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.
ADAS and Autonomous Driving technology by KPIT focuses on advancing L3+ autonomy, providing scalable and safe autonomous mobility solutions. This technology addresses fundamental challenges such as consumer safety, localized infrastructure dependencies, and comprehensive validation approaches. With the ever-evolving landscape of autonomous driving, ensuring robust AI solutions beyond mere perception is crucial for elevating autonomy levels in vehicles. By integrating innovative technology and adhering to regulatory standards, KPIT empowers automakers to offer safe and reliable autonomous vehicles that meet consumer trust and performance expectations.
The 802.11 LDPC solution by Wasiela is designed to offer high throughput with on-the-fly frame-to-frame configuration. It allows for flexible LDPC decoding iterations, balancing throughput with error correction performance according to specific requirements. This ensures optimal bit-error-rate and packet-error-rate performance, crucial for maintaining the integrity of wireless communications. With specifications aligning perfectly with industry standards, this product is vital for delivering reliable and efficient connectivity.
The eSi-Comms IP offers parameterizable and configurable solutions for modern air interface standards, such as Wi-Fi, LTE, and DVB. It features advanced DSP algorithms for synchronization, equalization, and modulation, thereby enhancing the robustness of communication links. Suitable for wireless sensor networks, remote metering, and broadcast applications, eSi-Comms delivers efficient transceiver designs optimized for power and area. Supported by C, SystemC, CUDA, and MATLAB libraries, it facilitates swift development and integration into existing systems, ensuring a reduced time-to-market and minimized risk.
Creonic's Turbo encoders and decoders provide powerful forward error correction techniques applicable in wireless communication systems, including 4G LTE and DVB-RCS2. Known for the efficiency in managing bandwidth and minimizing data loss, these IP cores are designed to boost communication integrity and performance. Leveraging sophisticated iterative algorithms, Turbo encoders and decoders execute precise error detection and correction with high data throughput. They are crafted to integrate seamlessly into various hardware platforms, with detailed hardware models and software reference models available for easy incorporation into any system. This versatility ensures that Creonic's Turbo solutions are suitable for both new and existing infrastructures. Quality assurance remains a cornerstone for these products, with each IP core undergoing extensive validation to meet demanding specifications. By addressing critical needs in modern communication systems, Creonic’s Turbo offerings continue to be a preferred choice for engineers and developers striving for reliability and efficiency.
Polar encoders and decoders by Creonic serve as vital components in enhancing data integrity for next-generation communication frameworks such as 5G. These IP cores are designed to deliver superior coding efficiency and robust performance in varied network conditions, supporting high-speed data transmissions while maintaining low latency. The technology stands out for its innovative use of polar codes, noted for their capacity to achieve channel capacities effectively. Creonic's Polar solutions include hardware and software models tailored for straightforward integration into diverse computational environments. They provide excellent adaptability and scalability across multiple hardware systems, making them ideal for cutting-edge digital communication networks. Backing their robust technological framework, Creonic ensures that each product adheres to strict industry standards through comprehensive testing and quality assurance. The result is a set of highly reliable Polar encoders and decoders designed to enhance the performance and efficiency of advanced communication systems.
The 5G NR LDPC Decoder from Mobiveil provides advanced error correction capabilities vital for the next generation of wireless communications. Utilizing the Min-Sum algorithm, it offers programmable bit width options and an iteration termination feature based on a concurrent parity check engine. It efficiently manages redundant transmissions, enhancing performance specifically for 5G applications.
The mmWave PLL by CoreHW is an advanced phase-locked loop suited for high-frequency applications ranging from 19 GHz to 81 GHz. This technology serves critical functions in modern wireless communication networks and radar systems, with applications spanning from 5G transceivers to automotive radar solutions. CoreHW's mmWave PLL features integrated frequency multipliers converting VCO output into radar frequency bands. With a chirp bandwidth of 1 GHz at VCO and scalable options, it's designed for enhanced precision in frequency synthesis and minimal noise output, crucial for broadband systems. Built for versatility, the PLL incorporates an integrated bandgap, LDOs, and digital calibration for process variations. This results in a robust PLL solution that addresses the complex demands of wireless infrastructure and mobile communications, ensuring reliable signal integrity and performance across diverse environments.
