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.
**Ceva-XC21** is the most efficient vector DSP core available today for communications applications. The Ceva-XC21 DSP is designed for low-power, cost- and size-optimized cellular IoT modems, NTN VSAT terminals, eMBB and uRLLC applications. Ceva-XC21 offers scalable architecture and dual thread design with support for AI, addressing growing demand for smarter, yet more cost and power efficient cellular devices. Targeted for 5G and 5G-Advanced workloads, the Ceva-XC21 has multiple products configurations enabling system designers to optimize the size and cost to their specific application needs. The Ceva-XC21, based on the advanced Ceva-XC20 architecture, features a product line of 3 vector DSP cores. Each of the cores offers a unique performance & area configuration with a SW compatibility between them. The different cores span across single thread or dual thread configurations, and 32 or 64 16bits x 16bits MACs. The Ceva-XC212, the highest performing variant of the Ceva-XC21 delivers up to 1.8x times the performance of Ceva’s previous-generation Ceva-XC4500 architecture, while reducing the core area. Ceva-XC210, the smallest configuration of the Ceva-XC21, enables system designers to reduce the core die size in 48% compared with the previous generation. Ceva-XC211 offers the same performance envelope compared with the previous generation at 63% of the area. [**Learn more about Ceva-XC21>**](https://www.ceva-ip.com/product/ceva-xc21/?utm_source=silicon_hub&utm_medium=ip_listing&utm_campaign=ceva_xc21_page)
**Ceva-PentaG2** is a complete IP platform for implementing a wide range of user-equipment and IoT cellular modems. The platform includes a variety of DSPs, modem hardware modules, software libraries, and simulation tools. Capabilities of the Ceva-PentaG2 include New Radio (NR) physical layer design ranging across all 3GPP profiles from RedCap IoT and mMTC, through eMBB up to ultra-reliable low-latency communications (URLLC). The platform has two base configurations. Ceva-PentaG2 Max emphasizes performance and scalability for enhanced mobile broadband (eMBB) and future proofing design for next generation 5G-Advanced releases. Ceva-PentaG2 Lite emphasizes extreme energy and area efficiency for lower-throughput applications such as LTE Cat 1, RedCap, and optimized cellular IoT applications. The PentaG2 platform comprises a set of Ceva DSP cores, optimized fixed-function hardware accelerators, and proven, optimized software modules. By using this platform, designers can implement optimized, hardware-accelerated processing chains for all main modem functions. In the selection process, designers can tune their design for any point across a huge space of area, power consumption, latency, throughput, and channel counts. Solutions can fit applications ranging from powerful eMBB for mobile and Fixed Wireless Access (FWA) devices to connected vehicles, cellular IoT modules, and even smart watches. System-C models in Ceva’s Virtual Platform Simulator (VPS) aid architectural exploration and system tuning, while an FPGA-based emulation kit speeds SoC integration. [**Learn more about Ceva-PentaG2 solution>**](https://www.ceva-ip.com/product/ceva-pentag2/?utm_source=silicon_hub&utm_medium=ip_listing&utm_campaign=ceva_pentag2_page)
The EW6181 is an advanced multi-GNSS silicon solution designed for high sensitivity and precision. This powerful chip supports GPS, Glonass, BeiDou, Galileo, SBAS, and A-GNSS, offering integration flexibility with various applications. Its built-in RF frontend and digital baseband facilitate robust signal processing, controlled by an ARM MCU. The EW6181 integrates essential interfaces for diverse connectivity, matched with DC-DC converters and LDOs to minimize BOM in battery-driven setups. This silicon marries low power demands with strong functional capabilities, thanks to proprietary algorithms that optimize its operation. It’s engineered to deliver exceptional accuracy and sensitivity in both standalone and cloud-related environments, adapting smoothly to connected ecosystems for enhanced efficiency. Its compact silicon footprint further enhances its suitability for applications needing prolonged battery life and reliable positioning. With a focus on Antenna Diversity, the EW6181 shines in dynamic applications like action cameras and smartwatches, ensuring clear signal reception even when devices rapidly rotate. This aspect accentuates the chip's ability to maintain consistent performance across a range of challenging environments, reinforcing its role in the forefront of GNSS technology.
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.
The Digital PreDistortion (DPD) Solution offered by Systems4Silicon is a versatile technology aimed at significantly enhancing the efficiency of RF power amplifiers. This advanced sub-system is scalable and adaptable to both ASIC and FPGA platforms, ensuring broad compatibility across various device vendors. The DPD solution meticulously enhances linearity, crucial for devices operating within multi-standard environments, such as 5G and O-RAN systems.\n\nDesigned to optimize the signal processing in transmission systems, this DPD technology allows for considerable power savings by enabling amplifiers to function more efficiently. Systems4Silicon’s approach ensures that the system can maintain its performance across different transmission bandwidths, which can scale to 1 GHz or higher. This makes it particularly valuable for large-scale and high-frequency applications.\n\nThe DPD technology's implementation is straightforward, providing a field-proven solution that integrates seamlessly with current infrastructures. Its adaptability is not merely limited to the hardware spectrum but extends to accommodate evolving communication standards, ensuring it remains relevant and effective in diverse market scenarios.
