In the ever-evolving landscape of computing technology, processor semiconductor IPs under the 'Other' category provide crucial solutions for niche and specialized applications. These semiconductor IPs cater to a variety of non-mainstream processing needs, fulfilling roles that might not be covered by traditional CPU or GPU options. With the advancement of technology and the increasing demand for customized processing solutions, these IPs offer flexibility and innovation to meet specific computing challenges.
Processor IPs in this category are often utilized in highly specialized devices and systems that require unique performance characteristics or unconventional architectures. This includes applications in embedded systems, telecommunications, automotive, aerospace, and IoT devices where standard processors fall short or are not suitable. These IPs include everything from DSPs (Digital Signal Processors) and NPU (Neural Processing Units) to custom accelerators designed for specific calculations or data processing tasks.
The flexibility provided by these 'Other' processors enables designers to tailor the performance and capabilities to the exact needs of their application. It allows for the integration of cutting-edge features like low-power consumption, real-time processing, or enhanced security measures. This customization is crucial in product areas that demand high efficiency, robustness, and novel functionality, setting them apart from more general-purpose processors.
By leveraging processor semiconductor IPs under this category, technology developers can achieve significant strategic advantages. These IPs help in reducing development costs and time-to-market, enabling a swift transition from concept to commercialization. Ultimately, they foster innovation by enabling the development of products that can meet the multifaceted demands of modern digital environments.
The J5 is a digital processor designed to perform advanced 3-D audio virtualization. Handling both TruSurround and SRS 3D algorithms, it allows users to enjoy a full surround sound feel with just two speakers by implementing complex channel downmixing and spatial audio effects. The J5 is economically designed, needing less than 0.16 sqmm of silicon, making it efficient and cost-effective for high-density audio systems.
Designed to scale effectively with the growing needs for high-volume data storage, CrossBar's ReRAM IP Cores for High-Density Data Storage offer clients the ability to manage extensive datasets with ease. The cores excel in providing high-speed data access and retrieval capabilities, making them an ideal choice for data centers, AI infrastructure, and complex analytics platforms. These cores support dense data storage configurations within devices, far surpassing the performance specifications of traditional memory options. CrossBar's ReRAM cores offer significant energy savings in storage operations, enabling data centers to drastically reduce power consumption while increasing throughput and efficiency. This green approach to data storage not only enhances computational performance but also aligns with global sustainability efforts to lower energy expenditure. With high-density capabilities, the ReRAM cores play a critical role in optimizing large-scale data handling and facilitate emerging trends like real-time analytics and advanced machine learning algorithms. Integrated into existing infrastructures, these ReRAM cores transcend traditional memory solutions. The technology's flexibility allows for customization, accommodating varied client needs and extending beyond standard operational limitations. Whether deployed in cloud services, enterprise data warehousing, or sophisticated AI training models, CrossBar's ReRAM cores ensure robust performance, reliability, and scalability in handling complex storage challenges.
The PB8051 Microcontroller Core is a sophisticated implementation of the 8051 Microcontroller Family, carefully constructed to enhance Xilinx FPGA applications. Adopting the Xilinx PicoBaze softcore microcontroller for emulation, the PB8051 is tailored for designers seeking to integrate compact and efficient microcontroller functionalities into Xilinx platforms. It is software-compatible with the 8031 variant, encompassing essential elements like the serial port and dual timers, enabling seamless execution of 8051 object codes. Designed with adaptability in mind, the PB8051 supports an array of design tools and platforms. It's particularly well-suited for Spartan II and newer Xilinx FPGA families, ensuring that users can leverage existing development tools and experience a smooth transition to PB8051-based implementations. Notably, its design permits the use of internal FPGA block RAM or external EPROM for program storage, adding flexibility to suit specific application needs. Beyond its technical prowess, the PB8051 stands out for its cost-effectiveness and ease of integration. It caters to varying levels of user expertise, supported by comprehensive documentation, a detailed test bench, and reference designs. Technical support is available to assist users, providing a pathway for both novice and experienced developers to utilize the PB8051 efficiently and effectively in FPGA designs, capitalizing on its compact size and high functionality.
