All IPs > Wireline Communication
Wireline Communication semiconductor IPs are critical components in the semiconductor industry, playing a vital role in enabling efficient data transmission across fixed networks. They are designed to optimize the performance of data transfer over physical media like copper cables, fiber optics, or hybrid systems. Given the growing demand for faster and more reliable data transmission, these IPs are indispensable in the development of network infrastructure and communication devices.
Products within this category cover a wide array of technologies essential for different communication protocols. For instance, Ethernet IPs are fundamental for creating network interfaces capable of high-speed data exchange, contributing to the performance of local and wide-area networks. The Fibre Channel IPs are specifically tailored for storage area networks, providing high-speed, lossless data transmission which is crucial for data-intensive applications in enterprise environments.
Additionally, this category includes Error Correction/Detection IPs, critical for maintaining data integrity during transmission by identifying and rectifying errors without needing retransmission. Our portfolio also comprises IPs for Modulation/Demodulation which play a key role in preparing data for transmission and ensuring it is correctly interpreted upon receipt. Other pivotal subcategories include ATM/Utopia, which aid in asynchronous transfer mode communications, and CEI, which contribute to high-speed chip-to-chip and board-to-board communications.
Overall, Wireline Communication semiconductor IPs facilitate the development of robust and efficient communication solutions across various industries. Whether for building telecommunication infrastructure or advancing next-generation networking devices, these IPs are central to achieving high performance, scalability, and reliability in wireline communication networks.
The Metis AIPU PCIe AI Accelerator Card is engineered for developers demanding superior AI performance. With its quad-core Metis AIPU, this card delivers up to 214 TOPS, tackling challenging vision applications with unmatched efficiency. The PCIe card is designed with user-friendly integration in mind, featuring the Voyager SDK software stack that accelerates application deployment. Offering impressive processing speeds, the card supports up to 3,200 FPS for ResNet-50 models, providing a competitive edge for demanding AI tasks. Its design ensures it meets the needs of a wide array of AI applications, allowing for scalability and adaptability in various use cases.
The 1G to 224G SerDes is a versatile serializer/deserializer technology designed to facilitate high-speed data transfers across various interface standards. It caters to stringent speed requirements by supporting a wide range of data rates and signaling schemes, allowing efficient integration into comprehensive communication systems. This SerDes technology excels in delivering reliable, low-latency connections, making it ideal for hyperscale data centers, AI, and 5G networking where fast, efficient data processing is essential. The broad compatibility with numerous industry protocols also ensures seamless interoperability with existing systems. Adapted for scalability, the 1G to 224G SerDes provides design flexibility, encouraging implementation across a variety of demanding environments. Its sophisticated architecture promotes energy efficiency and robust performance, crucial for addressing the ever-growing connectivity demands of modern technology infrastructures.
The Low Density Parity Check (LDPC) codes are powerful, capacity approaching channel codes and have exceptional error correction capabilities. The high degree of parallelism that they offer enables efficient, high throughput hardware architectures. The ntLDPC_WiFi6 IP Core is based on an implementation of QC-LDPC Quasi-Cyclic LDPC Codes and is fully compliant with IEEE 802.11 n/ac/ax standard. The Quasi-Cyclic LDPC codes are based on block-structured LDPC codes with circular block matrices. The entire parity check matrix can be partitioned into an array of block matrices; each block matrix is either a zero matrix or a right cyclic shift of an identity matrix. The parity check matrix designed in this way can be conveniently represented by a base matrix represented by cyclic shifts. The main advantage of this feature is that they offer high throughput at low implementation complexity. The ntLDPC_WiFi6 decoder IP Core may optionally implement one of two approximations of the log-domain LDPC iterative decoding algorithm (Belief propagation) known as either Layered Normalized Offset Min-Sum Algorithm or Layered Lambda-min Algorithm. Selecting between the two algorithms presents a decoding performance .vs. system resources utilization trade-off. The core is highly reconfigurable and fully compliant to the IEEE 802.11 n/ac/ax Wi-Fi4, Wi-Fi5 and Wi-Fi 6 standards. The ntLDPC_WiFi6 encoder IP implements a 81-bit parallel systematic LDPC encoder. An off-line profiling Matlab script processes the original matrices and produces a set of constants that are associated with the matrix and hardcoded in the RTL encoder.
**Ceva-PentaG2** is a complete IP platform for implementing a wide range of user-equipment and IoT cellular modems. The platform includes a variety of DSPs, modem hardware modules, software libraries, and simulation tools. Capabilities of the Ceva-PentaG2 include New Radio (NR) physical layer design ranging across all 3GPP profiles from RedCap IoT and mMTC, through eMBB up to ultra-reliable low-latency communications (URLLC). The platform has two base configurations. Ceva-PentaG2 Max emphasizes performance and scalability for enhanced mobile broadband (eMBB) and future proofing design for next generation 5G-Advanced releases. Ceva-PentaG2 Lite emphasizes extreme energy and area efficiency for lower-throughput applications such as LTE Cat 1, RedCap, and optimized cellular IoT applications. The PentaG2 platform comprises a set of Ceva DSP cores, optimized fixed-function hardware accelerators, and proven, optimized software modules. By using this platform, designers can implement optimized, hardware-accelerated processing chains for all main modem functions. In the selection process, designers can tune their design for any point across a huge space of area, power consumption, latency, throughput, and channel counts. Solutions can fit applications ranging from powerful eMBB for mobile and Fixed Wireless Access (FWA) devices to connected vehicles, cellular IoT modules, and even smart watches. System-C models in Ceva’s Virtual Platform Simulator (VPS) aid architectural exploration and system tuning, while an FPGA-based emulation kit speeds SoC integration. [**Learn more about Ceva-PentaG2 solution>**](https://www.ceva-ip.com/product/ceva-pentag2/?utm_source=silicon_hub&utm_medium=ip_listing&utm_campaign=ceva_pentag2_page)
RaiderChip's GenAI v1 is a pioneering hardware-based generative AI accelerator, designed to perform local inference at the Edge. This technology integrates optimally with on-premises servers and embedded devices, offering substantial benefits in privacy, performance, and energy efficiency over traditional hybrid AI solutions. The design of the GenAI v1 NPU streamlines the process of executing large language models by embedding them directly onto the hardware, eliminating the need for external components like CPUs or internet connections. With its ability to support complex models such as the Llama 3.2 with 4-bit quantization on LPDDR4 memory, the GenAI v1 achieves unprecedented efficiency in AI token processing, coupled with energy savings and reduced latency. What sets GenAI v1 apart is its scalability and cost-effectiveness, significantly outperforming competitive solutions such as Intel Gaudi 2, Nvidia's cloud GPUs, and Google's cloud TPUs in terms of memory efficiency. This solution maximizes the number of tokens generated per unit of memory bandwidth, thus addressing one of the primary limitations in generative AI workflow. Furthermore, the adept memory usage of GenAI v1 reduces the dependency on costly memory types like HBM, opening the door to more affordable alternatives without diminishing processing capabilities. With a target-agnostic approach, RaiderChip ensures the GenAI v1 can be adapted to various FPGAs and ASICs, offering configuration flexibility that allows users to balance performance with hardware costs. Its compatibility with a wide range of transformers-based models, including proprietary modifications, ensures GenAI v1's robust placement across sectors requiring high-speed processing, like finance, medical diagnostics, and autonomous systems. RaiderChip's innovation with GenAI v1 focuses on supporting both vanilla and quantized AI models, ensuring high computation speeds necessary for real-time applications without compromising accuracy. This capability underpins their strategic vision of enabling versatile and sustainable AI solutions across industries. By prioritizing integration ease and operational independence, RaiderChip provides a tangible edge in applying generative AI effectively and widely.
