All IPs > Memory & Logic Library
The Memory & Logic Library category in our semiconductor IP catalog offers a comprehensive range of intellectual property that is essential for creating efficient and high-performance semiconductor solutions. This category is pivotal for designers who require reliable and optimized components to be integrated into a wide array of electronic products.
Key offerings within this category include Embedded Memories, I/O Libraries, and Standard Cells, each playing a critical role in the functionality of integrated circuits (ICs). Embedded Memories are vital for storing data within semiconductor chips, ranging from simple storage solutions to complex memory architectures that support high-speed operations. These are used in everything from microcontrollers for consumer electronics to high-end processors for enterprise-grade applications.
I/O Libraries, on the other hand, provide the necessary interface between the semiconductor device and the outside world. They encompass a wide variety of input/output configurations and technologies, ensuring efficient communication and data transfer is maintained across the chip's interfaces.
Finally, Standard Cells form the building blocks of digital circuits. They provide pre-designed, pre-verified logic functions that simplify the design process, increase reliability, and reduce time to market. Standard cells are integral in the design of ASICs (Application-Specific Integrated Circuits) and other custom logic devices. Our Memory & Logic Library category thus enables semiconductor engineers to access a diverse set of IPs crucial for modern electronics design and innovation.
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 xcore.ai platform by XMOS is a versatile, high-performance microcontroller designed for the integration of AI, DSP, and real-time I/O processing. Focusing on bringing intelligence to the edge, this platform facilitates the construction of entire DSP systems using software without the need for multiple discrete chips. Its architecture is optimized for low-latency operation, making it suitable for diverse applications from consumer electronics to industrial automation. This platform offers a robust set of features conducive to sophisticated computational tasks, including support for AI workloads and enhanced control logic. The xcore.ai platform streamlines development processes by providing a cohesive environment that blends DSP capabilities with AI processing, enabling developers to realize complex applications with greater efficiency. By doing so, it reduces the complexity typically associated with chip integration in advanced systems. Designed for flexibility, xcore.ai supports a wide array of applications across various markets. Its ability to handle audio, voice, and general-purpose processing makes it an essential building block for smart consumer devices, industrial control systems, and AI-powered solutions. Coupled with comprehensive software support and development tools, the xcore.ai ensures a seamless integration path for developers aiming to push the boundaries of AI-enabled technologies.
The A25 processor model is a versatile CPU suitable for a variety of embedded applications. With its 5-stage pipeline and 32/64-bit architecture, it delivers high performance even with a low gate count, which translates to efficiency in power-sensitive environments. The A25 is equipped with Andes Custom Extensions that enable tailored instruction sets for specific application accelerations. Supporting robust high-frequency operations, this model shines in its ability to manage data prefetching and cache coherence in multicore setups, making it adept at handling complex processing tasks within constrained spaces.
The 16-bit Sigma-Delta ADC achieves a conversion rate of 16KSPS, leveraging SMIC's 55nm 2P7M CMOS technology. It incorporates a programmable gain feature ranging from 0 to 50dB alongside a configurable microphone bias. Supporting both mono audio input and four channels of fully differential inputs, this ADC delivers precise analog signal conversion. Boasting high signal quality verified by a signal-to-noise ratio (SNR) of 90dB, this component is optimized for applications within the audio domain, ensuring high fidelity and low power operation, ideal for compact audio processing solutions.
Dolphin Technology provides an extensive range of standard cell libraries that are critical for any SoC design project. These libraries include over 5,000 fully customizable cells, each precisely crafted to optimize speed, power, density, and routability. The standard cells are verified in silicon and designed for use across various process technologies, making them an ideal choice for a wide range of applications. The standard cell libraries support various process nodes such as 6-track, 7-track, and up to 14-track configurations, suitable for everything from high-performance to ultra-high density applications. Dolphin Technology’s standard cell IP offerings include Multi-VT (SVT, HVT, LVT) and multi-channel options, enabling flexibility in design to accommodate the specific needs of semiconductor projects. These cell libraries are tailored to support high-performance computing, provide efficiency in wafer yield, and ensure optimal SoC pricing. This high degree of customization, coupled with a focus on power and density, offers excellent options for semiconductor professionals aiming to create high-performance designs efficiently and cost-effectively.
CrossBar's ReRAM Memory brings a revolutionary shift in the non-volatile memory sector, designed with a straightforward yet efficient three-layer structure. Comprising a top electrode, a switching medium, and a bottom electrode, ReRAM holds vast potential as a multiple-time programmable memory solution. Leveraging the resistive switching mechanism, the technology excels in meter-scale data storage applications, integrating seamlessly into AI-driven, IoT, and secure computing realities. The patented ReRAM technology is distinguished by its ability to perform at peak efficiency with notable read and write speeds, making it a suitable candidate for future-facing chip architectures that require swift, wide-ranging memory capabilities. Unprecedented in its energy-saving capabilities, CrossBar's ReRAM slashes energy consumption by up to 5 times compared to eFlash and offers substantial improvements over NAND and SPI Flash memories. Coupled with exceptional read latencies of around 20 nanoseconds and write times of approximately 12 microseconds, the memory technology outperforms existing solutions, enhancing system responsiveness and user experiences. Its high-density memory configurations provide terabyte-scale storage with minimal physical footprint, ensuring effective integration into cutting-edge devices and systems. Moreover, ReRAM's design permits its use within traditional CMOS manufacturing processes, enabling scalable, stackable arrays. This adaptability ensures that suppliers can integrate these memory solutions at various stages of semiconductor production, from standalone memory chips to embedded roles within complex system-on-chip designs. The inherent simplicity, combined with remarkable performance characteristics, positions ReRAM Memory as a key player in the advancement of secure, high-density computing.
