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 EW6181 is a cutting-edge multi-GNSS silicon solution offering the lowest power consumption and high sensitivity for exemplary accuracy across a myriad of navigation applications. This GNSS chip is adept at processing signals from numerous satellite systems including GPS L1, Glonass, BeiDou, Galileo, and several augmentation systems like SBAS. The integrated chip comprises an RF frontend, a digital baseband processor, and an ARM microcontroller dedicated to operating the firmware, allowing for flexible integration across devices needing efficient power usage. Designed with a built-in DC-DC converter and LDOs, the EW6181 silicon streamlines its bill of materials, making it perfect for battery-powered devices, providing extended operational life without compromising on performance. By incorporating patent-protected algorithms, the EW6181 achieves a remarkably compact footprint while delivering superior performance characteristics. Especially suited for dynamic applications such as action cameras and wearables, its antenna diversity capabilities ensure exceptional connectivity and positioning fidelity. Moreover, by enabling cloud functionality, the EW6181 pushes boundaries in power efficiency and accuracy, catering to connected environments where greater precision is paramount.
The NaviSoC by ChipCraft is a highly integrated GNSS system-on-chip (SoC) designed to bring navigation technologies to a single die. Combining a GNSS receiver with an application processor, the NaviSoC delivers unmatched precision in a dependable, scalable, and cost-effective package. Designed for minimal energy consumption, it caters to cutting-edge applications in location-based services (LBS), the Internet of Things (IoT), and autonomous systems like UAVs and drones. This innovative product facilitates a wide range of customizations, adaptable to varied market needs. Whether the application involves precise lane-level navigation or asset tracking and management, the NaviSoC meets and exceeds market expectations by offering enhanced security and reliability, essential for synchronization and smart agricultural processes. Its compact design, which maintains high efficiency and flexibility, ensures that clients can tailor their systems to exact specifications without compromise. NaviSoC stands as a testament to ChipCraft's pioneering approach to GNSS technologies.
The GNSS VHDL Library by GNSS Sensor Ltd is an advanced collection of VHDL modules crafted for GNSS integration. This library offers a customizable GNSS engine along with Fast Search Engine capabilities for systems like GPS, Glonass, and Galileo. The utility of these modules extends to supporting independent RF channels and includes features like Viterbi decoders and self-test modules, thereby ensuring comprehensive functionality. The library is architected to provide high flexibility and independence from specific CPU platforms, driven by a single configuration file that allows for seamless adaptation across different environments. It supports integration with various external bus interfaces through its innovative bridge modules, ensuring streamlined operations and interactions with other system components. With its extensive configurability, the library can accommodate a wide range of configurations, including the number of supported systems, channels, and frequency bands. This allows developers to adapt the architecture to specific project needs efficiently. Additionally, the library's RF front-end capabilities significantly reduce system development costs and complexities by offering a ready-to-use navigation solution suitable for FPGA development boards and beyond.
ArrayNav represents a significant leap forward in navigation technology through the implementation of multiple antennas which greatly enhances GNSS performance. With its capability to recognize and eliminate multipath signals or those intended for jamming or spoofing, ArrayNav ensures a high degree of accuracy and reliability in diverse environments. Utilizing four antennas along with specialized firmware, ArrayNav can place null signals in the direction of unwanted interference, thus preserving the integrity of GNSS operations. This setup not only delivers a commendable 6-18dB gain in sensitivity but also ensures sub-meter accuracy and faster acquisition times when acquiring satellite data. ArrayNav is ideal for urban canyons and complex terrains where signal integrity is often compromised by reflections and multipath. As a patented solution from EtherWhere, it efficiently remedies poor GNSS performance issues associated with interference, making it an invaluable asset in high-reliability navigation systems. Moreover, the system provides substantial improvements in sensitivity, allowing for robust navigation not just in clear open skies but also in challenging urban landscapes. Through this additive capability, ArrayNav promotes enhanced vehicular ADAS applications, boosting overall system performance and achieving higher safety standards.
