The Ground Launched Small Diameter Bomb (GLSDB) is a weapon developed by
Boeing and the
Saab Group to allow Boeing's
GBU-39 Small Diameter Bomb (SDB), originally developed for use by aircraft, to be ground-launched from a variety of launchers and configurations. It combines the SDB with the
M26 rocket, enabling it to be launched from ground-based missile systems such as the
M270 Multiple Launch Rocket System and
M142 HIMARS.[9][10] It can also be fired from its own launch container, allowing it to be fired from sea.[11]
Design
Boeing, in partnership with Saab, developed an "inter-stage adapter" to connect the SDB to an
M26 rocket.[12][13] Also providing expertise are the Norwegian-Finnish company
Nammo (booster rocket)[14] and the Norwegian company Nordic Shelter (launchers).[15][10] The advantage of the M26 is that there is an abundant stockpile of these rockets.[16][17] Production of these rockets ceased in 2001, when 506,718 rockets had been produced.[18] As of 2004, 439,194 remained in total inventory. By 2007 the Army was paying to destroy them.[19] The original ordnance carried by the M26 did not meet the terms of the
Convention on Cluster Munitions (not signed by the United States).[14] Although the GLSDB can be launched from either MLRS or HIMARS, it also comes with its own launcher, which resembles a nondescript 20-foot (6.1 m)
shipping container, making it easier to create decoys and more difficult for the enemy to locate and target.[20][21] After the rocket motor launches it to a high enough altitude and speed, the SDB separates from the rocket and the wings deploy, allowing the bomb to glide to its target.[12] The GLSDB carries a smaller warhead, with about one-third less explosives than is delivered with the existing
GMLRS, depending on the type[17] (16 kg (35 lb)[22] vs 23 kg (51 lb)[23]). The company believed it could fill a gap for long-range precision fires while using its smaller warhead to save larger rocket munitions for strategic targets. While typical rockets from
multiple launch rocket systems (MLRS) follow a ballistic trajectory, the rocket-launched SDB can be launched to altitude and glide on a selected trajectory.[24][12] Twelve M26 rockets at a time can be launched from MLRS, six at a time from HIMARS.[25]
Boeing and Saab Group conducted three successful GLSDB tests in February 2015. Unlike traditional artillery weapons, the GLSDB offers 360-degree coverage for high and low angles of attack, flying around terrain to hit targets on the back of mountains, or circling back around to a target behind the launch vehicle. The GLSDB has a range of 150 km (93 mi), or can hit targets 70 km (43 mi) behind the launch vehicle.[26][27][28] According to Saab, it is accurate to within one meter. [29] The weapon can be set to detonate above the ground or with a delay for deep penetration,[13] and is resilient to electronic warfare jamming,[13] which has been used extensively by Russia in eastern Ukraine since March 2014.[30]
In a 2017 demonstration, the GLSDB engaged a moving target at a distance of 100 km (62 mi). The SDB and rocket motor separated at altitude and the bomb used a
semi-active laser (SAL) seeker to track and engage the target.[31] A 2019 test extended this range to 130 km (81 mi) against a target at sea.[11] The laser-guided SDB had previously been tested successfully using targets travelling at 50 miles per hour (80 km/h).[32]
The cost is undisclosed; however the SDB used in GLSDB has a cost to the U.S. military of about $40,000,[16][33] with the accompanying M26 rocket coming from obsolete inventory. The amount to be allocated to each GLSDB of the cost of the "inter-stage adapter", the cost to develop a launcher-container, and the other GLSDB development and production costs of Boeing and Saab is unknown.[34] For comparison purposes, the cost of a single
M31 missile is estimated at $500,000,[17] though this may be the "export price", always higher than the amount charged to the U.S. Army.[35] According to the U.S. Army's budget, it will pay about $168,000 for each GMLRS in 2023.[36][37] The GLSDB is being offered to Ukraine as a long distance alternative to the 300 km (190 mi)
ATACMS missiles,[38][39] which have a price per unit estimated to be well over $1 million.[40] The other long distance alternative is the 250 km (160 mi)
Storm Shadow missiles,[41] each of which is estimated to cost around £2 million ($2.5 million,[42] fiscal year 2023). The U.K. has agreed to supply these to Ukraine.[43] The purpose in developing the weapons was to offer poorer countries the strike capacity of more expensive and advanced air forces. Jim Leary, director of global sales for Boeing, told reporters in 2019: "It really fits across a broader customer set because we’re taking an existing capability, maximizing it and creating an opportunity [for countries] that don't have the ability to have a robust air force."[25]
Use in combat
On 3 February 2023, the United States government announced an aid package for Ukraine as part of assistance during the
2022 Russian invasion of Ukraine that would include the GLSDB, which can be launched out of existing Ukraine-operated HIMARS or MLRS launchers (or out of its own launcher) to hit Russian targets that had been moved out of GMLRS range. The GLSDB almost doubles the range that Ukraine could previously target with these launchers (150 km (93 mi) vs 85 km (53 mi) with GMLRS).[44][18] This "will put all of Russia's supply lines in the east of [Ukraine] within reach, as well as part of Russian-occupied Crimea", according to Reuters.[45]
According to Saab the glider will be more difficult to intercept since it can be programmed to approach a target from any direction, and from a variety of angles.[17] Unlike conventional artillery that follows a predictable path from launch to destination, the wings and navigation ability of the GLSDB allow it to evade obstacles and anti-air defenses by steering around them, even approaching from the target’s rear.[46][12] Also, because the GLSDB is a glider it has little
IR signature, making it a poor target for
IR homing missiles such as
MANPADS.[47] This will mark the weapon's first export and use in combat. When originally announced it was estimated that it might take up to nine months to develop a ground-launched version but Boeing announced that it could possibly be delivered as early as spring of 2023.[48][49][50][51]
On 30 March, Taiwanese media reported that Taiwan has deferred purchasing GLSDB so that it could be sent to Ukraine. This was done at the request of the United States. The weapon has only entered "initial mass production stage" in 2023.[52] The narrowest part of the
Taiwan Strait is 130 km (81 mi; 70 nmi) wide,[53] within the range of the GLSDB and making it more difficult for the
PLA to assemble an amphibious force to invade Taiwan.[54]
On 22 June,
Laura Cooper told Congress that because of delays caused by development and production issues, Ukraine would receive GLSDB missiles "no earlier than autumn".[38]
On 14 October 2023, Boeing said that the GLSDB will be delivered to Ukraine by winter.[55] On 30 November, it was reported that the delivery had been postponed to early 2024.[56] On 30 January 2024,
Politico reported that the missiles could be deployed as soon as the following day.[57] On 14 February 2024, Russian media published footage on what looks to be a GLSDB tail wreckage, reportedly found near
Kreminna, Luhansk Oblast.[58][59] On 26 March 2024, a GLSDB was used to strike a house, in Chernyanka, Kherson, where Russian UAV operators were based.[60] Ukrainian forces also destroyed a Russia
2S9 Nona 120 mm mortar and the “burning” of another in Zaporizhzhia.[61]
In April 2024, a U.S. defense official remarked that the combat performance had been disappointing: due to Russian jamming and deficiencies in tactics, techniques, and procedures "it just didn't work". The War Zone wasn't certain that this was weapon system referred to.
Under Secretary of Defense for Acquisition and Sustainment, William LaPlante, could have referred also to the
APKWS II or another undisclosed weapon system. The Under Secretary also noted that the production and testing of the weapon was "raced and (they) did it as fast as they could". He also referred to multiple reasons, including tactics, doctrine and "electromagnetic interference" as being issues.[62]