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.
Great River Technology offers the ARINC 818 Product Suite, a comprehensive collection of tools and products designed to cover the full spectrum of ARINC 818 applications. This suite is pivotal for engineers and designers who are focused on the aviation sector, providing solutions necessary for the creation, testing, and deployment of high-speed digital interfaces in avionics. The suite supports design and implementation phases by offering robust support tools tailored for ARINC 818 development, including detailed implementers' guides and simulation resources. What's unique about this suite is its ability to facilitate process integrations for ARINC 818 standards across various platforms, making it adaptable for differing needs in aviation systems. The integration tools provided ensure that systems can efficiently manage data and video transmissions, providing clarity, speed, and reliability, all essential factors in mission-critical environments. Great River Technology’s ARINC 818 Product Suite is engineered to ensure seamless interoperability, offering support from initial project development through to practical operation, thus enabling avionic systems to function optimally in both standard and specialized conditions.
**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)
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.
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.
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 RISCV SoC - Quad Core Server Class is engineered for high-performance applications requiring robust processing capabilities. Designed around the RISC-V architecture, this SoC integrates four cores to offer substantial computing power. It's ideal for server-class operations, providing both performance efficiency and scalability. The RISCV architecture allows for open-source compatibility and flexible customization, making it an excellent choice for users who demand both power and adaptability. This SoC is engineered to handle demanding workloads efficiently, making it suitable for various server applications.
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.
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 802.11ah HaLow Transceiver by Palma Ceia SemiDesign is crafted to meet the rigorous demands of modern IoT applications, which require efficient power usage and extended connection ranges. Conforming to the Wi-Fi HaLow standard, this transceiver is pivotal for developing low-power, long-range wireless networks. The device is equipped to handle various bandwidths and supports a wide frequency range, ensuring connectivity over great distances without compromising on power efficiency. Integrated features enable low-noise operations and real-time signal processing enhancements, which are crucial for maintaining high-quality links in variable environments. This transceiver is especially suited for battery-operated IoT devices, providing flexibility in design with its interfaces and calibration mechanisms. Its versatile nature makes it an asset for applications such as smart meters, security systems, and other automated infrastructure components, facilitating robust and secure communication across various IoT settings.
The FCM1401 is a highly efficient 14GHz CMOS power amplifier tailored for applications within the Ku-band spectrum, typically ranging from 12.4GHz to 16GHz. It excels in performance by delivering significant RF output power also characterized by a gain of 22dB. This amplifier is engineered with a power added efficiency (PAE) of 47%, making it an optimal choice for long-range communication systems where energy conservation is paramount. Additionally, it operates with a supply voltage of 1.8V, which aligns with its design for lower power consumption. This product is available in a QFN package, providing a compact solution for modern RF system designs.
eSi-Comms brings highly parametisable communications technology to the table, offering a flexible solution that can be tailored to specific interfacing needs. This IP supports a range of communication protocols and is designed to meet critical system requirements while minimizing integration risks and optimizing performance.
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 from Palma Ceia SemiDesign supports cellular-based IoT communications, compliant with 3GPP Release 13. Engineered for reliability, this transceiver is built to facilitate low-power wide-area network (LPWAN) applications, ideal for a plethora of IoT devices. Supporting a comprehensive frequency range, the transceiver is equipped with advanced features to improve signal reception and transmission even under challenging conditions. This includes internal calibration features for correcting signal offsets and mitigating IQ mismatch, which enhances overall connectivity reliability and throughput. This transceiver fulfills key IoT requirements such as long battery life and dependable network integration in both urban and rural settings. It is adaptable to various environmental conditions, making it suitable for applications in fields such as metering, asset tracking, and environmental monitoring where robust, wide-ranging connectivity is critical.
The SEMIFIVE AIoT Platform is designed to seamlessly integrate artificial intelligence and IoT functionalities into a single custom silicon framework. This platform offers a comprehensive ecosystem that supports smart device manufacturing and deployment by leveraging pre-verified IP cores tailored for AIoT applications. By employing advanced design methodologies, the platform provides extensive connectivity options and adaptable processing cores suited for edge computing. This facilitates real-time data processing and decision-making at the device level, enhancing the efficiency and responsiveness of AIoT systems. With its robust framework, the platform minimizes design complexity and accelerates product development cycles, allowing industries to swiftly innovate within the AIoT space. Its scalable architecture supports a wide range of AIoT applications, ensuring interoperability and seamless operation across diverse technology environments.