The LTE Lite solution is a versatile PHY product tailored to support a wide range of channel bandwidths and modulation schemes. Compliant with CAT 0/1 PHY specifications, it offers features such as IF input support, time tracking, and frequency correction for enhanced communication clarity and reliability. Designed for synthesizable Verilog-2001, the system integrates easily with external tuners and ADCs, making it a foundational component in efficient LTE communication setups.
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.
RF Integration's 802.11 Transceiver Core is engineered to provide high efficiency and performance for wireless communication applications. It supports various 802.11 standards, allowing for versatile integration into modern wireless network environments. This transceiver core is designed to facilitate seamless connectivity and data transfer, crucial for enabling robust Wi-Fi communication. The core incorporates sophisticated signal modulation and demodulation techniques to ensure optimal wireless performance. It is crafted to operate effectively across multiple bands, providing high data throughput and expanded wireless range. By integrating this core, devices can achieve reliable wireless connectivity, making it an ideal choice for consumer electronics, mobile devices, and other networked systems. Advanced power management features are embedded within the core's design, aimed at minimizing energy consumption and extending device battery life. Such efficiency makes it particularly suited for portable and mobile communications technology, highlighting its role in enhancing the user experience for connected wireless environments.
AccelerComm's Software-Defined High PHY is an adaptable O-RAN solution, optimized for the ARM processor architecture. This High PHY solution can operate with or without hardware acceleration, tailored to meet various capacity and power specifications. Developed to complement ASIC/SoC products, it supports a wide range of platforms, enhancing performance flexibility and integration simplicity. This solution is particularly beneficial in environments where dynamic computing capabilities are required and is pivotal in ensuring effective network scaling and performance delivery.
The RWM6050 Baseband Modem represents a leap in cost-effectiveness and power efficiency for applications requiring high bandwidth and capacity in mmWave technology. Designed in partnership with Renesas, this modem can effectively pair with mmWave RF chipsets to fulfill various access and backhaul market needs. With a flexible channel structure and modulation coding, it ensures scalability for multi-gigabit data transmission. The modem's platform is designed for high configurability, and includes subsystems for beamforming and digital signal processing. It stands out for its real-time programmable scheduler and integrated network synchronization, boosting throughput for numerous demanding applications. The RWM6050 combines power with efficiency, facilitating seamless and substantial data flow over several hundred meters with dual modem support providing redundancy and resilience.
LDPC (Low-Density Parity-Check) encoders and decoders from Creonic are designed to enhance data transmission reliability in complex communication systems. These IP cores support various standards, including DVB-S2X, 5G-NR, and IEEE 802.11, offering exceptional error correction capabilities essential for high-speed data transfer. Utilizing advanced algorithms, Creonic's LDPC solutions deliver robust performance while minimizing complexity and power consumption. The LDPC encoders and decoders embody state-of-the-art hardware models and bit-accurate software reference models for seamless integration into existing systems. The hardware models are compatible with FPGA platforms from leading manufacturers, ensuring adaptability across different technological environments. Comprehensive test environments accompany the IP cores, facilitating smooth deployment and validation. Creonic’s commitment to quality is evident in the rigorous testing processes each IP core undergoes, guaranteeing compliance with stringent industry standards. The LDPC solutions are available for download from secured servers, reflecting Creonic's focus on security and accessibility for their global clientele.
The EW6181 GPS and GNSS Silicon is designed to offer superior performance with minimal power consumption. This silicon solution integrates multi-GNSS capabilities, including support for GPS L1, Glonass, BeiDou, and Galileo signals. It incorporates patented algorithms that ensure a compact design with exceptional sensitivity and accuracy, all while consuming little power. The chip includes a robust RF front-end, a digital baseband processor for signal processing tasks, and an ARM MCU for running firmware that supports extensive interfaces for varied applications. With built-in power management features like DC-DC converters and LDOs, the EW6181 silicon is particularly suitable for battery-operated devices that demand low BoM costs. Additionally, it includes antenna diversity capabilities, highlighted with a two-antenna implementation to enhance connectivity, making it ideal for devices subject to frequent orientation changes, such as wearable tech and action cameras. The EW6181 is cloud-ready, allowing it to operate in a connected environment to optimize power usage further and enhance accuracy and sensitivity. When used with EtherWhere's AccuWhere cloud service, the silicon can significantly reduce device-side computations, leading to longer battery life and more frequent location updates, tailored for modern navigation and asset tracking applications.