Ethernet MAC 10M/100M/1G/2.5G IP is a solution that enables the host to communicate data using the IEEE 802.3 standard for 10M, 100M, 1G, 2.5G speeds and is suited for use in networking equipment such as switches and routers. The Client-side interface for the IP is AXI-S and the Ethernet MAC IP comes with GMII, RGMII or MII interfaces on the PHY side. The Ethernet MAC 10M/100M/1G/2.5G IP features a compact and low latency solution, it is highly configurable and can optionally include IEEE 1588 Timestamping Unit (TSU). The Silicon agnostic Ethernet MAC IP, suitable for ASICs and FPGAs, is prepared for easy integration with Ethernet PCS 10M/ 100M/1G/2.5G IP from Comcores.
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.
The GenAI v1-Q from RaiderChip brings forth a specialized focus on quantized AI operations, reducing memory requirements significantly while maintaining impressive precision and speed. This innovative accelerator is engineered to execute large language models in real-time, utilizing advanced quantization techniques such as Q4_K and Q5_K, thereby enhancing AI inference efficiency especially in memory-constrained environments. By offering a 276% boost in processing speed alongside a 75% reduction in memory footprint, GenAI v1-Q empowers developers to integrate advanced AI capabilities into smaller, less powerful devices without sacrificing operational quality. This makes it particularly advantageous for applications demanding swift response times and low latency, including real-time translation, autonomous navigation, and responsive customer interactions. The GenAI v1-Q diverges from conventional AI solutions by functioning independently, free from external network or cloud auxiliaries. Its design harmonizes superior computational performance with scalability, allowing seamless adaptation across variegated hardware platforms including FPGAs and ASIC implementations. This flexibility is crucial for tailoring performance parameters like model scale, inference velocity, and power consumption to meet exacting user specifications effectively. RaiderChip's GenAI v1-Q addresses crucial AI industry needs with its ability to manage multiple transformer-based models and confidential data securely on-premises. This opens doors for its application in sensitive areas such as defense, healthcare, and financial services, where confidentiality and rapid processing are paramount. With GenAI v1-Q, RaiderChip underscores its commitment to advancing AI solutions that are both environmentally sustainable and economically viable.
TTTech's Time-Triggered Ethernet (TTEthernet) is a breakthrough communication technology that combines the reliability of traditional Ethernet with the precision of time-triggered protocols. Designed to meet stringent safety requirements, this IP is fundamental in environments where fail-safe operations are absolute, such as human spaceflight, nuclear facilities, and other high-risk settings. TTEthernet integrates seamlessly with existing Ethernet infrastructure while providing deterministic control over data transmission times, allowing for real-time application support. Its primary advantage lies in supporting triple-redundant networks, which ensures dual fault-tolerance, an essential feature exemplified in its use by NASA's Orion spacecraft. The integrity and precision offered by Time-Triggered Ethernet make it ideal for implementing ECSS Engineering standards in space applications. It not only permits robust redundancy and high bandwidth (exceeding 10 Gbps) but also supports interoperability with various commercial off-the-shelf components, making it a versatile solution for complex network architectures.
