All IPs > Graphic & Peripheral > Interrupt Controller
In modern electronic systems, managing and prioritizing multiple tasks and processes effectively is crucial. An interrupt controller plays a pivotal role in this by managing the interrupts that require the processor’s attention immediately. This category of semiconductor IPs provides essential functionalities to handle various interrupts efficiently, ensuring that electronic devices operate smoothly and responsively.
Interrupt controller semiconductor IPs are integral components within microcontrollers, microprocessors, and system-on-chips (SoCs). They help in orchestrating seamless communication between the processor and peripheral devices by managing interrupt signals. These IPs allow for the prioritization and queuing of interrupt requests, ensuring that critical tasks are addressed promptly. The efficient operations of multimedia devices, network processors, and graphic subsystems often rely on sophisticated interrupt controllers to handle INTERRUPTs with minimal latency.
The products within this category are designed to enhance performance, reliability, and power efficiency of electronic devices. In complex devices where multiple peripheral components are integrated, such as smartphones and tablets, or in high-performance computing systems, interrupt controllers ensure that system resources are used optimally without unnecessary delays. Developers can select from a variety of interrupt controller semiconductor IPs tailored to different applications, ranging from simple designs for low-power devices to advanced solutions for high-performance systems.
Moreover, these semiconductor IPs are vital for developers seeking to build scalable systems able to handle increased processing demands. By employing robust interrupt control mechanisms, systems can be built to adapt to a range of operational conditions, enhancing both user experience and system longevity. Thus, the right choice of interrupt controller IP can significantly influence the overall efficiency and effectiveness of electronic products across various industries.
The Chipchain C100 is a pioneering solution in IoT applications, providing a highly integrated single-chip design that focuses on low power consumption without compromising performance. Its design incorporates a powerful 32-bit RISC-V CPU which can reach speeds up to 1.5GHz. This processing power ensures efficient and capable computing for diverse IoT applications. This chip stands out with its comprehensive integrated features including embedded RAM and ROM, making it efficient in both processing and computing tasks. Additionally, the C100 comes with integrated Wi-Fi and multiple interfaces for transmission, broadening its application potential significantly. Other notable features of the C100 include an ADC, LDO, and a temperature sensor, enabling it to handle a wide array of IoT tasks more seamlessly. With considerations for security and stability, the Chipchain C100 facilitates easier and faster development in IoT applications, proving itself as a versatile component in smart devices like security systems, home automation products, and wearable technology.
GNSS Sensor Ltd offers the GNSS VHDL Library, a powerful suite designed to support the integration of GNSS capabilities into FPGA and ASIC products. The library encompasses a range of components, including configurable GNSS engines, Viterbi decoders, RF front-end control modules, and a self-test module, providing a comprehensive toolkit for developers. This library is engineered to be highly flexible and adaptable, supporting a wide range of satellite systems such as GPS, GLONASS, and Galileo, across various configurations. Its architecture aims to ensure independence from specific CPU platforms, allowing for easy adoption across different systems. The GNSS VHDL Library is instrumental in developing cost-effective and simplified system-on-chip solutions, with capabilities to support extensive configurations and frequency bandwidths. It facilitates rapid prototyping and efficient verification processes, crucial for deploying reliable GNSS-enabled devices.
The iCan PicoPop® is a miniaturized system on module (SOM) based on the Xilinx Zynq UltraScale+ Multi-Processor System-on-Chip (MPSoC). This advanced module is designed to handle sophisticated signal processing tasks, making it particularly suited for aeronautic embedded systems that require high-performance video processing capabilities. The module leverages the powerful architecture of the Zynq MPSoC, providing a robust platform for developing cutting-edge avionics and defense solutions. With its compact form factor, the iCan PicoPop® SOM offers unparalleled flexibility and performance, allowing it to seamlessly integrate into various system architectures. The high level of integration offered by the Zynq UltraScale+ MPSoC aids in simplifying the design process while reducing system latency and power consumption, providing a highly efficient solution for demanding applications. Additionally, the iCan PicoPop® supports advanced functionalities through its integration of programmable logic, multi-core processing, and high-speed connectivity options, making it ideal for developing next-generation applications in video processing and other complex avionics functions. Its modular design also allows for easy customization, enabling developers to tailor the system to meet specific performance and functionality needs, ensuring optimal adaptability for intricate aerospace environments. Overall, the iCan PicoPop® demonstrates a remarkable blend of high-performance computing capabilities and adaptable configurations, making it a valuable asset in the development of high-tech avionics solutions designed to withstand rigorous operational demands in aviation and defense.