The General Purpose Accelerator (Aptos) from Ascenium stands out as a redefining force in the realm of CPU technology. It seeks to overcome the limitations of traditional CPUs by providing a solution that tackles both performance inefficiencies and high energy demands. Leveraging compiler-driven architecture, this accelerator introduces a novel approach by simplifying CPU operations, making it exceptionally suited for handling generic code. Notably, it offers compatibility with the LLVM compiler, ensuring a wide range of applications can be adapted seamlessly without rewrites. The Aptos excels in performance by embracing a highly parallel yet simplified CPU framework that significantly boosts efficiency, reportedly achieving up to four times the performance of cutting-edge CPUs. Such advancements cater not only to performance-oriented tasks but also substantially mitigate energy consumption, providing a dual benefit of cost efficiency and reduced environmental impact. This makes Aptos a valuable asset for data centers seeking to optimize their energy footprint while enhancing computational capabilities. Additionally, the Aptos architecture supports efficient code execution by resolving tasks predominantly at compile-time, allowing the processor to handle workloads more effectively. This allows standard high-level language software to run with improved efficiency across diverse computing environments, aligning with an overarching goal of greener computing. By maximizing operational efficiency and reducing carbon emissions, Aptos propels Ascenium into a leading position in the sustainable and high-performance computing sector.
Toggle MRAM technology from Everspin facilitates reliable non-volatile memory solutions ideal for high-performance, demanding environments. Known for its durability and speed, Toggle MRAM provides solutions that bridge the gap between volatile and solid-state storage. This technology is particularly useful for applications requiring fast data retention and retrieval, ensuring integrity even in power failure scenarios. Due to its robust framework, Toggle MRAM has proven indispensable in industries such as aerospace, where the reliability of data storage can be crucial. The non-volatility offers the capability to store data even when powered off, a feature much appreciated in dedicated electronic systems and embedded applications. Furthermore, Toggle MRAM supports a myriad of interfaces, catering to broad industrial and commercial needs. Its architecture ensures it remains versatile and adaptable to continuous technological advancements, making it a future-proof solution for various applications. This blend of performance, reliability, and adaptability makes Toggle MRAM a cornerstone technology in Everspin's suite.
The Spiking Neural Processor T1 is designed as a highly efficient microcontroller that integrates neuromorphic intelligence closely with sensors. It employs a unique spiking neural network engine paired with a nimble RISC-V processor core, forming a cohesive unit for advanced data processing. With this setup, the T1 excels in delivering next-gen AI capabilities embedded directly at the sensor, operating within an exceptionally low power consumption range, ideal for battery-dependent and latency-sensitive applications. This processor marks a notable advancement in neuromorphic technology, allowing for real-time pattern recognition with minimal power draw. It supports various interfaces like QSPI, I2C, and UART, fitting into a compact 2.16mm x 3mm package, which facilitates easy integration into diverse electronic devices. Additionally, its architecture is designed to process different neural network models efficiently, from spiking to deep neural networks, providing versatility across applications. The T1 Evaluation Kit furthers this ease of adoption by enabling developers to use the Talamo SDK to create or deploy applications readily. It includes tools for performance profiling and supports numerous common sensors, making it a strong candidate for projects aiming to leverage low-power, intelligent processing capabilities. This innovative chip's ability to manage power efficiency with high-speed pattern processing makes it especially suitable for advanced sensing tasks found in wearables, smart home devices, and more.
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.
Ncore Cache Coherent Interconnect is designed to tackle the multifaceted challenges in multicore SoC systems by introducing heterogeneous coherence and efficient cache management. This NoC IP optimizes performance by ensuring high throughput and reliable data transmission across multiple cores, making it indispensable for sophisticated computing tasks. Leveraging advanced cache coherency, Ncore maintains data integrity, crucial for maintaining system stability and efficiency in operations involving heavy computational loads. With its ISO26262 support, it caters to automotive and industrial applications requiring high reliability and safety standards. This interconnect technology pairs well with diverse processor architectures and supports an array of protocols, providing seamless integration into existing systems. It enables a coherent and connected multicore environment, enhancing the performance of high-stakes applications across various industry verticals, from automotive to advanced computing environments.
TwinBit Gen-1 is NSCore's pioneering solution in embedded non-volatile memory technology, optimized for seamless integration into CMOS logic processes across nodes ranging from 180nm to 55nm. Known for its robust endurance performance, it supports over 10,000 program/erase cycles, making it highly reliable for repeated usage. This IP is designed without necessitating any additional masks or process steps, which aligns with NSCore’s ethos of simplifying the integration process. TwinBit Gen-1's flexible memory configuration, spanning 64 bits up to 512K bits, ensures its applicability in a wide array of domains. From enabling secure key storage to supporting analog trimming and system switches on ASICs/ASSPs, it offers a broad spectrum of functional capabilities, making it ideally suited for modern IoT devices and embedded systems. With built-in test circuits that facilitate stress-free test environments and automotive-grade reliability, TwinBit Gen-1 presents a formidable option for applications that demand low-voltage and low-power operations. Its alignment with standard IPs and lack of additional process overhead also contribute to its attractive development turnaround time and cost-effectiveness.
