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Country or territory where the image was reported

Reported Location (50)

Year the image is reported to have been taken

Year (21)

Classification groups of key explosive munitions used in conflicts

Munition Category (8)

The impact or effect the munition is intended to have

Functional use (10)

The specific model of munition pictured

Tentative Model (383)

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The external organisation that documented the munition

Research Organisation (6)

Colour of the munition pictured

Base Colour (12)

Colour of all, or some, of the markings on the munition

Marking Colour (11)

Language or script of the marking on a munition

Marking Script (9)

Condition of the munition pictured

Condition (6)

Key features defining the operation mechanisms of a projectile

Mechanical Feature (10)

Whether a munition is guided or unguided

Guidance (2)

Where the munition is launched from and what it targets

Domain (7)

The type of fins visible on the munition

Fins Characteristic (6)

The nominal diameter of a projectile. For most modern munitions, this is expressed in millimetres (e.g. 82 mm mortar projectile), but older artillery gun projectiles may be described in inches.

Calibre (75)

Weight class of the aerial bomb pictured

Weight Class (14)

401–500 of 1,741
OSMP1683
Analyst Note:
The munition depicted in this image is a type of aerodynamically optimised artillery projectile, in this case 155 mm in calibre, known as an ‘Extended Range Full-Bore (ERFB)’ design. This example is a cargo projectile fitted with a base-bleed (BB) base unit to further extend its range. This configuration is designated NR269, and reportedly contains 56 M46 dual-purpose (anti-personnel/anti-armour) submunitions. (ARES)
OSMP1678
Analyst Note:
In this case, the tentative identification of this munition is possible based on an analysis of its silhouette, particularly the distinctive detachable warhead compartment that can be seen hanging from the base of the munition's body. In many cases, such an identification technique would not be possible to apply with confidence. (ARES)
OSMP1818
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)
OSMP1686
Analyst Note:
This image shows the base of a 155 mm Extended Range Full-Bore (ERFB) projectile, fitted with either a base-bleed (BB) or a base-bleed, rocket-assisted (BB/RA) base unit. Although munitions of this type are capable of carrying submunitions and this image is associated with an incident about which claims of cluster munitions use have been made, there is not enough of the projectile visible in the source images to determine what type of payload was carried by this particular round. (ARES)
OSMP1710
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)
OSMP1715
Analyst Note:
This image shows the venturi and tailfin assembly from a 57 mm S-5 series rocket. The S-5 series of rockets are commonly used around the world in a variety of roles, including air-to-surface and surface-to-surface. Unfortunately, from this image alone the specific model and country of origin cannot be determined. (ARES)
OSMP1666
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)
OSMP1667
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)
OSMP1758
Analyst Note:
This image shows an M49-series 60 mm high explosive (HE) mortar projectile, or a copy thereof. Due to the state of the round the available imagery, the specific model or variant cannot be determined. The fuze is also not clearly visible. Most M49 mortar projectiles use an M525, M717, M935, or similar point-detonating (PD) fuze. (ARES)
OSMP1668
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)
OSMP1671
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)
OSMP1764
Analyst Note:
This image shows several 107 mm rockets of the Type 63 pattern. Whilst developed by China, munitions of this design are now produced by several countries around the world, including Iran, North Korea, and Sudan. The state-owned Military Industry Corporation (MIC) of Sudan produces a copy of the Type 63 known as the TAKA-01, TAKA-1, or TAKA-107. (ARES)
OSMP1763
Analyst Note:
Based on the tail-fin assembly design and relative size, the item pictured appears to be a 122 mm rocket. However, it is unclear if this image shows a Russian 9M22-series (‘Grad’) rocket, a Chinese Type 81 rocket, or a similar variant from a different country of origin. (ARES)
OSMP1756
Analyst Note:
This images appears to show the remnants of a 122 mm rocket. It is unclear what the country of origin is, but it is most likely a 9M22-series or Type 81-series rocket. (ARES)
OSMP1794
2 Analyst Notes:
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)
OSMP878
2 Analyst Notes:
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)
OSMP1381
Analyst Note:
This image shows the damaged rocket motor section of a ballistic missile that was fired by the Houthis in Yemen towards Israel and likely intercepted. The Houthis employ ballistic missiles that are supplied by Iran, and given different names. In Houthi service, the Iranian Kheibar Shekan missile is known as the Hatem-2. (ARES)
OSMP1536
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)
OSMP1688
Analyst Note:
The image shows a one-way-attack (OWA) UAV that appears to have crashed, but failed to function. It consists of an FPV chassis, as well as some of the essential components required for flight and the explosive charge (purple container). The initiator and other parts relevant to both flight and the munition’s function are not visible. This appears to be craft-produced ‘sacrificial’ UAV. (ARES)
OSMP1643
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)
OSMP1642
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)
OSMP1647
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)
OSMP1648
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)