All IPs > Wireless Communication > 3GPP-LTE
The 3GPP-LTE category of semiconductor IPs is a vital component for modern wireless communication systems. As the world continues to rely on mobile connectivity, Long Term Evolution (LTE), standardized by the 3rd Generation Partnership Project (3GPP), has become an essential technology. This category includes sophisticated IP cores that enable semiconductor manufacturers to design and implement LTE-compatible solutions efficiently, ensuring seamless and robust communication services.
3GPP-LTE semiconductor IPs offer a comprehensive suite of features facilitating high-speed data transfer, low latency, and increased capacity for wireless networks. These IPs are integral in supporting a wide array of services, from voice over LTE (VoLTE) to multimedia streaming and cloud computing. By providing the foundational technology for creating modems, transceivers, and base station components, these IPs are pivotal in enhancing the user experience in smartphones, tablets, and other mobile devices.
Moreover, the designs within this category allow for flexible and scalable deployments across various market segments. With the continuous evolution of LTE, including advancements such as LTE-Advanced and LTE-Advanced Pro, developers find these solutions invaluable for staying ahead in the competitive telecom industry. They enable the efficient integration of multiple input and output antennas (MIMO) and carrier aggregation, thereby maximizing spectral efficiency and network performance.
In this fast-evolving digital landscape, 3GPP-LTE semiconductor IPs are not just about maintaining connectivity; they are about transforming it. These IPs provide the tools necessary for the next wave of innovations in IoT, automotive connectivity, and beyond, ensuring that manufacturers can develop the cutting-edge products required by the demands of today's consumers and industries. Whether for infrastructure or consumer applications, the IPs in this category support the progression and globalization of wireless communication technologies.
The eSi-Comms solution provides a highly parameterisable and configurable suite for communication ASIC designs. This comprehensive collection includes OFDM-based modem and DFE IPs supporting a vast array of contemporary air interface standards such as 4G, 5G, Wi-Fi, and DVB among others. It offers robust and efficient solutions for modulation, equalization, and error correction using advanced digital signal processing algorithms. With its capabilities specific to synchronization and demodulation across multiple standards, it equips systems for optimal data flow management. The adaptable DFE features support precision in digital frequency conversion and other enhancements, fortifying both the transmitting and receiving ends of communication systems. This IP empowers wireless sensors, remote metering, and cellular devices, ensuring seamless integration into a diverse range of communication applications.
The RWM6050 baseband modem by Blu Wireless represents a highly efficient advancement in mmWave technology, offering an economical and energy-saving option for high bandwidth and capacity applications. Developed alongside Renesas, the modem is configured to work with mmWave RF chipsets to deliver scalable multi-gigabit throughput across access and backhaul networks. This modem is ideal for applications requiring substantial data transfer across several hundred meters.\n\nThe RWM6050 leverages flexible channelization and advanced modulation support to enhance data rates with dual modems and integrated mixed-signal front-end processing. This ensures that the modem can effectively handle diverse use cases with varying bandwidth demands. Its versatile subsystems, including PHY, MAC, ADC/DAC, and beamforming, facilitate adaptive solutions for complex networking environments.\n\nA standout feature of the RWM6050 is its integrated network synchronization, ensuring high precision in data delivery. Designed to meet the futuristic needs of communication networks, it helps end-users achieve superior performance through its programmable real-time scheduler and digital front-end processing. Additionally, the modem's highly digital design supports robust, secure connections needed for next-generation connectivity solutions.
