Breaking News
Russian Mi-28NM Attack Helicopter Spotted with Possible Counter-Drone Electronic Warfare Upgrade.
Russia’s Mi-28NM attack helicopter has appeared with what seem to be new electronic warfare antenna housings, suggesting a potential upgrade aimed at countering the growing drone threat over the battlefield. Footage released by the Russian Ministry of Defense and published by tvzvezda on June 18, 2026, showed the helicopter conducting an LMUR missile strike in Ukraine, while the newly observed equipment points to efforts to improve survivability against FPV drones and other radio-frequency threats.
The antenna layout across the nose, wing-root fairings, and tail boom indicates a system designed to provide broad electromagnetic coverage rather than a single sensor function. If confirmed as a counter-UAS electronic warfare suite, the upgrade would reflect a wider shift in modern rotary-wing warfare, where helicopter survival increasingly depends on disrupting drones and their control links as much as defeating traditional air-defense threats.
Related Topic: China's New Z-21 Heavy Attack Helicopter Emerges as a Potential Competitor to the U.S. AH-64E Apache
Russian Mi-28NM attack helicopter footage shows possible new counter-drone electronic warfare antenna housings, suggesting Russia is adapting rotary-wing aircraft for survivability in Ukraine’s drone-heavy battlefield (Picture Source: Russian MoD / Edited by Army Recognition Group) © Army Recognition Group. All rights reserved. Unauthorized use, reproduction, or distribution prohibited.
On June 18, 2026, Russian defense outlet tvzvezda published footage released by the Russian Ministry of Defense showing a Mi-28NM attack helicopter conducting a strike against Ukrainian forces with an LMUR guided missile. The video was presented as an operation in the area of responsibility of Russia’s Center Group of Forces, where the crew reportedly engaged a camouflaged stronghold and personnel. Beyond the strike itself, several stills from the footage show what appear to be new antenna housings installed on the helicopter. Their presence suggests that Russia may be adapting one of its most capable attack helicopters for improved survivability against drones and radio-frequency threats in Ukraine.
New footage has shown that the Russian Aerospace Forces’ Mi-28NM attack helicopter appears to have been modified to enhance its performance in counter-drone roles. The sighting of new antenna housings in several locations across the airframe indicates that a significant upgrade may have been implemented to the helicopter’s electronic warfare capabilities. The structures are visible on the sides of the nose, on top of the stub-wing self-defence equipment fairings, and on the tail boom. Their distribution suggests a system intended to provide wider electromagnetic coverage around the aircraft, rather than a single forward-facing sensor or emitter. Although the Russian Ministry of Defense has not officially identified the equipment, the configuration is consistent with an electronic countermeasures installation, possibly linked to counter-UAS jamming.
One of the most notable details is the reported “СВЧ” marking visible on one of the housings. In Russian technical terminology, “СВЧ” usually refers to “сверхвысокие частоты,” or super-high frequencies, a term commonly associated with microwave emissions and centimetric wavelengths. This should be interpreted cautiously, but it is more technically accurate to link the marking to microwave or super-high-frequency radio emissions rather than simply to UHF. If the housings are part of an electronic warfare package, they could be intended to interfere with drone control links, video transmission channels, satellite navigation signals, or other radio-frequency systems used by small unmanned aerial systems. This would align with the operational reality in Ukraine, where FPV drones and reconnaissance UAVs have become a direct threat to vehicles, artillery, logistics nodes, air defense systems, and increasingly to rotary-wing aviation.
The Mi-28NM is the most modern operational variant of the Mi-28 attack helicopter family, known by the NATO reporting name Havoc. Developed from the Mi-28N Night Hunter, it was designed to improve day and night attack capability, target acquisition, crew situational awareness, survivability, and precision weapons employment. The helicopter is equipped with an armored tandem cockpit, a chin-mounted 30 mm 2A42 automatic cannon, stub wings for guided and unguided weapons, and upgraded avionics. It can employ the LMUR, also known as Izdeliye 305 or Kh-39, a light multipurpose guided missile used for stand-off engagements against fixed and mobile ground targets. For Russia, the Mi-28NM is important because it provides a heavy attack helicopter capability alongside the Ka-52M, supporting reconnaissance, anti-armor missions, close air support, armed overwatch, and precision strike missions in contested environments.
