All IPs > Wireless Communication > 3GPP-5G
The evolution of mobile communication technology has reached a pivotal stage with the introduction of 3GPP-5G, a standard that promises to transform wireless communications. In the realm of semiconductor IP, 3GPP-5G solutions encompass a wide range of technologies that are integral to developing and deploying next-generation communication networks. These semiconductor IPs provide the foundational architecture required for high-speed data transfer, ultra-reliable low latency, and massive connectivity, supporting the diverse and demanding use cases of modern mobile and IoT applications.
3GPP-5G semiconductor IP solutions are crucial for manufacturers and developers looking to design cutting-edge communication systems. These IPs enable the seamless integration of 5G capabilities into a variety of devices, from smartphones and smart home appliances to industrial IoT sensors and autonomous vehicles. They are designed to handle complex signal processing, support multiple frequency bands, and deliver enhanced performance metrics such as increased bandwidth and improved energy efficiency. By leveraging these semiconductor IPs, companies can significantly reduce time-to-market and development costs while ensuring that the end devices meet stringent 5G standards.
Within this category, you'll find a broad array of semiconductor IP products tailored to meet the specific challenges and opportunities posed by 5G networks. These include baseband processors, RF transceivers, and advanced modulation solutions, all of which are engineered to support the high demands of 5G technology. Furthermore, these IPs often come with software support and development kits that facilitate faster adoption and implementation into existing systems.
As the world moves towards more interconnected and intelligent systems, 3GPP-5G semiconductor IPs provide the essential building blocks for future innovations. By enabling the next generation of wireless communication, these IPs not only enhance current technologies but also pave the way for new applications and services that were previously unimaginable. Whether you are developing solutions for consumer electronics, automotive, healthcare, or smart cities, the 3GPP-5G semiconductor IP category offers the tools and technologies to bring your vision to life.
KPIT offers a comprehensive solution for Autonomous Driving and Advanced Driver Assistance Systems. This suite facilitates the widespread adoption of Level 3 and above autonomy in vehicles, providing high safety standards through robust testing and validation frameworks. The integration of AI-driven decision-making extends beyond perception to enhance the intelligence of autonomous systems. With a commitment to addressing existing challenges such as localization issues, AI limitations, and validation fragmentation, KPIT empowers automakers to produce vehicles that are both highly autonomous and reliable.
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.
The Polar encoding and decoding IP, compliant with 3GPP standards, offers comprehensive support for various uplink and downlink channels in 5G NR. Utilizing advanced decoding techniques, it provides unparalleled error correction with scalable parameters for parallelism and latency optimization. The Polar solution by AccelerComm is a versatile and powerful option for deploying efficient communication systems, supporting FPGA and ASIC processes, and offering flexibility in system design and implementation, significantly contributing to high error correction performance.
The software-defined High PHY from AccelerComm is tailored for ARM processor architectures, offering flexibility to accommodate a wide array of platforms. This configurable solution can operate independently or, if needed, with hardware acceleration, depending on the application's specific power and performance needs. It's suitable for use in situations where adaptability is paramount and is optimized to minimize latency and maximize efficiency across different platforms, adhering to O-RAN standards, and enhancing system capability by integrating with other IP offerings such as accelerators.
The 802.11 LDPC solution from Wasiela is designed to excel in delivering high throughput and robust error correction for wireless communication systems. It supports frame-to-frame, on-the-fly reconfiguration, enabling adaptability to varying data loads and transmission conditions. By permitting configurable LDPC decoding iterations, it allows users to find the perfect balance between throughput and error correction, ensuring optimum performance in all scenarios.<br><br>This LDPC offering matches bit-error-rate and packet-error-rate performance requirements, solidifying its reputation as a reliable choice for modern wireless systems. With its ability to handle high throughput at minimal latency, the 802.11 LDPC component is essential for applications demanding high-speed data transmission, ensuring that error-free data packets are a consistent reality.<br><br>Wasiela's design of the 802.11 LDPC takes into account the need for both performance and flexibility, crafting a solution that is ready to integrate seamlessly into various applications, from consumer electronics to industrial communication networks. This adaptability is a testament to Wasiela's commitment to empowering developers with IP cores that are both cutting-edge and user-friendly.
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.
Polar Encoders/Decoders from Creonic are designed with the latest communication standards in mind, delivering exceptional performance in error correction through polar coding techniques. Originally developed for 5G systems, polar coding offers strong error correction capabilities with high efficiency, making these cores critical for next-generation communication systems. These encoders/decoders provide a consistent performance boost by efficiently utilizing channel capacity, which is particularly beneficial in high-throughput scenarios such as wireless backhaul and cellular networks. Creonic’s implementation focuses on minimizing complexity while maximizing speed, ensuring the cores can handle demanding communication tasks without excessive processing overhead. The Polar Encoders/Decoders IP cores are packed with a rich set of features that include adjustable code rates and length, providing adaptability to various requirements. With comprehensive support for both FPGA and ASIC deployments, they offer a robust, flexible solution for those looking to enhance their existing digital communication frameworks.