The ntLDPC_G98042 (17664,14592) IP Core is defined in IEEE 802.3ca-2020, it is used by ITU-T G.9804.2-09.2021 standard document and it is based on an implementation of QC-LDPC Quasi-Cyclic LDPC Codes. These LDPC codes are based on block-structured LDPC codes with circular block matrices. The entire parity check matrix can be partitioned into an array of block matrices; each block matrix is either a zero matrix or a right cyclic shift of an identity matrix. The parity check matrix designed in this way can be conveniently represented by a base matrix represented by cyclic shifts. The main advantage of this feature is that they offer high throughput at low implementation complexity. The ntLDPCΕ_G98042 encoder IP implements a 256-bit parallel systematic LDPC encoder. The Generator LDPC Matrix is calculated off-line, compressed and stored in ROM. It is partitioned to 12 layers and each layer, when multiplied by the 14592 payload block, produces 256 parity bits. The multiplier architecture may be parameterized before synthesis to generate multiple multiplier instances [1:4,6], in order to effectively process multiple layers in parallel and improve the IP throughput rate. Shortened blocks are supported with granularity of 128-bit boundaries and 384 or 512 parity bits puncturing is also optionally supported. The ntLDPCD_G98042 decoder IP Core may optionally implement one of two approximations of the log-domain LDPC iterative decoding algorithm (Belief propagation) known as either Layered Offset Min-Sum Algorithm (OMS) or Layered Lambda-min Algorithm (LMIN). Selecting between the two algorithms presents a decoding performance vs. system resources utilization trade-off. The OMS algorithm is chosen for this implementation, given the high code rate of the Parity Check Matrix (PCM). The ntLDPCD_G98042 decoder IP implements a 256-bit parallel systematic LDPC layered decoder. Each layer corresponds to Z=256 expanded rows of the original LDPC matrix. Each layer element corresponds to the active ZxZ shifted identity sub-matrices within the layer. Each layer element is shifted accordingly and processed by the parallel decoding datapath unit, in order to update the layers’ LLR estimates and extrinsic information iteratively until the required number of decoding iterations has been run. The decoder IP also features a powerful optional syndrome check early termination (ET) criterion, to maintain identical error correction performance, while significantly increasing its throughput rate and/or reducing hardware cost. Additionally it reports how many decoding iterations have been performed when ET is activated, for system performance observation and calibration purposes. A top level architecture deployment wrapper allows to expand the parallelism degree of the decoder before synthesis, effec-tively implementing a trade-off between utilized area and throughput rate. Finally a simple, yet robust, flow control handshaking mechanism is included in both IPs, which is used to communicate the IPs availability to adjacent system components at 128-bit parallel bus interface. This logic is easily portable into any communication protocol, like AXI4 stream IF.
The EW6181 is an advanced multi-GNSS silicon solution designed for high sensitivity and precision. This powerful chip supports GPS, Glonass, BeiDou, Galileo, SBAS, and A-GNSS, offering integration flexibility with various applications. Its built-in RF frontend and digital baseband facilitate robust signal processing, controlled by an ARM MCU. The EW6181 integrates essential interfaces for diverse connectivity, matched with DC-DC converters and LDOs to minimize BOM in battery-driven setups. This silicon marries low power demands with strong functional capabilities, thanks to proprietary algorithms that optimize its operation. It’s engineered to deliver exceptional accuracy and sensitivity in both standalone and cloud-related environments, adapting smoothly to connected ecosystems for enhanced efficiency. Its compact silicon footprint further enhances its suitability for applications needing prolonged battery life and reliable positioning. With a focus on Antenna Diversity, the EW6181 shines in dynamic applications like action cameras and smartwatches, ensuring clear signal reception even when devices rapidly rotate. This aspect accentuates the chip's ability to maintain consistent performance across a range of challenging environments, reinforcing its role in the forefront of GNSS technology.
Convolutional FEC codes are very popular because of their powerful error correction capability and are especially suited for correcting random errors. The most effective decoding method for these codes is the soft decision Viterbi algorithm. ntVIT core is a high performance, fully configurable convolutional FEC core, comprised of a 1/N convolutional encoder, a variable code rate puncturer/depuncturer and a soft input Viterbi decoder. Depending on the application, the core can be configured for specific code parameters requirements. The highly configurable architecture makes it ideal for a wide range of applications. The convolutional encoder maps 1 input bit to N encoded bits, to generate a rate 1/N encoded bitstream. A puncturer can be optionally used to derive higher code rates from the 1/N mother code rate. On the encoder side, the puncturer deletes certain number of bits in the encoded data stream according to a user defined puncturing pattern which indicates the deleting bit positions. On the decoder side, the depuncturer inserts a-priori-known data at the positions and flags to the Viterbi decoder these bits positions as erasures. The Viterbi decoder uses a maximum-likelihood detection recursive process to cor-rect errors in the data stream. The Viterbi input data stream can be composed of hard or soft bits. Soft decision achieves a 2 to 3dB in-crease in coding gain over hard-decision decoding. Data can be received continuously or with gaps.
RapidGPT is a next-generation electronic design automation tool powered by AI. Designed for those in the hardware engineering field, it allows for a seamless transition from ideas to physical hardware without the usual complexities of traditional design tools. The interface is highly intuitive, engaging users with natural language interaction to enhance productivity and reduce the time required for design iterations.\n\nEnhancing the entire design process, RapidGPT begins with concept development and guides users through to the final stages of bitstream or GDSII generation. This tool effectively acts as a co-pilot for engineers, allowing them to easily incorporate third-party IPs, making it adaptable for various project requirements. This adaptability is paramount for industries where speed and precision are of the essence.\n\nPrimisAI has integrated novel features such as AutoReview™, which provides automated HDL audits; AutoComment™, which generates AI-driven comments for HDL files; and AutoDoc™, which helps create comprehensive project documentation effortlessly. These features collectively make RapidGPT not only a design tool but also a comprehensive project management suite.\n\nThe effectiveness of RapidGPT is made evident in its robust support for various design complexities, providing a scalable solution that meets specific user demands from individual developers to large engineering teams seeking enterprise-grade capabilities.
