All IPs > Memory Controller & PHY > Flash Controller
Flash Controller semiconductor IPs play a critical role in the efficient functioning of memory systems within various electronic devices. These controllers are integral in managing the storage, retrieval, and data transfer processes between memory and the system's main processing units. At their core, flash controllers serve as the interface that translates system-level requests into commands that can be understood by the flash memory itself.
In today's fast-paced digital world, flash controllers are essential components in a wide array of devices, from mobile phones and tablets to laptops and enterprise storage solutions. They ensure that data is written, read, and erased accurately in flash memory, optimizing performance while also extending the lifespan of the memory components. By leveraging advanced error correction codes (ECC), wear leveling, and bad block management strategies, these semiconductor IPs enhance the reliability and durability of the storage system.
Within this category, you'll find a range of flash controller solutions tailored for different types of flash memory technologies, such as NAND, NOR, and the increasingly popular 3D NAND. Each of these controllers is designed to meet specific performance, power, and cost requirements, thereby offering solutions for both consumer and industrial applications.
Ultimately, the selection of a flash controller can greatly influence the overall efficiency and user experience of a product. By choosing the right semiconductor IP from our Flash Controller category at Silicon Hub, product developers can ensure optimal performance for their storage applications, leading to faster, more reliable electronics.
Dolphin Technology offers a comprehensive range of memory IP products, catering to diverse requirements in semiconductor design. These products include a variety of memory compilers, specialty memory, and robust memory test and repair solutions such as Memory BIST. Designed to meet the demands of contemporary low-power and high-density applications, these IPs are built to work across a broad spectrum of process technologies. Advanced power management features, like light and deep sleep modes and dual rails, enable these products to tackle even the toughest low-leakage challenges. What sets these products apart is their flexibility and adaptability, evident in the support for different memory types and process nodes. Dolphin Technology’s memory IPs benefit from seasoned design teams that have proven their mettle in silicon across several generations. Thus, these IPs are not only versatile but also reliable in serving a wide variety of industry needs for technology firms worldwide. Clients can expect memory solutions that are fine-tuned for both power efficiency and performance. Additional capabilities such as power gating cater to ultra-low power devices while achieving a high level of device integration and compatibility. The specialized focus on low noise and rapid cycle times makes these memory solutions highly effective for performance-driven applications. These features collectively make Dolphin Technology’s memory IP an invaluable asset for semiconductor designers striving for innovation and excellence.
The NaviSoC is a cutting-edge system-on-chip (SoC) that integrates a GNSS receiver and an application processor on one silicon die. Known for its high precision and reliability, it provides users with a compact and energy-efficient solution for various applications. Capable of supporting all GNSS bands and constellations, it offers fast time-to-first-fix, centimeter-level accuracy, and maintains high sensitivity even in challenging environments. The NaviSoC's flexible design allows it to be customized to meet specific user requirements, making it suitable for a wide range of applications, from location-based services to asset tracking and smart agriculture. The incorporation of a RISC-V application microcontroller, along with an array of peripherals and interfaces, introduces expanded functionality, optimizing it for advanced IoT and industrial applications. Engineered for power efficiency, the NaviSoC supports a range of supply voltages, ensuring low power consumption across its operations. The chip's design provides for efficient integration into existing systems with the support of a comprehensive SDK and IDE, allowing developers to tailor solutions to their precise needs in embedded systems and navigation infrastructures.
The LEE Flash G1 is designed to cater to cost-sensitive embedded flash applications, leveraging a simple SONOS architecture that scales efficiently down to 40nm. This flash technology is perfect for moderate memory capacity needs, typically up to several hundred kilobytes, making it suitable for automotive and power-sensitive tasks. The G1 Flash supports a wide temperature range, enhancing its viability for extreme automotive requirements and ensuring long-term data retention stability. One of the standout features of the LEE Flash G1 is its power efficiency, characterized by low power consumption during program and erase cycles. This efficiency is achieved through Fowler-Nordheim tunneling technology, drastically minimizing power requirements compared to traditional methods. Furthermore, this technology simplifies the integration of flash memory by requiring only 2 to 3 additional masks, reducing the overall cost and complexity of chip fabrication. Operating on a standard CMOS logic process without altering the SPICE model, LEE Flash G1 allows for the re-use of existing IPs and design assets, offering a path to cost savings and simplifying design processes. The G1's architecture also shortens baking and testing times, significantly cutting down on chip production costs while maintaining quality and reliability under rigorous conditions.