Turbo Encoders/Decoders by Creonic represent key components for achieving effective forward error correction in communication systems. Utilizing turbo coding, these IP cores enhance data throughput by rapidly encoding and decoding signals, ensuring minimal error propagation and optimal data integrity. Widely used in standards like DVB-RCS2 and LTE, Turbo coding provides excellent performance gains in error correction. These cores are specifically designed to handle large volumes of data with high efficiency, allowing technologies like 4G and upcoming 5G networks to deliver their promised speeds reliably. Creonic’s Turbo Encoders/Decoders support a range of code rates, making them adaptable for various transmission conditions and enabling dynamic applications across different communication landscapes. Importantly, they incorporate advanced algorithmic techniques to accelerate processing speeds and reduce latency – essential qualities for real-time applications. Supported with a suite of testing environments and simulation models, these IP cores ensure straightforward integration into user hardware, providing considerable flexibility for both FPGA and ASIC implementation scenarios.
The 60GHz Wireless Solution by CLOP Technologies employs the IEEE 802.11ad WiFi standard, also known as the Wireless Gigabit Alliance MAC/PHY specification, to deliver high-speed data transfer. With peak data rates reaching up to 4.6Gbps, it is perfect for complex applications like real-time, uncompressed HD video streaming and high-speed file transfer, improving today’s WiFi speeds tenfold. A key feature of this technology is its support for 802.11ad IP networking, facilitating IP-based tasks such as peer-to-peer communication and router/access point functionalities. It also includes a USB 3.0 host interface for easy connection to hosts and compensates for RF impairments, ensuring robust performance even at high data operations. This product is engineered to handle the substantial data demands of modern IoT devices and provide a competitive advantage through its enhanced wireless data technology. Functioning in the 57GHz to 66GHz frequency band, it uses modulation modes like BPSK, QPSK, and 16QAM. Its FEC coding rates include LDPC 1/2, 5/8, 3/4, and 13/16, with AES-128 hardware security and IEEE 802.11e Real Time QoS to ensure a quality, secured wireless experience.
ArrayNav is an innovative GNSS solution that employs multiple antennas, enhancing sensitivity and accuracy to combat common issues like multipath interference and signal jamming. This technology is designed to increase the effectiveness of global positioning systems by using adaptive antenna systems, a concept borrowed from advanced wireless communications. ArrayNav provides up to 18dB gain in signal strength for fading channels and ensures robust performance even in complex environments like urban canyons. By identifying and nulling unwanted signals, it maintains the integrity of GNSS operations against spoofing and interference. This technology is vital for applications needing high precision under challenging signal conditions. With its sophisticated antenna diversity, ArrayNav is crafted to deliver sub-meter precision and swift signal acquisition. This makes it a valuable component for navigation in densely constructed urban landscapes or covered environments where satellite visibility might be obscured. ArrayNav's capability to handle multipath and interference issues effectively makes it a preferred choice for high-reliability navigation systems, contributing to both enhanced security and accuracy.
The 802.11ah HaLow Transceiver by Palma Ceia represents a significant advance in IoT communications technology. Designed to address the power and bandwidth limitations of traditional Wi-Fi for IoT applications, it offers enhanced range, lower power consumption, and operates in sub-1 GHz bandwidths. This transceiver supports low data rate communications over long distances, making it perfect for IoT devices that require reliable network presence. Its integrated power management mechanisms ensure prolonged battery life for sensor-based applications. Moreover, with stringent adherence to the 802.11ah standard, the transceiver guarantees compatibility with various IoT ecosystems. This IP's capability to function as both a standalone component or part of a System-on-Chip (SoC) allows for flexible design implementations. Applications range from smart city infrastructures to personal health monitoring devices, highlighting its versatility in meeting diverse connectivity needs in the IoT domain.
The Cortus NB-IoT C200 is a sophisticated narrowband-IoT solution integrated with Bluetooth Low Energy capabilities, designed to meet the needs of smart IoT systems. This IP enables seamless connectivity in sub-GHz unlicensed ISM bands, offering robust performance for remote and wireless communication. Ideally suited for smart metering and industrial IoT applications, this IP delivers reliable, low-power wireless connectivity essential for long-distance communication without sacrificing battery life. Built with the latest advancements in wireless technology, the NB-IoT C200 provides comprehensive support for various IoT standards, ensuring broad compatibility and adoption across multiple platforms. Its low-data-rate, extensive coverage, and reduced power consumption features make it an optimal choice for portable devices and remote sensors that rely on uninterrupted connections. With its capacity to handle significant data processing at reduced bandwidths, the NB-IoT C200 is in line with the demands of modern IoT ecosystems. This model is particularly adept at maintaining efficient operations in dense urban environments, thanks to its noise-immune and highly stable connection protocols.
