All IPs > Wireless Communication > 802.11
Under the Wireless Communication category, the 802.11 subcategory holds significant importance due to the ubiquitous need for seamless connectivity in our increasingly digital world. At the forefront of this connectivity revolution is the semiconductor IP for 802.11, commonly known as Wi-Fi technology. This category encompasses an array of semiconductor IP cores and components dedicated to the implementation and enhancement of Wi-Fi capabilities in a multitude of products.
802.11 semiconductor IPs are fundamental in providing the design blocks that enable the integration of Wi-Fi technology into various devices, ranging from consumer electronics like smartphones and tablets to industrial IoT devices and automotive systems. These IPs facilitate robust wireless communication by optimizing data transmission speeds, improving connection stability, and ensuring secure data exchange over wireless networks. By utilizing these IPs, semiconductor designers can expedite the development process, reduce costs, and enhance the overall performance of their products.
Inside this category, you’ll find a variety of solutions that cater to different aspects of wireless communication, including IPs for 802.11a/b/g/n/ac/ax standards. These IPs are engineered to support varying bandwidths and frequencies, thus catering to specialized applications ranging from simple data transfer to high-definition video streaming and critical real-time applications. The adaptability of these semiconductor IPs plays a crucial role in enabling devices to maintain seamless connectivity even in congested or challenging network environments.
In summary, the 802.11 wireless communication semiconductor IP category is a pivotal component within the Silicon Hub catalog, offering diverse solutions to meet the ever-growing demand for wireless technology in modern devices. By providing essential building blocks for efficient wireless communication, these IPs help manufacturers design integrated circuits that deliver superior connectivity, speed, and reliability. This ensures that end-users enjoy seamless and uninterrupted connectivity in both personal and professional capacities.
**Ceva-Waves Links** is a growing family of multi-standard wireless platforms. By optimizing connectivity support for various combinations of **Wi-Fi, Bluetooth, 802.15.4, and ultra-wideband (UWB)**, the Ceva-Waves Links family provides preconfigured, optimized solutions for SoCs requiring multiple connectivity standards. All Ceva-Waves Links configurations are based on field-proven Ceva-Waves hardware IP and software stacks. Unique Ceva coexistence algorithms ensure efficient and interference-free operation of multiple connections while sharing one radio. The **Ceva-Waves Links family** offers combinations of Ceva-Waves Wi-Fi, Ceva-Waves Bluetooth, 802.15.4 (supporting protocols such as Thread, Matter and Zigbee), and Ceva-Waves UWB hardware IP, integrated with Ceva or third-party radios and CPU- and OS-agnostic software stacks. New platforms will be introduced to address market trends or customers’ demands. [**Learn more about Ceva-Waves Links family solution>**](https://www.ceva-ip.com/product/ceva-waves-links/?utm_source=silicon_hub&utm_medium=ip_listing&utm_campaign=ceva_waves_links_page)
The Low Density Parity Check (LDPC) codes are powerful, capacity approaching channel codes and have exceptional error correction capabilities. The high degree of parallelism that they offer enables efficient, high throughput hardware architectures. The ntLDPC_WiFi6 IP Core is based on an implementation of QC-LDPC Quasi-Cyclic LDPC Codes and is fully compliant with IEEE 802.11 n/ac/ax standard. The Quasi-Cyclic LDPC codes are based on block-structured LDPC codes with circular block matrices. The entire parity check matrix can be partitioned into an array of block matrices; each block matrix is either a zero matrix or a right cyclic shift of an identity matrix. The parity check matrix designed in this way can be conveniently represented by a base matrix represented by cyclic shifts. The main advantage of this feature is that they offer high throughput at low implementation complexity. The ntLDPC_WiFi6 decoder IP Core may optionally implement one of two approximations of the log-domain LDPC iterative decoding algorithm (Belief propagation) known as either Layered Normalized Offset Min-Sum Algorithm or Layered Lambda-min Algorithm. Selecting between the two algorithms presents a decoding performance .vs. system resources utilization trade-off. The core is highly reconfigurable and fully compliant to the IEEE 802.11 n/ac/ax Wi-Fi4, Wi-Fi5 and Wi-Fi 6 standards. The ntLDPC_WiFi6 encoder IP implements a 81-bit parallel systematic LDPC encoder. An off-line profiling Matlab script processes the original matrices and produces a set of constants that are associated with the matrix and hardcoded in the RTL encoder.