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.
The Secure OTP (One-Time Programmable) solution by PUFsecurity elevates standard OTP technology by integrating anti-fuse memory and robust encryption techniques, ensuring the high-level protection of sensitive data. This sophisticated approach allows for secure data storage and management, even under duress from advanced attack methodologies. Secure OTP transforms how critical data like encryption keys and configuration states are stored, enabling devices to maintain data integrity during storage and transit. By encapsulating both physical macro implementations and digital RTL designs with intuitive control, Secure OTP allows seamless integration into a host of applications while safeguarding against unauthorized data extraction. The integration of diverse interface protocols makes Secure OTP adaptable to a wide range of industrial requirements. It stands as a robust defensive measure in the face of modern threats, offering reliability in an era where secure data storage solutions are more important than ever.
RegSpec is a comprehensive register specification tool that excels in generating Control Configuration and Status Register (CCSR) code. The tool is versatile, supporting various input formats like SystemRDL, IP-XACT, and custom formats via CSV, Excel, XML, or JSON. Its ability to output in formats such as Verilog RTL, System Verilog UVM code, and SystemC header files makes it indispensable for IP designers, offering extensive features for synchronization across multiple clock domains and interrupt handling. Additionally, RegSpec automates verification processes by generating UVM code and RALF files useful in firmware development and system modeling.
The Universal NAND Flash Controller (UNFC) from IP Maker provides a complete solution for integrating NAND flash technology into enterprise storage systems. It is specifically designed to manage high data throughputs and large interconnect bandwidths, which are crucial for high reliability applications. The UNFC is compatible with ONFI 5.x specifications and supports a range of NAND technologies, including SLC, MLC, TLC, and QLC, all while maintaining low costs. The IP core is versatile, supporting AXI, Avalon, and RAM interfaces for seamless system integration. The UNFC delivers adaptive support for multiple flash modes and integrates a robust ECC configuration that aligns with vendor-specific requirements. This makes it an ideal choice for developers looking to optimize data reliability and system performance. By integrating ECC, the controller offers significant protection against data corruption, vital for safeguarding data integrity in high-performance storage environments. Equipped with flexible configuration options, developers can tailor the controller to specific project needs, ensuring an optimal fit for various NAND architectures. This controller is especially effective for reducing time-to-market for storage OEMs by allowing rapid integration of NAND flash with enterprise systems, thus enhancing IOPS performances.
I-fuse® technology leads the way in non-volatile memory with a non-explosive programming method that avoids thermal disruptions commonly associated with other memory systems. It reduces the footprint by a factor of ten compared to eFuse and can be implemented without extra masks or process steps across multiple foundries. With low programming voltage capabilities (1.1V/1.8V) and high data security features, it provides reliability tested up to 300°C, making it suitable for harsh environmental conditions, especially in automotive applications.
Ubi.cloud is an innovative geolocation solution designed to minimize the typical limitations of GPS and Wi-Fi trackers in IoT applications. This software shifts energy-intensive processing from devices to the cloud, significantly reducing power consumption and hardware costs. The technology supports both outdoor GPS and indoor Wi-Fi geolocation, making it versatile for various environments. The solution features ultra-low power consumption, cutting the energy usage of receiver chipsets by up to tenfold compared to traditional devices. This is achieved by utilizing leading hardware components effectively, which accelerates time-to-market for IoT devices. Ubi.cloud is ideal for asset tracking, providing accurate geolocation services with enhanced efficiency. By leveraging the cloud, Ubi.cloud reduces the data payload to a mere 10 bytes per position, operating seamlessly with low-power wide-area networks such as Sigfox, LoRa, NB-IoT, and LTE-M. The flexible business model, offering pay-as-you-go or lifetime licenses, makes it accessible and adaptable to various commercial needs. Evaluation kits and SDKs are available, supporting easy integration and customization for specific applications.
