26. February 2026
Revolutionary Gps Alternative Unveiled: Boosts Autonomous Drone And Robot Performance In Gps-Denied Environments
In an era where autonomous systems are increasingly being used in various industries, including defense, maritime, and robotics, the need for reliable navigation systems has become paramount. Traditional Global Positioning Systems (GPS) have limitations, particularly in environments with high levels of interference or jamming.
Agilica, a Belgium-based company, has developed an ultra-wideband (UWB) radio technology-based solution that provides centimeter-level positioning accuracy even in GPS-denied environments. The company’s Agilica Geolocation (AGL) system is designed to support mission-critical autonomous drone operations, offering a robust and reliable alternative to traditional navigation methods.
The origins of Agilica date back to the Royal Military Academy in Belgium, where researchers began exploring the potential of UWB radio technology for local positioning. This R&D initiative eventually led to the development of the AGL system, which has since been refined through extensive testing and validation in various environments. From maritime to robotics, the company’s expertise spans multiple industries, ensuring that its solution meets the unique requirements of each application.
One key feature of the Agilica Geolocation (AGL) system is its ability to operate independently of GPS signals. This makes it an ideal choice for applications where satellite signals are jammed, spoofed, or degraded. The system uses advanced UWB radio technology to create a local coordinate system using fixed anchor nodes and passive mobile tags. By measuring the time-of-flight between the anchor node and the mobile tag, the AGL system calculates precise real-time positioning.
The Agilica Geolocation (AGL) system offers several advantages over traditional GPS-based navigation systems:
- GPS-Independent Operation: The AGL system provides reliable navigation even when satellite signals are unavailable or degraded.
- Centimeter-Level Accuracy: The system delivers precision positioning down to 10 cm, ensuring enhanced operational safety and control.
- Interference Resistance: Agilica’s solution performs robustly in urban canyons, indoor facilities, maritime environments, and other complex settings where traditional GPS may struggle.
- Passive, SWaP-Efficient Tags: The lightweight mobile tags have minimal impact on unmanned aircraft size, weight, and power budgets, outputting GPS-compatible NMEA data via UART, CANbus, or USB.
The AGL system’s architecture is highly scalable, enabling support for unlimited tag-equipped drones and thousands of ground-based assets. This makes it an attractive solution for large-scale autonomous operations.
Precise time synchronization is another critical aspect of the Agilica Geolocation (AGL) system. The anchor and tag synchronization occurs within less than a nanosecond, ensuring reliable 360-degree positioning.
Agilica offers comprehensive onboarding, on-site setup, and training support to enable rapid deployment for resilient drone tracking and navigation. The company’s solution is well-suited for various applications:
- Precision Takeoff and Landing: Agilica’s AGL system provides precise control during takeoff and landing on moving land and maritime platforms.
- Persistent Position Holding: The system enables reliable position holding for ISR (Intelligence, Surveillance, and Reconnaissance) and monitoring applications.
- Seamless Outdoor-to-Indoor Transitions: Agilica’s solution facilitates smooth transitions between outdoor and indoor environments.
- eVTOL (Electric Vertical Takeoff and Landing) Operations: The system is designed to support eVTOL drone operations, enabling safe takeoff, landing, and navigation.
- Scalable Drone Swarming Applications: Agilica’s AGL system enables large-scale drone swarming operations, making it an attractive solution for various industries.
Agilica, a Belgium-based company, has developed an ultra-wideband (UWB) radio technology-based solution that provides centimeter-level positioning accuracy even in GPS-denied environments. The company’s Agilica Geolocation (AGL) system is designed to support mission-critical autonomous drone operations, offering a robust and reliable alternative to traditional navigation methods.
The origins of Agilica date back to the Royal Military Academy in Belgium, where researchers began exploring the potential of UWB radio technology for local positioning. This R&D initiative eventually led to the development of the AGL system, which has since been refined through extensive testing and validation in various environments. From maritime to robotics, the company’s expertise spans multiple industries, ensuring that its solution meets the unique requirements of each application.
The Agilica Geolocation (AGL) system offers several advantages over traditional GPS-based navigation systems:
- GPS-Independent Operation: The AGL system provides reliable navigation even when satellite signals are unavailable or degraded.
- Centimeter-Level Accuracy: The system delivers precision positioning down to 10 cm, ensuring enhanced operational safety and control.