Crafted for high-frequency applications, the FCM3801-BD is a 39GHz CMOS power amplifier that addresses the needs of 5G mmWave communication systems. Its capability to operate across frequencies of 32GHz to 44GHz positions it as a versatile choice for next-gen network infrastructure, ensuring robust signal integrity and extended reach. With a gain of 19dB and a PAE of 45%, it exemplifies efficiency by converting more power into the RF output. Its compact bare die format allows for seamless integration and versatility in design. Sporting a 1.8V supply voltage, it aligns with demands for reduced power usage in energy-conscious digital infrastructure developments.
The RWM6050 is a key component designed for sophisticated wireless communication tasks, playing a critical role in Blu Wireless's high-speed connectivity solutions. This baseband modem supports real-time processing of complex tasks, enabling the higher efficiency and accuracy required for leading-edge communications infrastructure. Suitable for a wide range of applications, the RWM6050 ensures adaptive modulation and robust filtering, making it indispensable for dynamic wireless environments. The modem operates efficiently across a variety of use cases, including private network deployments and high-throughput data applications, which demand reliable and flexible connectivity. With the ability to accommodate the constantly evolving needs of wireless infrastructures, the RWM6050 provides versatile support for today's high-bandwidth requirements. Designed to integrate seamlessly with Blu Wireless's portfolio of networking solutions, the RWM6050 is optimized for performance and scalability, delivering exceptional processing capability indispensable in high-speed connectivity systems. This modem underscores Blu Wireless's commitment to offering advanced and comprehensive communication technology to its clients.
The 2.4GHz ISM Band RF solution is designed to propel high-performance wireless communication across numerous applications. Operating within the widely-used 2.4GHz industrial, scientific, and medical (ISM) radio band, this RF solution facilitates robust connectivity, ensuring reliable data transmission essential for modern wireless technologies. Ideal for Bluetooth and Wi-Fi-enabled devices, this RF technology conforms to the IEEE 802.1X protocol standards, catering to a broad range of communication needs. It is particularly effective in developing seamless connections in smart home environments, consumer electronics, and wearable devices. By optimizing power consumption, the 2.4GHz ISM Band RF solution supports extended battery life, which is critical for portable devices. Its inclusion into Bluetooth, Wi-Fi, and other short-range communication platforms enables designers to create innovative products that meet the escalating demands of wireless connectivity.
The PCS2100 is a specialized Wi-Fi HaLow IoT modem chip developed for client-side applications. Operating under the IEEE 802.11ah standard, the PCS2100 facilitates the creation of robust IoT networks with extended range and high throughput. It's particularly engineered for smart city infrastructures, offering enhanced network management capabilities essential for IoT deployments. This modem chip operates on sub-gigahertz frequency, ensuring connections can reach up to 1 km, which is vital for wide-area network deployment. Equipped with unique features like Target Wake Time and Resource Allocation Windowing, it is optimized for power efficiency, making it ideal for battery-operated devices requiring long duty cycles. The PCS2100's advanced security features, including WPA3 and AES-CCMP encryption, ensure secure data transmission, aligning with the latest IoT security protocols. The design supports various modulation and coding schemes to adapt to different network demands, underscoring its versatility in IoT environments ranging from home automation to industrial applications.
PhantomBlu by Blu Wireless is engineered for defense applications, focusing on delivering high-speed, secure, and reliable tactical communications. This mmWave networking solution is designed to be independent of conventional fibre optic or cabled networks, granting greater flexibility and range. With the capability to easily integrate with both legacy platforms and upcoming technological assets, PhantomBlu ensures interoperability and robust connectivity in demanding environments. The mmWave technology used in PhantomBlu allows for multi-gigabit data transmission over significant distances, catering to the dynamic needs of military operations. It can be configured to function as a PCP (hub) or STA (client), enhancing its adaptability in tactical scenarios. This flexibility is vital for mission-critical communications, ensuring data-rich, secure connections even in highly contested environments. By employing low Probability of Detection (LPD) and Low Probability of Interception (LPI) techniques, PhantomBlu provides stealthy communication capabilities, significantly reducing the risks of detection and interference by adversaries. This advanced technology strengthens the defense sector's communication arsenal, providing reliable gigabit connectivity that supports strategic and operational superiority on the battlefield.