The LEE Fuse ZA offers a robust anti-fuse memory solution, optimized for one-time programmable (OTP) applications such as system trimming and memory redundancy setups. This IP eliminates the need for additional manufacturing masks, offering a cost-effective path to integration within wide-ranging process nodes from 180nm down to advanced sub-10nm technologies. Its design, requiring only two or three metal layers, offers flexibility in using upper metal layers for further circuit integration, broadening its applicability across several advanced process technologies. This feature ensures that the LEE Fuse ZA can seamlessly integrate into complex semiconductor environments without the substantial costs usually associated with new IP incorporation. LEE Fuse ZA's support for extensive temperature ranges and long retention periods makes it a valuable resource for automotive standard products requiring severe condition reliability. Its track record spans various manufacturing statuses, making it a mature choice for industries looking for a dependable OTP solution capable of handling modern technology nodes efficiently.
Renowned as the only DDR system incorporating patented technologies that adjust to environmental and system variations, the High Speed Adaptive DDR Interface addresses the dual demands of high performance and low power. It effectively meets the technological needs of diverse markets like data centers, 5G, and AI/ML, while maintaining compatibility with DDR3/4/5, LPDDR3/4/5, and HBM standards. By leveraging over 24 US patents, Uniquify achieves high performance with reduced power, area, and latency costs, setting it apart as a leader in DDR interface technology.
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 LEE Flash G2 represents a cutting-edge evolution from its predecessor, offering enhanced memory capabilities and innovative features that cater to advanced electronic requirements. Built upon the proven architecture of the LEE Flash G1, the G2 version incorporates a clever switch transistor array, allowing for direct integration with logic circuits and enabling non-volatile SRAM functionalities. This design maintains a low power profile by not requiring high voltage for read operations and reduces layout complexity by eliminating isolation areas. This innovative flash solution is capable of supporting memory capacities up to several megabytes, making it ideal for applications that demand larger storage space while prioritizing energy efficiency. The G2 architecture also ensures compatibility with existing CMOS platforms without the need for changes in the SPICE model, facilitating the adoption of G2 technology within existing processes seamlessly. Other notable attributes include its suitability for high-temperature environments and long retention times, positioning it as a reliable option for automotive and industrial applications. The use of few additional masks further minimizes costs and accelerates production cycles, making G2 a cost-efficient choice for next-generation flash memory requirements.
PermSRAM is a sophisticated nonvolatile memory macro designed to operate on standard CMOS platforms, spanning process nodes from 180nm to 28nm and beyond. It supports a wide variety of nonvolatile memory functions, including a one-time programmable ROM and a pseudo multi-time PROM with exceptional multi-page configuration capabilities. The memory sizes range from 64 bits to 512Kbits, making it highly versatile for various applications. It features a non-rewritable hardware safety lock, specifically for secure code storage, ensuring data integrity and security.\n\nPermSRAM's robust design supports security code storage, program storage, and analog trimming, among other applications. It also provides features like gamma correction and chip ID management, making it suitable for complex tasks. The memory benefits from a compact silicon area, being tamper-resistant due to its invisible charge trap mechanism. Its built-in self-test circuits ensure seamless testing environments and all bits can be tested using conventional test equipment. Furthermore, it offers automotive-grade data retention capabilities, functioning optimally under high temperatures.\n\nCustomers benefit from its cost-efficiency, as it does not require a charge pump for read operations, which simplifies the design and lowers costs. The product's compatibility with conventional test strategies and its suitability for high-temperature environments make it an ideal choice for automotive applications and other demanding industrial uses.
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 eSi-ADAS suite is a high-performance radar processing solution primarily designed to enhance ADAS systems. It comprises a comprehensive set of radar accelerator IPs, such as FFT and CFAR engines, alongside tracking capabilities powered by Kalman filter technology. This setup facilitates real-time monitoring of diverse radar environments. Automotive and UAV sectors benefit significantly from eSi-ADAS, as it ensures precise situational awareness necessary for modern safety and collision avoidance systems. By offloading computationally intensive tasks from the central processing unit, it optimizes performance and power efficiency. This enables the handling of complex scenarios, from short-range radar operations to simultaneous tracking of numerous objects.
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.
