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
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
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 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
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
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.
The Mixed-Signal CODEC by Archband integrates advanced audio and voice processing capabilities, designed to deliver high-fidelity sound in a compact form. This technology supports applications across various audio devices, ensuring quality performance even at low power consumption levels. With its ability to handle both mono and stereo channels, it is perfectly suited for modern audio systems.
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.
DisplayPort and Embedded DisplayPort (eDP) IP by Silicon Library enables advanced digital display connectivity, offering superior video performance and enhanced sound. Designed to serve high-resolution displays, this IP supports next-gen display protocols, delivering robust signal quality and efficient energy use.
The HOTLink II Product Suite is a powerful video transmission solution that enables secure and rapid data exchange for avionics applications. This suite by Great River Technology is designed to facilitate seamless high-speed digital communications, minimizing latency while enhancing the system's reliability in demanding environments. The suite encompasses a range of tools that streamline the development and deployment of HOTLink II systems, which are crucial for managing high-bandwidth data flows. It offers extensive support mechanisms through well-crafted documentation and robust simulation tools, aiding engineers in achieving optimized system performance and regulatory compliance. By leveraging the HOTLink II Product Suite, users can achieve improved data integrity and support for multiple video interfaces, ensuring the readiness of systems for various missions. This makes the suite a vital component for both military and civilian aerospace projects, offering extensive scalability and customization to suit specific operational needs.
The DB9000AXI Display Controller is designed to handle a vast range of display resolutions for LCD and OLED panels. It supports standard configurations from 320x240 pixels to Full HD at 1920x1080 pixels, with advanced setups accommodating 4K and even 8K resolutions. This flexibility allows it to drive displays via on-chip AMBA interconnects, linking frame buffer memory and processing units. Moreover, it incorporates sophisticated capabilities like overlay windows and hardware cursors, ideal for applications requiring high precision and functionality. Built to align with the AXI protocol, the controller is optimized for performance, ensuring high throughput for demanding graphic operations. Its versatile nature suits it to multiple applications, ranging from consumer electronics to sophisticated medical and industrial monitors. The added advantages of reduced CPU burden and enhanced visual rendering make it a compelling choice for high-end display solutions. Additionally, the DB9000AXI supports optional features tailored to specific requirements, including alpha blending and color space conversion. These advanced functions ensure top-tier visual fidelity and are vital for modern, immersive viewing experiences. Paired with Linux drivers and extensive verification suites, the DB9000AXI is a future-proof solution for robust display management needs.
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.
The RISC-V Hardware-Assisted Verification by Bluespec is designed to expedite the verification process for RISC-V cores. This platform supports both ISA and system-level testing, adding robust features such as verifying standard and custom ISA extensions along with accelerators. Moreover, it offers scalable access through the AWS cloud, making verification available anytime and anywhere. This tool aligns with the needs of modern developers, ensuring thorough testing within a flexible and accessible framework.
The ARINC 818 Product Suite from Great River Technology offers a comprehensive platform for the design and implementation of ARINC 818 compatible systems. It provides tools and resources crucial for developing, qualifying, testing, and simulating video interface products within aerospace and defense industries. The suite supports engineers in effectively managing complex digital video signals, ensuring high-speed data transmissions maintain fidelity across various operational conditions. This product suite facilitates the integration of ARINC 818 standard interfaces within mission-critical environments, offering unparalleled support throughout the product lifecycle. Engineers can access development guides, simulation tools, and test solutions that simplify compliance with ARINC 818 protocol specifications. Whether for new projects or upgrades, the suite empowers designers and engineers to optimize performance and reliability of their systems. Additionally, the product suite aids in the seamless transition from design phase to deployment, ensuring that all components work harmoniously to deliver precision and efficiency. The suite’s robustness helps in mitigating risks associated with system integration, affording customers peace of mind when implementing high-stakes and complex avionics systems.
The Aeonic Integrated Droop Response System sets a new standard for droop management in sophisticated integrated circuits. With its innovative dual-focus on droop detection and mitigation coupled with fine-tuned DVFS capability, this turnkey solution ensures efficient power management for SoCs. The system's fast response time, extensive observability features, and configurability make it a critical component in silicon health management, easily integrating with leading analytic frameworks.
The I/O solutions by Analog Bits encompass differential clocking, signaling, and crystal oscillator IPs. These low-power, high-quality signaling technologies are designed to minimize transistor usage while maximizing signaling performance. With solutions that are silicon-proven and customizable, these IPs are highly efficient and support various die-to-die communication needs.
