing package. ZIA ISP delivers dynamically in managing high visual fidelity through real-time corrective processes, confirming its essential role in visual data processing applications targeting robust projects.
Great River Technology's ARINC 818 Product Suite offers a comprehensive set of tools and resources for the development, qualification, testing, and simulation of ARINC 818-enabled systems. This suite is designed for flexibility and scalability, supporting a wide range of mission-critical applications within the aerospace sector. With a dedication to advancing avionics technology, the ARINC 818 product suite provides implementers with all necessary components, from design to deployment stages. The suite includes an extensive development toolkit, facilitating the seamless integration of ARINC 818 standards into aerospace projects. Customers can benefit from detailed implementer's guides, extensive simulation capabilities, and robust testing frameworks that ensure reliability and compliance with industry standards. As a result, the ARINC 818 suite is essential for organizations looking to develop robust and agile avionics systems. Furthermore, Great River Technology's ARINC 818 suite supports lifecycle management for avionics equipment, offering tools to optimize system performance throughout its operational life. Continuous updates and additions to the suite ensure that users can stay ahead of technological changes, maintaining a competitive edge in the rapidly evolving aerospace market.
The Laser Triangulation Sensors by RIFTEK are designed for non-contact mobile measurement applications. These sensors are versatile, measuring a wide range of parameters including position, displacement, and deformation. With operating ranges from 2 to 1250 mm, they offer high precision with measuring errors as low as ±1 µm. These sensors provide essential feedback for liquid and solid material level measurements and exhibit robustness in sorting and profiling tasks. The platform supports both Blue and Infrared laser technologies, ensuring adaptability to various operating environments.
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 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.
ActLight's implementation of the Dynamic PhotoDetector (DPD) technology in smartphones focuses on transforming everyday mobile experiences. The innovative DPD enables functionalities such as proximity and ambient light sensing, which are integral to optimizing how smartphones interact with users and their environments. This technology applies ActLight’s expertise in 3D Time-of-Flight (ToF) camera integration, crucial for applications ranging from automatic screen adjustments based on proximity to immersive augmented reality (AR) experiences. The precise detection capabilities of the DPD ensure high accuracy and performance, enhancing both the aesthetic and functional aspects of smartphones. By operating efficiently at low power, this technology supports longer battery life, which is essential as smartphones continue to incorporate advanced features. DPD technology from ActLight also optimizes signal precision and energy use, making it ideal for high-demand applications like optical datacom. It's an excellent solution for manufacturers focusing on enhancing user experience with devices that are not only smarter but also more responsive and efficient. With these features, smartphones can achieve superior performance in challenging light conditions, improving everything from photography to immersive virtual environments.
DigiLens offers high-performance waveguide optics designed specifically for XR and AR applications. These optics are known for their outstanding transparency and minimal eye glow, making them socially acceptable and user-friendly. They provide an efficient solution for both indoor and outdoor use, with high transmissivity and excellent brightness levels that cater to a variety of applications.\n\nThe waveguide optic design is focused on delivering an exceptional user experience by combining lightweight and durable materials with high performance. DigiLens employs its proprietary inkjet printing and holographic techniques to ensure the unwavering quality and consistency of its optic offerings. This allows for rapid development cycles and cost-effective production, providing a competitive edge in the market.\n\nWith these optics, DigiLens aims to set new standards for AR and XR technologies by facilitating seamless integration and enhanced functionality. The integration of these high-efficiency waveguides into smartglasses enables users to work smarter by blending digital information with the physical world, which is crucial for various industry applications.
RIFTEK's 2D Laser Scanners are integral to non-contact profiling, providing precise measurements necessary for surface evaluation tasks. These scanners thrive in dynamic environments, suitable for applications involving welding robots and assembly systems. With ranges extending from 10 mm to over a meter, their accuracy and speed allow real-time adjustments during automated processes. The inclusion of Blue and IR laser technology aids in delivering high-resolution outputs even in challenging conditions, making them a staple in modern industrial setups.