The Software-Defined High PHY from AccelerComm is an adaptable solution designed for ARM processor architectures, providing versatile platform support. This PHY can function with or without hardware acceleration, catering to varying demands in capacity and power for diverse applications. It seamlessly integrates into O-RAN environments and can be tailored to optimize performance, aligning with specific network requirements. This versatile solution capitalizes on the strengths of ARM processors and offers additional flexibility through optional hardware accelerations. By providing a scalable framework, the Software-Defined High PHY supports efficient deployment, regardless of the network size or complexity. This adaptability ensures that network managers can configure the PHY to meet specific performance objectives, maximizing throughput while minimizing power consumption. Esteemed for its flexibility and ease of integration, this solution exemplifies AccelerComm's commitment to delivering high-caliber, platform-independent PHY solutions. It empowers network developers to tailor their setups, thus enhancing performance metrics like latency and spectral efficiency.
AccelerComm's Polar coding solution is a state-of-the-art offering tailored for the 5G NR control channel, providing efficiencies that redefine how fast data can be accurately processed and transmitted. This IP is groundbreaking due to its ability to enable higher degrees of parallelism and scalability, essential for high-demand network uses. The architecture stands out due to its high degree of resource efficiency, significantly lessening the use of computational resources while ensuring top-tier performance. Its compliance with 3GPP standards ensures smooth integration within existing frameworks, making it an invaluable asset for operators focusing on control channel integrity. Particularly advantageous for its configurability, the Polar solution scales to meet exacting BLER performance parameters. This level of adaptability underpins the capability to achieve superior spectral efficiency gains, crucial for modern wireless communications.
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.
The LTE Lite offers a high-performance PHY layer for user equipment with compliance to CAT 0/1 standards. Supporting flexible channel bandwidths, it works seamlessly with standard RF tuners. The design features automated demodulation via a controlling state machine and includes frequency and timing correction, ensuring accuracy even in high-offset environments. Synthesizable in Verilog-2001, it's highly adaptable for various telecommunication needs.
AccelerComm's High PHY Accelerators are advanced solutions featuring a library of IP cores that cater to a range of 5G NR needs, including key signal processing algorithms. These accelerators are aimed at maximizing efficiency in data throughput and reducing latency, which are essential for modern communication standards. Providing enhancements such as LDPC that improves BLER significantly, these accelerators deliver reduced spectral costs and power consumption. They are available in several forms - ASICs, FPGAs, or software-only configurations - and can be deployed in varied hardware environments. The integration of complex algorithms like Hybrid Automatic Repeat reQuest (HARQ) and channel estimation signify their role in enhancing the robustness and reliability of 5G communications. Born from rigorous academic research, the High PHY Accelerators are highly configurable, adapting to specific network demands. Their success is validated by compliance with key 3GPP standards, making them a cornerstone technology for achieving superior network performance and efficiency.
AccelerComm offers an LDPC solution meticulously crafted for 5G NR channels that promises efficient error correction and superior throughput. This solution represents the best of block-parallel and row-parallel decode architectures, enhancing efficiency while maintaining top-notch performance. Widely recognized for its hardware efficiency, the LDPC enhances signal integrity in the data channel, ensuring minimal latency. It adheres to the complete 3GPP standardization, supporting code and transport block processing. The architecture's configurability supports diverse deployment needs, allowing seamless integration into existing network environments. Delivered in ASIC, FPGA, or software-only form factors, AccelerComm's LDPC block is ideal for operators seeking to maximize reliability and performance in their communications infrastructures. This IP stands as a testament to AccelerComm's innovation, marrying tradition with modern demands for enhanced digital communications.
Perfect for advanced parking solutions, the ASPER radar sensor operates at 79GHz, providing superior performance compared to traditional ultrasonic systems. Designed to deliver a 180° coverage with a single module, it offers enhanced detection capabilities for both passenger and commercial vehicles. ASPER's edge processing and domain-specific features make it ideal for automotive applications like blind spot detection and tailgate protection, while ensuring accuracy unaffected by environmental conditions.
Pacific MicroCHIP's XCM_64X64_A is a sophisticated cross-correlator ASIC, comprising an array of 128 ADCs each running at 1GSps. It is optimized for radar receivers and spectrometers, delivering low power consumption and supporting bandwidths from 10MHz to 500MHz.