The PUSCH Equalizer by AccelerComm is a cutting-edge solution aimed at improving spectral efficiency in 5G NR networks, particularly those involving multiple antenna configurations. It addresses the challenges of noise and interference using advanced equalization algorithms, which are efficiently implemented as hardware accelerations. This product integrates with the PUSCH Decoder, enhancing performance and cost-efficiency by incorporating demodulation and decoding capabilities. Compliant with 3GPP standards, the PUSCH Equalizer offers superior uplink performance, optimized for both FPGA and ASIC platforms, and contributes to faster market deployment for network operators.
The Waves Dragonfly platform is a sophisticated IP solution designed to integrate full NB-IoT and GNSS support into smart IoT devices. It provides extensive features that cater to the needs of the cellular IoT market, offering embedded GPS capabilities for precise geolocation and tracking. With a robust, flexible architecture, this platform can support multiple standards for wide application in various IoT projects.
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 PentaG RAN platform is designed for emerging 5G network infrastructure, providing a comprehensive baseband solution for 5G RAN ASICs and Open RAN systems. It is recognized for industry-leading performance and scalability, tailored to meet the rigorous demands of modern communications networks. The platform supports a variety of network configurations and use cases, ensuring the facilitation of seamless communication in both urban and rural settings.
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.
The 5G Remote Radio Unit by Saankhya Labs represents a stride forward in ORAN-compliant infrastructure, designed to meet the expansive requirements of modern 5G networks. This multi-band RU is built with sophisticated analytics capabilities, allowing it to dynamically adapt and optimize the use of radio resources to enhance spectrum efficiency. Saankhya's 5G RU supports a wide array of 3gpp bands, with particular emphasis on the low and mid frequencies such as Bands 71, 29, and 40. This broad band support ensures wide applicability, from urban to rural deployments, making it suitable for a diverse set of network demands. Incorporated within it is a unique front haul compression technique which reduces operational expenses, allowing operators to scale their infrastructure cost-effectively. Its design reflects a commitment to offering a scalable, open, and flexible RAN solution that aligns with global 5G deployment strategies.
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 PCS2100 is a Wi-Fi HaLow IoT STA modem chip designed by Palma Ceia for IEEE 802.11ah standard applications. It's engineered to optimize connectivity in IoT environments, offering exceptional range and power efficiency. Operating in the sub-gigahertz frequency spectrum, it ensures long-range connectivity, which is ideal for applications like smart meters and industrial IoT devices. This chip facilitates reliable IoT networks with support for low power, high-density applications. It features innovative technologies like Target Wake Time (TWT) and Resource Allocation Window (RAW), contributing to extended battery life by optimizing device wake schedules and reducing power consumption. It also supports a broad range of modulation coding schemes, which enhance connection reliability and data throughput. The PCS2100 is highly adaptable, supporting interface standards including HS-SPI, HS-UART, and JTAG, among others. It offers comprehensive security features with support for WPA3 and AES-CCMP encryption, embedding the latest IoT network security protocols.
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 platforms offered by Tower Semiconductor are engineered to deliver exceptional performance for wireless communication applications. This platform is designed to address the needs of high-frequency and low-power RF applications essential for modern telecommunications, including 5G, IoT devices, and other consumer electronics requiring seamless connectivity. By leveraging RF-SOI technology, the platform achieves lower power consumption and improved integration of RF components, thereby enhancing system performance and reducing overall product costs. RF-CMOS adds to this by providing flexibility in designing integrated circuits that need both analog and digital components on a single chip, useful for space-constrained applications without sacrificing performance. These platforms support a wide bandwidth spectrum and high dynamic range, making them ideal for high-speed data transfer applications. With advanced design enablement support such as comprehensive PDKs and simulation tools, the RF-SOI and RF-CMOS platforms facilitate quick adaptation and integration into existing product lines, accelerating the development process of cutting-edge wireless solutions.
