All IPs > Processor > Wireless Processor
In the rapidly evolving world of connectivity, wireless processor semiconductor IPs have become essential components for a wide array of modern electronic devices. These IPs serve as the backbone for devices requiring communication capabilities without physical connections. Typical applications include smartphones, wearables, IoT devices, and advanced embedded systems, where seamless wireless communication enhances user experience and functionality.
Wireless processor semiconductor IPs integrate multiple functionalities such as RF transceivers, baseband processors, and digital signal processing capabilities. This integration allows for efficient handling of various wireless communication standards like Bluetooth, Wi-Fi, LTE, and emerging 5G technologies. By incorporating these IPs, designers can develop compact, energy-efficient devices that maintain high-performance levels, crucial for meeting the demands of today’s connected world.
The design and delivery of wireless processor semiconductor IPs require a high degree of technical expertise and precision engineering. Companies often seek these IPs from specialized providers to ensure compliance with international standards and to expedite time-to-market. These IPs provide a flexible foundation upon which companies can build specialized products tailored to unique operational requirements, whether for consumer electronics, automotive communication systems, or industrial IoT solutions.
Furthermore, advancements in wireless processor semiconductor IPs continue to foster innovation across industries. With the increasing demand for smart devices and interconnected systems, these IPs will remain pivotal in driving forward new applications and services. As the global push toward more efficient and ubiquitous wireless communication continues, wireless processor semiconductor IPs are set to play a central role in shaping the future landscape of digital connectivity and interaction.
The 1G to 224G SerDes is a versatile serializer/deserializer technology designed to facilitate high-speed data transfers across various interface standards. It caters to stringent speed requirements by supporting a wide range of data rates and signaling schemes, allowing efficient integration into comprehensive communication systems. This SerDes technology excels in delivering reliable, low-latency connections, making it ideal for hyperscale data centers, AI, and 5G networking where fast, efficient data processing is essential. The broad compatibility with numerous industry protocols also ensures seamless interoperability with existing systems. Adapted for scalability, the 1G to 224G SerDes provides design flexibility, encouraging implementation across a variety of demanding environments. Its sophisticated architecture promotes energy efficiency and robust performance, crucial for addressing the ever-growing connectivity demands of modern technology infrastructures.
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.
RAIV represents Siliconarts' General Purpose-GPU (GPGPU) offering, engineered to accelerate data processing across diverse industries. This versatile GPU IP is essential in sectors engaged in high-performance computing tasks, such as autonomous driving, IoT, and sophisticated data centers. With RAIV, Siliconarts taps into the potential of the fourth industrial revolution, enabling rapid computation and seamless data management. The RAIV architecture is poised to deliver unmatched efficiency in high-demand scenarios, supporting massive parallel processing and intricate calculations. It provides an adaptable framework that caters to the needs of modern computing, ensuring balanced workloads and optimized performance. Whether used for VR/AR applications or supporting the back-end infrastructure of data-intensive operations, RAIV is designed to meet and exceed industry expectations. RAIV’s flexible design can be tailored to enhance a broad spectrum of applications, promising accelerated innovation in sectors dependent on AI and machine learning. This GPGPU IP not only underscores Siliconarts' commitment to technological advancement but also highlights its capability to craft solutions that drive forward computational boundaries.
The H.264 FPGA Encoder and CODEC micro footprint cores are a compact and fast solution for video compression, specifically tailored for FPGAs. This licensable IP cores support 1080p60 H.264 Baseline encoding with a single core, offering various configurations such as an H.264 Encoder, CODEC, and I-Frame Only Encoder. These cores are renowned for their small size and rapid processing capabilities, designed to be ITAR compliant for secure applications. Developers can customize these cores to achieve desired pixel depths and resolutions, ensuring adaptability to diverse project needs. With an exceptionally low 1ms latency at 1080p30, these cores are acclaimed as industry-leading in terms of both size and performance. They enhance efficiency by providing fast video processing solutions without compromising quality. The cores are particularly useful in applications demanding high-speed and high-resolution video compression in FPGA implementations. These H.264 cores come with the option for a low-cost evaluation license, providing a seamless entry into advanced video processing tasks. With customizable features, they represent a versatile choice for engineers working on applications involving intensive video encoding and decoding needs.
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.
The Dynamic Neural Accelerator II (DNA-II) Architecture by EdgeCortix represents a leap in neural network processing capabilities, designed to yield exceptional parallelism and efficiency. It employs a runtime reconfigurable architecture that allows data paths to be reconfigured on-the-fly, maximizing parallelism and minimizing memory bandwidth usage on-chip. The DNA-II core can power AI applications across both convolutional and transformer networks, making it adaptable for a range of edge applications. Its scalable design, beginning from 1K MACs, facilitates flexible integration into SOC environments, while supporting a variety of target applications. It essentially serves as the powerhouse for the SAKURA-II AI Accelerator, enabling high-performance processing in compact form factors. Through the MERA software stack, DNA-II optimizes how network tasks are ordered and resources are allocated, providing precise scheduling and reducing inefficiencies found in other architectures. Additionally, the DNA-II features efficient energy consumption metrics, critical for edge implementations where performance must be balanced with power constraints.