**DRV64IMZicsr – 64-bit RISC-V Performance. Designed for Demanding Innovation.** The DRV64IMZicsr is a powerful and versatile 64-bit RISC-V CPU core, built to meet the performance and safety needs of next-generation embedded systems. Featuring the M (Multiply/Divide), Zicsr (Control and Status Registers), and External Debug extensions, this core is engineered to scale—from edge computing to mission-critical applications. As part of the DRVX Core Family, the DRV64IMZicsr embodies DCD’s philosophy of combining open-standard freedom with customizable IP excellence—making it a smart and future-proof alternative to legacy architectures. ✅ Why Choose RISC-V? * No license fees – open-source instruction set means reduced TCO * Unmatched flexibility – tailor the architecture to your specific needs * A global, thriving ecosystem – support from toolchains, OSes, and hardware vendors * Security & longevity – open and verifiable architecture ensures trust and sustainability 🚀 DRV64IMZicsr – Core Advantages: * 64-bit RISC-V ISA with M, Zicsr, and Debug support * Five-stage pipeline, Harvard architecture, and efficient branch prediction * Configurable memory size and allocation for program and data spaces Performance optimized: * **Up to 2.38 CoreMark/MHz** * **Up to 1.17 DMIPS/MHz** * Compact footprint starting from just 17.6k gates * Interface options: AXI, AHB, or native * Compatible with Classical CAN, CAN FD, and CAN XL through additional IPs 🛡️ Safety, Compatibility & Flexibility Built In: * Developed as an ISO 26262 Safety Element out of Context (SEooC) * Technology-agnostic – works seamlessly across all FPGA and ASIC vendors * Expandable with DCD’s IP portfolio: DMA, SPI, UART, I²C, CAN, PWM, and more 🔍 Robust Feature Set for Real Applications: * Full 64-bit processing – ideal for performance-intensive, memory-heavy tasks * M extension enables high-speed multiplication/division via dedicated hardware unit * Zicsr extension gives full access to Control and Status Registers, enabling: * Interrupts and exception handling (per RISC-V Privileged Spec) * Performance counters and timers * JTAG-compatible debug interface – compliant with RISC-V Debug Spec (0.13.2 & 1.0.0) 🧪 Ready for Development & Integration: * Comes with a fully automated testbench * Includes a comprehensive suite of validation tests for smooth SoC integration * Supported by industry-standard tools, ensuring a hassle-free dev experience Whether you’re designing for automotive safety, industrial control, IoT gateways, or AI-enabled edge devices, the DRV64IMZicsr gives you the performance, flexibility, and future-readiness of RISC-V—without compromise. 💡 Build smarter, safer systems—on your terms. 📩 Contact us today at info@dcd.pl to start your next RISC-V-powered project.
DRV32IMZicsr – Scalable RISC-V Power. Tailored for Your Project. Ready for the Future. The DRV32IMZicsr is a high-performance, 32-bit RISC-V processor core, equipped with M (Multiply/Divide), Zicsr (Control and Status Registers), and External Debug support. Built as part of DCD’s latest DRVX Core Family, it delivers the full flexibility, openness, and innovation that RISC-V promises—without locking you into proprietary architectures. ✅ Why RISC-V? RISC-V is a rapidly growing open standard for modern computing—backed by a global ecosystem of developers and vendors. It brings: * Freedom from licensing fees and vendor lock-in * Scalability from embedded to high-performance systems * Customizability with standard and custom instruction sets * Strong toolchain & ecosystem support 🚀 DRV32IMZicsr Highlights: * Five-stage pipeline and Harvard architecture for optimized performance * Configurable memory architecture: size and address allocation tailored to your needs Performance metrics: * **Up to 1.15 DMIPS/MHz** * **Up to 2.36 CoreMark/MHz** * Minimal footprint starting from just 14k gates * Flexible interfaces: Choose from AXI, AHB, or native bus options 🛡️ Designed for Safety & Integration: * Developed as an ISO 26262 Safety Element out of Context (SEooC) * Fully technology-agnostic, compatible with all FPGA and ASIC platforms * Seamless integration with DCD’s rich portfolio of IPs: DMA, SPI, UART, PWM, CAN, and more 🔍 Advanced Feature Set: * 32 general-purpose registers * Support for arithmetic, logic, load/store, conditional and unconditional control flow * M extension enables efficient integer multiplication/division * Zicsr extension provides robust interrupt and exception handling, performance counters, and timers * External Debug via JTAG: compliant with RISC-V Debug Specification 0.13.2 and 1.0.0, compatible with all mainstream tools 🧪 Developer-Ready: * Delivered with a fully automated testbench * Includes a comprehensive validation test suite for smooth integration into your SoC flow Whether you're building for automotive, IoT, consumer electronics, or embedded systems, the DRV32IMZicsr offers a future-ready RISC-V solution—highly configurable, performance-optimized, and backed by DCD’s 25 years of experience. Interested? Let’s build the next generation together. 📩 Contact us at info@dcd.pl
VISENGI's Bayer To RGB Converter is a bilinear interpolation hardware IP core designed to transform Bayer format pixel data into full-color RGB output. This intricate process involves interpolating missing color components at each pixel location using neighboring data, ensuring vibrant and true-to-life color replication. Capable of handling extremely high throughput, the converter facilitates one RGB pixel per cycle output with notable minimal latency. The core can be configured to support various Bayer sensor pixel bit widths, sensor signaling modes, and end-output pixel bit widths, lending it impressive flexibility across diverse applications. Equipped to handle images of unlimited sizes, the converter seamlessly integrates into existing systems using dual clock regions, thereby supporting different input and output clock logistics. Beyond this, it offers configurations that cater to resource-critical environments, optimizing logic use and adapting to specific operational constraints, making it an invaluable tool for modern imaging solutions.
Join the world's most advanced semiconductor IP marketplace!
It's free, and you'll get all the tools you need to discover IP, meet vendors and manage your IP workflow!
No credit card or payment details required.
Join the world's most advanced AI-powered semiconductor IP marketplace!
It's free, and you'll get all the tools you need to advertise and discover semiconductor IP, keep up-to-date with the latest semiconductor news and more!
Plus we'll send you our free weekly report on the semiconductor industry and the latest IP launches!