Ukrainian forces gain edge with cutting-edge AR night goggles

Ukrainian special forces soldiers have received unique equipment. The ENVG-B goggles, produced by L3Harris, enable users to see in darkness and access features far beyond normal human vision capabilities.

The AN/PSQ-42 Enhanced Night Vision Goggle-B (ENVG-B) was introduced in 2019 and ordered by the U.S. armed forces, including both the Army and the Marine Corps. These goggles represent a groundbreaking combination of a night vision device (light amplifier) and a thermal imaging device (heat radiation recorder) with a scope, a heads-up display, a compass, and a laser target designator.

The most recognizable feature of this equipment is the merging of night vision and thermal images, overlaid with an additional computer-generated graphics layer (augmented reality, or AR) that highlights the contours of objects.

In practice, the user not only sees in the dark and perceives temperature differences—such as recognizing a person hidden behind an obstacle or bush—but with AR, opponents in the field of view are highlighted.

Besides the "super sight" function, soldiers wearing the ENVG-B goggles can navigate more easily, access images from drones, and use an electronic sight mounted on a weapon. This allows them to aim by merely pointing the weapon around an obstacle without risking exposure to gunfire.

Moreover, with the integrated target marker, they can highlight an opponent in their field of vision. Objects seen with the ENVG-B can be designated for aviation or incoming guided artillery shells, such as the M712 Copperhead supplied to Ukraine by the United States.

According to information on the Telegram platform, this super-modern vision system is used by the Americans and Ukrainian Special Operations Forces soldiers. It's currently unclear how many ENVG-B sets Ukraine received and which specific units are equipped. Undoubtedly, soldiers using it will have an advantage over opponents during nighttime operations.

The ENVG-B goggles aren't the only equipment of their kind—Microsoft developed a strengthened military variant of their Hololens goggles called the IVAS (Integrated Visual Augmentation System) for the U.S. Army. In addition to features similar to the ENVG-B, IVAS offers facial recognition, text translation, and the ability to display drone images.

The use of AR goggles in Ukraine exemplifies the technical revolution that augmented reality is bringing to armed forces—currently limited and not yet widespread.

An early form of its use has been HUD (heads-up displays), applied since the 1960s (initial, imperfect solutions of this type appeared even earlier during World War II), which have gradually gained ground in other sectors, including the automotive industry. Thanks to HUD, pilots can see not only essential flight information but also graphically highlighted targets, and more.

In addition to HUD, helmet-mounted displays are also used today. F-35 pilots, including those in Poland, utilize advanced variants of such solutions. For this aircraft, the HMDS Gen III helmet was developed, displaying all key information directly in front of the pilot's eyes, regardless of where they are looking or orienting their head.

Besides data presentation, the HMDS Gen III helmet integrates an AN/AAQ-37 DAS (Distributed Aperture System) for surrounding observation, allowing pilots to "see through the fuselage" and, for example, view what's beneath the plane thanks to the cameras built into the aircraft.

This system is being replaced by an even more advanced AN/AAQ-37 EODAS (Next-Generation Electro-Optical Distributed Aperture System), which adds infrared viewing to 360-degree observation. With this solution, instead of observing FLIR sensor images on a screen in the cabin, pilots can freely look around, observing the infrared environment as if the fuselage and cockpit didn't enclose them.

An example of augmented reality application on an even larger scale is the quickly developed Japanese Mogami-class frigates. Their unique feature is the innovative AICIC (Advanced Integrated Combat Information Center), which is a circular space surrounded by vertically arranged screens.

Thanks to the ability to display images from cameras and other sensors, the center's operators can observe the situation outside the vessel in real-time, with additional markers or information about various objects superimposed on the real image.

Similar solutions are also being implemented in new combat vehicles and training systems. The advantages of using augmented reality during training are leveraged in the American STE (Synthetic Training Environment) project, enabling units to train together despite being located in different parts of the world.

Among AR applications is also support for technical maintenance, such as goggles developed by GridRaster for servicing CV-22 Osprey tiltrotor aircraft.

The image recorded by the camera is recognized and processed so that the technician looking at the machine's components sees the image with highlighted parts, their descriptions, or servicing instructions.