EverOn is an ultra-low voltage SRAM developed by sureCore to cater to modern applications requiring extensive dynamic and static power savings. Built on the 40ULP BULK CMOS process, EverOn achieves up to 80% reductions in dynamic power utilization while cutting static power draw by 75%, making it highly efficient for IoT and wearable technology. Operational from 0.6V to 1.21V, EverOn supports a cycle time as short as 20MHz at its lowest voltage, scaling impressively to over 300MHz at its highest. This voltage scaling unlocks robust performance capabilities in energy-constrained environments, aligning with the trend towards increasingly sophisticated, low-power always-on devices. EverOn incorporates advanced techniques such as subdividing memory into banks for flexible power management and synchronized single-port operation, which enhances versatility. Its high-density bit cells facilitate reduced area footprints while the patented SMART-Assist technology ensures robust operation even at the retention voltage, supporting extended battery life applications in emerging markets.
CrossBar's ReRAM IP Cores present a sophisticated solution for enhancing embedded NVM within Microcontroller Units (MCUs) and System-on-Chip (SoC) architectures. Designed to work with advanced semiconductors and ASIC (Application-Specific Integrated Circuit) designs, these cores offer efficient integration, performance enhancement, and reduced energy consumption. The technology seeks to equip contemporary and next-generation chip designs with high-speed, non-volatile memory, enabling faster computation and data handling. Targeting the unique needs of IoT, mobile computing, and consumer electronics, the ReRAM IP Cores deliver scalable memory solutions that exceed traditional flash memory limits. These cores are built to be stackable and compatible with existing process nodes, highlighting their versatility. Furthermore, the integration of ReRAM technology ensures improved energy efficiency, with the added benefit of low latency data access—a critical factor for real-time applications and processing. These IP cores provide a seamless route to incorporating high-performance ReRAM into chips without major redesigns or adjustments. As the demand for seamless, secure data processing grows, this technology enables manufacturers and designers to aptly meet the challenges presented by ever-evolving digital landscapes. By minimizing energy usage while maximizing performance capabilities, these IP cores hold potential for transformative applications in high-speed, secure data processing environments.
YouDDR is a comprehensive technology encompassing not only the DDR controller, PHY, and I/O but also features specially developed tuning and testing software. It provides a complete subsystem solution to address the complex needs of DDR memory interfaces. The integrated approach allows for cohesive synchronization between the controller and PHY, optimizing performance and reliability. The YouDDR technology ensures seamless integration into a variety of platforms, supporting a broad range of applications from simple consumer electronics to advanced computing systems. By offering enhanced tuning capabilities, it allows developers to fine-tune performance metrics, ensuring that systems can operate within their optimal performance windows. Developers utilizing YouDDR benefit from a thoroughly tested and verified subsystem that significantly simplifies the design cycle. This not only reduces development time but also enhances the likelihood of first-pass success, providing a competitive edge in manufacturing efficiency and product launch speed.
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.
Secure OTP by PUFsecurity offers a tamperproof data storage solution designed for the next generation of secure memory needs. It is an enhanced anti-fuse OTP memory that provides secure storage for key data across various forms, ensuring that data in transit, use, or rest remains protected. This technology integrates physical macros, a digital RTL controller, and a resilient anti-tamper shell to guard against hardware attacks. As IoT devices become increasingly susceptible to early-stage attacks, Secure OTP presents a reliable means to safely store sensitive data such as keys and boot code. By transitioning to this tamperproof storage format, devices can effectively mitigate vulnerabilities inherent in legacy storage systems, fortifying data security at the hardware level.
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.
BCD technology uniquely combines the traits of Bipolar, CMOS, and DMOS transistors to deliver efficient power management solutions. This technology is engineered to handle a range of power requirements, making it a versatile choice for applications spanning from consumer electronics to industrial equipment. The blend of these transistor types offers both high voltage handling capabilities and precise digital control. Bipolar transistors contribute excellent analog performance, while CMOS transistors provide intricate digital logic benefits. DMOS transistors add high current and voltage tolerance, resulting in a robust technology that excels in power-driving applications. This combination allows devices to efficiently manage power dissipation, significantly reducing energy waste and enabling longer battery life for portable devices. The BCD process supports the implementation of complex circuits with enhanced reliability. It is well-suited for automotive industries and consumer products requiring solid state power control. With the integration of multiple transistor types, the technology advances superior power management solutions, offering improved efficiency, thermal performance, and scalability. Tower Semiconductor ensures this process is backed by comprehensive design resources, allowing customers to harness the full potential of BCD technology for diverse applications.
