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.
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.
ArrayNav is an innovative GNSS solution that employs multiple antennas, enhancing sensitivity and accuracy to combat common issues like multipath interference and signal jamming. This technology is designed to increase the effectiveness of global positioning systems by using adaptive antenna systems, a concept borrowed from advanced wireless communications. ArrayNav provides up to 18dB gain in signal strength for fading channels and ensures robust performance even in complex environments like urban canyons. By identifying and nulling unwanted signals, it maintains the integrity of GNSS operations against spoofing and interference. This technology is vital for applications needing high precision under challenging signal conditions. With its sophisticated antenna diversity, ArrayNav is crafted to deliver sub-meter precision and swift signal acquisition. This makes it a valuable component for navigation in densely constructed urban landscapes or covered environments where satellite visibility might be obscured. ArrayNav's capability to handle multipath and interference issues effectively makes it a preferred choice for high-reliability navigation systems, contributing to both enhanced security and accuracy.
The EW6181 is an advanced multi-GNSS silicon designed for high sensitivity and low power consumption, a stand-out product in GPS and GNSS technology. It supports multiple global positioning systems like GPS L1, Glonass, BeiDou, Galileo, SBAS, WASS, and A-GNSS. This silicon includes an integrated RF frontend, a digital baseband for signal processing, and ARM MCU to efficiently run the necessary firmware. This chip is tuned for low energy use, incorporating a DC-DC converter along with high voltage and low voltage LDOs, which makes it ideal for battery-powered devices. Its size and energy efficiency make it a competitive module component that reduces the overall Bill of Materials (BoM) for manufacturers. The EW6181's architecture is optimized for cloud readiness, offering enhanced capabilities for applications needing intensified accuracy and power savings through cloud connectivity. A unique feature of the EW6181 is its implementation in a 2-antenna Evaluation Kit, showcasing its potential to improve device connectivity and performance with antenna diversity mode, perfect for rotating devices like action cameras and wearable tech. This diversity offers key advantages in both connectivity and user experience, emphasizing the EW6181 as a flexible, high-performing component in various technological ecosystems.
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 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.
Ubiscale offers the Ubi.cloud solution which innovatively shifts energy-intensive GPS and Wi-Fi processing to the cloud. This approach significantly minimizes the physical size, energy consumption, and costs associated with tracking devices. By leveraging cloud computing, Ubi.cloud provides ubiquitous geolocation services, with GPS for global outdoor navigation and Wi-Fi for precise indoor positioning. Ubi.cloud features include cutting the consumption of receiver chipsets to one-tenth when compared to the current state-of-the-art technology. This drastic reduction allows a more efficient use of resources and enhances the lifecycle of IoT devices. The API supports diverse requirements for asset tracking, utilizing embedded technologies such as UbiGNSS and UbiWIFI which offer significant time and power savings compared to traditional methods. With typical accuracy ranging between 10 to 20 meters, the system integrates seamlessly with leading GNSS/Wi-Fi hardware, making it a versatile solution. It is compatible with all leading Low Power Wide Area technologies including Sigfox, LoRa, NB-IoT, and LTE-M, and offers a flexible business model accommodating pay-as-you-go or lifetime licensing approaches. By operating with only a compact 10-byte payload per position and minimal power requirements, Ubi.cloud is positioned as a cost-effective and efficient solution for modern geolocation needs. Additionally, professional services are available for customized designs and consulting, ensuring that businesses can optimize their IoT strategies.
Moonstone, an offering from Lightelligence, is a highly versatile laser source available in both single and multi-wavelength configurations. Unlike conventional laser packages, Moonstone features a compact design and enhanced temperature management, making it a cost-effective and modular solution for diverse applications including telecommunications, LiDAR, and sensor technologies. The product leverages an automated optical packaging process that integrates off-the-shelf laser chips with the Moonstone carrier through advanced techniques like eutectic soldering and die-bonding. The ensuing laser assembly enables a free-space coupling method for single wavelength use, and a multiplexing approach for multi-wavelength scenarios, optimizing optical signal combination and transmission efficiencies. Moonstone's precision engineering and thermal regulation provide low coupling losses and high output power, suitable for demanding environments where high-speed and high-bandwidth data transmission are crucial. It serves a vital role in optical computing, offering substantial power delivery while maintaining a low phase noise footprint, thus bolstering AI computational capacities significantly.
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.