Emphasizing energy efficiency and processing power, the KL530 AI SoC is equipped with a newly developed NPU architecture, making it one of the first chips to adopt Int4 precision commercially. It offers remarkable computing capacity with lower energy consumption compared to its predecessors, making it ideal for IoT and AIoT scenarios. Embedded with an ARM Cortex M4 CPU, this chip enhances comprehensive image processing performance and multimedia codec efficiency. Its ISP capabilities leverage AI-based enhancements for superior image quality while maintaining low power usage during operation, thereby extending its competitiveness in fields such as robotics and smart appliances.
NeuroVoice is a powerful ultra-low-power neuromorphic front-end chip engineered for voice processing in environments plagued by irregular noises and privacy concerns. This chip, built on the NASP framework, improves real-time voice recognition, reducing reliance on cloud processing and providing heightened privacy. It is ideal for applications in hearables, smart home devices, and other AI-driven voice control systems, capable of efficiently processing human voice amidst noise. The NeuroVoice chip addresses key challenges faced by existing digital solutions, such as excessive power consumption and low latency in real-time scenarios. Its brain-inspired architecture processes voice commands independently of the cloud, which minimizes Internet dependency and enhances privacy. Furthermore, the chip's ability to manage voice detection and extraction makes it suitable for diverse environments ranging from urban noise to quiet domestic settings. Advanced features of the NeuroVoice chip include its ultra-fast inference capability, processing all data locally and ensuring user privacy without compromising performance. By supporting applications like smart earbuds and IoT devices, NeuroVoice optimizes energy efficiency while maintaining superior voice processing quality. This innovative technology not only empowers users with clearer communication abilities but also encourages adoption across multiple consumer electronics.
aiData introduces a fully automated data pipeline designed to streamline the workflow of automotive Machine Learning Operations (MLOps) for ADAS and autonomous driving development. Recognizing the enormous task of processing millions of kilometers of driving data, aiData employs automation from data collection to curation, annotation, and validation, enhancing the efficiency of data scientists and engineers. This crafted pipeline not only facilitates faster prototyping but also ensures higher quality in deploying machine learning models for autonomous applications. Key components of aiData include the aiData Versioning System, which provides comprehensive transparency and traceability over the data handling process, from recording to training dataset creation. This system efficiently manages metadata, which is integral for diverse use-cases, through advanced scene and context-based querying. In conjunction with the aiData Recorder, aiData automates data collection with precise sensor calibration and synchronization, significantly improving the quality of data for testing and validation. The aiData Auto Annotator further enhances operational efficiency by handling the traditionally labor-intensive process of data annotation using sophisticated AI algorithms. This process extends to multi-sensor data, offering high precision in dynamic and static object detection. Moreover, aiData Metrics tool evaluates neural network performance against baseline requirements, instantly detecting data gaps to optimize future data collection strategies. This makes aiData an essential tool for companies looking to enhance AI-driven driving solutions with robust, real-world data.
The IFC_1410 Intelligent FMC Carrier in AMC form factor is an advanced modular platform accommodating a broad spectrum of functionalities within a compact framework. It is built on the powerful NXP QorIQ T Series processors alongside Xilinx Artix-7 and Kintex UltraScale devices, making it suitable for high-performance applications. This carrier board serves as a foundational component in system designs, promoting flexibility and ease of integration. Its multi-purpose architecture is tailored for various complex systems, enabling developers to extend the capabilities of their VME data acquisition and control systems far beyond traditional limits. By harnessing the synergistic potential of cutting-edge processor technologies and FPGA platforms, the IFC_1410 carrier board delivers exceptional processing power and scalability necessary for high-energy physics and many industrial applications requiring intense computational capacity.
Brite Semiconductor's YouMIPI offers a complete set of solutions for MIPI interfaces, particularly focusing on the CSI and DSI standards. The solution is adept at handling data from a sensor to the image processing parts of a system, converting byte streams into pixel data while mitigating electromagnetic interference through configurable data scrambling. Featuring compliance with multiple versions of the MIPI standards, YouMIPI supports substantial data rates across several lanes in C-PHY and D-PHY configurations, allowing for flexible integration with a wide range of application processors. The architecture provides efficient multi-channel distribution and manages synchronization effortlessly, addressing both high-speed and low-power operational modes as specified by MIPI. YouMIPI is particularly designed for use in camera modules and display interfaces in mobile devices, automotive solutions, and consumer electronics. The robust design underpinning YouMIPI ensures optimal data handling and high-quality signal processing for superior image and display performance.
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.
Bluespec's Portable RISC-V Cores offer a versatile and adaptable solution for developers seeking cross-platform compatibility with support for FPGAs from Achronix, Xilinx, Lattice, and Microsemi. These cores come with support for operating systems like Linux and FreeRTOS, providing developers with a seamless and open-source toolset for application development. By leveraging Bluespec’s extensive compatibility and open-source frameworks, developers can benefit from efficient, versatile RISC-V application deployment.
The ACAM In-Cabin Monitoring Solution is a sophisticated 60 GHz mmWave radar designed to enhance vehicle safety and passenger comfort through non-intrusive monitoring. This advanced sensor facilitates comprehensive in-cabin detection, including child presence detection, seat occupancy, intrusion alerts, and vital signs monitoring. Leveraging NOVELIC's extensive software stack, ACAM ensures full interior coverage without compromising passenger privacy.
The GL3004 fisheye image processor offers comprehensive image processing capabilities, tailored specifically for wide-angle lens applications. It delivers exceptional fisheye correction methods, allowing for versatile dewarping options from spherical panorama views to specific stitching modes. Integrated hardware ensures that images maintain high fidelity, with a focus on accurate color processing and enhanced dynamic range. Supporting inputs up to 3 megapixels, it excels in real-time processing with an integrated ISP that handles a broad spectrum of imaging functions from noise reduction to auto-exposure control. This processor ensures that every captured scene disperses real-life details efficiently, which is critical in surveillance and advanced photography contexts. Designed with multiple interfaces, such as MIPI and BT standards, the GL3004 can fit into diverse applications, offering seamless integration potential. With an onboard Cyclone-8051 CPU, it processes instructions at a high speed, with reliable PLL systems managing clock operations across varied loads, making it a solid solution for creative and technical image requirements.
Certus Semiconductor's Analog I/O solutions deliver state-of-the-art protection through ultra-low capacitance and extreme ESD protection. Designed for high-speed SerDes and RF applications, these products ensure that signal integrity and impedance matching are not compromised. The Analog I/O offerings from Certus are driven by innovation, featuring less than 50 fF capacitance solutions apt for today's advanced technological demands. These analog solutions are equipped to tolerate signal swings below ground, capable of providing robust ESD protection withstanding over 16kV HBM. In addition to these capabilities, they possess high temperature tolerance and can endure aggressive operational environments, making them an ideal fit for sectors demanding high reliability and rugged performance. The comprehensive design integrates IO, ESD, and power clamps into significant macro cells for optimal performance. Certus Semiconductor ensures that their analog solutions are adaptable, scalable, and ready to meet future demands in high-speed and high-frequency applications.
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.
Packetcraft's Bluetooth LE Audio Solutions represent a robust package designed to support next-generation wireless audio experiences. These solutions encompass a wide array of capabilities, including full support for both host and controller functions as well as integration with the LC3 codec. This technological framework is built to streamline the transition to Bluetooth LE Audio, supporting innovative features like Auracast broadcast audio and true wireless stereo (TWS) configurations. The LE Audio Solutions provided by Packetcraft assure adaptability with popular chipsets, thus offering a great degree of flexibility to audio product manufacturers. With a commitment to seamless integration, Packetcraft’s offerings are optimized to enhance the efficiency of wireless audio systems, providing superior audio quality and extended battery life. Beyond mere audio transmission, these solutions are primed to fully leverage the advanced functionalities of Bluetooth 5.4. This enables developers to construct more efficient, feature-rich audio products that can satisfy the sophisticated desires of modern consumers.
The Domain-Specific RISC-V Cores from Bluespec are engineered to facilitate hardware acceleration in a streamlined and efficient manner. By packaging accelerators as software threads, these cores deliver high concurrency and efficient system performance. The scalability embedded in this technology caters to a range of application needs, enabling systematic hardware acceleration for developers and organizations aiming to optimize RISC-V implementations.
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 LVDS (Low-Voltage Differential Signaling) technology by Advinno is engineered to offer high-speed data transfer with minimal power consumption and electromagnetic interference. LVDS is a preferred choice for applications requiring fast data communication, such as video conferencing systems, high-definition displays, and networking equipment. By leveraging differential signaling, LVDS ensures less susceptibility to noise, which leads to improved performance in noisy electronic environments. This technology is particularly advantageous where power efficiency and signal integrity are critical. Advinno's LVDS solutions are flexible and compatible with a variety of industry-leading process nodes, capable of supporting customized requirements in advanced electronic applications.
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.
Himax offers a series of sophisticated display drivers specifically engineered for large-sized LCD TV panels, monitors, and notebooks. These drivers include a variety of integral components such as timing controllers, source drivers, and gate drivers, providing comprehensive solutions to ensure sharp, vibrant displays. The inclusion of advanced features such as gamma and Vcom operations contributes to exceptional image quality and color accuracy, meeting the high standards expected by end-users today. In addition to enhancing visual appeal, these display drivers are designed to be highly efficient, offering reliable performance with low power consumption. This efficient energy usage is vital for reducing operational costs and supporting long-term sustainability goals across the technology ecosystem. This thoughtful engineering approach ensures that Himax display drivers meet the diverse requirements of different applications while remaining adaptable to future technological advancements. Furthermore, Himax collaborates closely with leading panel manufacturers across the globe, ensuring their solutions are compatible with the latest technologies and market demands. This strategic alignment positions Himax as a leader in the industry, trusted by some of the biggest names in the global tech sector.
Exostiv Blade is engineered for unparalleled depth in FPGA data capture, offering a robust no-compromise trace buffer for debugging and validating complex FPGA systems and SoC prototypes. This system allows for extensive multi-FPGA captures, reaching an impressive bandwidth of up to 4.5 Tbps, with trace storage capabilities peaking at 5.12 TB. The Exostiv Blade's modular design supports varied configurations, adjusting to multiple FPGA systems and facilitating operations at target speeds for comprehensive pre-silicon validation and testing. Exostiv Blade systems are equipped with a versatile architecture supporting a range of configurations to meet different capture scenarios. Housing numerous capture boards within compact chassis, the setup is designed to scale effectively, accommodating increasing capture depths as required by the application. The boards are equipped with cutting-edge transceiver inputs, each linked to substantial memory banks that ensure ample data storage. Adaptable to a wide set of FPGA prototyping setups, the Exostiv Blade supports multiple AMD FPGA families, enabling structured yet flexible capturing processes. The integration of QSFP28 connectors ensures that connectivity options are not only comprehensive but also adaptable to various form factors with minimal space occupation.
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.
The pPOR01 is a power-on reset solution developed by Perceptia, designed to support stable system initialization processes. This component is essential for digital systems requiring robust reset mechanisms that can withstand the challenges of power transitions and fluctuating states. Integrating the pPOR01 into a variety of semiconductors enhances system reliability by ensuring devices return to a defined state upon start-up or after power interruptions. This feature is crucial for maintaining the integrity and performance of advanced digital circuits. Constructed with a focus on efficiency, the pPOR01 accommodates diverse system requirements, making it an ideal choice for enhancing the dependability of complex semiconductor designs. Its functionality supports broad application scenarios, providing a reliable reset strategy pivotal for modern digital architectures.
The mobile handset display drivers offered by Himax are versatile solutions that tackle the complexities of modern handheld devices. These drivers integrate a combination of source and gate drivers with timing controllers and frame buffers in one chip, enhancing integration and system efficiency. Their technology supports a range of applications, ensuring crisp and clear display performance while maintaining low power consumption—essential for extending battery life in mobile devices. Beyond just integration, Himax's mobile handset drivers focus on delivering superior image quality by employing advanced DC to DC circuits that regulate power effectively across the display. The enhanced capability of these drivers contributes to vivid and dynamic screen visuals that today's consumers expect. With the consumer electronic market's continual push for higher immersion levels and interactivity, these display drivers are developed to robustly handle various applications without compromising on speed or capacity. This commitment to quality and innovation places Himax as a pivotal player in advancing mobile display technologies.
The PHY Management Interface for MII is a vital component in the realm of semiconductor IP, providing a streamlined solution for managing media independent interfaces. This IP facilitates communication between an Ethernet MAC and a PHY device, which is crucial for network communication systems. Its design ensures compatibility across various Ethernet standards, offering a robust platform for diverse applications. With a focus on efficiency and reliability, this interface incorporates essential features that cater to modern networking needs. These features include support for varying data rates and adaptability to different network configurations, ensuring the IP remains versatile in dynamic environments. Additionally, the interface provides configuration options that enhance its usability and integration within broader system architectures. The PHY Management Interface is engineered to simplify the complexities associated with implementing media independent interfaces. Its architecture is tailored to facilitate quick adaptation and deployment, which is particularly beneficial in environments demanding rapid development cycles. This, combined with its high degree of interoperability, makes it an invaluable asset for engineers working in network system design. Beyond its technical capabilities, the PHY Management Interface stands out for its ease of use, ensuring that integration into existing systems is straightforward. By offering a comprehensive solution that covers all critical aspects of PHY management, Synflow has created a product that significantly reduces development timelines and enhances system robustness.
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 SoC Management technology by Sondrel is a comprehensive suite dedicated to the oversight of system start-up processes, along with clock and reset control, and handling of power domains. Central to this suite is the Power Management Unit (PMU) which oversees the SoC's initialisation, allowing for dynamic software-controlled power-ups and shutdowns of digital domains. It is proficient in reset management and addresses system faults by deploying preventive measures like shifting the system to 'Safe-Mode' during functional safety anomalies. Another component, the Universal Reset Generator (URG), serves an essential role in reset management tailored to the intricate logic systems within an SoC. The URG is designed to be lightweight yet scalable, facilitating multiple instances across multi-power-domain SoCs for intricate reset control. Its adaptable design leads to effective reset sequencing without compromising on complexity handling, stemming from a variety of hardware and software-driven events. Complementing these is the Universal Clock Generator (UCG), tasked with the meticulous management of on-chip clock systems. Accommodating numerous clock sources, the UCG enables the independent configuration of up to 128 clocking channels. It includes mechanisms for design safety and reliability, enabling fault detection in clock sources to maintain system stability. By incorporating such nuanced and flexible technologies, Sondrel's SoC Management suite stands as an integral solution for managing complex chip architecture systems.
The Display Controller Family from TES represents a suite of versatile and high-performance controller cores developed to manage complex video output functions. These controllers provide support for a variety of input and output standards, ensuring robust compatibility and integration capabilities across a wide range of electronic products. Each controller in the family is designed to deliver precise control over video formats, enhancing output quality while optimizing performance. Offering flexibility in deployment, these controllers can be customized to fit specific application needs, from consumer electronics to automotive display solutions.
NextNav 3D adds a three-dimensional layer to traditional geolocation methods, providing advanced visualization capabilities that are particularly useful for emergency services. The system supports real-time 3D mapping to help locate emergency responders and 9-1-1 callers more accurately in multi-story buildings. This capability allows for improved situational awareness and enhances personnel accountability during emergencies. The NextNav 3D solution integrates seamlessly with existing 9-1-1 and computer-aided dispatch systems. It provides detailed 3D building wireframes and vertical localization, offering a visual representation of a responder’s exact location within a structure, down to the floor level. This tool significantly reduces response times and enhances the effectiveness of emergency services. Developers can leverage the NextNav 3D SDK to incorporate these visualization capabilities into both web-based and mobile applications. The system offers budget-friendly, service-based access, minimizing the need for significant capital investment in geographic information systems (GIS). By providing tools like altimeter overlays and user-friendly toggles for building views, it ensures intuitive navigation of complex environments during high-stakes situations.
The IMG CXM High-Efficiency GPU provides a compact, yet powerful solution tailored for use in a wide range of consumer devices. As the smallest GPU supporting HDR (High Dynamic Range) user interfaces, it combines efficient performance with enhanced visual quality, delivering exceptional graphics while maintaining low power consumption, particularly important for cost-sensitive markets. Designed to support a variety of configurations, IMG CXM is adept in handling multimedia-rich content, thus making it a prime choice for devices that require dynamic and engaging visual experiences. Its support for advanced graphics processing units allows integration in applications ranging from digital televisions to smart home devices, enabling these products to offer modern, cinematic user interfaces. The hallmark of IMG CXM lies in its power and memory efficiency, which employs Imagination's Tiny Frame Buffer Compression (TFBC) technology to further reduce the demands on bandwidth. This makes the GPU ideal for applications in wearables, smart homes, and other devices where space and resource management are pivotal, ensuring that performance does not come at the cost of increased energy consumption.
TES's Video Input Controller is engineered to handle a variety of input video sources, providing seamless integration into broader electronic systems. Its primary function is to convert incoming video signals into formats suitable for further processing, ensuring minimal latency and maintaining high integrity of video data. The controller's architecture allows extensive compatibility with different video standards, enabling its deployment in diverse applications where video input management is critical. It is ideal for use in industries ranging from consumer entertainment to professional video broadcasting, where reliable and high-quality video input handling is essential.