Designed for efficient low-density parity-check decoding, Mobiveil's 5G NR LDPC Decoder IP implements an optimized version of the Min-Sum algorithm. This design provides flexibility with programmable bit widths and supports early termination features, enhancing decoding speeds. It is particularly adept in 5G communications, allowing for real-time iterative correction and improving overall transmission reliability in high-performance wireless applications.
The ntLDPC_5GNR Base Graph Encoder IP Core is defined in 3GPP TS 38.212 standard document and it is based on an implementation of QC-LDPC Quasi-Cyclic LDPC Codes. The specification defines two sets of LDPC Base Graphs and their respective derived Parity Check Matrices. Each Base Graph can be combined with 8 sets of lifting sizes (Zc) in a total of 51 different lifting sizes. This way by using the 2 Base Graphs, the 5G NR specification defines up to 102 possible distinct LDPC modes of operation to select from, for optimum decoding performance, depending on target application code block size and code rate (using the additional rate matching module features). For Base Graph 1 we have LDPC(N=66xZc,K=22xZc) sized code blocks, while for Base Graph 2 we have LDPC(N=50xZc,K=[6,8,9,10]xZc) sized code blocks. The ntLDPCE_5GNR Encoder IP implements a multi-parallel systematic LDPC encoder. Parallelism depends on the selected lifting sizes subsets chosen for implementation. Shortened blocks are supported with granularity at lifting size Zc-bit boundaries. Customizable modes generation is also supported beyond the scope of the 5G-NR specification with features such as: “flat parity bits puncturing instead of Rate Matching Bit Selection”, “maintaining the first 2xZc payload bits instead of eliminating it before transmission”, etc. The ntLDPCD_5GNR decoder IP implements a maximum lifting size of Zc_MAX-bit parallel systematic LDPC layered decoder. Each layer corresponds to Zc_MAX expanded rows of the original LDPC matrix. Each layer element corresponds to the active ZcxZc shifted identity sub-matrices within the layer. Each layer element is shifted accordingly and processed by the parallel decoding datapath unit, in order to update the layers LLR estimates and extrinsic information iteratively until the required number of decoding iterations has been run. The decoder IP also features a powerful optional early termination (ET) criterion, to maintain practically equivalent error correction performance, while significantly increasing its throughput rate and/or reducing hardware cost. Additionally it reports how many decoding iterations have been performed when ET is activated, for system performance observation and calibration purposes. Finally a simple, yet robust, flow control handshaking mechanism is included in both IPs, which is used to communicate the IPs availability to adjacent system components. This logic is easily portable into any communication protocol, like AXI4 stream IF.
The PCS2100 Wi-Fi HaLow IoT STA/Client is a transceiver designed to extend Wi-Fi networks to IoT devices operating in challenging environments. Utilizing the 802.11ah standard, this product emphasizes long-range transmission with a low power requirement, making it ideal for battery-powered IoT sensors and devices. With its sub-1GHz frequency, the PCS2100 provides superior wall penetration and reaches further distances compared to traditional Wi-Fi frequencies. It supports ultra-narrow bandwidth modulations, which enhances spectrum efficiency and minimizes interference. This makes it suitable for densely populated areas where multiple IoT devices need to be reliably connected. Palma Ceia has ensured that the PCS2100 is versatile, allowing it to integrate seamlessly into existing IoT ecosystems while offering robust security features to protect data integrity. Its adaptability and power efficiency are perfect matches for various IoT applications such as smart agriculture, logistics tracking, and environmental monitoring.
Creonic's LDPC Encoders/Decoders are designed to provide high-efficiency error correction for modern communication systems. These IP cores follow advanced LDPC (Low-Density Parity-Check) coding schemes to offer a balance of performance and flexibility. They are suitable for use in a plethora of standards such as DVB-S2, DVB-S2X, 5G, and CCSDS, ensuring robust data transmission across various signal conditions. The LDPC solutions by Creonic are known for their high throughput, making them fit for applications that demand speed and accuracy. Their capability to process and correct errors efficiently ensures data integrity, especially in bandwidth-critical systems. Users can expect comprehensive integration support with available design kits and simulation models that aid seamless incorporation within existing hardware platforms. With flexibility for both FPGA and ASIC implementations, Creonic's LDPC encoders and decoders come equipped with adaptive features that allow for various code rates and block lengths. This adaptability ensures that users can tailor the application to meet specific requirements, benefiting from the cores' proven reliability in delivering high-quality data communication.