ntLDPC_SDAOCT IP implements a 5G-NR Base Graph 1 systematic Encoder/Decoder based on Quasi-Cyclic LDPC Codes (QC-LDPC), with lifting size Zc=384 and Information Block Size 8448 bits. The implementation is based on block-structured LDPC codes with circular block matrices. The entire parity check matrix can be partitioned into an array of block matrices; each block matrix is either a zero matrix or a right cyclic shift of an identity matrix. The parity check matrix designed in this way can be conveniently represented by a base matrix represented by cyclic shifts. The main advantage of this feature is that it offers high throughput at low implementation complexity. The ntLDPCE_SDAOCT Encoder IP implements a systematic LDPC Zc=384 encoder. Input and Output may be selected to be 32-bit or 128-bits per clock cycle prior to synthesis, while internal operations are 384-bits parallel per clock cycle. Depending on code rate, the respective amount of parity bits are generated and the first 2xZc=768 payload bits are discarded. There are 5 code rate modes of operation available (8448,8448)-bypass, (9984,8448)-0.8462, (11136,8448)-0.7586, (12672,8448)-0.6667 and (16896,8448)-0.5. The ntLDPCD_SDAOCT Base Graph Decoder IP may optionally implement one of two approximations of the log-domain LDPC iterative decoding algorithm (Belief propagation) known as either Layered Min-Sum Algorithm (MS) or Layered Lambda-min Algorithm (LMIN). Variations of Layered MS available are Offset Min-Sum (OMS), Normalized Min-Sum (NMS), and Normalized Offset Min-Sum (NOMS). Selecting between these algorithms presents a decoding performance vs. system resources utilization trade-off. The ntLDPCD_SDAOCT decoder IP implements a Zc=384 parallel systematic LDPC layered decoder. Each layer corresponds to Zc=384 expanded rows of the original LDPC matrix. Each layer element corresponds to the active ZcxZc shifted identity submatrices within the layer. Each layer element is shifted accordingly and processed by the parallel decoding datapath unit, in order to update the layers LLR estimates and extrinsic information iteratively until the required number of decoding iterations has been run. The decoder IP also features a powerful optional early termination (ET) criterion, to maintain practically equivalent error correction performance, while significantly increasing its throughput rate and/or reducing hardware cost. Additionally it reports how many decoding iterations have been performed when ET is activated, for system performance observation and calibration purposes. Finally a simple, yet robust, flow control handshaking mechanism is included in both IPs, which is used to communicate the IPs availability to adjacent system components. This logic is easily portable into any communication protocol, like AXI4 stream IF.
Credo Semiconductor excels in SerDes (Serializer/Deserializer) IP for custom ASICs, providing solutions that facilitate easy integration into various System on Chip (SoC) designs. The architecture of Credo's SerDes IP is based on a mixed-signal DSP approach that enhances performance while minimizing power and integration challenges. This architecture is especially beneficial for high-bandwidth data processing scenarios, making it an ideal choice for applications in AI, high-performance computing, and advanced telecommunication infrastructures.<br /><br />Their custom-built SerDes solutions stand out for the ability to handle tens and even hundreds of lanes, thanks to their innovative approach that seamlessly bridges the gap between core and analog logic deployment. These IPs are crafted to thrive even in mature process nodes, delivering remarkable efficiency in terms of power consumption and cost-effectiveness. By implementing these IPs, companies can ensure their systems are robust, future-proof, and capable of handling substantial data transmission tasks.<br /><br />Among the notable advantages offered by Credo’s SerDes IP is their adaptability with various signaling standards such as NRZ and PAM4, facilitating diverse data rate requirements up to 112G per lane. This flexibility not only aligns with current technological trends but also positions companies to swiftly adapt to future advancements in data communication technology, leveraging Credo's partnership with leading foundries and process nodes, such as TSMC's N3 and N5 technologies.
The Digital PreDistortion (DPD) Solution offered by Systems4Silicon is a versatile technology aimed at significantly enhancing the efficiency of RF power amplifiers. This advanced sub-system is scalable and adaptable to both ASIC and FPGA platforms, ensuring broad compatibility across various device vendors. The DPD solution meticulously enhances linearity, crucial for devices operating within multi-standard environments, such as 5G and O-RAN systems.\n\nDesigned to optimize the signal processing in transmission systems, this DPD technology allows for considerable power savings by enabling amplifiers to function more efficiently. Systems4Silicon’s approach ensures that the system can maintain its performance across different transmission bandwidths, which can scale to 1 GHz or higher. This makes it particularly valuable for large-scale and high-frequency applications.\n\nThe DPD technology's implementation is straightforward, providing a field-proven solution that integrates seamlessly with current infrastructures. Its adaptability is not merely limited to the hardware spectrum but extends to accommodate evolving communication standards, ensuring it remains relevant and effective in diverse market scenarios.
The AXI4 DMA Controller is a highly versatile IP core that supports multi-channel data transfers, ranging from 1 to 16 channels, depending on system requirements. Optimized for high throughput, this controller excels in transferring both small and large data sets effectively. It features independent DMA Read and Write Controllers for enhanced data handling with options for FIFO transfers to a diverse array of memory and peripheral configurations. This IP core offers significant flexibility with its programmable burst sizes, supporting up to 256 beats and adhering to critical boundary crossings in the AXI specification.
The EZiD211, also known as Oxford-2, is a leading-edge demodulator and modulator developed by EASii IC to facilitate advanced satellite communications. It embodies a sophisticated DVB-S2X wideband tuner capable of supporting LEO, MEO, and GEO satellites, integrating proprietary features like Beam Hopping, VLSNR, and Super Frame applications. With EZiD211 at the helm, satellite communications undergo a transformation in efficiency and capacity, addressing both current and future demands for fixed data infrastructures, mobility, IoT, and M2M applications. Its technological forefront facilitates seamless operations in varied European space programs, validated by its full production readiness. EZiD211's design offers a unique capability to manage complex satellite links, enhance performance, and ensure robust and reliable data transmission. EASii IC provides comprehensive support through evaluation boards and samples, allowing smooth integration and testing to meet evolving satellite communication standards.
The Digital Radio (GDR) from GIRD Systems is an advanced software-defined radio (SDR) platform that offers extensive flexibility and adaptability. It is characterized by its multi-channel capabilities and high-speed signal processing resources, allowing it to meet a diverse range of system requirements. Built on a core single board module, this radio can be configured for both embedded and standalone operations, supporting a wide frequency range. The GDR can operate with either one or two independent transceivers, with options for full or half duplex configurations. It supports single channel setups as well as multiple-input multiple-output (MIMO) configurations, providing significant adaptability in communication scenarios. This flexibility makes it an ideal choice for systems that require rapid reconfiguration or scalability. Known for its robust construction, the GDR is designed to address challenging signal processing needs in congested environments, making it suitable for a variety of applications. Whether used in defense, communications, or electronic warfare, the GDR's ability to seamlessly switch configurations ensures it meets the evolving demands of modern communications technology.