Ubi.cloud is an innovative solution by Ubiscale that transforms the landscape of IoT device geolocation. It effectively transfers the power-intensive processes of GPS and Wi-Fi to the cloud, thereby significantly reducing the size, power usage, and cost of tracking devices. Ubi.cloud's focus is on providing ubiquitous geolocation by combining GPS for outdoor navigation with Wi-Fi for precise indoor and urban tracking. The architecture of Ubi.cloud integrates embedded technologies like UbiGNSS and UbiWIFI, and aims for substantial power savings and efficient operation. UbiGNSS minimizes power usage during location computation, boasting impressive power savings compared to traditional GPS cold-start processes. Meanwhile, UbiWiFi offers rapid location determination, outperforming standard Wi-Fi sniffing techniques. Ubi.cloud supports low-power wide-area networks like Sigfox, LoRa, and NB-IoT, ensuring versatile application across various IoT infrastructures. The solution provides not just location but accuracy metrics, while the device's power can be completely turned off between location updates to conserve energy. This combination of efficiency, adaptability, and cost-effectiveness makes Ubi.cloud an ideal solution for developers aiming to enhance IoT device capabilities with minimal resource consumption.
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.
The L5-Direct GNSS Receiver by oneNav is a pioneering solution designed to acquire and process L5-band signals independently. This advanced receiver utilizes a unique Application Specific Array Processor (ASAP) to directly acquire L5 signals, ensuring high sensitivity and rapid location fixing. This innovation allows the receiver to function effectively without relying on the older L1 signals, providing a robust alternative in urban settings where signal interference can be a significant issue. The technology supports a multitude of satellite signals, including those from GPS, Galileo, QZSS, and BeiDou, enabling it to adapt to various constellations. Its design optimizes space and power through a single RF chain, reducing the need for complex dual-band systems. This results in a smaller footprint and lower costs, making it ideal for compact electronic devices such as wearables or IoT gadgets. One of the standout features of this technology is its ability to manage multipath errors using machine learning algorithms, which effectively discriminate between direct signals and reflections. The receiver's resilience against GPS spoofing and jamming enhances security and trustworthiness, critical in areas of contested or compromised signals. By integrating seamlessly with non-terrestrial networks, the L5-Direct GNSS Receiver ensures reliable connectivity and positioning in diverse environmental conditions. Moreover, oneNav's receiver is built for endurance and efficiency, with a design that allows for continuous, low-power tracking—a feature especially beneficial for battery-operated applications. The overall architecture demonstrates significant advancements in both GNSS receiver technology and the broader field of navigation systems, offering unparalleled performance, precision, and reliability in the GNSS domain.
Moonstone Laser Sources are at the core of Lightelligence's photonic technologies, providing reliable and efficient laser solutions for optical computing systems. These laser sources are critical components in driving the performance of photonic devices, delivering consistent and precise optical signals essential for high-speed data communication and processing tasks inherent to AI and modern computing systems. Designed with a focus on stability and efficiency, Moonstone lasers operate at wavelengths ideally suited for photonic integration, ensuring minimal loss and maximum signal integrity. This allows for more robust interactions between components in a photonic system, leading to tangible improvements in computational throughput and system responsiveness. The high-performance nature of Moonstone lasers makes them an invaluable asset in applications where precision and reliability are paramount. Their integration into Lightelligence's broader product lineup showcases a commitment to advancing optical technologies, setting new benchmarks for what photonics can achieve in the context of computing and data processing environments.
The Satellite Navigation SoC Integration solution by GNSS Sensor Ltd facilitates the incorporation of GNSS capabilities into system-on-chips. This integration supports GPS, GLONASS, SBAS, and Galileo, enabling comprehensive navigation system compatibility. The solution involves independent search engines for rapid satellite signal acquisition and processing, enhancing the overall efficacy of the navigation systems. Additionally, it accommodates various frequency bands and provides platform-independent signal processing capabilities, making it a versatile option for developers. The solution is designed to provide optimum performance with its sophisticated navigation engine. It supports a broad spectrum of satellite frequency bands, ensuring a wide range of compatibility. This feature is pivotal for applications requiring precise geolocation capabilities, providing developers with a reliable and efficient platform to build upon. Its integration into SoCs simplifies development, allowing for seamless incorporation into existing systems. Further enriching its offering are features like a high update rate and a platform-independent API, ensuring that it meets the technical demands of modern applications. This API facilitates easy integration into various software platforms, ensuring that as navigation needs evolve, the system remains adaptable. Additionally, the focus on ensuring a high level of flexibility in design and functionality makes this solution particularly appealing for developers aiming to develop robust, innovative GNSS-enabled systems.
