All IPs > Wireless Communication > GPS
The GPS (Global Positioning System) category under Wireless Communication in Silicon Hub's semiconductor IP catalog represents a cornerstone in modern navigation and location solutions. GPS technology has revolutionized the way devices interact with the world, offering precise positioning and time synchronization. Semiconductor IPs designed for GPS applications empower an array of electronic devices, from consumer electronics to automotive systems, with the ability to pinpoint location with impressive accuracy.
In this category, you'll find semiconductor IPs that provide the essential building blocks for incorporating GPS capabilities into various products. These semiconductor IPs typically include components for signal processing, RF front-end design, and integration support for multi-frequency GPS systems. This is crucial for applications requiring high precision and reliability, such as navigation systems, geolocation services, and time-sensitive financial transactions. The IPs enable seamless connectivity and integration, catering to the diverse demands of modern electronics.
GPS semiconductor IPs play a critical role in not just consumer devices like smartphones and wearables, but also in more complex systems such as autonomous vehicles and industrial IoT devices. These IP blocks ensure that products can efficiently and accurately track location in real-time, crucial for enhancing user experience and operational efficiency. By leveraging these semiconductor IPs, developers can focus on innovation within their unique applications, leaving the complexities of GPS integration to the experts.
As the demand for precise location services continues to escalate, the GPS category of semiconductor IPs in Silicon Hub supports the evolutionary paths of newer technologies such as GPS with augmentation systems and integrated GNSS solutions. These advancements open doors to improved accuracy and functionality, paving the way for new applications and enhanced device capabilities. With such a dynamic portfolio, designers can tailor GPS functionalities to meet the specific needs of their end applications confidently and effectively.
The NaviSoC by ChipCraft is a sophisticated GNSS receiver system integrated with an application processor on a single piece of silicon. Known for its compact design, the NaviSoC provides exceptional performance in terms of precision, reliability, and security, complemented with low power consumption. This well-rounded GNSS solution is customizable to meet diverse application needs, making it suitable for IoT, Lane-level Navigation, UAV, and more. Designed to handle a wide range of GNSS applications, the NaviSoC is well-suited for scenarios that demand high accuracy and efficiency. Its architecture supports applications such as asset tracking, smart agriculture, and time synchronization while maintaining stringent security protocols. The flexibility in its design allows for adaptation and scalability depending on specific user requirements. The NaviSoC continuously aims to advance GNSS technology by delivering a holistic integration of processing capabilities. It stands as a testament to ChipCraft's innovative strides in creating dynamic, high-performance semiconductor solutions that excel in global positioning and navigation. The module's efficiency and adaptability offer a robust foundation for future GNSS system developments.
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 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 Ubi.cloud solution by Ubiscale is a groundbreaking software innovation designed for IoT tracking devices. This solution significantly reduces the power consumption and costs associated with typical GPS and Wi-Fi processing in IoT trackers by shifting these processes to the cloud. As a result, it supports the seamless implementation of geolocation services across diverse environments. The Ubi.cloud platform is versatile, offering high precision and low power options that make it ideal for tracking applications in both indoor and outdoor settings. This solution's architecture enables significant savings by reducing the time and power needed for GPS cold-starts and native Wi-Fi sniffing. Another advantage of the Ubi.cloud solution is its compatibility with a range of low-power wide-area networks (LPWANs) like Sigfox, LoRa, and NB-IoT. This allows for a wide application across different IoT ecosystems. It efficiently handles real-time geolocation data with minimal energy use, which is essential for devices that require prolonged battery life, such as asset trackers and wearables. Moreover, Ubi.cloud offers flexible business models, including pay-as-you-go and lifetime licenses, ensuring that it meets varied market needs. Its API services work seamlessly with the embedded technologies of UbiGNSS and UbiWIFI, providing robust solutions that cater to specific tracking requirements with programmable accuracy and compact data payloads.
The hellaPHY Positioning Solution is renowned for its exceptional capabilities in cellular positioning, particularly within massive IoT environments. It leverages the strength of 5G networks to provide scalable, low-cost, positioning services with high precision. PHY Wireless has engineered it to require significantly less data than other solutions, thanks to its unique algorithmic approaches. This reduces network interactions and enhances spectral efficiency, making it an enticing option for operators and developers alike. One of the key components of this solution is its ability to function indoors and outdoors with near GNSS accuracy. By employing edge computing, the position calculations are done locally on devices, protecting user privacy and maintaining tight security on location data. The software’s minimal footprint allows for integration into existing infrastructure, offering backward compatibility and ensuring future readiness. hellaPHY stands out in the realm of positioning technology by achieving unparalleled accuracy, thanks to its efficient data utilization. It supports efficient location tracking in challenging environments, such as urban areas, where traditional GPS might falter. Furthermore, the technology offers the flexibility of over-the-air updates, keeping network utility optimal and guardband costs low through advanced spectral efficiency.
