All IPs > Memory Controller & PHY > NVM Express
NVM Express (NVMe) is a high-performance, scalable host controller interface designed specifically for accessing non-volatile storage media attached via PCI Express (PCIe). It provides an efficient mechanism to interact with the storage media, presenting significant advantages over legacy protocols like SATA when it comes to speed, scalability, and flexibility. As data demands continue to escalate with modern applications, NVMe semiconductor IPs ensure robust and rapid communication between the processor and non-volatile memory, significantly boosting system performance.
In the semiconductor IP category of Memory Controller & PHY, NVMe plays a pivotal role in optimizing the interface between flash memory storage devices and the host processors. The NVMe IP cores are meticulously designed to accommodate the needs of various storage solutions, enabling them to manage data more effectively compared to traditional storage protocols. This results in reduced latency, increased bandwidth utilization, and expedited data processing, crucial for applications ranging from enterprise data centers to consumer electronics.
The comprehensive range of IP solutions within the NVMe category offers immense versatility for integration into SSDs, storage arrays, and data-centric computing environments. These IPs typically include advanced features such as multi-namespace support, end-to-end data protection, and flexible queuing mechanisms that cater to the high throughput requirements of modern systems. Their design is focused on maximizing the speed at which data exchanges occur, thus supporting innovative technological applications in AI, big data, and cloud computing.
By leveraging NVMe semiconductor IPs, designers can achieve high-performance storage solutions capable of handling massive data volumes effortlessly. The flexibility and efficiency offered by these IPs not only expedite product development cycles but also foster the creation of storage architectures that are both cost-effective and scalable. Whether used in high-speed personal computers, sophisticated mobile devices, or expansive server farms, NVMe technology is indispensable for any architecture requiring superior performance and reliability in data storage solutions.
The xT CDx is a sophisticated tumor profiling solution designed to advance precision oncology care for solid malignancies. This assay uses next-generation sequencing to assess alterations in 648 genes, identifying single nucleotide variants, multi-nucleotide variants, and insertions/deletions. It also evaluates microsatellite instability status and serves as a companion diagnostic to explore potential treatment avenues according to specific therapeutic product labeling. Uniquely, xT CDx offers mutation profiling through samplings from both formalin-fixed paraffin-embedded tumor tissues and matched normal samples such as blood or saliva, enhancing diagnostic clarity and treatment direction for patients with solid tumors. The comprehensive report generated includes valuable insights that can inform the personalized treatment path for cancer patients.
NVMe Expansion is engineered to augment NVMe storage capacity by 2-4 times through the use of LZ4 or zstd hardware-accelerated compression. This solution is tailored for environments where maximizing storage efficiency and minimizing energy use are critical. By enabling expanded storage capabilities without significant power increases, this product is well-suited for data centers and enterprise storage systems.
IP Maker’s IPM-NVMe Device is a comprehensive data transfer management solution for high-performance PCIe SSD Controllers. It enhances existing architectures by taking over data flow responsibilities from the CPU, which is traditionally burdened with this task. This NVMe-compliant IP core excels in automating command processing and supporting extensive multi-channel DMA operations. Adhering to modern NVMe standards, such as those maintained by UNH-IOL, the IP core supports multiple I/O queues and provides automatic command processing capabilities, thus significantly boosting throughput. By managing both host and controller memory buffers, the IPM-NVMe Device ensures that resource utilization is optimal, leading to cost reductions and improved performance. Its low latency and energy-efficient design make it adaptable to various NVMe-based applications, including enterprise and consumer-grade products. The IP is validated and ready for implementation on both FPGA and ASIC platforms, making it a versatile solution for companies looking to implement storage products with minimized time-to-market delays.
The Zhenyue 510 SSD Controller exemplifies T-Head's cutting-edge design in enterprise-grade storage solutions. Engineered to deliver exceptional I/O processing capabilities, this controller reaches stellar benchmarks such as 3400K IOPS and a data bandwidth of 14GByte/s. Its architecture integrates tightly controlled power management units with adaptable read/write power allocations, ensuring power efficiency marked by 420K IOPS per Watt. To guarantee data integrity, it utilizes T-Head’s proprietary error-checking algorithms which provide an unprecedented correction rate, reducing error counts significantly. Incorporating both hardware-software integrated algorithms, the Zhenyue 510 is capable of precisely predicting potential charge drift in flash memory at scale, optimizing storage reliability and longevity. The controller's versatility is enhanced by its 16 high-speed NAND channels, offering ample bandwidth for high-volume data demands while maintaining effective isolation in multi-tenant environments. Its SR-IOV support extends its utility across cloud-based and virtualized applications, underscoring its adaptability in modern computing scenarios, including online transactions, big data storage, and edge computing architectures.