Cobalt is Ubiscale's specialized GNSS receiver, designed for ultra-low-power consumption, making it ideal for integration into IoT systems on chip. This advanced GNSS receiver broadens the market potential of IoT devices by enabling cost-effective and power-efficient GNSS functionalities. It's particularly well-suited for systems constrained by size and power where GNSS is necessary. Engineered with embedded processing and optional cloud assistance, Cobalt optimizes power usage and maintains exceptional positioning sensitivity. It supports constellations such as Galileo/GPS/Beidou and provides robust standalone as well as cloud-assisted positioning capabilities, which cater to diverse application requirements. Cobalt is developed in partnership with CEVA DSP and benefits from the European Space Program's support, illustrating its integration into high-standard European technology initiatives. Its design allows for optimal use in massive-market applications like logistics and mobility, ensuring high precision despite challenging environmental conditions. The Cobalt GNSS Receiver allows for shared resources with modem functionalities and operates efficiently in the same frequency bands as older GPS modules, enhancing its utility without requiring additional infrastructure complexities.
The MGNSS IP Core is an advanced GNSS solution designed for integration into multifaceted GNSS and application SoCs targeting automotive, smartphones, precision applications, and IoT devices. This core stands out with its ability to process multi-constellation and multi-frequency GNSS signals, ensuring high precision and sensitivity. Highly configurable, it supports various legacy and modern GNSS signals, adapting to comprehensive application requirements.\n\nThis sophisticated IP is fabricated with an architecture that lets it process data from multiple RF channels, providing dual-frequency capabilities and strengthened resistance against interference. It's designed to accommodate up to 64 parallel GNSS signal tracking channels, promoting rapid acquisition and precision tracking essential for real-time applications. Its AHB compliance ensures smooth CPU interfacing, enhancing synchronization in device performance.\n\nMoreover, this IP core features extensive power management options, allowing it to operate at reduced power levels as needed, which is critical for battery-powered devices. By offering both low power consumption and flexible configurability, it extends support across a plethora of GNSS signals, making it the backbone for equipment demanding high navigation accuracy. Additionally, Accord supports customization for specific requirements, facilitating great integration ease, and providing services for AGPS, DR, and INS integration, further enhancing its application capability.
The L1 Band GNSS Transceiver Core is designed for precise geolocation services, leveraging multiple global satellite systems for enhanced accuracy. This solution integrates RF and digital functionalities to seamlessly operate with GPS, Galileo, and other major systems, ensuring reliable performance across all conditions. The design is optimized for low power consumption, making it ideal for portable devices and systems that require robust navigation capabilities. By utilizing advanced technologies in SiGe and RF CMOS, this transceiver provides high sensitivity and rapid acquisition capability. It can function effectively in challenging environments such as urban canyons and dense forests where high signal quality is imperative. The core is adaptable for both commercial and military applications, offering flexibility and scalability across various platforms. With its high level of integration, the L1 Band GNSS Transceiver minimizes component count on the board, helping to reduce the overall system cost and size. This makes it a preferred choice for manufacturers who seek to enhance their products' positioning capabilities without compromising on performance or reliability.
The GNSS ICs AST 500 and AST GNSS-RF form a crucial component of Accord's expanding portfolio of semiconductor solutions. These chips are meticulously designed to enhance the capabilities of GPS and GNSS systems, enabling superior performance in diverse applications. The AST 500 is engineered to provide robust and reliable navigation solutions, making it indispensable for applications that demand precise positioning and timing. Meanwhile, the AST GNSS-RF is optimized for RF front-end operations, ensuring high-quality signal processing required for accurate global positioning across various environments, whether terrestrial or space.\n\nWith a strong focus on innovation, these ICs support a wide range of global navigation satellite systems, including GPS, Galileo, and BeiDou. This makes them exceedingly versatile for integration into a myriad of devices where positioning accuracy is paramount. Thanks to robust architecture, these ICs can efficiently handle multi-frequency and multi-constellation tracking, providing users with flexibility and reliability in their GNSS applications.\n\nDesigned with precision and robustness, these ICs incorporate advanced features like enhanced interference mitigation capabilities. This ensures they can maintain reliable operation even in environments with significant electronic noise, thereby elevating the reliability of GNSS systems. Overall, the AST 500 and AST GNSS-RF chips underscore Accord's commitment to delivering cutting-edge solutions that push the boundaries of what's achievable in satellite navigation technology.