The mmWave PLL by CoreHW is a sophisticated frequency synthesizer designed to meet the demands of modern wireless communication networks and radar systems. It features a high-accuracy fractional-N PLL frequency synthesizer with a very low noise voltage-controlled oscillator (VCO). This design supports efficient generation of low phase noise carriers and rapid chirp frequency modulations required for fast-frequency modulated continuous wave (FMCW) radar. Operating initially in the frequency range of 19.00-20.15 GHz, the mmWave PLL is engineered to extend to radar frequency bands from 38-40.5 GHz and even further to 76-81 GHz through frequency multipliers. Its scalable frequency configuration makes it suitable for diverse applications including 5G networks and various mmWave communication devices, providing flexibility for adaptation to specific needs. Key features include integrated bandgap references, low-dropout regulators (LDOs), and integrated frequency multipliers. The PLL supports fractionally precise chirp modulation capabilities, making it ideal for automotive radar applications like collision avoidance and distance measurement. The device is robust, maintaining optimal performance across a wide temperature range, and includes comprehensive built-in self-test and calibration features to facilitate reliable deployment in high-demand environments.
AccelerComm's High PHY Accelerators are a set of scalable IP cores for ASIC, FPGA, and SoC platforms, employing patented signal processing algorithms to boost throughput while lowering latency and power consumption. These accelerators are essential for enhancing the overall performance of 5G NR networks. They support diverse architectures with flexibility in integration, catering to specific deployment capacities across platforms. These accelerators showcase AccelerComm's dedication to efficiency and performance, providing adaptable and robust designs suited for cutting-edge technological applications.
The LTE Lite from Wasiela offers a light yet powerful solution for User Equipment (UE) LTE applications, specifically designed to support CAT 0/1 PHY. It is compatible with intermediate frequency inputs and offers flexible channel bandwidths ranging from 1.4 MHz to 20 MHz, supporting a variety of modulation schemes including QPSK, 16QAM, and 64QAM.<br><br>This product is ideally suited for integrating into systems requiring flexible and scalable LTE solutions. Its design leverages a synthesizable Verilog-2001 framework, making it highly portable and adaptable for various applications. The operation is automated through a master finite state machine, optimizing the interaction between the LTE Lite and other system components.<br><br>Noteworthy is its ability to correct significant frequency and timing mismatches, ensuring reliable data transmission across extended network environments. Overall, LTE Lite by Wasiela offers a compelling blend of performance, flexibility, and ease-of-integration for a wide range of telecommunications and consumer electronics applications.
The PCS2500 Wi-Fi HaLow Access Point enables extended Wi-Fi coverage for IoT applications in industrial and consumer environments. This IP is based on the IEEE 802.11ah standard and is engineered for low power consumption and robust performance in extended ranges. As an access point, the PCS2500 can connect a multitude of IoT devices over wide areas, maintaining reliable communication channels even in electrically noisy environments. It offers features like advanced interference mitigation and efficient data throughput to ensure smooth and consistent network performance. This access point is designed to enhance IoT network flexibility, supporting various applications from smart homes to large-scale industrial setups. With a focus on ease of integration and scalability, the PCS2500 is a key component for building expansive and responsive IoT networks.
AccelerComm's LDPC solution brings in innovative designs that balance performance with efficiency for 5G NR data channels. Featuring robust error correction capabilities, this IP uses state-of-the-art architectural design to achieve superior throughput without error floors, essential for high-demand communication systems. It's adaptable and can be integrated seamlessly into existing systems, supporting various platform configurations and ensuring high hardware efficiency and low latency—all while complying with 3GPP standards for optimal integration.
The EW6181 is an advanced multi-GNSS silicon designed for high sensitivity and low power consumption, a stand-out product in GPS and GNSS technology. It supports multiple global positioning systems like GPS L1, Glonass, BeiDou, Galileo, SBAS, WASS, and A-GNSS. This silicon includes an integrated RF frontend, a digital baseband for signal processing, and ARM MCU to efficiently run the necessary firmware. This chip is tuned for low energy use, incorporating a DC-DC converter along with high voltage and low voltage LDOs, which makes it ideal for battery-powered devices. Its size and energy efficiency make it a competitive module component that reduces the overall Bill of Materials (BoM) for manufacturers. The EW6181's architecture is optimized for cloud readiness, offering enhanced capabilities for applications needing intensified accuracy and power savings through cloud connectivity. A unique feature of the EW6181 is its implementation in a 2-antenna Evaluation Kit, showcasing its potential to improve device connectivity and performance with antenna diversity mode, perfect for rotating devices like action cameras and wearable tech. This diversity offers key advantages in both connectivity and user experience, emphasizing the EW6181 as a flexible, high-performing component in various technological ecosystems.