The Digital Radio (GDR) from GIRD Systems is an advanced software-defined radio (SDR) platform that offers extensive flexibility and adaptability. It is characterized by its multi-channel capabilities and high-speed signal processing resources, allowing it to meet a diverse range of system requirements. Built on a core single board module, this radio can be configured for both embedded and standalone operations, supporting a wide frequency range. The GDR can operate with either one or two independent transceivers, with options for full or half duplex configurations. It supports single channel setups as well as multiple-input multiple-output (MIMO) configurations, providing significant adaptability in communication scenarios. This flexibility makes it an ideal choice for systems that require rapid reconfiguration or scalability. Known for its robust construction, the GDR is designed to address challenging signal processing needs in congested environments, making it suitable for a variety of applications. Whether used in defense, communications, or electronic warfare, the GDR's ability to seamlessly switch configurations ensures it meets the evolving demands of modern communications technology.
The 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.
This mmWave PLL is engineered to deliver exceptional performance in high-frequency applications, such as mmWave communications and advanced radar systems. The IP offers remarkable frequency synthesis capabilities, essential for the operation of modern communication networks and sensors, including the growing 5G infrastructure and automotive radar technologies. The design incorporates mechanisms to optimize phase noise and enhance frequency stability, which are critical in minimizing signal distortion in high-bandwidth transmissions. This PLL is compact yet powerful, making it an excellent choice for systems where space and performance are at a premium. Suitable for integration into a variety of RF and mmWave architectures, the mmWave PLL supports applications across telecommunications, automotive, and beyond. It helps designers achieve superior system performance while maintaining low latency and high data throughput.
Designed for seamless integration, High PHY Accelerators from AccelerComm encapsulate top-tier signal processing blocks critical for 5G solutions. Available as FPGA and ASIC ready IP cores, they are tailored for rapid deployment with minimal risk. These accelerators are supported by accurate simulation models and designed to use standardized interfaces for integration. Notably, they also provide support for space-hardened platforms, ensuring robust performance in diverse settings.
AccelerComm’s LDPC solutions cater specifically to the 5G standards, offering high efficiency and leading performance in channel coding. The IP suite includes comprehensive encoder and decoder capabilities that enhance hardware efficiency for this critical component of the PHY layer. This facilitates a marked improvement in throughput and error reduction, aligning with 3GPP standards. Born from academic excellence at Southampton University, they incorporate cutting-edge algorithms for signal performance, achieving substantial decoder performance enhancement and minimizing error floors.
The RISCV SoC developed by Dyumnin Semiconductors is engineered with a 64-bit quad-core server-class RISCV CPU, aiming to bridge various application needs with an integrated, holistic system design. Each subsystem of this SoC, from AI/ML capabilities to automotive and multimedia functionalities, is constructed to deliver optimal performance and streamlined operations. Designed as a reference model, this SoC enables quick adaptation and deployment, significantly reducing the time-to-market for clients. The AI Accelerator subsystem enhances AI operations with its collaboration of a custom central processing unit, intertwined with a specialized tensor flow unit. In the multimedia domain, the SoC boasts integration capabilities for HDMI, Display Port, MIPI, and other advanced graphic and audio technologies, ensuring versatile application across various multimedia requirements. Memory handling is another strength of this SoC, with support for protocols ranging from DDR and MMC to more advanced interfaces like ONFI and SD/SDIO, ensuring seamless connectivity with a wide array of memory modules. Moreover, the communication subsystem encompasses a broad spectrum of connectivity protocols, including PCIe, Ethernet, USB, and SPI, crafting an all-rounded solution for modern communication challenges. The automotive subsystem, offering CAN and CAN-FD protocols, further extends its utility into automotive connectivity.
D2D® Technology, developed by ParkerVision, is a revolutionary approach to RF conversion that transforms how wireless communication operates. This technology eliminates traditional intermediary stages, directly converting RF signals to digital data. The result is a more streamlined and efficient communication process that reduces complexity and power consumption. By bypassing conventional analog-to-digital conversion steps, D2D® achieves higher data accuracy and reliability. Its direct conversion approach not only enhances data processing speeds but also minimizes energy usage, making it an ideal solution for modern wireless devices that demand both performance and efficiency. ParkerVision's D2D® technology continues to influence a broad spectrum of wireless applications. From improving the connectivity in smartphones and wearable devices to optimizing signal processing in telecommunication networks, D2D® is a cornerstone of ParkerVision's technological offerings, illustrating their commitment to advancing communication technology through innovative RF solutions.