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.
Mobix Labs' mmWave RF Modules are at the forefront of next-generation wireless communication technologies. As the demand for high-frequency, low-latency communication continues to rise, these modules provide the necessary infrastructure to meet and exceed these requirements. Designed for both commercial and military applications, these modules facilitate seamless data transfer at millimeter-wave frequencies, playing a crucial role in the deployment of 5G and 6G networks. With capabilities that span from 24 GHz to 100 GHz, these modules offer unparalleled frequency compatibility and high throughput, essential for rapid data communication in complex environments. The design emphasizes ultra-low power consumption, making it possible to integrate with IoT and other battery-powered devices, without sacrificing performance. Known for their robust durability, these RF modules can withstand extreme environmental conditions, making them ideal for use in telecommunications, satellite communications, military, and aerospace applications. Featuring cutting-edge semiconductor technology, Mobix Labs ensures their modules provide superior signal clarity and reduced power consumption, supporting the future of wireless connectivity.
TurboConcept's 5G Polar encoder/decoder is crafted to meet the demands of modern wireless communication systems, particularly within the 5G network space. This IP core is engineered to deliver exceptional error correction while optimizing data transmission, which is critical for maintaining high performance in network environments. The core is carefully designed to provide seamless operation across various deployment scenarios, offering significant flexibility in ASIC and FPGA platforms. Its design prioritizes both power efficiency and high-speed data processing capabilities, ensuring that it meets the rigorous needs of contemporary telecom infrastructures. With its advanced error correction techniques, the 5G Polar solution enhances the reliability and efficiency of data communications, making it an ideal choice for companies seeking to bolster their network offerings with dependable and high-performance solutions.
The 802.11 LDPC solution offers a high-throughput design intended to meet demanding specifications for wireless communication standards. It features the flexibility to adjust LDPC decoding iterations, balancing throughput with error correction performance based on specific requirements. The system is designed to accommodate on-the-fly configuration from one frame to another, ensuring adaptability in various operating conditions. This feature-rich IP aims to maintain optimal bit-error-rate and packet-error-rate performance to ensure data integrity and reliability in dynamic digital communication environments.
Designed for 5G mmWave applications, the FCM2801-BD is a 28GHz CMOS power amplifier that brings enhanced RF power to support modern telecommunication needs. With operational frequencies ranging from 23GHz to 36GHz, it offers a gain of 22dB and PAE of 53%, making it highly efficient in delivering superior performance with minimal thermal footprint. Its architecture aligns with next-generation wireless standards, promising reduced system costs and increased lifespan for battery-powered equipment. By operating with a supply voltage of 1.8V, it contributes to energy savings—a critical factor in ever-evolving 5G networks. This amplifier is part of the broader ecosystem of modular designs, available as a bare die for flexibility in integration.
The Wireless Baseband IP from Low Power Futures is a sophisticated solution designed for small, ultra-low-power devices in IoT applications. It comprises a baseband processor hardware IP, the link layer or medium access control layer firmware, and integrated security features. This product is specifically optimized to ensure a minimal code size, while providing power and area efficiency. The Wireless Baseband IP supports standard compliance and can be easily integrated into systems on chips (SoCs). It is validated on FPGA platforms, making it a robust solution for developers aiming to leverage low-power IoT networks. This IP is versatile, finding applications in smart homes, smart city infrastructures, and connected audio systems. Its customizable nature allows for easy adaptation to various embedded processors, enabling seamless integration in different environments. The IP's design emphasizes efficient resource use, crucial for IoT devices that demand long battery life and low operational cost.