The PUSCH Equalizer by AccelerComm is designed to enhance spectral efficiency in wireless solutions employing multiple antennas. It utilizes sophisticated equalization algorithms, implemented directly in hardware to efficiently tackle signal interference and noise, thus improving overall data transmission quality. This Equalizer is integral to the Push Decoder, supplementing its functionality with advanced decoding capabilities, including LDPC and Polar, while maintaining alignment with 3GPP NR specifications such as TS 38.211 and 38.212. By doubling spectral efficiency depending on deployment conditions, the PUSCH Equalizer reduces operational expenditures and power requirements significantly. AccelerComm's PUSCH Equalizer is available for both FPGA and ASIC platforms, ensuring flexibility for future-proof deployment in diverse environments. Its implementation shortens time-to-market by enabling high-quality signal processing, which results in enhanced network performance.
The XCM_64X64 from Pacific MicroCHIP is an advanced cross-correlation system with a complete 64 by 2-channel configuration, suitable for synthetic radar and spectrometric applications. It minimizes power use while offering high-speed processing capabilities over a wide frequency range.
This front-end module is engineered to support the advanced communication standards of WiFi6, LTE, and 5G, operating within a frequency range of 2.4 to 7 GHz. Designed for integration in mobile and cellular devices, it combines a switch, low-noise amplifier (LNA), and power amplifier (PA), ensuring optimal performance across various communication protocols. The module's architecture is crafted to deliver superior connectivity and high-speed data transfer capabilities, bolstering the signal's integrity through each stage of processing. It provides excellent linearity and low noise figures, crucial for maintaining the high quality of service required in today's communication networks. Furthermore, this front-end module is noted for its power-efficient design, which is vital for extending device battery life while managing the demands of new generation communication technologies. These features make it a fundamental component for devices aiming to offer state-of-the-art wireless connectivity.
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 hellaPHY Positioning Solution by PHY Wireless utilizes cutting-edge technology for high precision and secure location tracking over cellular networks. It is particularly designed to cater to massive IoT applications, providing low-power and cost-efficient solutions that work seamlessly indoors and outdoors. Leveraging 5G and advanced edge computing, this solution ensures maximum privacy and scalability, making it ideal for diverse applications ranging from smart labels to logistics tracking. This solution dramatically outperforms traditional GNSS systems by using far less data, reducing costs, and enhancing spectral efficiency. Its innovative approach involves device-based processing of standardized 5G signals, which means the device's location is calculated locally. This not only improves speed and accuracy but also maintains a high level of data security, as the location information is encrypted and not shared with third-party servers. Designed with practicality and adaptability in mind, the hellaPHY Positioning Solution integrates effortlessly into existing hardware through a simple API, supporting a range of devices without the need for extensive modifications. With PHY Wireless's patented algorithms, operators can optimize their spectrum use, and users enjoy a robust location service that meets various operational demands. The technology underlying the hellaPHY Positioning Solution stands as evidence of PHY Wireless's commitment to innovation, ensuring that their products meet the growing needs of the IoT landscape. With support for existing LTE and 5G networks, this solution offers businesses a future-proof method to enhance operational efficiencies and service offerings.
The 3GPP LTE Turbo Decoder is engineered to enhance data processing in high-performance mobile networks. With an 8 state configuration and options for 1, 2, 4, or 8 parallel MAP decoders, it is designed to significantly improve error correction, ensuring reliable and high-speed data transmission in LTE environments. This decoder is optimized for networks where bandwidth efficiency is crucial, achieving peak performance while effectively handling the noise and interference prevalent in mobile networks. The option to integrate multiple parallel decoders allows for customized implementations, aligning with specific mobile network demands and optimizing overall system throughput and reliability. Deploying this decoder can vastly improve application responsiveness and network resource management. It plays a pivotal role in the tech infrastructure necessary to support 4G LTE services, meeting the high expectations for connectivity and data integrity demanded by users and service providers alike.