This IP core is engineered for applications where minimal latency is of paramount importance. The Ultra-Low Latency 10G Ethernet MAC features an optimized architecture to provide rapid data transmission and reception capabilities, ensuring that all processes occur smoothly and efficiently. It is tailored specifically for real-time operations where every millisecond counts, like high-frequency trading and real-time monitoring systems. By focusing on reducing latency, this Ethernet MAC core delivers exceptional performance, making it an excellent choice for demanding environments that cannot afford delayed communication. The core's architecture reduces overhead and maximizes throughput, leveraging Chevin Technology's advanced design expertise to minimize signal interference and processing delays. Its seamless integration with both AMD and Intel FPGA platforms makes it versatile for a variety of implementations across industry sectors. Moreover, it's designed to maintain optimal performance while managing high data loads, showcasing a consistent ability to handle extensive network traffic efficiently.
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 ntLDPC_5GNR Base Graph Encoder IP Core is defined in 3GPP TS 38.212 standard document and it is based on an implementation of QC-LDPC Quasi-Cyclic LDPC Codes. The specification defines two sets of LDPC Base Graphs and their respective derived Parity Check Matrices. Each Base Graph can be combined with 8 sets of lifting sizes (Zc) in a total of 51 different lifting sizes. This way by using the 2 Base Graphs, the 5G NR specification defines up to 102 possible distinct LDPC modes of operation to select from, for optimum decoding performance, depending on target application code block size and code rate (using the additional rate matching module features). For Base Graph 1 we have LDPC(N=66xZc,K=22xZc) sized code blocks, while for Base Graph 2 we have LDPC(N=50xZc,K=[6,8,9,10]xZc) sized code blocks. The ntLDPCE_5GNR Encoder IP implements a multi-parallel systematic LDPC encoder. Parallelism depends on the selected lifting sizes subsets chosen for implementation. Shortened blocks are supported with granularity at lifting size Zc-bit boundaries. Customizable modes generation is also supported beyond the scope of the 5G-NR specification with features such as: “flat parity bits puncturing instead of Rate Matching Bit Selection”, “maintaining the first 2xZc payload bits instead of eliminating it before transmission”, etc. The ntLDPCD_5GNR decoder IP implements a maximum lifting size of Zc_MAX-bit parallel systematic LDPC layered decoder. Each layer corresponds to Zc_MAX expanded rows of the original LDPC matrix. Each layer element corresponds to the active ZcxZc shifted identity sub-matrices within the layer. Each layer element is shifted accordingly and processed by the parallel decoding datapath unit, in order to update the layers LLR estimates and extrinsic information iteratively until the required number of decoding iterations has been run. The decoder IP also features a powerful optional early termination (ET) criterion, to maintain practically equivalent error correction performance, while significantly increasing its throughput rate and/or reducing hardware cost. Additionally it reports how many decoding iterations have been performed when ET is activated, for system performance observation and calibration purposes. Finally a simple, yet robust, flow control handshaking mechanism is included in both IPs, which is used to communicate the IPs availability to adjacent system components. This logic is easily portable into any communication protocol, like AXI4 stream IF.
High-Speed SerDes for Chiplets is engineered to provide exceptional interconnect solutions tailored for chiplet architectures. This product offers ultra-low power consumption while maintaining high data transfer rates, essential for modern multi-die systems. By facilitating rapid communication between chiplets, it enhances overall system efficiency and performance. This SerDes solution is optimized for integration with a range of tech nodes, ensuring compatibility with various semiconductor manufacturing processes. Its design is focused on providing robust data integrity and reducing latency, which are crucial for efficient system operation in complex, integrated circuits. High-Speed SerDes addresses the growing demand for advanced interconnect solutions in chiplet architectures, making it an indispensable tool for developing next-generation semiconductor devices. Its ability to support high data throughput while keeping power use minimal makes it a standout choice in high-performance design environments.
Ncore Cache Coherent Interconnect is designed to tackle the multifaceted challenges in multicore SoC systems by introducing heterogeneous coherence and efficient cache management. This NoC IP optimizes performance by ensuring high throughput and reliable data transmission across multiple cores, making it indispensable for sophisticated computing tasks. Leveraging advanced cache coherency, Ncore maintains data integrity, crucial for maintaining system stability and efficiency in operations involving heavy computational loads. With its ISO26262 support, it caters to automotive and industrial applications requiring high reliability and safety standards. This interconnect technology pairs well with diverse processor architectures and supports an array of protocols, providing seamless integration into existing systems. It enables a coherent and connected multicore environment, enhancing the performance of high-stakes applications across various industry verticals, from automotive to advanced computing environments.
This core is designed for high-performance applications requiring robust Ethernet connectivity with a high data throughput. The 10G Ethernet MAC and PCS solutions are developed to reliably handle speeds up to 10Gbps, optimizing the interface between Ethernet transmission and physical network layers. These IPs provide key functionality that helps maintain efficient data handling and transfer across networks, ensuring minimal latency and maximum productivity. Featuring refined architecture and robust design, this solution integrates seamlessly into FPGA frameworks, especially targeting Intel and AMD platforms. Its compatibility and reliability make it ideal for advanced networking tasks in a broad range of applications—from data centers to complex cloud infrastructures. The efficient management of data streams through this MAC and PCS combination ensures high-speed communication and responsiveness critical to high-demand environments. Its plug-and-play usability allows it to be quickly incorporated into existing systems, providing a flexible solution that maintains the scalability and performance needs of high-end systems. Additionally, Chevin Technology's expertise ensures that these cores come with comprehensive support tailored to enhance product integration and deployment efficiency.
The 2D FFT core is designed to efficiently handle two-dimensional FFT processing, ideal for applications in image and video processing where data is inherently two-dimensional. This core is engineered to integrate both internal and external memory configurations, which optimize data handling for complex multimedia processing tasks, ensuring a high level of performance is maintained throughout. Utilizing sophisticated algorithms, the 2D FFT core processes data through two FFT engines. This dual approach maximizes throughput, typically limiting bottlenecks to memory bandwidth constraints rather than computational delays. This efficiency is critical for applications handling large volumes of multimedia data where real-time processing is a requisite. The capacity of the 2D FFT core to adapt to varying processing environments marks its versatility in the digital processing landscape. By ensuring robust data processing capabilities, it addresses the challenges of dynamic data movement, providing the reliability necessary for multimedia systems. Its strategic design supports the execution of intensive computational tasks while maintaining the operational flow integral to real-time applications.
