Experts at the Russian Center for Integrated Unmanned Solutions (CDBR) have introduced the Peak tower to extend the operational range of FPV crews guarding naval and military facilities. The project aims to bolster the security of ships, critical infrastructure of the Russian Armed Forces, and airfields against Ukrainian drone threats. This development is reported through official channels, highlighting its role in enhancing battlefield communications and surveillance resilience.
The Peak tower functions as a long‑range digital communications complex designed to maintain a stable link between the FPV pilot and the drone. It complements a broader system of ground-based FPV computation equipment, enabling reliable control during extended flights. Officials indicate that the tower can be mounted on airport control towers and ship masts, creating a robust communication backbone that allows pilots to operate drones far from their platforms or within shared airspaces without losing connection.
A notable feature is its 100‑meter armored cable, which connects the ground equipment to the antenna. The entire system is operated from the ground via remote control, and adjustments to the settings can be made without taking the device apart. This design emphasizes ease of maintenance and rapid response during operations, reducing downtime and keeping the drone link secure in demanding environments.
Officials point out that the Peak tower was created with operator safety in mind. By extending the operator’s operating range while enabling work from cover, the system helps minimize exposure to potential threats. This approach is aligned with broader efforts to protect personnel during drone-based operations and to maintain effective command and control in contested zones.
In practical terms, the Peak tower is part of a broader strategy to safeguard drone operators and improve mission effectiveness. By ensuring stable communications and extended reach, the technology supports safer and more efficient execution of FPV missions, especially in environments where distances and exposure raise risk. The emphasis on robust, ground-based control also contributes to better situational awareness for crews and decision-makers on the ground and at command posts.
Earlier reports noted that Russian FPV drone operations already incorporated operator protection systems, reflecting a continuous focus on safety and reliability in unmanned aerial operations. The development of Peak fits into a larger narrative of advancing unmanned capabilities within the region, including ongoing discussions about drone warfare dynamics and the evolving tactical landscape between the Russian Federation and neighboring adversaries.
Overall, Peak represents a strategic upgrade to the control infrastructure for FPV drones, aimed at extending flight ranges, improving operator safety, and enhancing the effectiveness of ground crews in safeguarding critical assets. As unmanned systems continue to play a growing role in modern defense, such innovations are likely to influence how remote pilots execute missions and how command structures coordinate complex airspace operations.