LightningBlu is a state-of-the-art multi-gigabit connectivity solution for high-speed rail networks, delivering continuous high-speed data transfer between trackside and train systems. This innovative solution works within the mmWave spectrum of 57-71 GHz and is certified for long-term, low-maintenance deployment. It seamlessly integrates with existing trackside networks to provide a stable, high-capacity communication bridge essential for internet access, entertainment, and real-time information services aboard high-speed trains. The LightningBlu system includes robust trackside nodes and compact train-top nodes designed for seamless installation, significantly enhancing operational efficiencies and passenger experience by providing internet speeds superior to traditional mobile broadband services. With aggregate throughputs reaching around 3 Gbps, LightningBlu sets the standard for rail communications by supporting speeds at which data demands are met with ease. Crucially, LightningBlu is a key component in transforming the railway telecommunications landscape, offering upgraded technology that enables uninterrupted and enhanced passenger digital services even in the busiest railways across the UK and USA. Through its advanced mmWave technology, it ensures that the connectivity needs of the modern commuter are met consistently and effectively, paving the way for a new era in transit communication.
The ORC3990 is a groundbreaking LEO Satellite Endpoint SoC engineered for use in the Totum DMSS Network, offering exceptional sensor-to-satellite connectivity. This SoC operates within the ISM band and features advanced RF transceiver technology, power amplifiers, ARM CPUs, and embedded memory. It boasts a superior link budget that facilitates indoor signal coverage. Designed with advanced power management capabilities, the ORC3990 supports over a decade of battery life, significantly reducing maintenance requirements. Its industrial temperature range of -40 to +85 degrees Celsius ensures stable performance in various environmental conditions. The compact design of the ORC3990 fits seamlessly into any orientation, further enhancing its ease of use. The SoC's innovative architecture eliminates the need for additional GNSS chips, achieving precise location fixes within 20 meters. This capability, combined with its global LEO satellite coverage, makes the ORC3990 a highly attractive solution for asset tracking and other IoT applications where traditional terrestrial networks fall short.
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 802.11ah HaLow transceiver is designed to provide efficient and reliable connectivity for IoT devices, utilizing sub-GHz frequencies to ensure long-range transmission while maintaining minimal power consumption. This transceiver is a perfect fit for environments where traditional Wi-Fi bands fall short due to range or power constraints. Offering superior penetration through obstacles and walls, this transceiver is ideally suited for industrial IoT, smart agriculture, and connected home systems. Its long-range capabilities make it especially useful in applications requiring broad coverage across expansive areas or dense urban settings. Beyond range enhancements, the 802.11ah HaLow standard supported by this transceiver allows for interoperability with various IoT ecosystems, simplifying device integration and promoting scalability. By balancing power efficiency and connectivity, it supports seamless operation for battery-operated devices, aiding in the creation of sustainable IoT networks.
The ultra-low-power human body detector from Microdul is engineered to provide efficient, static detection capabilities essential for wearable technology. This detector helps significantly reduce energy consumption in devices when not actively in use. Its advanced design allows it to recognize the presence or absence of a human, making it ideal for applications requiring power-saving features, such as smart devices and IoT equipment. The precise nature of its operation ensures long battery life, thereby enhancing the user experience in battery-dependent gadgets. Moreover, its application in static detection means it can operate seamlessly without requiring constant recalibration or complex interfacing. Its implementation is particularly valuable in the wearables market where minimizing power draw while maintaining functionality is a critical competitive factor. With its ability to integrate smoothly into existing systems, this detector forms an indispensable part of power-efficient device design strategies focused on long-term effectiveness in changing environments. Its versatility extends to various industries, ensuring compatibility with diverse technological ecosystems while emphasizing seamless operation and reliability. As a result, it paves the way for new possibilities in the design of cutting-edge consumer electronics.
The RWM6050 Baseband Modem is an innovative component of Blu Wireless's mmWave technology portfolio, architected to support high-bandwidth, high-capacity data communications. Designed in collaboration with industry leaders Renesas, this modem unit stands out for its efficiency and versatility, effectively marrying physical modem layers with advanced processing capabilities. The RWM6050 modem is instrumental in providing seamless data transmission for access and backhaul networks. Built to accommodate varying channelisation modes, the RWM6050 supports deep levels of customisation for different bandwidth requirements and transmission distances. It handles multi-gigabit throughput, which makes it ideal for expanding connectivity in urban or industrial areas with dense infrastructure requirements. From smart cities to complex transport systems, this baseband modem scales effectively to meet demanding data needs. Equipped with dual modems and integrated mixed-signal front-end capabilities, the RWM6050 offers a flexible solution for evolving communication infrastructures. Its design ensures optimization for real-time digital signal processing, beamforming, and adaptable connectivity management. The RWM6050 is a key enabler in unlocking the full potential of mmWave technology in a variety of settings, furthering connectivity innovations.