Arasan's UFS 4.0 Host IP delivers a high-performance interface for universal flash storage, offering unparalleled data throughput necessary for modern devices. UFS 4.0, adhering to JEDEC standards, enhances data transfer rates up to 46.4 Gbps per lane while incorporating features like Write Turbo and Performance Throttling Mitigation, crucial for handling high volumes of data efficiently. This IP provides a robust framework for applications ranging from smartphones and tablets to automotive infotainment systems, enabling swift file transfers and seamless multimedia streaming. Arasan’s UFS solution is backed by rigorous compliance testing, ensuring that developers receive a ready-to-implement package with assured interoperability and high-speed connectivity, thereby facilitating a competitive edge in the burgeoning market for high-capacity storage solutions.
Cyclic Design's G13 and G13X IPs are crafted for 512-byte correction blocks, suited for NAND devices with 2KB and 4KB pages. Transitioning from traditional single bit correction using Hamming codes, these IPs support higher bit corrections essential as NAND technologies advance. The G13 IP offers a modular, customizable drop-in upgrade enhancing existing controller architectures with minimal investment, ensuring compatibility with both existing hardware and software.
The G15 IP is optimized for 2KB blocks, enhancing NAND controllers with a support system for higher ECC levels, simple integration across a variety of applications, and scalability for future technologies. Capable of reducing development costs while allowing customers to modify the source to fit specific requirements, it integrates seamlessly into established designs while also offering advanced ECC options.
The NVMe Streamer is a robust IP core designed to enhance data storage performance by leveraging the capabilities of Non-Volatile Memory Express (NVMe) protocols. Integrated seamlessly into FPGAs, this core provides full accelerator NVMe host subsystem functionalities, ideally suited for Xilinx Zynq Ultrascale+ MPSoC and RFSoC devices. The NVMe Streamer offers complete programmability, allowing for CPU-less operations that maximize data throughput while keeping the processing system unobtrusive. This subsystem efficiently utilizes Xilinx GTH and GTY Multi-Gigabit Transceivers along with PCIe Hard IP Cores, making it fully compatible with PCIe Gen 1 through Gen 4 speeds. It supports various lane configurations to ensure optimal scalability and adaptability for high-speed data applications. Users benefit from full acceleration features, integrating host controller capabilities that simplify the setup and configuration of NVMe IO commands, significantly increasing performance and system responsiveness. The NVMe Streamer's applications are extensive, covering high-speed data acquisition and seamless sensor data recording. It is particularly advantageous for automotive and aerospace data logging, where reliability and efficiency are paramount. Its design enables lossless and accurate recording and streaming from solid-state drives (SSDs), offering advanced storage protocol offloading for modern high-bandwidth demands.
The LDS NVME HOST IP has been done for beginners and experts in NVMe to drive NVMe PCIe SSD. Providing a CPU interface for long sequential recording or reading and a FIFO interface for I/O intensive data transfer, it simplifies management of the IP using AXI bus. The IP automatically configures PCIe RP and EP registers and NVMe registers, manages up to 8 Name Spaces and 16 IO Queues, handles 512Bytes or 4096Bytes sector sizes, and runs admin commands in parallel with the I/O Queue. It includes options for FAT32/EXFAT file system and offers easy connection to embedded Root Port PCIe IP through the AXI bus. Verified on the ALINX AXAU15 + AB19-M2PCI Board with several disks, it provides excellent performance with increased memory configurations.
The G14 and G14X IP series optimizes for 1KB correction blocks, designed to transition with MLC flash using 8KB page sizes. The IP supports both current MLC needs and future SLC requirements, providing a bridge as technologies shift. Offering flexibility in block size from 2 to 1800 bytes and customizable for latency and bandwidth needs, this IP ensures robust error correction including ECC4 and ECC8, vital for leveraging new SLC flash generations.