RF Integration's 802.11 Transceiver Core is specifically engineered to support wireless LAN communications. Compatible with IEEE 802.11 a/b/g/n standards, this transceiver facilitates seamless high-speed data transfer for a range of multimedia and internet connectivity applications. It integrates RF front-end components and baseband processing blocks, ensuring efficient handling of signal transmission and reception. The core is designed for power efficiency and superior performance, making it ideal for use in consumer electronics such as laptops, smartphones, and tablets. With support for multiple configurations and enhancements like MIMO (Multiple Input Multiple Output) technology, it caters to the growing demand for robust wireless solutions that provide improved data throughput and extended range. Its compatibility with both legacy and modern wireless standards ensures that it remains a versatile solution as network infrastructures evolve.
The Digital PreDistortion (DPD) Solution by Systems4Silicon is crafted to elevate the power efficiency of RF amplifiers. This adaptive technology thrives on various platforms, being vendor-independent and offering scalability for FPGAs and ASICs. The solution can handle bandwidths over 1 GHz and supports a plethora of communication standards, including 5G, enabling operations with multi-carrier and multi-standard single-antenna transmissions. Operating efficiently across different transistor technologies, the DPD advances amplifier performance by compensating for memory effects and facilitating operation in non-linear regions, achieving efficiency improvements above 50% under certain configurations.
The PUSCH Equalizer from AccelerComm targets the enhancement of spectral efficiency in environments with multiple antennas, effectively reducing noise and interference. Designed with advanced equalization algorithms and configurable for various 5G applications, this Equalizer integrates traditional PUSCH Decoding capabilities with additional features to improve performance dramatically. The product supports FPGA and ASIC implementations, showcasing AccelerComm’s emphasis on high performance and precise functionality for top-tier 5G NR applications, which are compliant with the latest 3GPP standards.
ntLDPC_SDAOCT IP implements a 5G-NR Base Graph 1 systematic Encoder/Decoder based on Quasi-Cyclic LDPC Codes (QC-LDPC), with lifting size Zc=384 and Information Block Size 8448 bits. The implementation is 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 it offers high throughput at low implementation complexity. The ntLDPCE_SDAOCT Encoder IP implements a systematic LDPC Zc=384 encoder. Input and Output may be selected to be 32-bit or 128-bits per clock cycle prior to synthesis, while internal operations are 384-bits parallel per clock cycle. Depending on code rate, the respective amount of parity bits are generated and the first 2xZc=768 payload bits are discarded. There are 5 code rate modes of operation available (8448,8448)-bypass, (9984,8448)-0.8462, (11136,8448)-0.7586, (12672,8448)-0.6667 and (16896,8448)-0.5. The ntLDPCD_SDAOCT Base Graph Decoder IP may optionally implement one of two approximations of the log-domain LDPC iterative decoding algorithm (Belief propagation) known as either Layered Min-Sum Algorithm (MS) or Layered Lambda-min Algorithm (LMIN). Variations of Layered MS available are Offset Min-Sum (OMS), Normalized Min-Sum (NMS), and Normalized Offset Min-Sum (NOMS). Selecting between these algorithms presents a decoding performance vs. system resources utilization trade-off. The ntLDPCD_SDAOCT decoder IP implements a Zc=384 parallel systematic LDPC layered decoder. Each layer corresponds to Zc=384 expanded rows of the original LDPC matrix. Each layer element corresponds to the active ZcxZc shifted identity submatrices within the layer. Each layer element is shifted accordingly and processed by the parallel decoding datapath unit, in order to update the layers LLR estimates and extrinsic information iteratively until the required number of decoding iterations has been run. The decoder IP also features a powerful optional early termination (ET) criterion, to maintain practically equivalent error correction performance, while significantly increasing its throughput rate and/or reducing hardware cost. Additionally it reports how many decoding iterations have been performed when ET is activated, for system performance observation and calibration purposes. Finally a simple, yet robust, flow control handshaking mechanism is included in both IPs, which is used to communicate the IPs availability to adjacent system components. This logic is easily portable into any communication protocol, like AXI4 stream IF.
This module caters to the demands of contemporary wireless communication, enhancing connectivity and performance for devices operating on WiFi6, LTE, and 5G networks. It features a front-end module that combines a switch, LNA, and PA, operating in the 2.4 and 5-7 GHz frequency ranges. This integration is designed to optimize the RF front-end path in mobile and communication devices, ensuring seamless data transfer and robust connection strength in advanced wireless systems.
TES's Ultra-Wideband (UWB) Technology & IP is developed to meet the demands of high-precision positioning and communication applications. Known for its ability to offer precise location data and robust communication links, this IP is a cornerstone for applications like asset tracking, indoor navigation, and secure communications. The UWB IP is optimized to function with low power consumption while maintaining high performance, making it ideal for battery-operated devices that require long operational life. Key features include enhanced range resolution and the ability to operate in environments with numerous reflective surfaces, which are common in indoor scenarios. TES's UWB IP is adaptable for integration into various systems and supports the development of new applications in fields requiring cutting-edge wireless communication technology. Whether for industrial automation or consumer electronics, its reliability and precision make it a sought-after solution for state-of-the-art networking requirements.
The 3GPP LTE Turbo Decoder is engineered to enhance data processing in high-performance mobile networks. With an 8 state configuration and options for 1, 2, 4, or 8 parallel MAP decoders, it is designed to significantly improve error correction, ensuring reliable and high-speed data transmission in LTE environments. This decoder is optimized for networks where bandwidth efficiency is crucial, achieving peak performance while effectively handling the noise and interference prevalent in mobile networks. The option to integrate multiple parallel decoders allows for customized implementations, aligning with specific mobile network demands and optimizing overall system throughput and reliability. Deploying this decoder can vastly improve application responsiveness and network resource management. It plays a pivotal role in the tech infrastructure necessary to support 4G LTE services, meeting the high expectations for connectivity and data integrity demanded by users and service providers alike.
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.
Designed for multi-standard networks, the 3GPP LTE and 3GPP2 1xEV-DO Turbo Decoder excels in environments requiring flexibility and advanced error correction. It features an 8 state turbo decoding system, utilizing ping-pong input and output memories for enhanced data processing and throughput. This decoder ensures consistency in data communication, a necessity for networks that support LTE and 1xEV-DO standards. It is engineered for efficient operation across different network types, supporting varied communication protocols and improving signal integrity and data correctness. Optimizing both data transfer speeds and network reliability, this decoder supports robust implementations for telecom operators, facilitating smoother transitions and reduced error rates within network infrastructure. It significantly contributes to improved user experiences and reliable data exchanges, even under heavy network demands.
The 5G Remote Radio Unit (RRU) by Saankhya Labs is a cutting-edge offering designed to amalgamate the vast possibilities of fifth-generation wireless technology with robust and adaptable hardware. With its compliance to the ORAN 7.2x standard, this multiband RRU is engineered to cater to the dynamic requirements of modern telecommunications service providers, addressing both current needs and future expansions. Equipped with advanced analytics capabilities, the Saankhya RRU delivers a unique advantage by providing network operators with tools to optimize their spectrum usage. This optimization capability translates into a reduced Total Cost of Ownership (TCO) for operators, allowing for significant savings while enhancing service quality and reliability. The RRU is part of Saankhya's comprehensive 5G RAN solution portfolio which includes RAN Intelligent Analytics. The inherent flexibility of the 5G RRU allows it to support numerous frequency bands, ensuring seamless integration into existing infrastructure and offering a scalable solution for network growth. Its smart design ensures that it can be employed across various geographic and population density landscapes, making it suitable for both urban centres and rural zones.
Digital Down Conversion (DDC) transforms received high-frequency signals into baseband equivalents through a structured chain of interpolating filters and mixers. Adopting techniques like CIC and FIR interpolations corrects spectral losses and ensures signal integrity throughout the conversion process. Focused on maintaining consistency and precision, Faststream’s DDC solution employs numerically controlled oscillators to mitigate frequency errors effectively. Designed to operate smoothly at standard clock rates, DDCs are pivotal in managing vast data transmission demands typical in mobile network receivers. Facilitating adaptive implementations within FPGA platforms, Faststream tailors its DDC technology to fit wider network applications. Combining efficiency with practicality, this solution is integral in optimizing data flow systems, ensuring minimized latency and enhanced data fidelity across telecommunication infrastructures.
The J1 core cell is a remarkably small and efficient audio decoder that manages Dolby Digital, AC-3, and MPEG audio decompression. With a design that occupies only 1.0 sqmm of silicon area using 0.18u CMOS technology, it delivers a robust solution for decoding 5.1 channel dolby bitstreams and supports data rates up to 640kb/s. The J1 produces high-quality stereo outputs, both normal and Pro-Logic compatible, from Dolby Digital and MPEG-encoded audio, ideal for set-top boxes and DVD applications.