The RFicient chip is designed for the Internet of Things (IoT) applications, famously recognized for its ultra-low-power operations. It aims to innovate the IoT landscape by offering a highly efficient receiver technology that significantly reduces power consumption. This chip supports energy harvesting to ensure sustainable operation and contributes to green IoT development by lessening the dependency on traditional power sources. Functionally, the RFicient chip enhances IoT devices' performance by providing cutting-edge reception capabilities, which allow for the consistent and reliable transmission of data across varied environments. This robustness makes it ideal for applications in industrial IoT settings, including smart cities and agricultural monitoring, where data integrity and longevity are crucial. Technically advanced, the RFicient chip's architecture employs intelligent design strategies that leverage low-latency responses in data processing, making it responsive and adaptable to rapid changes in its operational environment. These characteristics position it as a versatile solution for businesses aiming to deploy IoT networks with minimal environmental footprint and extended operational lifespan.
The SiFive Performance family is dedicated to offering high-throughput, low-power processor solutions, suitable for a wide array of applications from data centers to consumer devices. This family includes a range of 64-bit, out-of-order cores configured with options for vector computations, making it ideal for tasks that demand significant processing power alongside efficiency. Performance cores provide unmatched energy efficiency while accommodating a breadth of workload requirements. Their architecture supports up to six-wide out-of-order processing with tailored options that include multiple vector engines. These cores are designed for flexibility, enabling various implementations in consumer electronics, network storage solutions, and complex multimedia processing. The SiFive Performance family facilitates a mix of high performance and low power usage, allowing users to balance the computational needs with power consumption effectively. It stands as a testament to SiFive’s dedication to enabling flexible tech solutions by offering rigorous processing capabilities in compact, scalable packages.
OneNav presents the innovative L5-direct GNSS Receiver, a specialized component drawing focus to accuracy and reliability by operating independently of the L1 signal. Leveraging L5 Band signals, this receiver captures and maintains precise location data while ensuring protection against signal jamming. Incorporating a single RF chain, the system reduces redundancy and facilitates optimal antenna placement to enhance device designs in space-restricted environments. This approach critically lowers system costs while delivering robust, reliable location tracking ideal for wearables and IoT applications. The L5-direct receiver integrates seamlessly across multiple satellite constellations like GPS, Galileo, QZSS, and BeiDou, delivering accurate data regardless of environmental constraints. Its refinement in multipath error reduction through machine learning ensures the most precise data acquisition, even in dense urban landscapes. Enhanced with Application Specific Array Processor, the receiver accelerates signal acquisition without sacrificing time or power, ensuring reliable operation wherever used. Additionally, L5-direct GNSS stands out by optimizing power usage, with solutions designed specifically for extended battery life in ultra-low-power devices. Its adaptability allows for integration into diverse systems, serving industries with requirements across different geographies or use cases—from standalone GNSS ASICs to flexible modems and application processors. Featuring silicon-proven capabilities, such as a hot start fix in under one second and open-sky accuracy within 1.5 meters, L5-direct GNSS leads the way for next-generation technology in critical mission deployments.
The NX Class RISC-V CPU IP by Nuclei is characterized by its 64-bit architecture, making it a robust choice for storage, AR/VR, and AI applications. This processing unit is designed to accommodate high data throughput and demanding computational tasks. By leveraging advanced capabilities, such as virtual memory and enhanced processing power, the NX Class facilitates cutting-edge technological applications and is adaptable for integration into a vast array of high-performance systems.
The eSi-Comms suite from EnSilica stands as a highly parametizable set of communications IP, integral for developing devices in the RF and communications sectors. This suite focuses on enhancing wireless performance and maintaining effective communication channels across various standards. The modular design ensures adaptability to multiple air interface standards such as Wi-Fi, LTE, and others, emphasizing flexibility and customizability.\n\nThis communication IP suite includes robust components optimized for low-power operation while ensuring high data throughput. These capabilities are particularly advantageous in designing devices where energy efficiency is as critical as communication reliability, such as in wearables and healthcare devices.\n\nMoreover, eSi-Comms integrates seamlessly into broader system architectures, offering a balanced approach between performance and resource utilization. Thus, it plays a pivotal role in enabling state-of-the-art wireless and RF solutions, whether for next-gen industrial applications or advanced consumer electronics.
Suite-Q HW is a robust system-on-chip (SoC) solution that envelops all the necessary cryptography required for secure protocols within compact and efficient hardware. Targeted at both high-end servers and low-end embedded systems, this solution emphasizes the dual benefits of scalability and adaptability. Suite-Q HW efficiently offloads demanding symmetric and asymmetric cryptographic processes by leveraging specialized accelerators, offering enhanced execution speeds that cater to different application requirements. A key component of its utility lies in its support for a wide array of cryptographic operations. This includes classical public key methods, such as ECDSA and ECDH, alongside emerging post-quantum techniques within isogeny and lattice frameworks. The hardware is further augmented by secure hash algorithms and diverse AES encryption modes, delivering comprehensive protection across a variable security landscape. Incorporating optional Differential Power Analysis (DPA) countermeasures and validated security standards, Suite-Q HW ensures security for sensitive data against contemporary and emerging threats. It facilitates integration with existing development flows across SoCs and FPGAs, optimizing power and silicon footprint according to specific needs. Furthermore, the hardware package provides comprehensive resources for integration, from testbench data to simulation scripts, enhancing its adaptability and effectiveness in today's digital security paradigm.