Tower Semiconductor's Non-Volatile Memory Solutions offer advanced memory technology for a wide range of applications. This platform specializes in memory retention without power, crucial for devices that require data persistence. The NVM solutions encompass a variety of memory types, including EEPROM and Flash, enabling reliable data storage across sectors. These solutions are characterized by high reliability and endurance, making them suitable for industrial, consumer, and automotive applications. The ability to sustain numerous write/erase cycles without degradation ensures longevity and durability, critical in environments where stable memory performance is essential. The NVM Technology from Tower Semiconductor is designed to integrate easily with various logic processes, fostering efficient semiconductor design. This capability allows for the creation of optimized systems that enhance performance while minimizing energy consumption, aligning with industry demands for greener, more sustainable technologies.
The NVMe Gen 5 Controller IP from XtremeSilica delivers high-speed data processing capabilities crucial for next-generation storage solutions. As the NVMe standard evolves, this IP ensures seamless integration with the latest devices, maximizing data handling efficiency, and enhancing operational performance in storage architectures. NVMe Gen 5 offers significant improvements in data throughput and latency reduction, essential for modern data centers and high-demand computing environments. Its design addresses the needs for increased speed and reliability, ensuring consistent and rapid data access, which is crucial in managing large data workloads efficiently. Additionally, this controller supports various storage configurations, enhancing compatibility across multiple platforms. This flexibility is integral in developing adaptable storage solutions that can evolve with industry trends, particularly as data consumption and storage needs grow exponentially worldwide.
The P-Series MRAM-DDR3 and MRAM-DDR4 Solution offers an advanced memory solution that combines the benefits of MRAM technology with DDR3 and DDR4 interfaces. This product features sophisticated timing control mechanisms, allowing adaptability to various MRAM configurations without compromising on performance. It includes support for heterogeneous modes and improved hardware initialization features. Designed to deliver high endurance and persistence, this solution meets rigorous memory requirements while providing flexibility in power and size considerations, making it well-suited for a broad range of applications.
The High-Speed Interface Technology provided by VeriSyno Microelectronics is engineered to enable seamless data transmission across various applications. This technology supports multiple protocols such as USB, DDR, MIPI, HDMI, PCIe, SATA, and XAUI, making it highly versatile for a wide range of digital communication needs. Designed to meet the requirements of both new and existing process nodes, it is adaptable for customer-specific applications, ensuring optimal performance. VeriSyno leverages diverse fabrication processes ranging from 28nm to 90nm, which allows them to cater to advanced manufacturing needs as well as traditional requirements between 90nm and 180nm. The company's approach ensures that their high-speed interface technology is compatible with different industry standards, offering a scalable solution that is both powerful and reliable. This high-speed technology is crucial for enhancing the performance of electronic systems, providing efficient and robust data transfer mechanisms. Whether it's for consumer electronics, data centers, or automotive applications, VeriSyno's solutions are designed to lead advancements in technology, facilitating next-generation connectivity and communication.
The NVMe Host Controller Core is designed to efficiently manage high-speed data transactions, primarily targeting PCIe SSDs. This IP core fully supports the NVMe specification, ensuring seamless interaction with SSDs for high-performance applications. It can function without a CPU or external memory, leveraging its internal architecture for superior integration into PCIe systems. Without relying on a PCIe Gen4 Hard IP, the NVMeG4 variant enables connectivity with the latest ultra-fast SSDs, providing a comprehensive solution for high-throughput data storage systems. The core is ideal for applications demanding extreme storage performance, offering data transfer rates that significantly exceed traditional storage solutions. Moreover, the optional raNVMe and muNVMe cores provide enhanced access solutions, supporting multiple users and simultaneously accessing via different logical constructs. These innovations allow the NVMe Host Controller Core to meet the rigorous demands of modern data centers and high-speed storage networks.