The RF-SOI and RF-CMOS platform developed by Tower Semiconductor is a critical solution for wireless communication applications, providing the necessary framework for the development of high-performance, low-power RF components. This platform is tailored to meet the complex demands of modern wireless technologies, facilitating enhanced signal processing and transmission efficiency. Using SOI (Silicon on Insulator) and CMOS processes, this technology enables the creation of RF components that are not only reliable but also feature reduced parasitic capacitance, leading to higher speed and lower power dissipation. It is particularly suited for mobile devices, Internet of Things (IoT) applications, and telecommunications infrastructure, where performance and battery longevity are key considerations. The platform is adaptable to different frequency bands, providing support for both standard and customized RF circuit designs. By enabling excellent isolation and linearity, Tower Semiconductor’s RF platform ensures that devices can operate with superior signal integrity in diverse environments. Overall, the RF-SOI and RF-CMOS platform provides a robust environment for innovation in wireless communication, supporting the continuous evolution of mobile technologies by enabling the integration of sophisticated RF features with scalable production methodologies.
The NB-IoT (LTE Cat NB1) Transceiver provides a cost-effective solution for low-bandwidth wide-area network IoT applications. With compliance to the 3GPP Release 13 and 14 standards, this transceiver is tailored for efficient communication across cellular networks. It offers a robust receiver and transmitter performance with a diverse range of bandwidths and modulation options, ensuring high data reliability and low latency. The receiver features internal DC offset and IQ mismatch correction capabilities, while the programmable interface facilitates easy integration into existing systems. Optimized for low power consumption without compromising performance, this transceiver is suitable for applications ranging from smart metering to environmental sensors. Its extensive documentation and support resources further simplify the integration process, ensuring a smooth transition during deployment.
The YouRF range from Brite offers comprehensive RF solutions for wireless applications. It includes BLE and NB-IoT modules, with specialized 2.4G proprietary and 802.15.4G transceivers. These are optimized for low power consumption and high performance across a range of wireless frequencies. Utilized primarily in IoT and intelligent meters, YouRF helps facilitate seamless connectivity in modern wireless ecosystems.
Systems4Silicon's Crest Factor Reduction (CFR) Technology is designed to optimize the power efficiency of RF amplifiers by controlling the transmit signal's envelope. This versatile solution is independent of the target device vendor and accommodates a variety of communication standards through dynamic re-programming. CFR technology proficiently reduces amplifier costs and enhances efficiency by increasing transmit power relative to bias power and is capable of adapting for single and multi-carrier operations. Furthermore, it exhibits 100% deterministic behavior, allowing for precise performance modeling and supports integration with Digital Predistortion and envelope tracking technologies.
Digital Pre-Distortion (DPD) technology is essential for enhancing the linearity and efficiency of RF power amplifiers in modern wireless systems. This process addresses the distortion issues linked with broadband signals, mitigating spectral regrowth which typically occurs with wide signal transmissions like WCDMA. Faststream's DPD utilizes the Memory Polynomial Algorithm, optimizing PA performance for various test conditions and ensuring minimal non-linear distortion. Through advanced signal processing, DPD supports enhancements in amplifier efficiency while safeguarding signal integrity. By converting non-linear amplifier characteristics into closer linear representation, DPD significantly improves transmission efficacy and reduces operational costs by optimizing power usage in RF systems. Moreover, Faststream’s approach suits modern communication challenges, with optimized DSP core integration allowing DPD functionalities to be housed efficiently within FPGAs. This setup decreases footprint and cost, presenting a viable option for companies aiming to adhere to stringent spectral masks and error vector magnitude criteria.
The PCS1100 Wi-Fi 6E 4x4:4 transceiver is designed to support the next generation of wireless communications. It offers enhanced range, improved speed, and reduced latency over previous Wi-Fi standards, making it ideal for high-demand environments such as enterprise and industrial IoT. By utilizing the newly opened 6 GHz band, this transceiver provides less congestion and interference, leading to a more reliable connection. The transceiver supports multiple modulation and coding schemes, ensuring efficient data transfer across various devices. It is equipped with advanced RF capabilities to maintain strong connectivity even in dense environments. Furthermore, the PCS1100 is compatible with existing Wi-Fi infrastructure, enabling easy upgrades and expansions. Built with a focus on energy efficiency, the PCS1100 prioritizes battery preservation without compromising on performance. This makes it suitable for a wide range of portable and stationary applications, from consumer electronics to professional equipment. As part of Palma Ceia's cutting-edge lineup, it embodies the company's commitment to high-quality and innovative solutions.
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.
IMST's wireless solutions cater to the demand for customized radio modules, a critical component in modern communication systems. These solutions are developed to meet the specific needs of clients, offering flexibility from the initial design phase through to manufacturing. The custom radio modules provide seamless incorporation into various device architectures. With expertise in critical areas such as RF hardware, digital components, and communication software, IMST ensures that each module is tailored for its unique application, delivering both performance and efficiency. These bespoke solutions facilitate innovations in consumer electronics, telecommunication infrastructures, and more, enabling enhanced connectivity and operational effectiveness. IMST's dedication to quality and precision in their radio systems offers clients a reliable partner in navigating the complexities of modern wireless communication demands.
