All IPs > Memory & Logic Library > Embedded Memories
Embedded memories play a crucial role in the architecture of modern electronic devices, offering storage and retrieval capabilities that are integral to processor function and data management. In Silicon Hub's Memory & Logic Library, the Embedded Memories category encompasses a wide variety of semiconductor IPs designed to meet these needs in diverse applications, from consumer electronics to industrial systems.
The primary function of embedded memories is to store and manage data internally within a device, which is essential for efficient processing and quick data access. These semiconductor IPs are typically integrated within a system on chip (SoC) to optimize performance and minimize latency compared to off-chip memory solutions. This integration helps improve overall device performance, reduce power consumption, and enhance the speed of data processing.
Common types of embedded memories available in this category include SRAM (Static Random Access Memory), DRAM (Dynamic Random Access Memory), MRAM (Magnetic Random Access Memory), and non-volatile memory types like Flash and EEPROM. Each type offers distinct advantages, such as high speed in SRAM, lower power consumption in DRAM, or the ability to retain data without power in non-volatile memories. These memory IPs are utilized in a plethora of products from smartphones and tablets to automotive systems and IoT devices, where compact, reliable, and efficient memory solutions are paramount.
Developers seeking to enhance computational efficiency and data handling capabilities in their designs will find this category indispensable. By choosing the right embedded memory IP from our Memory & Logic Library, manufacturers can create products that meet the demanding requirements of modern applications, ensuring reliability and excellent performance in a competitive market.
Nantero's NRAM Technology represents a groundbreaking shift in memory innovation, aimed at redefining performance expectations in electronics. Known for its ultrafast read and write speeds comparable to DRAM, yet nonvolatile like Flash, NRAM presents a unique advantage in the memory landscape. It achieves these feats while employing a simple structure that is conducive to 3D multilayering, promising extreme scalability in future applications. One of its flagship features is its environmental resilience, boasting the ability to withstand harsh conditions including temperatures up to 300°C, magnetic fields, and radiation. This makes NRAM highly suitable for applications in critical infrastructures, such as national electrical grids, where reliability is paramount. Beyond its robustness, NRAM is designed to have exceptionally low power consumption, operating with virtually zero standby power and eliminating the need for refresh or precharge cycles. As a future-ready technology, NRAM has immense potential for scalability below 5nm, setting the stage for eliminating older storage forms like SSDs and hard drives. Its high endurance capabilities ensure it performs an order of magnitude more cycles than traditional flash, making it not just an efficient choice, but a sustainable one, aligning with green technology goals. This pioneering technology redefines what is possible in memory solutions, paving the way for future innovations in electronic and industrial technologies.
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 YouDDR technology offered by Brite Semiconductor encompasses not just DDR controllers and PHY, but also I/O features and specialized software designed for tuning and testing. This forms a comprehensive subsystem delivering efficient data handling with robust performance for high-speed applications.<br><br>Designed with versatility, YouDDR is adaptable to cater to varied DDR technology demands, ensuring seamless integration in diverse electronic environments. Whether in consumer electronics or high-speed computing systems, it enables precise control and optimal function.<br><br>With additional tuning and testing software, the YouDDR system is engineered to maintain performance integrity across extensive operational ranges. It represents a complete solution, addressing every aspect from control to interface and verification.
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 Titanium Ti375 FPGA presents an advanced solution ideal for developers seeking high-density, low-power configurations. Within its design is Efinix's Quantum compute fabric, which offers superior computational efficiency bundled with a robust I/O interface. Highlighting its versatility, the Ti375 incorporates a hardened RISC-V block, facilitating complex data processing tasks without confining power usage. Additionally, features such as a SerDes transceiver and LPDDR4 DRAM controller mark it as a powerful asset in high-demand environments, ensuring smooth and reliable data transactions. Further empowering its capability is an integrated MIPI D-PHY, making it particularly well-suited for modern applications demanding high-speed data exchange and connectivity.
The AndeShape Platforms are designed to streamline system development by providing a diverse suite of IP solutions for SoC architecture. These platforms encompass a variety of product categories, including the AE210P for microcontroller applications, AE300 and AE350 AXI fabric packages for scalable SoCs, and AE250 AHB platform IP. These solutions facilitate efficient system integration with Andes processors. Furthermore, AndeShape offers a sophisticated range of development platforms and debugging tools, such as ADP-XC7K160/410, which reinforce the system design and verification processes, providing a comprehensive environment for the innovative realization of IoT and other embedded applications.
Topaz FPGAs are engineered to be a go-to solution for industries requiring a swift scale-up to volume production without compromising on performance or efficiency. Centered around an efficient architectural framework, these FPGAs deliver the power and functionality needed to address mainstream applications. They are renowned for their innovative fabric, which optimizes both die area and performance metrics. As such, Topaz FPGAs are indispensable for projects ranging from consumer electronics to automotive solutions, ensuring adaptability and scalability along evolving technological paths. Furthermore, with their seamless system integration capability, these FPGAs significantly shorten the development cycle, facilitating a faster go-to-market strategy while maintaining the high standards Efinix is known for.
