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.
AccelerComm's LDPC solution stands out for its innovative design that marries block-parallel and row-parallel architectures to deliver peak performance and efficiency. Primarily designed for 5G NR use cases, this product supports both data and control channels, proving its versatility across different communication requirements. With a focus on maximizing throughput and minimizing latency, the LDPC decoder is optimized for various hardware formats, including ASIC, FPGA, and software implementations. It supports a wide range of configurations, allowing it to adapt to specific performance requirements across applications. This LDPC solution has been rigorously validated against IEEE standards and offers enhanced error correction capabilities within a compact design. By reducing resource demands while improving overall communication reliability, it exemplifies AccelerComm's commitment to leading-edge technological solutions.
AccelerComm's High PHY Accelerators provide a suite of IP cores designed to boost signal processing capabilities for 5G New Radio applications. Integrating patented high-performance algorithms, this library of accelerators ensures peak throughput and efficiency, facilitating robust signal processing across ASIC, FPGA, and SoC platforms. These accelerators are characterized by their ability to significantly reduce latency and improve spectral efficiency, making them indispensable in high-demand environments. By supporting a wide array of features, including high-throughput modulation/demodulation and sophisticated error correction techniques, the accelerators empower systems to handle intricate data transmission with precision. Moreover, these accelerators seamlessly integrate with existing hardware platforms, offering a versatile solution for enhancing signal processing in diverse network scenarios. Their robust design and functionality reflect AccelerComm's commitment to driving innovation in communication technologies.
Polar encoding and decoding for 5G NR leverages AccelerComm's expertise in creating sophisticated IP that reduces resource and memory demands while delivering superior BLER performance. This solution, selected for 5G NR control channels, utilizes PC- and CRC-aided SCL polar decoding techniques to achieve high error correction accuracy. The polar IP is fully compliant with 3GPP NR standards, encompassing the entire encoding and decoding chain required for seamless integration. It offers high levels of parallel processing and scalability, making it suitable for diverse applications, from simple to complex data transmission systems. With its configurable design, the Polar IP allows adjustments in decoder list size to best fit specific BLER and PPA requirements. This flexibility, combined with its efficient integration capabilities, underscores its role as a critical enabler of efficient, high-performance wireless communication solutions.
The ASPER sensor operates at a 79GHz frequency, making it a sophisticated module for automotive applications like parking assistance. This short-range radar sensor boasts a coverage of 180 degrees with a superior detection range that extends beyond other conventional technology, such as ultrasonic systems. Its application in vehicle systems allows for enhanced features, including rear and front collision warning, blind spot detection, and more. ASPER is designed to detect low-lying objects and maintain accurate function in adverse weather conditions like fog or rain, making it a versatile component for comprehensive vehicle safety and awareness systems.
The eSi-Comms suite is a versatile toolset designed for enabling sophisticated communication functionalities in integrated circuits. Known for its high degree of parameterization, this communication IP adapts to various industry standards, effectively facilitating connectivity across a range of applications. Built to support modern wireless and wireline standards like Wi-Fi, Li-Fi, LTE, and DVB, eSi-Comms demonstrates a balance between adaptability and high performance, suiting dynamic communication environments. It facilitates robust network communications, ensuring seamless data exchange and reliable connectivity in demanding scenarios. EnSilica's focus on optimized resource usage allows eSi-Comms to deliver top-tier communication capabilities with minimized power consumption, a crucial feature in portable and battery-operated devices. Furthermore, its integration ability ensures that it aligns with diverse system architectures, enhancing interoperability across different technology ecosystems.
Functioning as a comprehensive cross-correlator, the XCM_64X64 facilitates efficient and precise signal processing required in synthetic radar receivers and advanced spectrometers. Designed on IBM's 45nm SOI CMOS technology, it supports ultra-low power operation at about 1.5W for the entire array, with a sampling performance of 1GSps across a bandwidth of 10MHz to 500MHz. The ASIC is engineered to manage high-throughput data channels, a vital component for high-energy physics and space observation instruments.
