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, a flagship product of ChipCraft, combines a GNSS receiver with an on-chip application processor, providing an all-in-one solution for high-precision navigation and timing applications. This product is designed to meet the rigorous demands of industries such as automotive, UAVs, and smart agriculture. One of its standout features is the ability to support all major global navigation satellite systems, offering versatile functionality for various professional uses. The NaviSoC is tailored for high efficiency, delivering performance that incorporates low power consumption with robust computational capabilities. Specifically tailored for next-generation applications, NaviSoC offers flexibility through its ability to be adapted for different tasks, making it a preferred choice for many industries. It integrates seamlessly into systems requiring precision and reliability, providing developers with a wide array of programmable peripherals and interfaces. The foundational design ethos of the NaviSoC revolves around minimizing power usage while ensuring high precision and accuracy, making it an ideal component for battery-powered and portable devices. Additionally, ChipCraft provides integrated software development tools and navigation firmware, ensuring that clients can capitalize on fast time-to-market for their products. The design of the NaviSoC takes a comprehensive approach, factoring in real-world application requirements such as temperature variation and environmental challenges, thus providing a resilient and adaptable product for diverse uses.
The Matchstiq™ X40 by Epiq Solutions is a compact, high-performance software-defined radio (SDR) system designed to harness the power of AI and machine learning at the RF edge. Its small form factor makes it suitable for payloads with size, weight, and power constraints. The unit offers RF coverage up to 18GHz with an instantaneous bandwidth up to 450MHz, making it an excellent choice for demanding environments requiring advanced signal processing and direction finding. One of the standout features of the Matchstiq™ X40 is its integration of Nvidia's Orin NX for CPU/GPU operations and an AMD Zynq Ultrascale+ FPGA, allowing for sophisticated data processing capabilities directly at the point of RF capture. This combination offers enhanced performance for real-time signal analysis and machine learning implementations, making it suited for a variety of high-tech applications. The device supports a variety of input/output configurations, including 1 GbE, USB 3.0, and GPSDO, ensuring compatibility with numerous host systems. It offers dual configurations that support up to four receivers and two transmitters, along with options for phase-coherent multi-channel operations, thereby broadening its usability across different mission-critical tasks.
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.
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.
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 GNSS VHDL Library from GNSS Sensor Ltd is designed to streamline satellite navigation system integration into FPGA platforms. This versatile library includes numerous modules such as configurable GNSS engines and fast search engines catering to GPS, GLONASS, and Galileo systems. Complementing these are special components like a Viterbi decoder and RF front-end control, ensuring comprehensive system integration support. Engineered to achieve maximum independence from CPU platforms, the GNSS VHDL Library is built upon a simple configuration file to deliver flexibility and ease of use. Users benefit from pre-built FPGA images compatible with both 32-bit SPARC-V8 and 64-bit RISC-V architectures. The library enables GNSS operations as a co-processor with SPI interface, supporting diverse external bus interfaces without requiring changes in the core library structure. The GNSS VHDL Library incorporates Simplified Core Bus (SCB) for interfacing, enabling interactions through a system-defined bridge module. This provides flexibility in design and ensures efficient data processing and integration with existing systems, simplifying the development process for both new and existing FPGA platforms. Whether enhancing current designs or developing new navigation solutions, this library equips developers with the tools needed for effective GPS, GLONASS, and Galileo integration.