The ARINC 818 Product Suite by Great River Technology provides a comprehensive solution for high-performance digital video transmission in avionics applications. It supports the implementation, qualification, testing, and simulation of ARINC 818 products. This suite allows developers to access essential ARINC 818 tools and resources. It ensures optimal performance and reliability in mission-critical equipment by offering both hardware and software components tailored for the ARINC 818 standard. With its focus on high-speed data transfer and signal integrity, the ARINC 818 Product Suite is ideal for applications requiring lossless video transmission and real-time data handling in challenging conditions.
Convolutional FEC codes are very popular because of their powerful error correction capability and are especially suited for correcting random errors. The most effective decoding method for these codes is the soft decision Viterbi algorithm. ntVIT core is a high performance, fully configurable convolutional FEC core, comprised of a 1/N convolutional encoder, a variable code rate puncturer/depuncturer and a soft input Viterbi decoder. Depending on the application, the core can be configured for specific code parameters requirements. The highly configurable architecture makes it ideal for a wide range of applications. The convolutional encoder maps 1 input bit to N encoded bits, to generate a rate 1/N encoded bitstream. A puncturer can be optionally used to derive higher code rates from the 1/N mother code rate. On the encoder side, the puncturer deletes certain number of bits in the encoded data stream according to a user defined puncturing pattern which indicates the deleting bit positions. On the decoder side, the depuncturer inserts a-priori-known data at the positions and flags to the Viterbi decoder these bits positions as erasures. The Viterbi decoder uses a maximum-likelihood detection recursive process to cor-rect errors in the data stream. The Viterbi input data stream can be composed of hard or soft bits. Soft decision achieves a 2 to 3dB in-crease in coding gain over hard-decision decoding. Data can be received continuously or with gaps.
**Ceva-Waves Wi-Fi platforms portfolio** provide a comprehensive selection of hardware IP and CPU-agnostic host software for energy-efficient SoC implementation of any of a wide range of Wi-Fi subsystems, from Wi-Fi 4 to Wi-Fi 7, for both client devices and access points. The portfolio includes a suite of pre-optimized solutions for various generations and configurations for specific Wi-Fi uses, power consumption levels, and price points, ranging from low-bandwidth IoT connectivity to high-bandwidth hubs. Embedded into one of the Ceva-Waves Links multi-protocol wireless platforms, the Ceva-Waves Wi-Fi IPs can efficiently co-exist with the Ceva-Waves Bluetooth IPs and/or Ceva-Waves UWB IP. The Ceva-Waves Wi-Fi platforms comprise hardware modem PHY IP that supports DSSS, CCK, OFDM and OFDMA modulations; optimized MAC IP that offloads MAC functions from the CPU; and a comprehensive selection of MAC protocol software stacks. The IP and software elements are further organized into three main solution profiles. * Wi-Fi IoT is for energy-efficient low-bandwidth connectivity for IoT devices, supporting 2.4GHz single band or dual/triple bands on 2.4/5/6 GHz for IEEE 802.11n, ax, or be (Wi-Fi 4, 6 or 7). * Wi-Fi High-Performance supports up to 160 MHz bands at 2.4, 5, or 6 GHz in either single-antenna or 2×2 MIMO mode for IEEE 802.11ax or be (Wi-Fi 6 or 7), and is intended for consumer media-streaming applications. * Wi-Fi Access Point supports 160 MHz bands and 2×2 MIMO for IEEE 802.11ax or be (Wi-Fi 6/6E/7), for applications such as media access points, gateways, and small-cell offload that must support up to hundreds of clients. The Ceva-Waves Wi-Fi platforms include a coexistence interface that permits highly efficient operation with the Ceva-Waves Bluetooth platforms. [**Learn more about Ceva-Waves Wi-Fi solution>**](https://www.ceva-ip.com/product/ceva-waves-wi-fi/?utm_source=silicon_hub&utm_medium=ip_listing&utm_campaign=ceva_waves_wifi_page)
The Digital Radio (GDR) from GIRD Systems is an advanced software-defined radio (SDR) platform that offers extensive flexibility and adaptability. It is characterized by its multi-channel capabilities and high-speed signal processing resources, allowing it to meet a diverse range of system requirements. Built on a core single board module, this radio can be configured for both embedded and standalone operations, supporting a wide frequency range. The GDR can operate with either one or two independent transceivers, with options for full or half duplex configurations. It supports single channel setups as well as multiple-input multiple-output (MIMO) configurations, providing significant adaptability in communication scenarios. This flexibility makes it an ideal choice for systems that require rapid reconfiguration or scalability. Known for its robust construction, the GDR is designed to address challenging signal processing needs in congested environments, making it suitable for a variety of applications. Whether used in defense, communications, or electronic warfare, the GDR's ability to seamlessly switch configurations ensures it meets the evolving demands of modern communications technology.