The XCM_64X64_A is a powerful array designed for cross-correlation operations, integrating 128 ADCs each capable of 1GSps. Targeted at high-precision synthetic radar and radiometer systems, this ASIC delivers ultra-low power consumption around 0.5W, ensuring efficient performance over a wide bandwidth range from 10MHz to 500MHz. Built on IBM's 45nm SOI CMOS technology, it forms a critical component in systems requiring rapid data sampling and intricate signal processing, all executed with high accuracy, making it ideal for airborne and space-based applications.
The 802.11 LDPC core by Wasiela is engineered for high throughput applications in wireless communication systems. It excels in providing frame-to-frame on-the-fly configuration, allowing developers to balance throughput and error correction performance according to specific needs. This LDPC solution is compliant with relevant throughput and performance specifications, ensuring reliable bit-error-rate and packet-error-rate outcomes that meet industry standards. The core's adaptability in decoding iterations is key to maintaining high efficiency without compromising on quality.
The RWM6050 Baseband Modem is a cutting-edge component designed for high-efficiency wireless communications, ideally suited for dense data transmission environments. This modem acts as a fundamental building block within Blu Wireless's product portfolio, enabling seamless integration into various network architectures. Focusing on addressing the needs of complex wireless systems, the RWM6050 optimizes data flow and enhances connectivity capabilities within mmWave deployments. Technical proficiency is at the core of RWM6050's design, targeting high-speed data processing and signal integrity. It supports multiple communication standards, ensuring compatibility and flexibility in diverse operational settings. The modem's architecture is crafted to manage substantial data payloads effectively, fostering reliable, high-bandwidth communication across different sectors, including telecommunications and IoT applications. The RWM6050 is engineered to simplify the setup of communication networks and improve performance in crowded signal environments. Its robust design not only accommodates the challenges posed by demanding applications but also anticipates future advancements within wireless communication technologies. The modem provides a scalable yet efficient solution that meets the industry's evolving requirements.
ParkerVision's Direct-to-Data (D2D) Technology marks a transformative development in RF communication, significantly enhancing the performance of modern smartphones and wireless devices. This innovative technology replaces the century-old super-heterodyne downconverter with a new RF downconverter that operates efficiently within CMOS architectures. D2D allows RF receivers to connect more seamlessly across global bands while processing high data rates essential for today's media and communication needs. D2D RF receivers built on ParkerVision technology minimize power usage while delivering fast data speeds, substantially contributing to the functionality and efficiency of modern smartphones. These receivers are capable of handling a wide spectrum of data rates from streaming video to large data transfers, thanks to their high-performance design capable of managing a range of signal strengths from various distances with cellular towers. This patented technology plays a crucial role in the smartphone revolution, with its incorporation leading to smarter, faster devices. These developments are enabled by a precise downconversion mechanism that transforms high-frequency RF signals into data-efficient formats. The D2D technology reduces the traditional noise and signal loss, making it a cornerstone in the advancement of mobile and IoT device communication strategies.
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 Software-Defined High PHY offered by AccelerComm is a flexible solution designed for ARM processor architectures. This IP enables high performance across various platforms, optimizing capacity and power utilization based on application demands. By embodying a software-defined approach, it affords users the versatility to either integrate it with hardware acceleration or operate it as a standalone solution, depending on specific project needs. This IP underscores AccelerComm's focus on platform independence while ensuring seamless integration across diverse systems. The Software-Defined High PHY is equipped to handle high throughput and low latency requirements, making it ideal for applications that demand dynamic performance adjustments. It allows for seamless blending of hardware and software, delivering a balance between performance and resource consumption. This makes the Software-Defined High PHY an ideal choice for companies looking to implement scalable, adaptable wireless communication solutions with efficiency at their core.
The LTE Lite offering by Wasiela is a highly versatile physical layer component tailored for Long-Term Evolution (LTE) applications. This core is designed to support user equipment compliant with CAT 0/1 specifications, ensuring compatibility across a wide spectrum of bandwidths. Its flexible design allows modulation formats up to 64QAM, with capabilities for significant timing and frequency offset corrections. Delivered as synthesizable Verilog, LTE Lite is ready for integration with standard RF tuners in communication systems looking to leverage LTE technology efficiently.
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.
