All IPs > Graphic & Peripheral > Peripheral Controller
Peripheral Controller semiconductor IPs play a crucial role in the seamless integration of peripherals with core processing units, enhancing the functionality and connectivity of various electronic devices. These IPs are designed to manage the communication between the central processing unit (CPU) and external devices such as keyboards, mice, printers, and other peripherals. By enabling efficient data transfer and control signals between components, Peripheral Controller IPs ensure that systems operate smoothly and efficiently.
A key application of Peripheral Controller semiconductor IPs is in consumer electronics, where they facilitate the connection of tablets, smartphones, and laptops to a multitude of accessories and networks. For example, Universal Serial Bus (USB) controllers, memory card readers, and audio interfaces are just a few of the peripherals that these IPs manage. This allows end-users to transfer data quickly, connect various devices seamlessly, and enjoy a more versatile computing experience.
In industrial and automotive sectors, Peripheral Controller IPs are vital for maintaining robust and reliable communication within complex electronic systems. They are used to interface with sensors, actuators, and other control systems, ensuring that necessary data is transmitted accurately and in real-time. This is critical for applications that require precise timing and synchronization, such as automated manufacturing systems, smart grids, and advanced driver-assistance systems (ADAS).
Moreover, the evolution of Internet of Things (IoT) devices has further expanded the importance of Peripheral Controller IPs. As IoT ecosystems continue to grow, the need for efficient data management and connectivity solutions becomes more prominent. Peripheral Controller IPs offer the adaptability and scalability required to support a wide array of IoT applications, ensuring that devices can connect, communicate, and interact with each other effectively in both personal and industrial settings.
Overview: The UCIe IP supports multiple protocols (CXL/PCIe/Streaming) to connect chiplets, reducing overall development cycles for IPs and SOCs. With flexible application and PHY interfaces, The UCIe IP is ideal for SOCs and chiplets. Key Features: Supports UCIe 1.0 Specification Supports CXL 2.0 and CXL 3.0 Specifications Supports PCIe Gen6 Specification Supports PCIe Gen5 and older versions of PCIe specifications Supports single and two-stack modules Supports CXL 2.0 68Byte flit mode with Fallback mode for PCIe non-flit mode transfers Supports CXL 3.0 256Byte flit mode Supports PCIe Gen6 flit mode Configurable up to 64-lane configuration for Advanced UCIe modules and 16 lanes for Standard UCIe modules Supports sideband and Mainband signals Supports Lane repair handling Data to clock point training and eye width sweep support from transmitter and receiver ends UCIe controller can work as Downstream or Upstream Main Band Lane reversal supported Dynamic sense of normal and redundant clock and data lines activation UCIe enumeration through DVSEC Error logging and reporting supported Error injection supported through Register programming RDI/FDI PM entry, Exit, Abort flows supported Dynamic clock gang at adapter supported Configurable Options: Maximum link width (x1, x2, x4, x8, x16) MPS (128B to 4KB) MRRS (128B to 4KB) Transmit retry/Receive buffer size Number of Virtual Channels L1 PM substate support Optional Capability Features can be Configured Number of PF/VFDMA configurable Options AXI MAX payload size Variations Multiple CPI Interfaces (Configurable) Cache/memory configurable Type 0/1/2 device configurable
iWave Global introduces the ARINC 818 Switch, a pivotal component in the management and routing of video data within avionics systems. Designed for applications that require efficient video data distribution and management, the switch is optimized for performance in environments with stringent data handling requirements. The switch's architecture supports a high level of bandwidth, allowing for the smooth routing of multiple video streams in real-time. Its design includes advanced features that ensure low-latency, error-free data transfer, integral to maintaining the integrity and reliability of video data in critical applications. Featuring robust interoperability characteristics, the ARINC 818 Switch easily integrates into existing systems, facilitating modular expansion and adaptability to new technological standards. It is indispensable for any aerospace project that involves complex video data management, providing a stable platform for video data routing and switching.
Our Expanded Serial Peripheral Interface (JESD251) Master controller features a low signal count and high data bandwidth, making it ideal for use in computing, automotive, Internet of Things, embedded systems, and mobile system processors. It connects multiple sources of Serial Peripheral Interface (xSPI) slave devices, including nonvolatile memories, graphics peripherals, networking peripherals, FPGAs, and sensor devices. Features • Compliant with JEDEC standard JESD251 expanded Serial Peripheral Interface (xSPI) for Non-Volatile Memory Devices, Version 1.0. • Supports a single master and multiple slaves per interface port. • Supports Single Data Rate and Double Data Rate. • Supports source synchronous clocking. • Supports data transfer rates up to: o 400MT/s (200MHz Clock) o 333MT/s (167MHz Clock) o 266MT/s (133MHz Clock) o 200MT/s (100MHz Clock) • Supports Deep Power Down (DPD) enter and exit commands. • Standard support for eight IO ports, with the possibility to increase IO ports based on system performance requirements. • Optional support for Data Strobe (DS) for writemasking. • Supports 1-bit wide SDR transfer. • Supports Profile 1.0 commands to manage nonvolatile memory devices. • Supports Profile 2.0 commands to read or writedata for any type of slave device. • Compatible with non-volatile memory arrays such as NOR Flash, NAND Flash, FRAM, and nvSRAM. • Compatible with volatile memory arrays such as SRAM, PSRAM, and DRAM. • Supports register-mapped input/output functions. • Supports programmable function devices such as FPGAs. Application • Consumer Electronics. • Defence & Aerospace. • Virtual Reality. • Augmented Reality. • Medical. • Biometrics (Fingerprints, etc). • Automotive Devices. • Sensor Devices. Deliverables • Verilog Source code. • User Guide. • IP Integration Guide. • Run and Synthesis script. • Encrypted Verification Testbench Environment. • Basic Test-suite.