The High PHY Accelerators from AccelerComm are a suite of IP cores that enhance signal processing capabilities for 5G networks. These accelerators are pivotal in handling complex algorithms like LDPC and Polar, which are essential for channel coding. The range from AccelerComm includes accelerators for ASIC, FPGA, and SoC, each designed to maximize throughput and minimize latency and power consumption. Exploiting patented signal processing algorithms, these accelerators meet the stringent requirements of modern network infrastructures, enhancing spectral efficiency and reducing operational costs.
Palma Ceia's NB-IoT (LTE Cat NB1) Transceiver is designed to meet the stringent requirements of the 3GPP Release 13 standards. This transceiver provides reliable connectivity for narrowband IoT applications, ensuring low power consumption and robust network performance, making it suitable for wide-ranging IoT deployments. The transceiver is versatile, functioning in bands across wide frequency ranges, and is built to sustain operations under varied environmental conditions with high RF efficiency. Its scalable design includes programmable features and interfaces like SPI and UART, allowing easy integration into complex network architectures. Offering enhanced control of both transmit and receive paths, the NB-IoT transceiver supports extended gain ranges and low signal noise, crucial for sustained, reliable IoT network management. Equipped with calibration features for DC offset and IQ imbalance, it enhances connectivity precision and offers seamless integration with FPGA and silicon baseband modules for reliable data throughput.
Palma Ceia's PCS2500 is an integrated Wi-Fi HaLow Access Point chip, designed to operate within the sub-gigahertz band and conforming to the IEEE 802.11ah standard. This chip functions as both an access point and a modem gateway in Wi-Fi HaLow networks, enabling efficient management of dense, low-power IoT networks with extended range capabilities. The PCS2500 is built to streamline network communication with features like Target Wake Time (TWT) and Resource Allocation Windowing (RAW), which optimize device interaction across the network, improving efficiency and reducing power consumption. It supports a broad frequency range and offers flexibility to comply with regional standards, ensuring reliable connectivity over large distances. Security is a key focus of the PCS2500, incorporating robust encryption technologies such as WPA3 and AES-CCMP. It includes a variety of interfaces for integration flexibility, making it an ideal choice for building secure and scalable IoT ecosystems with extended battery performance.
AccelerComm's Polar coding solution is at the forefront of error correction for 5G NR control channels, characterized by its flexibility and efficiency. This patented IP enables high degrees of parallelism in its design, significantly cutting down on resource usage while maximizing performance. It features a detailed polar encoding and decoding chain, integrates smoothly with wider communication systems, and is delivered in various form factors suitable for both ASIC and FPGA platforms. The solution meets all 3GPP standards, ensuring reliable communication with excellent error correction capability, making it vital for maintaining robust connection quality across an array of 5G applications.
Wireless IP from Analog Circuit Works empowers devices with the ability to efficiently handle both power and data transmission across various wireless applications. These include portable, medical, and sensor-based devices, where reliable and high-frequency operation is critical.\n\nDesigned to achieve maximum frequency performance across several process nodes, this IP supports seamless integration into systems that require robust wireless functionalities. Its adaptability ensures compatibility with innovative wireless technologies while achieving efficient power management.\n\nThe adoption of Wireless IP facilitates enhanced communication capabilities, optimizing connectivity and bandwidth management, necessary for today's wireless communication challenges. This ensures devices are future-ready, equipped with state-of-the-art transceiver technology that meets rigorous modern standards.
The 802.11ah HaLow Transceiver by Palma Ceia is specifically designed to meet the demands of contemporary IoT applications, providing robust connectivity with extended range and optimal power usage. Compliant with the IEEE 802.11ah standard, this transceiver is tailored for environments where long battery life and reliable signal coverage are crucial, such as smart homes and industrial IoT applications. Its advanced receiver architecture minimizes noise and latency, ensuring superior performance even in challenging environments. It offers a versatile modulation capability with support for various bandwidths, enhancing flexibility and making it adaptable to multiple IoT applications. This transceiver supports a variety of interfaces for seamless integration, and features an onboard temperature sensor and battery monitoring for improved system reliability. It is designed to be easily incorporated into broader system architectures, either as a standalone unit or as part of a more sophisticated system-on-chip (SoC).
