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.
The WAVE6 codec series by Chips&Media is a versatile solution offering multi-standard video encoding and decoding capabilities, tailored for high-resolution content delivery. Integrating AV1 encoding, it ensures superior streaming and bandwidth optimization. This solution is especially viable for devices requiring high efficiency and low power consumption, such as data centers and surveillance cameras. With its dual-core architecture, the WAVE6 achieves better processing speeds, supporting up to 8K resolution at 60 frames per second. Engineered with an optimized architecture, WAVE6 includes features like frame buffer compression and color space conversion, which enhance the overall performance while minimizing power use. Its design is straightforward, with a single-clock domain facilitating on-the-fly processes for various codec engines. This codec is not only efficient in terms of power usage but also capable of supporting a range of YUV formats and bit depths, maintaining high image quality with features like rotate/mirror and down-scaling functionalities. The WAVE6's specification supports a broad array of applications, from data centers needing robust processing power to automotive systems where efficiency and reliability are paramount. Its compatibility with multiple industry standards, including HEVC, AVC, and VP9, ensures that it meets diverse customer requirements while optimizing usage of external memory bandwidth through advanced compression technologies.
The DSC Encoder core is meticulously engineered for encoding video signals using the Display Stream Compression technique. Ideal for both FPGA and ASIC applications, this encoder reduces data transmission needs while preserving visual fidelity, making it an excellent choice for high-definition broadcasting, professional video editing, and more. It supports integration across various process nodes and is compatible with existing industry standards.
The TW330 IP offers cutting-edge image warping capabilities through GPU technologies, designed to transform and correct image distortions in real-time. This technology is tailored for high-resolution outputs, supporting resolutions up to 16K x 16K. It is ideal for applications such as head-up displays in automotive systems, VR/AR devices, and projectors, providing accurate image processing for demanding visual environments.
The DSC Decoder is a high-efficiency core designed to decompress video streams conforming to the Display Stream Compression (DSC) standard. Its implementation on diverse silicon platforms allows it to be integrated into a wide variety of applications, from consumer devices to medical imaging. This decoder ensures that video content remains high-quality while significantly reducing the bandwidth required for transmission.
Chips&Media's WAVE5 is a proven multi-standard video codec IP renowned for its versatility in handling a broad spectrum of video formats. Designed for high-performance applications, it ensures efficient processing by utilizing dual-core technology, suitable for environments like data centers and surveillance setups. The WAVE5's capability to encode and decode at high resolutions and frame rates makes it a reliable choice for video-intensive operations. Incorporating sophisticated features such as frame buffer compression and multi-instance support, WAVE5 provides enhanced video quality while ensuring minimal latency. With support for industry standards like HEVC and AVC, it meets diverse demands within the multimedia domain, efficiently processing video streams at up to 8K60fps. The codec is optimized for power usage, allowing it to deliver excellent performance without excessive resource consumption. WAVE5's interface architecture supports robust data transfer and system control through AMBA3 APB and AXI protocols, ensuring seamless communication and operational efficiency. This is complemented by comprehensive support for bit-depth and YUV format conversions, enhancing compatibility with various media types and application needs. Its wide applicability in fields such as automotive, drones, and home entertainment underscores its adaptability and powerful processing capabilities.
Hermes 3D is crafted for the simulation of arbitrary 3D structures, offering unparalleled insights into electromagnetic performance across a variety of applications. Its core strength lies in providing high-precision FEM simulations that support the evaluation of complex geometrical designs typical in today's advanced electronic circuits. Hermes 3D empowers engineers with the capability to investigate and optimize diverse electromagnetic interactions within detailed 3D structures. This function is particularly essential when working with components that require precise behavior predictions under various operational conditions, ensuring that systems maintain their integrity and performance over time. By facilitating rigorous analysis, Hermes 3D aids in reducing costly design iterations and enhances efficiency in the product development cycle. Its application in arbitrary structural simulations makes it an essential tool for any designer seeking to ensure their systems are both innovative and reliable.