The PCS1100 transceiver is designed for next-generation Wi-Fi 6E applications, supporting tri-band operations, including the 6GHz band. This RF transceiver is integral to building Wi-Fi 6/6E networks, providing robust support for high-efficiency wireless LAN systems. With its 4x4 spatial stream capability, the chip supports multi-user MIMO, an essential feature for enhancing the capacity and spectral efficiency of network systems. The PCS1100 operates seamlessly as both an access point and a station, offering dual-band concurrent operation that enhances its applicability in various setups. The transceiver excels in delivering consistent connectivity with support for up to 1024 QAM modulation, increasing throughput capabilities. It incorporates advanced features such as OFDMA, which reduces latency and improves network efficiency, particularly in crowded signal environments. Its design ensures compatibility with multiple frequency bands, including 2.4 GHz, 5 GHz, and the newly available 6 GHz spectrum. This flexibility, combined with excellent receiver sensitivity and phase noise performance, renders it suitable for a wide range of uses, including smart home devices, industrial automation, and public Wi-Fi installations. The PCS1100 supports integration into advanced process nodes, maximizing logic gate density and supporting compact ASIC and ASSP designs.
The 4G multi-mode CTC decoder by TurboConcept is a versatile and high-performance solution for 4G communication networks. Designed to handle varying coding schemes, this IP core effectively enhances data integrity and reliability in transmission. Specifically tailored for multi-mode operation, the decoder efficiently manages different CTC (Convolutional Turbo Codes) required in 4G systems, ensuring seamless integration and adaptability. Its design supports high-speed data processing capabilities, making it well-suited for dynamic telecom environments. Built to offer robust performance in both FPGA and ASIC settings, the 4G multi-mode CTC decoder facilitates improved throughput and minimal latency. It's a vital component for operators looking to optimize their 4G network systems, providing both flexibility and enhanced performance.
The PCS2500 serves as a central hub for Wi-Fi HaLow network deployments, facilitating extensive IoT communications across wide areas. Designed under the IEEE 802.11ah standard, the PCS2500 enables a seamless connection between IoT devices and broader internet networks, functioning effectively within sub-gigahertz frequency bands. As a highly integrated modem chip, it supports both access point and gateway functionalities, permitting efficient network management and expanded reach. The PCS2500 is capable of connecting with and managing several client devices simultaneously while optimizing power consumption and reducing network contention, making it an excellent choice for densely populated IoT ecosystems. Its network features include advanced functionalities like Target Wake Time and RAW, promoting efficiency in data transmission and enhancing battery life for connected devices. Security features are robust with support for WPA3 and AES-CCMP, ensuring safe operations essential for sensitive IoT applications in smart homes, industrial sites, and beyond.
TurboConcept's 5G LDPC encoder/decoder stands as a comprehensive solution designed for next-generation 5G communication systems. It ensures reliable data transmission with superior error correction capabilities, making it a crucial component in enhancing signal integrity in wireless networks. This LDPC core is meticulously crafted to support high-speed data processing while maintaining optimal power efficiency, catering to the stringent requirements of 5G infrastructures. The 5G LDPC solution is developed to provide seamless integration into existing systems, delivering robust performance in both ASIC and FPGA environments. Its versatility makes it suitable for a vast array of applications within the telecommunications sector, ensuring flexibility in deployment while maintaining stringent compliance with 5G standards. Utilizing state-of-the-art algorithms, this LDPC encoder/decoder delivers enhanced throughput and lower latency, essential for modern high-performance networks. The technology is designed to adapt to varying data rates, making it indispensable for service providers aiming to offer superior network experiences.
The IEEE 802.15.4 WPAN IP is crafted to support the latest wireless personal area network standards, catering to the needs of IoT devices necessitating low-power operation and compact sizes. This IP includes support for BPSK and OQPSK modulation techniques and is compatible with sub-gigahertz and 2.4GHz frequencies, ensuring a comprehensive communication solution. Built with a strong focus on security, this IP integrates extensive security options to protect data integrity and confidentiality in wireless communications. Its versatility makes it a match for an array of applications, including smart homes, industrial monitoring systems, and personal area networks. Assured compliance with current standards ensures that the IEEE 802.15.4 WPAN IP is capable of meeting rigorous market demands. Its utility in resource-constrained environments makes it a reliable choice for developers aiming to maximize performance while minimizing power consumption.