The GNSS VHDL Library is a high-performance, sophisticated library developed to streamline the integration of satellite navigation capabilities within digital hardware systems. Tailored for flexibility and adaptability, this library facilitates various GNSS systems, including GPS, GLONASS, and Galileo. Its design enables effective signal processing and navigation solutions through dedicated VHDL modules. A notable aspect of the GNSS VHDL Library is its compatibility with multiple hardware platforms and architectures, which include SPARC V8 and RISC-V systems. It encompasses modules like fast search engines, Viterbi decoders, and self-test units, allowing developers to customize and refine their application according to specific needs. The library supports a range of configurations: it can be tailored to manage different numbers of channels, frequencies, and system modules as specified by user requirements. By implementing a single, comprehensive configuration file, it minimizes the need for repetitive customization across different systems, which can significantly decrease development times and costs.
The Satellite Navigation SoC Integration by GNSS Sensor Limited is engineered to optimize the incorporation of satellite navigation capabilities directly into system-on-chip designs. This product is notable for its compatibility with various satellite systems including GPS, GLONASS, and Galileo, featuring independent fast search engines for each navigation protocol. This integration offers substantial flexibility, allowing the navigation system to operate efficiently across a broad spectrum of platforms. The SoC integration includes a distinctive set of features designed to cater to the requirements of modern digital hardware environments. It supports a wide array of architectures, notably those based on RISC-V and SPARC V8, as well as FPGA environments, which are testament to its adaptability in different technological frameworks. This flexibility is further bolstered by its use of universal bus interfaces such as AMBA and SPI, facilitating integration without necessitating extensive design modifications. Moreover, this SoC solution supports a comprehensive range of frequency bands and channels, ensuring robust satellite tracking and data acquisition capabilities. Its architecture allows for maximum independence from CPU platforms, providing a single configuration file to manage various system needs, thus reducing the complexity and development costs associated with integrating navigation functions into bespoke silicon solutions.
Wireless Sensor Modules by Granite SemiCom are designed to provide high flexibility and extended range for IoT applications. Utilizing LoRa transceivers, these modules operate over long distances, making them suitable for environments where connectivity over vast areas is required. Their design is optimized for battery efficiency, ensuring long operational lifetimes with low power consumption. These modules also support over-the-air updates, enhancing their functionality and adaptability in dynamic settings. With built-in encryption, they offer secure wireless communication, crucial for safeguarding data integrity across networks.
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.
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 L1 Band GNSS Transceiver Core is specially adapted for precision location and navigation applications. It supports a wide array of GNSS signals, including the GPS and GLONASS systems. This core is designed to deliver exceptional performance in real-time positioning and tracking, making it ideal for use in various commercial and military applications that require dependable GNSS solutions. It is optimized to provide robust performance in challenging environments such as urban canyons, enhancing its utility in dense metropolitan areas. Furthermore, the transceiver core integrates sophisticated signal processing capabilities, ensuring it can handle multiple signal reception and processing with high efficiency. Users benefit from its versatility and capability to quickly adapt to different GNSS bands, including L1, L2, and L5, enhancing the system's overall accuracy and reliability in delivering precise time and location data. The core's design leverages advanced semiconductor technologies to minimize power consumption and support prolonged operation in mobile devices or field applications. The compact nature of the design allows for seamless integration into existing systems, providing a significant competitive advantage in delivering state-of-the-art GNSS functionalities.
The L5-Direct GNSS Receiver from oneNav leverages the advanced capabilities of the L5-band, providing a robust and highly accurate satellite navigation solution. Unlike the older L1 band, the L5 signal is designed to improve resilience against interference and spoofing, ensuring more reliable location services. This technology is particularly beneficial in urban environments, where signal blockage and reflections can significantly impair performance.\n\nOneNav's L5-Direct solution stands out by offering direct acquisition of L5 signals, allowing users to tap into the benefits of the L5-band without reliance on the older L1 signals. This is crucial as L1 signals are prone to several issues, including multipath distortion and lower transmission power. With the ability to directly acquire L5 signals, this receiver guarantees faster location acquisition and enhanced coverage across various scenarios.\n\nThe receiver integrates seamlessly into devices like smartphones, smartwatches, IoT gadgets, and automotive systems, where space and power efficiency are critical. It incorporates machine learning techniques to process GNSS data, improving accuracy and reducing errors from signal reflections in dense urban areas. The L5-Direct technology showcases oneNav's commitment to providing state-of-the-art GNSS solutions that meet the needs of modern technological environments.
