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OSMP Collection

Ukraine and Russia 2022–2026

On February 24, 2022, Russia launched a full-scale invasion of Ukraine, involving military forces aimed at capturing most major cities, including the capital, Kyiv. It became the largest conflict in Europe since World War II, and about a quarter of Ukraine’s territory came under Russian control. But Russian troops were eventually pushed back from Kyiv. Later that year, a Ukrainian counteroffensive led to the liberation of a number of key regions, including the second largest city, Kharkiv.

After the initial invasion and counteroffensive, the war was characterised by relatively stable and well-fortified front lines, an atypical trend for 21st-century warfare. Both sides used significant amounts of heavy weapons, including artillery and mortars. UAVs were also widely used, including so-called kamikaze drones—single-use strike drones. Airspace remains contested, so although the use of aerial munitions is frequent, it is less common than in other modern conflicts.

Although Russian military actions were recorded throughout Ukraine, the most intense fighting took place in the eastern regions, near the border with Russia. As of May 2024, Ukraine’s hopes of a breakthrough seemed to have faded due to the numerical and military superiority of Russian forces in many places.

545

Images

2

Countries

127

Munition Models

Methodology

This collection contains all images from the OSMP archive from Ukraine and Russia for the period 2022–2026. It features munitions allegedly used by Russian and Ukrainian forces.

Models in collection

AIM-120 Series AIM-120C-8 POM-2 PFM-1 series POM-3 Lancet series UMPK kit Geran-5 3OF39 Krasnopol Shahed-101/107 series Patriot PAC-3 Series Patriot PAC-3 CRI Kh-69 series Shahed-238 (Geran-3) series 9M7 Iskander series Patriot PAC-3 MSE OF56 OF56-1 RBK-500 ShOAB-0.5 FAB-3000 M-54 ADM-160B MALD FAB-500 M62 RBK-500 series 9M317 Series Storm Shadow/SCALP-EG APKWS series Hydra-70 series 9M38 series R-60 GMLRS M30 Kh-101 series M77/M101 Gerbera series 9M33 series Osa series 9M330/9M331 Kh-22 series Kh-59 series Kh-59MK2 AGM-88 HARM and AARGM series 5V55 (S-300)/48N6 (S-400) BK18M PTM-1 series Shahed-136 series 9M55 Smerch series Kh-47M2 Kinzhal series Shahed-131 series MAM-L KN-23/KN-24/Hwasong-11 series JVA 1571 9M723K1 Iskander 57E6 Pantsir 3M22 Zircon series M48 R-77 9M55K Smerch series 9M27 Uragan series Kh-55 Series AASM-250 HAMMER series 9M22S Grad OF5 3M-14 / 3M-54 Kalibr series OF-843B 5V55 (S-300) 3M-14 Kalibr series OF59 OFZAB-500 M712 Copperhead 9M54 Smerch series 9M27K Uragan series 9M22 Grad series MGM-140 ATACMS series 9M27K3 Shahed-131/136 series 9M79 Tochka series M1 9M79K Tochka series R-73 9M28S Grad JDAM-ER kit MK 82 series DM 105 9M27K Uragan 9M544 OF-25 3OF22 M982 Excalibur 9M22U Grad S-8 R-27 OF-482M S-25-O FGM-148 Javelin missile Grom O-832 series M927 M107 OF-843 J-M49A2 O-832D P1A1 OF-462 3M-54 Kalibr series S-832S F-843 OF-540 OF49 D-5 HE ER FB-BB FAB-500Sh series S6 3VOF32 Kh-31 series 9M27K2 S-843 PG-7VL OFAB-500 ShR MO.1.01.04 series F-864 9M120 S-5 series NLAW Missile OF-462Zh OFAB-250 ShN VOF-463M 9M83 series
Analyst Note:
This image shows a Lancet-series one-way attack (OWA) UAV. It strongly resembles the Z-51E made by Zala Aerospace, a Russian manufacturer, although this cannot be confirmed from the available image. The Lancet series of drones can carry a variety of different warheads, including blast, fragmentation, thermobaric, and High Explosive Anti-Tank (HEAT). (ARES)
Analyst Note:
Positive identification of the model of air-delivered bomb to which the UMPK kit is fitted cannot be made from the source imagery. Based on the size of the UMPK and historical use in the area, it is likely an OFAB-250-270 model. (ARES)
Analyst Note:
It is reported that this jet engine was recovered from the wreckage of a Geran-5 one-way attack (OWA) UAV. It is most likely a Telefly TF-TJ2000A model, manufactured by Telefly Telecommunications Company in China. It is reported that the TF-TJ2000A engine produces 200 kg of thrust; this is a significant increase in thrust compared to the Telefly JT80 engine used on the Shahed-238 (Geran-3) UAV, which produces approximately 80 kg of thrust. (ARES)
Analyst Note:
This image shows the remains of a Russian Geran-5 drone. These drones are reported to be roughly 6 meters long and have a wingspan of up to 5.5 meters. They are fitted with a warhead weighing approximately 90 kg and have a range of about 1,000 km. (ARES)
Analyst Note:
The 3OF39 Krasnopol is a laser-guided, rocket-assisted 152 mm tank gun projectile carrying a high explosive fragmentation (HE-FRAG) warhead. The round is built and shipped with a cover over the optical sensor. This protective cover is fitted with a T-90 mechanical time delay fuze. Once fired, the T-90 fuze will initiate after a pre-selected time and will jettison the protective cover, exposing the optical sensor in the nose. The internal impact fuze, which can be set for immediate or delayed initiation, is then responsible for detonating the projectile. (ARES)
Analyst Note:
This image shows the remains of the attitude control section of either a PAC-3 CRI or PAC-3 MSE missile. This section contains the attitude control motors, used in combination with control fins to guide and adjust the missiles on its way to the target. It is difficult to determine which of the two models this wreckage belongs to due the similarities of this section in both missiles and the absence of other distinctive components. (ARES)
Analyst Note:
This image shows the remnants of a PAC-3 Cost Reduction Initiative (CRI) missile. The PAC-3 family of missiles are hit-to-kill interceptors that defend against incoming ballistic missiles, cruise missiles, aircraft, and other targets primarily by using kinetic impact. However, it is important to note that these missiles contain a high explosive fragmentation (HE-FRAG) “lethality enhancer” warhead. These warheads are much smaller than what would normally be expected on a surface-to-air missile of this size, but still present a hazard if it fails to function as designed. (ARES)
Analyst Note:
Shown is the Russian Kh-69 (marked in Cyrillic: “Х-69”) cruise missile which was debuted at a Russian arms show in August 2022, and entered into active military service the following year. The Kh-69 was reportedly first used in combat in February 2024, engaging Ukrainian targets. The more compact design when compared with previous Russian missiles results in a smaller radar signature, which is further reduced by the trapezoidal form factor. The Kh-69 is classed by the Russian military as a ‘stealth cruise missile’ and carries either a penetrator or cluster (submunitions) warhead. (ARES)
Analyst Note:
This image shows 122 mm high explosive (HE) artillery gun projectiles manufactured in three different states, L–R: Iran, North Korea, and Russia. Whilst these examples are distinct from one another—particularly in coloration, as well as the presence or absence of paint over the driving band and bourrelet—this is not always the case, and a combination of physical features and markings should be assessed before identification is made. (ARES)
Analyst Note:
The UMPK guidance package is a ‘bolt-on’ kit that can be fitted to unguided air-delivered bombs to convert them to guided munitions. The UMPK kit also greatly extends the range of the munition to which it is fitted, allowing aircraft to strike from beyond the range of many air-defence systems. Currently only Russia manufacturers and uses these kits. (ARES)
Analyst Note:
This image shows a russian air-delivered bomb fitted with a UMPK guidance kit. Not enough of the bomb is visible to positively identify the model, but it is most likely an OFAB-250-270 based on what can be seen of the tail section. (ARES)
Analyst Note:
This Russian air-delivered cluster bomb is marked with a threatening message directed at the French people: «Français! Changer la politique du président dans le pays, sinon ces bombes vont changer le lieu d'atterrissage!» (“French people! Change the president’s policy in the country, otherwise these bombs will change their landing site!”). (ARES)
Analyst Note:
This sheet-metal body component is marked with a manufacturer’s CAGE Code (“MFR-59518”) which indicates it was produced by GlenDee Corp. of Moorpark, California, which does business as Metalagraphics, Inc. (MGI). (ARES)
Analyst Note:
Moog Inc.—headquartered in East Aurora, New York, as marked on this munitions remnant—describes itself as a “worldwide designer, manufacturer, and integrator of precision control components and systems”. Moog supplies actuator and control components to the prime contractor on the Miniature Air-Launched Decoy (MALD) programme, Raytheon. (ARES)