ISPido represents a fully configurable RTL Image Signal Processing Pipeline, adhering to the AMBA AXI4 standards and tailored through the AXI4-LITE protocol for seamless integration with systems such as RISC-V. This advanced pipeline supports a variety of image processing functions like defective pixel correction, color filter interpolation using the Malvar-Cutler algorithm, and auto-white balance, among others. Designed to handle resolutions up to 7680x7680, ISPido provides compatibility for both 4K and 8K video systems, with support for 8, 10, or 12-bit depth inputs. Each module within this pipeline can be fine-tuned to fit specific requirements, making it a versatile choice for adapting to various imaging needs. The architecture's compatibility with flexible standards ensures robust performance and adaptability in diverse applications, from consumer electronics to professional-grade imaging solutions. Through its compact design, ISPido optimizes area and energy efficiency, providing high-quality image processing while keeping hardware demands low. This makes it suitable for battery-operated devices where power efficiency is crucial, without sacrificing the processing power needed for high-resolution outputs.
ISPido on VIP Board is a customized runtime solution tailored for Lattice Semiconductors’ Video Interface Platform (VIP) board. This setup enables real-time image processing and provides flexibility for both automated configuration and manual control through a menu interface. Users can adjust settings via histogram readings, select gamma tables, and apply convolutional filters to achieve optimal image quality. Equipped with key components like the CrossLink VIP input bridge board and ECP5 VIP Processor with ECP5-85 FPGA, this solution supports dual image sensors to produce a 1920x1080p HDMI output. The platform enables dynamic runtime calibration, providing users with interface options for active parameter adjustments, ensuring that image settings are fine-tuned for various applications. This system is particularly advantageous for developers and engineers looking to integrate sophisticated image processing capabilities into their devices. Its runtime flexibility and comprehensive set of features make it a valuable tool for prototyping and deploying scalable imaging solutions.
The Camera PHY Interface tailored for advanced semiconductor processes is integral for optimizing high-speed data transmission between image sensors and processors. Specialized to accommodate the latest advancements in process technology, this interface IP ensures superior performance while maintaining minimal power consumption and enhanced data integrity. By leveraging cutting-edge technology, it is engineered to handle multiple data lanes simultaneously, providing flexibility and adaptability across various applications in the visual data industry. This interface finds its utility in high-definition imaging solutions, contributing significantly to industries such as automotive, consumer electronics, medical imaging, and surveillance systems. Its design is aimed at simplifying integration in complex systems while providing robust data throughput and decreasing electromagnetic interference to ensure unmitigated signal clarity. With compatibility extending to the sub-LVDS, MIPI D-PHY, and HiSPi standards, this Camera PHY Interface IP is adaptable for evolving interface technologies, ensuring that devices can benefit from advanced connectivity protocols without compromising on performance metrics. The adoption of this IP supports industry trends towards miniaturization and reduced device footprints, thus making it indispensable for modern imaging solutions.
The IP Camera Front End from Bitec is tailored for optimizing CMOS sensor outputs, providing high-performance IP core solutions designed for digital video stream processing. Fully parameterized, this core supports a wide range of sensor types and configurations, making it adaptable to numerous application needs including surveillance, broadcasting, and consumer electronics. By integrating with Altera devices, the core offers streamlined processing, aligning with standard industry practices for image capture and processing. It ensures minimal latency and high efficiency in operating image pipelines, which is crucial for applications requiring real-time video analysis and transmission. This IP core's flexibility allows for significant customization, ensuring that it can be fine-tuned to meet the demands of diverse imaging tasks. By leveraging its parameterization capabilities, developers can optimize power consumption and data throughput, enhancing both the performance and efficiency of camera systems designed for various sectors.