The RecAccel N3000 AI Inference Chip is crafted to handle the demands of AI inference workloads, delivering high efficiency and low power consumption. It supports complex neural network inference tasks, making it ideal for data-driven applications demanding real-time processing. This chip excels in environments where precision and speed are critical, offering enhanced throughput capabilities that optimize performance across various AI models. By reducing latency and improving data processing speeds, it ensures smooth operations even under heavy processing tasks. Tailored for seamless integration, the RecAccel N3000 Inference Chip provides businesses with a scalable and reliable AI processing component critical for maintaining operational flow and improving AI task management efficiency. Its architecture is designed to support emerging AI technologies, positioning it as a forward-thinking choice for enterprises looking to stay ahead of the curve.
hellaPHY Positioning Solution is an advanced edge-based software that significantly enhances cellular positioning capabilities by leveraging 5G and existing LTE networks. This revolutionary solution provides accurate indoor and outdoor location services with remarkable efficiency, outperforming GNSS in scenarios such as indoor environments or dense urban areas. By using the sparsest PRS standards from 3GPP, it achieves high precision while maintaining extremely low power and data utilization, making it ideal for massive IoT deployments. The hellaPHY technology allows devices to calculate their location autonomously without relying on external servers, which safeguards the privacy of the users. The software's lightweight design ensures it can be integrated into the baseband MCU or application processors, offering seamless compatibility with existing hardware ecosystems. It supports rapid deployment through an API that facilitates easy integration, as well as Over-The-Air updates, which enable continuous performance improvements. With its capability to operate efficiently on the cutting edge of cellular standards, hellaPHY provides a compelling cost-effective alternative to traditional GPS and similar technologies. Additionally, its design ensures high spectral efficiency, reducing strain on network resources by utilizing minimal data transmission, thus supporting a wide range of emerging applications from industrial to consumer IoT solutions.
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 NB-IoT (LTE Cat NB1) transceiver is a specialized solution catered to the unique requirements of large-scale IoT deployments within the realm of cellular networks. With a focus on low power consumption and enhanced coverage, this transceiver stands as a critical component for ensuring IoT connectivity across vast geographical distances. Its design facilitates extensive device interoperability and integration within existing LTE networks, enabling easy scalability and cost-effective implementation. The ability to handle numerous connections efficiently makes this transceiver vital for smart city projects, remote monitoring systems, and other IoT initiatives that demand long-range communication. Moreover, the NB-IoT transceiver’s adaptability allows it to penetrate barriers and reach locations where connectivity options are otherwise limited, ensuring continuous data exchange. This breadth of capability secures its position as a backbone for enabling ubiquitous IoT connectivity across diverse environments and use cases.
The memBrain™ technology is pioneering advancements in neuromorphic computing by optimizing neural network inference at the edge. By incorporating analog compute-in-memory techniques, memBrain™ efficiently handles deep neural networks' substantial Multiply-Accumulate (MAC) operations, pivotal for AI applications like video and voice recognition. This integration significantly enhances system performance by reducing system bus latencies and power consumption—achieving up to 20-fold power savings compared to conventional digital DSP methods.\n\nUtilizing SuperFlash® technology, memBrain™ stores significant synaptic weights within the floating gate, mitigating the need for off-chip storage and streamlining processing capabilities. The result is a reduction in both cost and system complexity, making advanced AI inferencing capabilities widely accessible. As AI applications evolve to require more efficient storage management, memBrain™ stands out as a solution that economizes power without compromising on performance.\n\nmemBrain™ is particularly influential in scenarios requiring efficient weight storage and MAC operations, such as large-scale neural systems. By employing a tile-based architecture, it supports numerous configurations tailored to specific application needs, ensuring scalability and adaptability in diverse AI models, from edge devices to broader AI systems. This adaptability positions memBrain™ as a forefront technology for edge AI innovations, offering robust solutions across various sectors from industrial to consumer applications.
AresCORE UCIe Die-to-Die PHY is a tailored solution for die-to-die interconnects, designed to simplify the link between chiplets within a complex system. It addresses the critical demand for reliable, high-bandwidth communication channels in multi-die packages, facilitating scalable system architectures. Capable of supporting wide bandwidth requirements, AresCORE enhances performance with minimized power consumption, essential in preventing bottlenecks in data-intensive applications. This PHY is engineered to seamlessly integrate into modern SoC designs, offering flexibility and enhanced operational efficiency. The robust architecture and comprehensive testing capabilities of AresCORE ensure data integrity and compatibility with future technological advancements. Its adaptability to various implementation scenarios makes it a suitable choice for next-generation computing technologies.
