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.
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.
The iCan PicoPop® System on Module offers a compact solution for high-performance computing in constrained environments, particularly in the realm of aerospace technology. This system on module is designed to deliver robust computing power while maintaining minimal space usage, offering an excellent ratio of performance to size. The PicoPop® excels in integrating a variety of functions onto a single module, including processing, memory, and interface capabilities, which collectively handle the demanding requirements of aerospace applications. Its efficient power consumption and powerful processing capability make it ideally suited to a range of in-flight applications and systems. This solution is tailored to support the development of sophisticated aviation systems, ensuring scalability and flexibility in deployment. With its advanced features and compact form, the iCan PicoPop® System on Module stands out as a potent component for modern aerospace challenges.
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 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 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.
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.
Bitec's IP Camera Front End core is specifically optimized for Altera's CMOS sensor technology, offering a highly parameterized solution for camera systems. This innovative core facilitates enhanced image processing for camera applications, including surveillance, broadcasting, and industrial uses. The IP Camera Front End is engineered to deliver superior image clarity and precision, ensuring that high-quality video is captured under various environmental conditions. The core supports a range of customization features, allowing for fine-tuning of image outputs to suit specific application needs. Its design is focused on delivering real-time processing capabilities, making it possible to incorporate advanced camera functionalities that can be adapted quickly as technological trends evolve. With flexible integration capabilities, this core serves as a robust foundation for building high-performance camera systems. Whether for wide area monitoring or detailed image processing, Bitec's IP Camera Front End facilitates powerful performance and adaptability, ensuring exceptional results across diverse camera-based applications.
The Camera PHY Interface is cornerstone technology intended for contemporary camera systems requiring high-speed data transfer and compatibility with advanced semiconductor process nodes. It includes support for multiple interface types such as sub-LVDS, MIPI D-PHY, and HiSPi, making it adaptable over a wide range of imaging applications. With its robust integration capabilities, this interface supports powerful throughput, facilitating smooth data transitions critical for capturing high-resolution images and videos in real time.
Tailored for hearables, the Dynamic PhotoDetector (DPD) from ActLight offers significant improvements in ambient light detection crucial for enhancing user experiences in audio devices. The DPD is designed with a focus on low power consumption, ensuring extended use without frequent battery charges, which is a critical feature for earbuds and other in-ear devices. This technology facilitates the creation of adaptive audio environments by accurately responding to light variations, ultimately leveling up the performance of any audio-centric wearable technology. Its miniaturized profile combined with high sensitivity paves the way for more compact and efficient hearable designs, allowing manufacturers to build devices that are as aesthetically pleasing as they are functional.
The Platform-Level Interrupt Controller (PLIC) is a versatile and fully parameterized controller designed to manage interrupt signals in RISC-V platforms. It is compliant with the RISC-V standards, offering full customization to match various system needs, making it a critical component in managing complex interrupt schemes across different CPU environments. The PLIC ensures efficient handling of interrupts, optimizing both performance and resource utilization. With its flexible architecture, the PLIC can be tailored to fit a wide range of applications, enhancing its utility in diverse embedded systems. It supports multiple levels of interrupts, prioritization, and custom configurations, ensuring it can integrate seamlessly with other system components. The inclusion of this controller in a system design gives developers the tools needed to effectively manage interrupt processing, thus maintaining high system throughput and responsiveness.
The eFPGA Technology offered by QuickLogic emphasizes hardware re-programmability, allowing for the optimization of designs across a variety of applications. This technology is silicon-efficient and incorporates programmable logic architectures that are known for their reliability and quality at scale. It serves a broad spectrum of industries, providing the flexibility needed to adjust hardware functionalities post-production, thus extending the lifecycle and adaptability of electronic products.
Wireless non-radiative energy transfer technology developed by WiTricity offers a breakthrough in delivering power over distance without the need for physical connectors. This system utilizes magnetic resonance to enable efficient energy transfer between a source and a receiver, ensuring robust power delivery across varying distances. Critical to this technology's success is its ability to maintain high efficiency despite the presence of obstacles and misalignment of the power receiving and transmitting devices. The system's non-radiative nature implies that the power transfer does not rely on traditional wireless methods such as electromagnetic radiation, which can suffer from inefficiencies and regulatory constraints. Instead, it leverages resonant induction principles to facilitate energy flow over an essentially unbroken space, mitigating typical power loss associated with long-range energy transfer. WiTricity's wireless non-radiative technology is also adaptable across various environments and applications, including electric vehicle charging and industrial automation. It is designed with a focus on minimizing environmental impact while enhancing the user experience, making it an ideal solution for the future of wireless energy distribution.