The SL 300X is a compact, next-generation universal DTV demodulator known for its outstanding adaptability and performance in diverse broadcasting environments. As a fully software-defined solution, it offers high throughput and precision, allowing it to work seamlessly with various digital television standards globally. This demodulator is engineered for efficiency, featuring advanced computational capabilities that support complex signal processing tasks necessary for clear, consistent video and audio quality. It ensures that broadcasters and device manufacturers can deliver reliable transmissions without extensive hardware changes, thanks to its ability to adapt quickly to evolving standards and technologies. Ideal for digital broadcasting applications, the SL 300X reduces the technical barriers to entry, providing a powerful platform for delivering high-quality content to audiences without the need for frequent hardware updates. Its small footprint also aids in reducing power consumption and operational costs, making it a cost-effective and sustainable choice for modern broadcasting needs.
The CTAccel Image Processor tailored for AWS takes advantage of FPGA technology to offer superior image processing capabilities on the cloud platform. Available as an Amazon Machine Image, the CIP for AWS offloads CPU tasks to FPGA, thereby boosting image processing speed by 10 times and reducing computational latency by a similar factor. This performance leap is particularly beneficial for cloud-based applications that demand fast, efficient image processing. By utilizing FPGA's reconfigurable architecture, the CIP for AWS enhances real-time processing tasks such as JPEG thumbnail generation, watermarking, and brightness-contrast adjustments. These functions are crucial in managing the vast image data that cloud services frequently encounter, optimizing both service delivery and resource allocation. The CTAccel solution's seamless integration within the AWS environment allows for immediate deployment and simplification of maintenance tasks. Users can reconfigure the FPGA remotely, enabling a flexible response to varying workloads without disrupting application services. This adaptability, combined with the CIP's high efficiency and low operational cost, makes it a compelling choice for enterprises relying on cloud infrastructure for high-data workloads.
ELFIS2 is a versatile image sensor designed to cope with challenging environments, with its high reliance on radiation-hardened features. This sensor is characterized by its true high dynamic range (HDR) capabilities, making it optimal for applications requiring accurate light detection across a broad range of intensities. The ELFIS2 features motion artifact-free (MAF) operation, a critical attribute for high-fidelity imaging. Built with a global shutter and back-side illumination (BSI), the sensor ensures all pixels capture light simultaneously, which is vital for sharp images devoid of motion blur. The BSI technology further enhances its sensitivity by allowing more light to reach the photodiode, a crucial feature for low-light conditions or fast imaging demands. With its SEL/SEU radiation-hardened design, the ELFIS2 is tailored for environments exposed to high radiation levels, like space or certain industrial settings. This resiliency, coupled with its innovative design, makes ELFIS2 suitable for complex imaging tasks, capturing high-quality images without compromising performance.
The CTAccel Image Processor (CIP) on Intel PAC platform leverages FPGA technology to offload image processing workloads from CPUs, thereby significantly boosting data center efficiency. By transferring tasks such as JPEG transcoding and thumbnail generation onto the FPGA, the CIP increases image processing speeds by up to 5 times and reduces latency by 2 to 3 times, promoting higher throughput and reducing total costs dramatically. The Intel PAC enables this swift processing by utilizing advanced FPGA capabilities, which support massively data-parallel processing. This effectively addresses the limitations of traditional CPU and GPU architectures in handling intricate image processing tasks, particularly those requiring high parallelism. Additionally, the CIP ensures full compatibility with leading image processing libraries, including ImageMagick, OpenCV, and GraphicsMagick, which facilitates hassle-free integration into existing workflows. The use of Partial Reconfiguration technology allows users to reconfigure FPGA processing tasks dynamically, ensuring maximum performance adaptability without necessitating server reboots, thus enhancing operational ease and efficiency.
Designed for direct conversion, this TV tuner supports multiple bands and standards, making it versatile for global broadcast reception. Its architecture allows for seamless integration into various devices, from televisions to set-top boxes, enabling high-quality audio and visual output. The tuner features advanced filtering techniques to minimize interference, ensuring crisp and clear picture and sound regardless of the band or broadcast standard used. Its low power design also makes it suitable for mobile media devices.