Overview: The Expanded Serial Peripheral Interface (xSPI) Master/Slave controller offers high data throughput, low signal count, and limited backward compatibility with legacy SPI devices. It is designed to connect xSPI Master/Slave devices in computing, automotive, Internet of Things, embedded systems, and mobile processors to various peripherals such as non-volatile memories, graphics peripherals, networking devices, FPGAs, and sensor devices. Key Features: Compliance with JEDEC standard JESD251 eXpanded SPI for Non-Volatile Memory Devices, Version 1.0 Support for Single master and multiple slaves per interface port Single Data Rate (SDR) and Double Data Rate (DDR) support Source synchronous clocking Deep Power Down (DPD) enter and exit commands Eight IO ports in standard, expandable based on system requirements Optional Data Strobe (DS) for write masking bit wide SDR transfer support Profile 1.0 Commands for non-volatile memory device management Profile 2.0 Commands for read or write data for various slave devices Applications: Consumer Electronics Defense & Aerospace Virtual Reality Augmented Reality Medical Biometrics Automotive Devices Sensor Devices
Overview: PCIe Gen6 is a high-speed, layered protocol interconnect interface supporting speeds up to 64GT/s, featuring multi-lanes and links. The Transport, Data Link, and Physical layers specified in the PCIe specification are implemented, along with PIPE interface logic connecting to PHY and AXI Bridging logic for application connectivity. Specifications: Supports PCIe Gen 6 and Pipe 5.X Specifications Core supports Flit and non-Flit Mode Lane Configurations: X16, X8, X4, X2, X1 AXI MM and Streaming supported Supports Gen1 to Gen6 modes Data rate support of 2.5 GT/s, 5 GT/s, 8 GT/s, 16 GT/s, 32 GT/s, 64 GT/s PAM support when operating at 64GT/s Encoding/Decoding Support: 8b/10b, 128b/130b, 1b/1b Supports SerDes and non-SerDes architecture Optional DMA support as plugin module Support for alternate negotiation protocol Can operate as an endpoint or root complex Lane polarity control through register Lane de-skew supported Support for L1 states and L0P Support for SKP OS add/removal and SRIS mode No equalization support through configuration Deemphasis negotiation support at 5GT/s Supports EI inferences in all modes Supports PTM, OBFF, MSI, MSIX, Power management, and all message formats
The ARINC 818 Product Suite by Great River Technology provides a comprehensive solution for high-performance digital video transmission in avionics applications. It supports the implementation, qualification, testing, and simulation of ARINC 818 products. This suite allows developers to access essential ARINC 818 tools and resources. It ensures optimal performance and reliability in mission-critical equipment by offering both hardware and software components tailored for the ARINC 818 standard. With its focus on high-speed data transfer and signal integrity, the ARINC 818 Product Suite is ideal for applications requiring lossless video transmission and real-time data handling in challenging conditions.
Stereax is Ilika's micro-scale solid state battery innovation, designed primarily for use in miniature and implantable medical devices as well as industrial IoT sensors. Known for their ultra-thin and mm-scale form factor, Stereax batteries eliminate the presence of liquid or polymer components, which significantly enhances their safety profile. They are engineered to deliver long-lasting power, with a capability to undergo thousands of charge cycles, making them particularly suitable for critical applications requiring reliability and minimal maintenance. These batteries are compact yet powerful, adopting a rectangular IC-like form factor suitable for disruptive device designs. Stereax batteries maintain high capacity despite their small size, offering significant pulse power and low leakage, ideal for devices where space and performance are at a premium. This makes Stereax an attractive choice for innovations in medical technology, enabling new possibilities in areas such as neurostimulation, cardiac sensing, and smart orthopaedics. The collaboration with Cirtec Medical stands out in the commercialization path of Stereax, where Cirtec handles manufacturing and distribution under a licensing agreement with Ilika. This partnership exemplifies Ilika's approach to integrating cutting-edge technology with effective commercial strategies, ensuring that Stereax batteries become an industry-standard in their fields of application.
iWave Global delivers the Serial FPDP (sFPDP) solution, a high-bandwidth, low-latency serial communication protocol widely deployed in high-performance computing systems. This technology is optimized for applications that require rapid data transport, such as radar and high-definition video processing, making it a vital tool in industrial and defense sectors. By supporting high throughput rates, the Serial FPDP ensures timely and reliable data transmission, crucial for systems where time sensitivity and data integrity are paramount. The solution is particularly designed to address real-time data operations, ensuring that data handling meets rigorous industry standards. With its robust design, the Serial FPDP accommodates various network topologies, allowing for the flexible deployment of communication systems. This flexibility and performance make it highly applicable in environments where system designers demand unobstructed high-speed data transfer capabilities.