Ubi.cloud represents a transformative leap in IoT tracking innovation, targeting the reduction of power consumption by transferring GPS and Wi-Fi processing to the cloud. This strategic shift helps in creating compact, efficient IoT tracking devices that boast a reduced footprint and minimized cost. By enhancing power efficiency, Ubi.cloud supports improved device longevity and operational cost, positioning itself as a vital element for device and chipset manufacturers seeking to manage IoT tracking efficiently. The Ubi.cloud platform integrates two core technologies: UbiGNSS and UbiWiFi. UbiGNSS manages outdoor geolocation through GPS, providing impressive savings by reducing the positioning time drastically compared to traditional methods. Meanwhile, UbiWiFi facilitates indoor urban geolocation through efficient Wi-Fi sniffing, ensuring performance that rivals native Wi-Fi solutions. Beyond its technological advantages, Ubi.cloud enables flexible business models with options for pay-as-you-go or lifetime licenses, catering to diverse market needs. Compatibility with low-power wide area network technologies such as Sigfox, LoRa, NB-IoT, and LTE-M offers users versatile use-cases in asset tracking and enhances the effectiveness of connected solutions in various sectors.
The hellaPHY Positioning Solution by PHY Wireless utilizes cutting-edge technology for high precision and secure location tracking over cellular networks. It is particularly designed to cater to massive IoT applications, providing low-power and cost-efficient solutions that work seamlessly indoors and outdoors. Leveraging 5G and advanced edge computing, this solution ensures maximum privacy and scalability, making it ideal for diverse applications ranging from smart labels to logistics tracking. This solution dramatically outperforms traditional GNSS systems by using far less data, reducing costs, and enhancing spectral efficiency. Its innovative approach involves device-based processing of standardized 5G signals, which means the device's location is calculated locally. This not only improves speed and accuracy but also maintains a high level of data security, as the location information is encrypted and not shared with third-party servers. Designed with practicality and adaptability in mind, the hellaPHY Positioning Solution integrates effortlessly into existing hardware through a simple API, supporting a range of devices without the need for extensive modifications. With PHY Wireless's patented algorithms, operators can optimize their spectrum use, and users enjoy a robust location service that meets various operational demands. The technology underlying the hellaPHY Positioning Solution stands as evidence of PHY Wireless's commitment to innovation, ensuring that their products meet the growing needs of the IoT landscape. With support for existing LTE and 5G networks, this solution offers businesses a future-proof method to enhance operational efficiencies and service offerings.
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.
Satellite Navigation SoC Integration by GNSS Sensor Ltd represents an advanced solution for incorporating satellite navigation capabilities into system-on-chip designs. This product integrates various global navigation satellite systems (GNSS) such as GPS, GLONASS, SBAS, and Galileo, ensuring comprehensive coverage and accuracy. The design is supported on ASIC evaluation boards that showcase its ability to work as a standalone receiver and tracker. This enables not only verification of GNSS quality but also supports its function as a universal SPARC V8 development platform. Additionally, its compact format ensures easy integration into existing systems, making it versatile for different applications. Technical features of this solution also include specific ASIC CPU functionalities like the LEON3 SPARC V8 processor compliant with 32-bit architecture and a clock speed of 100MHz. It includes memory management, high-speed AMBA bus connections, and debugging features, emphasizing robustness and performance. GNSS functionalities are extensive, comprising multiple I/Q ADC inputs and channels across various systems, ensuring rapid signal acquisition and processing. These abilities make it effective for fast signal detection and positioning accuracy. The engineering behind Satellite Navigation SoC Integration also provides sophisticated features like dual mode power supply, UART connectivity, and multiple antenna inputs, ensuring seamless data transmission and reception. Designed for simplicity and efficiency, it accommodates further hardware extensions and custom configurations, allowing users to tailor the solution to their specific needs. This turnkey solution leverages efficient power and memory management strategies to provide steady and reliable performance across diverse environments.