The iCan PicoPop® is a highly compact System on Module (SOM) based on the Zynq UltraScale+ MPSoC from Xilinx, suited for high-performance embedded applications in aerospace. Known for its advanced signal processing capabilities, it is particularly effective in video processing contexts, offering efficient data handling and throughput. Its compact size and performance make it ideal for integration into sophisticated systems where space and performance are critical.
The Universal DSP Library is designed to simplify digital signal processing tasks. It ensures efficient and highly effective operations by offering a comprehensive suite of algorithms and functions tailored for various DSP applications. The library is engineered for optimal performance and can be easily integrated into FPGA-based designs, making it a versatile tool for any digital signal processing needs. The comprehensive nature of the Universal DSP Library simplifies the development of complex signal processing applications. It includes support for key processing techniques and can significantly reduce the time required to implement and test DSP functionalities. By leveraging this library, developers can achieve high efficiency and performance in their digital signal processing tasks, thereby optimizing overall system resources. Moreover, the DSP library is designed to be compatible with a wide range of FPGAs, providing a flexible and scalable solution. This makes it an ideal choice for developers seeking to create innovative solutions across various applications, ensuring that their designs can handle demanding signal processing requirements effectively.
aiData is designed to streamline the data pipeline for developing models for Advanced Driver-Assistance Systems and Automated Driving solutions. This automated system provides a comprehensive method of managing and processing data, from collection through curation, annotation, and validation. It significantly reduces the time required for data processing by automating many labor-intensive tasks, enabling teams to focus more on development rather than data preparation. The aiData platform includes sophisticated tools for recording, managing, and annotating data, ensuring accuracy and traceability through all stages of the MLOps workflow. It supports the creation of high-quality training datasets, essential for developing reliable and effective AI models. The platform's capabilities extend beyond basic data processing by offering advanced features such as versioning and metrics analysis, allowing users to track data changes over time and evaluate dataset quality before training. The aiData Recorder feature ensures high-quality data collection tailored to diverse sensor configurations, while the Auto Annotator quickly processes data for a variety of objects using AI algorithms, delivering superior precision levels. These features are complemented by aiData Metrics, which provide valuable insights into dataset completeness and adequacy in covering expected operational domains. With seamless on-premise or cloud deployment options, aiData empowers global automotive teams to collaborate efficiently, offering all necessary tools for a complete data management lifecycle. Its integration versatility supports a wide array of applications, helping improve the speed and effectiveness of deploying ADAS models.
Floadia's LEE Flash G2 transcends standard flash memory by blending the qualities of logic and memory. This provides a dual benefit of non-volatile performance with logic-level operation, achieved through its unique tri-gate transistor architecture. The G2 cell combines a SONOS transistor with switching transistors, offering high-speed, non-volatile SRAM capabilities. The G2 memory's design addresses one of the major challenges in memory technology: reducing power consumption. By employing a programming current that is substantially lower than conventional floating gate NVMs, it considerably lowers power demands. This technology allows for the memory and logic circuits to be connected directly, enabling more efficient chip architectures. Additionally, the LEE Flash G2 supports a novel application where it can function as Non-Volatile SRAM (NV-SRAM). This combination eliminates the need for dedicated flash blocks, thereby streamlining the microcontroller architecture and enabling rapid wake-up or sleep modes. Such a configuration enhances the overall efficiency of systems, especially in complex SOC and FPGA designs.
Ventana's System IP is a critical component for next-generation RISC-V platforms, providing essential support for integrating high-performance CPUs into sophisticated computing architectures. This IP block enables system-level functionality that aligns with the stringent demands of modern computing environments, from cloud infrastructures to advanced automotive systems. Equipped with comprehensive system management capabilities, the System IP includes crucial components such as memory management units and I/O handling protocols that enhance the overall efficiency and reliability of RISC-V-based systems. It is optimized for virtualization and robust security, essential for maintaining integrity in high-traffic data centers. The System IP supports seamless integration with Ventana's Veyron processor families, ensuring scalability and consistent performance under demanding workloads. Its design allows for easy customization, making it an ideal choice for companies looking to innovate and expand within the rapidly evolving field of high-performance computing.
PermSRAM is a highly adaptive nonvolatile memory macro designed to operate on standard CMOS fabrication processes. It supports a variety of process nodes ranging from 180nm to 28nm and beyond. One of its key features is its ability to offer diverse functionalities such as one-time programmable ROM and pseudo multi-time PROM, along with a multipage configuration that greatly broadens its utility across different applications. A prominent attribute of PermSRAM is its security-oriented design. It incorporates a non-rewritable hardware safety lock for secure code storage, which ensures data integrity and tamper resistance. This product caters to a wide span of memory sizes, from 64 bits to a robust 512K bits, accommodating both minimal and extensive data storage requirements. PermSRAM's inherently stable yield and reliability are complemented by its automotive-grade data retention, making it ideal for demanding applications that require long-term data retention capability at high temperatures. Furthermore, it operates efficiently without the need for a charge pump in read operations, offering significant efficiency and area savings.