The AHB-Lite Memory module from Roa Logic is a sophisticated, fully parameterized memory solution for systems deploying the AHB-Lite protocol. This IP provides on-chip memory capabilities to AHB-Lite based master devices, ensuring seamless and rapid data access. Its parameterized nature allows for a high degree of customization, enabling it to cater to a broad spectrum of design needs and application requirements. With the AHB-Lite Memory module, system architects can efficiently integrate memory resources within their designs, enhancing both speed and accessibility. The memory is designed to handle high-speed transactions, ensuring that performance remains consistent even in demanding situations, which is critical for applications requiring fast memory transactions. Roa Logic supports the integration of the memory module with comprehensive documentation and testbenches, facilitating smoother implementation into system architectures. By offering robust support, developers can ensure that their systems capitalize on the module's capabilities for optimized data handling and processing. The AHB-Lite Memory stands as a testament to Roa Logic's dedication to providing high-quality, adaptable memory solutions for complex digital environments.
TwinBit Gen-1 represents an advanced non-volatile memory solution that is embedded within logic-based semiconductor designs, adapting seamlessly to CMOS logic processes without necessitating additional masks or process steps. This IP supports a range of process nodes from 180nm to 55nm, demonstrating high endurance through over 10,000 program and erase cycles. The memory solution excels in flexibility and efficiency, providing a sizeable range of memory density from 64 bits to 512K bits. Particularly beneficial for applications like analog trimming, security key storage, and system switches for ASIC and ASSP, it helps reduce manufacturing costs while maintaining compatibility with modern semiconductors. TwinBit Gen-1's remarkable features also include low-voltage, low-power operations, complemented by an automotive grade under AEC-Q100 conditions. Additionally, this technology's built-in test circuits streamline stress-free test environments, ensuring its integration doesn't hamper production. Compared to other technologies such as eFuses, TwinBit Gen-1 saves silicon area and simplifies test procedures without sacrificing operational capacity. Its design is particularly poised for embedded applications needing secure reprogrammable memory.
Certus Semiconductor's Digital I/O solutions are engineered to meet various GPIO/ODIO standards. These versatile libraries offer support for standards such as I2C, I3C, SPI, JEDEC CMOS, and more. Designed to withstand extreme conditions, these I/Os incorporate features like ultra-low power consumption, multiple drive strengths, and high levels of ESD protection. These attributes make them suitable for applications requiring resilient performance under harsh conditions. Certus Semiconductor’s offerings also include a variety of advanced features like RGMII-compliant IO cells, offering flexibility for different project needs.
CodaCache optimizes system-on-chip (SoC) performance by reducing memory latency with its highly configurable shared cache. By enhancing data flow and improving power efficiency, CodaCache provides a notable advantage in handling the key challenges of SoC design such as performance, data access, and layout congestion. The product is engineered to support seamless integration and maximize the design's efficiency and throughput.
The LEE Flash G1 represents a cost-effective SONOS flash memory solution, offering high reliability through its unique charge retention mechanism which mitigates the risks associated with leaking charges. This IP is built on a robust framework that enhances endurance and stability even after substantial use cycles. The G1 architecture is optimized for ease of integration into existing manufacturing processes, using common materials to ensure compatibility and ease of scalability across a range of applications. This promotes short testing times and contributes to reduced overall production costs. In terms of functionality, the LEE Flash G1 utilizes Fowler-Nordheim tunneling for programming and erasure, a technique that ensures low power consumption and minimal oxide damage, thereby extending the life and reliability of the memory cells. It is designed for applications requiring embedded memory solutions with a focus on efficiency in data processing power and operational stability. Floadia's G1 flash memory is particularly adept at maintaining a stable threshold voltage (Vt) distribution, which enhances its performance under repeated use conditions. The strategic design and robust characteristics of the G1 make it a suitable choice for a wide array of electronics that demand durable and efficient storage capabilities. By ensuring minimal processing overhead and maximizing the potential for integration, the G1 stands as a testament to Floadia's commitment to pioneering durable and cost-effective memory solutions.