ArrayNav is an innovative GNSS solution that applies multiple antennas to significantly improve signal sensitivity and accuracy. This advanced technology is an adaptation from the communication sector’s use of MIMO, tailored to address GNSS challenges like multipath errors and potential signal jamming. By employing a diversified antenna setup, ArrayNav enhances signal gain and diversity, achieving higher accuracy, especially in environments prone to signal degradation such as urban canyons. The multi-antenna approach allows for distinct identification and suppression of interfering signals, including those used for spoofing or jamming, by analyzing their unique signatures. The system effectively places null signals in the direction of such disturbances, maintaining the reliability and precision of positioning data. This makes ArrayNav particularly beneficial for applications reliant on sub-meter accuracy and quick acquisition. ArrayNav’s patented capabilities ensure robust GNSS performance, even in constrained environments, by boosting channel gain by 6 to 18 dB. This gain significantly improves operational efficacy in various applications, from automotive advanced driver-assist systems (ADAS) to personal navigation devices, ensuring dependable operation no matter the surroundings.
The Complete 5G NR Physical Layer offered by AccelerComm is a versatile and high-performance solution ideal for specialized applications including O-RAN, satellite, and small-cell networks. This comprehensive suite integrates the High PHY 5G NR product with AccelerComm's Low PHY, providing a robust physical layer IP solution. Designed for performance optimization, it ensures superior power efficiency and spatial resource management, enabling high-capacity communication across diverse hardware platforms. The solution leverages AccelerComm's cutting-edge 5G acceleration technologies coupled with innovative signal processing methods, unlocking unmatched link performance. Openly licensable and adaptable, this IP core is available for software, FPGA, and ASIC environments, ensuring seamless integration and reduced project timelines through early testing on COTS development boards.
The PCS1100 is an advanced Wi-Fi 6E transceiver chip by Palma Ceia SemiDesign. Engineered for use in Wi-Fi 6 networks, it supports the IEEE 802.11ax standard, facilitating high-speed wireless communication in both Access Point (AP) and Station (STA) configurations. Its robust RF architecture is optimized for tri-band operation, covering 2.4 GHz, 5 GHz, and 6 GHz frequency bands, which is essential for modern, high-density environments. This transceiver supports multiple spatial streams up to 4x4 and employs advanced features like MU-MIMO and OFDMA, providing increased throughput and efficiency across congested networks. With capabilities such as dual-band concurrent operation and 1024-QAM modulation, the PCS1100 ensures high performance and reliability, making it ideal for environments ranging from smart homes to large public venues. The PCS1100 also features a compact design suitable for integration into various systems, including ASICs and ASSPs, enhancing its versatility in different technological setups. It offers connectivity and ease of integration with its analog I/Q interface and chip-to-chip communication via SerDes link.
The PentaG2 baseband platform represents Ceva's latest advancements in 5G technology, incorporating robust support for mobile broadband and IoT applications. This platform excels in delivering high performance with flexibility, catering to the increasing demands for data connectivity and speed in mobile devices. With enhanced capabilities for multi-standard operation, it supports a diverse range of applications from commercial consumer electronics to industrial IoT devices.
Creonic's demodulation IP cores are central to efficient signal processing in communication systems, addressing the needs of both conventional standards like DVB-S2 and more recent versions such as DVB-S2X. These IP cores decode complex modulated signals robustly, ensuring high-rate data transmission accuracy crucial for applications like satellite communications. The demodulators leverage advanced algorithms to adaptively process signals with minimal distortion and noise, thus maintaining data integrity across long distances and varying conditions. Compatibility with multiple digital modulation techniques is a notable feature, making these cores versatile and highly applicable to diverse communication protocols. Testing and validation at multiple levels are conducted to ensure these cores meet the rigorous demands of modern communication environments. Creonic's dedication to quality and innovation is reflected in their demodulation solutions, making them a trusted choice for reliable, high-performance signal processing.