LightningBlu is a state-of-the-art multi-gigabit connectivity solution for high-speed rail networks, delivering continuous high-speed data transfer between trackside and train systems. This innovative solution works within the mmWave spectrum of 57-71 GHz and is certified for long-term, low-maintenance deployment. It seamlessly integrates with existing trackside networks to provide a stable, high-capacity communication bridge essential for internet access, entertainment, and real-time information services aboard high-speed trains. The LightningBlu system includes robust trackside nodes and compact train-top nodes designed for seamless installation, significantly enhancing operational efficiencies and passenger experience by providing internet speeds superior to traditional mobile broadband services. With aggregate throughputs reaching around 3 Gbps, LightningBlu sets the standard for rail communications by supporting speeds at which data demands are met with ease. Crucially, LightningBlu is a key component in transforming the railway telecommunications landscape, offering upgraded technology that enables uninterrupted and enhanced passenger digital services even in the busiest railways across the UK and USA. Through its advanced mmWave technology, it ensures that the connectivity needs of the modern commuter are met consistently and effectively, paving the way for a new era in transit communication.
The ORC3990 is a groundbreaking LEO Satellite Endpoint SoC engineered for use in the Totum DMSS Network, offering exceptional sensor-to-satellite connectivity. This SoC operates within the ISM band and features advanced RF transceiver technology, power amplifiers, ARM CPUs, and embedded memory. It boasts a superior link budget that facilitates indoor signal coverage. Designed with advanced power management capabilities, the ORC3990 supports over a decade of battery life, significantly reducing maintenance requirements. Its industrial temperature range of -40 to +85 degrees Celsius ensures stable performance in various environmental conditions. The compact design of the ORC3990 fits seamlessly into any orientation, further enhancing its ease of use. The SoC's innovative architecture eliminates the need for additional GNSS chips, achieving precise location fixes within 20 meters. This capability, combined with its global LEO satellite coverage, makes the ORC3990 a highly attractive solution for asset tracking and other IoT applications where traditional terrestrial networks fall short.
The 802.11ah HaLow transceiver is designed to provide efficient and reliable connectivity for IoT devices, utilizing sub-GHz frequencies to ensure long-range transmission while maintaining minimal power consumption. This transceiver is a perfect fit for environments where traditional Wi-Fi bands fall short due to range or power constraints. Offering superior penetration through obstacles and walls, this transceiver is ideally suited for industrial IoT, smart agriculture, and connected home systems. Its long-range capabilities make it especially useful in applications requiring broad coverage across expansive areas or dense urban settings. Beyond range enhancements, the 802.11ah HaLow standard supported by this transceiver allows for interoperability with various IoT ecosystems, simplifying device integration and promoting scalability. By balancing power efficiency and connectivity, it supports seamless operation for battery-operated devices, aiding in the creation of sustainable IoT networks.
The RWM6050 Baseband Modem is an innovative component of Blu Wireless's mmWave technology portfolio, architected to support high-bandwidth, high-capacity data communications. Designed in collaboration with industry leaders Renesas, this modem unit stands out for its efficiency and versatility, effectively marrying physical modem layers with advanced processing capabilities. The RWM6050 modem is instrumental in providing seamless data transmission for access and backhaul networks. Built to accommodate varying channelisation modes, the RWM6050 supports deep levels of customisation for different bandwidth requirements and transmission distances. It handles multi-gigabit throughput, which makes it ideal for expanding connectivity in urban or industrial areas with dense infrastructure requirements. From smart cities to complex transport systems, this baseband modem scales effectively to meet demanding data needs. Equipped with dual modems and integrated mixed-signal front-end capabilities, the RWM6050 offers a flexible solution for evolving communication infrastructures. Its design ensures optimization for real-time digital signal processing, beamforming, and adaptable connectivity management. The RWM6050 is a key enabler in unlocking the full potential of mmWave technology in a variety of settings, furthering connectivity innovations.
The FCM1401 is a 14GHz CMOS Power Amplifier tailored for Ku-band applications, operating over a frequency range of 12.4 to 16 GHz. This amplifier exhibits a gain of 22 dB and a saturated output power (Psat) of 19.24 dBm, ensuring optimal performance with a power-added efficiency (PAE) of 47%. The architecture enables reduction in battery consumption and heat output, making it ideal for satellite and telecom applications. Its small silicon footprint facilitates integration in space-constrained environments.
TES Electronic Solutions provides a comprehensive Ultra-Wideband (UWB) technology suite tailored for high-precision ranging and communication applications. UWB Technology & IP is designed to offer robust wireless data transmission, combining low power consumption with high data rates, ideal for indoor positioning and real-time location tracking systems. The UWB solutions support various industrial standards, ensuring interoperability across different platforms and systems, which is essential for modern interconnected environments. With its strong signal resilience and multipath immunity, UWB Technology & IP is particularly effective in environments with reflective materials or where traditional wireless technologies might struggle. This technology is vital in applications requiring precision, such as asset tracking, position monitoring, and security systems. TES's framework ensures flexibility, allowing for customization and optimization based on unique client requirements, facilitating integration into existing and future communication infrastructures.
The Polar channel coding offering by AccelerComm is crafted for the 3GPP 5G NR, providing both uplink and downlink encoding and decoding capabilities. Designed for easy integration, it includes PC- and CRC-aided SCL polar decoding techniques to ensure uncompromised error correction. Key parameters of the decoding IP can be tuned to adjust parallelism, latency, and throughput, making it adaptable to specific application needs without sacrificing performance.
The RFicient chip is designed for the Internet of Things (IoT) applications, famously recognized for its ultra-low-power operations. It aims to innovate the IoT landscape by offering a highly efficient receiver technology that significantly reduces power consumption. This chip supports energy harvesting to ensure sustainable operation and contributes to green IoT development by lessening the dependency on traditional power sources. Functionally, the RFicient chip enhances IoT devices' performance by providing cutting-edge reception capabilities, which allow for the consistent and reliable transmission of data across varied environments. This robustness makes it ideal for applications in industrial IoT settings, including smart cities and agricultural monitoring, where data integrity and longevity are crucial. Technically advanced, the RFicient chip's architecture employs intelligent design strategies that leverage low-latency responses in data processing, making it responsive and adaptable to rapid changes in its operational environment. These characteristics position it as a versatile solution for businesses aiming to deploy IoT networks with minimal environmental footprint and extended operational lifespan.
Wasiela's LTE Lite offers a streamlined solution for LTE communications by supporting user equipment (UE) compliant with Category 0/1 standards. It integrates seamlessly with intermediate frequency (IF) inputs and accommodates various channel bandwidth configurations, including 1.4, 3, 5, 10, 15, and 20 MHz. This flexibility is key for devices with varying broadband requirements, enabling efficient transmission across different frequency bands. The LTE Lite solution is engineered to optimize modulation processes, supporting Quadrature Phase Shift Keying (QPSK) and higher-order QAM options. This allows it to adapt to diverse telecommunication needs by balancing between data rate and signal strength, achieving optimal performance in both high and low signal environments. Built to be resource-efficient, it minimizes power consumption while maintaining high-performance standards, making it ideal for portable and battery-powered devices. LTE Lite's advanced features ensure it remains a versatile and future-proof choice for next-generation cellular networks, supporting robust communication infrastructures in evolving markets.
ArrayNav is at the forefront of GNSS enhancements, utilizing multiple antennas to improve the sensitivity and performance of navigation systems. This sophisticated technology significantly boosts GNSS accuracy in challenging environments such as urban canyons. By leveraging up to four antennas, ArrayNav mitigates multipath issues and strengthens signal reception, dramatically enhancing performance. The heart of ArrayNav's innovation lies in its ability to filter out unwanted signals like interference or jamming attempts, ensuring the precision of GNSS operations. As each antenna adds unique benefits, this system ensures reliable navigation across diverse scenarios, whether in open areas or densely constructed urban landscapes. ArrayNav's technology is pivotal in the automotive sector, especially within advanced driver-assistance systems (ADAS). By providing sharper, more reliable positioning data, it contributes to improved safety and efficiency in vehicular systems, showcasing its indispensable role in modern navigation.
The Forward Error Correction (FEC) sub-system is one of the essential basing blocks in any communication systems, so a powerful FEC code is needed. The New Radio (NR) FEC for the control channel is designed based on Polar codes, allowing close to the Shannon limit/Capacity operation. It features Polar code successive cancellation decoding, as needed for the 3GPP physical layer standard, with Parity Check bits that simplify the pruning of the search tree. The encoding of the NR Polar code is performed in GF(2), structured using static reliabilities from the ETSI standard. This IP Core supports a maximum code block length of 1024 bits and a minimum of 32 bits. It can be easily integrated with interleavers and Rate matching circuitry to support all rates required by 5G NR. Additional features include successive cancellation decoding with list decoding, soft decision decoding, high peak rates, low latency, and compliance with the 3GPP TS 38.212 V15.1.1 standard. The IP Core is suitable for applications such as 3GPP-LTE Rel. 15 control channels, 5G NR air interfaces, machine-to-machine communication, and high traffic IoT.
The Complete 5G NR Physical Layer solution by AccelerComm is meticulously optimized for 3GPP 5G NTN networks, aiming to enhance link performance with leading SWaP (Size, Weight, and Power) parameters. This solution supports a variety of applications including broadband, D2D (Direct to Device), and defense. With its openly licensable IP, available across multiple platforms such as arm processors, AI engines, and FPGA, it ensures the necessary flexibility for broad architecture compatibility. Complete reference systems facilitate early integration and testing, while additional consulting services provide expertise in early project phases.