Spectral CustomIP encompasses an expansive suite of specialized memory architectures, tailored for diverse integrated circuit applications. Known for breadth in memory compiler designs, Spectral offers solutions like Binary and Ternary CAMs, various Multi-Ported memories, Low Voltage SRAMs, and advanced cache configurations. These bespoke designs integrate either foundry-standard or custom-designed bit cells providing robust performance across varied operational scenarios. The CustomIP products are engineered for low dynamic power usage and high density, utilizing Spectral’s Memory Development Platform. Available in source code form, these solutions offer users the flexibility to modify designs, adapt them for new technologies, or extend capabilities—facilitating seamless integration within standard CMOS processes or more advanced SOI and embedded Flash processes. Spectral's proprietary SpectralTrak technology enhances CustomIP with precise environmental monitoring, ensuring operational integrity through real-time Process, Voltage, and Temperature adjustments. With options like advanced compiler features, multi-banked architectures, and standalone or compiler instances, Spectral CustomIP suits businesses striving to distinguish their IC offerings with unique, high-performance memory solutions.
The APB4 GPIO core from Roa Logic is a fully parameterized solution designed to provide a customizable number of general-purpose, bidirectional I/O pins. This core enables developers to define the I/O behavior precisely, adapting to a plethora of configurations to meet specific project requirements. It is essential for applications that require extensive interfacing capabilities, ensuring streamlined connectivity across multiple components. The GPIO core supports a range of operational modes, providing the flexibility to handle complex I/O operations. With capabilities like programmable drive strength and individual pin configuration, it offers a high degree of customization that can be tailored to precise application needs. Roa Logic’s offering enhances design functionality and accelerates development timelines by facilitating easy integration and application-specific optimization. This component serves as a cornerstone for designs requiring robust peripheral interaction, catering to both industrial projects and educational purposes. Its adaptability and ease of integration ensure it's an invaluable component in modern electronics design, adhering to the high standards expected in today's interconnected environments.
The SiFive Essential family provides a comprehensive range of embedded processor cores that can be tailored to various application needs. This series incorporates silicon-proven, pre-defined CPU cores with a focus on scalability and configurability, ranging from simple 32-bit MCUs to advanced 64-bit processors capable of running embedded RTOS and full-fledged operating systems like Linux. SiFive Essential empowers users with the flexibility to customize the design for specific performance, power, and area requirements. The Essential family introduces significant advancements in processing capabilities, allowing users to design processors that meet precise application needs. It features a rich set of options for interface customizations, providing seamless integration into broader SoC designs. Moreover, the family supports an 8-stage pipeline architecture and, in some configurations, offers dual-issue superscalar capabilities for enhanced processing throughput. For applications where security and traceability are crucial, the Essential family includes WorldGuard technology, which ensures comprehensive protection across the entire SoC, safeguarding against unauthorized access. The flexible design opens up various use cases, from IoT devices and microcontrollers to real-time control applications and beyond.
TwinBit Gen-2 represents the next evolution in NSCore's non-volatile memory offering, supporting process nodes from 40nm to 22nm and beyond. Maintaining the foundational benefits of its predecessor, TwinBit Gen-2 further elevates its efficiency with the inclusion of the Pch Schottky Non-Volatile Memory Cell, which facilitates ultra-low-power operations without additional masks or process steps. The Gen-2 variant is engineered with an increased focus on minimizing power consumption while ensuring strong functional performance. It is adept at handling a wide range of program/erase dynamics through controlled hot carrier injection, offering refined operational flexibility for diverse applications. This memory technology serves applications requiring robust data management in tightly constrained power scenarios. Like its predecessor, TwinBit Gen-2 excels in environments demanding longevity and durability, boasting comprehensive integration flexibility into existing systems. Its ability to harmonize cutting-edge non-volatile memory design with the demands of smaller process nodes makes it highly beneficial for forward-looking applications.
The 12-bit ADC with a maximum conversion rate of 1MSPS is designed on Samsung's 100nm LF6 CMOS technology. This ADC supports a wide operating range, with an analog supply voltage varying from 2.7V to a peak of 5.5V. It features a multi-channel configuration accommodating 16 single-ended inputs, offering extensive input range flexibility from the analog ground to the supply voltage. Alongside its high signal-to-noise ratio (SNR) of 70.7dB, the ADC provides robust performance for a diverse set of applications requiring reliable signal acquisition and conversion, ensuring data fidelity.
The AHB-Lite Memory module is a fully parameterized component tailored for integration in AHB-Lite based designs. As a soft IP, it provides flexible and efficient on-chip memory access, offering a simple integration path into various system architectures. This memory module is crafted to support a wide array of applications that require dependable and swift data storage solutions. Roa Logic has designed this component to embody high reliability and operational efficiency. The memory’s design is optimized for quick data retrieval and storage, making it a critical component for applications that demand immediate access to data. Its adaptability accommodates different data storage requirements, ensuring that it aligns with the performance demands of contemporary embedded systems. The AHB-Lite Memory module guarantees seamless integration and stable operational capacity, reinforcing Roa Logic's dedication to offering solutions that drive system performance. Its configurable design ensures it's well-suited to both small-scale and expansive architectures, maintaining efficiency across diverse computing environments.