- Interference Resistance: Agilica’s solution performs robustly in urban canyons, indoor facilities, maritime environments, and other complex settings where traditional GPS may struggle.
- Passive, SWaP-Efficient Tags: The lightweight mobile tags have minimal impact on unmanned aircraft size, weight, and power budgets, outputting GPS-compatible NMEA data via UART, CANbus, or USB.
The AGL system’s architecture is highly scalable, enabling support for unlimited tag-equipped drones and thousands of ground-based assets. This makes it an attractive solution for large-scale autonomous operations.
Precise time synchronization is another critical aspect of the Agilica Geolocation (AGL) system. The anchor and tag synchronization occurs within less than a nanosecond, ensuring reliable 360-degree positioning.
Agilica offers comprehensive onboarding, on-site setup, and training support to enable rapid deployment for resilient drone tracking and navigation. The company’s solution is well-suited for various applications:
- Precision Takeoff and Landing: Agilica’s AGL system provides precise control during takeoff and landing on moving land and maritime platforms.
- Persistent Position Holding: The system enables reliable position holding for ISR (Intelligence, Surveillance, and Reconnaissance) and monitoring applications.
- Seamless Outdoor-to-Indoor Transitions: Agilica’s solution facilitates smooth transitions between outdoor and indoor environments.
- eVTOL (Electric Vertical Takeoff and Landing) Operations: The system is designed to support eVTOL drone operations, enabling safe takeoff, landing, and navigation.
- Scalable Drone Swarming Applications: Agilica’s AGL system enables large-scale drone swarming operations, making it an attractive solution for various industries.
In an era where autonomous systems are increasingly being used in various industries, including defense, maritime, and robotics, the need for reliable navigation systems has become paramount. Traditional Global Positioning Systems (GPS) have limitations, particularly in environments with high levels of interference or jamming.
The company’s expertise spans multiple industries, ensuring that its solution meets the unique requirements of each application.
One key feature of the Agilica Geolocation (AGL) system is its ability to operate independently of GPS signals. This makes it an ideal choice for applications where satellite signals are jammed, spoofed, or degraded. The system uses advanced UWB radio technology to create a local coordinate system using fixed anchor nodes and passive mobile tags.
By measuring the time-of-flight between the anchor node and the mobile tag, the AGL system calculates precise real-time positioning.
The Agilica Geolocation (AGL) system offers several advantages over traditional GPS-based navigation systems:
- GPS-Independent Operation: The AGL system provides reliable navigation even when satellite signals are unavailable or degraded.
- Centimeter-Level Accuracy: The system delivers precision positioning down to 10 cm, ensuring enhanced operational safety and control.
- Interference Resistance: Agilica’s solution performs robustly in urban canyons, indoor facilities, maritime environments, and other complex settings where traditional GPS may struggle.
- Passive, SWaP-Efficient Tags: The lightweight mobile tags have minimal impact on unmanned aircraft size, weight, and power budgets, outputting GPS-compatible NMEA data via UART, CANbus, or USB.
The AGL system’s architecture is highly scalable, enabling support for unlimited tag-equipped drones and thousands of ground-based assets. This makes it an attractive solution for large-scale autonomous operations.
Precise time synchronization is another critical aspect of the Agilica Geolocation (AGL) system. The anchor and tag synchronization occurs within less than a nanosecond, ensuring reliable 360-degree positioning.
Agilica offers comprehensive onboarding, on-site setup, and training support to enable rapid deployment for resilient drone tracking and navigation.
The company’s solution is well-suited for various applications:
- Precision Takeoff and Landing: Agilica’s AGL system provides precise control during takeoff and landing on moving land and maritime platforms.
- Persistent Position Holding: The system enables reliable position holding for ISR (Intelligence, Surveillance, and Reconnaissance) and monitoring applications.
- Seamless Outdoor-to-Indoor Transitions: Agilica’s solution facilitates smooth transitions between outdoor and indoor environments.
- eVTOL (Electric Vertical Takeoff and Landing) Operations: The system is designed to support eVTOL drone operations, enabling safe takeoff, landing, and navigation.
- Scalable Drone Swarming Applications: Agilica’s AGL system enables large-scale drone swarming operations, making it an attractive solution for various industries.
The Agilica Geolocation (AGL) system is designed to support mission-critical autonomous drone operations. With its ability to operate independently of GPS signals and provide centimeter-level accuracy, the system offers a reliable alternative to traditional navigation methods.