The Wi-Fi 6 IP is a powerhouse in wireless communication technology, set to redefine the standards of speed and connectivity. Designed for the current evolution in Wi-Fi networks, Wi-Fi 6 IP ensures users experience high data throughput, optimal bandwidth usage, and minimized latency. This solution is critical in environments demanding reliable and fast wireless internet access such as smart homes, office spaces, and large public venues. Wi-Fi 6 IP integrates cutting-edge features such as OFDMA, MU-MIMO, and BSS Coloring, enhancing network efficiency and providing seamless connectivity even in congested areas. This allows multiple devices to maintain high-speed connectivity and reduced interference, thus optimizing the overall network capacity and user experience. Adopting this technology signifies a commitment to future-proofing designs, accommodating the rapid growth of connected devices in a variety of applications from smart wearables to IoT devices. It's crafted for robust deployment in the evolving ecosystem of wireless communication, supporting high-density device environments and the expansive requirements of next-generation wireless networks.
The BLE 5.1 RF/MODEM Baseband offers comprehensive support for Bluetooth low energy applications. It integrates multiple functionalities necessary for efficient communication, including radio frequency, modem support, baseband processing, and a protocol stack. This combination enhances not only the performance but also the ease of integration into a wide array of products, making it highly desirable for the increasingly interconnected world of IoT devices. Key features of this offering include advanced RF coupling, robust modem functions, and a state-of-the-art baseband processor. The integrated protocol stack ensures compatibility with existing BLE devices, regular updates, and seamless performance across diverse applications. Moreover, the profiling capabilities facilitate tailored communication suited to specific user requirements, optimizing energy consumption and data transmission rates. Designed for easy deployment and integration, this product underscores Rafael Micro's commitment to efficiency and technological advancement. By simplifying the complexities typically associated with Bluetooth and RF technologies, the BLE 5.1 RF/MODEM Baseband promotes widespread adoption and innovation, paving the way for smarter communication networks. Whether for consumer electronics, smart home systems, or mobile applications, it stands as a testament to the potential of cutting-edge engineering in enhancing everyday technologies.
The SBR6201 transceiver from SaberTek supports dual compatibility with 802.15.4g and 802.11ah standards, making it a versatile choice for applications like wireless metering and smart grid communications. This transceiver is optimized for performance in challenging environments, providing reliable networking capabilities even in dense area deployments. It excels in forming mesh networks that are resilient in harsh conditions, offering solid performance well above standard requirements.
This transceiver integrates Power Amplifier (PA) and RF Switch (RFSW) capabilities with 802.11n Wi-Fi standards, targeted for low-power IoT applications. The SBR7517IoT ensures robust signal performance, providing enhanced connectivity solutions while preserving power efficiency. It is ideal for systems that require a blend of Wi-Fi connectivity with integrated analog components, catering to complex IoT network demands.
The GNSS Receiver by ChipCraft represents cutting-edge technology designed for precision and reliability in global positioning. This receiver is engineered to provide users with a high-performance, energy-efficient solution that fits into a small form factor, making it suitable for a wide range of applications, from consumer electronics to professional surveying. It is tailored for versatility and can be integrated into various devices, offering adaptability for location-based services as well as complex navigation systems. The GNSS Receiver operates with exceptional sensitivity and accuracy, ensuring resistance to typical urban noise and navigation signal interference, which makes it ideal for use in both commercial products and ambitious developmental projects. Additionally, this receiver supports high precision mapping and provides invaluable utility in applications demanding precise synchronization and timing. Industries such as smart agriculture and advanced surveying benefit greatly from the reliable data provided by this state-of-the-art receiver, affirming ChipCraft's commitment to quality and technological advancement.
Tailored for IoT environments, the SBR7501IoT transceiver supports 802.11n Wi-Fi standards, operating at 2.4GHz. It is engineered to deliver minimal power consumption while ensuring comprehensive Wi-Fi connectivity, aligning with the requirements of smart, interconnected devices. This transceiver is optimized for low-silicon-area designs, making it a preferred choice for device manufacturers focused on compact, efficient Wi-Fi solutions in IoT contexts.
The Zmod SDR A sophisticated tool designed for software-defined radio (SDR) applications, combines high-performance processing with flexible, reconfigurable RF capabilities. Utilizing state-of-the-art FPGA technologies, this module supports complex signal processing tasks, adapting easily to various communication standards and protocols. It's an ideal solution for developers and researchers working on advanced wireless communication systems.