LightningBlu is a sophisticated mmWave connectivity solution explicitly designed for high-speed rail environments. This advanced system offers continuous, on-the-move multi-gigabit connectivity between trackside infrastructure and trains, ensuring seamless internet access, entertainment services, and real-time updates for passengers. Operating within the 60 GHz spectrum and compliant with IEEE 802.11 ad and ay standards, LightningBlu provides robust and efficient wireless communication for the rail industry. The LightningBlu system's standout feature is its ability to maintain reliable service even at speeds of over 300 km/h, enhancing the passengers' travel experience with fast and dependable connectivity. Its architecture allows for dynamic interaction between train-mounted and trackside units, facilitating uninterrupted data transfer essential for modern transport needs. This product not only addresses current connectivity requirements but also positions itself as a future-proof solution adaptable to evolving technological landscapes. Adopting a highly functional design, LightningBlu effectively eliminates the dependency on cabled infrastructure, making it an ideal choice for upgrading existing rail systems or deploying in new corridors. By supporting innovative services and enhancing passenger contentment, LightningBlu contributes significantly to modernizing the rail sector, aligning with the increasing push towards digital transformation in mass transit.
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.
Designed for modern communication standards, the WiFi6, LTE, and 5G Front-End Module enhances connectivity in cellular and wireless networks. This sophisticated module operates across multiple frequency bands, specifically between 2.4 and 5-7 GHz, catering to a diverse range of communication protocols including WiFi6, LTE, and emerging 5G technology. Featuring integrated components such as low-noise amplifiers (LNAs), power amplifiers (PAs), and RF switches, this module significantly boosts signal reception and transmission efficiency while maintaining low power consumption. Aimed at improving data throughput and connectivity reliability, it supports seamless transitioning between different network types, which is crucial for devices like smartphones and IoT gadgets. Engineers have crafted this module to address the next-generation requirements of wireless communication by ensuring compatibility with global network specifications. Its deployment is essential in paving the way for devices that demand high-speed data, stable connections, and reduced latency, thus making it ideal for consumer electronics, telecommunication infrastructure, and advanced wireless applications.
AccelerComm offers a comprehensive physical layer solution for 5G New Radio (NR), tailored to high-performance satellite and O-RAN applications. This solution seamlessly integrates with existing systems and optimizes power, performance, and area considerations. The product's inherent flexibility allows it to adapt to a variety of platforms, including ARM processors, FPGAs, and ASICs, ensuring broad applicability across different hardware environments. The Complete 5G NR Physical Layer makes use of patented signal processing algorithms to deliver high link performance, aiding in the reduction of latency and enhancement of spectral efficiency. Designed with 3GPP compliance in mind, the solution supports the entire processing chain, ensuring that users benefit from reduced errors and maximized throughput. Furthermore, this physical layer solution is enhanced by its support for cutting-edge features like rate matching and HARQ protocols. Highly configurable, it allows for integration with various platforms, which underscores AccelerComm's commitment to providing versatile and efficient solutions tailored for modern 5G networks.
ParkerVision's Energy Sampling Technology has revolutionized the paradigm of RF signal processing with an inventive approach for frequency down-conversion. Traditionally dominated by super-heterodyne techniques, which used high L.O. power to achieve sensitivity and linearity, these were not suited for low-power CMOS applications as well as modern integrated transceivers. Energy Sampling Technology provides the highest sensitivity and dynamic range required for modern receivers while enhancing selectivity and interference rejection. By eliminating RF signal division between I and Q paths, ParkerVision's technology helps in reducing power consumption and improving demodulation accuracy. It offers a compact and cost-effective solution feasible with CMOS technologies, allowing for the development of multimode receivers compatible with advancing CMOS geometries and power levels. The benefits span various transmission standards like GSM, EDGE, CDMA, UMTS, and LTE, making it relevant for devices such as handsets and embedded modems. This technology fundamentally shifts RF signal processing by using matched-filter correlators, enhancing the overall performance capabilities of direct conversion receivers. The elimination of redundant components reduces silicon area, and improved dynamic range lessens the need for external filters. This technology paves the way for a wide array of innovative applications across contemporary wireless ecosystems, thereby facilitating rapid technological leaps in the communication field.