The LDPC IP from AccelerComm is developed for 5G New Radio, providing high-efficiency channel coding and decoding capabilities. This IP delivers robust error correction performance through novel propagation schedules and integrated workflow solutions. It supports AMD, Intel, and Achronix FPGAs, and is optimized for ASIC applications. The LDPC solution achieves quick integration, low latency, and high throughput, crucial for uplink and downlink data channels in modern, dense communication networks.
Creonic's modulation IP cores are crafted to optimize data transmission through sophisticated signal processing. These cores support various specifications, including DVB-S2X, providing efficient modulation capabilities that enhance signal robustness and transmission reliability, essential for wireless communication technologies. Leveraging state-of-the-art algorithms, these modulation cores ensure effective transformation of digital data into signals that can be accurately transmitted through different media channels. The compatibility with a range of hardware architectures underscores their adaptability, which is further facilitated through comprehensive software and hardware models for seamless integration. As with all Creonic products, the modulation cores are subjected to stringent quality checks to assure performance and compliance with global standards. This dedication to excellence ensures Creonic's modulation cores are an exemplary choice for engineers looking to boost efficiency and integrity in data communication systems.
The RT583 integrates Bluetooth 5.1/5.2 with Matter Thread standards, empowering developers to build interconnected smart home devices. With its ARM Cortex M3 MCU and multi-protocol support, it's a sophisticated solution for creating robust, interoperable smart ecosystems.
The 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.
CML Microsystems' SµRF MMICs are cutting-edge high-frequency, high-bandwidth semiconductor products designed for RF and mmWave applications. These devices are tailored to support burgeoning markets like 5G, satellite communications, and the Internet of Things (IoT). They offer superior performance in operation frequency ranges that meet the exacting demands of modern communication infrastructures. The MMICs are engineered to drive advancements in wireless communication by providing highly efficient signal processing capabilities. This suite of products ensures seamless integration into network architectures, facilitating enhanced data transmission and reception. As such, they play a critical role in supporting the reliable and efficient functioning of complex communication systems. Highly suitable for applications requiring robust and dynamic RF solutions, these MMICs address the significant technological demands of network providers and manufacturers. Through leveraging their high-frequency processing capabilities, CML Microsystems enables its customers to build next-generation communication solutions that are pivotal for future connectivity.
Brite Semiconductor offers the YouRF series, providing a range of RF communication solutions. This product line includes Bluetooth Low Energy (BLE), NB-IoT, and proprietary 2.4 GHz radios, catering to diverse RF needs. YouRF BLE provides a full blue-tooth low energy IP, optimized for high-performance in the 2.4GHz ISM band. It integrates a high-precision receiver, a phase-locked loop, and a high-efficiency amplifier. Ideal for IoT and wearable applications, YouRF BLE ensures stable and energy-efficient communication. Additionally, the YouRF NB-IoT transceiver is engineered for narrowband IoT applications, spanning frequencies of 699 MHz to 960 MHz. This transceiver integrates multiple functional units, facilitating effective IoT connectivity while optimizing for low power consumption, pivotal for extended battery life in IoT devices.
Digital Down Conversion (DDC) is instrumental in translating high-frequency signals down to a baseband frequency, making them easier to process and analyze. The technology integrates a carrier selector, frequency down converter, filter, and decimator, each playing a pivotal role in transforming signals into a more manageable form without sacrificing data integrity. Faststream Technologies' DDC is designed to provide accurate frequency conversion, ensuring that signals maintain their integrity through each processing stage. It efficiently utilizes filtering techniques to eliminate noise and unwanted frequencies, while the decimator optimizes sampling rates for better data handling. DDC is particularly essential in applications where signal clarity and precision are crucial, such as in wireless communication systems. It enables efficient data processing, reducing complexity while maintaining high-quality signal outputs, which is vital for advanced digital communication infrastructure.