This system enhances positioning accuracy by utilizing three different satellite constellations - GPS, GLONASS, and NavIC. This multi-constellation approach ensures that users receive the most accurate and reliable position information possible, making it ideal for applications where precision is critical. The system is designed to work efficiently in challenging environments with limited sky visibility, such as urban environments or dense forests. By leveraging signals from multiple satellites, it significantly reduces errors and improves location accuracy, even under suboptimal conditions. SkyTraq's technology is suitable for a broad spectrum of uses, including personal navigation devices, fleet management, and surveying tools, offering high reliability and consistency. Its ability to maintain continuous and accurate positioning is a testament to SkyTraq's commitment to advancing navigation technology.
SkyTraq's Real-Time Kinematic (RTK) system offers carrier phase positioning with centimeter-level accuracy, suitable for precision guidance and mapping applications. This technology is crucial for tasks requiring high precision, such as surveying and automated control in agriculture and construction. By utilizing multiple satellite constellations, it ensures reliable positioning information even in complex environments. The RTK system achieves fast convergence times and enhanced performance in dynamic conditions, thanks to its multi-band, multi-GNSS capabilities. This makes it particularly effective for applications where both precision and speed are critical. Its compact form factor enables integration into a wide range of devices and systems, supporting both base and rover configurations. Moreover, SkyTraq's RTK technology includes moving base functionality, allowing the determination of precise heading information. This feature is indispensable for autonomous vehicles and other navigation-dependent technologies, ensuring accurate and stable guidance under varying conditions.
The Matchstiq™ X40 model is a high-performance software-defined radio (SDR) platform featuring advanced computing capabilities, designed specifically for AI and machine learning applications at the RF edge. This device is tailored for use in environments where small form factor and low size, weight, and power (SWaP) parameters are essential, without compromising on operational efficiency. This platform operates over an expanded frequency range from 1 GHz to either 6 GHz or 18 GHz depending on the model, supporting bandwidths up to 450 MHz per channel. Sophisticated digital signal processing is powered by an integrated graphics processing unit (GPU), enhancing capabilities for complex signal and data handling tasks. Both support for extensive RF motor, sensors and, advanced AI processing make it particularly suited for mission-critical applications. The Matchstiq X40 is ideal for dense RF environments, providing flexibility through its open architecture which facilitates integration with existing systems. It embodies the essence of Epiq Solutions' focus on delivering cutting-edge technology within compact designs, enabling versatile deployment in challenging operational scenarios.
SkyTraq's Dead-Reckoning Navigation Technology combines satellite positioning with inertial navigation systems to maintain accurate navigation even when satellite signals are unavailable. This intelligent blending of data sources ensures uninterrupted service, crucial for navigation in urban canyons or tunnels where traditional GPS signals fail. At the heart of this technology is the integration of a 6-axis IMU, vehicle odometer, and barometric sensors to calculate precise location data. This fusion of sensor inputs not only provides high accuracy but also offers altitude differentiation, which is particularly beneficial in multi-level environments like parking structures. SkyTraq's dead-reckoning solutions are designed to be seamlessly integrated into automotive and industrial applications, providing consistent and reliable navigation aids regardless of environmental conditions. This technology supports a new wave of autonomous and semi-autonomous vehicles, enhancing safety and operational efficiency even in the most challenging scenarios.
Designed for the NB-IoT market, the Ceva-Waves Dragonfly is a comprehensive platform that integrates optimized hardware IP and protocol software for the development of cellular modem SoCs. With additional support for GNSS functionalities such as GPS and BeiDou, the platform extends its utility towards sensor fusion applications, making it ideal for geographical tracking and data aggregation in IoT devices.\n\nCeva-Waves Dragonfly combines advanced hardware with the Ceva-BX1 processor as the core, supporting various wireless connectivity standards while affording low power consumption. This configuration supports the main LTE baseband features, thus offering a reliable infrastructural solution for IoT systems while ensuring compliance with 3GPP standards.\n\nThe platform’s modular nature and pre-certified core software significantly decrease the time-to-market for OEMs, paving the way for rapid deployment and adaptation in narrow-bandwidth applications such as smart metering, wearable technologies, and other IoT innovations.
Augmenting the capabilities of its predecessor, the SBR7040 integrates GPS functionality with LTE/3G transceiver capabilities. This multi-functional IP is designed to fulfill the needs of mobile and fixed IoT systems, where both communication and location tracking are imperative. This combination serves diverse purposes, offering seamless connectivity alongside reliable GPS navigation across numerous applications. The transceiver's power efficiency ensures it stands out in terms of battery life, making it suitable for OEMs focusing on sustainability. Combining robust connectivity with precision GPS data collection, the SBR7040 is an excellent solution for logistics, fleet management, and wearable technologies. Its dual proficiency in communication and location services distinguishes it as a comprehensive wireless solution, ensuring enduring performance in varying environmental settings.
