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.
ISPido on the VIP Board is tailored for Lattice Semiconductors' Video Interface Platform, providing a runtime solution optimized for delivering crisp, balanced images in real-time. This solution offers two primary configurations: automatic deployment for optimal settings instantly upon startup, and a manual, menu-driven interface allowing users to fine-tune settings such as gamma tables and convolution filters. Utilizing the CrossLink VIP Input Bridge with Sony IMX 214 sensors and an ECP5-85 FPGA, it provides HD output in HDMI YCrCb format, ensuring high-quality image resolution and real-time calibration.
The iCan PicoPop® is a highly compact System on Module (SOM) based on the Zynq UltraScale+ MPSoC from Xilinx, suited for high-performance embedded applications in aerospace. Known for its advanced signal processing capabilities, it is particularly effective in video processing contexts, offering efficient data handling and throughput. Its compact size and performance make it ideal for integration into sophisticated systems where space and performance are critical.
ISPido offers a comprehensive set of IP cores focused on high-resolution image signal processing and tuning across multiple devices and platforms, including CPU, GPU, VPU, FPGA, and ASIC technologies. Its flexibility is a standout feature, accommodating ultra-low power devices as well as systems exceeding 8K resolution. Designed for devices where power efficiency and high-quality image processing are paramount, ISPido adapts to a range of hardware architectures to deliver optimal image quality and processing capabilities. The IP has been widely adopted in various applications, making it a cornerstone for industries requiring advanced image calibration and processing capabilities.
Sentire Radar systems by IMST are cutting-edge solutions for precise radar sensing and measurements. They provide accurate distance and speed assessments for various applications, using high-frequency circuits and advanced signal processing techniques. Ideal for autonomous navigation, industrial measurement, and surveillance, Sentire Radar systems are equipped with multi-channel antennas and powerful processing boards that manage radar deployment effectively. These units are adept at classifying targets and can integrate with AI technologies for enhanced decision-making capabilities.
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 Camera PHY Interface for Advanced Processes from Curious Corporation is engineered to support advanced imaging needs, optimizing data transfer in demanding environments. This interface excels in high-speed performance, providing robust connectivity for complex camera configurations. It is particularly valuable in applications requiring efficient bandwidth utilization and superior image data handling. Designed with modern imaging demands in mind, the Camera PHY Interface offers compatibility with various camera modules, allowing for seamless integration into diverse systems. Engineers can utilize this interface to enhance image capture capabilities, making it ideal for high-definition multimedia applications. Furthermore, its adaptability to different process nodes ensures that it can meet the rigorous demands of modern technological innovations. The interface's ability to support high-frequency operation while minimizing power consumption makes it suitable for portable and fixed imaging solutions.
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 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 Dynamic PhotoDetector (DPD) tailored for hearables by ActLight offers an unparalleled advancement in light sensing technology for compact audio devices. Designed for energy efficiency, the DPD operates at low voltages which not only conserves battery life but also maintains peak performance, crucial for modern, on-the-go audio wearables. With its high sensitivity, the sensor excels in detecting minute changes in light conditions, thus ensuring consistent and reliable biometric data acquisition. This makes it particularly advantageous for heart rate and activity monitoring in hearables, enhancing the overall user experience with precise health tracking capabilities.
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 designed to enhance image processing through high-precision execution. Featuring a robust architecture optimized for FP16 floating-point precision, it supports AI models adapted from PC or cloud infrastructure without the need for retraining. This capability makes it ideal for autonomous driving systems and reliable robotics, where high inference accuracy is paramount. The series also boasts adaptability to various deep neural network models for tasks such as object detection and semantic segmentation, offering versatile capabilities for AI application development.
The Platform-Level Interrupt Controller (PLIC) by Roa Logic is a comprehensive solution for managing interrupt signals in sophisticated and large-scale computing environments. Compatible with RISC-V platforms, it is fully parameterised and offers an efficient means to handle and prioritize multiple interrupt sources. The PLIC's design emphasizes scalability and flexibility, allowing developers to adapt the module for a wide range of system requirements. The PLIC supports a configurable number of interrupt sources, each with customizable priority levels. This enables a tailored approach to the handling of critical interrupts, ensuring that high-priority tasks receive immediate attention. It serves as an essential building block for systems that demand precise and reliable interrupt management, making it indispensable in complex processor environments. With its easy integration into existing RISC-V platforms, the PLIC provides a seamless upgrade to traditional interrupt controllers. Its high level of adaptability ensures that it can be calibrated to complement specific system architectures, enhancing performance in varied operational scenarios.
HES-DVM is a hybrid verification and validation environment specifically crafted for complex SoC and ASIC designs. This sophisticated system supports designs up to 633 million ASIC gates and is capable of accelerating simulation at bit-level with features such as SCE-MI 2.1 transaction emulation, hardware prototyping, and virtual modeling. By leveraging the latest co-emulation technologies, HES-DVM allows designers to explore robust emulation strategies that dramatically improve verification speed without sacrificing detail or accuracy. The product provides a fully scriptable environment, enabling automation of various verification tasks, which is vital for managing large-scale projects efficiently. Its integration capabilities with multiple hardware platforms allow seamless connectivity between design tools and physical prototypes, fostering a fluid and dynamic design process. HES-DVM also plays a critical role in supporting hardware scalability and flexibility. This aids designers in adjusting their approach as projects evolve, addressing shifting demands without a total overhaul of the verification strategy. This adaptability ensures HES-DVM remains a cornerstone tool for leading-edge design verification workflows.