The KL530 represents a significant advancement in AI chip technology with a new NPU architecture optimized for both INT4 precision and transformer networks. This SOC is engineered to provide high processing efficiency and low power consumption, making it suitable for AIoT applications and other innovative scenarios. It features an ARM Cortex M4 CPU designed for low-power operation and offers a robust computational power of up to 1 TOPS. The chip's ISP enhances image quality, while its codec ensures efficient multimedia compression. Notably, the chip's cold start time is under 500 ms with an average power draw of less than 500 mW, establishing it as a leader in energy efficiency.
Silicon Creations crafts highly reliable LVDS interfaces designed to meet diverse application needs, going from bi-directional I/Os to specialized uni-directional configurations. Spanning process compatibilities from 90nm CMOS to advanced 7nm FinFET, these interfaces are a cornerstone for high-speed data communication systems, thriving particularly in video data transmission and chip-to-chip communications. Supporting robust data rates over multiple channels, the LVDS Interfaces guarantee flexible programmability and protocol compatibility with standards such as FPD-Link and Camera-Link. They capitalize on proven PLL and CDR architectures for superior signal integrity and error-free data transfers. Operating efficiently in various technology nodes, they remain highly effective across collaborative chipset environments. The interfaces are fortified with adaptable features like dynamic phase alignment to stabilize data sequences and on-die termination options for superior signal integrity. Their proven record places them as a critical enabler in applications where consistent high-speed data transfer is paramount, demonstrating Silicon Creations’ prowess in delivering industry-leading communication solutions.
eSi-Connect offers an extensive suite of AMBA-compliant peripheral IPs designed to streamline SoC integration. This suite encompasses versatile memory controllers, standard off-chip interface support, and essential control functions. Its configurability and compatibility with low-level software drivers make it suitable for real-time deployment in complex system architectures, promoting reliable connectivity across various applications.
Our Expanded Serial Peripheral Interface (JESD251) Slave controller offers high data throughput, low signal count, and limited backward compatibility with legacy Serial Peripheral Interface (SPI) devices. It is used to connect xSPI Master devices in computing, automotive, Internet of Things, embedded systems, and mobile system processors to non-volatile memories, graphics peripherals, networking peripherals, FPGAs, and sensor devices. Features • Compliant with JEDEC standard JESD251 expanded Serial Peripheral Interface (xSPI) for Non-Volatile Memory Devices, Version 1.0. • Supports Single Data Rate (SDR) and Double Data Rate (DDR). • Supports source synchronous clocking. • Supports data transfer rates up to: o 400MT/s (200MHz Clock) o 333MT/s (167MHz Clock) o 266MT/s (133MHz Clock) o 200MT/s (100MHz Clock) • Supports Deep Power Down (DPD) enter and exit commands. • Standard support for eight IO ports, with the possibility to increase IO ports based on system performance requirements. • Optional support for Data Strobe (DS) for timing reference. • Supports 1-bit wide SDR transfer. • Supports Profile 1.0 commands to manage nonvolatile memory devices. • Supports Profile 2.0 commands for reading or writing data for any type of slave device. • Compatible with non-volatile memory arrays such as NOR Flash, NAND Flash, FRAM, and nvSRAM. • Compatible with volatile memory arrays such as SRAM, PSRAM, and DRAM. • Supports register-mapped input/output functions. • Supports programmable function devices such as FPGAs. Application • Consumer Electronics. • Defence & Aerospace. • Virtual Reality. • Augmented Reality. • Medical. • Biometrics (Fingerprints, etc). • Automotive Devices. • Sensor Devices. Deliverables • Verilog Source code. • User Guide. • IP Integration Guide. • Run and Synthesis script. • Encrypted Verification Testbench Environment. • Basic Test-suite.
Overview: The Multi-Protocol Accelerator IP is a versatile technology designed to support low latency and high bandwidth accelerators for efficient CPU-to-device and CPU-to-memory communication. It also enables switching for fan-out to connect more devices, memory pooling for increased memory utilization efficiency, and provides memory capacity with support for hot-plug, security enhancements, persistent memory support, and memory error reporting. Key Features: CXL 3.0 Support: Compliant with CXL spec V3.X/V2.X PCIe Compatibility: Supports PCIe spec 6.0/5.0 CPI Interface: Support for CPI Interface AXI Interface: Configurable AXI master, AXI slave Bus Support: PIPE/FLEX bus, Lane x1,x2,x4,x8,x16 Protocol Support: Gen3, Gen4, Gen5 & Gen6, Fallback Mode Register Checks: Configuration and Memory Mapped registers Dual Mode: Supports Dual Mode operation Transfer Support: HBR/PBR & LOpt Transfers, Standard Cache and Mem Transfers CXL Support: Can function as both CXL host and device Data Transfer: Supports Standard IO, 68Byte Flit, and 256Byte Flit Transfers FlexBus Features: FlexBus Link Features, ARB/MUX, ARB/MUX Bypass Optimization: Latency Optimization, Credit Return Forcing, Empty Flits (Latency Optimized) Power Management: Supports Power Management features Enhancements: CXL IDE, RAS Features, Poison & Viral Handling, MLD/SLD Testing: Compliance Testing and Error Scenarios support
aLFA-C is another notable product from Caeleste, intended for diverse applications requiring refined imaging capabilities. This sensor is exemplary in balancing speed and precision, catering to both scientific and industrial imaging requirements. Its design includes advanced features that ensure reliable image quality, even in suboptimal lighting conditions, making it a versatile tool for industries that demand rigorous accuracy.\n\nBuilt by leveraging Caeleste's extensive knowledge in CMOS image sensor technology, the aLFA-C provides users with flexibility in utilization across varying scenarios. From capturing high-speed industrial processes to detailed life sciences imaging, this sensor adapts to deliver optimal results. Its robustness and precision imaging are supported by sophisticated sensor architecture that minimizes noise while maintaining the integrity of the readout signal.\n\nCaeleste’s focus on offering customizable solutions is evident in the aLFA-C sensor's adaptability to different usage parameters, allowing users to achieve their specific imaging goals. The sensor represents a blend of performance and adaptability, ensuring that whatever the need, from industrial inspections to detailed scientific analysis, aLFA-C consistently delivers.