Great River Technology's HOTLink II Product Suite is designed to support high-speed serial communication applications. This suite focuses on enabling reliable and efficient data transmission across various mission-critical platforms. It leverages technologies well-suited for environments demanding robustness and precision, such as infrared sensors and optical camera systems. The HOTLink II suite aids engineers in interfacing and implementing solutions that require high-throughput and low-latency performance characteristics. This suite, continuing to support existing FC-AV applications, ensures these systems can handle new challenges in fast-paced aerospace and defense sectors. The suite’s design tools and components are optimized for seamless integration into existing systems, facilitating the transition from legacy to cutting-edge technologies.
Imec's Hyperspectral Imaging System leverages its advanced semiconductor technology to push the boundaries of on-chip spectral imaging. Designed for high-performance applications, this imaging system allows for detailed Earth observation and a variety of other uses. The system encompasses unique innovations in sensor technology, enabling a broad spectrum of light capture that extends beyond traditional imaging limits. By merging this with an enhanced imaging processor, the Hyperspectral Imaging System offers even more refined and precise data capture. This system is tailored for industries where precision and reliability are paramount, such as agriculture, mining, and environmental monitoring. Imec has engineered this technology to not only capture visible light but also the infrared spectrum, maximizing the information the device can collect. The compact, efficient setup makes it feasible for integration into broader systems or standalone applications. By ensuring impeccable spectral resolution and operational efficiency, the Hyperspectral Imaging System stands out as a versatile solution for demanding imaging requirements. Imec's continual research and development in this domain ensure that this imaging technology evolves alongside the emergent needs of diversified industries.
The TW220/240 IP enables efficient distortion correction, scaling, and rotation for image processing applications, geared for embedded systems needing robust transformation capabilities. It supports outputs up to 4K x 4K resolutions, optimizing image quality for video outputs across cameras and automotive systems. This solution is perfect for applications requiring real-time image adaptations.
ZIA Stereo Vision is an advanced stereoscopic vision module designed to provide precise distance estimation. By combining left and right camera inputs, it leverages semi-global matching algorithms to derive depth maps essential for applications like autonomous vehicles and robotic navigation. It operates under varying image resolutions and provides high-speed processing, ensuring integration into systems where rapid environmental mapping is crucial. Its hardware design optimizes power, space, and performance metrics, making it ideal for high-demand use cases that rely on accurate spatial awareness.
SMPTE ST 2110 facilitates the transport of professional media over IP networks, empowering broadcast and professional AV equipment to both send and receive uncompressed video, audio, and ancillary data. This suite of standards breaks down the transport of media streams into individual essence streams, offering precise control over video synchronization and minimizing resource use.
ISPido on VIP Board is a tailored run-time solution designed specifically for Lattice Semiconductors' VIP board, offering enhanced image processing capabilities. Designed for real-time image sharpness and balance, the system provides both automatic configuration options and manual fine-tuning capabilities through a menu interface. This interface allows the selection of different gamma tables, application of convolutional filters, and more. The VIP Board includes CrossLink and HDMI bridges and uses Sony IMX 214 image sensors with an ECP5-85 FPGA processor, ensuring robust processing power and high-quality image output. With a resolution output of 1920 x 1080p over HDMI and YCrCb 4:2:2 format, this board is instrumental in achieving runtime calibration. Overall, ISPido on VIP Board offers a customizable platform for image processing tasks, balancing ease of use with powerful processing capabilities, thus supporting a variety of video and vision applications.
The VIDIO 12G SDI FMC Daughter Card is engineered to facilitate the development of SDI interfaces, supporting an extensive range of resolutions and standards. It simplifies the integration of SDI and IP protocols by providing necessary hardware with no software initialization required, ensuring immediate productivity for developers.
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 ZIA Image Signal Processing solution, tailored for high-performance image tasks, brings exceptional capabilities to handle challenging environments. It supports Sony's high-sensitivity image sensor IMX390, ensuring superior noise reduction even in harsh lighting conditions like rain or glare. Designed to work with HDR functions, it supports dynamic range compression and other image transformations to provide clarity in diverse scenarios. The ISP maintains image quality across various lenses and configurations, allowing for robust real-time processing crucial for automotive and industrial environments.