Secure OTP by PUFsecurity offers the next generation in secure storage solutions within semiconductor devices. It builds on standard OTP technology by providing enhanced protection mechanisms for key and data storage. Combining physical macro components with digital RTL, Secure OTP offers comprehensive security for data at rest, in use, and during transit. This level of protection is imperative for today’s connected environments, where devices often face sophisticated hardware attacks. One critical aspect of Secure OTP is its ability to integrate seamlessly within a range of IC applications, supporting various interface controllers (I/F) for easy deployment. This integration ensures that sensitive data such as boot codes and cryptographic keys get the robust protection they need, preventing unauthorized access and possible exploitation. With an anti-tamper shell as part of its design, Secure OTP stands as a resilient guardian against attempts to extract or modify data illegitimately. As the security landscape evolves, Secure OTP acts as a pivotal element in transitioning from outdated e-fuse solutions to more impregnable storage systems. This IP essentially forms a crucial part of the defense-in-depth strategy, underpinning secure operations in IoT developments and beyond. Designed to withstand the increasingly rigorous demands of modern security standards, Secure OTP ensures that data integrity and confidentiality are preserved throughout the life cycle of electronic products.
Trion FPGAs by Efinix cater specifically to the edge computing and Internet of Things (IoT) market. These versatile FPGAs are designed with a flexible architecture that serves a wide range of logic applications, making them an excellent choice for general-purpose computing needs. With support for applications demanding both high performance and low power, Trion FPGAs provide an ideal environment for innovative designs that push the boundaries of IoT technology. Designed to integrate seamlessly within existing systems, they're ideal for applications needing agile solutions capable of processing at the network's edge, bringing new capabilities to IoT deployments and smart technology installations. From 4K to 120K logic elements, Trion offers scalable solutions to cater to varied project needs, empowering designers to tailor solutions specifically for their unique requirements.
PermSRAM is a versatile non-volatile memory solution integrated into foundry standard CMOS platforms accommodating process nodes from 180nm to 22nm and beyond. This memory technology offers various functionalities, such as one-time programmable ROM and pseudo multi-time PROM, which feature a multi-page configuration spread across memory sizes from 64 bits to 512K bits. A notable aspect of PermSRAM is its non-rewritable hardware safety lock that ensures the secure storage of critical security codes. In addition to its security features, PermSRAM delivers high reliability and a stable yield, making it suitable for automotive applications that require data retention at temperatures exceeding 150 degrees Celsius. This memory type is designed for seamless integration with existing system infrastructures as it doesn't need additional read operation circuitry like charge pumps. Its built-in self-test circuit is pivotal for supporting stress-free testing environments, ensuring ease of implementation in various applications like DRM and HDMI decoding, security code storage, and program storage. The benefits of PermSRAM extend to a smaller silicon footprint, achieved through a tamper-resistant design mechanism that uses an invisible charge trap memory system. This compactness is complemented by a fully testable architecture using conventional equipment. PermSRAM beams with capabilities that cater significantly to secure and reliable memory demands, whether for market differentiation or meeting stringent automotive standards.
CrossBar's ReRAM technology offers a revolutionary approach to data storage and processing. This memory technology leverages a simplistic yet powerful structure that employs a top electrode, a switching medium, and a bottom electrode. Upon applying voltage across these electrodes, a filament forms within the switching material, allowing data to be stored in a stable, efficient manner. ReRAM's capability to withstand extreme temperature fluctuations, its impressive cycle endurance, and its data retention over years make it ideal for various robust applications. What sets ReRAM apart is its ability to integrate directly with CMOS processing, facilitating seamless adoption across various semiconductor processes. Its potential to form dense 3D structures for massive data storage on a single chip offers significant advantages in terms of space and power efficiency. The simple device structure allows for incredible simplicity in its integration, providing a scalable memory solution that enhances performance and reduces energy consumption. Additionally, the technology's versatility allows it to serve multiple non-volatile memory functions, including as few-time or one-time programmable (FTP/OTP) memory. It's particularly well-suited for security applications, using its physical structure for the generation of securely encrypted keys within devices. The potential applications for ReRAM span from consumer electronics to highly secure computing systems, marking a new era in memory technology.
SmartMem Subsystem is an adaptive memory management IP core that enhances power efficiency, performance, and endurance of MRAM-based memories, including third-party solutions. It offers a fully synthesizable and configurable approach, making it a versatile choice for high-volume deployments. SmartMem enhances the ease-of-use of various memory types including RRAM, PCRAM, and Flash, alongside the NuRAM lineup. This IP is engineered to boost performance by enabling SOC Compute in Memory capabilities, which are customizable to meet specific application needs, thereby supporting a broad array of applications and environments. As a comprehensive memory management solution, SmartMem IP core does more than enhance NuRAM performances by ensuring adaptability across different memory ecosystems, improving memory management in devices with various operational demands. Its inclusion of Compute in Memory options allows for significant improvements in application processing, serving as a key subsystem for next-gen SoCs, particularly in scenarios requiring superior performance and resilience. SmartMem's sophisticated features are designed to handle diverse application requirements from edge AI inference to demanding data center operations, positioning it as a strategic IP for current and future memory technology advancements.
The 16-bit Sigma-Delta ADC from Leo LSI is built on the advanced 55nm 2P7M SMIC CMOS technology, making it suitable for precision audio applications. It features a programmable gain of up to 50 dB, allowing fine-tuning for varied input densities. Supporting a conversion rate of 16KSPS, this ADC is optimized for mono audio inputs with fully differential configurations and boasts a power-efficient design ideal for mobile devices.