The MGNSS IP offers a comprehensive multi-frequency and multi-constellation GNSS baseband core that supports integration into automotive, smartphone, precision and IoT application systems. It is designed to manage legacy and modernized GNSS signals across various constellations, seamlessly adapting to application needs. This IP emphasizes energy efficiency and swift acquisition alongside precise tracking capabilities. Featuring 64 parallel GNSS signal tracking channels, it stands capable of fast acquisition and precise measurement outputs. It supports dual-frequency operations through two RF channels and employs advanced interference management techniques. This configuration enables the IP to operate effectively amidst both intentional and unintentional signal disturbances, providing robust navigation solutions. This core is notable for its comprehensive support across L1, L2, L5, and S band frequencies, making it adaptable for use with GPS, Galileo, GLONASS, BeiDou, QZSS, IRNSS, and SBAS systems. Focusing on power conservation, it allows for various power-down modes adjusting to application demands.
IMST's wireless solutions cater to the demand for customized radio modules, a critical component in modern communication systems. These solutions are developed to meet the specific needs of clients, offering flexibility from the initial design phase through to manufacturing. The custom radio modules provide seamless incorporation into various device architectures. With expertise in critical areas such as RF hardware, digital components, and communication software, IMST ensures that each module is tailored for its unique application, delivering both performance and efficiency. These bespoke solutions facilitate innovations in consumer electronics, telecommunication infrastructures, and more, enabling enhanced connectivity and operational effectiveness. IMST's dedication to quality and precision in their radio systems offers clients a reliable partner in navigating the complexities of modern wireless communication demands.
The L1 Band GNSS Transceiver Core developed by RF Integration is a sophisticated solution for satellite navigation systems. Particularly tailored to handle signals in the L1 band, this core is instrumental for precision in various positioning applications, being a vital component in smartphones, portable navigation devices, and more. The transceiver is designed to acquire and track GNSS signals, providing real-time location data with high accuracy and reliability. It's versatile enough to integrate with both new and existing platforms, enabling enhanced pinpoint precision in urban environments and challenging geographic regions. It supports various GNSS systems, ensuring global operability and compatibility with multiple standards such as GPS, GLONASS, and others. By leveraging RF Integration's advanced design methodologies, the core optimizes power consumption and boosts signal integrity, enabling it to maintain robust performance even in high-density or signal-degraded environments. Such versatility makes it indispensable for applications that demand precise and reliable location tracking, from military and commercial aviation to survey and mapping solutions.
The Cobalt GNSS receiver by Ubiscale is an ultra-low-power IP core designed to expand the IoT System-on-Chip (SoC) market scope by integrating GNSS functionalities. This receiver is specifically crafted to meet the stringent power and size constraints of modern IoT applications, ensuring efficient geolocation processes. Engineered to optimize power consumption through advanced embedded processing and cloud collaboration, Cobalt ensures the lowest possible energy use while maintaining high-performance standards. It delivers an easy GNSS integration option into NB-IoT SoCs, offering a cost-effective solution through shared resources between the GNSS system and the modem. Designed for mass-market applications such as logistics, agriculture, and goods protection, Cobalt operates across multiple satellite constellations including Galileo, GPS, and Beidou. It supports both standalone and cloud-assisted positioning which enhances GNSS operation efficiency and system integration flexibility. The solution is bolstered by collaboration with key players like CEVA DSP and backing from the European Space Program Agency. Cobalt's software-defined receiver provides robust sensitivity with minimal processing and memory needs, making it ideal for integration in modern IoT devices. This highly efficient design is perfect for size and cost-constrained applications, providing durable and precise tracking and positioning solutions that target a variety of industries.
SkyTraq's Triple Constellation Positioning System is designed to offer superior accuracy and stability by leveraging multiple satellite navigation systems. This system supports simultaneous tracking of different GNSS constellations, providing enhanced precision and redundancy. Such a configuration mitigates the risk of signal loss, ensuring that positioning data remains consistent and reliable even in obstructed or challenging signal conditions. The system is particularly useful in applications that require uninterrupted service, such as maritime navigation, aviation, and geospatial data collection. Its ability to maintain high accuracy across varied global conditions makes it a preferred choice for critical applications.
Designed for seamless integration into navigation systems, this receiver supports multiple satellite navigation systems, including GPS, Galileo, and GLONASS. It operates efficiently across various channels, enabling accurate and reliable positioning and navigation for a variety of applications. With advanced signal processing capabilities, it ensures enhanced performance in challenging environments by effectively filtering and amplifying weak satellite signals. The receiver's architecture is optimized for low power consumption, which is crucial for battery-powered devices, making it ideal for portable and embedded systems.