ISPido is a comprehensive RTL Image Signal Processing (ISP) pipeline, configurable via the AXI4-LITE protocol, that offers extensive flexibility and modularity for integrating into various systems. Designed to handle a video stream with 8 to 12 bits depth, ISPido includes an array of modules for efficient image processing. The pipeline encompasses features like pixel defect correction, color filter array interpolation using the Malvar-Cutler algorithm, and a color correction matrix. It supports color space conversions between RGB and YCbCr, facilitating operations within a vision system. Tiny in area yet robust in functionality, ISPido is compatible with AMBA AXI4 standards, ensuring seamless integration into existing systems. Each module addresses specific image processing needs, from auto-white balance to HDR chroma resampling. The ISP module is designed for resolutions up to 7680x7680, supporting the latest 4K2Kp30 (3840x2160) standards, making it ideal for demanding applications in areas like industrial automation and consumer electronics. ISPido’s implementation is versatile, supporting configurable modules that cater to a vast array of applications. Its first-rate architecture allows it to be utilized in both low-powered battery-operated devices as well as cutting-edge 8K vision systems. The image processing capabilities make ISPido a vital component for developers aiming to enhance video and image quality in diverse hardware applications.
aiSim 5 is aiMotive's state-of-the-art ISO26262 ASIL-D certified simulator designed to accelerate and optimize the validation process of Advanced Driver Assistance Systems (ADAS) and automated driving (AD) software. Its core components leverage AI-based rendering and highly optimized sensor simulation to establish a new standard in automotive simulation, delivering unmatched realism and adaptiveness. This cutting-edge tool allows for extensive multisensor environments, supporting over 20 cameras, 10 radars, and numerous lidars, thereby offering an authentic, comprehensive testing platform for autonomous systems. A testament to aiSim 5's capabilities is its robust 3D asset library and versatile content pipeline. These facilitate the creation and deployment of complex, high-fidelity environments crucial for thorough ADAS and AD software validation. Additionally, the simulator provides a cloud-native UI and open SDK, giving developers ample flexibility to create custom test scenarios and seamlessly integrate them into existing toolchains. Its proprietary aiSim AIR engine plays a pivotal role, delivering high-quality virtual sensor data streams while maintaining efficient resource use. The engine supports distributed rendering and balances workload by allowing asynchronous data transfer, further elevating the simulator's performance and ensuring compliance with stringent automotive standards.
The third generation APIX3 technology addresses the increasing demands of new infotainment and cockpit architectures in automobiles by supporting multiple UHD resolutions. APIX3 enables transmission rates of up to 6 Gbps over single shielded twisted pair cables, and up to 12 Gbps over quad twisted pairs. This new iteration boasts enhanced diagnostic capabilities like cable monitoring and supports high-definition content through several video interfaces, making it crucial for advanced in-car video solutions. APIX3 facilitates the transmission of multiple video channels on a single connection, supporting advanced cockpit architectures. It also integrates 100 Mbps Ethernet among other serial protocols, while offering backward compatibility with its predecessor, APIX2. A critical feature is the active equalizer that automatically adjusts to individual cable transmission lines, ensuring plug-and-play connectivity and compensating for cable aging and temperature fluctuations. The technology supports full duplex communication, and through its scalable bandwidth, can be flexibly adapted from entry-level to high-end vehicle systems. APIX3 is instrumental in establishing seamless vehicle network systems and is engineered to be integrated effortlessly into existing setups with minimal reconfiguration required.