The possible addition of counter-drone electronic warfare equipment would represent a logical evolution of the Mi-28NM’s defensive aids suite. Traditional helicopter self-protection has focused on missile approach warning, laser warning, radar warning, infrared countermeasures, chaff and flare dispensers, and low-altitude flight profiles using terrain masking. These measures remain relevant against MANPADS, radar-guided systems, anti-aircraft guns, and battlefield air defense networks, but they do not fully address the growing threat from FPV drones and small UAVs. These systems can approach from unexpected angles, attack during takeoff or landing phases, target forward operating locations, or strike helicopters when they are operating at low speed and low altitude. A distributed antenna layout on the nose, wing-tip fairings, and tail boom could provide a wider protective field and allow the aircraft to disrupt certain drone threats before they reach terminal attack range.
The main operational advantage of such a system would be its soft-kill effect. Instead of destroying an incoming drone kinetically, the helicopter could attempt to deny the drone operator control, degrade the video feed, disrupt navigation, or interfere with command guidance. This would be particularly relevant for aircraft operating close to the forward line of troops or from dispersed airstrips where rotary-wing assets are vulnerable to low-cost UAV attacks. However, this type of protection would not be absolute. Drones using frequency-hopping links, autonomous terminal guidance, pre-programmed flight profiles, relay networks, or fiber-optic control would be harder to defeat through conventional radio-frequency jamming. Powerful electronic emissions can also create an electromagnetic signature detectable by enemy electronic support measures. The new housings should therefore be assessed as part of a layered survivability package, not as a complete shield against unmanned threats.
Compared with other attack helicopters, the Mi-28NM reflects a Russian approach shaped by direct combat experience in Ukraine. The Ka-52M remains another key Russian attack helicopter, with a coaxial rotor design, advanced sensors, and extensive use of guided weapons. The U.S. AH-64E Apache emphasizes network-centric operations, manned-unmanned teaming, advanced target sharing, and integration into a wider digital battlespace. Europe’s Tiger MkIII modernization follows a similar Western trend by prioritizing connectivity, upgraded avionics, sensor fusion, and cooperative engagement. The apparent Mi-28NM modification points to a different but increasingly important requirement: the need for attack helicopters to defend themselves against drones operating inside the electromagnetic spectrum. This does not make the Mi-28NM superior to Western equivalents, but it shows that combat helicopter survivability is now being reshaped by counter-UAS requirements as much as by armor, weapons, or flight performance.
The strategic implication is that Russia appears to be adapting high-value rotary-wing assets to remain operational in a drone-saturated battlespace. If the system proves effective, it could help Mi-28NM crews reduce their exposure to FPV drones and small UAVs during missions, sustain sortie rates, and support ground formations with precision strikes from greater distances. For Ukraine, the likely response would be continued development of more resilient drone technologies, including alternative frequencies, hardened datalinks, autonomous navigation modes, relay systems, and fiber-optic UAVs that are less vulnerable to conventional jamming. At the geopolitical and military level, this sighting illustrates how the war is accelerating the convergence of aviation, electronic warfare, and counter-drone protection. For NATO and partner forces, it is also a relevant indicator that future helicopter modernization programs may need onboard counter-UAS electronic protection as a standard requirement rather than an optional defensive upgrade.
The newly observed Mi-28NM antenna housings send a clear message about the changing nature of rotary-wing warfare. Attack helicopters can no longer rely only on armor, speed, terrain masking, and traditional missile-warning systems to survive near the front line. They now require protection against drones, radio-frequency threats, and electronic attack in a battlespace where small unmanned systems can threaten platforms that are far more expensive and complex. Whether the observed system is fully effective remains unconfirmed, but its appearance indicates that Russia has recognized the operational pressure created by Ukrainian drone warfare. The broader lesson is direct: in modern combat, the survivability of attack helicopters increasingly depends on their ability to fight inside the electromagnetic spectrum as much as on their weapons, armor, and flight performance.
Written by Teoman S. Nicanci – Defense Analyst, Army Recognition Group
Teoman S. Nicanci holds degrees in Political Science, Comparative and International Politics, and International Relations and Diplomacy from leading Belgian universities, with research focused on Russian strategic behavior, defense technology, and modern warfare. He is a defense analyst at Army Recognition, specializing in the global defense industry, military armament, and emerging defense technologies.
Explore More Defense News: