All IPs > Interface Controller & PHY > V-by-One
V-by-One semiconductor IP solutions represent a leap forward in high-speed serial communication interfaces, designed to streamline connectivity and enhance the efficiency of modern electronic systems. Originating from the need to handle higher data rates with minimal signal interference, V-by-One technology has become an industry standard in the realm of high-definition displays and beyond. This category in our Silicon Hub is dedicated to providing a comprehensive selection of V-by-One interface controllers and physical layer (PHY) IPs, crucial for optimizing data transmission in various high-performance applications.
The primary utilization of V-by-One semiconductor IPs lies in their ability to manage significant data throughput while maintaining signal integrity over shorter physical connections. These IPs are essential in digital signage, television displays, and automotive infotainment systems, where large volumes of data must be seamlessly transmitted across different components. V-by-One IPs support resolutions such as 4K and 8K, enabling clear, vivid imagery without lag or distortion, making them indispensable for next-generation visual technologies.
Within this category, you will find a range of products designed to meet various design requirements and technical specifications. Our selection includes versatile V-by-One interface controllers known for their adaptability in handling diverse multimedia and data communication tasks. Additionally, our PHY IP offerings ensure robust signal processing, providing the hardware capabilities necessary to sustain high-speed data flow in complex electronic environments.
Whether you're developing consumer electronics, automotive, or industrial equipment, implementing V-by-One semiconductor IP solutions can greatly improve your product's performance. By ensuring superior data transmission efficiency and reducing electromagnetic interference, these IP solutions facilitate cutting-edge innovations for manufacturers and designers who demand the best in interface technology. Explore our extensive catalog to find the right V-by-One IPs that align with your production goals and technical needs.
Silicon Library's V-By-One HS technology offers a sophisticated solution for high-speed data transmission in displays. It provides a compact and efficient interface that supports high-resolution display panels, enhancing image quality with reduced latency. Ideal for automotive applications, as well as televisions and monitors, V-By-One HS supports a significant reduction in cabling needs, optimizing space and improving system reliability. The technology ensures minimal electromagnetic interference, crucial for maintaining signal integrity in sensitive environments. This interface is engineered to support high-bandwidth needs, making it suitable for applications requiring seamless data flow. Its efficiency in both power usage and data handling capabilities makes it an excellent choice for advanced multimedia systems seeking top-tier performance.
The LVDS/OpenLDI solution from Silicon Library supports high-speed, low-power data transmission for displays and other digital interfaces. This technology is suited for various applications where efficient and reliable data transfer is necessary, including automotive displays and advanced computing systems. With LVDS/OpenLDI, devices can achieve high data rates over long distances with minimal crosstalk and electromagnetic interference. Its robust performance ensures that data integrity is maintained, even in challenging environments. This makes it ideal for settings where reliability and performance cannot be compromised. As a part of advanced digital systems, LVDS/OpenLDI contributes to reducing overall power consumption, an essential feature for battery-operated devices. The technology’s flexibility and efficiency make it a preferred choice for engineers looking to streamline data communication across different electronic ecosystems.
The Ethernet Real-Time Publish-Subscribe (RTPS) core offers a comprehensive hardware implementation for the Ethernet RTPS protocol. Designed to deliver high-speed, reliable data transfer in network environments requiring real-time communications, this core is pivotal for industries where synchronization and minimal latency are critical. Ideal for systems requiring deterministic data delivery, the Ethernet RTPS core ensures seamless integration and performance. It specializes in maintaining high-fidelity communication, crucial for military and aerospace applications where precision and timing are non-negotiable. Supporting robust data throughput across various platforms, this IP core allows for enhanced system flexibility and reduces protocol handling overhead. Engineered for maximum efficiency, this product offers a balanced blend of speed, reliability, and hardware utilization, rendering it a key component in advanced network systems. With its capacity to accommodate high-performance demands, the RTPS core is an invaluable asset in mission-critical scenarios.
The THOR Toolbox provides a multifaceted platform for NFC and UHF connectivity, tailored for a wide range of IoT applications. It contains high-precision NFC components optionally combined with UHF for diverse data transfer capabilities, allowing for secure identification processes. This adaptability across multiple protocols makes it a valuable tool for capturing data and providing early-stage design validation for emerging technologies. Incorporating a robust temperature sensor, THOR measures environmental conditions with high accuracy, which is critical in industrial settings. It supports external sensor interfacing through analog and digital connections, providing flexibility in data acquisition. The toolbox also includes encryption features to ensure data integrity and security, making it ideal for applications requiring stringent data management, such as medical devices. Tailored for sectors facing rigorous demands like the industrial and medical markets, THOR's efficient memory storage and configurable data logging offer scalable solutions across safety, logistics, and healthcare monitoring domains. By enabling rapid development and deployment demonstrations, it significantly accelerates project timelines from concept to completion.
Korusys's Video Wall IPr efficiently processes input from HDMI or DisplayPort sources and displays it across multiple monitors. Designed for applications like digital signage and public displays, it can handle resolutions up to 3840x2400p60 input and 1920x1200p60 output. The product supports various configurations, including cloning and stretching with bezel compensation, enabling seamless integration into different environments. The package includes a comprehensive API for control and configuration, ensuring adaptability to diverse project requirements.
FaintStar is an innovative star sensor designed for medium to high accuracy star tracking, navigation, and rendezvous operations. Its architecture includes a 1020 x 1020 pixel array with a 10 µm pitch, coupled with a 12-bit A/D conversion to deliver precise image processing capabilities. Flight-proven, it is rated at TRL9, ensuring reliability for critical aerospace missions.\n\nThe sensor supports 'light-to-centroids' image processing, a critical feature for space applications that require high precision in object positioning and tracking. Its interfaces such as SpaceWire LVDS enhance communication efficiency and data throughput, supporting speeds of 40Mb/s and 80Mb/s. Furthermore, the FaintStar is built to be radiation-tolerant, addressing Total Ionizing Dose (TiD), proton, and Single Event Effects (SEE) challenges, maintaining its performance under the high radiation levels encountered in space.\n\nThis sensor is ITAR-free and has undergone ESCC 2269000 evaluation and ESCC 9020 flight model procurement, ensuring compliance with stringent space industry standards. Its robust design and adaptability make it an excellent choice for space missions, where high accuracy, reliability, and long-term operational capability are paramount.
The Alcora V-by-One® HS Daughter Card is engineered to connect seamlessly with any FPGA development board equipped with high-speed transceivers, supporting advanced video applications with ease. This card supports amalgamation of two FMC cards, resulting in up to 16 lanes that can handle video resolutions as high as 4K at 120Hz or 8K at 30Hz. Versatile by nature, the Alcora card comes in two configurations: with either 51-pin or 41-pin headers, expanding its adaptability to various devices. It features two clock generators aimed at minimizing jitter in the recovered RX clock, thus ensuring reliable video transmission under high-speed operation conditions. V-by-One® HS, developed by THine Electronics, Inc., is a high-speed digital interface technology primed for the flat-panel display market. Its design easily supports the growing need for higher resolution and frame rate in modern displays, making it an ideal choice for high-definition video transmission projects. The Alcora daughter card enhances design flexibility and capability in developing next-generation video applications.
Dyumnin Semiconductors' RISCV SoC is a powerful, 64-bit quad-core server-class processor tailored for demanding applications, integrating a multifaceted array of subsystems. Key features include an AI/ML subsystem equipped with a tensor flow unit for optimized AI operations, and a robust automotive subsystem supporting CAN, CAN-FD, and SafeSPI interfaces.\n\nAdditionally, it includes a multimedia subsystem comprising HDMI, Display Port, MIPI, camera subsystems, Gfx accelerators, and digital audio, offering comprehensive multimedia processing capabilities. The memory subsystem connects to various prevalent memory protocols like DDR, MMC, ONFI, NorFlash, and SD/SDIO, ensuring vast compatibility.\n\nThe RISCV SoC's design is modular, allowing for customization to meet specific end-user applications, offering a flexible platform for creating SoC solutions with bespoke peripherals. It also doubles as a test chip available as an FPGA for evaluative purposes, making it ideal for efficient prototyping and development workflows.
The Tentiva Video FMC board stands out as a sophisticated solution for advanced video processing needs, offering modularity for easy customization and expansion. This board includes two high-speed PHY slots that support data rates up to 20 Gbps, designed to facilitate communication between the board and a variety of PHY cards. The modular architecture allows developers to adapt to specific project requirements easily, inserting or removing PHY cards as needed. This design flexibility supports a variety of applications, ranging from standard video transmission to more intricate and diverse setups. Available PHY card options include DPT14X, DP14RX, eDP14TX, DP21TX, and DP21RX, facilitating operations across different DisplayPort versions. Designed for compatibility with FPGA development boards equipped with an FMC header, the Tentiva Video FMC integrates seamlessly with numerous boards from various manufacturers. Its versatility makes it a reliable choice for projects demanding high-speed video processing and transmission capabilities, keeping pace with evolving industry demands.
The ARINC664 Switch IP Core provides essential switching functionalities within the ARINC664 network, facilitating the seamless connection between various devices and modules in aerospace systems. This implementation of ARINC664 part 7 ensures that data packets are efficiently switched and routed within the network, supporting the reliable and effective transfer of information across complex aerospace systems.\n\nEngineered to manage the intricacies of aerospace communication networks, the ARINC664 Switch is designed to provide high-level performance even under challenging environments. It ensures that data is swiftly managed and exchanged, enhancing the overall operational efficiency of the aerospace systems it integrates with. The functionality of the switch ensures that data transfer is consistent, reducing the likelihood of data loss or miscommunication, which is crucial in flight operations.\n\nThis core is indispensable in scenarios requiring high integrity and reliability, accompanying the ARINC664 End System to complete the comprehensive network solution. By effectively elevating data handling and network communication, the ARINC664 Switch proves to be pivotal in advancing the technology surrounding aircraft systems, ensuring they remain at the forefront of technological appgebraahes in communications and control.
MeasureExpert is engineered for automated measurement and analysis, providing detailed insights essential for maintaining quality and performance in electronic products. By automating tests and measurements, this tool enables large-scale data management and quick iteration, streamlining the verification phase of electronic design. The tool's capability to handle multiple testing scenarios simultaneously makes it invaluable in ensuring that a product meets the specified requirements before production. MeasureExpert assists engineers by simplifying the testing process, reducing the potential for human error and increasing the efficiency of the quality assurance stage. MeasureExpert's automation prowess supports the production of high-reliability electronic systems, offering detailed analytical feedback that helps refine designs and confirm their readiness for market launch. It is a crucial component of any design cycle focused on high standards of precision and efficiency.
Analog Bits excels in SERDES technology, providing highly efficient and customizable products across PCIe generations 3, 4, and 5. These solutions support enterprise-class performance, offering low power and small die area, perfect for demanding applications like FPGA, mobile computing, and SSDs. Supporting unlimited lane configurations and capable of integrating multiple data protocols such as PCIe, SAS, and USB, these SERDES options are versatile enough to meet diverse market needs while minimizing latency for seamless chip-to-chip communication.
The third generation APIX3 technology addresses the increasing demands of new infotainment and cockpit architectures in automobiles by supporting multiple UHD resolutions. APIX3 enables transmission rates of up to 6 Gbps over single shielded twisted pair cables, and up to 12 Gbps over quad twisted pairs. This new iteration boasts enhanced diagnostic capabilities like cable monitoring and supports high-definition content through several video interfaces, making it crucial for advanced in-car video solutions. APIX3 facilitates the transmission of multiple video channels on a single connection, supporting advanced cockpit architectures. It also integrates 100 Mbps Ethernet among other serial protocols, while offering backward compatibility with its predecessor, APIX2. A critical feature is the active equalizer that automatically adjusts to individual cable transmission lines, ensuring plug-and-play connectivity and compensating for cable aging and temperature fluctuations. The technology supports full duplex communication, and through its scalable bandwidth, can be flexibly adapted from entry-level to high-end vehicle systems. APIX3 is instrumental in establishing seamless vehicle network systems and is engineered to be integrated effortlessly into existing setups with minimal reconfiguration required.
The CXL 3.1 Switch by Panmnesia represents a leap in interconnect technology, designed to facilitate seamless communication between an array of diverse computing components. These switches are integral to scaling memory resources efficiently, enhancing the interconnectivity between devices such as GPUs and memory expanders. Notably, the switch supports advanced multi-level switching and port-based routing, which bolsters its scalability across multiple nodes, making it ideal for large, high-performance data center environments.\n\nBuilding on its CXL 3.1 standard, this switch is highly adaptable, supporting a wide variety of device types, including Type 2 and Type 3 CXL devices. This adaptability ensures comprehensive support and optimal performance across CPUs, GPUs, and memory devices. The switch's architecture is designed for high-throughput and low-latency operations, which are crucial for modern AI and high-performance computing applications.\n\nThe switch is also engineered with future-forward features that enable extensive device interconnections, facilitating large-scale, composable systems. Its efficient design helps reduce the total cost of ownership by minimizing unnecessary hardware investments while enhancing data transfer speeds and processing efficiencies.\n\nPanmnesia’s CXL 3.1 Switch is poised to become a pivotal component in the evolution of computing resources, offering unmatched scalability and reliability for enterprise-level AI deployments and memory-centric systems.
The FPGA Tick-To-Trade system is designed to optimize financial transactions by significantly reducing latency, crucial for high-frequency trading environments. The solution involves a direct mapping of trading algorithms into FPGA logic, streamlining the process from order placement to execution. This system allows financial institutions to maintain a competitive edge by executing trades faster than those using traditional software-based OMS solutions. Its integration capabilities enable it to work seamlessly with existing infrastructures, further enhancing its utility in the fast-paced trading sector.
The GL9767 by Genesys Logic is a card reader controller that supports high-speed data transfer and an extensive range of memory cards. Designed in accordance with PCI Express Rev. 2.1, this controller incorporates PCIe PHY and UHS-II PHY to provide robust connectivity options for various multimedia cards, including SDHC, miniSD, and microSD cards. Its advanced features make it compatible with SD 7.1 Express modes, offering data rates up to 3940MB/s, ensuring high-performance data processing for diverse consumer and industrial applications. This card reader controller is equipped with efficient power management features such as PCI Express ASPM, runtime D3 states, and latency tolerance reporting for minimized power consumption without sacrificing speed. By integrating multiple power regulators and a card power switch, it provides stable operations across a wide range of voltage requirements, supporting SD 3.0 UHS-I, SD 4.0 UHS-II, and more recent card standards. GL9767's advanced hardware DMA engine optimizes data transfer, while its built-in protection mechanisms protect against over-current situations, enhancing the overall durability and reliability of devices utilizing this chip. This solution stands out for its low power consumption and comprehensive bus support, making the GL9767 an asset for applications in mobile, PC, and other consumer electronics sectors requiring efficient, high-capacity data processing capabilities.
Atria Logic's Low Power ARM AV Player is a versatile, software-based multimedia player intended to decode AVC files efficiently across various consumer electronics like digital picture frames and in-flight infotainment systems. Embedded with ARM processing technology, it targets environments where power efficiency and performance are critical. This AV player combines a comprehensive suite including a file reader, de-multiplexer, an H.264 decoder, and an AAC-LC stereo decoder. This combination allows it to handle multimedia content seamlessly, presenting high definition video content while maintaining precise audio synchronization. The implementation on Xilinx Zynq FPGA with dual ARM Cortex-A9 cores optimizes the processing capabilities further, ensuring that additional programmable FPGA resources are kept available for other tasks. Its Linux-based multimedia framework makes the player highly adaptable, providing robust support for various multimedia applications in cost-sensitive markets.