aiSim 5 is a state-of-the-art automotive simulation platform designed for ADAS and autonomous driving testing. Recognized as the world's first ISO26262 ASIL-D certified simulator, it offers unparalleled accuracy and determinism in simulating various driving scenarios and environmental conditions. The simulator integrates AI-based digital twin technology and an advanced rendering engine to create realistic traffic scenarios, helping engineers verify and validate driver assistance systems. Harnessing powerful physics-based simulation capabilities, aiSim 5 replicates real-world phenomena like weather effects and complex traffic dynamics with precision. By offering a comprehensive set of 3D assets and scenarios, it allows for the extensive testing of systems in both typical and edge conditions. With its flexible and open architecture, aiSim 5 can seamlessly integrate into existing testing toolchains, supporting significant variations in sensor configurations and driving algorithms. The platform encourages innovation in simulation methodologies by providing tools for scenario randomization and synthetic data generation, crucial for developing resilient ADAS applications. Additionally, its cloud-ready architecture makes it applicable across various hardware platforms, turning simulation into a versatile resource available on inexpensive or high-end computing configurations alike.
The ARINC 818-3 IP Core from iWave Global represents an advancement in avionics video interface technology, designed for high-speed and high-fidelity video data transmission. This IP core addresses the needs of modern aerospace systems that require robust video communication links both for military and commercial use. It supports a wide array of enhancements over previous generations, including increased bandwidth and improved signal integrity. This ensures that the ARINC 818-3 IP Core can handle the demands of next-generation avionic systems seamlessly, supporting advanced video processing and display systems. The core's design prioritizes modularity and scalability, allowing for easy integration and expansion to meet evolving system requirements. It is positioned as an essential tool for aviation applications demanding high reliability and accuracy in video data handling and display solutions, making it indispensable for new and retrofitted aerospace projects.
Bluespec's Portable RISC-V Cores are designed to bring flexibility and extended functionality to FPGA platforms such as Achronix, Xilinx, Lattice, and Microsemi. They offer support for operating systems like Linux and FreeRTOS, making them versatile for various applications. These cores are accompanied by standard open-source development tools, which facilitate seamless integration and development processes. By utilizing these tools, developers can modify and enhance the cores to suit their specific needs, ensuring a custom fit for their projects. The portable cores are an excellent choice for developers looking to deploy RISC-V architecture across different FPGA platforms without being tied down to proprietary solutions. With Bluespec's focus on open-source, users can experience freedom in innovation and development without sacrificing performance or compatibility.
The HOTLink II Product Suite by Great River Technology is tailored for mission-critical avionics systems requiring robust data communication. It enables seamless data transfer and ensures consistent performance under high-stress operational environments. This suite incorporates advanced technologies to handle complex data streams effectively. It includes component options that enhance data throughput and communication efficiency, meeting stringent industry standards for avionics platforms. Designed with precision, the HOTLink II suite supports the integration and management of large datasets, ensuring that avionics systems can perform efficiently and reliably, crucial for modern aircraft and defense applications.
The Mixed-Signal CODEC offered by Archband Labs integrates advanced analog and digital audio processing to deliver superior sound quality. Designed for a variety of applications such as portable audio devices, automotive systems, and entertainment systems, this CODEC provides efficiency and high performance. With cutting-edge technologies, it handles complex signal conversions with minimal power consumption. This CODEC supports numerous interface standards, making it a versatile component in numerous audio architectures. It's engineered to offer precise sound reproduction and maintains audio fidelity across all use cases. The integrated components within the CODEC streamline design processes and reduce the complexity of audio system implementations. Furthermore, the Mixed-Signal CODEC incorporates features that support high-resolution audio, ensuring compatibility with high-definition sound systems. It's an ideal choice for engineers looking for a reliable and comprehensive audio processing solution.
Packetcraft's Bluetooth LE Audio Solutions offer a full suite of host, controller, and LC3 components optimized for seamless transition to Bluetooth LE Audio. The platform supports Auracast broadcast audio and True Wireless Stereo (TWS), making it adaptable to prevalent chipsets and providing flexibility to product companies. The modular design facilitates simplified integration, ensuring companies can leverage advanced audio capabilities in a variety of applications. As Bluetooth audio technology evolves, Packetcraft remains at the leading edge, offering industry-leading solutions that cater to modern audio requirements.