The LEE Flash ZT is engineered for automotive and industrial environments where high temperature and durability are critical. What sets the LEE Flash ZT apart is its zero additional mask requirement, significantly reducing manufacturing costs and enabling rapid integration within existing product lines. Its ability to maintain data retention over 20 years at 125°C demonstrates its reliability in demanding applications. Lee Flash ZT supports a wide range of use cases, making it ideal for precision trimming, parameter storage, and sensor integration in high-performance electronic devices. It leverages FN tunneling to achieve ultra-low power during program and erase cycles, which not only cuts down operation costs but also accelerates testing and final product release. Its compact form factor and compatibility with standard CMOS processes allow companies to re-use existing designs and IPs, eliminating the need for bespoke development efforts. This adaptability combined with its performance characteristics makes it a viable solution for manufacturers looking to enhance their product lines without incurring substantial initial investments or production delays.
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 D-Series DDR5/4/3 Controller is designed to excel in latency, bandwidth, and area optimization. It connects to the PHY via a standard DFI 5.0 interface, facilitating seamless integration. This memory controller includes advanced scheduling technologies, ECC support, and multi-channel capabilities. Incorporating over 300 custom features available for customization, it enables significant flexibility and differentiation in memory system design. The D-Series DDR Controller is engineered to ensure robust performance in high-bandwidth requirements, making it suitable for diverse computing environments.
CrossBar's ReRAM Memory is a pioneering memory solution that significantly enhances data storage capabilities for modern applications. Employing a minimalist three-layer structure, ReRAM Memory utilizes a silicon-based switching medium between two electrodes to facilitate resistive switching. This setup results in a highly stable memory cell that operates across varied temperatures and conditions. ReRAM Memory's ability to scale vertically in 3D allows it to deliver extensive terabyte-level storage on a single chip, alongside providing incredible endurance and rapid read/write capabilities. The technology's compatibility with standard CMOS processes facilitates easy integration into existing manufacturing setups, making it highly versatile for a wide range of applications, from IoT devices to data centers, and more. Notably, ReRAM Memory's unique design addresses some critical challenges facing conventional memory technologies. By reducing energy consumption to a mere 1/20th of traditional memory solutions, it delivers unmatched performance, sustaining up to 1000 times more write cycles and operating reliably with significant endurance and retention capabilities. Furthermore, its potential to be combined directly with logic circuits in a foundry augments the memory performance significantly while optimizing space and power requirements. Applications of ReRAM Memory spread across various domains such as artificial intelligence, mobile computing, and secure computing. Its benefits are clearly outlined in its secure features, where the memory is deployed for developing advanced applications involving secure cryptographic keys and tamper-resistant solutions. This makes ReRAM Memory an ideal choice for scenarios demanding high security and reliability, paving the way for future innovations in the semiconductor industry. CrossBar's ReRAM Memory showcases a perfect blend of cutting-edge design and practical implementation potential, enabling the semiconductor field to explore new possibilities in data processing and storage technologies. As digital landscapes continue to evolve, CrossBar's ReRAM offers lifecycle improvements and operational efficiencies that align with the industry's growing needs for high-density, reliable, and energy-efficient memory technologies.
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 IPM-BCH from IP Maker is built on the BCH error-correcting code algorithm to manage NAND flash memory's inherent limitations regarding write cycles. This IP core is engineered to enhance data validity and longevity by correcting and detecting failed operations. Fully configurable, it is adept for use across various FPGA and SoC applications, making it versatile for different technological environments. BCH Encoding/Decoding capabilities are critical for ensuring the data integrity of NAND flash-based storage solutions. The IPM-BCH core can be tailored to specific project needs, balancing performance with resource utilization. Its implementation offers significant reductions in latency or might be optimized for minimal footprint, providing flexibility depending on design requirements. This technology helps extend NAND flash memory's utility within data storage applications by protecting data through robust ECC methodologies. Such implementations shorten the time-to-market by providing pre-verified, high-performance error correction, all while maintaining data accuracy through effective Galois field operations.
Notus provides comprehensive analysis capabilities across signal and power integrity, thermal management, and stress analysis for PCB and package designs. Equipped with electromagnetic technologies, it can offer detailed DC and AC power analyses, optimize decoupling capacitors, and conduct electrothermal simulations. Notus supports examining complex package structures and stacked die solutions, catering to specifications required in modern electronic designs. Its integration-friendly environment and dynamic analysis capabilities confirm Notus as a robust solution for optimizing power delivery systems and improving product reliability in electronic design.