Analyst Note:
This image shows a Hydra-70 rocket fitted with an Advanced Precision Kill Weapon System (APKWS) guidance kit, converting it into a guided missile. In this case, the missile features an M151 high explosive (HE) warhead fitted with either an M427 or M423 point-detonating (PD) fuze. The rocket motor model cannot be determined from this source alone, but it is most likely to be a MK 66-series motor. The launcher appears to be a LAND-LGR4 model produced by Arnold Defense. (ARES)
Analyst Note:
Positive identification of this surface-to-air missile cannot be made based on the imagery in the source. The items highlighted in this image are most likely the remains of either a 9M38- or 9M317-series missile, based on fin construction and their size relative to the individual posing in the foreground. These two missiles are close in design and function, and are predominantly fired from the Buk series of SAM systems. (ARES)
Analyst Note:
This image represents the first documented instance of a Shahed-series UAV carrying an R-60 air-to-air missile. This appears to add a new capability to the Shahed, enabling it to target enemy aircraft. Arming UAVs to counter interception and engage alternative targets is an emergent trend. Previously, unmanned surface vessels (USVs) employed by the Ukrainian Armed Forces have been observed carrying R-73 air-to-air missiles, for example. (ARES)
Analyst Note:
This image shows the rear section of a Hydra-70 rocket. The Hydra-70 uses the MK 66 series of rocket motors, visible here, but can be fitted with at least 11 different warheads. They can also be fitted with the Advanced Precision Kill Weapon System (APKWS) ‘bolt-on’ guidance kit, converting an unguided rocket into a guided missile. From the available imagery, it is not clear with which warhead or guidance section this munition may have been fitted. (ARES)
Analyst Note:
This munition remnant is marked with a manufacturer’s CAGE Code (“MFR-05DN8”) which indicates it was produced by Klune Industries. Klune Industries is a sub-contractor on the GMLRS contract. (ARES)
Analyst Note:
This munition remnant is marked with a manufacturer’s CAGE Code (“MFR-62313”) which indicates it was produced by Lockheed Martin. Lockheed Martin is the primary contractor that makes GMLRS missiles. (ARES)
Analyst Note:
This image shows a remnant from an American M30 Guided Multiple Launch Rocket System(GMLRS) missile, which carries M77/M101 submunitions. The yellow diamond markings indicate a payload of explosive submunitions. (ARES)
Analyst Note:
This munition remnant is marked with a manufacturer’s CAGE Code (“MFR-57413”) which indicates it was produced by the Maine Machine Products Company, a sub-contractor on the GMLRS contract. (ARES)
Analyst Note:
This image shows a remnant of the TRDD-50A(M) (ТРДД-50А(M)) turbojet engine, which powers Kh-101 and Kh-59M missiles. Other models of Russian cruise missiles are known to use other variants of the TRDD-50. (ARES)
Analyst Note:
This photo shows some of the lithium-ion power banks found within a Gerbera UAV. These are used to power the onboard avionics, control surfaces, communications hardware, camera, and other components. The quantity and type of batteries fitted to the Gerbera will often vary based on the role for which the UAV has been configured—one-way attack (OWA; i.e., a ‘sacrificial’ munition), reconnaissance, signal relay, or decoy—and which specific hardware has been installed to effect this mission. (ARES)
Analyst Note:
This photo shows the fuel bladder of a Gerbera UAV, which still contains some fuel. It is likely that a bladder is used—rather than a rigid tank—to save on both weight and cost. Some variants of the Gerbera have been observed to be fitted with a second bladder in the forward section of the fuselage, serving to extend the UAV’s range. (ARES)
Analyst Note:
The DLE60 two-stroke petrol (gasoline) engine pictured here is the standard engine found on Gerbera UAVs. It is produced by the Chinese company Mile Haoxiang Technology Co., Ltd. and marketed specifically for use in UAVs. Although the Gerbera is manufactured in Russia, the engine and many other key components continue to be supplied from Chinese sources. (ARES)
Analyst Note:
This image shows a Controlled Reception Pattern Antennas (CRPA) unit installed on a Gerbera-series UAV. CRPAs are specialised antenna arrays that help protect GPS receivers from interference, spoofing, and jamming. This particular model, featuring four antennas, was first observed on the Shahed-136 UAV and has since been routinely seen fitted to Gerbera-series UAVs. An alternative array, with six antenna elements, has also been observed, reflecting the varied and ever-evolving state of electronic warfare in Ukraine. (ARES)
Analyst Note:
A Gerbera-series UAV is pictured here being carried by just two Ukrainian soldiers. This highlights the Gerbera’s lightweight design—the airframe is mostly constructed from Styrofoam and wood, which saves on both weight and cost. This particular example does not bear signs of significant damage, suggesting that it either malfunctioned or was brought down by EW and crashed. (ARES)
Analyst Note:
This image shows an A40 Pro camera, manufactured by the Chinese company Viewpro UAV and design specifically for use in UAVs. The black box to the right of the camera is the control box which manages video output, camera control, and power. The manufacturer claims this model has a 40× optical zoom, AI detection and tracking, and 3-axis gyro-stabilisation. The company further claims that it can customise the onboard AI recognition based on “target characteristics” provided by the client. Numerous Gerberas fitted with this model of camera are known to have been recovered by Ukrainian forces, although it is by no means the only camera model in use. (ARES)
Analyst Note:
This image shows the back surface of a wireless communications module contained within a downed Gerbera UAV. Although labeled as an HX-50 model designed for fixed locations, Ukrainian military analysis indicates this is an XK-F358 mesh-network module more suitable for use in UAVs. See OSMP1646 for further details. (ARES)
Analyst Note:
This image shows the front and interior surfaces of a wireless communications module recovered from a downed Gerbera UAV. Although labelled as an HX-50 industrial wireless modem (compatible with WiFi and 5G/4G networks and designed for fixed locations), analysis by Ukrainian military sources indicates that this component is, in fact, an XK-F358 mesh-network module which offers significantly more capabilities. Manufactured and sold by Shenzhen Xingkai Technology Co., Ltd., these modules are designed for, amongst other things, use in robots and unmanned vehicles. Gerbera UAVs have been found operating on a wide variety of frequencies and networks, and this type of module is well-suited to this use. (ARES)
Analyst Note:
Pictured is a navigation/GPS module recovered from a downed Gerbera UAV. This particular model is used with the 4-antenna CRPA module seen in OSMP1648. The four RX ports on the bottom are normally directly connected to the CRPA (antenna) module, with other connections made to the UAV’s flight controller and power sources. Some Gerberas have been recovered with CRPA modules bearing a different number of antennas; different navigation modules have been observed on these. (ARES)
Analyst Note:
This munition remnant is marked with a manufacturer’s CAGE Code (“MFR CAGE CODE: 62313”) which indicates it was produced by Lockheed Martin. Lockheed Martin is the primary contractor that makes GMLRS missiles. (ARES)
Analyst Note:
This remnant shows a munition component marked with the CAGE Code for a sub-contractor who produced part of a larger munition. “64344” is the code for Unique Electronics Inc., a known sub-contractor working on Lockheed Martin’s GMLRS contract. One of the parts they make is the “CABLE ASSEMBLY W459“, as seen in this image. (ARES)
Analyst Note:
This image shows the three lenses that form the new version of the Kh-101 Digital Scene Matching Area Correlator (DSMAC) system. (The older version only had a single lens.) DSMAC systems take digital images of the ground as the missile passes overhead, and then compare those images to pre-captured images stored in the onboard memory. The DSMAC corrects the flight path as needed based on differences between the two sets of images. (ARES)
Analyst Note:
This image shows the second warhead present in some variants of the Kh-101 cruise missile. The inclusion of this additional warhead requires a smaller fuel tank in the missile, offering increased explosive weight in exchange for a reduced maximum range. (ARES)