MajEQ Pro is an advanced equalizer tailored for professional audio applications, allowing both static and dynamic EQ adjustments to match specific frequency response targets. It handles tasks such as venue correction or adapting to atmospheric changes at live events. This tool encompasses features including high and low-pass filters with variable slopes, tone controls, and unique filter designs such as Bell or Presence filters with customizable gain, frequency, and Q.
The APB4 GPIO core from Roa Logic is a fully parameterized solution designed to provide a customizable number of general-purpose, bidirectional I/O pins. This core enables developers to define the I/O behavior precisely, adapting to a plethora of configurations to meet specific project requirements. It is essential for applications that require extensive interfacing capabilities, ensuring streamlined connectivity across multiple components. The GPIO core supports a range of operational modes, providing the flexibility to handle complex I/O operations. With capabilities like programmable drive strength and individual pin configuration, it offers a high degree of customization that can be tailored to precise application needs. Roa Logic’s offering enhances design functionality and accelerates development timelines by facilitating easy integration and application-specific optimization. This component serves as a cornerstone for designs requiring robust peripheral interaction, catering to both industrial projects and educational purposes. Its adaptability and ease of integration ensure it's an invaluable component in modern electronics design, adhering to the high standards expected in today's interconnected environments.
Silicon Creations' Bi-Directional LVDS Interfaces are engineered to offer high-speed data transmission with exceptional signal integrity. These interfaces are designed to complement FPGA-to-ASIC conversions and include broad compatibility with industry standards like FPD-Link and Camera-Link. Operating efficiently over processes from 90nm to 12nm, the LVDS interfaces achieve data rates exceeding 3Gbps using advanced phase alignment techniques. A standout feature of this IP is its capability to handle independent LVCMOS input and output functions while maintaining high compatibility with TIA/EIA644A standards. The bi-directional nature allows for seamless data flow in chip-to-chip communications, essential for modern integrated circuits requiring high data throughput. The design is further refined with trimmable on-die termination, enhancing signal integrity during operations. The LVDS interfaces are versatile and highly programmable, meeting bespoke application needs with ease. The interfaces ensure robust error rate performance across varying phase selections, making them ideal for video data applications, controllers, and other high-speed data interfaces where reliability and performance are paramount.
Silicon Library Inc. offers a high-quality DisplayPort/eDP IP that supports seamless transmission of audio and video data for modern display standards. Engineered for compatibility with DP/eDP 1.4 standards, this IP is geared toward contemporary computing and media devices requiring sharp and clear image displays. The DisplayPort/eDP interface is crucial for devices like monitors, laptops, and all-in-one PCs. It provides a robust link for transmitting high-definition content, capable of managing complex video signals with multiple streams efficiently. The IP is designed to support high-bandwidth communication, enabling it to handle resolutions required for newer display technologies, including 4K and 8K displays. Optimized for power and performance, the DisplayPort/eDP IP integrates features like adaptive sync, dynamic refresh rates, and multi-monitor support. Its low-power footprint and efficiency in managing resources make it suitable for portable and high-performance devices where display quality is paramount.
The Aeonic Integrated Droop Response System is a groundbreaking approach to managing voltage droop in complex IC environments. This solution combines fast multi-threshold detection with churn-key integration of fine-grained dynamic voltage and frequency scaling capabilities. It offers advanced features such as tight coupling of droop detection and response, leading to the fastest commercial adaptation times that can significantly reduce margin requirements and power usage. The system’s observability features provide valuable data for silicon health assessments and lifecycle management. Process portability ensures scalability across different technology nodes, making the solution versatile for use in various sophisticated systems. This system is crucial for managing droop-induced challenges, and its integration with current architectures leads to enhanced system power and performance efficiency.
Trifecta-GPU design offers an exceptional computational power utilizing the NVIDIA RTX A2000 embedded GPU. With a focus on modular test and measurement, and electronic warfare markets, this GPU is capable of delivering 8.3 FP32 TFLOPS compute performance. It is tailored for advanced signal processing and machine learning, making it indispensable for modern, software-defined signal processing applications. This GPU is a part of the COTS PXIe/CPCIe modular family, known for its flexibility and ease of use. The NVIDIA GPU integration means users can expect robust performance for AI inference applications, facilitating quick deployment in various scenarios requiring advanced data processing. Incorporating the latest in graphical performance, the Trifecta-GPU supports a broad range of applications, from high-end computing tasks to graphics-intensive processes. It is particularly beneficial for those needing a reliable and powerful GPU for modular T&M and EW projects.
The DB9000AXI Display Controller is engineered to interface seamlessly with Frame Buffer Memory via the AMBA AXI protocol, offering support for a wide range of display resolutions from basic QVGA up to advanced 8K panels. Besides baseline display capabilities, advanced versions feature enhanced processing attributes such as multiple overlay windows, hardware cursor functions, and high dynamic range (HDR) imaging. With features like Color Space Conversion and programmable resolution settings, this IP core meets diverse display demands across numerous applications.