Floadia's LEE Flash G2 offers a groundbreaking approach beyond traditional flash memory technologies by serving as both a logic and non-volatile memory element. Its design integrates a SONOS transistor with additional switching transistors, facilitating direct interfacing between memory and logic circuits without isolation barriers. This integration significantly reduces power requirements and enhances circuit flexibility, allowing for innovative design approaches in silicon chip manufacturing. One of the hallmark features of the G2 is its use of a high-speed non-volatile SRAM (NV-SRAM), which drastically changes memory architecture by eliminating the need for separate flash memory sections and interconnection circuits. Data transfer between SRAM and flash is seamless, offering faster operational capabilities with reduced power consumption. This is achieved through the use of Fowler-Nordheim tunneling for efficient low-power operation during programming and erasure phases, ensuring the longevity and reliability of the memory storage. The G2 is particularly advantageous for microcontroller and SOC designs where non-volatile memory performance is critical. By supporting VDD level read operations, it simplifies power management while enhancing speed and reliability, contributing to improved system efficiencies and providing a flexible platform for various high-demand applications.
The LEE Flash ZT by Floadia introduces a zero additional mask multi-time programmable (MTP) flash memory solution, which focuses on reducing manufacturing complexity while enhancing flexibility and performance. This MTP technology employs a unique implementation that avoids the need for additional mask layers, thereby simplifying the fabrication process and cutting costs without compromising on memory capability or reliability. At the core of the ZT flash memory is the emphasis on efficiency in programming and data retention. The SONOS-based architecture of the ZT leverages a simpler process flow to achieve a balance between operational speed and durable memory performance. It uses a refined charge trapping mechanism to ensure stable data integrity over extensive use and numerous programming cycles, rendering it ideal for dynamic and versatile use cases in various technology fields. This memory solution is particularly suited for applications that require repeated programming and erasure while maintaining low operational power parameters. The focus on eliminating unnecessary processing steps makes the LEE Flash ZT a compelling choice for advanced semiconductor applications seeking economic and efficient non-volatile memory systems.
Avant's DRAM Memory Modules are designed for a wide range of industrial applications, adhering to JEDEC standards to ensure compatibility and performance. These modules are particularly beneficial for sectors such as gaming, point-of-sale systems, kiosks, and medical and automation technologies. With various configurations available, including low voltage and high capacity options, Avant's DRAM modules offer flexibility to accommodate diverse technical requirements. Known for their reliability, these modules support different interfaces, ensuring adaptability in various operational environments.
Silvaco offers comprehensive Embedded Memory Compilers that cater to high-performance and power-efficient applications in the semiconductor industry. The suite includes compilers for SRAM, register files, and ROM, which are designed to operate efficiently across different power levels. These memory solutions help designers achieve the right balance between performance and power consumptions tailored for diverse process technologies. The memory compilers come with advanced power management features, making them ideal for low-power, low-leakage applications. They offer customization options with features like embedded power switches and support for Built-In Self Test (BIST) for reliability checks during manufacturing. Silvaco's architecture ensures data locality and optimal system performance, and their compilers support technologies like FDSOI and CMOS down to 3nm nodes. In addition, Silvaco's Embedded Memory Compilers are configured to support a wide voltage range, allowing for dynamic power and frequency adjustment. These compilers have been time-tested in a multitude of applications, providing designers with world-class support to integrate seamlessly into major EDA tool flows and enhancing the overall design environment with their versatile functionalities.
The Cyclone V FPGA is equipped with a pre-integrated PQC processor, featuring a comprehensive suite of NIST-approved post-quantum cryptography algorithms. Designed for easy integration, it is tailored for proof-of-concept testing in various quantum-safe applications. This FPGA board, priced at $15,000, offers a viable solution for industries looking to trial and eventually implement quantum-resistant security measures.
The NuRAM Low Power Memory leverages cutting-edge patented memory technology based on MRAM. It offers a compelling alternative to traditional SRAM or nvRAM, boasting fast access times and significantly lower leakage power. Designed with industry-standard production processes, NuRAM excels in terms of power efficiency, providing an ideal solution for applications requiring considerable power savings and enhanced performance. The IP's low leakage power and compact cell area make it suitable for replacing older memory technologies in xPU or ASIC designs. Optimized for power-sensitive AI and edge computing, NuRAM serves as an efficient on-chip memory alternative to minimize DDR memory access and related power and latency issues. Additionally, its ability to power down completely without losing data highlights its suitability for various stand-by operations.
Built using 65nm technology, this ADC delivers high accuracy with a 12-bit resolution offering conversion rates from 0.1MSPS to 1MSPS. It operates efficiently with an analog supply voltage between 2.4V and 3.6V and a digital supply voltage ranging from 1.08V to 1.32V. Designed for low power applications, it is particularly suitable for wireless sensor networks and pressure sensors, ensuring reliability across diverse operational conditions.