The PUSCH Equalizer by AccelerComm is designed to enhance spectral efficiency by effectively managing noise and interference, especially in systems utilizing multiple antennas. Built with advanced equalization algorithms, this product is tailored to be implemented as a hardware solution, thereby offering high performance beyond what a standard CPU can achieve. This equalizer is fully compliant with 3GPP NR specifications and integrates seamlessly with demodulation, LDPC, and polar decoding processes. This synergy ensures not only significant improvements in spectral efficiency but also reductions in cost per bit and system power consumption. Offering both FPGA and ASIC compatibility, the PUSCH Equalizer is engineered to minimize time to market and deliver robust performance in modern telecommunications environments. Its advanced features make it a vital component for improving overall network performance and user experience in advanced 5G NR deployments.
The PCS1100 transceiver is an advanced component in Palma Ceia SemiDesign’s portfolio designed to cater to the burgeoning demand for Wi-Fi 6 networks. It seamlessly integrates with Wi-Fi 6/6E systems, operating efficiently as the RF module within access points or stations. This transceiver supports multiple frequency bands, offering tri-band operations that cover 2.4 GHz, 5 GHz, and the newly allocated 6 GHz range. It is expertly designed for high-capacity environments like public venues and smart cities, aiming to enhance network efficiency and signal reliability. Equipped with MU-MIMO and OFDMA technologies, the PCS1100 ensures high data throughput and reduced latency, accommodating the needs of modern applications such as streaming and IoT devices. The transceiver excels in both transmitting and receiving capacities through advanced modulation schemes up to 1024 QAM, achieving peak throughput around 4.2 Gbps across four spatial streams. This enables simultaneous data communication with multiple devices, improving network capacity and speed. Furthermore, the transceiver is built with robust RF architecture that accounts for rigorous operational specifications, providing long-range and efficient connectivity. It incorporates a variety of design optimizations, including digital calibration and compensation features, which ensure consistent performance across varying conditions. This component serves as the RF backbone, particularly in systems requiring high reliability and swift data handling.
The NB-IoT (LTE Cat NB1) Transceiver from Palma Ceia SemiDesign stands as a pivotal component for low-power, wide-area (LPWA) network solutions, explicitly tailored for the growing IoT domain. Designed to align with the 3GPP Release 13 specifications, this transceiver facilitates efficient cellular communication within IoT networks, providing essential connectivity for devices in energy-sensitive applications. This transceiver is distinguished by its compliance with broader LTE standards, offering extensive programmability through simple SPI interfaces. It is built with integral calibration features to manage DC offset and IQ mismatches, ensuring high fidelity in data transmission. These design attributes make it versatile across a range of cellular network bands, accommodating various operational environments. Optimized for power efficiency, the NB-IoT transceiver's compact frame supports numerous applications including smart metering, wearable technology, and surveillance systems. It offers seamless integration with existing networks, significantly improving data throughput and extending operational range while maintaining minimal power consumption, all pivotal in sustaining IoT growth across global infrastructures.
The RISC-V CPU IP NI Class is tailored for AI, ADAS communications, and advanced video processing applications. Developed for performance-intensive environments, this processor is equipped to handle complex computational tasks required for sophisticated AI operations and real-time data processing in advanced driver-assistance systems (ADAS). With its focus on AI and video applications, the NI Class supports a wide range of functionalities that promote efficient processing and integration into systems that demand high computational capabilities. The flexibility of the RISC-V architecture allows developers to implement custom solutions that meet specific application criteria, ensuring efficient deployment across varied markets. The RISC-V CPU IP NI Class is supported by a dynamic ecosystem providing extensive development tools and libraries to maximize its potential in applications. This ecosystem facilitates rapid prototyping and deployment, allowing designers to stay ahead in evolving industries such as multimedia processing and automotive technology, where performance and adaptability are keys to success.
TurboConcept's 4G multi-mode CTC decoder is engineered for modern broadband wireless communications, ensuring efficient and error-free data exchange. Designed to handle the complexity of decoding convolutional turbo codes, this core offers flexibility and high performance across various 4G applications. It seamlessly integrates with existing systems to enhance data transmission quality, effectively managing multiple modes to cater to diverse network requirements. By providing robust error correction, this decoder enhances network reliability and supports high-speed data operations, making it essential for competitive 4G LTE platforms.