The RISC-V Hardware-Assisted Verification by Bluespec is a high-performance platform designed for swift and precise verification of RISC-V cores. It supports testing at both the core level (ISA) and system level, accommodating RTOS and Linux-based environments. This solution can verify standard ISA extensions, custom ISA extensions, and integrated accelerators, making it a versatile tool for various verification needs. One of the standout features of this platform is its scalability and accessibility via the AWS cloud, which ensures that resources can be tapped into as needed, enabling efficient verification anytime, anywhere. Such scalability is crucial for teams that require the flexibility to test various designs without being confined to local server limitations. With an emphasis on broad compatibility, the RISC-V Hardware-Assisted Verification platform is ideal for those involved in developing RISC-V based systems. It assists developers in ensuring their designs are accurate and reliable before deployment, reducing errors and speeding up time-to-market.
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.
Analog Bits provides robust I/O solutions that are essential for the efficient transfer of signals between semiconductor devices and their external environment. These input/output interfaces are designed to meet the most demanding performance criteria, ensuring fast data rates and minimal signal distortion. Their I/O IP solutions can accommodate a variety of protocols, including high-speed digital interfaces and analog conversions, offering versatility and support for applications such as networking, data processing, and consumer electronics. By optimizing the signal integrity and electromagnetic compatibility, these I/Os enhance the overall system performance. Equipped with advanced features for low power consumption, these I/Os contribute to reducing the overall energy footprint of semiconductor devices, making them ideal for battery-operated devices and environmentally sensitive applications. Analog Bits' I/Os are comprehensively integrated to function seamlessly within mixed-signal environments, further broadening their application range.
Certus Semiconductor's Analog I/O offerings bring ultra-low capacitance and robust ESD protection to the forefront. These solutions are crafted to handle extreme voltage conditions while securing signal integrity by minimizing impedance mismatches. Key features include integrated ESD and power clamps, support for broad RF frequencies, and the ability to handle signal swings below ground. Ideal for high-speed RF applications, these Analog I/Os provide superior protection and performance, aligning with the most demanding circuit requirements.
Nextera Video's NMOS Control Platform is a vital component for ensuring seamless interoperation of SMPTE ST 2110 devices within multi-vendor IP networks. Developed by the Advanced Media Workflow Association (AMWA) and specified by the Joint Taskforce on Networked Media (JT-NM), the NMOS platform simplifies the management of media systems over IP, enabling plug-and-play interoperability in complex environments. This platform allows for automatic discovery and registration of devices, connection management, and resource labeling, which is crucial for effective system monitoring and control. Key features encompass a broad range of functionalities, including IP equivalent of GPIO events, real-time configuration of audio channels, and comprehensive system parameter management. These capabilities make it indispensable for operations demanding high-quality media routing and flexibility. NMOS is not only a means of efficient configuration but also enhances the security of media communications through integration with HTTPS and TLS standards. This ensures that only authorized users have access, thereby strengthening the integrity of media operations on the network. As a JT-NM tested solution, it guarantees adherence to industry standards, contributing to its widespread acceptance amongst broadcasters and media producers.
The D/AVE 2D is a dynamic graphics processing unit designed to efficiently handle two-dimensional graphic rendering. It provides a robust platform for rendering complex graphics in embedded systems with limited resources, making it a perfect choice for consumer electronics, automotive displays, and industrial monitoring systems. Its architecture enables fast image processing and supports features like anti-aliasing and alpha blending to deliver high-quality visual outputs. The D/AVE 2D utilizes efficient hardware acceleration to reduce the load on the main processor, allowing for smoother graphics operation and faster refresh rates. Its integration is enhanced with straightforward software tools, enabling easy adaptation to various operating systems and hardware configurations. Notably, the D/AVE 2D is scalable and adaptable, providing a flexible solution for applications needing robust graphic capabilities. This GPU not only improves graphic performance but also enhances energy efficiency, providing a balance of performance and power consumption ideal for embedded applications. Its support for various display formats and interfaces makes it versatile and ready for deployment in a multitude of systems, ensuring it meets the diverse needs of today's demanding graphic applications.
Himax's display drivers are crafted for expansive displays found in televisions, monitors, and other large-sized electronic panels. These drivers are engineered to provide accurate color representation and clarity, optimizing the viewer experience. With their high integration levels, Himax's display drivers are designed to support the latest trends in consumer electronics, ensuring seamless interfaces across various devices. The architecture of these drivers facilitates enhanced performance for high-definition and ultra-high-definition displays. By leveraging advanced algorithms, these components are capable of reducing motion blur and enhancing the overall visual impact. Designed for energy efficiency, they cater to the growing demands of eco-friendly electronic solutions. Adapting to fast-evolving market trends, these drivers address the need for improved refresh rates and resolution. The design focuses on maintaining image integrity while supporting growing data transmission requirements. Himax ensures that these products meet the rigorous standards expected in today’s dynamic technology ecosystem.
Mobix Labs introduces its EMI Flex Filters, designed to tackle electromagnetic interference effectively. These filters are crafted for critical applications where interference-free transmission is crucial, ensuring high performance in complex settings. Their ultra-thin, flexible form allows them to conform to various surfaces and fit snugly into tight enclosures.\n\nThese filters promise exceptional EMI attenuation, meeting stringent military and aerospace requirements while maintaining minimal signal loss. They are compatible with high-frequency applications, filtering up to 50 GHz which is ideal for 5G and radar technologies. Additionally, the customizable form factors enable tailored solutions for specific devices, ensuring long-term reliability in harsh conditions.\n\nThe EMI Flex Filters are utilized across multiple sectors. In military and defense, they secure communication systems and manage mission-critical signals. Aerospace uses them to maintain essential communications, while in the telecom industry, they prevent crosstalk in high-frequency environments. Furthermore, they are pivotal in protecting medical and IoT devices from interference and ensuring the stable operation of automotive and electric vehicle systems.