The Raptor N3000 AI Accelerator is a robust solution tailored for AI tasks, designed to optimize efficiency and speed for AI inferencing applications. Its architecture allows for accelerated computation, reducing the time needed for complex AI model processing. Equipped with ASIC technology tuned for high-performance inference, the Raptor N3000 delivers uncompromising accuracy and efficiency. It's engineered to tackle the demands of modern AI systems, ensuring tasks can be executed with minimal delay and high accuracy. This accelerator is essential for organizations needing reliable and fast AI processing solutions, providing a high-density and power-effective accelerator that seamlessly integrates into existing systems. Through its advanced interfacing capabilities, the Raptor N3000 is an indispensable asset for advancing AI capabilities across varied sectors.
The High-Performance Computing (HPC) Platform from SEMIFIVE is crafted to meet the demands of computationally intensive tasks and data-centric applications. This platform is tailored for environments that require high-speed computations and advanced data handling capabilities, featuring leading-edge processor technologies and interconnect architectures. Capable of supporting heavy data processing and complex simulations, the platform integrates the latest in processor designs with high-speed memory interfaces and robust I/O capabilities. The emphasis on optimizing throughput, latency, and efficiency makes it well-suited for use in data centers, research labs, and industrial applications needing massive data analytics power. Integrating high-bandwidth and low-latency networking capabilities, the platform ensures seamless data flow and processing. It provides scalable solutions that adapt to changing workloads, making it ideal for cloud services, real-time analytics, and AI-intensive tasks, offering robust performance characteristics that are crucial for next-gen computing environments.
Neuchips' Viper Series Gen AI PCIe Card is engineered for advanced AI applications, aiming to enhance inferencing speed and efficiency. This card is optimized for handling deep learning tasks and is well-suited for scalable AI environments, providing users with a robust solution for deploying AI applications. Its design focuses on achieving high throughput and low latency, ensuring swift execution of AI functions critical to business operations. By shifting significant computational tasks from the central processor, it allows for more efficient resource allocation and improved system performance. The Viper Series is compatible with a broad range of AI models, offering flexibility and ease of integration for modern businesses. Its emphasis on power efficiency and advanced software compatibility makes it a top choice for organizations seeking to leverage AI technology in a power-efficient manner, without compromising on performance.
The PCS2100 serves as a pillar for IoT connectivity, employing Wi-Fi HaLow technology to deliver extended range and low-power operation. It's specifically crafted to meet the unique demands of IoT devices, ensuring reliable internet access with less power consumption. The standard offers sub-GHz operation essential for improved penetration and coverage, making it ideal for industrial and smart agriculture applications. By leveraging the advantages of Wi-Fi HaLow, the PCS2100 facilitates robust communications over larger distances than traditional Wi-Fi, whilst still maintaining efficient power use—a critical factor for remote and battery-operated devices. This substantial range capability is further enhanced by its compatibility with existing Wi-Fi protocols, easing integration concerns. The PCS2100 demonstrates exceptional adaptability, catering to a wide array of IoT connectivity requirements. It supports the deployment of not only consumer-grade devices but also critical infrastructure components, underlining its importance in the advancement of smart city and AI-driven automation technologies.
Domain-Specific RISC-V Cores from Bluespec provide targeted acceleration for specific application areas by packaging accelerators as software threads. This approach enables developers to achieve systematic hardware acceleration, improving the performance of applications that demand high computational power. These cores are designed to support scalable concurrency, which means they can efficiently handle multiple operations simultaneously, making them ideal for complex scenarios that require high throughput and low latency. The ease of scalability ensures that developers can rapidly adapt their designs to meet evolving demands without extensive redesign. Bluespec’s domain-specific cores are well-suited for specialized markets where performance and efficiency can make a significant impact. By providing a robust platform for acceleration, Bluespec empowers developers to create competitive and rapidly deployable solutions.
PhantomBlu is a sophisticated mmWave communication solution specifically designed for the defense sector, empowering military operations with robust, high-performance connectivity. Leveraging advanced mmWave technology, it supports tactical connections between land, sea, and air platforms, enabling seamless IP networking over a secure, anti-jam resistant mesh network. PhantomBlu’s design is optimized for rapid deployment and versatile use across various challenging military and defense environments. The PhantomBlu system offers unprecedented connectivity and integration capabilities, supporting high-bandwidth, low-latency communications essential for defense operations. It features LPI (Low Probability of Interception) and LPD (Low Probability of Detection), ensuring stealth and operational security. Its adaptive networking solutions significantly enhance situational awareness and interoperability amongst varied defense assets, assuring seamless transfer of C4ISR data. Whether deployed across large terrains or in mobile units, PhantomBlu's resilience and scalability ensure that defense teams operate with confidence. Its advanced capabilities are critical in mitigating risks and enhancing strategic emission, making it an invaluable asset for modern military communications needs.