The Satellite Navigation SoC Integration offering by GNSS Sensor Ltd is a comprehensive solution designed to integrate sophisticated satellite navigation capabilities into System-on-Chip (SoC) architectures. It utilizes GNSS Sensor's proprietary VHDL library, which includes modules like the configurable GNSS engine, Fast Search Engine for satellite systems, and more, optimized for maximum CPU independence and flexibility. This SoC integration supports various satellite navigation systems like GPS, Glonass, and Galileo, with efficient hardware designs that allow it to process signals across multiple frequency bands. The solution emphasizes reduced development costs and streamlining the navigation module integration process. Leveraging FPGA platforms, GNSS Sensor's solution integrates intricate RF front-end components, allowing for a robust and adaptable GNSS receiver development. The system-on-chip solution ensures high performance, with features like firmware stored on ROM blocks, obviating the need for external memory.
The logiCVC-ML is an advanced display controller that supports resolutions up to 2048x2048, tailored for TFT LCD displays. Optimized for AMD's Zynq 7000 AP SoC and FPGAs, this IP core is equipped with software drivers compatible with Linux, Android, and Windows Embedded Compact 7. This versatility ensures the logiCVC-ML can be implemented across a wide array of applications demanding high-resolution display capabilities. With a strong focus on integrating with existing systems, the logiCVC-ML offers multilayer video capabilities, making it ideal for complex display needs in various industries. Its support extends beyond simple display output, accommodating sophisticated graphics operations that enhance user experiences across diverse platforms. The IP core's efficient use of resources ensures minimal impact on overall system performance, allowing developers to allocate resources to other critical functions. The logiCVC-ML thus represents a blend of high performance and resource efficiency, making it a valuable component in any high-resolution display application.
ActLight's Dynamic PhotoDetector (DPD) technology, optimized for hearable devices, offers high sensitivity and reliability even in low-light environments. By eliminating the need for additional amplification thanks to advanced dynamic detection modes, the DPD ensures consistent and precise biometric data collection. This efficiency translates into hearables that consume less power, enabling longer device usage and supporting an active lifestyle. Designed with precision and compactness in mind, these sensors set new standards for hearable technology, enhancing user experience with accurate vital sign monitoring.
eFPGA Technology from QuickLogic allows for hardware reprogrammability, optimizing solutions for various applications. This innovative technology is designed to be silicon-efficient, ensuring reliability and high-quality logic architectures at scale. The eFPGA offerings are crafted to support versatility in projects, from strategic systems to critical infrastructure, ensuring adaptability and efficiency. QuickLogic’s eFPGA Technology seamlessly integrates with open-source modules, providing scalability and transparency. This integration supports longevity and adaptability in changing technological landscapes, thereby improving the future viability of developed solutions. With a focus on minimizing risks, QuickLogic aids in developing eFPGA solutions from their initial architecture through to silicon verification. Targeting applications in fields necessitating ruggedized solutions, the technology is well-suited for industries such as aerospace and defense. Moreover, QuickLogic combines its eFPGA solutions with post-quantum cryptographic readiness, thereby ensuring robustness against emerging security threats. This approach helps QuickLogic to maintain its position as a cutting-edge provider of FPGA technology for demanding environments.
The WDR Core provides an advanced approach to wide dynamic range imaging by controlling image tone curves automatically based on scene analysis. This core is adept at ensuring that both shadows and highlights are appropriately compensated, thus maintaining image contrast and true color fidelity without the reliance on frame memory. Automatic adjustments extend the dynamic range of captured images, providing detailed correction in overexposed and underexposed areas. This capability is vital for environments with variable lighting conditions where traditional gamma corrections might introduce inaccuracies or unnatural visual effects. The core focuses on enhancing the user experience by delivering detailed and balanced images across diverse scenarios. Its versatility is particularly useful in applications like surveillance, where clarity across a range of light levels is critical, and in consumer electronics that require high-quality imaging in varying illumination.
This technology represents a significant innovation in the field of wireless energy transfer, allowing for the efficient transmission of power without physical connections or radiation. By leveraging magnetic resonance, this non-radiative energy transfer system can power devices over distances with high efficiency. It's designed to be safe and environmentally friendly, avoiding the pitfalls of electromagnetic radiation while maintaining a high level of power transfer efficiency. The technology finds its applications in various sectors, including consumer electronics, automotive, and industrial applications where it provides a seamless and reliable solution to power transfer needs. The system's capability to transfer power efficiently without contact makes it ideal for scenarios where traditional power connections might be impractical or inconvenient, enabling new levels of convenience and flexibility for users. Designed to integrate smoothly with existing infrastructure, this energy transfer system can significantly reduce reliance on traditional charging methods, paving the way for more innovative and sustainable energy solutions. Furthermore, the system's architecture is geared towards scalability and adaptability, making it suitable for a wide range of devices and use cases.