Designed for multi-standard networks, the 3GPP LTE and 3GPP2 1xEV-DO Turbo Decoder excels in environments requiring flexibility and advanced error correction. It features an 8 state turbo decoding system, utilizing ping-pong input and output memories for enhanced data processing and throughput. This decoder ensures consistency in data communication, a necessity for networks that support LTE and 1xEV-DO standards. It is engineered for efficient operation across different network types, supporting varied communication protocols and improving signal integrity and data correctness. Optimizing both data transfer speeds and network reliability, this decoder supports robust implementations for telecom operators, facilitating smoother transitions and reduced error rates within network infrastructure. It significantly contributes to improved user experiences and reliable data exchanges, even under heavy network demands.
The LightningBlu solution by Blu Wireless is an innovative track-to-train multi-gigabit solution specifically engineered for high-speed rail connectivity. This cutting-edge system ensures seamless, high-speed communication for moving trains, making it ideal for future gigabit trains. The trackside node is optimized for deployment every kilometer, serving as a bridge between wireless links to trains and a fixed trackside fiber network. Offering unparalleled efficiency, it features two-sector radios that provide continuous 3 Gbps aggregate throughput. Having been deployed across major railways such as South Western Rail and Caltrain, it has greatly enhanced connectivity and commuter experience.\n\nBlu Wireless emphasizes mobile connectivity with its mmWave solution, operating at significantly lower power levels compared to 4G or 5G, yet is capable of data speeds nearly 100 times faster than 5G. This ensures operational efficiencies, safety, and a superior passenger experience. Through consistent gigabit throughput, passengers can access substantial data volumes in real-time, a stark contrast to current capabilities offering minimal capacity. The LightningBlu represents a transformative leap in train travel connectivity by meeting contemporary data needs and establishing a groundwork for future advancements.
Saankhya Labs' 5G Remote Radio Unit is an ORAN 7.2x compliant device, designed to provide multiband support for next-generation 5G networks. This unit plays a pivotal role in facilitating advanced wireless communications by connecting cellular base stations to the core network efficiently and seamlessly. Its support for multiple frequency bands allows it to cater to diverse communication needs, making it a versatile solution for modern cellular infrastructure. This adaptability is coupled with robust performance capabilities, ensuring reliable connections across varied geographies and network conditions. Specially built to enhance network capacity and data throughput, the 5G Remote Radio Unit enhances interoperability with existing and upcoming network technologies, ensuring smooth transitions and backward compatibility. It is especially suitable for deployment in dense urban environments and underserved rural locations, aiding in bridging the communication divide.
The NB-IoT (LTE Cat NB1) Transceiver by Palma Ceia SemiDesign is tailored for IoT operations under Release 13 and 14 standards from 3GPP. It offers a comprehensive feature set designed for cellular IoT, providing robust and efficient connectivity by accommodating a variety of bandwidth and modulation requirements. Built with state-of-the-art RF design principles, this transceiver facilitates low power consumption while maintaining high performance. It features a well-balanced receive path and integrates seamless DC offset correction mechanisms. For enhanced interoperability, the transceiver offers various interfaces such as SPI, UART, and I2C, ensuring it can seamlessly fit into a wide range of electronic designs. Its versatility extends to the supported frequency range, covering diverse global channels. This, combined with advanced calibration and low latency, makes it ideal for mission-critical applications. Furthermore, its security and integration capabilities make it a preferred choice for developers seeking robust design and ease of implementation.
The Ceva-PentaG RAN platform offers a robust baseband processing solution for 5G infrastructure, providing the necessary components to develop open and versatile radio access networks (RAN). Ideal for macro cell base stations, small cells, and remote radio units, the platform supports scalable high-PHY/low-PHY splits. With support for enhanced 5G features like massive MIMO and beamforming, Ceva's platform ensures efficient deployment for operators transforming their infrastructure for next-generation connectivity. The inclusion of the Ceva-XC22 vector DSP core and specialized hardware accelerators helps achieve excellent power-performance area metrics.