The LTE CTC Decoder offered by TurboConcept is a key technology for LTE networks, delivering enhanced decoding performance through its state-of-the-art turbo decoding capabilities. This IP core is engineered to provide reliable data transmission, reducing errors and improving overall network efficiency. Designed for seamless integration, the LTE CTC Decoder supports both ASIC and FPGA deployments, offering significant versatility across different platform requirements. Its architecture is optimized for high-speed processing, meeting the high-demand needs of modern telecom infrastructures without compromising on power consumption. The solution is particularly well-suited for data-critical applications within LTE systems, ensuring improved connectivity and service delivery. By leveraging advanced turbo code technology, the LTE CTC Decoder enables operators to offer exceptional network services to their users.
TurboConcept's LTE Cat-0 Turbo Decoder is a sophisticated IP core designed to enhance the efficiency of LTE networks. This decoder is integral to improving data throughput and ensuring reliable communication by employing advanced turbo decoding algorithms for error correction. The LTE Cat-0 Turbo Decoder is optimized for low power consumption, making it highly suitable for battery-operated devices that require endurance and reliability. Its streamlined architecture allows for seamless integration into existing network systems, offering scalability and adaptability to future technology advancements. Engineered to support a wide range of LTE applications, this decoder ensures robustness and flexibility, which are crucial in meeting today's connectivity demands. Its high-performance capabilities make it a pivotal asset in maintaining superior network service quality.
The PCSRPWH reference platform embodies Palma Ceia SemiDesign's commitment to simplifying the development of Wi-Fi HaLow-based solutions. This platform is versatile, covering global application frequencies and facilitating real-world testing and validation of IoT innovations. Designed for both product developers and system architects, the platform includes transceiver ICs with FPGA modules for baseband and MAC layer implementation. Providing a Linux-generated environment, developers can exploit real-time testing with Ethernet integration for seamless transitions between wired and wireless interfaces. Supporting a wide frequency spectrum, the platform serves versatile applications ranging from consumer devices to industrial systems, encouraging extended battery life through its efficient power usage profile. This reference platform stands out as a laboratory tool essential for prototyping and optimizing Wi-Fi HaLow deployments before commercial scale-up.
The Wi-Fi 6 technology transforms modern wireless networking, offering unprecedented data transfer capabilities, enhanced network coverage, and reduced latency. Crafted for the bustling environments of today, Wi-Fi 6 caters to the increasing number of smart devices connected to the internet, creating a seamless network experience through superior throughput and efficiency. Implementing Wi-Fi 6 ensures that devices operate at higher speeds with greater stability, even in areas with dense networks. The technology leverages OFDMA and MU-MIMO to deliver exceptional connectivity without interference, maintaining robust communication links across a multitude of devices. This next-generation Wi-Fi technology is pivotal for smart homes, businesses, and public networks, optimizing connectivity for various applications such as streaming, gaming, and IoT devices. Adopting Wi-Fi 6 is not just about upgrading connectivity—it’s about revolutionizing digital interactions in increasingly interconnected environments.
The Complex Digital Down Converter (DDC) from Zipcores is designed for high-precision processing of intermediate frequency (IF) signals. This 16-bit DDC facilitates the conversion of IF signals to baseband, preparing them for further processing stages. It features a meticulously designed decimation filter stage, essential for reducing the sampling rate of the signal while preserving its integrity. The integrated digital oscillator and decimation filter provide a comprehensive solution to handle complex signal processing tasks with remarkable efficiency. This DDC is an ideal choice for applications that demand precise and reliable conversion of frequency-domain signals into baseband, ensuring that subsequent processing stages maintain quality and accuracy.
The NRC79A1 is a mmWave radar front end used for applications requiring detailed environmental monitoring and data acquisition. With its 1Tx-1Rx structure, this radar front end is designed for precision and efficiency, ensuring accurate capture and analysis of radar signals. Its application scope spans across numerous industries, making it a staple for organizations that need to harness accurate real-time data for decision-making processes. This all-encompassing capability supports seamless integration into complex technological frameworks.
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