The Tianqiao-90 exemplifies a high-performance RISC-V CPU core designed for commercial-grade applications. This core integrates a sophisticated pipeline architecture with multiple fetching and super-scaled operations, resulting in exceptional computational capability. It's perfect for data centers, PCs, mobile devices, and high-efficiency network communications. Engineered for robust execution, the Tianqiao-90 supports the RISC-V RV64GCBH standard extensions and offers high optimization in performance and frequency. Its architecture also includes deep disorder execution, enhancing processing efficiency for complex computing tasks. With a focus on advanced machine learning and automated systems, this CPU core addresses the complexities of high-performance computing environments. The core's proven design has undergone pre-integration and rigorous testing, providing configurations of single to four-core options, simplifying SoC development. Its performance metrics boast speeds up to 9.4 SPECint2006 per GHz, with superior power efficiency, making it versatile for various applications such as enterprise-level computing, telecommunication networks, and next-gen firewalls.
The Blazar Bandwidth Accelerator Engine is an advanced memory solution that integrates in-memory computing capabilities for high-capacity, low-latency applications. This engine accelerates data processing by incorporating up to 32 RISC cores, significantly boosting data throughput and application performance. The built-in memory offers a capacity of up to 1Gb, effectively supporting high bandwidth and low latency operations critical in modern networking and data center infrastructures. Key features include the ability to perform tasks traditionally reserved for external processing units directly within the memory, reducing data movement and improving system efficiency. By embedding specific in-memory operations such as BURST and RMW functions, the Blazar engine minimizes execution time and interaction with external processors, offering optimal performance in SmartNICs and SmartSwitch applications. This accelerator engine is specifically designed to operate seamlessly with dual-port memory architectures, allowing parallel data access and processing. This feature is crucial for applications requiring high reliability and fast data aggregation, thus supporting sophisticated networking requirements inherent in 5G and advanced computing environments.
The PCS1100 is designed to support high-speed wireless communication through its advanced 4x4:4 transceiver capabilities. This Wi-Fi 6E solution extends the use of frequencies into the 6 GHz band, thereby increasing bandwidth and reducing latency in crowded networks. With its silicon-proven design, the PCS1100 ensures seamless integration into consumer electronics, offering improved connectivity and data throughput. Wi-Fi 6E technology embraced by the PCS1100 is pivotal for applications demanding high-capacity, low-latency connections, such as streaming, gaming, and virtual reality experiences. Additionally, the transceiver's ability to operate efficiently in the new spectrum addresses issues related to network congestion and interference. Incorporating the latest in Wi-Fi security standards, this transceiver is equipped to handle the increased data rates and extensive range required by modern IoT devices and smart home technology. The PCS1100 stands at the forefront of wireless innovation, providing robust connectivity solutions for current and future wireless needs.
Engineered for next-generation IoT applications, the PCS2500 functions as an access point utilizing Wi-Fi HaLow to extend connectivity for a multitude of devices. This IP supports innovations in IoT networks by providing a powerful station for device coordination, simplifying network management, and optimizing resource use throughout diverse environments. Wi-Fi HaLow's long-range and robust connection capabilities ensure that the PCS2500 can manage a greater number of nodes compared to traditional access points, all the while maintaining a reliable link with minimal power usage—a vital aspect in IoT and smart homes where energy efficiency is paramount. This makes it an integral part of large-scale IoT deployments. Notably, the PCS2500 is designed to align with existing Wi-Fi infrastructure, facilitating seamless upgrades to incorporate IoT functionality in enterprises and urban environments. Its comprehensive coverage and efficiency can propel cities toward smarter, more connected solutions, while also supporting the infrastructure necessary for smart grids and future-ready environments.
The Atlas Series from MIPS is a comprehensive suite of compute subsystems tailored for the Physical AI landscape. Combining the three core components—Sense, Think, and Act—this series enables seamless real-time processing, decision-making, and actuation for autonomous systems. The Sense component is adept at handling immense data streams for efficient sensor fusion, while the Think component empowers AI inference models for precise edge-based decision processes. Act, the final component, excels in real-time motor control and efficient energy management, completing a robust framework for modern AI applications. Designed to scale and adapt rapidly, the Atlas Series offers unmatched performance across automotive, industrial, and robotics sectors.
The BLE 5.1 RF/MODEM Baseband is a semiconductor device designed for low-energy Bluetooth applications. Its architecture supports various connectivity protocols tailored for efficient, high-performance wireless communication. Built on a robust stack and profile structure, this device excels in energy efficiency, making it ideal for applications in smart grid, smart home, and other IoT networks. This BLE 5.1 module also supports advanced location services, offering precise angle of arrival and departure features.
The Akeana 100 Series targets the demand for compact, energy-efficient processing in deeply embedded systems. Designed around a 32-bit RISC-V architecture, these processors are ideal for applications requiring real-time processing capability and low power usage. The series supports a variety of configurations in cache and closely-coupled memory, making it adaptable to diverse system requirements. This entry-level line is particularly suited to smart speakers, drones, and wearables, providing substantial flexibility for small-scale, power-constrained devices. The architecture of the Akeana 100 Series features a streamlined in-order execution pipeline, which minimizes power consumption without compromising on performance. With support for up to 64KB of data and instruction caches and closely-coupled memory, this processor series is versatile in handling fast-paced computational tasks involved in real-time environments. In addition to its performance capabilities, this processor line offers advanced features such as a physical memory protection unit and support for scalar cryptographic extensions, which deliver robust security and control in resource-sensitive applications. Customers benefit from the adaptability of this processor series, which can be tailored with additional custom instructions to meet specific market needs.