Crest Factor Reduction (CFR) is a critical technique in wireless communications, used to lower the peak-to-average power ratio (PAPR) of multi-carrier and multi-user signals. High PAPR can lead to inefficiencies within RF power amplifiers, driving the need for effective solutions such as CFR to ensure optimal performance. By minimizing PAPR, Faststream's CFR IP simplifies power supply design and cuts down the peak power requirements in amplifiers, enhancing their power efficiency. CFR is often deployed alongside Digital Pre-Distortion (DPD) within transmission chains, functioning as part of the broader strategy to linearize power amplifiers. This IP enables system configurability for various transmission architectures, offering compatibility with single-channel, multi-channel, and mixed-mode systems. Faststream has developed their CFR IP using advanced modeling techniques in Structural Verilog and MATLAB, facilitating robust design exploration and verification phases. Key features of the CFR IP include its adaptability to digital pre-distortion (DPD) and envelope tracking technologies, with versatile configurations that support multiple antennas and clock-to-sample ratios. By providing significant PAPR reduction, Faststream's CFR IP enhances the overall reliability and efficiency of wireless network systems, making it a valuable asset in modern telecommunications setups.
The RFicient chip, designed for Internet of Things (IoT) applications, is renowned for its energy efficiency and wireless communication capabilities. This chip has been exactly engineered to drastically reduce power consumption, making it a pivotal component in sustainable IoT solutions. It plays a critical role in IoT devices, seeking to maximize data transmission while minimizing energy use, catering to an ever-expanding network of interconnected devices. By utilizing the RFicient chip, users can leverage advancements in technology while ensuring beneficial environmental impacts. One notable feature of the RFicient chip is its capability to handle a massive volume of messages daily, making it integral to Industrial IoT applications that require robust and reliable communication streams. Its adaptability allows deployment across various IoT domains, thus supporting varied applications, from smart agriculture to industrial automation. The innovation behind the RFicient chip lies in its capacity to perform effectively within sub-GHz spectrum ranges, ensuring long-range connectivity and resilience against interference. This makes it an attractive solution for environments that require a stable, far-reaching, and energy-frugal connectivity option. Its adoption is set to enhance efficiency and sustainability across industries that depend on IoT technologies.
Vyapi LTE eNodeB by Lekha Wireless is a 4G solution that underscores Indigenous technology developed entirely in India. Designed to align with national initiatives like Aathmanirbhar Bharath, this product delivers robust mobile broadband coverage and is optimized for extensive area outreach. Vyapi supports both TDD and FDD frequency bands, with RF power levels reaching up to 40W, thereby accommodating small and macro cell deployment needs. The eNodeB has been rigorously tested with multiple EPC vendors, making it ideal for both greenfield and brownfield 4G network deployments. Its flexibility in supporting private and enterprise network solutions is integral to reducing total cost of ownership for service providers.
Faststream's Digital Down Conversion (DDC) technology plays a crucial role in the reduction of high-frequency RF signals to baseband, optimizing processes for improved transmission and reception performance in high-speed communication systems. At its core, the DDC IP involves an intricate assembly of carrier selectors, frequency down converters, filters, and decimators working in unison to achieve precise signal manipulation. This DDC solution caters specifically to the demanding environments of 5G and LTE communication systems, enhancing overall network throughput by efficiently managing the conversion of wideband signals. It integrates seamlessly into the existing signal chain, supporting robust modulation schemes and offering a stable platform for further signal processing tasks crucial to telecommunications infrastructure. Employing state-of-the-art algorithms and architectures, the DDC IP enables highly accurate manipulation of signal parameters, ensuring rapid adaptation to dynamic network requirements. The capability to down-sample and filter at critical stages in the conversion process emphasizes its value in competitive telecommunications markets, providing service providers with a vital tool for optimizing signal integrity and efficiency.
Lekha Wireless's 4G/LTE Software Stack adheres to the 3GPP Release 10 specifications, enabling OEMs to develop robust 4G radio network products. These stacks are designed to be platform-independent, with some optimized for the Texas Instruments’ Keystone II architecture. The company plans to upgrade these stacks to support Release 14, fortifying network security and capabilities. The modular stack format allows developers to construct and refine LTE networks efficiently, whether utilizing LTE or non-LTE bands. Included in this package is the LTE WaveGuru Toolkit, which serves as a complete suite for generating and analyzing LTE signals, enhancing testing and debugging capabilities for developers.