The Peripheral IP Suite enhances the microcontroller IP offerings by including various interface cores tailored for the 8051 architecture. It includes the Four-Wire Slave Interface (M4WIS), the Two-Wire Slave Interface (M2WIS), and the 1-Gigabit UDP/Ethernet MAC (UDPMAC) core. These peripherals extend the interface capabilities of the standard M8051W and M8051EW cores, encompassing UDP datagram and Ethernet MAC functionalities with integral DMA, configurable packet FIFOs, and a RGMII interface.
Catalyst-GbE is an innovative networking solution offering high-performance Ethernet NIC modules for PXIe and CPCIe systems. These single-slot modules integrate up to 4x10, 2x25, and 2x100 Gigabit Ethernet connections, drawing on technology from Intel and NVIDIA Mellanox PCIe NICs for leading-edge network capabilities. Designed for modular high-performance applications, Catalyst-GbE enhances connectivity and data transfer rates significantly within PXIe systems. It stands out by delivering exceptional networking performance at competitive pricing, making it a vital component for network-intensive applications where speed and reliability are crucial. Ideal for rapid data communication requirements in sophisticated testing environments, Catalyst-GbE provides a remarkable solution with rapid delivery schedules, typically within a month. It offers excellent operational flexibility and impressive value, positioning it as an indispensable tool for modern digital systems.
The ARINC664 End System product offers a seamless mechanism for interfacing between aircraft line-replaceable units (LRUs) and the ARINC664 network. This core adheres to ARINC664 part 7 standards, which is vital for aviation communication networks that manage data exchanges. It integrates robust mechanisms to ensure secure and efficient data transmission within the stringent requirements of aerospace applications.\n\nDesigned to meet the high demands of network systems in aviation, this IP stands out for its capacity to provide stable interaction paths for various onboard systems. It ensures that data traffic is smoothly managed and transmitted, mitigating any communication delays. The ARINC664 network protocol when integrated within aircraft systems facilitates high-speed data management necessary for modern aviation applications, marking this IP as critical for the next-generation aircraft.\n\nFurthermore, its architecture is built to cater to the multi-channel demands of aircraft communication networks, enabling a dependable interface that meets the exacting standards required by aerospace industries. The ARINC664 IP efficiently implements the interface functions, making it a preferred choice for developers focused on avionics and similar high-stakes fields.
The PHY Management Interface for MII is designed to facilitate communication with Ethernet physical layer devices. This interface handles operations such as reading and writing to specific registers within the PHY. A significant feature is its ability to manage communication sequences, ensuring smooth data flow and reliability in network operations. The interface is robust, capable of adapting to various configurations and operational demands. Central to its design is a versatile state machine that handles various phases of operation. The architecture supports multiple operational states, including initialization, data transfer, and completion stages. Such a design promises seamless transitions between states, thereby maintaining the integrity and efficiency of data handling processes in networked devices. This adaptability makes the interface suitable for a wide range of applications where reliable network communication is critical. From a technical perspective, this interface is implemented with high precision in logic design, leveraging standard protocols to ensure compatibility and performance. With features such as synchronous data capturing, error checking and signal conditioning, the PHY Management Interface is a comprehensive solution for modern networking needs.
The GEDEK Ethernet IP offers a distinct, groundbreaking solution for integrating Ethernet connectivity into FPGA designs without the need for processors or software stacks. Unlike traditional implementations, GEDEK ensures full bandwidth utilization for both transmitting and receiving data, bypassing complexities such as external memories or real-time operating systems. Tailored to accommodate both Fast Ethernet and Gigabit Ethernet standards, this IP provides dual-mode capabilities that are vital for a wide range of applications. GEDEK facilitates seamless connections between PCs and FPGAs or interlinks multiple FPGA units, optimizing the use of Ethernet connections in industrial or data-intensive settings.