The Non-Volatile Memory (NVM) Solutions provided by Tower Semiconductor are engineered to offer efficient data storage capabilities that maintain integrity even without power. These solutions are critical for applications where data persistence is paramount, such as in industrial automation and consumer electronics. NVM from Tower Semiconductor includes advanced memory technologies, such as EEPROM and flash memory, catering to different storage requirements. These technologies are designed for longevity and reliability, ensuring that data is consistently accessible and secure over extended periods and across various environmental conditions. Their incorporation of proprietary techniques enhances memory density and speed, addressing the needs of contemporary data-driven applications. NVM solutions from Tower Semiconductor are integral to systems requiring constant data availability, enabling efficient and durable memory management.
The SoC Platform by SEMIFIVE is designed to streamline the system-on-chip (SoC) development process, boasting rapid creation capabilities with minimal effort. Developed using silicon-proven IPs, the platform is attuned to specific domain applications and incorporates optimized design methodologies. This results in reduced costs, minimized risks, and faster design cycles. Fundamental features include a domain-specific architecture, pre-verified IP components, and hardware/software bring-up tools ready for activation, ensuring seamless integration and high performance. Distinct attributes of the SoC Platform involve leveraging a pre-configured and thoroughly validated IP pool. This preparation fosters swift adaptation to varying requirements and presents customers with rapid time-to-market opportunities. Additionally, users can benefit from a reduction in engineering risk, supported by silicon-proven elements integrated into the platform's design. Whether it's achieving lower development costs or maximizing component reusability, the platform ensures a comprehensive and tailored engagement model for diverse project needs. Capabilities such as dynamic configuration choices and integration of non-platform IPs further enhance flexibility, accommodating specialized customer requirements. Target applications range from AI inference systems and AIoT environments to high-performance computing (HPC) uses. By managing every aspect of the design and manufacturing lifecycle, the platform positions SEMIFIVE as a one-stop partner for achieving innovative semiconductor breakthrough.
EverOn represents sureCore's single port ultra-low voltage SRAM solution, meticulously designed for minimal power usage. Ensuring silicon-proven reliability on the 40ULP BULK CMOS process, EverOn extends its capabilities with a striking 80% reduction in dynamic power consumption and up to 75% less static power usage. This IP operates down to an unparalleled 0.6V, allowing for a wide range of applications, from IoT and AI-driven devices to advanced wearables that require longevity and efficiency. The architecture of EverOn enables it to support dynamic voltage and frequency scaling, achieving high performance at low operating voltages. This flexibility in voltages, coupled with a robust cycle time from 20MHz at 0.6V to over 300MHz at 1.21V, suits a range of cutting-edge applications. It features sureCore's "SMART-Assist" technology, which enhances operation even at retention voltages, ensuring the memory's resilience and adaptability. EverOn's design includes power-saving modes and the ability to partition memory into multiple banks, each supporting independent operations. This feature offers applications excellent system-level flexibility, catering to varied operational needs and prolonged battery lifespans. Each memory bank can maintain states like light sleep, deep sleep, or fully powered down as per requirement, marking EverOn as a key asset in the pursuit of energy-efficient technology solutions.
Analog Bits' I/O solutions offer highly efficient differential clocking and crystal oscillator IPs with customizable options for die-to-die connectivity. These technologies are optimized to utilize minimal transistors while ensuring the highest quality of signal transmission. Demonstrating proven silicon performance at 5nm and developments at 3nm, the company's I/O solutions are at the forefront of innovation, meeting high-volume production demands across top-tier fab facilities. These products are tailored to specifically address customer requirements, ensuring optimal operation with precision in signal integrity and low power usage, offering users flexibility in implementation across systems.
Designed for specialized memory applications, Spectral's CustomIP offers a diverse range of memory architectures, including Binary and Ternary CAMs, multi-ported memories, and more. These solutions emphasize high density and low dynamic power consumption, offering architectures tailored to networking, graphics, and consumer devices. With capabilities that include advanced compiler features and comprehensive integration views, CustomIP is ideal for differentiated ICs that demand unique memory solutions. Users benefit from a source code availability that facilitates modifications, enabling further technological customization.
Floadia's LEE Fuse ZA is designed as a zero additional mask anti-fuse one-time programmable (OTP) memory technology. It provides a high-efficiency solution for applications that require permanent data storage combined with robust security features. By employing an anti-fuse mechanism, the LEE Fuse ZA ensures that data once written cannot be altered, thereby providing a safeguard against unauthorized modifications or data corruption. This IP's architecture benefits from a streamlined manufacturing approach that reduces the complexity of integration into current processes, supporting cost-effective production. The anti-fuse technology used in the Fuse ZA offers high data integrity and resistive to electrical and environmental disturbances, ensuring reliable performance even under challenging conditions. The Fuse ZA's optimal design for seamless embedding in a variety of chip types makes it suitable for a wide-range of applications, particularly those where security and tamper-proof data are pivotal. Its easy integration and the return on investment provided through reduced production overhead and enhanced security make it an advantageous component in modern semiconductor solutions.