The Dead-Reckoning Navigation Technology by SkyTraq offers enhanced positioning capabilities by seamlessly combining GNSS data with inertial sensor inputs. This blend of technologies ensures robust performance in environments where satellite signals are weak or obstructed, making it invaluable for urban navigation and tunnels. The system continuously calculates position and direction through complex algorithms, effectively reducing positioning drift and maintaining accuracy. It is a reliable choice for automotive applications, providing drivers with uninterrupted navigational support and enhancing the functionality of advanced driver assistance systems (ADAS).
This multisystem receiver supports GPS, Galileo, BeiDou, and GLONASS, providing comprehensive satellite coverage for enhanced global navigation capabilities. Its design is aimed at improving signal reception under diverse conditions, facilitating dependable location services in urban, rural, and remote areas. The receiver's architecture incorporates sophisticated filtering and processing technologies to reduce interference and noise, enhancing performance and accuracy. It is engineered to minimize energy use, extending battery life in portable devices while maintaining robust signal integrity.
Trimension UWB represents NXP's cutting-edge ultra-wideband technology designed to enhance precise sensing and positioning. This technology enables secure ranging and radar capabilities, transforming various applications across automotive, industrial, and consumer domains. It is particularly impactful in automotive systems for ensuring safety and precision in navigation and in industrial IoT for asset tracking and management. Trimension UWB technology stands out by offering high immunity to interference, maintaining performance even in challenging environments. The robust data transfer capabilities make it ideal for applications requiring real-time communication and location-based services. Its ability to support a wide range of bandwidths and frequencies allows for seamless integration into existing infrastructures, enhancing system flexibility and future readiness. The technology's advanced features make it a preferred choice for mobile devices and IoT systems, providing unparalleled accuracy in distance and location measurements. The interoperability of Trimension UWB solutions ensures compatibility with various digital ecosystems, thereby enabling new and innovative use cases in smart cities and connected vehicles. Through its unique capabilities, Trimension UWB drives advancements in secure, efficient, and precise digital interactions.
This advanced receiver seamlessly integrates support for multiple global satellite navigation systems including GLONASS, GPS, Galileo, and BeiDou, spread across two channels. Its dual-channel design enhances multipath rejection and signal acquisition even in difficult conditions. The embedded RFIC architecture allows for enhanced integration within complex systems, reducing component footprint and improving overall system performance. Optimized for low power and high performance, the receiver is suitable for demanding applications across automotive and industrial sectors.
SkyTraq's Real-Time Kinematic (RTK) System offers top-tier precision for positioning applications, essential for industries reliant on high-accuracy location data. Utilizing satellite-based positioning with real-time correction data, this system ensures centimeter-level accuracy, crucial for precise navigation and surveying tasks. It supports multiple GNSS constellations, allowing for robust performance even under challenging conditions. The system integrates seamlessly with other data sources, providing versatility and reliability. Its sophisticated algorithms adapt to dynamic environments, making it ideal for applications across various sectors such as construction, agriculture, and autonomous vehicles.
The Nordic nRF9151 is a highly efficient System-in-Package (SiP) designed for cellular IoT applications. It supports LTE-M, NB-IoT, and a GNSS solution that ensures a broad range of functionality for global operations. With its multimode modem, the nRF9151 SiP caters to asset tracking needs by allowing the integration of GNSS for precise location tracking. Supporting a range of 700 MHz to 2200 MHz LTE bands, it is tailored to meet the requirements of different regions. Furthermore, the nRF9151 includes a dedicated 64 MHz Arm Cortex-M33 processor, offering 1 MB of flash memory and 256 KB of RAM to manage its sophisticated functionalities effectively. The SiP is optimized for low power consumption, making it ideal for devices that rely on battery power, which is crucial in IoT applications. The feature-rich SiP also includes Arm TrustZone for secure operations and Arm CryptoCell for enhanced cryptographic capabilities. The nRF9151's robust design and global LTE band support position it as a versatile platform for developing cellular IoT devices. Developers can leverage Nordic's nRF Connect SDK to create customized solutions, taking advantage of the built-in security and connectivity features. Suitable for environments demanding reliability and precision, the nRF9151 aids in accelerating development times while granting a competitive edge in the IoT sector.