The RISCV SoC developed by Dyumnin Semiconductors is engineered with a 64-bit quad-core server-class RISCV CPU, aiming to bridge various application needs with an integrated, holistic system design. Each subsystem of this SoC, from AI/ML capabilities to automotive and multimedia functionalities, is constructed to deliver optimal performance and streamlined operations. Designed as a reference model, this SoC enables quick adaptation and deployment, significantly reducing the time-to-market for clients. The AI Accelerator subsystem enhances AI operations with its collaboration of a custom central processing unit, intertwined with a specialized tensor flow unit. In the multimedia domain, the SoC boasts integration capabilities for HDMI, Display Port, MIPI, and other advanced graphic and audio technologies, ensuring versatile application across various multimedia requirements. Memory handling is another strength of this SoC, with support for protocols ranging from DDR and MMC to more advanced interfaces like ONFI and SD/SDIO, ensuring seamless connectivity with a wide array of memory modules. Moreover, the communication subsystem encompasses a broad spectrum of connectivity protocols, including PCIe, Ethernet, USB, and SPI, crafting an all-rounded solution for modern communication challenges. The automotive subsystem, offering CAN and CAN-FD protocols, further extends its utility into automotive connectivity.
D2D® Technology, developed by ParkerVision, is a revolutionary approach to RF conversion that transforms how wireless communication operates. This technology eliminates traditional intermediary stages, directly converting RF signals to digital data. The result is a more streamlined and efficient communication process that reduces complexity and power consumption. By bypassing conventional analog-to-digital conversion steps, D2D® achieves higher data accuracy and reliability. Its direct conversion approach not only enhances data processing speeds but also minimizes energy usage, making it an ideal solution for modern wireless devices that demand both performance and efficiency. ParkerVision's D2D® technology continues to influence a broad spectrum of wireless applications. From improving the connectivity in smartphones and wearable devices to optimizing signal processing in telecommunication networks, D2D® is a cornerstone of ParkerVision's technological offerings, illustrating their commitment to advancing communication technology through innovative RF solutions.
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.
ntRSD core implements a time-domain Reed-Solomon decoding algorithm. The core is parameterized in terms of bits per symbol, maximum codeword length and maximum number of parity symbols. It also supports varying on the fly shortened codes. Therefore any desirable code-rate can be easily achieved rendering the decoder ideal for fully adaptive FEC applications. ntRSD core supports erasure decoding thus doubling its error correction capability. The core also supports continuous or burst decoding. The implementation is very low latency, high speed with a simple interface for easy integration in SoC applications.
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 802.11n/ac/ax LDPC decoder is developed for high throughput WLAN applications. It features layered decoding, soft decision decoding, and is compliant with IEEE 802.11n/ac/ax standards. The decoder supports all LDPC code rates of ½, ⅔, ¾, and ⅚, as well as all LDPC codeword sizes of 648, 1296, and 1944 bits. This IP provides a high throughput design and allows for frame-to-frame on-the-fly configuration, offering configurable LDPC decoding iterations for a trade-off between throughput and error correction performance.
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.
ParkerVision's Energy Sampling Technology is a state-of-the-art solution in RF receiver design. It focuses on achieving high sensitivity and dynamic range by implementing energy sampling techniques. This technology is critical for modern wireless communication systems, allowing devices to maintain optimal signal reception while consuming less power. Its advanced sampling methods enable superior performance in diverse applications, making it a preferred choice for enabling efficient wireless connectivity. The energy sampling technology is rooted in ParkerVision's expertise in matched filter concepts. By applying these concepts, the technology enhances the modulation flexibility of RF systems, thereby expanding its utility across a wide range of wireless devices. This capability not only supports devices in maintaining consistent connectivity but also extends their battery life due to its low energy requirements. Overall, ParkerVision's energy sampling technology is a testament to their innovative approach in RF solutions. It stands as an integral part of their portfolio, addressing the industry's demand for high-performance and energy-efficient wireless technology solutions.
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.