Analyst Note:
This image shows three sets of three PTM-1 series scatterable anti-vehicle mines taped together. While these mines have likely been repurposed from their original delivery munition to be delivered via UAV, this cannot be confirmed based off this image alone. (ARES)
Analyst Note:
This image shows four PFM-1 series anti-personnel landmines retained by a release mechanism to enable deployment via UAV. Ordinarily, PFM-1 series and other ‘scatterable mines’ are deployed via carrier munitions or dedicated mine-dispensing devices. In Ukraine and other conflicts, these mines have often been removed from their original carrier munitions in order that they may be delivered via UAV. (ARES)
Analyst Note:
This image shows three different warheads developed by Russia for the Shahed-136/Geran-2 one-way attack (OWA) unmanned aerial vehicle (UAV), each of which differ from the original warhead designed by Iran for the Shahed-136. Left: A thermobaric explosive warhead; Middle: TBBCh-50M, a thermobaric explosive warhead; Right: OFZBCh-50, a high explosive warhead with an incendiary effect. Each of these warheads is also fitted with a fragmentation liner to increase the fragmentation effect generated when the warhead detonates. Some of the fragmentation liners may contain zirconium, a metal which is ignited when the warhead detonates, providing an additional incendiary effect. (ARES)
Analyst Note:
This image shows the copper cone of the shaped charge located at the front of the warhead fitted to a Shahed-131. The Ukrainian armed forces have recorded that the cone measures 111 mm in diameter and 162 mm in depth. The warhead is lined with cubic pre-formed fragments of 7 mm in diameter. The explosive content of the warhead is estimated to be between 10 and 15 kg. (ARES)
Analyst Note:
This image shows a remnant of the aft motor section, which includes the venturi nozzle, of a North Korean KN-23/KN-24/Hwasong-11 series missile. The KN-23/KN-24/Hwasong-11 has a generally similar appearance to the Russian 9M7 ‘Iskander’ series of ballistic missiles, but has differences in performance and in some aspects of the construction. (ARES)
Analyst Note:
This image shows the BSF-50, one of several warheads developed by Russia for the Shahed-136/Geran-2 to replace the original Shahed-136 warhead designed by Iran. The BSF-50 is a high explosive warhead with a fragmentation effect. (ARES)
Analyst Note:
Depicted here is the MD-550 motor of a Shahed-136/Geran-2. This image was presented by Ukrainian President Zelenskyy as a fragment of the drone that reportedly hit the Chernobyl Nuclear Power Plant’s New Safe Confinement shelter. (ARES)
Analyst Note:
Two R-77 air-to-air missiles (NATO reporting name: AA-12 Adder) are carried in this photograph by a Russian Aerospace Forces Sukhoi Su-35 fighter aircraft. Key markings, including the aircraft’s bort number (a coloured numeral that acts as a unit or base identifier), have been digitally obscured. (ARES)
Analyst Note:
The Armement Air-Sol Modulaire (AASM; ‘Modular Air-to-Ground Armament’) family of French bolt-on guidance kits are fitted to air-delivered bombs of various sizes in a similar fashion to American JDAM kits. In some marketing materials, the acronym HAMMER is used, standing for ‘Highly Agile Modular Munition Extended Range’. This refers, in part, to the rocket boosters fitted to munitions in the family to extend their effective range. (ARES)
Analyst Note:
In this photo, a Ukrainian Sukhoi Su-25 ground-attack aircraft from the 299th Tactical Aviation Brigade, with the bort number ‘Blue 28’, is seen carrying an AASM-250 guided air-delivered bomb under its left wing. Available imagery shows that the AASM-250 has also been fitted to Mikoyan MiG-29 fighter aircraft, and can likely be carried by the Sukhoi Su-27 as well. (ARES)
Analyst Note:
This image shows a 9M22S rocket with some of its unfunctioned payload of 180 ML-5 incendiary elements. Each ML-5 is a hexagonal prism formed from a hollow shell of magnesium that is filled with an incendiary composition. These elements are ignited by the ejection charge of the rocket’s warhead upon functioning. Two fuzes are also visible at the bottom of the image, immediately above and below the ruler. (ARES)
2 Analyst Notes:
This image shows one of several possible warhead variants that can be carried by the Shahed-136/Geran-2 one-way attack (OWA) UAV. The Shahed-136/Geran-2 (and the smaller Shahed-131/Geran-1) has been documented carrying shaped-charge warheads, penetrator warheads, and multi-function warheads. Due to the various warheads that can be carried by a Shahed/Geran drone, the functional use cannot be determined without the warhead being visible. In this case, the munition was fitted with a TBBCh-50M warhead that contains a thermobaric explosive composition with an additional fragmentation effect. (ARES)
Analyst Note:
Shahed-131/Geran-1 and Shahed-136/Geran-2 one-way-attack (OWA) UAVs can be fitted with on of a variety of warheads with different functional uses. The specific type carried by each UAV cannot be determined unless the munition has been damaged in such a way as to reveal the warhead, such as in this case. This image shows the cone of the shaped charge, indicating that this Shahed-1/Geran-1 carries a warhead with a penetrating or anti-armour effect. This warhead has been documented with 18 additional liners for enhanced anti-armour effect, and in some cases has been fitted with fragmentation liners for an enhanced anti-personnel effect. (ARES)
Analyst Note:
The M712 ‘Copperhead’ is a laser-guided 155 mm artillery gun projectile carrying a high explosive anti-tank (HEAT) warhead designed to engage armoured vehicles. The Copperhead was developed in the United States in the 1970s, and saw limited use during Operation Desert Storm. The M712 is is pictured here inside its shipping container, and the slots for the enclosed, deployable (‘pop-out’) wings and fins are visible. The M712 has two operational modes: a ballistic mode that follows a gun’s ballistic trajectory like a traditional artillery projectile, and a glide mode, which follows a longer and flatter trajectory. The preferred mode is set by the artillery crew before firing. (ARES)
Analyst Note:
This 9M27K-series surface-to-surface cargo rocket is loaded with either 9N210 or 9N235 high explosive fragmentation (HE-FRAG) submunitions. These models are nearly identical in construction, differing primarily in the nature of the pre-formed fragments they carry. (ARES)
Analyst Note:
This image shows part of the warhead section of an MGM-140 Army Tactical Missile System (ATACMS) series tactical ballistic missile. This is the top of the warhead section, where it connects to the guidance section. A data plate is visible, giving information about the manufacturer (“Lockheed Martin Vought Systems”) and identifying this specific part (“WARHEAD, GUIDED MISSILE. HIGH EXPLOSIVE”. (ARES)
Analyst Note:
The internal components of large, complex munitions often feature markings to aid in assembly, supply chain oversight, and quality assurance. In this case, a data plate marked with the name of the manufacturer (“MBDA FRANCE”) has been affixed to one of the rear control fins (“EQ, VENTRAL, FIN TIP”) of the missile. The NATO Stock Number (NSN) is also visible. (ARES)
Analyst Note:
This image shows an actuator from a Storm Shadow-series missile. Actuators are components of guided munitions that are most often used to move control surfaces (e.g., fins and wings), enabling the munition to adjust its course in-flight in response to guidance commands. In this case, the component is fitted with a ‘data plate’ that indicates it was manufactured by MBDA France. (ARES)
Analyst Note:
This image shows a Microturbo TRI 60-30 turbojet engine from a Storm Shadow-series air-launched cruise missile. Further remnants of the rear of the missile are also visible, including one of the rear control fins. The Storm Shadow has a range of more than 250 kilometres. (ARES)
Analyst Note:
This image shows the rear of the second stage of the penetrator warhead (also called a ‘follow-through’ warhead) of the Bomb Royal Ordnance Augmented Charge (BROACH) multi-stage warhead system present in the Storm Shadow/SCALP-EG missile. The cylindrical object in the centre of the warhead (with a data plate marked “THALES”) is the fuze. (ARES)
Analyst Note:
This image shows the first stage of the Bomb Royal Ordnance Augmented Charge (BROACH) multi-stage warhead used by the Storm Shadow/SCALP-EG missile. The BROACH uses a shaped-charge warhead (seen here) as its first stage, to help penetrate hardened targets, whilst the second stage comprises a conventional high explosive penetrator warhead (also called a ‘follow-through’ warhead) (ARES).
Analyst Note:
The remnant at left in this image is the second stage, or penetrator warhead, of the Bomb Royal Ordnance Augmented Charge (BROACH) multi-stage warhead as used in the Storm Shadow/SCALP-EG air-launched cruise missile. In this case, it has failed to function as intended. (ARES)
Analyst Note:
This image shows part of a heavy-duty suspension lug associated with the Storm Shadow air-launched cruise missile. This is made clear from dot-peened markings which include “STORM SHADOW USE ONLY” and identifiers such as a NATO Stock Number (NSN). (ARES)
Analyst Note:
The munitions remnant on the left of this image is part of a suspension lug associated with the Storm Shadow air-launched cruise missile, which is used to attach the munition to an aircraft. This component is of heavy construction, and as such often survives the missile’s functioning intact. This photograph purports to show remnants recovered from a Storm Shadow missile that was fired by Ukrainian forces into Russian territory, but this claim cannot be verified from the image alone. (ARES)
Analyst Note:
This image shows a rocket motor section from an MGM-140 ATACMS series surface-to-surface ballistic missile. The warhead section of the MGM-140 series missiles separate from the rocket motor before functioning, resulting in the rocket motor often being found relatively intact near the target. The MGM-140 series missiles use the same rocket motor, preventing a positive identification of the variant based off the rocket motor alone, unless the variant markings are visible. (ARES)
Analyst Note:
This remnant of an MGM-140 Army Tactical Missile System (ATACMS) surface-to-surface ballistic missile is marked to indicate it is the MGM-140A variant, a cluster munition which carries 950 M74 multi-purpose submunitions. Submunitions of this type are sometimes referred to by the acronym ‘anti-personnel and anti‑materiel (APAM)’. Additional markings indicate a manufacturing date (“10/96”; October 1996), a serial number (“411240”), and other information. (ARES)
Analyst Note:
The 9M27K3 surface-to-surface rocket is fitted with the 9N128K3 cargo warhead (seen here). This warhead carries a payload of 312 PFM-1 or PFM-1S scatterable anti-personnel landmines. (ARES)
Analyst Note:
The 9M22S is essentially the ‘full-sized’ version of the shorter 9M28S surface-to-surface rocket previously recorded in the OSMP. Both rockets carry the same 9N510 incendiary warhead, but differ in the length of their rocket motor sections, and thus range. (ARES)
Analyst Note:
The 9Н123К (9N123K) cargo warhead is delivered by a 9М79К (9M79K) series surface-to-surface guided missile. This cluster munition carries fifty 9Н24 (9N24) high explosive fragmentation (HE-FRAG) submunitions, and is launched from the 9К79 Tochka series of tactical ballistic missile launchers. (ARES)
Analyst Note:
A 9N24 submunition is visible to the left of the 9N123K warhead in this image. This high explosive fragmentation (HE-FRAG) submunition is marked to indicate it was produced in 1989 and filled with A-IX-2 explosive composition. (ARES)
Analyst Note:
The 9M28S surface-to-surface unguided rocket carries the 9N510 warhead, which disperses burning thermite-type incendiary elements over a wide area upon functioning. This munition is designed to start fires in target areas vulnerable to incendiary attack, including forests, ammunition dumps, and fuel storage sites. (ARES)
Analyst Note:
This 9M27K-series surface-to-surface cargo rocket is carrying a payload of 9N210 or 9N235 high explosive fragmentation (HE-FRAG) submunitions. These submunitions are difficult to distinguish unless their external markings are visible, or a close examination is made. (ARES)
2 Analyst Notes:
The JDAM-ER in this photograph is affixed to an unusual pylon thought to be of Ukrainian design, which allows the Western munition to be carried by the Soviet-designed Mikoyan MiG-29 and Sukhoi Su-27 fighter aircraft in service with the Ukrainian Air Force (a MiG-29 is pictured here). (ARES)
Analyst Note:
The MGM-140 Army Tactical Missile System (ATACMS) series includes variants with a variety of different payloads, including submunitions and unitary high explosive (HE) warheads. The number of submunitions carried and effective ranges also vary. Ukraine has reportedly received the MGM-140A and MGM-140B variants, which are externally visually identical and must usually be distinguished by markings. The MGM-140A carries 950 M74 submunitions, with an effective range of 165 km, while the MGM-140B carries only 300 M74 submunitions but has a longer effective range of 300 km. (ARES)
Analyst Note:
The Joint Direct Attack Munition – Extended Range (JDAM-ER) marries the JDAM guidance kit to a ‘glide bomb’ wing kit developed by the Australian Defence Force, offering a munition with at least three times the range of a standard GBU-38 500-pound-class guided aerial bomb. (ARES)
Analyst Note:
The remnants shown in these linked images have been falsely identified in Russian sources as chemical munitions. This image clearly exhibits the marking “NBK DM 1216”—the ‘NBK’ standing for the German Nebelkörper (‘smoke element’)—identifying this as one of four DM 1216 hexachloroethane/zinc (HC) smoke elements dispensed by the German DM 105 155 mm artillery gun projectile. Video of the incident shows all four elements being ejected from the base of the projectile in flight. (ARES)
Analyst Note:
Once fired, four canards will deploy from the forward (ogival) section of these M982 Excalibur guided artillery projectiles. The narrow-shaped ports through which the canards deploy are a good indicator of a guided or extended-range artillery projectile. (ARES)
Analyst Note:
Many guided (or otherwise complex) munitions like this one are marked with additional information on individual assemblies or components. This can include information on sub-contractors that produced or integrated specific parts of a munition. (ARES)
Analyst Note:
In this image, a Ukrainian soldier is using an M1155 Enhanced Portable Inductive Artillery Fuze Setter (EPIAFS) to input the target coordinates and set functioning parameters for an M982 Excalibur guided artillery projectile. (ARES)
Analyst Note:
122 mm ‘Grad’ rockets can be fired from a variety of launchers and even in improvised ways. The most common is the BM-21 launcher and its later derivatives, but many other portable or vehicle-mounted launchers have been used around the world. Craft-produced examples—ranging from simple rails to more complex designs comparable to factory made launchers—are also common. In some cases, Grad rockets are even fired whilst supported by a crude arrangement of logs, bricks, or rocks. (ARES)
Analyst Note:
These S-25-O air-to-surface rockets are each loaded into a single-barrelled O-25 rocket launcher (sometimes called a 'launch tube' or 'rocket pod') that is affixed to an aircraft hardpoint. The over-calibre high explosive fragmentation warhead (of 420 mm in diameter) protrudes from the front of the tube. (ARES)
Analyst Note:
Whereas many cartridges are of the 'fixed' type—with the propellant charge contained entirely within the cartridge, and the cartridge case crimped around the projectile—the OF-540 artillery gun projectile is a type of 'semi-fixed' ammunition. A round of semi-fixed ammunition is separated into two groups of components: the projectile and fuze; and the cartridge case, primer, and one or more propellant charges. These two component groups are typically combined at the time of loading the gun, or shortly beforehand. The majority of ammunition fired by artillery systems is either semi-fixed or 'separate loading' (see Glossary). (ARES)
Analyst Note:
This image shows a 9M27K2 cargo rocket as well as several partially ejected PTM-1 anti-vehicle landmines. This 9M27K variant is fitted with the 9N128K2 payload section which carries and dispenses 24 PTM-1 mines. Other variants carry different mines or submunitions. (ARES)
Analyst Note:
The Next-generation Light Anti-tank Weapon (NLAW) uses an uncommon form of guidance known as predicted line-of-sight (PLOS). PLOS guidance calculates the anticipated position of a moving target prior to launch, with the munition using inertial guidance to fly to the projected impact point. This fire-and-forget technique allows the operator to move positions immediately after firing, and is generally cheaper than other fire-and-forget guidance types. (ARES)
Analyst Note:
This image shows a remnant of the control section from a 9M83-series surface-to-air missile. The 9M83 is launched by the Russian S-300V air defence system. The system and its missile have received the NATO designation ‘SA-12A Gladiator’. Missiles launched by air defence systems are often referred to by the name of the respective complete platform, rather than the specific model of the missile itself. For example, ‘S-300’ or ‘S-300V’ rather than ‘9M83’. (ARES)