RIFTEK's 2D Laser Scanners are engineered for high-precision, non-contact measurements of surface profiles and dimensions. These scanners are pivotal in creating accurate 3D models and support efficient sorting and inspection processes across various industries. Delivering detailed characterizations of object profiles, they employ dual-camera technology to enhance dimensional accuracy and cover larger fields of view. The RF627Smart series sets the bar high, integrating measurement capabilities and industry-standard protocols to enable streamlined automation processes. These intelligent profilers perform measurements, analysis, and tolerance checks directly within the scanner, simplifying the integration into automated lines. Equipped with built-in industrial protocols, these units can directly interact with robots and other automation systems, eliminating the need for external computing modules. Delivering exceptional resolution and high-speed sampling rates, these profilers capture extensive data quickly, facilitating real-time adjustments in complex applications such as weld seam tracking. Their durable design is emphasized by high IP ratings, ensuring that these units can withstand challenging industrial environments and maintain performance under continuous operation.
The ARINC 818 Product Suite by Great River Technology provides comprehensive solutions for developing systems compliant with the ARINC 818 standard. This suite includes a set of tools and resources designed to support the development, implementation, and testing of ARINC 818 products. Great River Technology's suite addresses mission-critical applications in areas such as cockpit displays and graphics generation. The ARINC 818 suite aids in streamlining the design process, ensuring systems meet rigorous performance and quality standards expected in the aerospace industry. With continued innovation, the suite is equipped to handle the evolving needs of avionics systems, maintaining compatibility with existing and future technologies.
The SL-400X Mobile TV Integrated Receiver is designed for an era where mobile consumption of media content is predominant. This compact device supports next-generation mobile digital television viewing, providing consumers with flexible access to broadcast TV channels on-the-go. Engineered by Saankhya Labs, the SL-400X integrates seamless signal reception with powerful decoder capabilities to enhance user experiences, even in environments with weaker signal strengths. Its software-defined nature allows for seamless adaptation to various tech upgrades and advancements in broadcasting standards. By adopting a low power, compact design, the SL-400X harmonizes high performance with portability. This makes it a preferred choice for mobile devices while ensuring audiences receive high-quality multimedia content reliably and effectively.
DigiLens offers advanced waveguide optics tailored for extended reality (XR) and augmented reality (AR) applications. Leveraging state-of-the-art materials and manufacturing processes, these waveguides provide high transmission rates exceeding 90% while maintaining a thin profile of less than 1.2 mm. Designed for both consumer and enterprise use, they exhibit superior brightness and resolution without compromising on eye comfort or social acceptability. Innovation is a hallmark of DigiLens's waveguides, marked by minimal eye glow, which ensures that the user's eyes are visible while minimizing distractions in various lighting conditions. The company's proprietary photopolymer material combined with precise inkjet printing techniques enables scalable production, making these waveguides suitable for a wide range of applications from gaming to professional use. The optical efficiency, averaging over 350 nits/lumen across the full field of view, makes these waveguides ideal for high-performance scenarios. Their adaptability and lightweight nature bring unprecedented flexibility to AR smartglasses, heralding a future where wearable tech seamlessly integrates with daily life. By focusing on the intersection of technology and design, DigiLens's waveguides represent a significant leap forward in reducing manufacturing costs while delivering premium AR experiences.
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 ELFIS2 is an advanced visible light image sensor notable for its radiation hardening, making it highly reliable in challenging environments. This sensor is engineered with a true high dynamic range, ensuring superior image quality across varying lighting conditions without suffering from motion artifacts. It features a global shutter technology combined with backside illumination, enhancing the capture of moving subjects and ensuring precise image reads.\n\nDesigned for durability, the ELFIS2 withstands high levels of radiation, making it suitable for use in aerospace and other environments exposed to high radiation levels. The sensor provides outstanding image clarity and fidelity, thanks to its architecture that minimizes noise and maximizes the dynamic range capabilities. This enables the sensor to perform exceedingly well in both low-light and high-contrast settings, making it ideal for scientific and industrial imaging applications.\n\nThe global shutter feature is pivotal in eliminating geometric distortion effects while its backside illumination maximizes light collection efficiency, vital for applications requiring stringent image quality. This makes ELFIS2 apt for scenarios demanding precise and error-free image capture, confirming its application in intricate research and development projects.