Lekha's 4G/LTE Software Stack is a robust solution designed to fulfill the diverse needs of telecommunications. Aligned with the 3GPP Release 10 specifications, it aids OEMs in building 4G radio network products. The software is scalable, modular, and capable of supporting various SoC architectures, including optimization for Texas Instruments' Keystone II platform. This modular approach helps facilitate seamless incorporation into diverse hardware environments, offering flexibility and performance consistency. The stack includes comprehensive end-to-end solutions that enable the development of secure LTE networks. These can be customized for both LTE and non-LTE bands, allowing for wide applicability across different network settings. The stack also provides a platform-independent codebase, ensuring adaptability across multiple operating environments, fostering innovation and versatility. Moreover, Lekha has designed this software to seamlessly upgrade to future releases, promoting investment protection through scalable evolution. Comprehensive technology support and optimization further enhance the software's utility across a spectrum of telecommunications applications, from commercial deployments to bespoke solutions.
AccelerComm offers a sophisticated 5G NR physical layer solution that is particularly geared for specialized applications such as O-RAN, satellite communications, and small-cell networks. This solution supports options 6 and 7.x, integrating high-performance PHY elements with AccelerComm's bespoke Low PHY. The IP is designed to balance performance, power, and scalability, enabling optimal deployment across diverse networks. The 5G NR physical layer is equipped with Acceleration IP cores that leverage innovative signal processing techniques to boost link performance. Openly licensable, this IP supports a wide array of platforms, making it adaptable for ARM-based, FPGA, and ASIC implementations. It enhances project assurance with accessible reference systems that allow thorough integration and testing on commercially available boards. AccelerComm's complete physical layer IP is dedicated to ushering in transformative power and performance improvements to 5G networks, underpinning the infrastructure with superior signal processing to meet the rising demand for high-capacity data transmission.
The PCS1100 is a sophisticated Wi-Fi 6E RF transceiver designed by Palma Ceia SemiDesign, catering to the latest demands in connectivity. This transceiver, adhering to the IEEE 802.11ax specification, supports tri-band operations over 2.4 GHz, 5 GHz, and the newer 6 GHz band. Its design is well-suited for both Access Point (AP) and Station (STA) roles, highlighting capabilities such as MU-MIMO for enhanced simultaneous user connections. Engineered for power optimization, the PCS1100 offers superior radio frequency architecture with dual-band concurrent capabilities, allowing it to handle multiple data streams efficiently. It supports a wide range of modulations including 1024-QAM, which significantly boosts data throughput, reaching up to 4.2 Gbps. The transceiver's design focuses on reliability, boasting excellent receiver sensitivity and low phase noise, guaranteeing high-quality wireless communication over long ranges. This device is crafted with high standards, demanding strict RF performance under diverse conditions. Industries can leverage it for various applications, from smart cities to electronics requiring robust connectivity. Additionally, its integration is facilitated through simple interfaces such as SerDes and analog I/Q, enabling seamless cooperation with other chips ensuring error vector magnitude significantly exceeds standard requirements.
Specialized for dual-standard networks, the 3GPP UMTS/LTE and 3GPP2 Turbo Decoder accommodates systems requiring heightened flexibility and error correction capabilities. It operates using an 8 state design, with optional configurations of 16, 32, 64, or even 256 state Viterbi decoders. This wide range supports extensive error correction and aligns with various protocol demands. The decoder facilitates seamless transitions and data exchanges between UMTS and LTE networks, ensuring stability and continuity in service provision. Its adaptable design enables integration across varying network architectures, promoting improved data throughput and network efficiency for telecom providers looking to enhance their service quality. This decoder's sophisticated error correction capabilities make it suitable for advanced telecom applications, reducing error rates and enhancing signal integrity across different channels and frequencies. It is instrumental in ensuring strong connectivity and robust performance essential in today's complex mobile network environments.