CLOP Technologies' 60GHz Wireless Solution offers businesses an impressive alternative to traditional networking systems. Leveraging the IEEE 802.11ad WiFi standard and Wireless Gigabit Alliance MAC/PHY specifications, this solution achieves a peak data rate of up to 4.6Gbps. This makes it particularly suited for applications that require significant bandwidth, such as real-time, uncompressed HD video streaming and high-speed data transfers — operations that are notably quicker compared to current WiFi systems. The solution is engineered to support 802.11ad IP networking, providing a platform for IP-based applications like peer-to-peer data transfer and serving as a router or access point. Its architecture includes a USB 3.0 host interface and mechanisms for RF impairment compensation, ensuring both ease of access for host compatibility and robust performance even under high data rate operations. Operating on a frequency band ranging from 57GHz to 66GHz, the wireless solution utilizes modulation modes such as BPSK, QPSK, and 16QAM. It incorporates forward error correction (FEC) with LDPC codes, providing various coding rates for enhanced data integrity. Furthermore, the system boasts AES-128 hardware security, with quality of service maintained through IEEE 802.11e standards.
Designed for the burgeoning field of wireless connectivity, the 802.15.4 Transceiver Core from RF Integration is targeted towards low-rate wireless personal area networks (LR-WPANs). This core provides the backbone for connecting devices in home automation, industrial monitoring, and consumer electronics applications. Capable of supporting IEEE 802.15.4 standards, including Zigbee, the core facilitates low-power data communication, which is essential for devices where energy efficiency is paramount. The transceiver's design emphasizes reduced power consumption while maintaining robust wireless communication, making it an ideal choice for battery-powered devices. The flexibility of this core allows it to be integrated with various systems, enhancing the functionality of networked devices through secure and reliable connections. By leveraging RF Integration's expertise, this transceiver core not only meets the demand for energy-efficient solutions but also paves the way for future advancements in the Internet of Things (IoT).
The eSi-Comms suite from EnSilica stands as a highly parametizable set of communications IP, integral for developing devices in the RF and communications sectors. This suite focuses on enhancing wireless performance and maintaining effective communication channels across various standards. The modular design ensures adaptability to multiple air interface standards such as Wi-Fi, LTE, and others, emphasizing flexibility and customizability.\n\nThis communication IP suite includes robust components optimized for low-power operation while ensuring high data throughput. These capabilities are particularly advantageous in designing devices where energy efficiency is as critical as communication reliability, such as in wearables and healthcare devices.\n\nMoreover, eSi-Comms integrates seamlessly into broader system architectures, offering a balanced approach between performance and resource utilization. Thus, it plays a pivotal role in enabling state-of-the-art wireless and RF solutions, whether for next-gen industrial applications or advanced consumer electronics.
The 5G NR LDPC Decoder resource by Mobiveil supports advanced LDPC decoding capabilities optimized for modern telecommunication needs. Employing the Min-Sum LDPC decoding algorithm, it allows for programmable bit widths and features early exit iteration capabilities. Support for Hybrid Automatic Repeat Request (HARQ) ensures robustness by accumulating computed LLR values, increasing its efficacy in error correction scenarios.
This RF transceiver is a versatile solution designed for effective communication in the Sub-GHz frequency bands, specifically 433, 868, and 915 MHz. Ideal for global applications, it adheres to the IEEE 802.15.4-2015 standard, ensuring compatibility with many existing wireless systems. With a data rate capability ranging from 128 kbps for both Rx and Tx to over 3+ Mbps for transmission, it supports robust connectivity in various environments. The transceiver stands out with its high integration, featuring an on-chip RF subsystem that eliminates the need for external radio chips, simplifying system architecture. Its built-in voltage regulators and bandgap reference enhance ease of integration into system designs. Notably, this transceiver supports modulation schemes such as GFSK, BPSK, and O-QPSK, offering flexibility for custom protocol development. Designed to operate efficiently across process nodes, the transceiver supports a wide range of foundries, making it a versatile option for diverse applications. With a transmit power range from -20 to +8 dBm and sensitivity levels reaching down to -106 dBm, it is engineered to assure reliable long-range communication without relying on complex mesh network setups. This simplifies the deployment in scenarios like smart metering where indoor and outdoor connectivity is critical.
hellaPHY Positioning Solution is an advanced edge-based software that significantly enhances cellular positioning capabilities by leveraging 5G and existing LTE networks. This revolutionary solution provides accurate indoor and outdoor location services with remarkable efficiency, outperforming GNSS in scenarios such as indoor environments or dense urban areas. By using the sparsest PRS standards from 3GPP, it achieves high precision while maintaining extremely low power and data utilization, making it ideal for massive IoT deployments. The hellaPHY technology allows devices to calculate their location autonomously without relying on external servers, which safeguards the privacy of the users. The software's lightweight design ensures it can be integrated into the baseband MCU or application processors, offering seamless compatibility with existing hardware ecosystems. It supports rapid deployment through an API that facilitates easy integration, as well as Over-The-Air updates, which enable continuous performance improvements. With its capability to operate efficiently on the cutting edge of cellular standards, hellaPHY provides a compelling cost-effective alternative to traditional GPS and similar technologies. Additionally, its design ensures high spectral efficiency, reducing strain on network resources by utilizing minimal data transmission, thus supporting a wide range of emerging applications from industrial to consumer IoT solutions.
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.