EMPIRE XPU is recognized for its robust capabilities as a 3D simulator for electromagnetic fields applied in antenna design, microwave circuits, and EM chip design. This simulation tool is esteemed for implementing the Finite Difference Time Domain (FDTD) method, recognized as a benchmark in the RF and microwave component design sectors. The simulator achieves rapid problem-solving, unparalleled by previous generation tools, allowing users to obtain results in minutes that previously required days. The software’s strength lies in its efficiency, achieving remarkable speeds through innovative algorithms that utilize the CPU’s cache memory for simultaneous calculations across multiple steps. This capability ensures the full RAM of a PC is efficiently harnessed for electromagnetic simulations, hastening the design process for large-scale and complex structures. EMPIRE XPU offers comprehensive support for 3D CAD formats, easing the import and export of various designs with healing functionalities for 3D structures. Its user-friendly graphical interface simplifies the design process, offering intuitive tools for multi-layer design and visualization of electromagnetic wave phenomena. Its powerful simulation capabilities make it indispensable for sectors that demand precision and efficiency in electromagnetic design.
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.
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.
The multiband multistandard direct-conversion TV tuner is a versatile solution engineered to handle multiple bands and standards in television signal reception. This tuner adopts a direct-conversion architecture, enabling seamless conversion of TV signals for better performance in digital and analog broadcast environments. Crafted using TSMC's 180nm biCMOS technology, it provides superior sensitivity and wide frequency coverage. The device efficiently supports a broad array of television standards, which ensures compatibility across different regional broadcast technologies. Its architecture minimizes signal loss and distortion, critical for maintaining high-quality video and audio outputs. Intended for integration into set-top boxes, televisions, and media capture devices, this tuner meets the needs of consumers requiring reliable signal processing capability in diverse ambient conditions. Its design facilitates easy integration with minimal implementation challenges, making it a staple in modern broadcasting and multimedia solutions.
Gyrus AI offers a Video Anonymization solution that employs state-of-the-art computer vision and deep learning techniques to ensure privacy in video surveillance. This technology utilizes intricate algorithms to mask, blur, or replace sensitive information in video footage, providing a reliable way to anonymize visual data without losing analytical value. The solution is particularly beneficial for organizations needing to comply with privacy regulations while simultaneously extracting valuable insights from video content. The Video Anonymization process has multiple levels of intensity, offering options such as face blurring or substitution with synthetic characters. This flexibility allows users to choose the appropriate level of privacy protection based on the specific requirements of their projects. Additionally, these models can be customized and deployed either on-premises or in cloud-based environments, ensuring versatility to meet varying IT infrastructure needs. By utilizing this IP, businesses can safely store, share, and analyze video data without breaching privacy regulations, turning anonymized data into actionable insights. This represents a forward-thinking approach to data security and compliance, effectively addressing the challenges of contemporary video surveillance and processing.
Designed with modern automotive systems in mind, the INAP590T transmitter supports high-speed digital data transfer essential for next-generation communication in infotainment and driving assistance systems. Featuring dual-channel support, the unit propels audio and video data over single twisted-pair cables, maintaining fidelity and integrity across expansive in-car networks. This transmitter plays a pivotal role in bridging advanced cockpit displays with backend processing systems through its robust HDMI and DSI video interfaces. It ensures encrypted data transfer using HDCP standards, safeguarding both media content and communication privacy. Furthermore, the INAP590T is designed to operate seamlessly within a wide range of digital ecosystems, encompassing SPI, AShell interfaces, and Ethernet, which increases its adaptability and integration potential in diverse automotive scenarios.
Incorporates the AMD Zynq UltraScale+ ZU47DR-1E, this RFSoC module is designed to meet high-performance requirements with its 4 GByte DDR4 memory and 128 MByte SPI Boot Flash. It boasts a significant size of 6.5 x 9 cm, supporting 8 RFADCs with 5 GSPS and 8 RFDACs with 9.85 GSPS, which provides robust signal conversion capabilities essential for telecommunication and defense applications.