Russia Gives Soviet-Era Laser Tank New Lease on Life

1K17 Szhatie self-propelled laser vehicle

Russian engineers are working to breathe new life in Soviet-era plans to develop a laser tank, a staple of Hollywood blockbusters and video games, Russian media reported.

During the closing years of the Cold War, the USSR tried to make that part of science fiction come true and it worked, but not too well.
In its May 28, 2015 article the state-run Rossiyskaya Gazeta newspaper hinted that Russian engineers were now working on similar laser weapons “without advertising it.”By the mid-1970s, the Soviet Union was eagerly pursuing laser weapons on land, at sea, in the air and in outer space as a useful counter to US and Western European optics, missiles, spy satellites and other high-tech systems.

In 1982, it built the first full-size prototype of an energy weapon for a ground vehicle and installed in on a tracked chassis.

The first laser tank was born.

“Creators of the wonder-weapon began thinking about what to call their development so no one would guess anything and, most important, so there also was no mention of a laser,” the Moscow-based Rossiyskaya Gazeta noted.

“They called it a portable automated sighting device, designated the vehicle the 1K11 and dubbed it the Stilet —   or Stiletto. It was meant to burn out enemy cameras, scopes and seekers,” it added.

Far more impressive was the 1K17, which boasted a far more powerful multi-channel laser on a T-80 tank chassis. A dozen individual lenses amplified the main beam as huge batteries allowed the vehicle to fire multiple “shots” in rapid succession.

“[The] laser guns … were capable of burning out all enemy optics within direct line of sight in fractions of a second,” the newspaper wrote. “When there was contact with enemy armored vehicles, Soviet laser tanks simply would blind them, making aimed fire impossible,” Rossiyskaya Gazeta wrote.

The energy beam would have twice the range of a normal tank gun.

In 1992, the first prototypes rolled out of the factory, but the economic chaos in the wake of the Soviet collapse forced the government to cancel the program.

“But one high-ranking official of the Yeltsin government once publicly let it slip that platforms were practically ready,” Rossiyskaya Gazeta noted. “The technology has not been lost.”

“There are a handful of areas … where, theoretically, Soviet-era engineering remains competitive on today’s battlefield,” retired US Army Major Ray Finch,  -  an analyst at the Army’s Foreign Military Studies Office , —  wrote in the June 2015 edition of OE Watch.

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Laser warfare and tank-based systems

November 25, 2014 Alexander Korolkov, RIR

In the second part of this series on military lasers, Alexander Korolkov looks at tank-based systems that were pioneered in the Soviet era and in some cases are still cloaked in secrecy.

Laser warfare and tank-based systems
    The 1K17 “Szhatiye” project which went into service in 1992. Source: Scientific production association “Astrophysics”

It was a busy fall season in the world of military laser warfare. In September, Boeing unveiled its truck-mounted 10-kilowatt High Energy Laser Mobile Demonstrator, capable of knocking out drones and even missiles.

In November, the commander of the Fifth Fleet of the U.S. Navy, Vice Admiral John Miller, confirmed receipt of the first combat laser and its installation on the amphibious assault ship USS Ponce.

China also announced the development of a laser that can shoot down small aerial targets. And while little is revealed publicly, Russia has not let its laser development program idle either.

At the current stage of development, rocket technology is still far superior to existing laser weapon capacity. But the quest to harness laser power is also about the cost of a single shot.

All missile technology is costly, but when used over long distances this requires additional navigation systems, a large fuel load and other line items that drive up the cost of a single strike. The attraction of lasers remains their simple power to effect ratio: Firing one costs as much as generating the power it consumes.

This was also a guiding principle when the Soviet Union powered up its laser program in the 1960s at the top-secret “Astrophysics” scientific research and production centre. Appointed to head it in 1978 was the talented physicist Nikolai Ustinov, son of the powerful Soviet Defence Minister Dmitry Ustinov.

Stiletto

But technology at the time did not enable the construction of mobile lasers powerful enough to destroy a target. So researchers instead focused on ‘blinding’ a tank, self-propelled gun or low-flying helicopter by targeting photo-sensors in its optical sighting systems. Once these are neutralized, the vehicle or aircraft becomes easy prey.

Laser guidance systems had now been developed in anti-missile laser systems. The SLK 1K11 Stiletto uses radar to detect a target, probes it with a laser to detect any lens gleam and hits the spot with a powerful laser impulse.

The system was fitted with a mobile power supply and installed on the chassis of a tracked mine-laying vehicle. The Stiletto was delivered to the Red Army in this form in 1982 but was still classed as experimental. While only two units were ever produced, it is formally still in service with the Russian Army.

Sanguine

The year after Stiletto became suitable for service, Astrophysics began work on a more advanced device that was originally conceived for air defence, a laser equivalent of the Shilka self-propelled anti-aircraft system.

Unlike the Stiletto, Sanguine was a modern variant that eschewed bulky mirrors and could be fired vertically. A laser cannon mounted on the Shilka platform could disable a helicopter’s optical system at a range of 6 miles and disable it entirely at 5 miles.

Szhatiye

But the pinnacle of Soviet physicists’ laser research was the 1K17 Szhatiye (compression) project which went into service in 1992. While resembling the Buratino (Pinocchio) salvo-firing rocket and heavy flamethrower systems, Szhatiye’s 12 barrels did not hold rockets but multi-line lasers. Each had its own frequency band and internal guidance system, which were impervious to enemy filter systems.

The weapon comprised a solid-state laser with fluorescent energizing lights similar to those of the American ZEUS remote demining system. Because of its powerful generator and power plant, Szhatiye was mounted on the chassis of the heavy Msta-S self-propelled gun. The system is still classified and there is no open data on characteristics like the range, firing rate or number of simultaneously engaged targets.

Its range may be presumed to be no less than Sanguine’s, so twice the effective range of a modern tank. But while impressive on the drawing board, this must be set against the laser’s main disadvantage: the need for a clear line of sight in order to hit a target.

Shooting at point-blank range in combat conditions is also hampered by terrain relief, rendering such systems largely impractical.

But as evidenced by U.S. and Chinese activity, the use of lasers against guided missiles, helicopters and UAV drones (where using conventional missiles is prohibitively expensive), is a strong incentive for further development.

Dal

The collapse of the Soviet Union slammed the brakes on science and technology development in Russia for several years. Many items ended up as exhibits, including units built by Astrophysics, and examples are still surfacing unexpectedly. While the first Stiletto built probably saw some use, a second without laser sighting was found by enthusiasts in a factory in the Ukrainian city of Kharkov in 2010.

The fate of Sanguin and Aquilon is not known, but at least one Szhatiye system made it into the public eye, now displayed in a museum in Ivanovskoye near Moscow.

One Astrophysics brainchild did make it into full military service, however. The KDHR-1H Dal chemical detection and monitoring system uses a laser radar to locate sources of contamination, scanning 45 square miles in 60 seconds.

After detecting a toxic cloud, Dal calculates its coordinates and linear dimensions. The system’s automatic operating time without refuelling is 130 hours, and three hours after a 500km drive. A unique piece of equipment when it was first introduced in 1988, Distance remains in service with the Russian Army.