The NB-IoT Software Stack from Lekha Wireless targets the burgeoning demand for low power, wide-area connectivity as outlined in 3GPP Release 13. By providing robust solutions for both eNodeB and user equipment, this stack ensures that silicon designers and OEMs have the tools necessary to achieve swift market entry. Its interoperability standards compliance enhances reliability and performance across various end applications. Leveraging Software Defined Radio platforms, the stack facilitates flexible design and customization, ideal for applications ranging from industrial to consumer IoT products. By offering extensive testing and certification processes, the stack ensures alignment with global deployment standards, fostering confidence in deployment scenarios. The stack serves as a strategic component for any organization aiming to establish a strong presence in IoT technologies, with proven capabilities that reduce developmental risks and optimize time-to-market for product innovations.
The 3GPP UMTS/LTE and 3GPP2 Turbo Encoder caters to dual-standard networks, offering versatile encoding capabilities to accommodate both UMTS and LTE standards. Utilizing an 8 state framework, it enhances data processing and integrity to ensure seamless communication across different network protocols. This encoder enables smooth transitions between network types, facilitating improved data encoding and signal strength across disparate service environments. Its flexible architecture supports integration in complex telecom infrastructures, providing performance enhancements and reliability improvements for service providers. Key to supporting modern telecommunication requirements, the 3GPP UMTS/LTE and 3GPP2 Turbo Encoder expands operational capabilities, ensuring that network operators can maintain high-quality service deliverables while managing increased traffic and protocol complexities.
The 3GPP LTE Turbo Encoder is constructed to support fast and reliable data encoding for LTE infrastructure, providing an 8 state turbo encoding solution for mobile network applications. It's developed to enhance data rates and protocol efficiencies across LTE platforms, ensuring superior quality and performance. This encoder is essential for maintaining high throughput and low error rates, pivotal in today's high-demand mobile communication environments. It supports seamless deployment in varying LTE architectures, enhancing connectivity across diverse operational scenarios. With its focus on advanced data encoding, the 3GPP LTE Turbo Encoder is designed to facilitate optimized network performance, aligning with the ever-evolving demands of global LTE networks. It backs mobile operators in delivering enhanced user experiences while supporting expansive coverage and reliability.
Bit Chains are crucial IP components for handling variable bitframe structures in communications protocols like DVB-T2 and LTE. They are equipped to handle different modulation techniques and bandwidth requirements, offering flexibility in transmission characteristics. By accommodating short and long frames and diverse modulation schemes, Bit Chains serve to enhance the flexibility and efficiency of digital communication systems.
Wasiela's Diversity MIMO Decoder line includes various configurations to optimize multiple input, multiple output (MIMO) processing. Offering features like the Fixed Depth K-Best Decoder, they support multiple synchronized data streams and different QAM types. These decoders enhance MIMO processing by achieving near Maximum Likelihood BER performance in different use-case scenarios.
The Mobile WiMAX IP Core by MIMOWAVES targets high-speed data communication for broadband wireless networks. It aligns with the IEEE 802.16e-2005 standard, providing robust OFDMA-based modulation and adaptive techniques such as BPSK, QPSK, 16-QAM, and 64-QAM. Suitable for FPGA platforms like Xilinx and Altera, this IP core is ideal for building scalable and efficient wireless communication systems, capable of operating in varied bandwidths from 3.5MHz to 20MHz.
The MIMO Wireless Communications technology leverages multiple input and output antennas to enhance data throughput and link range across wireless networks. This technology inherently increases spectral efficiency and link reliability without additional bandwidth or transmit power requirements. It is critical in modern communication standards like WiFi, LTE, and WiMAX, utilizing spatial multiplexing techniques to combat multi-path interference effectively when combined with OFDM modulation.