I-fuse is designed for seamless integration into standard semiconductor processes, distinguished by its non-explosive mechanism. This one-time programmable memory (OTP) stands out for not requiring special processes or charge pumps, offering ease of use and high reliability. Encapsulated within it is a patented technology that spans processes from 0.7 µm to 22 nm, ensuring flexibility across various manufacturing environments. This innovative solution emphasizes robustness, qualifying to AEC-Q100 standards and making it ideal for automotive, industrial, and medical applications. Its compact design doesn't compromise on performance, providing low programming voltage and low power consumption. I-fuse's adaptability across multiple temperature ranges makes it suitable for both high and low-temperature environments. Incorporating I-fuse into products enhances their competitive edge, thanks to the extensive reliability and testability aspects intrinsically built into the design. It allows seamless product evolution, promoting innovation without sacrificing dependability.
TwinBit Gen-2 enhances the prior version by supporting more advanced process nodes, spanning from 40nm to 22nm and adapted for further processes. It retains the simplicity of integration found in Gen-1, with no requirement for additional process steps, masks, or auxiliary charges despite its sophistication and efficiency enhancements. This memory technology leverages a newly developed Pch Schottky Non-Volatile Memory Cell that optimizes power consumption for ultra-low-power operations. The tech allows controlled hot carrier injection by cell bias during the program/erase cycle, ensuring the retention and reliability of data throughout its lifecycle. TwinBit Gen-2 thus guarantees a heightened level of operational efficiency for modern electronic devices. Suitable for various memory applications demanding high security and low energy consumption, TwinBit Gen-2 is a valuable asset in fields like IoT and other high-volume consumer electronics requiring reprogrammable memory infrastructure. By achieving this balance, TwinBit Gen-2 establishes itself as a leading non-volatile memory solution in the evolving semiconductor market.
GCRAM is a pioneering on-chip memory solution created by RAAAM Memory Technologies, specifically designed to deliver substantial improvements over traditional SRAM systems. It provides up to a 50% reduction in chip area and a tenfold increase in power efficiency, while remaining fully compatible with standard CMOS fabrication processes. This innovation provides a cost-effective approach to maintaining competitive performance and efficiency in devices necessitating large amounts of on-chip memory, such as AI and ML technologies. The robust architecture of GCRAM allows for easy integration as a drop-in replacement for existing SRAM in semiconductor designs. This makes it a versatile resource across multiple sectors, including automotive, 5G, and high-performance computing, which are experiencing exponential growth in on-chip memory demands. Additionally, by extending the viability of Moore's Law through efficient resource management, GCRAM consolidates significant cost savings while boosting operational efficiency. GCRAM is tailored to meet the evolving technological requirements driven by complex workloads. Its adaptability to growing demand is showcased through its application-specific design flexibility, allowing it to support single or two-ported architectures and extending standard interfaces while facilitating single-cycle operation. This makes GCRAM an exemplary choice for optimizing performance in modern computational tasks.
CrossBar's ReRAM IP Cores for Embedded NVM represent a leap forward in non-volatile memory technology for use in microcontrollers and System-on-Chip (SoC) devices. These IP cores are distinguished by their capacity for multi-time programming, making them a superb choice for applications where high-performance, low-latency memory is critical. The ReRAM technology meets the requirements for today's embedded systems by operating efficiently at advanced process nodes starting from 28nm down to below 10nm. The ReRAM IP Cores are known for their capability to handle large data storage and run efficient code execution while maintaining low energy consumption. This technology exceeds the performance of traditional flash memory, with superior endurance and retention capabilities, making it an excellent fit for demanding industrial, automotive, and high-frequency consumer electronics that call for reliable memory solutions. Furthermore, these cores are engineered to be robust, dealing efficiently with diverse environmental conditions, ensuring data integrity and security. The ReRAM's design also includes options for incorporating secure physical unclonable function (PUF) keys, further enhancing its suitability for secure computing applications. CrossBar's technology thus enables a new wave of intelligent, secure, and low-power electronic devices.
This 12-bit 1MSPS ADC leverages Samsung's 100nm LF6 CMOS technology, providing a wide operating range for diverse electronic applications. With conversion rates up to 1MHz at standard voltage levels (3.6V to 5.5V), it's designed for high performance in environments demanding consistent accuracy. The converter features a broad input range from analog ground to AVDD, accommodating varied design needs seamlessly.