Specialized for advanced radio frequency applications, the RF-SOI and RF-CMOS platform merges high-performance substrates with CMOS design flexibility to enable sophisticated wireless communication solutions. SOI (Silicon-On-Insulator) technology in this platform excels in reducing parasitic capacitance, thereby enhancing speed and power efficiency – critical for RF applications where performance must meet stringent wireless standards. This platform offers extensive frequency range support, from sub-GHz to millimeter wave frequencies, making it a suitable choice for cellular infrastructure, IoT devices, and automotive radar systems. By integrating RF-SOI, the solutions achieve low-loss and high linearity, addressing the demands of next-generation wireless networks. The additional benefit of leveraging RF-CMOS provides improved integration capabilities for multi-function devices on a single chip. Tower Semiconductor's platform is augmented by its comprehensive design enablement resources, including standard cell libraries and PDKs, to facilitate efficient design cycles. The enhanced capabilities of the RF-SOI and RF-CMOS platform thus continue to push forward the frontier of wireless technology, supporting the evolution of high-speed data communications.
The NB-IoT (LTE Cat NB1) transceiver is a specialized solution catered to the unique requirements of large-scale IoT deployments within the realm of cellular networks. With a focus on low power consumption and enhanced coverage, this transceiver stands as a critical component for ensuring IoT connectivity across vast geographical distances. Its design facilitates extensive device interoperability and integration within existing LTE networks, enabling easy scalability and cost-effective implementation. The ability to handle numerous connections efficiently makes this transceiver vital for smart city projects, remote monitoring systems, and other IoT initiatives that demand long-range communication. Moreover, the NB-IoT transceiver’s adaptability allows it to penetrate barriers and reach locations where connectivity options are otherwise limited, ensuring continuous data exchange. This breadth of capability secures its position as a backbone for enabling ubiquitous IoT connectivity across diverse environments and use cases.
The 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.
Systems4Silicon's Crest Factor Reduction (CFR) Technology is a highly adaptable solution for optimizing the efficiency of RF power amplifiers. This innovative technology is designed to limit the signal envelope of transmitted signals, which in turn facilitates significant improvements in amplifier performance. By reducing signal peaks, the CFR technology enables amplifiers to operate at enhanced power levels without exceeding their linearity thresholds.\n\nThe FlexCFR product is standard-agnostic and highly configurable, ensuring its compatibility with a broad range of systems, including those utilizing ASIC or FPGA platforms. This flexibility means that the CFR solution can be tailored to meet the specific needs of diverse communication setups, ensuring that users gain maximum efficiency in signal management and transmission.\n\nIncorporating the CFR solution can lead to lower operational costs and reduced heat generation, making it an attractive option for systems where power efficiency is paramount. Its robust compatibility and vendor independence ensure that it can be incorporated into various platforms, maintaining the integrity of different communication protocols and standards.
The MVUM1000 stands out as a compact, advanced linear ultrasound array designed for medical imaging. Featuring 256 elements, it integrates capacitive micromachined ultrasound transducers (CMUT), enhancing both power efficiency and sensitivity. This integration aids in high-quality medical diagnostics and imaging applications.\n\nOffered with a range of adaptive imaging modes, such as Doppler, these arrays facilitate multifaceted ultrasound applications, from portable devices to comprehensive cart-based systems. They provide exceptional lateral and axial imaging capabilities, meeting rigorous clinical needs.\n\nThe sensor array is also characterized by a high degree of integration with electronics, enabling seamless embedding into various platforms. Its flexibility in operation and customizable features allow for expansive usability in point-of-care situations, ensuring healthcare professionals can deliver precise diagnostics efficiently.
Secure-IC's Post-Quantum Cryptography IP offers robust, future-ready security for digital communications, addressing the challenges of quantum computing on traditional encryption methods. This IP is crucial for systems that require long-term confidentiality and authenticity of data, ensuring they remain secure against threats posed by advancements in quantum computing. Designed to integrate seamlessly into existing hardware and software infrastructures, the Post-Quantum Cryptography IP is adaptable and scalable, providing flexibility in implementation. It supports a variety of cryptographic algorithms specifically chosen for their resistance to quantum attacks, ensuring they meet the highest security standards. By adopting this technology, systems can safeguard against potential future vulnerabilities that quantum processors might exploit. This IP is an essential component for industries looking to fortify their security measures, particularly in sensitive sectors such as defense, finance, and critical infrastructure. It provides a forward-thinking approach to cybersecurity, aligning with global trends and regulatory requirements for enhanced cryptographic solutions. By securing today’s systems against tomorrow’s threats, this IP is a strategic investment in sustained security resilience.