The L5-Direct GNSS Receiver by oneNav is a groundbreaking solution that focuses on acquiring advanced L5-band signals for positioning with unparalleled accuracy and reliability. This receiver breaks free from the limitations inherent in traditional L1-first GNSS systems by directly tracking L5 signals, which are crucial for reducing vulnerabilities to interference and improving positioning performance in complex urban landscapes. With L5, users benefit from features such as rapid acquisition, reduced power consumption, and immunity to signal disruption, which are crucial for modern navigation devices. This GNSS receiver's design is optimized for the diverse spectrum of modern devices including smartphones, smartwatches, IoT devices, and automotive applications. It leverages a single RF chain for multi-constellation L5-band signals, thereby minimizing the complexity and footprint of RF components. Moreover, the innovative use of AI and machine learning models significantly enhances multipath mitigation and positioning accuracy by utilizing the unique characteristics of the GNSS signals available. Designed to be portable and flexible, oneNav's L5-Direct solution can be integrated into a wide range of semiconductor processes, making it a versatile and efficient GNSS solution. Its digital IP core is scalable, easily programmable, and comes with a comprehensive test bench for rapid deployment. Proving its practicality and effectiveness, this technology has been successfully synthesized at leading manufacturing nodes such as TSMC 12nm and GlobalFoundries 22FDX, ensuring reliability and high performance across various environments.
The MGNSS IP Core offered by Accord Software and Systems is a sophisticated silicon-proven core designed to facilitate the integration of GNSS capabilities into SoCs used in automotive, precision, and IoT applications. This core is designed to support multi-constellation and multi-frequency GNSS operations, making it highly versatile for a variety of uses. It offers a high level of configurability to accommodate both existing and future GNSS signals, allowing it to operate in parallel or sequential modes depending on the specific application requirements. This flexibility ensures that developers can optimize the core's functionality for the specific requirements of their end products. One of the key features of the MGNSS IP Core is its ability to process input from two RF channels, providing dual-frequency GNSS capabilities which contribute significantly to enhancing accuracy and reducing acquisition time. The core is also equipped with advanced interference rejection features, enabling it to maintain performance in environments that are subject to signal disturbances. This makes it particularly suitable for applications that cannot afford to have compromised performances, such as automotive navigation systems and precision surveying tools. The baseband architecture of the MGNSS IP Core is designed for efficient power consumption, with options for low sampling rates and power-down modes that are beneficial for portable and battery-dependent devices. It supports a wide range of GNSS frequencies, including those from GPS, Galileo, GLONASS, BeiDou, QZSS, IRNSS, and SBAS, ensuring broad applicability across global markets. Furthermore, the core's design adheres to AHB standards, simplifying integration with other system components and enhancing the overall efficiency of the solution.
A specialized digital core designed for high-efficiency satellite navigation and positioning applications, the L1 Band GNSS Transceiver Core supports multiple global navigation satellite systems. It is crafted to handle the L1, L2, and L5 bands, facilitating precise position fixes and enhanced operability within urban environments. By integrating signals from different global systems, it ensures superior position accuracy and is instrumental in remote control operations of smart machines and data monitoring arrays.
The Cobalt GNSS Receiver is a cutting-edge GNSS receiver that stands out for its emphasis on ultra-low-power consumption, making it an integral addition to any System-on-Chip design for IoT applications. By leveraging its innovative design, Cobalt elevates the capabilities of IoT devices, facilitating an efficient and cost-effective way to enhance tracking functionalities. Developed in collaboration with CEVA DSP and supported by the European Space Program Agency, Cobalt integrates seamlessly with multiple constellation systems such as Galileo, GPS, and Beidou. This multi-constellation compatibility ensures that devices can handle a wide range of geolocation scenarios with precision and reliability. The sophisticated processing capabilities inherent in the Cobalt design reduce the power requirement while maintaining high sensitivity and accuracy, crucial for efficient device operation. Particularly suited for mass-market applications, Cobalt addresses the specific needs of sectors like logistics, agriculture, mobility, and goods protection. Its ability to integrate GNSS options into modem SoCs while maintaining a small size and lower cost further underscores its suitability for scalable IoT solutions.
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.