SEMIFIVE’s AIoT Platform targets smart environmental ecosystems, offering convergence of AI capabilities with IoT frameworks. This platform enhances connectivity and intelligence in next-generation smart devices and facilities, integrating edge computing and AI capabilities to enable intelligent data processing and real-time action. The AIoT platform is equipped with multi-core processing capabilities, providing energy-efficient solutions suited for edge environments. This facilitates distributed AI computations right where data is generated, significantly improving response times and reducing backhaul costs compared to traditional centralized models. Designed to support a wide range of devices and systems, the platform allows developers to build solutions that are scalable and adaptable to various IoT applications. It provides comprehensive hardware-software co-design solutions, simplifying the development process for applications like smart homes, industrial IoT systems, and intelligent transportation networks.
IMST's Custom Radio Modules offer innovative, easy-to-integrate wireless solutions for various applications. Designed for use in license-free frequency bands, these modules support embedded software, RF circuit design, and are compatible with a range of wireless standards. Whether creating a custom device or developing new technologies, this solution provides step-by-step support throughout the entire process, ensuring that clients can leverage advanced wireless communications smoothly and effectively.
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.
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 802.11 Transceiver Core designed by RF Integration provides comprehensive connectivity solutions for wireless networking. This core is optimized for the IEEE 802.11 a/b/g/n standards, ensuring high-speed data transmission and robust local area network coverage. It supports MIMO architectures and OFDM signals, allowing data throughput up to 600Mbps, which is essential for modern wireless infrastructure and consumer electronics. The transceiver core integrates seamlessly with existing digital processing systems, providing a reliable wireless connection essential for various applications, from smart home devices to enterprise network setups. Its sophisticated design minimizes power consumption and cost, making it a practical choice for developers looking to implement efficient wireless solutions. Incorporating both RF and mixed-signal elements, the 802.11 Transceiver Core is designed to deliver high performance even in environments prone to interference. This makes it ideal for use in areas requiring high bandwidth and stable performance over large coverage areas. RF Integration's focus on quality and innovation ensures this core remains a leader in the wireless technology market, driving forward connectivity capabilities in a range of devices.
The 802.11 LDPC core by Wasiela is designed to provide high data rate wireless communication with increased error correction capabilities. Leveraging low-density parity-check (LDPC) codes, this product significantly enhances the reliability of wireless networks by correcting errors that occur during data transmission. It is particularly tailored for environments where maintaining high throughput is critical, such as in dense urban areas or during streaming high-definition content across networks. Wasiela’s design implements an efficient iterative decoding process, adjusting the number of iterations dynamically to ensure optimal performance. The 802.11 LDPC is compatible with various wireless communication standards, making it a versatile choice for manufacturers aiming to integrate robust error correction features in their devices. This core is also optimized for low power consumption, ensuring it meets the power efficiency standards required by modern wireless devices. By ensuring frame-to-frame configuration capabilities, the 802.11 LDPC core not only operates efficiently under varying conditions but also provides seamless adaptability across different data rates. This adaptability makes it well-suited for evolving network demands, meeting the needs of next-generation applications with ease.
Actt's 2.4GHz ISM Band RF technology offers a highly integrated RF solution tailored for modern wireless communication needs. This IP is built to support low power consumption while maintaining high performance standards, suitable for both industrial and consumer applications that operate within the 2.4GHz ISM band. Designed to facilitate seamless wireless communication, this RF technology is compatible with multiple protocols including Bluetooth, enhancing its applicability across a host of devices. Its low energy footprint allows it to be used effectively in battery-powered devices without draining the power supply, ensuring prolonged functioning. The 2.4GHz ISM Band RF technology is engineered to handle extensive data transmission, providing robust and reliable connectivity. This makes it perfect for applications in areas such as home automation, health monitoring devices, and personal electronics looking to leverage this band for efficient communication.
The Wireless Baseband IP from Low Power Futures is designed to optimize ultra-low-power consumption while minimizing footprint and code size. It includes a comprehensive configuration of baseband processor hardware IP, link layer, or medium access control layer firmware, built specifically for IoT applications including beacons, smart sensors, connected audio, and more. The IP offers easy integration into systems on a chip (SoC) and has been fully validated on an FPGA platform to ensure standards compliance and ease of use for developers. Built-in security features further enhance its suitability for secure IoT device deployments.
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.
Blu Wireless's Application Software is an integral aspect of their mmWave solutions, crafted to maximize the performance and adaptability of their communication networks. This software suite supports IEEE 802.11ad and 11ay compliance, facilitating advanced wireless mesh networking, mobility management, and comprehensive network oversight. It is specifically designed to cater to the complex needs of service providers across multiple high-demand applications. The Application Software enables rapid data transfer rates, boasting throughput capabilities up to 3.5 Gbps—dramatically quicker than traditional broadband services. By harnessing high-frequency mmWave bands, it offers improved performance, increased range, and robust mobility support. Its design also allows for post-deployment updates and custom configurations, ensuring networks remain agile and responsive to evolving demands. A standout feature of Blu Wireless’s application solutions is the Mobile Connection Manager (MCM), developed initially for the railway sector but now adaptable for broader vehicle and high-mobility use cases. This offers tailored network management possibilities, crucial for maintaining high-quality connections across challenging and dynamic environments.
Built to facilitate low-power, short-range communications, Low Power Futures' IEEE 802.15.4 WPAN offering is crafted to include both the physical and MAC layers for compliance with recent amendments of the IEEE standard. The design supports BPSK and OQPSK modulations with optional GFSK modulator, covering sub-gigahertz and 2.4 GHz frequency bands. It's equipped with built-in security features, making it fitting for applications requiring reliable, low-power networking such as home automation, smart metering, and industrial IoT communications.
The WiFi/WLAN IP Core designed for FPGA and DSP systems provides a robust solution for wireless LAN implementation according to IEEE 802.11 standards. Built to operate effectively across different hardware platforms, this IP core combines both PHY and MAC layer functionalities, ensuring compliance with various WLAN protocols. The physical layer utilizes technologies like OFDM for high data rate transmission, and the MAC layer supports operations over multiple processor brands including ARM and Motorola. Suitable for different DSP and FPGA architectures, the core is adaptable, allowing seamless hardware integration with minimal effort. This flexibility ensures that the design can accommodate both current and future WLAN technological advancements, making it a cost-effective choice for developers focused on creating cutting-edge wireless solutions.
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.
ChipCraft's GNSS Receiver addresses a diverse set of positioning requirements by integrating advanced technologies in satellite navigation. This GNSS core is a powerhouse of precision and efficiency, offering solutions with robust performance capabilities for a multitude of applications, including IoT devices and autonomous vehicles. Engineered for reliability, the GNSS Receiver delivers rapid time-to-first-fix, even in challenging environments, enhancing its suitability for ground-breaking navigation solutions. Its compatibility with multiple GNSS constellations ensures users receive an uninterrupted stream of precise location data. The scalable design of the GNSS Receiver supports integration with other systems, such as RISC-V processors, to optimize functionality across various platforms. It is primed for tasks needing high accuracy and dependability, such as mapping, surveying, and smart city infrastructure monitoring. By leveraging ChipCraft's silicon-proven IP, this GNSS Receiver offers a reliable, comprehensive solution with reduced power consumption and significant space savings, demonstrating ChipCraft's dedication to advancing GNSS technology into new industry standards.
The RT990 trans-impedance amplifier caters specifically to optical CATV applications, delivering superior signal amplification and clarity. It provides seamless integration into cable television networks, enhancing signal reception and transmission quality. Designed to tackle common issues such as signal attenuation and noise, the RT990 ensures comprehensive coverage and reliable transmission over wide areas. Its deployment in CATV systems results in efficient signal processing, facilitating better-quality broadcasts.
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.
The GRT Velocity PXIe Card is a high-performance ARINC 818 frame grabber and video converter designed by Great River Technology. It is engineered to meet the demands of rapid digital data processing in avionics systems. This card captures and processes video data with high efficiency, providing seamless integration into existing avionics infrastructures. The product's capabilities include converting video data formats and enabling real-time video signal management that is crucial in flight operations. The PXIe Card is noted for its reliability and performance, making it suitable for both development environments and operational deployment in aircraft systems, where precise video data handling is essential.
The Complex Digital Down Converter (DDC) offered by Zipcores plays a vital role in signal processing, primarily used to downconvert a frequency domain signal to baseband using complex mixing. It is highly applicable in software-defined radio and communication applications where signal bandwidth is reduced for further processing stages. Engineered to ensure high precision, this DDC efficiently processes digital samples, adapting to different input data rates and formats, making it a versatile solution for both military and commercial communication systems. Its design accommodates significant data manipulation while preserving system resources, thus enhancing deployment in scalable architectures. The core utilizes innovative algorithms to minimize errors during frequency conversion, which is critical for maintaining fidelity in demodulated signals. This capability makes it suitable for advanced signal analysis applications where clarity and accuracy of the output are imperative. With its robust adaptability, it meets the needs of complex DSP tasks across various platforms.
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