The WiFi6, LTE, and 5G Front-End Module is a versatile solution engineered for next-generation wireless communication. This module is tailored to support the high data rate demands and extensive network coverage requirements of WiFi6, LTE, and 5G technologies. It plays a crucial role in enhancing wireless connectivity by facilitating efficient signal transmission and reception across multiple frequency bands. By leveraging cutting-edge RF and analog/mixed-signal design techniques, this front-end module offers exceptional performance characteristics, including high linearity, enhanced gain, and reduced noise figures. These aspects are critical for ensuring seamless connectivity and efficient spectrum usage in densely populated environments, where maintaining signal clarity and reducing interference are paramount. The module integrates seamlessly with advanced wireless architectures, supporting a wide range of device types from consumer electronics to professional communication equipment. Its robust design is prepared to handle the diverse operational requirements of modern wireless systems, providing reliable performance across varied environmental conditions.
The FCM3801-BD is designed for those requiring 39GHz CMOS Power Amplification within the 5G mmWave range. It supports frequencies from 32 to 44 GHz, featuring a 19 dB gain and a Psat of 18.34 dBm. With a PAE of 45%, this amplifier is engineered for high-power applications where efficiency and thermal management are crucial. It's particularly suited for modern telecom environments requiring minimal energy use and weight savings.
The PCS2100 serves as a pillar for IoT connectivity, employing Wi-Fi HaLow technology to deliver extended range and low-power operation. It's specifically crafted to meet the unique demands of IoT devices, ensuring reliable internet access with less power consumption. The standard offers sub-GHz operation essential for improved penetration and coverage, making it ideal for industrial and smart agriculture applications. By leveraging the advantages of Wi-Fi HaLow, the PCS2100 facilitates robust communications over larger distances than traditional Wi-Fi, whilst still maintaining efficient power use—a critical factor for remote and battery-operated devices. This substantial range capability is further enhanced by its compatibility with existing Wi-Fi protocols, easing integration concerns. The PCS2100 demonstrates exceptional adaptability, catering to a wide array of IoT connectivity requirements. It supports the deployment of not only consumer-grade devices but also critical infrastructure components, underlining its importance in the advancement of smart city and AI-driven automation technologies.
The Cobalt GNSS Receiver represents a paradigm shift in the design of System-on-Chip (SoC) technologies, particularly in its integration of ultra-low-power GNSS capabilities. Developed in collaboration with CEVA DSP and supported by the European Space Program Agency, Cobalt is engineered for efficiency and precision in resource-constrained environments. Its architecture supports standalone and cloud-assisted positioning using Galileo, GPS, and Beidou constellations, optimizing the balance between power consumption and market reach. One of the distinctive features of Cobalt is its ability to integrate seamlessly into NB-IoT SoCs, providing an easy GNSS option that is cost-effective and resource-efficient. By leveraging shared resources between the GNSS receiver and modem, this solution not only reduces the footprint of the device but also enhances its cost efficiency, making it an attractive option for mass-market applications. Critical sectors such as logistics, agriculture, insurance, and even animal tracking benefit from Cobalt’s ability to maintain high sensitivity and accuracy, while operating at low power consumption. Cobalt’s design incorporates advanced processing techniques that ensure low MIPS and memory requirements, contributing to its small size and low operational costs. This strategic use of technology empowers clients to deploy wide-scale tracking applications with confidence, knowing that their solutions are backed by robust and reliable location tracking capabilities. With its state-of-the-art sensitivity and precision, Cobalt stands as a pivotal element in the evolution of GNSS technology integration into modern IoT systems.
ARDSoC is a pioneering embedded DPDK solution tailored for ARM-based SoCs, specifically engineered to enhance ARM processor performance by bypassing the traditional Linux network stack. This solution brings the efficiencies of DPDK, traditionally reserved for datacenter environments, into the embedded and MPSoC sphere, extending DPDK functionalities to a broader range of applications. The architecture of ARDSoC allows users to minimize power consumption, decrease latency, and reduce the total cost of ownership compared to conventional x86 solutions. This IP product facilitates packet processing applications and supports various technologies such as VPP, Docker, and Kubernetes, ensuring hardware-accelerated embedded network processing. Designed for integration across Xilinx Platforms, ARDSoC also offers high flexibility with the ability to run existing DPDK programs with minimal modification. It is optimized for performance on ARM A53 and A72 processors, ensuring that data structures are efficiently produced and consumed in hardware, thereby providing robust and reliable network data handling capabilities.
PhantomBlu is a sophisticated mmWave communication solution specifically designed for the defense sector, empowering military operations with robust, high-performance connectivity. Leveraging advanced mmWave technology, it supports tactical connections between land, sea, and air platforms, enabling seamless IP networking over a secure, anti-jam resistant mesh network. PhantomBlu’s design is optimized for rapid deployment and versatile use across various challenging military and defense environments. The PhantomBlu system offers unprecedented connectivity and integration capabilities, supporting high-bandwidth, low-latency communications essential for defense operations. It features LPI (Low Probability of Interception) and LPD (Low Probability of Detection), ensuring stealth and operational security. Its adaptive networking solutions significantly enhance situational awareness and interoperability amongst varied defense assets, assuring seamless transfer of C4ISR data. Whether deployed across large terrains or in mobile units, PhantomBlu's resilience and scalability ensure that defense teams operate with confidence. Its advanced capabilities are critical in mitigating risks and enhancing strategic emission, making it an invaluable asset for modern military communications needs.