This IP component integrates GPS, Galileo, and GLONASS systems into a single-band receiver. Designed to capture signals from multiple satellite systems, it offers versatility and precision in tracking and geolocation services. Suitable for various applications, from consumer electronics to professional navigation devices, it ensures robust performance in multi-system environments. Its architecture is tailored for efficient signal processing, supporting enhanced connectivity and accuracy required by modern GPS solutions.
The nRF9151 is a cutting-edge System-in-Package (SiP) optimized for cellular IoT applications, boasting a multimode LTE-M/NB-IoT modem along with GNSS support. This SiP provides comprehensive connectivity solutions due to its broad LTE band support ranging from 700 to 2200 MHz, and 1.9 GHz NR+ band capability, ensuring global operational compatibility. Equipped with a 64 MHz Arm Cortex-M33 processor, it possesses 1 MB of flash memory alongside 256 KB of RAM, offering sufficient processing power and memory resources for complex IoT applications. The nRF9151 is enhanced with Arm TrustZone and CryptoCell, providing robust security features that are critical for secure IoT deployments.
Accord's GNSS ICs AST 500 and AST GNSS-RF represent a pinnacle of technology in providing comprehensive Global Navigation Satellite System (GNSS) solutions. These ICs are designed to deliver unmatched performance in GNSS signal processing, and are optimized to support all major global navigation satellite systems, including GPS, GLONASS, Galileo, BeiDou, NavIC, and QZNSS. They feature advanced anti-jamming and anti-spoofing capabilities, ensuring reliable operation in the presence of intentional or unintentional interference. Developed for high-precision applications, the AST ICs provide excellent accuracy, making them ideal for a wide range of industrial, automotive, and navigation applications. The AST GNSS-RF variant enhances the standard AST 500 capabilities by integrating RF front-end functionalities, which further strengthens its performance in satellite communication. This integration supports multi-frequency and multi-constellation tracking, allowing devices that use these ICs to maintain accurate positioning even in challenging environments such as urban canyons and dense forest regions. The AST GNSS-RF is also geared towards power efficiency to support battery-operated devices, extending their operational life without compromising on performance. Backed by Accord's long-standing expertise in the GNSS domain, these ICs are a testament to the company's commitment to excellence in engineering and innovation. Their robust design and versatile application potential make them a preferred choice for developers seeking GNSS solutions that combine flexibility, reliability, and state-of-the-art features.
This receiver module integrates multiple global navigation satellite systems, including GPS, Galileo, BeiDou, and GLONASS, into a single device. It is designed to provide comprehensive coverage and accuracy in positioning and tracking. The module supports a range of applications from mobile devices to automotive systems, ensuring reliable and precise location data. It is optimized for minimal power consumption, making it ideal for battery-operated devices requiring long operational lifetimes.
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.
This RFIC is equipped with the capability to receive from an array of satellite systems - GLONASS, GPS, Galileo, and BeiDou. It supports dual-channel operation, allowing simultaneous reception of signals from multiple satellite constellations, which significantly boosts accuracy and reliability. Ideal for advanced navigation systems, this RFIC is crafted to address the requirements of both commercial and industrial applications, offering low-power consumption while ensuring high-performance signal reception.
The NDR504 by Epiq Solutions is a rugged and phase-coherent four-channel downconverter capable of handling RF signals in the 18 GHz to 40 GHz range. It's specifically designed to convert these high-frequency signals to intermediate frequencies below 18 GHz. This capability makes it a pivotal component in modern RF signal processing, enabling detailed signal analysis across multiple scenarios. This versatile downconverter includes a two-band sub-octave preselector for each channel, effectively enhancing the signal filtering capability and ensuring clear and precise output. The phase coherence across channels is a standout feature, driven by a unified local oscillator distribution, offering unparalleled multi-channel processing accuracy which is crucial for applications demanding synchronized data across several channels. The compact design of the NDR504 allows flexibility in deployment, suitable for installation near high-frequency antennas in various environments such as on the ground, in airborne systems, or with unmanned systems. Its compatibility with a wide range of Epiq Solutions receivers and processors further extends its versatility, providing users with an efficient, reliable solution for complex RF environments.