The AVB/Automotive Ethernet Switch is tailored for automotive and professional audio/video bridging applications that require precise synchronization and low-latency data transfer. This technology enables seamless integration into complex network architectures while maintaining high-performance levels critical for automotive systems and AV environments. This switch supports key protocols including Audio Video Bridging (AVB) and Ethernet Audio Video Bridging (AVB), which are essential for maintaining the quality of service in multimedia communications. With its robust design, it facilitates the real-time transmission of audio and video streams without compromising on data integrity or timing accuracy. Designed to work with multiple network standards, the AVB/Automotive Ethernet Switch delivers flexible networking solutions that can be adapted for a wide range of applications in the automotive and AV domains. This adaptability, combined with robust synchronization capabilities, makes it an ideal choice for environments demanding high data throughput and precision timing.
The logiCVC-ML is a highly advanced multilayer video controller designed for TFT LCD displays, supporting resolutions up to 2048x2048. Optimized for AMD's Zynq 7000 SoC and FPGAs, it integrates seamlessly with various operating systems like Linux, Android, and Windows Embedded Compact 7. It serves as an essential component in display systems, providing robust video processing capabilities while maintaining exceptional quality.<br><br>This IP core offers significant flexibility, allowing customization to meet specific system requirements. The multi-year licensing options make it accessible for various project timelines, promoting ease of integration into existing development workflows. The logiCVC-ML is particularly suitable for applications demanding high-resolution video outputs and reliability.<br><br>With its advanced features, engineers can manage complex display configurations efficiently, ensuring smooth operations in demanding embedded environments. Whether used in industrial displays, automotive interfaces, or high-tech consumer electronics, the logiCVC-ML stands out for its performance and adaptability.
Designed for high-efficiency and crisp graphical outputs, the Vivante 2D GPU targets applications that require reliable 2D processing. Its architecture focuses on power conservation while delivering high-speed performance for tasks like UI rendering, simple animations, and graphical user interfaces. The 2D GPU is ideally suited for devices where speed and visual quality for 2D content are critical.
The ARINC 818-2 Single Channel Conversion Card from iWave Global provides a high-performance solution for the conversion of video data across different standards while maintaining signal integrity. This IP core is engineered to support a range of applications where reliable video data conversion is vital. The card offers seamless integration with existing systems and supports various video transmission standards. This conversion card is particularly beneficial in aerospace and defense applications, where data accuracy and reliability are non-negotiable. With its ability to handle high-bandwidth video streams efficiently, it aids in the smooth conversion and transmission of video data. The card's robust design ensures durability, making it suitable for use in harsh environments. The ARINC 818-2 Single Channel Conversion Card enhances data conversion processes by offering low-latency video signal handling and extended protocol support. These features ensure that the card meets the rigorous demands of real-time video data processing, providing a reliable and efficient solution for complex video conversion needs.
The Display Controller CDC is a versatile core designed to meet the varying needs of electronic display solutions. This controller core manages display interfaces, seamlessly transmitting video content from a source to a display. It supports multiple video input and output formats, ensuring broad compatibility across devices and technologies. Along with its robust configuration abilities, the CDC is designed to optimize video output while minimizing resource consumption. This makes the CDC a prime choice for developers seeking to integrate comprehensive display functionalities into their products, with an emphasis on both flexibility and performance. Its sophisticated architecture ensures that complex display operations are handled efficiently, serving applications including consumer electronics, automotive systems, and medical display technologies.
iWave Global's ARINC 818-2 Multi-Channel Conversion Card is designed for high-efficiency conversion of video data across multiple channels. This card is ideal for aerospace environments where managing numerous data streams is crucial for operations. It integrates seamlessly into existing systems, offering compatibility with a variety of video standards. Built to operate under stringent conditions, the multi-channel variant supports multiple video streams concurrently, enhancing operational efficiency in data-intensive applications. It is a critical component for systems requiring simultaneous handling of various video data sources without compromising on speed or accuracy. The card's architecture is focused on reducing latency while maximizing throughput, ensuring a consistent and reliable performance across applications like avionics, where data precision and system integration are essential. With its advanced capabilities, the ARINC 818-2 Multi-Channel Conversion Card is an indispensable tool for complex video data management in dynamic aviation environments.
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