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.
The SµRF MMIC series, introduced by CML, represents a pioneering line of high-frequency, high-bandwidth monolithic microwave integrated circuits (MMICs), tailored to meet the increasing demands of RF and mmWave applications. As the communication landscape evolves with technologies like 5G and satellite systems, these MMICs provide unparalleled performance, crucial for supporting next-generation infrastructure. With an emphasis on high-frequency capabilities, they enable exceptional data flow and communication efficiency across diverse networks.
The 5G NR Software Stack from Lekha Wireless is engineered to meet the comprehensive requirements of modern 5G networks. This software solution is compliant with Release 15, covering enhanced mobile broadband (eMBB), ultra-reliable low latency communications (URLLC), and massive machine-type communications (mMTC). With its modular architecture, the stack supports diverse network splits, making it ideal for various system-on-chip (SoC) based platforms, ensuring versatility across a wide range of deployment scenarios. The software stack is designed to be flexible, facilitating integration with multiple platform architectures. This adaptability makes it suitable for the evolving demands of 5G networks, providing seamless migration paths for different technology generations. Lekha’s solution offers essential components like the gNodeB PHY Layer Stack and gNodeB Protocol Stack for both Layer 2 and Layer 3, optimizing network performance. By providing a robust framework for 5G deployment, this software stack aids companies in achieving their network objectives effectively. It assists in building systems with high reliability and low latency, crucial for applications across telecom infrastructure, rural broadband, and tactical communications. The solution is further supported by extensive technical assistance, ensuring clients can deploy and maintain their networks with confidence.
AccelerComm offers a comprehensive 5G NR physical layer solution designed for high-demand applications such as satellite and private networks. This complete physical layer solution optimizes performance by implementing innovative signal processing methods, providing a high degree of flexibility and configurability. Delivered as licensable IP across ARM software, FPGA, and ASIC-ready platforms, it ensures reduced project risk through reference systems on COTS development boards for early integration and testing. The solution focuses on maximizing link performance by using cutting-edge technologies for efficient power and area trade-offs, making it ideal for specialized O-RAN and small-cell solutions.
Crest Factor Reduction (CFR) technology serves to enhance the performance of RF power amplifiers by managing the Peak-to-Average Power Ratio (PAPR) of signals. Employed in wireless communication systems, CFR techniques lower the PAPR by reshaping peak signal levels. This process reduces stress on power supply designs and lowers peak power demands. CFR is often paired with Digital Pre-Distortion to optimize amplifier efficiency, as low PAPR is crucial for maintaining signal fidelity in high-frequency applications. Faststream’s CFR uses sophisticated algorithms modeled in MATLAB and Verilog for simulation and verification, ensuring compatibility with multi-channel transmission systems. By enabling more effective power management and reduced energy consumption, CFR plays a pivotal role in sustaining amplifier lifecycle and operational integrity. This becomes particularly significant in high-throughput environments which are essential for supporting emerging technologies such as 5G and beyond.
Digital Up Conversion (DUC) encompasses an interpolating filter chain that transforms baseband signals into higher frequency signals suitable for transmission. This involves stages like half-band and CIC compensation interpolations to achieve high fidelity in spectral responses and minimize bandwidth loss. The DUC effectively handles conversion tasks with precision, enabling swift transition of data rates necessary for top-tier LTE environments. Incorporating a numerically controlled oscillator and mixer, it balances interpolation factors and output sampling rates to meet rigorous standards in signal processing. Faststream’s DUC solution is engineered for adaptability in FPGA structures, leveraging the stability of dedicated DSP units. This finely-tuned architecture allows for seamless integration into broader system designs, facilitating efficient resource utilization alongside consistent high-performance conversion operations.
Specialized for dual-standard networks, the 3GPP UMTS/LTE and 3GPP2 Turbo Decoder accommodates systems requiring heightened flexibility and error correction capabilities. It operates using an 8 state design, with optional configurations of 16, 32, 64, or even 256 state Viterbi decoders. This wide range supports extensive error correction and aligns with various protocol demands. The decoder facilitates seamless transitions and data exchanges between UMTS and LTE networks, ensuring stability and continuity in service provision. Its adaptable design enables integration across varying network architectures, promoting improved data throughput and network efficiency for telecom providers looking to enhance their service quality. This decoder's sophisticated error correction capabilities make it suitable for advanced telecom applications, reducing error rates and enhancing signal integrity across different channels and frequencies. It is instrumental in ensuring strong connectivity and robust performance essential in today's complex mobile network environments.
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.