The Digital Pre-Distortion (DPD) technology is pivotal in optimizing RF Power Amplifiers' efficiency. By compensating for the inherent non-linearities generated by these amplifiers, DPD ensures signal integrity, enhancing output performance and reliability. This technology is crucial for the efficient functioning of RF systems, minimizing distortions and improving overall signal quality. Faststream's DPD solution is engineered to counteract the memory effects seen in power amplifiers, providing a cleaner, more accurate signal output. Employing advanced algorithms, this technology adjusts the input signal, pre-distorting it to anticipate and negate the effects of amplifier-induced distortions. This not only improves the signal clarity but also extends the amplifier's lifespan by reducing stress. By enhancing the power efficiency of RF amplifiers, DPD contributes to reduced energy consumption, thus promoting sustainable practices in wireless communications. Faststream's implementation of DPD stands out for its precision and effectiveness in maintaining high-quality signal transmission across various applications.
Crest Factor Reduction (CFR) technology is essential for managing power amplifier demands by minimizing peak-to-average power ratios. This reduction aids in easing power supply design constraints and cuts down peak power needs, ensuring more efficient power amplifier operations. CFR is indispensable in modern communication systems where maintaining signal integrity and reducing power consumption are paramount. Faststream Technologies’ CFR solution is structured to streamline power amplifier requirements, enabling more efficient power usage and enhancing system reliability. By adjusting the signal’s amplitude distribution, CFR effectively diminishes the peaks that would otherwise lead to power inefficiencies or potential overloads. Utilizing CFR, communication systems can achieve improved power efficiency, reduce operational costs, and extend the life of their hardware components. This technology supports high-performance signal processing, ensuring that systems remain robust under variable load conditions, all while maintaining optimal performance metrics.
This PCD03VH turbo decoder supports 3GPP LTE and 3GPP2 1xEV-DO networks with its eight-state high-speed configuration. It is engineered to minimize latency through ping-pong input and output memory configurations. This feature allows for effective parallel processing, making it extremely efficient for LTE and advanced CDMA applications where rapid response and system flexibility are critical. The decoder's architecture is built for robust performance in demanding communication situations.
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.
The 5G ORAN Base Station is designed to revolutionize mobile networking by significantly boosting wireless data capacity. It opens new doors for various wireless applications, supporting the advancement of mobile technology. With this cutting-edge base station, Faststream Technologies contributes to setting new standards in mobile networking technologies, accommodating the surging demand for high-speed data transfer. The base station is engineered to facilitate seamless connectivity, allowing users to experience enhanced network capabilities. It supports the integration of new applications and services, propelling the wireless communication industry forward. The deployment of 5G ORAN is not only about faster speeds but also about enhancing reliability and expanding network reach. A major benefit of the 5G ORAN Base Station is its flexibility and scalability, which are crucial in meeting diverse consumer and business needs. Its architecture enables dynamic resource management and efficient spectrum usage, making it a highly effective solution for modern network requirements.
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.
The Digital Up Conversion system is a sophisticated technology composed of an interpolating filter chain, a numerically controlled oscillator, and a mixer. This system is crucial for the effective conversion of baseband signals to higher frequency bands suitable for transmission. The process involves accurately synthesizing the increased frequency, ensuring the signal is prepared for the next stages of communication. Faststream Technologies' Digital Up Conversion technology excels in providing precise frequency translation, making it instrumental in advanced signal processing. By utilizing interpolating filters, the system enhances signal resolution, and the numerically controlled oscillator ensures stable frequency generation. The mixer further adjusts the signal for optimal transmission conditions. Digital Up Conversion not only facilitates frequency translation but also plays a role in enhancing overall signal integrity and reducing potential noise interference. This capability is particularly beneficial in environments where high-frequency signal integrity is critical, ensuring robust and clear communication paths.
LightningBlu offers a world-first, multi-gigabit track-to-train solution, ensuring uninterrupted on-the-move connectivity. With its deployment in challenging transport environments, this system uses mmWave technology to deliver flawless communication between trackside and train. With a capacity for a robust gigabit train experience, both trackside nodes and train-top equipment are qualified for their environments, ensuring rigorous and efficient data performance. The solution is currently in active use on some of the busiest railways, improving connectivity for all commuters significantly. Its technical prowess lies in its ability to provide an exceptional throughput of up to 3.5 Gbps, operating efficiently to surpass the offerings of traditional mobile networks while ensuring a low carbon footprint.