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.
The UART IP is crafted to manage asynchronous data communication over various platforms efficiently. It stands as a versatile solution in embedded systems that require simple, reliable data exchanges over serial communication links. Focusing on straightforward data handling and compatibility, this IP facilitates communication between integrated circuits and devices across diverse application areas, from industrial automation to consumer electronics. UART IP's design emphasizes ease of use and integration, providing developers with the flexibility to ensure secure and seamless communication pathways in high-demand environments. It's a quintessential component for simplifying communication protocol implementation while maintaining robust performance.
The ZIA DV700 Series is a highly precise AI processing component tailored for advanced systems that demand top-tier reliability such as autonomous vehicles and robotics. This series incorporates standard support for FP16 precision floating-point operations which enables seamless integration without the need for model retraining, perfect for AI models developed on PC or cloud servers. This feature facilitates the system's ability to maintain high inference accuracy crucial in critical AI applications. Designed with deep learning in mind, the ZIA DV700 Series provides an optimal hardware architecture for inference tasks. Its hard-wired structure makes it ideal for detection tasks, semantic segmentation, skeleton estimation, and other varied DNN models by leveraging the power of Mobilenet, Yolo v3, SegNet, and PoseNet. Development is streamlined with the inclusion of a support environment (SDK/Tool), enabling smooth integration with AI frameworks such as Caffe, Keras, and TensorFlow. Once models are prepared under these frameworks, developers can effortlessly migrate AI inference tasks to the DV700 Series.
Ant200 is a graphics processor engineered specifically for efficient vector graphics processing. Ideal for use in compact systems, it processes vector graphics commands with high precision and speed. This unit is geared towards designers needing elegant and powerful processing without the energy cost of larger units. The processor is built to handle complex calculations seamlessly, employing cutting-edge algorithms that enhance vector graphic processing capabilities, crucial for rendering precise and sharp images required in graphic design applications. Versatile and powerful, the ant200’s deployment in compact systems makes it a reliable choice for applications demanding high-quality graphic outputs. The architecture of ant200 allows it to maintain the balance between performance and energy consumption, ensuring extended use in portable devices and embedded systems.
Ant300 GPU stands as a versatile graphics unit designed for compact devices, ensuring powerful graphics rendering capabilities in small hardware profiles. Its sophistication enables enhanced visual processing with reduced power requirements, making it an ideal component for mobile and embedded systems. The GPU delivers excellent results in image rendering and computation, exhibiting capabilities to perform complex graphical tasks with exceptional speed and energy performance. It supports various graphics standards and introduces developments that improve real-time graphics and imaging results. Ant300’s ability to merge powerful processing with compact design, allows developers to seamlessly integrate it into diverse platforms that require high-end visual performance without compromising on energy efficiency.
Ant100 Mobile GPU is a compact yet powerful graphics unit optimized for mobile devices needing high-performance graphics. Adapted for energy efficiency, it delivers robust graphical processing power while preserving battery life. Laden with features supporting graphic rendering and computational tasks, the Ant100 offers seamless graphics management in mobile environments, supporting the latest graphic standards and technologies for superior image clarity. Compact and efficient, Ant100 is a strategic fit for portable devices, balancing graphical potency with power conservation, providing an unmatched experience in mobile graphic capabilities.
The K3000 vector graphics processor, designed for high-performance vector graphics rendering, supports a range of applications from gaming to complex scientific visualization. Its architecture is tailored for the efficient processing of vector and geometric data, delivering high-speed rendering without sacrificing image quality. This processor employs advanced processing techniques to manage vector calculations and graphical transformations required in rendering high-detail, sharp images. With its focus on vector graphics, the K3000 ensures fast and efficient graphical workloads, adept for workflows involving extensive modeling and design applications. The processor’s adeptness at handling complex graphical requirements makes it a key player in industries where precision and speed are paramount, providing capabilities that extend to both gaming and professional graphic design settings.
Besso is a diagnostic tool for PCIe environments, providing high-speed debugging and in-depth diagnostic insights. This product is engineered to enhance the understanding of PCIe operations, making it invaluable for troubleshooting and ensuring optimal performance. Besso aids in identifying errors and bottlenecks within PCIe systems, thus facilitating smoother and more reliable data communication.
The JTAG TAP (Test Access Port) Controller delivers critical test access functions in integrated circuits, supporting standard JTAG protocol. Its implementation enables precise testing and debugging of complex systems, forming an essential element in device validation and fault isolation.
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