The WiFi6, LTE, and 5G Front-End Module is a versatile solution engineered for next-generation wireless communication. This module is tailored to support the high data rate demands and extensive network coverage requirements of WiFi6, LTE, and 5G technologies. It plays a crucial role in enhancing wireless connectivity by facilitating efficient signal transmission and reception across multiple frequency bands. By leveraging cutting-edge RF and analog/mixed-signal design techniques, this front-end module offers exceptional performance characteristics, including high linearity, enhanced gain, and reduced noise figures. These aspects are critical for ensuring seamless connectivity and efficient spectrum usage in densely populated environments, where maintaining signal clarity and reducing interference are paramount. The module integrates seamlessly with advanced wireless architectures, supporting a wide range of device types from consumer electronics to professional communication equipment. Its robust design is prepared to handle the diverse operational requirements of modern wireless systems, providing reliable performance across varied environmental conditions.
The ARINC 664 P7 IP Core by iWave Global is at the forefront of aviation network solutions, offering an advanced platform for Ethernet-based communication in aerospace systems. Known for adhering to stringent industry standards, this IP core provides reliable and efficient communication protocols essential for avionics Ethernet networks. It effectively manages high-speed data across network infrastructures, paving the way for streamlined operations within aircraft systems. The core supports features essential for critical networked systems, such as bandwidth allocation, prioritization of data flows, and quality of service mechanisms. Ideal for enhanced networking capabilities in aircraft, the ARINC 664 P7 IP Core ensures data communication integrity, which is essential for the safety-critical operations found in modern aviation environments. This core is crucial for developers aiming to create sophisticated onboard systems that require precise and dependable data exchange mechanisms.
Domain-Specific RISC-V Cores from Bluespec provide targeted acceleration for specific application areas by packaging accelerators as software threads. This approach enables developers to achieve systematic hardware acceleration, improving the performance of applications that demand high computational power. These cores are designed to support scalable concurrency, which means they can efficiently handle multiple operations simultaneously, making them ideal for complex scenarios that require high throughput and low latency. The ease of scalability ensures that developers can rapidly adapt their designs to meet evolving demands without extensive redesign. Bluespec’s domain-specific cores are well-suited for specialized markets where performance and efficiency can make a significant impact. By providing a robust platform for acceleration, Bluespec empowers developers to create competitive and rapidly deployable solutions.
Engineered for energy-sensitive applications, Microdul’s capacitive proximity switch combines precision with ultra-low-power consumption, making it ideal for modern technological needs. This switch is designed to detect touch reliably without direct physical contact, thereby facilitating advanced user interfaces, particularly in devices where minimizing energy usage is critical. The switch’s lightweight design and responsive detection capability allow it to support numerous applications such as touchpads and sliders commonly used in consumer electronics. Its capacitive nature ensures swift response times, making it suitable for dynamic environments where instant feedback is necessary, such as in user interface control panels. Applications extend to smart technology fields, where energy savings can be maximized. The capacitive proximity switch continues to function effectively across various climates and conditions, promising versatility and adaptability. By enhancing system efficiency through minimal power demands, it impressively complements design strategies that focus on sustainability and long-term operational economy.
The ARINC 818-2 IP Core by iWave Global is engineered to support the high-speed video interface standard used in aerospace applications. This IP core signifies a leap in the integration of advanced video transmission protocols with existing avionics architectures. It is tailored for applications that demand highly reliable and efficient video data communications. Focusing on seamless compatibility, the ARINC 818-2 IP Core integrates easily into various platforms, ensuring minimal modifications and reduced time-to-market for development. This core supports high-speed data transfer rates, providing robust solutions for real-time video streaming and data transfer. Ideal for systems requiring precise video data handling, the ARINC 818-2 IP Core guarantees data integrity and synchronization across all transmission stages. Its versatile design allows for broad implementation across military and commercial aviation sectors, where data reliability and transfer efficiency are paramount.
The Guiliani GUI Framework is a robust solution designed for creating sophisticated, interactive user interfaces. Tailored for embedded systems with constrained resources, it offers a powerful toolkit and editor to develop dynamic and efficient GUI applications across various platforms like FPGAs, microcontrollers, and embedded processors. Guiliani optimizes for performance, providing advanced animation techniques and a robust rendering engine that runs efficiently even on hardware with limited graphical processing power. This framework supports a wide range of interface designs, from simple to complex applications, all while ensuring minimal resource consumption. The framework's adaptability and flexible architecture allow developers to customize and extend user interfaces based on application-specific requirements. The inclusion of a GUI editor facilitates easy integration and rapid development cycles, enhancing productivity and allowing developers to focus on optimizing user experience.