Designed to cater to AI-specific needs, SEMIFIVE’s AI Inference Platform provides tailored solutions that seamlessly integrate advanced technologies to optimize performance and efficiency. This platform is engineered to handle the rigorous demands of AI workloads through a well-integrated approach combining hardware and software innovations matched with AI acceleration features. The platform supports scalable AI models, delivering exceptional processing capabilities for tasks involving neural network inference. With a focus on maximizing throughput and efficiency, it facilitates real-time processing and decision-making, which is crucial for applications such as machine learning and data analytics. SEMIFIVE’s platform simplifies AI implementation by providing an extensive suite of development tools and libraries that accelerate design cycles and enhance comprehensive system performance. The incorporation of state-of-the-art caching mechanisms and optimized data flow ensures the platform’s ability to handle large datasets efficiently.
The Time-Triggered Protocol (TTP) designed by TTTech is an advanced communication protocol meant to enhance the reliability of data transmission in critical systems. Developed in compliance with the SAE AS6003 standard, this protocol is ideally suited for environments requiring synchronized operations, such as aeronautics and high-stakes energy sectors. TTP allows for precise scheduling of communication tasks, creating a deterministic communication environment where the timing of data exchanges is predictable and stable. This predictability is crucial in eliminating delays and minimizing data loss in safety-critical applications. The protocol lays the groundwork for robust telecom infrastructures in airplanes and offers a high level of system redundancy and fault tolerance. TTTech’s TTP IP core is integral to their TTP-Controller ASICs and is designed to comply with stringent integrity and safety requirements, including those outlined in RTCA DO-254 / EUROCAE ED-80. The versatility of TTP allows it to be implemented across varying FPGA platforms, broadening its applicability to a wide range of safety-critical industrial systems.
The DisplayPort 1.4 IP-core offered by Parretto B.V. is a compact yet potent solution for DisplayPort connectivity needs. Supporting a range of link rates from 1.62 to 8.1 Gbps, this IP-core accommodates varied setups with ease, including embedded DisplayPort (eDP) applications. It provides support for multiple lane configurations and both native video and AXI stream interfaces. The inclusion of Single and Multi Stream transport modes enhances its versatility for different video applications. Tailored for modern FPGA devices, the core supports a comprehensive video format range, including RGB and various YCbCr colorspaces. A standout feature is the secondary data packet interface, enabling audio and metadata transport alongside video signals. This makes it a full-fledged solution for video-centric applications, complemented by a Video Toolbox geared for video processing tasks like timing and test pattern generation. Parretto ensures the IP-core's adaptability by offering it with a thin host driver and API for seamless integration. The core is compatible with an extensive list of FPGA devices, such as AMD UltraScale+ and Intel Arria 10 GX. Customers benefit from the availability of source code via GitHub, promoting easier customization and deep integration into diverse systems. Comprehensive documentation supports the IP-core, ensuring efficient setup and utilization.
Designed for seamless integration, High PHY Accelerators from AccelerComm encapsulate top-tier signal processing blocks critical for 5G solutions. Available as FPGA and ASIC ready IP cores, they are tailored for rapid deployment with minimal risk. These accelerators are supported by accurate simulation models and designed to use standardized interfaces for integration. Notably, they also provide support for space-hardened platforms, ensuring robust performance in diverse settings.
The AST 500 and AST GNSS-RF are multifaceted SOC and RF solutions designed for GNSS applications. They support a wide array of constellations such as GPS, GLONASS, NavIC, and others, in multiple frequency bands, enhancing navigation performance. These ICs integrate features like secure boots and data encryption, facilitating robust security measures crucial for sensitive data. The AST GNSS-RF is equipped with capabilities for L1, L2, L5, and S band reception, catering to high-fidelity signal requirements across various applications. The support for dual-band reception ensures that ionosphere errors are minimized, offering exceptional positioning accuracy.
The RISCV SoC developed by Dyumnin Semiconductors is engineered with a 64-bit quad-core server-class RISCV CPU, aiming to bridge various application needs with an integrated, holistic system design. Each subsystem of this SoC, from AI/ML capabilities to automotive and multimedia functionalities, is constructed to deliver optimal performance and streamlined operations. Designed as a reference model, this SoC enables quick adaptation and deployment, significantly reducing the time-to-market for clients. The AI Accelerator subsystem enhances AI operations with its collaboration of a custom central processing unit, intertwined with a specialized tensor flow unit. In the multimedia domain, the SoC boasts integration capabilities for HDMI, Display Port, MIPI, and other advanced graphic and audio technologies, ensuring versatile application across various multimedia requirements. Memory handling is another strength of this SoC, with support for protocols ranging from DDR and MMC to more advanced interfaces like ONFI and SD/SDIO, ensuring seamless connectivity with a wide array of memory modules. Moreover, the communication subsystem encompasses a broad spectrum of connectivity protocols, including PCIe, Ethernet, USB, and SPI, crafting an all-rounded solution for modern communication challenges. The automotive subsystem, offering CAN and CAN-FD protocols, further extends its utility into automotive connectivity.
AccelerComm’s LDPC solutions cater specifically to the 5G standards, offering high efficiency and leading performance in channel coding. The IP suite includes comprehensive encoder and decoder capabilities that enhance hardware efficiency for this critical component of the PHY layer. This facilitates a marked improvement in throughput and error reduction, aligning with 3GPP standards. Born from academic excellence at Southampton University, they incorporate cutting-edge algorithms for signal performance, achieving substantial decoder performance enhancement and minimizing error floors.
The Ethernet Real-Time Publish-Subscribe (RTPS) IP Core provides a comprehensive hardware implementation of the Ethernet RTPS protocol, facilitating real-time data sharing in network systems. It is designed to enable efficient and synchronized communications crucial in time-sensitive applications. Ideal for environments where timing precision and reliability are paramount, this core supports high-speed data exchanges with low latency performance. This ensures that critical data is published and subscribed to in real-time, meeting rigorous industry standards for communication efficiency. Moreover, the RTPS IP Core is constructed to seamlessly integrate into existing infrastructures, allowing for enhanced operations across diverse platforms while ensuring data flow consistency and system interoperability.
