Colour of all, or some, of the markings on the munition
Marking Colour (10)
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 (5)
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.
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)
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)
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)
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)
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)
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)
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)
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)
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)
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)
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)
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)
This image shows an Israeli-made 122 mm rocket motor found following a strike on Amr School in Gaza City. Although it is not possible to be definitive from this image alone, it is likely that this rocket motor was part of an Israeli ‘Bar’ missile, a guided munition designed for precision strikes in urban areas that uses a 122 mm rocket motor. (ARES)
This image shows remnants of two different rocket motors from AGM-114 series Hellfire missiles. While it cannot be determined by these entries alone, images of the damage from the strike associated with this image, gathered by Mwatana, indicate that both of these AGM-114 missiles were the kinetic AGM-114R9X variant. (ARES)
This image shows the top of the booster of an Arrow 3 interceptor missile, where it connects to the kill vehicle. The Arrow 3 was jointly developed by the United States and Israel, and first entered service in 2017. The date of manufacture marking (“DATE OF MFG: 05/2018”) indicates that this booster was produced in the year after the Arrow 3 first entered service. (ARES)
This image shows the booster of an Israeli Arrow 3 interceptor missile. The Arrow 3 is designed to engage ballistic missiles and is capable of exo-atmospheric interceptions. Once the booster is expended, it separates from the ‘kill vehicle’. The kill vehicle has a sustainer motor that propels it towards the incoming ballistic missile, and uses kinetic impact, rather than an explosive warhead, to disable or destroy its target. This is sometimes called the ‘hit-to-kill’ principle. (ARES)
This image shows the rocket motor of an AGM-114 "Hellfire" series guided missile found in Jordan during the 12 day conflict between Israel and Iran. This specific Hellfire missile is likely an air-to-air "C-UAS" variant used to intercept one-way attack drones, such as those launched by Iran towards Israel, rather than the more common air-to-surface Hellfire missile variants. (ARES)
This image shows a Mikholit that was ejected from the weapons pod of an Israeli Hermes 900 drone that was downed in Iran. This Hermes 900 drone had two weapons pod, each capable of carrying 4 Mikholit bombs. (ARES)
This image shows a variety of small air-delivered munitions that have been developed specifically for deployment via UAV. Some of these appear to be original designs, whilst others have been made by modifying existing munitions. This entry reflects those munitions outlined with the red box, but all of the munitions are generally of similar in size and format, and all have tailfin assemblies intended to orient the munition as it falls, just like more traditional air-delivered bombs. (ARES)
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)
The warhead of the OWA UAV indicated in this image cannot be positively identified from this photograph alone. It appears to be the warhead section of either an OG-9 series or OG-15 series high explosive fragmentation (HE-FRAG) projectile, with a GO-2 or similar impact fuze fitted in the nose. (ARES)
This image shows the nosecone from an Israeli SPICE 250 air-delivered bomb. Whilst generally similar in appearance to the nosecone of the GBU-39, the SPICE 250 nosecone is longer and narrower. (ARES)
This image shows the flare from a Terminal High Altitude Area Defense (THAAD) system's ‘Talon’ kinetic interceptor missile. The flare is located at the aft end of the missile's booster engine. The ‘petals’ of the flare are initially flush, and are actuated into the deployed position, seen here, as part of the missile‘s functioning. (ARES)
This image shows a Mikholit glide bomb, with its warhead removed (green cylinder on the left side of the box). The fins that spring outward when deploye have been taped down. This Mikholit was reportedly recovered by the Israeli Defense Forces (IDF) from Hamas, who had captured the bomb after it failed to function when originally deployed by the IDF. (ARES)
This image shows two Mikholit air-delivered bombs (‘glide bombs’), and four Mikholit warheads. There are at least two different variants of warheads available for the Mikholit glide bomb. The green cylinder on the left is a blast (high explosive) warhead, whilst the other three warheads are shaped charge warheads which incorporate additional fragmentation. Blast warheads of this type have also been seen with red markings, while the shaped charge warheads have been seen with yellow markings. (ARES)
This image shows the rear fin section that is attached to a M-302/Khaibar-1/Fadi series rockets to add guidance capabilities. This rear fin section is installed, along with a forward control section between the warhead and the rocket motor. The guided munition, now classified as a missile, is referred to as a Nasr-1/Nasr-2. A similar, but larger, rear fin section is fitted to Zelzal rockets to convert them to guided munitions. (ARES).
This image shows the rocket motor of a Kheibar Shekan or Fattah-1 medium-range ballistic missile (MRBM). The Fattah-1 was publicly unveiled by Iran in June 2023, with very few images surfacing since that time. Due to the lack of available reference material, differentially identifying the Kheibar Shekan and Fattah-1 is difficult. The missile components displayed at unveilings and public displays are also often different from those used in production models. (ARES).