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.
This interface circuit caters to four GNSS channels, allowing concurrent signal processing and enhancement for improved geolocation accuracy. Designed for high-performance environments, it extends the capabilities of GNSS applications by offering robust signal reception and real-time processing. This circuit is engineered to support broad use in navigation and timing devices, offering flexibility to adapt to both commercial and specialized applications with efficiency and precision.
This interface circuit is tailored for GNSS systems, especially in environments with significant RF interference. It ensures single-channel robust signal reception, utilizing advanced interference mitigation techniques to maintain signal integrity. This design is pivotal for enhancing signal robustness and accuracy, essential for navigation systems that operate in densely packed RF environments, ensuring uninterrupted service and reliability in data acquisition.
This interface circuit is specifically designed for GNSS applications, supporting dual-channel connectivity to ensure precision and accuracy in receiving satellite signals. It enhances GPS systems by providing reliable signal reception and pre-processing, improving overall system performance for geolocation and timing applications. Built to support multiple GNSS systems, it caters to a wide variety of markets, from consumer to military-grade devices, enhancing GNSS capabilities in any application it is integrated into.
Building on its foundational Bluetooth achievements, Packetcraft introduces the Channel Sounding Technology that revolutionizes spatial awareness in Bluetooth devices. This platform leverages advanced signal processing to offer extremely precise distance measurement and localization, surpassing traditional boundaries of Bluetooth functionality. Appropriate for integration into automotive systems and consumer electronics, this technology enhances user experiences by facilitating precise control and seamless interaction within digital environments. The technology is pivotal in applications requiring pinpoint accuracy, such as navigation aids and augmented reality interfaces, where user-environment interaction is critical. The deployment of Channel Sounding Technology by Packetcraft signifies a leap towards more intelligent and responsive digital ecosystems. As industries gravitate towards smarter, more interconnected devices, the incorporation of accurate spatial data through Bluetooth will be an essential component of forward-thinking applications and systems, setting a new standard for connectivity solutions.
ERA™ by Epiq Solutions is a versatile, portable spectrum monitoring solution, designed to offer real-time visualization and recording of RF activities. Built for precision and speed, ERA™ enables users to track transient or faint signals and capture data across time and frequency domains. It is optimized for those needing to capture and analyze environmental RF signals effectively. ERA™ facilitates thorough analysis with features like matched sweep speeds, which allow users to efficiently gather historical signal data for post-event analysis. This aspect is particularly beneficial in applications like military and security, where understanding spectrum behavior is essential for decision-making processes. The system is notably user-friendly, requiring no additional software for operation. It integrates seamlessly with Epiq's Matchstiq™ series and can turn ordinary laptops into powerful analyzers. ERA™ supports remote operations via web interfaces, thus expanding its deployment possibilities into areas demanding flexibility and ease of access.
The Ceva-Waves Dragonfly platform offers a full solution for implementing narrowband-IoT (NB-IoT) cellular modem systems, equipped with low-power hardware IP and protocol software essential for modern networks. It supports global navigation satellite system (GNSS) functionalities, enhancing applications in consumer IoT and industrial use cases. The platform is optimized for power efficiency and provides comprehensive GNSS support, making it a robust choice for IoT applications requiring precise positioning and low energy consumption.
ChipCraft's GNSS Receiver features a RISC-V processor core and is engineered to deliver high-precision positioning and navigation capabilities. It is designed to cover all major navigation satellite technologies. The integration of a RISC-V processor core ensures the system is both powerful and flexible, capable of handling a wide range of applications from IoT to autonomous vehicles. Additionally, the receiver includes comprehensive GNSS signal processing capabilities, enhancing its overall accuracy and reliability. The GNSS Receiver is proven in both silicon and FPGA implementations, providing a trusted solution for modern navigation demands.