The SMPTE ST 2059 IP core provides reliable time synchronization for broadcast and professional AV equipment, ensuring seamless audio and video alignment. By implementing standards such as ST 2059-1 and ST 2059-2, this core leverages IEEE 1588 PTP for precise time signal generation, contributing to high-accuracy sync across media networks. This IP core aligns signals to a master time generator, crucial for maintaining synchronization during live productions. It supports non-PTP-aware switches, allowing flexibility and scalability across various network speeds, including 1G and up to 100G Ethernet networks. Developed modularly with easy integration in mind, the ST 2059 core maintains compatibility with genlocked SDI equipment, paving the way for a unified approach to time-aligned media processing.
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.
The GL9767 is a PCI Express Rev. 2.1 compatible card reader controller, integrating multiple key functions within its compact design. It supports a wide array of SD memory cards, including SD, SDHC, SDXC, and the ultra high-speed SD 7.1 Express cards, providing reliable and swift data access. Equipped with multiple features aimed at reducing power consumption, the GL9767 embraces PCI Express ASPM, L1 sub-states, and Runtime D3 modes. This card reader controller is designed for optimal performance, supporting various application classes and speed classifications, making it versatile for devices that demand high storage capacity and speed. The GL9767 also features on-chip regulators and power switches to efficiently manage power distribution. Built to support modern standby modes for Windows, Chrome, and Linux OS, it allows seamless integration into diverse operating environments. Its support for enhanced power and performance management makes it suitable for high-performance consumer electronics.
Designed to replace traditional laser fuses, I-fuse® Replaser provides comprehensive benefits in terms of programming and operational reliability. Its operation is characterized by low power requirements for both programming and reading, coupled with rapid response time, ensuring it meets rigorous industry standards like the AEC-Q100 Grade 0. It functions well in environments spanning -40°C to 150°C, further broadening its applicability in tough conditions. With attributes like low program/read voltage and soft programming features for pre-testing, it enables flexible integration into designs requiring efficient space use.
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 X1 SATA SSD Controller is engineered for high-efficiency power management and superior performance in industrial settings. It integrates a 32-bit dual-core microprocessor tailored with specific instruction sets and hardware accelerators for optimal flash memory management. Equipped with hyMap®, a flexible sub-page-based Flash Translation Layer, and FlashXE® for extended endurance, the X1 ensures durability and reliability in data storage applications. This controller is designed to meet the rigorous demands of industrial applications, supporting a wide array of SATA-based storage formats including U.2, M.2, MO-297, and MO-300 modules. The X1 offers robust data protection features such as end-to-end datapath protection and superior wear leveling, making it ideal for environments requiring high reliability and longevity. Incorporating a plethora of advanced security features and custom firmware extensions, the X1 guarantees secure data operations, backed by a comprehensive suite of development tools including firmware, hardware for testing and development, and reference schematics. This makes the X1 a versatile and robust solution for high-stakes industrial applications.
The S9 controller is crafted for industrial-grade microSD and SD storage solutions, offering enhanced flexibility and security features specifically tailored for diverse industrial applications. It seamlessly integrates with systems up to the SD 7.1 interface and is fortified with the hyMap® firmware, providing a turnkey solution for high-endurance flash memory modules. Particularly suitable for applications requiring robust data protection and security, the S9 incorporates specialized security features, including secure erase and trim capabilities. It also supports firmware extensions via an API, allowing users to tailor the controller’s functions to meet specific security needs. Built to handle high-performance demands, the S9 ensures excellent endurance and reliability across various devices and systems. It is ideal for applications in sectors that require dependable storage and security, such as industrial automation, automotive systems, and other technology-heavy industries.
Supporting an impressive data rate, the GDDR7 PHY and Controller from InnoSilicon complies fully with JEDEC's latest standards. This advanced PHY embraces the 32Gbps PAM3 modulation scheme, allowing for a distribution of ten DQ signals and one DQE signal per data byte in the PAM3 mode. Additionally, the GDDR7 architecture supports the NRZ IO mode to enable efficient power operations. The PHY achieves remarkable speeds reaching up to 32Gbps, and the memory device interface can accommodate up to 128Gbps bandwidth, catering to the needs of high-end integrated circuits deployment. InnoSilicon ensures compatibility with the latest FinFET process nodes to deliver on high integration demands seen within high-end customer solutions.