The Akeana 1000 Series is a versatile line of 64-bit RISC-V processors, offering significant configurability for data-intensive and high-performance applications. This midrange series provides support for multi-threading and both in-order and out-of-order microarchitectures, tailored to various industry needs from smart devices to automotive systems. Its comprehensive feature set allows for efficient operation with rich operating systems, such as Linux or Android, providing reliable computing power in diverse environments. With capabilities for scalable processing via a configurable issue width, the Akeana 1000 Series is ideal for edge AI, industrial automation, and advanced automotive applications, where high throughput and precision are crucial. Its architecture allows for flexible configuration of pipeline stages and memory management units, ensuring compatibility with a wide range of computation demands. This processor line offers built-in ECC support, ensuring data integrity in complex computational environments. The series' adaptability is further reinforced by support for physical memory protection, vector extensions, and hypervising capabilities, making it a comprehensive choice for mid-tier processing needs in modern technological ecosystems.
Trimension SR250 is designed to optimize application performance in ultra-wideband (UWB) technology. This solution allows for precise location tracking across a range of scenarios, including automotive and industrial applications. Its robust architecture is tailored for seamless integration with existing systems, enhancing overall functionality and user experience. Trimension SR250's UWB capabilities make it a versatile choice for developers looking to implement real-time tracking and proximity-based solutions. The SR250 module stands out for its high accuracy and reliability, which are crucial for applications requiring consistent performance in dynamic environments. This technology supports various use cases, such as enhancing vehicular safety through reliable in-car communications and expanding the capabilities of smart infrastructure. With its cutting-edge design, the Trimension SR250 ensures minimal interference, thus guaranteeing stable operations even in densely populated wireless environments. Furthermore, Trimension SR250 is engineered for energy efficiency, aligning with the industry's move towards sustainable technology use. Its power optimization features make it suitable for battery-powered devices, extending operational time without frequent charging. This innovative UWB solution exemplifies NXP's dedication to providing cutting-edge technologies that meet modern demands for precision and efficiency.
The DP8051XP is an ultra-high performance , speed- optimized softcore, of a single-chip, 8-bit embedded controller, intended to operate with fast (typically on-chip) and slow (off-chip) memories. The core was designed with a special concern about the performance to power-consumption ratio. This ratio is extended by the PMU – an advanced power management unit. The DP8051XP softcore is 100% binary-compatible with an industry-standard 8051 8-bit microcontroller. There are two configurations of the DP8051XP: Harvard, where internal data and program buses are separated, and von Neumann, with common program and external data bus The DP8051XP has a Pipelined RISC architecture and executes 120-300 million instructions per second. Dhrystone 2.1 benchmark program runs from 11.46 to 15.55 times faster than the original 80C51 at the same frequency. The same C compiler was used for benchmarking of the core vs 80C51 with the same settings. This performance can be also exploited to great advantage in low- power applications, where the core can be clocked over ten times slower than the original implementation, without performance depletion. The DP8051XP is delivered with a fully automated test bench and a complete set of tests , allowing easy package validation at each stage of the SoC design flow. Each of DCD’s 8051 Cores has built-in support for a proprietary Hardware Debug System called DoCD™. It is a real-time hardware debugger, which provides debugging capability of a whole System-on-Chip (SoC). Unlike other on- chip debuggers, the DoCD™ provides non-intrusive debugging of a running application. It can halt, run, step into or skip an instruction, and read/write any contents of the microcontroller, including all registers, internal and external program memories, and all SFRs, including user-defined peripherals. ALL DCD’S IP CORES ARE TECHNOLOGY AGNOSTIC, ENSURING 100% COMPATIBILITY WITH ALL FPGA AND ASIC VENDORS.
Trimension SR040 is engineered for ultra-precision tracking and communication in fast-evolving technological landscapes, particularly focusing on proximity-based applications. This module is crucial for systems where detailed spatial awareness and communication are required, like in industrial automation and automotive safety applications. It effectively bridges the gap between advanced technology and practical, everyday usage through its precise UWB capabilities. Among its innovative features, the SR040 supports seamless integration into broader systems, enhancing network capabilities and improving device-to-device communication. This is particularly beneficial in crowded signal environments where reliable communication is necessary. The SR040 allows for tight spatial resolutions and high accuracy, making it a trusted choice for developers who need consistent and reliable performance. NXP developers focused on energy optimization to ensure the SR040 meets the industry's call for environmentally friendly solutions. Its ability to operate efficiently on minimal power supports the longevity of battery-driven devices. As smart technology becomes more prevalent, the Trimension SR040 stands out by offering efficient, scalable, and sustainable solutions for future connectivity challenges.