This RF front-end interface circuit supports dual-channel GNSS applications, providing enhanced signal accuracy for GPS, Galileo, and GLONASS systems. Tailored to elevate the performance of positioning devices, it integrates advanced techniques for signal processing and noise reduction, ensuring pinpoint accuracy and high reliability. Dual-channel support allows simultaneous management of multiple signals, thereby improving the precision and speed of data acquisition. The circuit excels in environments where precision and resilience against interference are prerequisites. It is comprehensively designed to handle complex signal environments, making it suitable for professional and high-demand consumer-grade products. The interface circuit is compact and efficient, maximizing performance while maintaining energy considerations. With strategic noise mitigation and signal enhancement, this circuit is optimal for deployment in navigation systems where reliability and accuracy are non-negotiable, supporting enhanced user experiences across various applications.
The SC1260 60GHz Radar Sensor is designed for automotive interior sensing, offering unparalleled precision and reliability in detecting and monitoring the car's interior environment. This highly advanced radar sensor utilizes sophisticated technology to deliver real-time data on occupancy, seatbelt usage, and interior conditions, enhancing passenger safety and comfort. By integrating cutting-edge radar technology, the SC1260 provides a compact solution for automotive manufacturers aiming to improve the safety and efficiency of their vehicles. With high precision and advanced algorithms, the SC1260 Radar Sensor offers accurate real-time data collection, making it crucial for automotive applications focused on safety and resource optimization. Its innovative design allows for seamless integration in various vehicle models, providing flexibility and adaptability in the ever-evolving automotive landscape. As a critical component for next-generation vehicles, the SC1260 Radar Sensor supports the automotive industry's shift towards more intelligent and connected systems. By offering comprehensive integration capabilities and exceptional performance, this radar sensor stands out as a pivotal solution for enhancing in-vehicle environments.
The GNSS Receiver from ChipCraft represents a pinnacle in satellite navigation technology integrated with modern processing capabilities. This receiver is engineered to deliver superior precision and trustworthiness while maintaining low energy usage. It caters to a spectrum of applications, from simple navigation to complex time synchronization and precise positioning services essential in various high-demand industries. Renowned for its versatile architecture, ChipCraft's GNSS Receiver can be customized to support specific operational requirements, encompassing applications in the Internet of Things to sophisticated surveying tasks. By balancing advanced security measures with robust performance, the receiver paves the way for innovative solutions in smart systems. With a focus on scalability and adaptability, ChipCraft provides solutions that seamlessly integrate into diverse user environments, thereby enhancing efficiency and effectiveness across industries.
The SBR1585 is a versatile GNSS receiver that tackles multiple satellite systems, designed for applications where extreme power efficiency is vital. It supports four major systems: GPS, GLONASS, Galileo, and BeiDou, enhancing location services' reliability and accuracy across various regions. This receiver's ultra-low-power consumption is a key feature, making it suitable for IoT devices that require precise and continuous location tracking without frequent battery replacements. With its high-performance capabilities, it's positioned as an essential component for wearable GPS gadgets and other mobile setups. Manufactured to occupy minimal silane area, the SBR1585 not only reduces costs but offers a robust performance package, ensuring steady and accurate position fixing. Its applications span multiple industries, from personal navigation to industrial tracking, highlighting its flexibility and value.
This GNSS RF front-end interface circuit is designed to enhance GPS systems by providing robust interference resistance. It supports single-channel signal processing and integrates seamlessly with a wide range of GPS, Galileo, and GLONASS modules. With its state-of-the-art architecture, the interface ensures precision in positioning by mitigating disruptions from unwanted signals. Such resilience is critical for accurate geolocation in challenging environments. Built on a sophisticated platform, the circuit boasts advanced interference suppression capabilities. Its design includes strategic noise filtering and signal modulation, resulting in high-fidelity outputs. The technology imparts superior accuracy and reliability, essential for both industrial and consumer GPS applications. The device is thus ideal for integration into systems where stability and precision are paramount. Additionally, the circuit's compact design allows it to fit into a variety of device formats, ensuring flexibility in deployment. Whether for navigation devices, mobile applications, or embedded systems, this RF front-end interface circuit delivers consistent performance standards and supports a wide spectrum of geolocation technologies.
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