The HDR Core is engineered to deliver enhanced dynamic range image processing by amalgamating multiple exposures to preserve image details in both bright and dim environments. It has the ability to support 120dB HDR through the integration of sensors like IMX585 and OV10640, among others. This core applies motion compensation alongside detection algorithms to mitigate ghosting effects in HDR imaging. It operates by effectively combining staggered based, dual conversion gain, and split pixel HDR sensor techniques to achieve realistic image outputs with preserved local contrast. The core adapts through frame-based HDR processing even when used with non-HDR sensors, demonstrating flexibility across various imaging conditions. Tone mapping is utilized within the HDR Core to adjust the high dynamic range image to fit the display capabilities of devices, ensuring color accuracy and local contrast are maintained without introducing noise, even in low light conditions. This makes the core highly valuable in applications where image quality and accuracy are paramount.
The ZIA DV700 Series is a sophisticated AI processor designed to meet the challenges of next-generation AI applications. It excels in executing complex computations quickly and accurately, thanks to its powerful architecture that supports a broad range of neural network models. The series is renowned for its high precision and flexibility, making it suitable for various AI applications that demand rapid and accurate processing.
The ant200 Vector Graphics Processor stands out for its optimization in size and cost-effectiveness while delivering robust 2D graphics performance. It is more compact than its predecessors by stripping away unnecessary technical features, making it ideal for embedded systems with constrained resources. Its design supports a wide range of display resolutions, providing flexibility for device integration without compromising on graphics quality.
The ant300 GPU is crafted to balance power consumption and high-efficiency 3D rendering, optimizing performance for applications ranging from automotive to personal computing. With its robust graphical capabilities and efficient resource management, it excels in environments where detailed 3D graphics and visualization are crucial, managing complex calculations and rendering tasks seamlessly.
Besso PCIe Diagnostics is designed to offer deep insights into the operation of PCIe systems. This software solution equips users with an advanced diagnostic toolset, enabling thorough analysis and debugging of system performance. Through features like EyeScope, BER monitors, and comprehensive logic analyzers, Besso allows engineers to gain unparalleled visibility into PCIe link activity without needing expensive laboratory equipment. The intuitive dashboard interface of Besso simplifies the process of remotely monitoring and analyzing PCIe systems. Capable of operating in both laboratory and field environments, it enhances server, networking, and storage equipment by providing detailed data on link transitions, errors, and overall system states. Besso is especially useful in systematically breaking down complex networks, offering diagnostics that aid in swift identification and rectification of issues that might not be immediately visible. The software's bifurcation mode further extends its utility, letting users test and monitor multiple link segments simultaneously. This makes Besso an invaluable tool for maintaining high-performance and reliable operation across extensive PCIe infrastructures, thereby facilitating efficient problem-solving and system optimization.
The ant100 Mobile GPU is designed for portable and mobile devices, optimizing performance for 3D graphic rendering. This GPU combines power efficiency with high graphical throughput, addressing the needs of gaming and multimedia applications on mobile platforms. Its architecture is crafted to manage resource constraints efficiently while delivering a premium graphical experience, making it perfect for smartphones and other handheld devices.
The K3000 Vector Graphics Processor is tailored for high-performance and low-power 2D vector graphics processing. Emphasizing industry-leading Power/Performance/Area (PPA) metrics, it is based on OpenVG 1.1 standards, offering seamless integration with UI applications in cameras and printers. The processor supports a wide array of applications in digital cameras, media devices, and automotive instruments, delivering smooth 2D rendering to enhance user experience.
The Platform-Level Interrupt Controller (PLIC) from Roa Logic is a fully compliant and flexible solution designed in accordance with the RISC-V specifications. This interrupt controller is crucial for managing multiple interrupt sources in a computing system, providing reliable and efficient handling of interrupt requests. Its parameterized design enables easy configuration to meet specific project requirements, thus offering an adaptable solution for varied embedded applications.
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