The Digital Up Conversion (DUC) technology is integral to modern signal processing within wireless communication systems. It converts baseband signals to intermediate frequency, a step necessary for efficient radio transmission. Faststream's DUC IP employs a sophisticated interpolating filter chain, a numerically controlled oscillator, and a mixer, all designed to ensure high precision in frequency conversion processes. DUC is particularly beneficial in improving signal quality and optimizing bandwidth utilization in LTE and advanced communication systems. By adapting a series of filters, including a low-pass interpolator and half-band interpolator, the DUC IP ensures accurate and efficient up-sampling of signals, catering to varying criteria like cell search and master information block recovery in LTE receivers. The DUC solution is engineered for high clock rates, with a design optimized for operation at frequencies up to 122.88 MHz. Faststream's approach facilitates significant resource efficiency, making it a well-suited solution for handling the stringent demands of high-performance telecommunications infrastructure. Through expert integration of up-conversion components, this IP stands as a cornerstone for robust network deployments.
The SBR7020 offers a comprehensive solution for applications leveraging both LTE and 3G technologies, specifically tailored for ultra-low power performance. This transceiver is adept at managing dynamic data requirements typical in IoT and M2M communications, ensuring optimal energy efficiency. Given its simultaneous support for LTE and 3G, the SBR7020 is particularly beneficial in regions with mixed-network infrastructures, helping maintain seamless connectivity across different systems. Its design facilitates minimized power use, enhancing the longevity of IoT devices. Flexibility and reliability define the SBR7020, as it consistently delivers robust signals under diverse conditions. Its development underscores the need for encompassing modern communication technologies with cost-effective and energy-efficient designs, bolstering its place in the future of wireless communication standards.
Digital Pre-Distortion (DPD) technology enhances the efficiency and linearity of RF power amplifiers by mitigating out-of-band emissions, often caused by non-linearities in the amplifier's operational range. This advancement becomes critical in contemporary wireless communication systems where spectral regrowth must be minimized to maintain signal integrity. The DPD solution achieves this by pre-adjusting the signal before amplification, allowing for more effective power usage and less distortion. The Faststream DPD IP is meticulously engineered to handle the complexities of modern multi-band and wideband power amplifiers, including those required for 5G communications. It addresses the intricate requirements of power amplification in the presence of wideband signals such as WCDMA and LTE, among others, by adapting the signal path to enhance linearity. Moreover, the DPD process incorporates sophisticated algorithms, like the Memory Polynomial Algorithm, to correct the non-linear behavior of power amplifiers at high frequencies, thereby boosting overall network performance. Optimized for Xilinx FPGA implementations, the Digital Pre-Distortion IP offers a streamlined approach for integrating within existing systems, achieving compact FPGA footprints with reduced costs. It significantly boosts the performance of Gallium Nitride (GaN) amplifiers, ensuring compliance with strict spectrum emission mask and error vector magnitude requirements across power levels. This IP is an indispensable element for telecommunications providers aiming for a blend of efficiency and quality in their power amplification solutions.
The SBR7035 transceiver incorporates a power amplifier, designed specifically for LTE applications, focusing on NB-IoT and Cat-M standards. This integration of the power amplifier is crucial for enhancing signal strength without increasing the power consumption, thereby ensuring consistent communication quality across various IoT deployments. Efficiency is the hallmark of the SBR7035, allowing for significant reductions in both power use and operational costs compared to traditional LTE solutions. It's tailored to meet the demands of IoT networks where high efficiency and minimal interference are critical. The compact design of the SBR7035 makes it highly adaptable for use in low-space environments. With its advanced features, it offers a seamless balance between performance and economy, making it an ideal choice for next-generation IoT devices that require reliable connectivity and extended battery life.
The SBR7030 is designed to support dual modes in LTE applications, catering specifically to Cat-M and NB-IoT standards. This transceiver stands out due to its low power consumption, making it ideal for IoT applications where efficiency is crucial. Its capability to operate across various LTE modes allows network versatility and supports seamless communication between devices in a cost-effective manner. This transceiver is optimized to offer robust performance in IoT networks, facilitating reliable and rapid data transmission while maintaining low energy usage. The small silicon footprint not only contributes to energy efficiency but also helps reduce manufacturing costs, making it a preferred choice for cutting-edge IoT deployments. Moreover, the SBR7030 supports a variety of applications where battery life and operational efficiency are essential, thus extending the longevity and sustainability of IoT devices. This technological innovation reflects SaberTek's commitment to progressing the standards and capabilities within wireless communications.
