Key Point: The age of hypersonic missiles is here.
A Powerpoint slide at a recent defense conference showed details of the Long-Range Hypersonic Weapon, or LRHW, a land-based U.S. Army system. The LRHW is one of multiple U.S. military projects to develop weapons that travel at hypersonic (faster than Mach 5) speeds. The Army is aiming to deploy the first experimental LRWH battery in 2023.
The slide, shown at the 22nd Space and Missile Defense Symposium in Huntsville, Alabama earlier this month, depicts the planned first LRHW battery. It consists of a prototype ballistic missile – an All Up Round, or AUR -- encased in a canister. The missile has a diameter of 34.5 inches. By comparison, a Tomahawk cruise missile only has a diameter of about 20 inches.
Atop the missile is a Common Hypersonic Glide Body (C-HGB). Developed by Sandia National Laboratory, the C-HGB will be used by the Army, Navy and Air Force. It is a boost-glide weapon, lofted high into the atmosphere by the missile, and then gliding down at high speeds. Unlike an ICBM’s warheads, which descends on a fixed trajectory, these gliders have small wings to maneuver at high speeds within the atmosphere (presumably without burning up) before they hit the target.
The slide also shows four Transporter Erector Launchers (TELs), each with two missile canisters. The TELs are based on the M983A4 Heavy Expanded Mobility Tactical Trucks (HEMTT) used to move and launch Patriot anti-aircraft missiles, plus a modified M870 trailer. In addition, the battery will have a command truck using the Advanced Field Artillery Tactical Data System Version 7.0, the Army’s standard artillery fire control system.
The C-HGB is probably based on the Army Hypersonic Weapon, or AHW. A boost-glide vehicle, the AHW was tested in 2011 and achieved a speed of Mach 8 and a range of almost 4,000 miles. That’s slower than an ICBM warhead that descends through the atmosphere at speeds of up to Mach 23, but unlike a ballistic missile warhead, a boost-glide vehicle can maneuver to evade interception.