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.
ResQuant's Cyclone V FPGA solution is a powerful tool in achieving quantum-safe security, coming pre-integrated with a complete suite of NIST post-quantum cryptography standards. This FPGA solution ensures seamless integration and widespread applicability, facilitating practical proof-of-concept testing for quantum-safe applications. Its vendor-independent design ensures flexibility and adaptability across various setups and environments. The Cyclone V FPGA with PQC Processor is tailored to support sectors that demand rigorous security, such as automotive, ICT, and military applications. It is optimized for real-world scenarios where quantum-resistance is paramount, providing enhanced security for critical data and operations. With its robust performance metrics and adaptability, the Cyclone V FPGA stands out as a pivotal component for organizations preparing for a quantum-resilient future. In addition to its technical capabilities, ResQuant offers comprehensive workshops that guide organizations through the nuances of quantum computing threats. These workshops provide actionable insights and strategies, ensuring that ResQuant's clients can confidently navigate and implement advanced cryptographic solutions required for a secure future.
NAND is a non-volatile memory type utilized in countless modern devices like flash drives, MP3 players, and digital cameras. Its inherent advantages, such as speed and robustness over hard disks, make it an attractive choice for portable electronics. This technology is not only more compact and power-efficient but can also be integrated into chips for streamlined incorporation into computers. Furthermore, NAND technology can be erased and rewritten multiple times while maintaining data storage capacity, making it indispensable for devices needing high capacity in small footprints.
The NVMe Host Controller from iWave Global offers an advanced solution for managing NVMe drive interfaces in computing systems. This controller is designed to facilitate the high-speed data exchange that NVMe drives demand, streamlining operations across data-centric applications. Engineered for scalability and performance, the NVMe Host Controller supports high data throughput, ensuring quick access and transfer of data between storage devices and host systems. Its design caters to the demands of modern computational environments where rapid data retrieval and storage are critical. The controller is integral in systems requiring high-performance storage solutions, and its support for multiple interfaces underscores its adaptability and broad applicability in data-intensive industries such as enterprise storage and high-performance computing.
The I-fuse® S3 further innovates on the core I-fuse platform with an architecture that allows for significant scaling and compacting capabilities. It shines when the memory density required is below 4Kbits, offering a top-notch solution for minimal size applications. Engineered to be compatible with several foundries without needing additional processing steps, it maintains its low programming voltage and silicon-proven reliability, achieving AEC-Q100 Grade 0. Its ability to adapt to various foundries and process nodes ensures a broad applicability, from consumer electronics to automotive systems.
PRSsemicon's Flash Solutions encompass a wide array of storage interface technologies designed to meet modern data handling demands. These solutions include UFS devices and hosts compatible with the latest specs, alongside advanced configurations for eMMC, SDIO, SPI, and serial flash technologies. The lineup ensures superior performance and reliability across various applications, enhancing memory efficiency and access speeds crucial for enterprise and consumer storage environments.
Attopsemi's OTP IP is designed to be a high-performance, reliable solution for embedded memory, tackling the needs of modern electronic designs with high reliability and minimal footprint requirements. The technology integrates seamlessly into a wide range of devices, from consumer electronics to sophisticated automotive applications, supporting extensive testability and delivering high-speed operations. Its architecture is frequently updated to meet evolving standards, ensuring robust protection against environmental stresses and extending product life spans.
Designed for managing data in CompactFlash and Parallel ATA environments, the F9 CF PATA Controller offers high reliability and endurance for industrial applications. This controller employs advanced flash management techniques like hyReliability™ for wear leveling and power fail management, ensuring robustness in demanding environments. The F9 is equipped with a flexible BCH ECC engine capable of 96-Bit/1K corrections, delivering support for all major flash memory types while maintaining long-term availability. Its design includes a 32-bit RISC core which enhances instruction handling for flash operations, optimizing overall performance. With a comprehensive set of features such as AES encryption support and the ability to include custom firmware enhancements, the F9 enables customization to specific customer needs. This makes it a versatile choice for legacy systems requiring enhanced data processing and storage resilience.