IMG DXS GPU is engineered to meet the needs of automotive and industrial applications where functional safety is paramount. Built on efficient PowerVR architecture, it ensures high-performance graphics rendering with a focus on reduced power consumption. The DXS technology supports comprehensive safety suites, catering to ADAS and digital cockpit applications, thereby addressing stringent automotive safety standards.
The ant200 Vector Graphics Processor excels in 2D graphics rendering by providing high performance in compact devices. It strips down unnecessary functions to optimize for size and cost-efficiency, making it ideal for IoT products and mobile applications. This processor eliminates unnecessary features while upholding essential graphics processing tasks, ensuring that the final product remains both effective and economical. It fits seamlessly into low-power applications, delivering reliable graphics processing in resource-constrained environments.
The UART IP facilitates serial communication in embedded systems, ideal for applications requiring asynchronous data transfer. It features support for various data rates, ensuring compatibility with a wide array of devices and communication standards. This IP integrates seamlessly into different system architectures, offering a robust solution for efficient data interchange. It is designed to ensure high reliability and performance irrespective of operating conditions, making it indispensable in environments where consistent communication is critical. Through sophisticated resource management, the UART IP balances performance with power efficiency, ensuring minimal energy consumption without compromising on data integrity. This makes it optimal for use in diverse industries, from industrial automation to consumer electronics, where reliability and efficiency are paramount.
The UWB Impulse Radar Toolkit is a versatile and robust solution for environments requiring precise detection and monitoring capabilities. Utilizing ultra-wideband technology, this toolkit is designed to perform exceptionally well in applications where detecting subtle movements or changes is critical, such as in search and rescue operations or advanced surveillance systems. This toolkit is particularly well-suited for penetrating various materials, allowing for effective monitoring in diverse conditions and terrains. Its range and sensitivity make it invaluable for scientists and engineers in fields that require detailed subsurface and through-the-wall imaging capabilities. The UWB Impulse Radar Toolkit supports both research and practical applications by providing reliable and accurate data essential for decision-making. Durable and adaptable, this toolkit can be employed in a wide array of environments and for an array of purposes, from geological exploration to security monitoring. Its capability to deliver high-resolution, real-time data ensures that users are well-equipped to handle demanding operational needs.
The Automated Railway Crossing Surveillance System, known as PAKS, offers groundbreaking solutions for enhancing the safety and management of railway intersections. By implementing advanced surveillance technologies, PAKS ensures that crossings are monitored continuously and efficiently, reducing the risk of accidents and improving traffic flow. This system uses high-resolution cameras paired with state-of-the-art data analysis software to detect and report any obstructions or malfunctions in real time. By providing live updates and alerts to authorities, it facilitates timely interventions that can prevent potential incidents. The system's robust design allows it to operate effectively under varying weather conditions, making it a dependable choice for railway management worldwide. PAKS represents a significant leap forward in railway safety technology, combining innovative surveillance methods with reliable communication channels to enhance both operational efficiency and public safety.
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 ant300 GPU is dedicated to enhancing 3D graphical applications with a focus on efficiency and scalability. This GPU supports a wide range of 3D rendering tasks, delivering high-quality graphics for modern applications in entertainment and professional visualization. Benefiting from efficient shader processing and optimized memory architecture, it ensures that graphical applications maintain high performance while conserving energy. The ant300 offers a pivotal solution for systems where graphics processing and energy efficiency must go hand-in-hand.
The K3000 Vector Graphics Processor is tailored for delivering top-notch 2D graphics performance, particularly focusing on embedded devices. It supports APIs like OpenVG1.1, providing smooth and seamless 2D vector graphics rendering across various platforms. This processor is known for its high power efficiency and reduced footprint, making it suitable for portable devices and embedded systems. With robust compatibility for interfacing with digital displays, the K3000 is an optimal choice for UI-driven applications where power and performance are key.
The ant100 Mobile GPU focuses on providing efficient graphics processing capabilities for mobile devices. This GPU is designed to execute graphic rendering tasks with high efficiency, ensuring smooth performance in portable and energy-sensitive applications. Its architecture supports complex graphical functions while maintaining a low power profile, making it an excellent fit for smartphones, tablets, and other mobile electronics where extended battery life and reduced heat output are critical. With this GPU, users can experience superior graphics without compromising on device portability.
IQonIC Works' RISC-V PLIC is designed to handle complex interrupt management tasks in systems with multiple interrupt sources and destinations. Conforming to the RISC-V PLIC specification, the controller is highly configurable to suit the specific needs of various applications. It supports from 31 to 1023 interrupt sources and can manage up to 32 hardware thread (hart) contexts, enabling flexible and efficient interrupt handling across wide-ranging system architectures. The PLIC ensures secure and efficient allocation of interrupts through configurable priority levels and supports asynchronous and synchronous signal requests, as well as edge-triggered sensitivities. Its interface uses AHB-Lite for priority, enables, and claim completion settings, facilitating streamlined processing and response management. Designed for integration into both single and multiprocessor environments, the PLIC allows interrupt sharing across different processor execution contexts, thereby optimizing resource utilization. Through this functionality, the PLIC enhances the system's ability to manage a broad spectrum of asynchronous events, vital for high-performance and real-time applications.
The Universal Asynchronous Receiver Transmitter core supports communication via common standards like RS-232, RS-422, and RS-485. Through its adaptation to DO-254 standards, it ensures reliable data transmission in various electronic applications, ranging from consumer electronics to aerospace systems.
An LVDS transceiver designed for efficient data transmission, the OT3910b reduces electromagnetic interference and power consumption while maintaining high-speed data transfer. It is crucial in reducing noise levels in digital communication and computing systems, ensuring signal integrity and system performance. The transceiver’s design is tailored for modern multimedia and networking applications, providing a reliable solution for high-demand environments.
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