Designed for high-precision, short-range location services, the Trimension SR150 offers unrivaled performance in UWB technology for spatial awareness applications. This product serves industries such as automotive and industrial automation, where short-range communication and location tracking are critical. Fully compatible with modern technologies, the SR150 module enables seamless interactions within smart ecosystems. The versatility and adaptability of the Trimension SR150 make it perfect for various applications, including real-time asset tracking and enhanced vehicular communication systems. It significantly improves situational awareness, providing insights that are essential for safety and efficiency in automotive and industrial settings. The robust capabilities of the SR150 module ensure that it retains superior functioning amidst challenging environments. Combining state-of-the-art technology with energy-efficient design, the Trimension SR150 highlights NXP’s commitment to sustainability and innovation. Its low power consumption extends device lifespan, making it an ideal component for devices requiring long operation times. By focusing on providing stable and accurate UWB performance, this product supports the growing demand for precise and reliable location services.
The Cortus NB-Iot C200 is designed to fulfill the growing demand for efficient NB-IoT solutions, particularly in the realm of low-power wide-area networks (LPWANs). Tailored to support a broad spectrum of IoT applications, this product promises exceptional power efficiency and extended coverage, crucial for devices operating in remote locations or challenging environments. Thanks to its integration within a robust RISC-V architecture, the NB-Iot C200 offers enhanced connectivity capabilities while maintaining reduced energy consumption. Apart from its technical specifications, the NB-Iot C200 is crafted with versatility in mind, making it suitable for both consumer and industrial uses. It can be deployed to streamline operations in smart cities, agriculture, logistics, and manufacturing sectors, offering real-time data collection and delivery. By incorporating advanced features that ensure secure data communication, this solution stands out as a reliable component for future IoT networks. Additionally, the NB-Iot C200 is designed to seamlessly integrate with Cortus' existing suite of intellectual property, allowing developers to build customized solutions that align with specific project requirements. This flexibility ensures that the product remains applicable across a wide variety of devices and industry needs, reinforcing its placement as a cornerstone in Cortus' diverse product lineup.
The RT568 is a Bluetooth 5 Low Energy RF transceiver designed to deliver enhanced wireless connectivity with minimal power consumption. It integrates seamlessly with microcontroller systems, offering a variety of interface options for flexible design integration. With excellent sensitivity and robust RF blocking-resilience, it is ideal for smart devices that require quick response times and stable wireless communication. The RT568 supports multiple wireless standards, ensuring reliable performance in diverse IoT environments.
The RT569 is an advanced RF transceiver capable of supporting multiple wireless communication protocols, including Bluetooth 5 Low Energy and 802.15.4. Built for versatility, it is crucial for applications that require interoperability between different wireless standards. It excels in maintaining high data rates and robust connectivity, even in challenging environments. This makes it particularly useful in smart home devices and industrial applications where consistent connectivity is required over extended ranges.
The RT583 is designed to support Matter, a unified connectivity standard, along with Thread and Bluetooth 5 LE technologies. This SoC facilitates the creation of highly interoperable smart home devices, ensuring seamless communication across various platforms and brands. With integrated advanced security features, the RT583 is primed for applications that demand reliable and secure connectivity, such as in-home automation and professional installations. It provides a solid foundation for rapidly developing smart home ecosystems.
The RT582 is a high-performance system-on-chip (SoC) incorporating Bluetooth 5 Low Energy connectivity paired with robust processing capabilities. Built around an ARM Cortex-M3 core, it provides efficient handling of wireless protocols and application processing. This SoC supports a variety of communication standards and features an extensive range of peripherals, thus offering flexibility and efficiency for IoT device development. It is particularly suited for applications like wearables and home automation where power efficiency and solid performance are priorities.
SB1001-00, a BLE 6.0 Subsystem IP, consists of an integrated Controller and Modem paired to a proprietary RF on T22 ULL. It is suitable for ASIC developers or fabless semiconductor companies who want to add BLE functionality without the hassle of dealing with multiple IP vendors or design groups. It features ultra-low active and deep-sleep power consumption and high TX power with industry-leading RX sensitivity for reliable, longer-range BLE communications. Key applications include wireless sensing networks, smart lighting, and portable medical devices.
The SB1001-C/M BLE 6.0 digital modem and baseband controller IP enables industry-leading, ultra-efficient, wireless SoCs for a multitude of connected applications. It supports all key features up to BLE 6.0, such as distance measurement, audio, mesh, and channel sounding. The modem offers industry-leading link budget for RF environment reliability and resilience. A Zephyr driver is included for ease of host integration. Our software development and testing environment greatly reduces development times, enabling significantly faster time to market compared to most large players.
VibroSense Tiny AI Chip stands out as a solution to the Industrial IoT (IIoT) challenge of handling massive data volumes generated by vibration sensors. Based on a Neuromorphic Analog Signal Processor, this chip preprocesses vibration data directly at the sensor, significantly reducing the amount of data that needs to be transmitted and stored. It's an ideal component for predictive maintenance systems, where early detection of machine conditions can prevent costly failures. The VibroSense chip enables streamlined communications across long distances with narrow bandwidth, which lessens operational expenses while ensuring precise and timely decision-making in industrial settings. This chip's application spectrum spans various machinery, from engines to wind turbines, promising substantial advances in efficiency and reliability.
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