Eureka Technology's NAND Flash Memory Controller is integral for managing NAND flash memory operations, offering efficient handling of read, write, and erase functions. This controller is pivotal for applications needing reliable and robust data storage solutions, from mobile devices to enterprise servers. The controller is designed to optimize flash memory cycles, extending the lifespan of storage components. It incorporates sophisticated algorithms for error correction and wear leveling, ensuring data integrity and prolonging device endurance even in heavily-used environments. Compatible with various NAND flash configurations, this controller offers flexible interface options, adapting to specific application requirements. Its architecture supports scalability and future-proofing, allowing integration into both current and next-generation products with ease.
The Embedded ReRAM technology by Weebit Nano is an innovative non-volatile memory solution tailored for embedding into various electronic systems. Known for its fast speed and low power requirements, this ReRAM module is seamlessly integrable into a wide range of applications, from IoT devices to automotive electronics. Its compact design allows for high-density memory storage, making it an excellent choice for devices where space and power efficiency are critical. This technology is built to withstand extreme conditions, offering reliable performance for automotive and aerospace domains where high temperatures and environmental variability are a given. With its capability to maintain data integrity without a power source, the embedded ReRAM module suits applications requiring persistent data storage. With Weebit's focus on scalability, the embedded ReRAM can be customized to meet specific design requirements across various semiconductor processes, ensuring that manufacturers can leverage this technology across different platforms. Its modular nature and solid performance profile make it a strategic tool for creating next-gen smart devices.
CrossBar's ReRAM IP Cores focused on High-Density Data Storage offer a breakthrough in managing extensive data volumes within compact integrated circuits. Designed for high scalability and integration, these cores utilize ReRAM technology to provide unparalleled storage density, making them suitable for systems where storing large amounts of data efficiently is critical. These cores leverage the unique 3D stackable and energy-efficient properties of ReRAM, allowing them to provide terabytes of storage on minimal footprint, which is essential for applications in data centers and advanced computing. Their robust architecture ensures superior performance, maintaining rapid access speeds and low latency, which are vital for today’s high-performance systems. Moreover, the scalability of ReRAM technology incorporated in these IP cores aids in reducing overall system cost and complexity, while simultaneously enhancing capacity. This makes them ideal for enterprise-level storage solutions and applications requiring rapid, reliable access to extensive datasets. CrossBar's ReRAM IP Cores for High-Density Storage thus represent a significant advancement in data management technology, offering a practical solution for industries in need of high-capacity, energy-efficient storage options. By deploying these cores, companies can leverage superior memory performance and adaptability, keeping pace with the rapid expansion of data-driven applications globally.
The BCH Encoder and Decoder from IPrium is optimized for use with NAND Flash memory, providing reliable error correction capabilities. This IP core is designed to handle the complexities of high-speed data transmission, ensuring data integrity through its robust error-detecting and correcting features. Its implementation supports different configurations depending on the memory density and performance requirements, making it a versatile choice for a wide range of applications. Engineered to maximize system reliability, the BCH Encoder and Decoder is equipped to manage error correction in challenging environments. It employs a sophisticated algorithm to detect errors in data blocks and perform necessary corrections without significantly impacting data throughput. The IP core's adaptability allows it to be tailored for specific applications, offering customizability to suit unique operational needs. This IP core is also beneficial in enhancing the lifespan of NAND Flash by mitigating bit errors that can accumulate during continuous usage. By incorporating IPrium's BCH Encoder and Decoder, manufacturers can improve the durability and reliability of their memory products, leading to enhanced user confidence and product longevity. Its robust error correction capability makes it an indispensable component in memory-intensive and data-critical applications.
CrossBar's ReRAM IP Cores specifically tailored for Embedded Non-Volatile Memory (NVM) applications in Microcontroller Units (MCUs) and Systems-on-Chip (SoCs) offer a next-generation solution for memory integration. Designed for high adaptability, these IP cores leverage the inherent benefits of ReRAM technology to enhance system performance and efficiency significantly. They provide robust support for embedding secure and reliable memory functionalities in complex integrated circuits. These IP cores allow for a reduction in chip area and manufacturing costs, as the inherent scalability and stackability of ReRAM enable high-density memory storage on a minimal footprint. This makes them an ideal choice for embedded systems requiring secure, high-speed, and efficient data storage solutions. ReRAM IP Cores for Embedded NVM are also designed to be highly compatible with existing fabrication processes, making their adoption relatively straightforward for industry partners looking to upscale their system capabilities without substantial redesign. As a non-volatile memory solution, they excel in low power consumption and endurance, thereby supporting a wide range of applications from automotive to consumer electronics and smart devices. Through seamless integration and superior performance features, CrossBar's ReRAM IP Cores cater to the growing need for compact and durable embedded memory solutions. By offering a reliable and powerful alternative to traditional NVM solutions, they significantly enhance the functionality and lifecycle of modern integrated systems.