Enclustra's Stream Buffer Controller facilitates efficient data management in FPGA systems through a versatile Stream to Memory Mapped DMA bridge. Supporting up to 16 streams, it enables virtual FIFO capabilities by utilizing external memory for data buffering. The IP core is configured via a memory mapped slave interface and operates with a variety of interfacing standards, making it suitable for high-performance data acquisition and image processing applications. Its adaptability across different operational modes ensures versatile implementation in data-driven environments.
The Vega eFPGA is a flexible programmable solution crafted to enhance SoC designs with substantial ease and efficiency. This IP is designed to offer multiple advantages such as increased performance, reduced costs, secure IP handling, and ease of integration. The Vega eFPGA boasts a versatile architecture allowing for tailored configurations to suit varying application requirements. This IP includes configurable tiles like CLB (Configurable Logic Blocks), BRAM (Block RAM), and DSP (Digital Signal Processing) units. The CLB part includes eight 6-input Lookup Tables that provide dual outputs, and also an optional configuration with a fast adder having a carry chain. The BRAM supports 36Kb dual-port memory and offers flexibility for different configurations, while the DSP component is designed for complex arithmetic functions with its 18x20 multipliers and a wide 64-bit accumulator. Focused on allowing easy system design and acceleration, Vega eFPGA ensures seamless integration and verification into any SoC design. It is backed by a robust EDA toolset and features that allow significant customization, making it adaptable to any semiconductor fabrication process. This flexibility and technological robustness places the Vega eFPGA as a standout choice for developing innovative and complex programmable logic solutions.
The AON1100 is a leading AI chip built for efficient voice and sensor processing tasks, offering exceptional performance with under 260μW power usage. It achieves a 90% accuracy level even in sub-zero decibel noise environments. Ideal for devices that require continuous sensory input without significant power drain, it is designed to function seamlessly in demanding acoustic environments, optimizing both performance and power.
Designed for both voice recognition and sensor applications, the AON1020 integrates the AONSens Neural Network cores. It features capabilities such as multi-wake-word detection, context awareness, and sensor applications including human activity detection. Delivered in Verilog RTL, it is well-suited for ASIC and FPGA implementations, providing exceptionally low-power operation ideal for always-on listening scenarios. It delivers highly accurate performance amid noisy conditions, making it a comprehensive solution for various sensor-driven applications.
Spectral's MemoryIP suite provides a range of high-density and low-power static random access memories optimized for embedded applications. The library includes six major compiler architectures such as single and dual-port SRAMs, offering efficient designs suitable for various use cases. These architectures harness high-density bit cells and optimized circuitry for enhanced performance, delivering high-speed operation while minimizing power usage. Additionally, the MemoryIP integrates seamlessly into standard CMOS process technologies, providing flexibility and customization options to developers.
The TSP1 Neural Network Accelerator is a state-of-the-art AI chip designed for versatile applications across various industries, including voice interfaces, biomedical monitoring, and industrial IoT. Engineered for efficiency, the TSP1 handles complex workloads with minimal power usage, making it ideal for battery-powered devices. This AI chip is capable of advanced bio-signal classification and natural voice interface integration, providing self-contained processing for numerous sensor signal applications. A notable feature is its high-efficiency neural network processing element fabric, which empowers signal pattern recognition and other neural network tasks, thereby reducing power, cost, and latency. The TSP1 supports powerful AI inference processes with low latency, enabling real-time applications like full vocabulary speech recognition and keyword spotting with minimal energy consumption. It's equipped with multiple interfaces for seamless integration and offers robust on-chip storage for secure network and firmware management. The chip is available in various packaging options to suit different application requirements.
Designed at 55nm, this 8-channel 12-bit ADC offers a range of 0.1MSPS to 1MSPS, optimized for applications requiring low power consumption and minimal size. With an analog power supply range of 2.4V to 3.6V and a digital power supply range from 1.08V to 1.32V, it efficiently manages power resources while maintaining superior resolution and accuracy. Ideal for battery-powered systems and data acquisition solutions.
The High-Speed Low-Power SRAM from Xenergic is engineered to achieve an ideal balance between power consumption and performance efficiency. With significant reductions in dynamic power and leakage, reaching reductions up to 40% and 55% respectively, this SRAM is a versatile solution for diverse applications. Designed to address the power constraints in edge computing, it supports optimal speeds bringing computation close to the edge, proving particularly advantageous for IoT and always-on devices. This innovative SRAM helps extend device battery life by minimizing the power footprint within SoCs for products such as sensors and wearables. It's particularly suitable for applications that require low power use over extended periods, making it a pivotal component in modern mobile and IoT devices. Additionally, its architecture supports significant retention leakage reductions, ensuring it does not inadvertently become a key power consumer in various electronic designs. Xenergic’s High-Speed Low-Power SRAM ensures that developers can meet their stringent power requirements without compromising on speed or area, rendering it an essential component for edge computing and IoT development. The memory architecture facilitates seamless integration within existing design flows and dynamically addresses the power and performance needs of any given application.