To augment their diverse microcontroller IP lineup, Syntill8 provides an array of peripheral interface IP cores designed to integrate seamlessly with their 8051 microcontrollers. The suite includes a Two-Wire Slave Interface (M2WIS) and a Four-Wire Slave Interface (M4WIS), which complement the integral interfaces within the microcontroller cores. Additionally, the UDPMAC core caters to networking needs, providing a robust 1-Gigabit UDP/Ethernet MAC solution. These peripheral integrations enable comprehensive connectivity options for diverse applications.
The D/AVE 3D graphics processor is specifically designed to handle three-dimensional rendering tasks with high efficiency. It delivers smooth and realistic 3D graphics performance for a range of applications, including automotive onboard systems, mobile devices, and other interactive media systems. Equipped with advanced graphics capabilities, this IP supports features such as texture mapping, shading, and rendering of complex objects. Its architecture allows for significant reduction in memory bandwidth usage, facilitating faster graphics processing suitable for real-time applications without compromising on quality. The D/AVE 3D is compatible with various hardware and software platforms, providing a versatile solution that can be integrated seamlessly into existing systems. Moreover, the IP's design focuses on low power consumption, making it ideal for portable and battery-operated devices where energy efficiency is crucial. This focus on power efficiency does not impede its ability to produce high-resolution graphics, maintaining the performance needed for next-generation visual applications.
The 28GHz Pin Diode SP4T Switch is designed to provide high isolation and low insertion loss for RF applications. Operating from 24 to 32GHz, this switch exhibits a loss of 0.8dB while providing isolation greater than 23dB. This switch is engineered using compact design principles suitable for integration into microwave systems requiring multiple signal paths.
Catalyst-GPU represents a cost-effective and powerful graphics solution for the PXIe/CPCIe platform. Equipped with NVIDIA Quadro T600 and T1000 GPUs, this module excels in providing enhanced graphics and computing acceleration required by modern signal processing and AI applications. One of the standout features of Catalyst-GPU is its ease of programming and high compute capabilities. It meets the requirements of both Modular Test and Measurement (T&M) and Electronic Warfare (EW) sectors, offering significant performance improvements at reduced operational costs. Built as a part of the Catalyst family, this module allows access to advanced graphics capabilities of NVIDIA technology, paving the way for efficient data processing and accelerated computational tasks. The Catalyst-GPU sets itself apart as a robust choice for users needing reliable high-performance graphics within a modular system framework.
The Flat Panel Display Interface for Advanced Processes by Curious Corporation is a sophisticated solution aimed at enhancing display technologies. This interface supports high-speed data transfer between the processor and display panels, making it ideal for modern electronic displays that require quick refresh rates and low power usage. Designed for use in digital displays, this interface ensures sharp and vibrant image rendering, utilizing advanced technology to manage data flow seamlessly. It is perfect for devices where visual clarity and power efficiency are paramount, such as smartphones, tablets, and wearable devices. Incorporating this interface into display systems enhances the overall viewing experience by providing a stable connection that can handle a wide range of display resolutions and formats. It is highly adaptable to different manufacturing processes, ensuring longevity and compatibility with future display technology advancements.
Akeana's Processor System IP offers a comprehensive set of system IP blocks designed to enhance the performance and efficiency of processor systems. This product line includes a variety of sophisticated components such as Compute Coherence Blocks (CCB), coherent and non-coherent interconnect fabrics, and advanced interrupt architectures, essential for building scalable and reliable multi-core systems. Notably, the Compute Coherence Block is pivotal in facilitating coherent clusters of cores through a directory-based protocol, ensuring caches are efficiently shared among processors. This, combined with the company's adherence to AMBA specifications for interconnect fabrics, allows easy integration into existing systems, providing flexible and robust solutions for handling complex data management tasks. The IP supports a wide array of functions including the IOMMU and interrupt controllers, critical for ensuring seamless device communication and control in diversified processing environments. Akeana's in-depth understanding of processing systems enables customers to configure and deploy highly customizable solutions, achieving optimal performance through tailored IP configurations suited to their specific application needs.
The DisplayPort 1.1a Transmitter offers a fully-compliant solution for digital video and audio transmission, supporting resolutions of considerable quality. This transmitter is essential for developers integrating high-definition multimedia interface technologies into a diverse range of consumer electronics. Its design enables reliable video and audio streaming by incorporating HDCP content protection compliance, which is crucial for safeguarding copyrighted content during transmission. This protection is an integral feature for professional broadcast environments and consumer applications. Beyond its secure transmission capabilities, this transmitter supports large data streams with minimal latency, thereby improving the quality of interactive displays and ensuring that video synchronization is maintained. This characteristic is increasingly important as high-definition multimedia becomes the norm across computing devices.
The D/AVE NX is a state-of-the-art graphics processing unit conceptualized for handling high-end graphics rendering tasks. Its high efficiency and broad feature set make it an ideal choice for applications such as gaming devices, advanced automotive displays, and virtual reality systems. Integrating advanced-performance graphics processing, the D/AVE NX supports complex graphical elements using efficient algorithms and techniques. With the ability to handle extensive graphical processing workloads, D/AVE NX employs cutting-edge technologies like dynamic lighting, shadowing, and complex texture mapping. These features ensure a lifelike and immersive user experience without demanding excessive system resources. Designed to minimize power consumption, this GPU caters to applications that demand high performance while maintaining energy efficiency. Its seamless integration capability with various software ecosystems makes it suitable for modern electronic systems that prioritize both performance and operational efficiency.
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