Designed to address the evolving power needs of integrated circuits, Xenergic's High-Speed Low-Power SRAM emerges as a leading solution for energy-conscious applications. By optimizing both dynamic power and leakage, this SRAM offers a 70% to 90% reduction in power usage, making it ideal for sensors, wearables, and other low-power devices. Its architecture allows for high efficiency in edge computing applications, minimizing latency while bringing computation closer to the data source.\n\nWith critical features like reduced leakage and dynamic power consumption, this SRAM ensures that your SoC stays competitive in terms of power efficiency. By enabling the SoC to serve multiple features without significant energy drain, it becomes a perfect match for always-on mobile and IoT applications, enhancing user convenience and experience. The SRAM integrates seamlessly into existing designs, aided by comprehensive memory interface views and support for a range of standard optional memory features.
The silicon IP Platform for Low-Power IoT by Low Power Futures integrates pre-validated, configurable building blocks tailored for IoT device creation. It provides a turnkey solution to accelerate product development, incorporating options to employ both ARM and RISC V processors. With a focus on reducing energy consumption, the platform is prepared for various applications, ensuring a seamless transition for products from conception to market. The platform is crucial for developing smart IoT solutions that require secure and reliable wireless communications across industries like healthcare, smart home, and industrial automation.
The 65nm 12-bit ADC provides an optimal balance of performance and power efficiency for modern semiconductor applications. Capable of managing a 1MSPS conversion rate, this ADC functions on an analog power supply between 2.4V and 3.6V and a digital supply from 1.08V to 1.32V. With low power consumption and compact design, it is suitable for systems where space and energy efficiency are paramount. Whether for data acquisition or sensor networks, the device is crafted to enhance battery-powered systems with reliable performance across varying operational conditions.
The LEE Flash G1 from Floadia is designed as a cost-effective SONOS technology solution. This nonvolatile memory offers remarkable cost efficiency, employing a low-cost process that requires minimal additional masks, thus reducing fabrication complexity. The design ensures compatibility with existing semiconductor processes, making it economical without sacrificing quality or performance. This flash memory is built on a robust SONOS architecture, which stands out for its high reliability, a crucial factor in memory retention and endurance. The electric charge retention mechanism in SONOS is distinct from the traditional floating gate charge storage, offering superior reliability due to its resistance to leakage through defects. By utilizing Fowler Nordheim (FN) tunneling, the G1 guarantees minimal oxide damage and sustains a high level of performance even after many cycles. Additionally, the G1's design focuses on simplifying manufacturing processes by using common materials, allowing for seamless integration into existing foundry workflows. This ease of implementation, combined with its robustness and low power requirements, makes the LEE Flash G1 a key product in high-demand, cost-sensitive applications.
The Xilinx Serial PROM Programmer by Roman-Jones is a competitive solution designed to streamline the programming process for Xilinx Serial PROM devices. This acclaimed programmer is recognized for its affordability and ease of use, demonstrating exceptional compatibility with any Xilinx Serial PROM part. It operates through a simple parallel port interface, obviating the need for specialized interface cards. Users can benefit from software support across multiple platforms, including DOS and various Windows versions, and the device is powered conveniently by a 9-volt battery, eliminating the requirement for an AC adapter. This product includes an external programmer coupled with proprietary interface software, which has received certification and endorsement from Xilinx. Its setup is straightforward, allowing for seamless co-existence with existing printer connections using an AB switchbox. The package supports a range of industry-standard file formats such as Intel Hex, Motorola S-Record, and Binary files crafted by Xilinx compilers, catering to diverse programming needs. Further enhancing its utility, the programmer includes options for socket adapters, enabling compatibility with varying package types including the 8-pin DIP and additional configurations. This adaptability ensures the programmer fulfills a wide array of customization requirements, making it a versatile tool for any electronics professional working with Xilinx Serial PROMs.
Tower Semiconductor's non-volatile memory solutions leverage cutting-edge design to enhance data retention and simplify integration within various devices. The solutions include advanced Y-Flash and e-Fuse technologies, offering reliable data storage options that retain information without a constant power supply. This makes them ideal for applications requiring persistent data, ranging from consumer electronics to critical industrial controls. The NVM solutions are designed to offer high endurance and retention periods, granting devices the capability to operate effectively across diverse environmental conditions. Y-Flash supports fast write and erase times, while e-Fuse enables secure, permanent programming options, prototyping a versatile memory solution suitable for field programming and personalization. In addition to their technological sophistication, these solutions are supported by a comprehensive suite of design resources including detailed libraries and validation data. This ensures seamless integration with existing architectures, allowing designers to rapidly bring enhancements to market. As such, Tower Semiconductor's NVM offerings signify a blend of reliability, adaptability, and innovation in modern data storage technology.
Offering a zero additional mask solution, LEE Flash ZT stands for a zero-technology-cost addition to Floadia’s flash memory repertoire. It is particularly valued for its minimal impact on manufacturing processes while maintaining robust performance attributes inherent to Floadia's memory products. This memory eliminates additional mask requirements in the production process, which not only reduces costs but also simplifies the manufacturing workflow. The ZT model effectively retains the essential features of robustness and high reliability, necessary for modern semiconductor applications, through its efficient architecture. In terms of functionality, the ZT adheres to high standards of charge retention and endurance, similar to other products in Floadia's lineup. With this design choice, Floadia ensures that the technology maintains the integrity and reliability expected from advanced embedded memory solutions, making it suitable for a wide array of industrial applications.