The Wi-Fi HaLow Module crafted by MegaChips is engineered for next-generation IoT communications, leveraging the IEEE 802.11ah standard. This module excels in providing long-distance, low-power wireless connectivity, making it ideal for applications where energy efficiency and extended range are essential. Catering to smart homes, industrial IoT, and agriculture, it supports large-scale device networking with minimal power usage. One of the key attributes of this module is its ability to operate effectively in environments requiring extensive coverage and minimal interference. It's designed to penetrate obstacles better than traditional Wi-Fi, thus increasing its applicability in remote or densely structured areas where maintaining a connection can be challenging. Further enhancing its utility, the Wi-Fi HaLow Module complements MegaChips' focus on delivering solutions that blend versatility with performance. It makes a noteworthy contribution to advancing IoT technology by facilitating dependable connectivity for a wide range of devices while adhering to stringent energy-conservation standards.
Adaptive Digital Predistortion (DPD) is designed to enhance the efficiency and linearity of RF power amplifiers, particularly in multi-carrier and wideband applications such as those demanded by 5G networks. By mitigating spectral regrowth—a byproduct of non-linearities within power amplifiers—this IP enables superior signal fidelity and reduced emissions that comply with strict regulatory requirements. This IP employs advanced computational models and real-time adaptation capabilities to pre-distort signals before amplification, ensuring that the eventual amplified signal closely mirrors the original intended waveform. The adaptive nature of this DPD solution allows it to automatically adjust to varying signal conditions and amplifier characteristics, making it an indispensable asset for modern communication infrastructures aiming to minimize distortion without compromising power efficiency. Optimized for integration within FPGA environments, the Adaptive DPD IP offers scalable deployment options and significant versatility across different network platforms. It ensures performance stability across a range of operational conditions and assists in extending the practical bandwidth and efficiency of power amplifier systems in modern telecom settings.
This RF transceiver is designed for dual-band communication over the 2.4GHz and 5GHz spectrums, targeting high-performance applications. It supports Wi-Fi 6 (802.11ax) and BLEv5.4, offering robust performance for demanding environments while maintaining energy efficiency. The concurrent operation in dual bands is optimized for low latency and high throughput tasks. It features a finely-tuned fractional-N synthesizer, integrated Rx/Tx switches, and an onboard crystal oscillator. Engineered to deliver fast data rates and minimize network congestion, this transceiver integrates advanced RF components for seamless operation. It handles diverse modulation schemes and is tailored to facilitate extensive wireless communication for multiple devices across enterprise and consumer networks. Its architectural design ensures longevity in service and compatibility with various network protocols. With features such as full concurrent dual-band operation and bandwidth support up to 80 MHz in the high band, it becomes a proficient choice for applications like VR, AR, and smart city infrastructures. Calibration routines and a straightforward interface make it adaptable across digital systems, enhancing connectivity across platforms and devices.
The WiMax 802.16e AES Core from IP Cores, Inc. supports high-speed encryption and decryption operations for the IEEE 802.16e standard using AES in CTR and CBC modes. Tailored for WiMax security, this core is ideal for integration into systems operating at IEEE 802.16 data speeds, ensuring data integrity and confidentiality with its robust encryption schemes. Fully synchronous, this design is lightweight yet powerful, requiring minimal external components, and includes comprehensive test benches and documentation. Tailored for varying data lengths, it supports header parsing required for flow-through data processing in secure communication systems.
Join the world's most advanced semiconductor IP marketplace!
It's free, and you'll get all the tools you need to discover IP, meet vendors and manage your IP workflow!
Join the world's most advanced AI-powered semiconductor IP marketplace!
It's free, and you'll get all the tools you need to advertise and discover semiconductor IP, keep up-to-date with the latest semiconductor news and more!
Plus we'll send you our free weekly report on the semiconductor industry and the latest IP launches!