The TSN Switch for Automotive Ethernet is designed to address the needs of modern automotive networks by offering time-sensitive networking capabilities. This switch is tailored to manage Ethernet-based communication in vehicles, ensuring low-latency and reliable data transmission. It supports complex automotive network architectures, making it ideal for real-time communication requirements in vehicles. With its robust time-sensitive networking features, this switch is capable of guaranteeing data delivery within tight time constraints, a critical requirement for advanced driver assistance systems (ADAS) and autonomous driving. It integrates seamlessly within the automotive Ethernet ecosystem, providing scalability and integration flexibility. The switch is engineered to support the industry's move towards centralized vehicle networking, improving data throughput and reducing cabling complexity. The switch’s architecture supports multiple ports, allowing for the connection of various vehicle subsystems within a unified network framework. Implementing this technology can drastically improve the efficiency and reliability of in-vehicle communication systems. The TSN capabilities optimize network traffic management, ensure the prioritization of time-critical messages, and enhance the overall stability and predictability of automotive data flows.
The High Speed Data Bus (HSDB) IP Core offers a robust hardware implementation featuring PHY and MAC layers, optimized for high-speed data transmission. This IP core ensures seamless integration and supports F-22 compatible interface implementations, making it indispensable for advanced military communication systems. This core is instrumental in providing high throughput and low latency, crucial for applications that manage complex data transmissions. Its design caters to environments that require secure and efficient data handling, meeting the rigorous requirements of modern defense systems. The HSDB IP Core is particularly suited for situations where data integrity and transmission speed are pivotal, addressing the needs of platforms reliant on effective real-time communications. Its deployment aids in stabilizing operations across varied legacy and state-of-the-art systems, offering flexibility and reliability.
LightningBlu is a state-of-the-art multi-gigabit connectivity solution for high-speed rail networks, delivering continuous high-speed data transfer between trackside and train systems. This innovative solution works within the mmWave spectrum of 57-71 GHz and is certified for long-term, low-maintenance deployment. It seamlessly integrates with existing trackside networks to provide a stable, high-capacity communication bridge essential for internet access, entertainment, and real-time information services aboard high-speed trains. The LightningBlu system includes robust trackside nodes and compact train-top nodes designed for seamless installation, significantly enhancing operational efficiencies and passenger experience by providing internet speeds superior to traditional mobile broadband services. With aggregate throughputs reaching around 3 Gbps, LightningBlu sets the standard for rail communications by supporting speeds at which data demands are met with ease. Crucially, LightningBlu is a key component in transforming the railway telecommunications landscape, offering upgraded technology that enables uninterrupted and enhanced passenger digital services even in the busiest railways across the UK and USA. Through its advanced mmWave technology, it ensures that the connectivity needs of the modern commuter are met consistently and effectively, paving the way for a new era in transit communication.
The iCan PicoPop® is a highly compact System on Module (SOM) based on the Zynq UltraScale+ MPSoC from Xilinx, suited for high-performance embedded applications in aerospace. Known for its advanced signal processing capabilities, it is particularly effective in video processing contexts, offering efficient data handling and throughput. Its compact size and performance make it ideal for integration into sophisticated systems where space and performance are critical.
The Network Protocol Accelerator Platform (NPAP) is engineered to accelerate network protocol processing and offload tasks at speeds reaching up to 100 Gbps when implemented on FPGAs, and beyond in ASICs. This platform offers patented and patent-pending technologies that provide significant performance boosts, aiding in efficient network management. With its support for multiple protocols like TCP, UDP, and IP, it meets the demands of modern networking environments effectively, ensuring low latency and high throughput solutions for critical infrastructure. NPAP facilitates the construction of function accelerator cards (FACs) that support 10/25/50/100G speeds, effectively handling intense data workloads. The stunning capabilities of NPAP make it an indispensable tool for businesses needing to process vast amounts of data with precision and speed, thereby greatly enhancing network operations. Moreover, the NPAP emphasizes flexibility by allowing integration with a variety of network setups. Its capability to streamline data transfer with minimal delay supports modern computational demands, paving the way for optimized digital communication in diverse industries.
The PRACH IP Suite is a comprehensive solution optimized for 5G NR O-RAN Split 7.2X design. It includes a complete MATLAB model, RTL implementation, and a robust verification environment for bit-exact simulation and testing. This suite supports seamless integration and speeds up the development process with its 5G NR O-RAN compatibility, catering to the evolving needs of modern telecommunications infrastructure.
The High-Speed Interface Technology by VeriSyno Microelectronics Co., Ltd. encompasses a range of connectivity solutions designed to meet the rigorous demands of modern applications. This suite includes versatile interfaces such as USB, DDR, MIPI, HDMI, PCIe, and SATA, each meticulously crafted to ensure seamless data transmission and robust performance across various technological landscapes. VeriSyno's high-speed interface solutions are built upon a robust framework that supports rigorous signaling protocols, ensuring consistency and reliability in high-bandwidth environments. These interfaces are optimized for diverse manufacturing processes, ranging from 28nm to 90nm, demonstrating flexibility and adaptability to next-generation design requirements. The technology facilitates customization, allowing clients to tailor interface attributes to specific application needs, thereby maximizing system efficiency. With a commitment to excellence, VeriSyno consistently updates its technology suite to incorporate latest advancements, ensuring clients benefit from leading-edge connectivity solutions.