Analog Bits provides robust I/O solutions that are essential for the efficient transfer of signals between semiconductor devices and their external environment. These input/output interfaces are designed to meet the most demanding performance criteria, ensuring fast data rates and minimal signal distortion. Their I/O IP solutions can accommodate a variety of protocols, including high-speed digital interfaces and analog conversions, offering versatility and support for applications such as networking, data processing, and consumer electronics. By optimizing the signal integrity and electromagnetic compatibility, these I/Os enhance the overall system performance. Equipped with advanced features for low power consumption, these I/Os contribute to reducing the overall energy footprint of semiconductor devices, making them ideal for battery-operated devices and environmentally sensitive applications. Analog Bits' I/Os are comprehensively integrated to function seamlessly within mixed-signal environments, further broadening their application range.
CodaCache Last-Level Cache is an advanced, shared cache solution specifically designed to minimize memory latency and boost SoC performance. Its configurable nature allows it to be tailored to specific design needs, optimizing data flow and enhancing power efficiency across the chip. This cache helps overcome common SoC challenges related to timing closure, performance, and layout congestion by providing a flexible caching architecture that ensures effective data management and reliable operations. Its role in optimizing memory hierarchy enhances computational speeds and system reliability. CodaCache is particularly beneficial for applications that require rapid access to large data sets, ensuring that power consumption is minimized while maintaining high performance standards. Its versatility and efficiency make it a top choice for industries striving for high data throughput and low latency operations.
Avant Technology's DRAM Memory Modules are designed to meet the stringent requirements of industrial, commercial, and consumer applications. These JEDEC-compliant modules excel in environments like gaming, Point-of-Sale systems, kiosks, medical devices, and automation, where reliability and performance are critical. Avant's DRAM offerings include a wide variety of DIMMs, each tailored for different use cases with options for low voltage, high capacitance, and low power consumption, ensuring compatibility with diverse application needs. The DRAM modules come in various form factors such as UDIMM, SODIMM, ECC DIMM, and Mini DIMM, providing flexibility for integration into different systems. These form factors are equipped with interfaces such as DDR3, DDR4, and DDR5, enabling seamless performance upgrades and adaptations to newer technology standards. This adaptability is crucial for businesses seeking to maintain cutting-edge performance while managing costs. With a focus on durability and efficiency, Avant's DRAM memory solutions cater to a range of temperature conditions, making them suitable for both industrial and commercial use. Their robust design ensures prolonged lifespan and stability, a testament to Avant Technology's dedication to quality and reliability in memory solutions.
LEE Fuse ZA from Floadia offers a unique approach with its zero additional mask anti-fuse memory technology. Designed for one-time programmable (OTP) applications, this memory type is cost-efficient and easily adaptable to existing manufacturing processes without requiring additional masks. The ZA fuse is characterized by its reliable anti-fuse mechanism, providing secure data retention. It excels in applications requiring a permanent programming solution and offers high endurance due to its robust design. By eliminating the need for complex mask layers, the LEE Fuse ZA significantly cuts down production costs while maintaining superior performance. Its compatibility with standard CMOS processes further underscores its suitability for various implementations where cost efficiency and reliability are paramount. The design guarantees effective fuse operation, making the LEE Fuse ZA a popular choice for applications in diverse sectors needing a robust OTP solution.
Global Unichip Corp.'s High Bandwidth Memory solution is engineered to facilitate vast data transfer rates crucial for AI and high-performance computing tasks. This product is pivotal in reducing latency and increasing bandwidth, addressing performance bottlenecks often faced in data-intensive applications. Through the integration of advanced packaging technologies, the High Bandwidth Memory enables seamless communication between systems, enhancing operational efficiencies. The solution also supports multiple process nodes which allows for scalability across various semiconductor technologies. This adaptability ensures it meets diverse industry requirements from data centers to AI-driven applications. This IP’s design also promotes efficient thermal management, necessary for maintaining optimal function under high workloads. Emphasizing innovations in interconnectivity, the High Bandwidth Memory works hand in hand with other IPs in GUC’s portfolio, creating a comprehensive ecosystem for modern semiconductor solutions. Its design is aligned with global standards for memory solutions, ensuring broad compatibility and ease of integration into existing systems, leading to quicker deployment and reduced time-to-market.
Dolphin Semiconductor's Foundation IPs are crafted to enhance the efficiency and cost-effectiveness of System-on-Chip (SoC) designs through robust offerings of embedded memories and standard-cell libraries. Specially designed for energy-efficient applications, these components help optimize space and power usage while ensuring the cutting-edge performance of modern electronic devices. Incorporated within Dolphin's Foundation IP portfolio are standard cells that allow chip designers to achieve up to 30% density gains at the cell level, compared to conventional libraries. Further, these components are engineered to support always-on applications with exceptionally low leakage rates. The Foundation IP suite optimizes SoC designs by delivering dramatically reduced leakage and area consumption, avoiding the additional cost and complexity of using a regulator. The memory compilers within Foundation IPs offer ultra-low power and high-density memory solutions, including SRAM and via-programmable ROMs. These are formulated to deliver up to 50% energy savings, providing flexibility with multi-power modes and adaptable to varied instances. With optimization for TSMC processes, Dolphin's Foundation IPs provide an essential backbone for creating innovative, efficient, and sustainable SoC products.