NeoPUF technology harnesses the unpredictability and uniqueness of physical variations formed during chip manufacturing to create a highly secure root of trust. This technology is crucial in providing secure keys and authentication for applications needing strong security frameworks, such as IoT and mobile communications. NeoPUF's ability to generate cryptographic keys without storing them aims to protect data from unauthorized access and cloning, making it highly valuable for devices requiring elevated security standards.
Everspin's xSPI products are transforming memory solutions with their industrial STT MRAM, compliant with the latest JEDEC standards. The xSPI family introduces a high-performance, multi-I/O interface equipped for SPI compatibility, designed to operate with a 1.8V power supply, facilitating up to 400MBps read and write speeds. This versatility positions it as an ideal replacement for existing devices like SRAM, NOR, and NVSRAM, with applications spanning Industrial Automation, Process Control, and more. Featuring both Octal and Quad interface options, xSPI devices provide expansive capacities ranging from 4Mb to 128Mb, catering to diverse memory demands within the IoT and other embedded systems. This expanded SPI standard ensures higher data transfer rates, supporting rapid industrial growth. Configurations include advanced evaluation boards compatible with multiple FPGA systems, simplifying integration and performance testing for developers. The products are not just known for their speed and reliability but also for their ability to handle versatile computing conditions efficiently.
The AON1000 is a cutting-edge AI processing engine that excels in wake word detection, voice commands, acoustic event detection, and speaker identification, specifically designed for low-power, high-accuracy operations. It boasts superior performance in noisy surroundings by using proprietary neural network architectures and inference algorithms. This IP can be deployed within standalone chips or integrated into sensors like microphones. Its ultra-low power design allows other processors to remain in idle mode during always-on listening states, optimizing power consumption without compromising accuracy.
Designed to optimize performance, power, area, and reliability, Aragio's GPIO solutions offer a comprehensive range of general-purpose I/Os suited for integrated circuit design. These circuits are equipped with a complete set of power pads, corner and spacer pad cells, and breakers, ensuring a seamless implementation in varying design contexts. With specific considerations for power supply sequencing, these IPs utilize Distributed Power-on-Control (POC) during the power-up and power-down phases of systems. Their adaptable voltage range enables versatility across different system requirements, and they support the creation of isolated power domains to enhance design flexibility. This suite offers programmable GPIO and fault-tolerant configurations, ensuring robust input-output interfacing. Alongside this, support for isolated analog power supplies and a full complement of pads are provided, facilitating a wide range of electronic applications. The recommended operational conditions cover diverse voltage scenarios and operating temperatures, making these solutions viable for rigorous application environments. Moreover, the broad foundry support ensures that Aragio's GPIO solutions can be implemented across various manufacturing technologies, ranging from older nodes like 130nm to cutting-edge nodes like 7nm, thereby reaffirming the adaptability and long-term applicability of these IPs.
The Trifecta-SSD-RAID is a modular, high-performance storage solution optimized for PXIe/CPCIe-based systems engaged in wideband, high-speed RF and Microwave data applications. Its design accommodating eight M.2 NVMe SSDs in a single slot, Trifecta-SSD-RAID provides important enhancements in capacity and performance over traditional single-slot SSD modules. Trifecta-SSD-RAID supports storage capacities ranging from 8TB to 64TB per slot, offering substantial improvements, particularly in systems using data-intensive RF recording, playback, and analysis. With a PCIe Gen 3 x8 interface and a unique architecture, it delivers up to ~7 GB/Sec of sustained, sequential read/write performance. This capability avoids the hiccups or glitches noted in other RAID modules limited by only four SSDs. Designed to comply with essential industry standards, including RoHS, FCC Class A, CE, and MIL-PRF-28800F, it extends support for 64-bit Windows and select Linux environments, ensuring maximum compatibility and performance. The Trifecta-SSD-RAID solution effectively serves as a cost-effective storage alternative, offering high capacity, best-in-class performance, and affordability in price-per-terabyte.
OPENEDGES’ DDR Memory Controller is designed to efficiently manage data flow between processors and memory, ensuring high-speed and low-latency access in advanced computing environments. This IP offers a wide range of functionalities to accommodate the demands of modern applications, providing enhanced bandwidth while minimizing power usage. The controller enhances memory access times and optimizes resource sharing, making it suitable for applications requiring robust data processing capabilities such as graphic-intensive applications, AI systems, and network infrastructure. With flexible memory configurations, it provides substantial improvements in data throughput and system performance. Additionally, the DDR Memory Controller is built to seamlessly integrate with DDR PHY, allowing for a complete memory subsystem solution that offers unparalleled efficiency and reliability. Its design supports varying memory standards and is tailored to address specific application needs, thereby ensuring scalable and adaptable memory management solutions.
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