CrossBar's ReRAM integrated as FTP (Few-Time Programmable) and OTP (One-Time Programmable) Memory solutions represent a flexible and secure alternative for memory applications demanding configurability and permanence. This integration employs the ReRAM’s intrinsic properties to deliver robust performance and flexibility for varied programming needs. As a non-volatile memory, ReRAM FTP/OTP excels in energy efficiency, ensuring consistent performance across multiple write and read cycles. The adoption of FTP and OTP memory configurations is ideal for applications in fields such as security, IoT, and automotive where durability and reliability of stored data are paramount. By utilizing a simple memory cell structure, these configurations can be compactly designed to fit within minimal space while delivering high memory density and programming flexibility. Moreover, the capability to integrate both FTP and OTP configurations in a single memory solution offers versatility for developers needing the dual benefits of multi-use programmability and secure, single-use data setting. This combination enhances the overall utility of ReRAM in scenarios where data integrity and low power usage are essential. CrossBar's ReRAM solutions as FTP and OTP memory stand at the forefront of innovation, offering a new horizon for manufacturers seeking to advance their memory technologies. Through their adaptable nature, they support a broad spectrum of industrial applications, leveraging ReRAM's core attributes to maximize memory efficacy and reliability.
NeoFuse offers an innovative approach to anti-fuse technology in OTP applications, designed to meet the demands of advanced and more-than-Moore technology nodes. As a silicon IP solution, NeoFuse emphasizes robust security and outstanding yield, being particularly effective in the context of secure data storage and handling. This technology provides secure memory storage by utilizing an anti-fuse mechanism that guarantees data integrity and longevity. It is ideal for applications that require stringent security measures, such as data encryption and key management systems. NeoFuse's versatility allows it to be deployed in diverse technology environments, ensuring compatibility across a host of applications. Engineered with a focus on advanced automotive and communication markets, NeoFuse IP solutions prioritize both performance and security. It supports a range of electronic systems and paves the way for manufacturers to develop products that are not only secure but also future-ready, meeting the evolving needs of the modern market.
HermesCORE HBM3 Controller IP is crafted for applications that necessitate high memory bandwidth and low latency, such as graphics and data-heavy computing. Fully compliant with JEDEC standards, it handles complex memory management tasks, ensuring efficient operation and high data throughput in advanced computing environments.
NeoEE is an advanced, multi-time programmable embedded EEPROM solution, developed by eMemory for applications requiring reliable data storage over many cycles. Known for its low implementation cost combined with high endurance, NeoEE is a preferred choice in areas that demand extensive programming capabilities. This technology supports up to 500,000 program and erase cycles, making it highly suitable for industries that value both performance consistency and longevity, such as automotive electronics and industrial control systems. Its minimalistic single-poly architecture ensures that users benefit from enhanced space and cost efficiency. NeoEE’s capacity to provide consistent data writes and erase functions over its lifespan, even under rigorous operational conditions, makes it indispensable for mission-critical applications. It delivers impressive reliability and supports varied process nodes, affirming its utility in modern semiconductor manufacturing.
NeoFlash is an embedded non-volatile memory device offering developers over 100K program/erase cycles, tailored for high-performance applications that require substantial data retention capacity. Designed for robust operation, NeoFlash ensures secure and reliable non-volatile storage, making it suitable for a wide array of applications including consumer electronics and communication systems. This OTP technology excels in environments where endurance and fast access are paramount. The flexibility it offers allows for customization based on density requirements specified by the customer, ensuring it meets a wide variety of application demands. NeoFlash’s dynamic architecture supports multiple interfacing options, enhancing its usability in complex system configurations. Ideal for large-scale data storage needs, NeoFlash maintains data integrity, adapting easily to evolving technological demands and promoting longevity and resilience in product designs.
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