IMST GmbH's Wireless Solutions provide custom radio modules especially suited for easy integration into wireless communication networks. These modules cater to license-free bands, along with comprehensive development services including embedded software, high-frequency circuit design, antenna design, and certification, affording customers a complete continuum from concept to finished product. The development of these radio modules integrates smart IoT device capabilities, offering a versatile base for building sophisticated wireless communication products. These solutions are tailored to meet specific client needs, utilising modular starter kits with user-friendly interfaces that facilitate the evaluation and testing of various technologies. Additionally, IMST extends its service to include feasibility studies, prototyping, and mass production certification, supported by extensive testing services for high-frequency materials, antennas, and entire systems. The partnership with ST ensures the accessibility of these advanced wireless solutions to a broad range of IoT customers, emphasizing their role in simplifying wireless connectivity.
Accord's MGNSS IP is a highly sophisticated GNSS baseband IP Core designed to enhance high-accuracy, high-sensitivity GNSS receivers. Compliant with AMBA AHB standards, this versatile IP caters to automotive, smartphone, precision, and IoT applications. The IP features a flexible architecture that enables processing of various GNSS signals across all major constellations either simultaneously or in sequence, responding to the specific requirements of an application.
The AST 500 is a sophisticated Multi GNSS baseband Receiver SOC that handles a variety of satellite signals including GPS, GLONASS, NavIC, BeiDou, GALILEO, QZSS, and GAGAN, across different frequency bands. Its dual-band capability eliminates ionosphere errors, ensuring precise navigation in urban settings. With secure boot and encryption features, it offers a comprehensive security solution. Integrated interface options like CAN, UART, SPI, I2C, and GPIOs allow seamless platform integration.
Ubiscale's Cobalt GNSS Receiver is an ultra low-power IP designed to scale the potential of IoT system-on-chip solutions. This GNSS receiver IP is engineered for short power consumption and optimized embedded processing, complementing its cloud-assisted capabilities. It offers enhanced market reach, allowing easy integration into narrowband IoT (NB-IoT) SoC environments and ensuring cost-efficient GNSS functionalities. The Cobalt GNSS Receiver supports multiple GNSS constellations, including Galileo, GPS, and Beidou, facilitating both standalone and cloud-assisted operations. By efficiently managing MIPS and memory for processing, it helps reduce the overall footprint, making it especially suitable for applications where space and power are at a premium. The receiver utilizes state-of-the-art sensitivity optimization techniques to deliver reliable performance in a compact size. Developed in collaboration with CEVA DSP and the European Space Agency, the Cobalt offers robust processing capabilities for precise positioning. This collaboration ensures modulators with high accuracy, improved resistance to multipath interference, and compatibility with existing SoC infrastructures. Such features make it an excellent choice for mass-market tracking scenarios that are sensitive to size and cost, including logistics, agriculture, and animal tracking applications.
The GPS/Galileo/GLONASS multisystem single-band receiver is a sophisticated solution designed to operate with multiple navigation systems. This integrated receiver combines tri-system support, ensuring reliable performance across GPS, Galileo, and GLONASS networks. The architecture is optimized for single-band operation, facilitating seamless navigation data reception with enhanced precision and minimal signal interference. Built using a robust 180nm SMIC CMOS process, this receiver caters to applications demanding high accuracy and robustness in varying environments. The design emphasizes low power consumption, making it ideal for portable and remote devices that require efficient energy management without compromising on performance. Incorporating advanced signal processing technology, the receiver is suited for applications in personal navigation devices, smart transportation systems, and any application where geographic positioning is critical. Its flexible configuration options enable developers to tailor the receiver's functionality to specific project requirements, rendering it a versatile choice among navigation solutions providers.
This receiver integrates support for multiple global navigation satellite systems, including GPS, Galileo, BeiDou, and GLONASS, into a robust single-band receiver design. Leveraging cutting-edge bi-CMOS technology from TSMC's 180nm process, this IP block is engineered for efficiency and adaptability across various geolocation applications. The design focus of this receiver is on delivering high-precision location data with low latency and high reliability. Its architecture is tailored to handle an extensive array of signals, thereby enhancing its functionality in environments with varying satellite availability. This IP is particularly suited for applications that demand precise geolocation, such as advanced mapping, geofencing, and asset tracking in complex urban or natural landscapes. By integrating this receiver, engineers can achieve superior system accuracy and operational flexibility.
This dual-channel receiver RFIC is designed to accommodate multiple GNSS systems, including GLONASS, GPS, Galileo, and BeiDou. It supports a single-band operation that facilitates enhanced signal reception and processing capabilities across two channels simultaneously. This ensures robust functionality even in challenging signal environments. Developed with a focus on precision and efficiency, this product employs a 180nm SMIC CMOS technology, targeted to optimize power usage and offer extensive operational flexibility in a compact form. The design priorities include minimizing noise and maximizing signal throughput, which are critical in applications necessitating accurate synchronization and high-quality signal reception. Typical applications encompass an array of sectors, such as autonomous navigation, fleet management, and time synchronization systems where dual-channel processing enhances data reliability. Its resilience to interference and its ability to process concurrent signals make it a preferable choice for high-demand positioning and tracking solutions.