The CTAccel Image Processor on Alveo U200 provides a robust image processing solution by shifting demanding computational workflows from the CPU to FPGA. Specifically designed to handle massive data throughput efficiently, the CIP elevates server performance by up to 6 times while simultaneously reducing latency fourfold. This jump in performance is critical for managing the vast influx of mobile-generated image data within Internet Data Centers (IDCs). Utilizing the FPGA as a heterogeneous coprocessor, the CIP leverages the Alveo U200 platform to enhance tasks such as JPEG decoding, resizing, and color adjustments. The technology removes bottlenecks associated with conventional processing architectures, making it ideal for environments where quick data processing and minimal latency are imperative. The FPGA's ability to undergo remote reconfiguration supports flexible deployment and is designed to maximize operational uptime. The CIP is compatible with popular software libraries like OpenCV and ImageMagick, ensuring an easy transition from traditional software-based image processing to this high-performance alternative. By deploying CIP, data centers can drastically increase compute density, which translates into lower hardware, power, and maintenance costs.
The INAP590T is among INOVA's flagship products in their APIX3 series, designed for optimal performance in modern automotive infotainment architectures. This product supports HDMI interfaces and is equipped to handle multiple data and video channel transmissions over a single cable, ensuring high fidelity and reduced lag. Its robust design includes high-speed differential transmission capabilities that adapt to varied cable qualities, mitigating signal loss and ensuring consistent communication even in demanding automotive environments. The INAP590T also features integrated HDCP support for encrypted communication, critical for secure data exchange in automotive systems.
The Orion Family of Pattern Projectors from Metalenz is a series of high-performance, compact projector systems designed to enhance 3D depth sensing. These projectors leverage advanced meta-optic technology to convert laser emissions into highly detailed dot, line, or flood patterns, making them ideal for various applications including smartphones, AR/VR systems, and industrial robotics. A key element of their design is the integration of multifunctional elements into a single, flat optic, which streamlines the production process and reduces the size and cost of the system. The Orion 18K, a prominent model in this family, generates approximately 18,000 dots in a pseudorandom pattern using a VCSEL array, offering high contrast even under challenging lighting conditions. Additionally, these projectors are renowned for their robust optical performance, stable operation across a wide temperature range, and ease of integration into existing systems. Their capability to replace multiple traditional optical elements with a single meta-optic not only simplifies assembly but also enhances the precision and efficiency of 3D sensing applications. With their compact design and powerful performance, Orion Pattern Projectors are setting a new standard in the field of optics for depth sensing and recognition technologies.
Crest Factor Reduction (CFR) technology is a sophisticated signal processing technique that addresses the challenges faced by power amplifiers in handling peak power demands. By managing the peak-to-average power ratio (PAPR), CFR helps to ensure that power amplifiers operate efficiently, thus reducing the burden on power supplies and improving overall system reliability. CFR is pivotal in telecommunications, where signal spikes can cause inefficiencies or even damage to the system. This technology carefully adjusts signal peaks to manageable levels without compromising the quality of the transmitted information, thereby extending the life span of equipment while reducing operational costs. The implementation of CFR can lead to substantial cost savings associated with power efficiency and infrastructure longevity. It also enhances the ability of providers to meet regulatory and performance standards in modern communication systems, positioning the technology as a vital tool in the arsenal of those aiming to maintain top-quality service in high-demand scenarios.
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 DVB-C QAM demodulator is designed to be used with a cable tuner and an ADC. It features an internal state machine for operation control, configurable via the SPI interface. The IP supports QAM constellations from 16 to 256, using blind acquisition and decision-feedback mode for tracking. It also includes convolutional interleaving and Reed-Solomon error correction to address signal degradation due to impulse noise. The device offers both parallel and serial MPEG outputs and complies with DVB-C EN 300 429 and ITU-T J.83 Annex A & C standards.
RIFTEK offers innovative Speed and Length Sensors that operate using either Raster Spatial Filtration or Laser Doppler Interferometry techniques. Designed for the precision measurement of moving objects, these sensors can monitor items such as wire, paper, and steel at high speeds. Impressive accuracy levels of less than ±0.1% RMS make them indispensable in industries like metallurgy, textile manufacturing, and cable production, where precise distance and speed readings are critical to process efficiency.
RIFTEK's Laser Seam Tracking System, particularly the RF627Smart-Weld, is adept at improving the precision and efficiency of welding operations. It features robust interfacing with industrial robots, allowing for seamless tracking of welding seams through real-time data processing. This system is optimized for use in complex welding environments, providing accurate seam position feedback that enhances the quality and speed of automated welding tasks. Its integration capabilities make it an integral part of the modern robotic welding landscape.
BTREE's Display Compression Encoder and Decoder IP efficiently compresses visual data to enhance display performance while reducing bandwidth requirements. This IP is particularly vital in multimedia systems that demand high resolution and excellent display quality. By compressing image data before transmission, it reduces the load on the system's bandwidth, ensuring smooth and seamless visual performance in real-time applications. The encoder and decoder combination is meticulously engineered to offer lossless data compression, preserving image integrity and quality. This is critical for applications where accuracy and detail are crucial, such as in medical imaging and professional video production. The compression method is designed to operate effectively across various imaging platforms, ensuring compatibility and ease of integration across different systems. Moreover, the IP's advanced algorithms enable it to deliver compression ratios that are optimal for both storage and display functions, helping devices maintain high performance while minimizing data errors. This capability helps extend the functionality of portable devices by reducing the need for extensive storage solutions while continuing to offer premium image quality to the user.
The AFBR-POC205A8 is engineered as an advanced optical power converter for applications requiring power conversion at the higher 1480 nm wavelength. It efficiently converts optical power to electrical power, delivering an output of 0.7 W. Its design caters to fiber optic systems, offering exceptional performance where precise power conversion is vital.\n\nThis converter excels in its ability to seamlessly integrate with fiber-optic network architectures, ensuring minimal loss and reliable power transfer across varied operational scenarios. Its development meets the exacting standards required for both high-demand commercial and industrial settings, where maintaining power efficiency is key.\n\nThe AFBR-POC205A8 is crafted to support different fiber channel devices, enhancing the capability and performance of optical communications systems. Its robust power delivery ensures continued operational stability, positioning it as an integral component in advanced networking solutions that depend on efficient optical-electrical conversion mechanisms.
The AFBR-POC205A2 is an optical power converter that operates at the 850 nm wavelength, delivering up to 0.75 W of power. Tailored for optical communication interfaces, this converter efficiently interfaces with fiber channel devices, enhancing power delivery systems. Its compact form and precision engineering ensure reliable performance in demanding applications where optimal power conversion is crucial for effective data transmission.\n\nWith its capacity to operate effectively within fiber optic communications, the AFBR-POC205A2 stands out for its ability to maintain stable outputs over multiple operating conditions. This converter is particularly suited for environments that prioritize power efficiency and reliability. Its design facilitates use in both industrial and commercial settings, meeting diverse needs with a consistent performance standard.\n\nThis optical power converter supports seamless integration into existing systems, offering straightforward connections for data and telecommunication infrastructures. The AFBR-POC205A2 thus proves essential for organizations seeking to advance their networking equipment's operational efficiency, providing dependable power conversion in a streamlined package.
The logiREF-ACAP-VDF is a comprehensive framework designed to simplify the development of multi-camera vision applications using the AMD Versal Adaptive SoC VCK190 Evaluation Kit. It provides a robust design package that includes pre-verified reference designs, facilitating efficient project development and reducing the complexities involved in integrated camera applications. Particularly useful in applications such as advanced driver assistance systems (ADAS) and machine vision, this framework supports the rapid prototyping and deployment of sophisticated camera systems, enabling developers to focus on enhancing application-specific functionalities. Its integration capabilities ensure compatibility with camera-to-display setups and LIDAR visualization sequences, expanding its utility across varied industrial domains. Built on the robust Versal Adaptive SoC platform, the logiREF-ACAP-VDF framework promises unmatched performance and ease of use, making it a valuable asset for developers seeking to reduce design cycles and enhance project outcomes.
Nexperia offers a range of Silicon Carbide (SiC) Schottky diodes designed to provide high efficiency and reduced thermal losses. These diodes are pivotal in applications demanding high power efficiency and reliability. Their portfolio includes various models optimized for fast switching and low forward voltage drops, ensuring minimal power loss during operation. SiC Schottky diodes from Nexperia are highly suitable for automotive applications, thanks to their ability to perform under high temperatures and voltage conditions. The use of SiC technology in these diodes provides significant advantages over traditional silicon diodes. They are engineered to handle higher voltages and currents, making them ideal for industries where efficiency and power density are critical. Nexperia's SiC diodes are known for their robustness and reliability, making them a premium choice for cutting-edge power management systems. Another highlight of these SiC Schottky diodes is their compact design, which allows for more space-efficient solutions in complex systems. They offer high-speed switching capabilities that enhance performance in electric vehicles, renewable energy systems, and other high-power applications. Nexperia's SiC diodes are a testament to their commitment to innovation and high-quality standards in power semiconductor solutions.
This digital video scaler allows for flexible upscaling and downscaling operations with independent horizontal and vertical adjustments. It uses a sophisticated 5x5 FIR polyphase filter with 16-phase selectivity to produce studio-quality video output devoid of aliasing artifacts. The design negates the need for a frame buffer and additional external memory, which simplifies setup while ensuring processor efficiency.
logiHOG is an advanced object detection core based on Histogram of Oriented Gradients (HOG) and Support Vector Machine (SVM) methodologies. Developed for enhanced multi-object detection within camera-based systems, it provides comprehensive solutions for installment in surveillance, automotive safety, and intelligent robotic applications. This core is crucial where dependable, fine-tuned object detection is necessary, facilitating precise identification and classification of multiple objects in a scene, essential for automated driving systems and industrial automation. Integral to Xylon’s product offerings, logiHOG’s high-performance capabilities ensure broad applicability and adaptability across evolving technological domains. Its implementation empowers developers to overcome traditional detection challenges, delivering next-gen solutions for contemporary systems.
Designed for use with Xylon's logiVID-ZU Vision Development Kit, the logiADAK-VDF-ZU IP framework offers a comprehensive solution for developing multi-camera vision applications based on AMD Zynq UltraScale+ MPSoC. This framework accelerates development by providing pre-verified camera-to-display reference designs, essential for creating advanced vision systems for AD/ADAS applications, machine vision, and more. The framework effectively reduces design complexity, allowing developers to focus on application-specific improvements rather than base-level integration challenges. Its alignment with AMD's MPSoC architecture ensures that deployments are quick, efficient, and scalable across various projects demanding sophisticated visual outputs. By offering detailed pathways for development and integration, the logiADAK-VDF-ZU framework enhances productivity and innovation within vision application domains, supporting a wide array of potential use cases in rapidly advancing technological environments.
The logiREF-ACAP-MULTICAM-ISP is a comprehensive IP design framework tailored for multi-camera vision applications. This HDR Image Signal Processing framework optimizes the capabilities of Xylon's logiVID-ACAP-6CAM kit users, making it possible to efficiently develop sophisticated multi-camera vision systems on AMD's Versal Adaptive Compute Acceleration Platform (ACAP). Users benefit from the complete package, which includes pre-verified designs, allowing for streamlined development processes. The framework addresses both camera-to-display and LIDAR visualization, significantly reducing design time and enabling developers to concentrate on enhancing specific vision-related application areas such as AD/ADAS or machine vision. The thoughtful integration within AMD's ACAP infrastructure ensures compatibility and superior performance across a variety of vision-based applications. This framework embodies cutting-edge innovation necessary to remain competitive in fast-evolving fields reliant on multi-camera setups and high dynamic range image processing.
A sophisticated IP core for on-screen display, the GPU Overlay Module allows for seamless blending of 2D graphics and text over 30-bit RGB video feeds. Offering advanced features such as anti-aliasing and multiple font sizing, it is designed for top-tier visual clarity and customization. This module is ideal for professional presentations needing high-definition graphics within video outputs and supports extensive overlay capabilities.
The logiSLVDS_RX is engineered to assist in interfacing Sony CMOS image sensors employing Sub-LVDS differential technology with AMD's programmable devices. This IP core facilitates the connection of ultra-high-resolution imaging sensors to processing pipelines, suitable for wide-ranging high-end applications. Ideal for projection systems, high-definition video capture, and industrial imaging, this core ensures data integrity and high throughput, crucial for processing detailed imagery. The straightforward integration with image signal processing systems emphasizes its applicability across diverse fields requiring precision imaging. Customers benefit from Xylon's robust tech support and comprehensive documentation accompanying this core, simplifying its use and ensuring successful deployment in diverse imaging environments.