The 802.11 Transceiver Core designed by RF Integration provides comprehensive connectivity solutions for wireless networking. This core is optimized for the IEEE 802.11 a/b/g/n standards, ensuring high-speed data transmission and robust local area network coverage. It supports MIMO architectures and OFDM signals, allowing data throughput up to 600Mbps, which is essential for modern wireless infrastructure and consumer electronics. The transceiver core integrates seamlessly with existing digital processing systems, providing a reliable wireless connection essential for various applications, from smart home devices to enterprise network setups. Its sophisticated design minimizes power consumption and cost, making it a practical choice for developers looking to implement efficient wireless solutions. Incorporating both RF and mixed-signal elements, the 802.11 Transceiver Core is designed to deliver high performance even in environments prone to interference. This makes it ideal for use in areas requiring high bandwidth and stable performance over large coverage areas. RF Integration's focus on quality and innovation ensures this core remains a leader in the wireless technology market, driving forward connectivity capabilities in a range of devices.
The 802.11 LDPC core by Wasiela is designed to provide high data rate wireless communication with increased error correction capabilities. Leveraging low-density parity-check (LDPC) codes, this product significantly enhances the reliability of wireless networks by correcting errors that occur during data transmission. It is particularly tailored for environments where maintaining high throughput is critical, such as in dense urban areas or during streaming high-definition content across networks. Wasiela’s design implements an efficient iterative decoding process, adjusting the number of iterations dynamically to ensure optimal performance. The 802.11 LDPC is compatible with various wireless communication standards, making it a versatile choice for manufacturers aiming to integrate robust error correction features in their devices. This core is also optimized for low power consumption, ensuring it meets the power efficiency standards required by modern wireless devices. By ensuring frame-to-frame configuration capabilities, the 802.11 LDPC core not only operates efficiently under varying conditions but also provides seamless adaptability across different data rates. This adaptability makes it well-suited for evolving network demands, meeting the needs of next-generation applications with ease.
The FCM2801-BD is a 28GHz CMOS Power Amplifier, specifically designed for applications in the 5G mmWave spectrum. It operates across a frequency range of 23 to 36 GHz and delivers a gain of 22 dB with a Psat of 19.55 dBm. Boasting a PAE of 53%, this amplifier suits high-frequency telecommunications, offering improved range and reduced energy consumption. The design minimizes thermal output, which further aids in reducing system maintenance costs.
TurboConcept’s 5G Polar core is crafted for enhancing the reliability and efficiency of 5G wireless communications. This IP core focuses on robust error correction to improve signal integrity, a vital feature for 5G networks that require high data rates and low latency. With the implementation flexibility on FPGA and ASIC platforms, it caters to varying application needs in mobile devices and 5G infrastructure. This IP is designed with consideration for the strict power and performance demands of 5G standards. Category IDs: [308, 301]
Actt's 2.4GHz ISM Band RF technology offers a highly integrated RF solution tailored for modern wireless communication needs. This IP is built to support low power consumption while maintaining high performance standards, suitable for both industrial and consumer applications that operate within the 2.4GHz ISM band. Designed to facilitate seamless wireless communication, this RF technology is compatible with multiple protocols including Bluetooth, enhancing its applicability across a host of devices. Its low energy footprint allows it to be used effectively in battery-powered devices without draining the power supply, ensuring prolonged functioning. The 2.4GHz ISM Band RF technology is engineered to handle extensive data transmission, providing robust and reliable connectivity. This makes it perfect for applications in areas such as home automation, health monitoring devices, and personal electronics looking to leverage this band for efficient communication.
The 39GHz 1W Power Amplifier is tailored for 5G mmWave applications, boasting significant power efficiency. Fabricated with 0.15um PHEMT technology, this amplifier operates between 38 to 42GHz, delivering 19dB of gain with a third-order intercept point (IP3) of 40dBm. With a power of 31dBm at P-1dB, it's housed in a surface-mount technology (SMT) package, ensuring optimal integration in high-frequency systems.
The Convolutional Encoder and Viterbi Decoder IP core is designed to implement error correction capabilities in digital communication systems, ensuring accuracy in transmitted data over noisy channels. This core adheres to configurable polynomials, allowing it to be tailored to specific applications that require robust error detection and correction techniques. In digital communication, the role of a convolutional encoder is to add redundancy to the information sequence, while the Viterbi Decoder helps in tracing back the most probable path of input sequences received, thus correcting any errors introduced during transmission. This IP core facilitates increased reliability and performance for applications where high error rates in data transmission are non-negligible. With its adaptability to a vast array of polynomial configurations, it benefits communication systems like wireless networks, satellite communications, and any system requiring robust error correction. As data channels evolve, having this adaptable and resilient IP core becomes even more pivotal in maintaining data integrity, making it an integral player in modern telecommunications engineering.
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