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.
KPIT's propulsion technologies cover both traditional internal combustion engines and modern electric powertrains. By focusing on reducing the total cost of ownership for new energy vehicles, KPIT helps OEMs streamline development cycles and enhance vehicle quality. The company's platform supports agile software updates and sustains efforts on sustainable practices by increasing offerings in zero-emission vehicles (ZEVs) and exploring alternative fuels like hydrogen. With solutions spanning engine subsystems, transmission, and driveline optimization, KPIT addresses the intricate balance needed between legacy and emerging automotive platforms.
The ORC3990 is a sophisticated System on Chip (SoC) solution designed for low-power sensor-to-satellite communication within the LEO satellite spectrum. Utilizing Totum's DMSS technology, it achieves superior doppler performance, facilitating robust connectivity for IoT devices. The integration of an RF transceiver, power amplifiers, ARM CPUs, and memory components makes it a highly versatile module. Leveraging advanced power management technology, this SoC supports a battery life that exceeds ten years, even within industrial temperature ranges from -40 to +85°C. It's optimized for usage with Totum's global LEO satellite network, ensuring substantial indoor signal coverage without the need for additional GNSS components. Efficiency is a key feature, with the chip operating in the 2.4 GHz ISM band, providing unparalleled connectivity regardless of location. Compact in design, comparable in size to a business card, and designed for easy mounting, the ORC3990 offers sought-after versatility for IoT applications. The ability to function with excellent TCO in terms of cost compared to terrestrial IoT solutions makes it a valuable asset for any IoT deployment focused on sustainability and longevity.
eSi-Comms represents EnSilica’s suite of communication IP blocks, designed to enhance modern communication systems through flexible, parameterized IP. These IPs are optimized for a range of air interface standards, including 4G, 5G, Wi-Fi, and DVB, providing a robust framework for both custom and standardized wireless designs.\n\nThe flexibility of eSi-Comms IP allows it to be configured for various interfacing standards, supporting high-level synchronization, equalization, and modulation techniques. The suite includes advanced DSP algorithms and control loops that ensure reliable communication links, vital for applications like wireless sensors and cellular networks.\n\nEnSilica also supports software-defined radio (SDR) applications by offering hardware accelerators compatible with processor cores like ARM, enhancing processing power while maintaining flexibility. This adaptability makes eSi-Comms IP a valuable asset in developing efficient, high-performance communication solutions that can quickly adapt to changing technological demands.
nxLink Network Infrastructure is crafted to optimize wireless network management and address latency challenges. Employing FPGA technology, it offers advanced processing capabilities that enhance network stability and performance, crucial for investment banks and market data providers. The suite incorporates features like fair bandwidth allocation, link redundancy, and fiber arbitration, ensuring reliable data transmission even under adverse conditions. nxLink is tailored for diverse networking requirements, providing scalable options that can be adapted to different infrastructural needs, thus making it an invaluable asset for maintaining competitive edge in fast-paced trading environments.
The RWM6050 Baseband Modem from Blu Wireless is a high-performance component designed for mmWave communications. It supports gigabit-level data rates through its advanced modulation and channelization technologies, making it ideal for various access and backhaul applications. The modem's substantial flexibility is attributed to its compatibility with multiple RF chipsets and its design which is influenced by Renesas collaboration, ensuring robust, scalable wireless connectivity. This modem features dual integrated modems and an adaptable digital front end, including PHY, MAC, and ADC/DAC functionalities. It supports beamforming with phased array antennas, facilitating efficient signal processing and network synchronization for enhanced performance. These attributes make the RWM6050 a key enabler for deploying next-generation wireless communication systems. Built to optimize cost efficiency and power consumption, the RWM6050 offers versatile options in channelization and modulation coding, effectively scaling bandwidth to match multi-gigabit requirements. It provides a powerful solution to meet the growing demands of modern data networks, effectively balancing performance, adaptability, and integration ease.
The NX Class of RISC-V CPU IP is crafted to serve the needs of applications such as storage, AR/VR, and AI with its potent 64-bit architecture. Its design focus lies in offering enhanced computing capabilities and data throughput, pivotal for tasks demanding high-efficiency processing. With features that support advanced data handling and computational tasks, the NX Class IP is well-suited for environments where large datasets and complex algorithms are at play. This makes it an excellent fit for AR/VR applications, where real-time data processing is paramount. The IP is complemented by an extensive development ecosystem, including SDKs and support for various RTOS/Linux environments. Its design ensures compatibility with state-of-the-art technologies, providing a reliable foundation for innovative industry solutions.
The 1000 Series by Akeana offers high-performance processing capabilities designed to tackle data-heavy computational tasks. With features aimed at enhancing throughput and power efficiency, these processors are suitable for environments that require robust processing power like AI on the edge, industrial automation, and automotive sensing. Supporting rich operating systems like Android and Linux, the 1000 Series is crafted to ensure superior performance with efficient power management, making it a prime choice for modern high-demand applications.
Designed for minimal energy usage, this detector is perfect for applications where power efficiency is critical. It's ideal for devices that remain idle for extended periods and need to reduce consumption during those times. This technology is used in wearables to lower power usage significantly when not in use, effectively extending the battery life of the device. The sensor detects static presence effectively but is also competent in recognizing touch, making it versatile for various applications. This component is adept at identifying dynamic touch events, allowing it to operate as a single button, a keyboard, slider, or proximity switch. Such versatility makes it useful in applications ranging from activating devices upon contact to function selection in various electronics. The detector’s reliability and low energy demand make it an optimal choice for energy-conscious systems. Furthermore, the Human Body Detector integrates seamlessly into IoT systems, particularly in devices requiring sustained battery life. It ensures that electronics operate effectively with minimal power, providing a significant advantage in terms of energy efficiency and operational longevity.
The hellaPHY Positioning Solution is renowned for its exceptional capabilities in cellular positioning, particularly within massive IoT environments. It leverages the strength of 5G networks to provide scalable, low-cost, positioning services with high precision. PHY Wireless has engineered it to require significantly less data than other solutions, thanks to its unique algorithmic approaches. This reduces network interactions and enhances spectral efficiency, making it an enticing option for operators and developers alike. One of the key components of this solution is its ability to function indoors and outdoors with near GNSS accuracy. By employing edge computing, the position calculations are done locally on devices, protecting user privacy and maintaining tight security on location data. The software’s minimal footprint allows for integration into existing infrastructure, offering backward compatibility and ensuring future readiness. hellaPHY stands out in the realm of positioning technology by achieving unparalleled accuracy, thanks to its efficient data utilization. It supports efficient location tracking in challenging environments, such as urban areas, where traditional GPS might falter. Furthermore, the technology offers the flexibility of over-the-air updates, keeping network utility optimal and guardband costs low through advanced spectral efficiency.
RafaelMicro's BLE 5.1 RF/MODEM/Baseband solution provides a comprehensive framework for RF communication. It includes the entire stack, from baseband to application profiles, tailored for low-power IoT implementations. This robust solution is designed to support a wide range of applications in the rapidly advancing IoT space, offering increased range, enhanced reliability, and improved energy efficiency.
The SFA 100 is designed for handling data processing tasks at the edge of IoT networks. This component is built to efficiently process data streams, making it ideal for edge computing environments where low latency and high throughput are crucial. It plays a vital role in enhancing the performance and efficiency of IoT networks by managing data processing directly at the source, thus reducing the need for data transmission back to central servers.
The Spiking Neural Processor T1 is a groundbreaking ultra-low power microcontroller designed for sensing applications that require continuous monitoring and rapid data processing while maintaining minimal energy consumption. At its core, it fuses an event-driven spiking neural network engine with a RISC-V processor, creating a hybrid chip that effectively processes sensor inputs in real-time. By boosting the power-performance efficiency in dealing with intricate AI tasks, the T1 chip allows for a wide range of applications even in battery-limited environments. In terms of capabilities, the T1 is equipped with a 32-bit RISC-V core and a substantial 384 KB embedded SRAM, which together facilitate fast recognition of patterns within sensor data such as audio signals. The processor draws on the inherent advantages of spiking neural networks, which are adept at task handling through time-sensitive events. This aspect of SNNs enables them to operate with impressive speed and with significantly reduced power requirements compared to conventional architectures. Additional features include numerous interfaces such as QSPI, I2C, UART, and JTAG, providing versatile connectivity options for various sensors. Housed in a compact 2.16mm x 3mm package, the T1 is an ideal candidate for space-constrained applications. It stands out with its ability to execute both spiking and classical neural network models, facilitating complex signal processing tasks ranging from audio processing to inertial measurement unit data handling.
Akeana offers the 100 Series, a compact and energy-efficient processor line optimized for applications demanding minimal power consumption and compact design. These processors are ideal for deeply embedded controllers across electronics that value low size, low cost, and real-time processing, such as smart home appliances, drones, and wearable technology. Designed for ultra-low power real-time processing, these processors stand out for their adaptability to small-scale, cost-sensitive environments, enabling smarter consumer electronics with efficient power management.
Bluespec's Domain-Specific RISC-V Cores are engineered to deliver enhancement in computational efficiency through systematic hardware acceleration. These cores are optimized to operate as accelerators, functioning alongside main processors to execute specific tasks more efficiently by leveraging software threads packaged as part of their design. The domain-specific approach enables application-specific tuning, ensuring that the cores provide optimum performance for targeted tasks. This feature is particularly beneficial in industries where performance and speed are critical, such as in machine learning, data processing, and high-performance computing environments. By incorporating hardware acceleration into applications, developers can achieve higher throughput and process efficiency, making these cores suitable for scenarios where intensive computation and rapid execution are required. The Domain-Specific Cores by Bluespec stand as a testament to the potential of RISC-V architecture in specialized applications.
The RT583 integrates Bluetooth 5.1/5.2 with Matter Thread standards, empowering developers to build interconnected smart home devices. With its ARM Cortex M3 MCU and multi-protocol support, it's a sophisticated solution for creating robust, interoperable smart ecosystems.
The nxAccess Trading Engine is a powerful solution that integrates FPGA technology with software flexibility, designed for high-frequency trading applications. It features a hybrid architecture that combines an FPGA data path for latency-critical operations with a software path for complex decision-making processes. This approach ensures ultra-low latency trading while preserving the flexibility needed for sophisticated algorithmic strategies. The engine allows users to preload, trigger, update, and send orders directly from hardware, achieving performance levels previously thought unattainable with traditional software solutions. It's particularly well-suited for market making, arbitrage, and high-performance trading, offering the ability to react swiftly to market changes using an embedded FPGA-based feedhandler and a pattern matcher for raw market data processing.
The 802.15.4 Transceiver Core from RF Integration is a highly specialized solution for low-power personal area networks (PANs). Compatible with the IEEE 802.15.4 standard, this transceiver is essential for applications such as Zigbee networks, which are utilized extensively in smart home and industrial IoT systems. It encompasses both RF front-end and digital baseband components needed for effective low-data-rate communication across short to medium ranges. The core is engineered to provide energy-efficient performance, catering to the needs of battery-operated devices where power conservation is paramount. By supporting diverse network topologies and node densities, it enhances the flexibility of network deployment. Additionally, it can be integrated into various products ranging from smart meters and industrial controls to personal health devices and smart lighting systems, facilitating the growth of interconnected smart applications.
The CwIP-RT is a real-time processing core tailored for applications that necessitate rapid and efficient data processing. This powerful core is ideal for environments where time-sensitive data operations are critical, providing developers with a robust platform to execute complex data tasks seamlessly. The CwIP-RT is built to manage substantial data loads while maintaining precise operational efficiency, embodying Coreworks' commitment to high-performance computing solutions. Designed for diverse computing environments, the CwIP-RT offers flexibility and reliability, ensuring that it can adapt to the varying demands of real-time applications. Its architecture supports rapid data throughput, making it suitable for cutting-edge computing systems that require swift and efficient data handling. This processing core is engineered to integrate effortlessly with existing systems, providing enhanced processing capabilities without complicating system architecture. Coreworks' attention to detail in optimizing processing performance manifests in the CwIP-RT's design, which emphasizes both speed and accuracy. It's an essential tool for developers aiming to improve the responsiveness and processing power of their systems, making it invaluable for applications that include real-time analytics, IoT, and advanced computational tasks. With the CwIP-RT, Coreworks offers a solution that pushes the boundaries of real-time processing while ensuring stability and reliability.
The iCan PicoPop® System on Module (SOM) is a high-performance miniaturized module designed to meet the advanced signal processing demands of modern avionics. Built on the Zynq UltraScale+ MPSoC from Xilinx, it provides unparalleled computational power ideal for complex computation tasks. This SOM is perfectly suited for embedded applications within aerospace sectors, offering flexibility and performance critical for video processing and other data-intensive tasks. The compactness of the PicoPop® does not detract from its capabilities, allowing it to fit seamlessly into tight spaces while providing robust functionality. The versatility and scalability of the iCan PicoPop® make it an attractive option for developers seeking high-data throughput and power efficiency, supporting enhanced performance in avionics applications. By leveraging cutting-edge technology, this module elevates the standard for embedded electronic solutions in aviation.
Combining Bluetooth 5 LE and 802.15.4 communications, the RT569 by RafaelMicro serves as a versatile RF transceiver for multi-protocol IoT applications. This RF component supports seamless integration into various embedded systems, enabling advanced connectivity and interoperability with other smart devices.
GIRD Systems offers versatile IP cores designed for digital signal processing, communication, and electronic warfare algorithms. These IP cores are crafted to be hardware-agnostic and resource-efficient, created using inferred VHDL. They provide flexibility in code portability, enabling the targeting of Xilinx, Altera, and Microsemi FPGAs, as well as ASICs, without rewriting the underlying code. This significantly decreases the time-to-market for designs intended for a multitude of platforms. Such capabilities ensure that these IP cores are suitable for various applications, accommodating different design needs with ease.
The LightningBlu solution from Blu Wireless is a groundbreaking mmWave technology platform specifically designed for high-speed rail connectivity. It offers a seamless, multi-gigabit track-to-train communication system, enhancing both passenger experience and operational efficiencies. The deployment includes trackside nodes set at regular intervals to ensure uninterrupted, high-speed data transfer between the train and trackside fiber networks. With capabilities extending up to 3.5 Gbps throughput, the system is qualified for harsh rail environments, providing reliable service over extensive ranges and supporting communication needs at speeds exceeding traditional mobile networks. The on-board train equipment is compact and works in conjunction with internal distribution networks, making it ideal for delivering internet access and entertainment services throughout the journey. The LightningBlu system operates within the 57-71 GHz spectrum, surpassing mobile 4G and even 5G speeds, ensuring continual high-speed data availability. This innovative system is a cornerstone for modernizing rail systems into the next generation of connected transport solutions, setting a new standard for rail communication infrastructure.
Sentire Radar from IMST is an advanced radar system designed for precise distance and speed measurement. Utilizing cutting-edge radar technologies, it supports applications that require high accuracy and reliability, making it ideal for both industrial and automotive sectors. This radar system incorporates multiple transmitters and receivers to facilitate complex spatial mapping. Its intelligent design enables it to not only measure but also interpret radar data for comprehensive monitoring and control applications. The flexibility of Sentire Radar allows it to adapt to diverse operational environments, providing robust solutions that are consistent and scalable. Whether employed in traffic monitoring, security systems, or industrial automation, Sentire Radar offers detailed analysis capabilities. Its integration into systems can vastly enhance the understanding of spatial dynamics, leading to improved efficiency and safety standards across various applications.
The SoC Platform offered by SEMIFIVE is an advanced solution for rapid and efficient SoC development, utilizing silicon-proven IPs and optimized design methodologies. This platform is tailored for key applications, ensuring lower costs, reduced risks, and quicker time-to-market. It leverages a domain-specific architecture, a pre-configured IP pool, and brings up hardware and software quickly, catering to AI Inference, AIoT, and HPC scenarios. The platform facilitates significant cost savings in prototyping NRE expenses and design implementation, providing a reduction of up to 50% compared to industry norms. By utilizing SEMIFIVE's infrastructure and methodology, it accelerates time-to-market, achieving faster design and verification cycles than the industry average. Moreover, it minimizes engineering risks by using a pre-verified platform IP pool and silicon-proven SoC design components. Notably, the platform supports various engagement models. These models range from the Max Efficiency Model, which uses a competitive and comprehensive platform IPs architecture, to the Max Flexibility Model, allowing configuration changes for third-party IPs. These flexible solutions maximize customer IP integration, providing an optimal system tailored to specific needs.
With an embedded ARM Cortex M3 MCU, the RT582 SoC from RafaelMicro provides efficient Bluetooth 5 Low Energy connectivity. It is ideal for smart home applications, supporting high-speed data transmission, enhanced range, and low power consumption tailored for next-generation IoT ecosystems.
This high-efficiency Bluetooth 5 Low Energy (LE) RF transceiver, model RT568 by RafaelMicro, is designed to facilitate seamless wireless communications in various IoT devices. It integrates with smaller form factor designs, offering robust performance while conserving power, making it an optimal choice for low-energy applications.
SEMIFIVE's HPC Platform offers a comprehensive solution for high-performance computing needs, integrating cutting-edge processor capabilities with advanced memory and interface options. Built around the ARM quad-core Cortex-A53, this platform supports a GDDR6 memory interface, ensuring it can handle enormous data throughput efficiently. It also incorporates PCIe Gen5 interfaces, making it ideal for heavy computational and networking tasks often required in hyperscale data centers and cloud server environments. The platform is distinctly tuned for demanding applications in high-performance AI and network processing. SEMIFIVE’s design maximizes utilization of advanced semiconductor technologies to provide superior compute functionalities while ensuring minimal latency. It facilitates rapid system deployment through a robust architecture that ensures performance optimization and energy efficiency. Targeted applications of the HPC Platform include cloud servers and high-performance AI, where the necessity for seamless data management and processing is paramount. The platform permits scalability and sustained operational excellence, making it a preferred choice for enterprises pursuing cutting-edge technological innovation in data-centric industries.
The nRF54L15 stands at the forefront of Nordic Semiconductor's ultra-low-power wireless offerings, part of their advanced nRF54L Series. With its integrated 128 MHz Arm Cortex-M33 processor, the nRF54L15 combines multiprotocol capabilities, including support for Bluetooth Low Energy, Zigbee, Thread, and other 2.4 GHz protocols. This SoC is versatile enough to run a Wi-Fi stack for the nRF70 Series ICs, making it highly adaptable for various IoT applications. The nRF54L15 offers an impressive 1.5 MB of non-volatile memory and 256 KB of RAM, catering to demanding applications that require extensive memory resources. Its ultra-low-power design ensures efficient battery utilization, making it suitable for high-volume, cost-sensitive products. Security is a key feature, with the nRF54L15 providing secure boot, secure firmware updates, and secure storage solutions. A cryptographic accelerator with anti-tampering features enhances security, offering peace of mind in IoT deployments. The comprehensive peripheral set, including a 14-bit ADC and high-speed serial interfaces, makes the nRF54L15 a robust solution for next-generation IoT devices.
Trimension UWB represents NXP's cutting-edge ultra-wideband technology designed to enhance precise sensing and positioning. This technology enables secure ranging and radar capabilities, transforming various applications across automotive, industrial, and consumer domains. It is particularly impactful in automotive systems for ensuring safety and precision in navigation and in industrial IoT for asset tracking and management. Trimension UWB technology stands out by offering high immunity to interference, maintaining performance even in challenging environments. The robust data transfer capabilities make it ideal for applications requiring real-time communication and location-based services. Its ability to support a wide range of bandwidths and frequencies allows for seamless integration into existing infrastructures, enhancing system flexibility and future readiness. The technology's advanced features make it a preferred choice for mobile devices and IoT systems, providing unparalleled accuracy in distance and location measurements. The interoperability of Trimension UWB solutions ensures compatibility with various digital ecosystems, thereby enabling new and innovative use cases in smart cities and connected vehicles. Through its unique capabilities, Trimension UWB drives advancements in secure, efficient, and precise digital interactions.
PhantomBlu is a versatile mmWave technology solution crafted for high-performance communication needs in military and defense operations. This technology provides resilient, high-bandwidth connections between mobile platforms in demanding and diverse environments, ensuring secure data transport with a minimized risk of interception or detection. The platform is equipped with advanced mesh networking capabilities, supporting communication across various domains including land, sea, and air. It provides robust connectivity solutions that facilitate effective information exchange, critical for real-time tactical operations. The PhantomBlu system's modular design allows it to adapt quickly to different operational scenarios, supporting infrastructure security and unmanned systems. PhantomBlu not only supports a high data rate significantly exceeding conventional networks like Wi-Fi and 5G but also enables seamless integration of disparate legacy systems and cutting-edge technology. Its efficient design prioritizes reduced size, weight, and power (SWaP) requirements, making it an ideal solution for deployment in constrained and resource-limited environments.