The Key-Value-Store Accelerator (KVS) significantly advances data center storage capabilities through FPGA-based acceleration. By integrating high-performance computing systems, this accelerator optimizes data flow architectures, facilitating hyperconvergence and object storage within networked environments. It features the ability to support high processing throughput, balancing low-latency access with expansive storage capacities via interfaces connecting to DDR3/DDR4 DRAM, NVMe SSDs, or SATA/SAS disks. Built with a foundation on the Xilinx Zynq UltraScale+ MPSoC, the KVS Accelerator promises seamless compatibility and scalability. Its architecture harnesses a combination of line-rate TCP/IP and Memcached processing within the programmable logic, producing extensive server power reductions via heterogeneous computing frameworks. This approach promises efficient processing capabilities at line speeds of 10, 25, 40, and even 100 GigE. This technology suits a range of applications, including accelerating Memcached servers for online transactional processing, object storage for hyper-converged nodes, and hybrid SSD/HDD setups. Its modular design in HDL and C/C++ ensures easy integration into existing frameworks, offering tailored configurations for diverse storage requirements across various markets.
The MICROCHIP NVME HOST RECORDER IP developed by Logic Design Solutions is crafted to offer excellent performance in NVMe data management and execution, specifically aligned with Microchip's FPGA environments. Engineered for robustness, this IP module ensures high data throughput and minimal latency, which is crucial for applications that depend on efficient data storage and retrieval. Its architecture is structured to align seamlessly with Microchip's PolarFire and PolarFire SoC product lines, enhancing NVMe functionality without compromising the performance attributes these platforms are known for. This solution supports the latest NVMe standards to ensure compatibility and adherence to modern storage needs. Specially designed for developers working within Microchip’s FPGA frameworks, this IP provides the tools necessary to implement effective and high-performing storage solutions that can manage complex data in real time. With an emphasis on performance stability, this IP caters to applications where high-speed data processing is essential. Integrating this IP into your Microchip FPGA framework enables developers to leverage the extensive capabilities of NVMe protocols, enhancing the efficiency of storage operations dramatically. The solution represents a reliable and effective path to achieving data management excellence in diverse technological environments, known for its adaptability and high support for efficient data communication across platforms.
The XILINX NVME HOST RECORDER IP by Logic Design Solutions is a sophisticated solution designed to manage NVMe data recording and transfer with efficiency and high performance. This IP is optimized for integration within FPGA architectures, leveraging Xilinx's robust hardware capabilities to deliver exceptional data handling for storage applications. The design ensures minimal latency and maximizes throughput, catering to high-demand environments. With versions available for various FPGA models such as Kintex UltraScale Plus and Zynq UltraScale Plus, it caters to a spectrum of performance needs, ensuring flexibility in deployment. This IP is engineered to support the latest NVMe standards, ensuring compatibility and forward-looking integration within cutting-edge storage solutions. Its flexible architecture allows for seamless adaptation to different configurations, making it a versatile choice for developers seeking to deploy sophisticated data storage solutions on Xilinx platforms. With a focus on reliability and performance, the IP is optimized to handle extensive data loads, guaranteeing that operations are performed with high accuracy and speed. Incorporating the NVMe Host Recorder IP into your infrastructure promises a leap in data management capabilities, harnessing the advanced features of Xilinx FPGA technology to elevate data processing efficiencies. The IP provides a robust foundation for building storage solutions that require reliable NVMe interfacing, making it an essential component for modern data storage systems that demand high performance and reliability.
The NSF030120 is a state-of-the-art Silicon Carbide (SiC) MOSFET, designed to meet the increasing demands for high-efficiency and high-power switching applications. Known for its robust performance in harsh environments, this device offers enhanced thermal conductivity and voltage tolerance, making it ideal for applications requiring reliable and durable power management solutions. Built using advanced SiC technology, this MOSFET provides superior switching speeds and reduced energy losses, contributing to overall system efficiency. Its compact design and high-power density ensure that engineers can incorporate it into diverse electronic systems without compromising their space-saving requirements. The NSF030120 SiC MOSFET is key for applications in industries such as automotive, industrial, and renewable energy sectors, where its ability to handle high currents and voltages with minimal heat generation distinguishes it from traditional silicon devices. This makes it especially valuable for electric vehicles, photovoltaic inverters, and power supplies that demand optimal efficiency and reliability under continuous operation. Enhancements in SiC material allow this device to operate beyond the capabilities of conventional silicon-based products, providing solutions that are both future-proof and environmentally conscious. As such, the NSF030120 is a testament to Nexperia's commitment to innovation and sustainability in power electronics.
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