On the transmitter side, the turbo -phi encoder architecture is based on a parallel concatenation of two double -binary Recursive Systematic Convolutional (RSC) encoders, fed by blocks of K bits (N=K/2). It is a 16-state double-binary turbo encoder. On the receiver side, the turbo decoder engine is built using two functioning soft-in/soft-out modules (SISO). The outputs of one SISO, after applying the scaling and interleaving are used by its dual SISO in the next half iteration. Both the turbo encoder and decoder are fully compliant with the DVB-RCS2, supporting all its code rates and block sizes. In order to achieve higher throughput, the turbo decoder uses parallel MAP decoders. The sliding window algorithm is used to reduce the internal memory sizes. Turbo decoder accepts input LLR’s and outputs the hard decision bits after completing the decoder iterations.
ntRSD core implements a time-domain Reed-Solomon decoding algorithm. The core is parameterized in terms of bits per symbol, maximum codeword length and maximum number of parity symbols. It also supports varying on the fly shortened codes. Therefore any desirable code-rate can be easily achieved rendering the decoder ideal for fully adaptive FEC applications. ntRSD core supports erasure decoding thus doubling its error correction capability. The core also supports continuous or burst decoding. The implementation is very low latency, high speed with a simple interface for easy integration in SoC applications.
The QUIC Protocol Core by Design Gateway is a high-speed, low-latency communication core designed to optimize network traffic in environments prone to congestion. It offers exceptional performance benefits over traditional protocols, leveraging the latest technology in secure and reliable data transmission.\n\nThis core is engineered to support high-speed environments, enhancing data throughput while reducing the likelihood of packet loss. It is particularly effective in networks with high congestion, where maintaining a seamless and efficient flow of data is critical. The QUIC Protocol Core's design focuses on minimizing latency, providing faster data exchange and enhancing overall network performance.\n\nIntegrating this protocol core into existing network infrastructure supports secure, encrypted data communication, vital for maintaining data integrity across various network environments. Its high-performance capabilities reduce overhead and improve application response times, making it indispensable for modern, high-speed data networks.\n\nBy incorporating the QUIC Protocol Core, businesses can optimize their network capabilities, ensuring secure, efficient, and reliable communications that are crucial for today's technology-driven communication systems.
The RWM6050 Baseband Modem is an innovative component of Blu Wireless's mmWave technology portfolio, architected to support high-bandwidth, high-capacity data communications. Designed in collaboration with industry leaders Renesas, this modem unit stands out for its efficiency and versatility, effectively marrying physical modem layers with advanced processing capabilities. The RWM6050 modem is instrumental in providing seamless data transmission for access and backhaul networks. Built to accommodate varying channelisation modes, the RWM6050 supports deep levels of customisation for different bandwidth requirements and transmission distances. It handles multi-gigabit throughput, which makes it ideal for expanding connectivity in urban or industrial areas with dense infrastructure requirements. From smart cities to complex transport systems, this baseband modem scales effectively to meet demanding data needs. Equipped with dual modems and integrated mixed-signal front-end capabilities, the RWM6050 offers a flexible solution for evolving communication infrastructures. Its design ensures optimization for real-time digital signal processing, beamforming, and adaptable connectivity management. The RWM6050 is a key enabler in unlocking the full potential of mmWave technology in a variety of settings, furthering connectivity innovations.
The FCM1401 is a 14GHz CMOS Power Amplifier tailored for Ku-band applications, operating over a frequency range of 12.4 to 16 GHz. This amplifier exhibits a gain of 22 dB and a saturated output power (Psat) of 19.24 dBm, ensuring optimal performance with a power-added efficiency (PAE) of 47%. The architecture enables reduction in battery consumption and heat output, making it ideal for satellite and telecom applications. Its small silicon footprint facilitates integration in space-constrained environments.
The Polar channel coding offering by AccelerComm is crafted for the 3GPP 5G NR, providing both uplink and downlink encoding and decoding capabilities. Designed for easy integration, it includes PC- and CRC-aided SCL polar decoding techniques to ensure uncompromised error correction. Key parameters of the decoding IP can be tuned to adjust parallelism, latency, and throughput, making it adaptable to specific application needs without sacrificing performance.
The BlueLynx Chiplet Interconnect system provides an advanced die-to-die connectivity solution designed to meet the demanding needs of diverse packaging configurations. This interconnect solution stands out for its compliance with recognized industry standards like UCIe and BoW, while offering unparalleled customization to fit specific applications and workloads. By enabling seamless connection to on-die buses and Networks-on-Chip (NoCs) through standards such as AMBA, AXI, ACE, and CHI, BlueLynx facilitates faster and cost-effective integration processes. The BlueLynx system is distinguished by its adaptive architecture that maximizes silicon utilization, ensuring high bandwidth along with low latency and power efficiency. Designed for scalability, the system supports a remarkable range of data rates from 2 to 40+ Gb/s, with an impressive bandwidth density of 15+ Tbps/mm. It also provides support for multiple serialization and deserialization ratios, ensuring flexibility for various packaging methods, from 2D to 3D applications. Compatible with numerous process nodes, including today’s most advanced nodes like 3nm and 4nm, BlueLynx offers a progressive pathway for chiplet designers aiming to streamline transitions from traditional SoCs to advanced chiplet architectures.
The ntRSC_DP1.4 IP core is compliant with Display Port 1.4 standard as published by Video Electronics Standards Association (VESA) for use in DSC (Display Stream Compression) technology. It is based on Reed-Solomon RS(254,250), 10 bit symbols, forward error correction code, where the codeword block consists of 250 information symbols and 4 RS parity symbols. The ntRSC_DP1.4 FEC IP Core ensures error resilient / glitch-free compressed video transport (DSC) to external displays. The implementation is very low latency, high speed with a simple interface for easy integration in SoC applications.
The SiFive Performance family is dedicated to offering high-throughput, low-power processor solutions, suitable for a wide array of applications from data centers to consumer devices. This family includes a range of 64-bit, out-of-order cores configured with options for vector computations, making it ideal for tasks that demand significant processing power alongside efficiency. Performance cores provide unmatched energy efficiency while accommodating a breadth of workload requirements. Their architecture supports up to six-wide out-of-order processing with tailored options that include multiple vector engines. These cores are designed for flexibility, enabling various implementations in consumer electronics, network storage solutions, and complex multimedia processing. The SiFive Performance family facilitates a mix of high performance and low power usage, allowing users to balance the computational needs with power consumption effectively. It stands as a testament to SiFive’s dedication to enabling flexible tech solutions by offering rigorous processing capabilities in compact, scalable packages.
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