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 Cyclone V FPGA with Integrated PQC Processor by ResQuant is a specialized product that comes pre-equipped with a comprehensive NIST PQC cryptography suite. This FPGA is tailored for applications requiring a robust proof-of-concept for quantum-safe implementations. It ensures seamless integration into existing systems, providing a practical platform for testing and deployment in quantum-secure environments. This product is available at a competitive price and represents an ideal starting point for entities looking to explore and adopt quantum-resilient technologies. Its configuration allows for straightforward implementation in diverse hardware infrastructures while offering a reliable option for organizations aiming to stay ahead in the evolving cyber security landscape. By incorporating the latest in cryptographic standards and ensuring vendor independence, the Cyclone V FPGA with Integrated PQC Processor by ResQuant effectively bridges current hardware technologies and future-proof security needs. It supports industry-wide applications, from IoT and ICT to automotive and military sectors, underscoring ResQuant's versatility in hardware security solutions.
SuperFlash® technology is distinguished by its proprietary split-gate Flash memory architecture, designed to deliver high performance with simplified integration into System-on-Chip (SoC) solutions. This technology ensures reliability and efficiency across various industrial applications. It offers compatibility with standard silicon CMOS and has been proven to possess high endurance and excellent data retention capabilities. Given its ability to withstand extreme temperatures while maintaining performance, SuperFlash® is ideal for applications in the automotive sector requiring stringent reliability standards.\n\nThis technology spans multiple process nodes, from 500nm down to 28nm, solidifying its flexibility and adaptability across different foundry platforms. With a distinct advantage of low power consumption, SuperFlash® emerges as a preferred choice for resource-constrained environments, such as IoT devices and smart cards. Its consistent performance in high-temperature conditions and immunity to stress-induced leakage current further underscore its robustness.\n\nThe adaptability of SuperFlash® technology is enhanced by tailored licensure options, which accommodate a wide array of business needs—from semiconductor manufacturers to fabless design firms. This licensing flexibility ensures that businesses of all sizes can effectively integrate SST's Flash solutions, supporting a diverse spectrum of applications spanning automotive to consumer electronics.
The NuRAM Low Power Memory represents a state-of-the-art memory solution utilizing advanced MRAM technology. Engineered to provide rapid access times and extremely low leakage power, NuRAM is significantly more efficient in terms of cell area compared to traditional SRAM, being up to 2.5 times smaller. This makes it an ideal replacement for on-chip SRAM or embedded Flash, particularly in power-sensitive environments like AI or edge applications. The emphasis on optimizing power consumption makes NuRAM an attractive choice for enhancing the performance of xPU or ASIC designs. As modern applications demand higher efficiency, NuRAM stands out by offering crucial improvements in power management without sacrificing speed or stability. The technology offers a compelling choice for those seeking to upgrade their current systems with memory solutions that extend battery life and deliver impressive performance. NuRAM is particularly beneficial in environments where minimizing power usage is critical while maintaining high-speed operations. This makes it a preferred choice for applications ranging from wearables to high-performance computing at the edge.
The SoC Platform by SEMIFIVE enables swift and minimal-effort design of system-on-chip solutions through their streamlined platforms. Built with silicon-proven IPs and optimized methodologies, these platforms significantly reduce costs and risks while ensuring a faster turnaround time. The platform supports domain-specific architectures and offers a pre-configured and verified IP pool, facilitating quick hardware and software bring-up. This platform stands out for its ability to turn ideas into silicon by leveraging SEMIFIVE’s infrastructure and IP partnerships. It promises substantial cost reduction in areas like design NRE, fabrication, and IP licenses, offering savings upwards of 50% compared to industry norms. Its rapid development process is poised to cut development times in half, maintaining high levels of design and verification reusability. The SoC Platform also minimizes engineering risks associated with the complexities of cutting-edge process technologies. By utilizing pre-verified platform IP pools and silicon-proven design components, SEMIFIVE offers a highly reliable and efficient path from concept to silicon production.
The Rabbit 2000 microprocessor is a compact yet powerful processor, featuring approximately 19,000 gates and a 100-pin configuration. It is a foundational component within Systemyde's suite of synthesizable IP offerings. As a versatile microprocessor, the Rabbit 2000 is designed for seamless compatibility with various technology and foundry options, ensuring adaptability in diverse design scenarios. With its comprehensive specifications and robust design, the Rabbit 2000 exemplifies Systemyde's commitment to high-quality IP development. This silicon-proven processor incorporates a range of functions that make it suitable for both FPGA and ASIC implementations. Given its optimized architecture, it performs efficient computations, making it ideal for applications requiring swift processing power. Additionally, it lays the groundwork for subsequent Rabbit microprocessors, which expand on its capabilities with enhanced features and configurations. The Rabbit 2000 benefits from Systemyde's extensive expertise in formulating high-performance, technology-independent solutions. Its adaptability is bolstered by a comprehensive suite of design packages, including a synthesizable model, test benches, and a detailed test suite for exhaustive verification. This ensures that the Rabbit 2000 is not only powerful but also reliable, supporting a wide array of embedded applications.
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