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In late 2019, photos and footage showing Russia’s Uran-9 combat robot deployed in Syria appeared online. They became a rare visual evidence of the Uran-9 combat deployment in the war-torn country, which, according to official sources, took place in 2018.
The Uran-9 multipurpose unmanned ground combat vehicle was officially unveiled by Russian military equipment manufacturer JSC 766 UPTK during the Army-2016 International Military-Technical Forum in Russia in September 2016. The vehicle is designed to provide remote reconnaissance and fire support to a variety of tasks conducted by the counter-terrorism, reconnaissance and military units in urban environments.
The Uran-9 can be used fully autonomously on a predefined road or manually operated by one man from a truck control station or via a small backpack control station.
Back in 2016, the Uran-9 was armed with a 30mm Shipunov 2A72 automatic cannon, four ready-to-launch 9M120-1 Ataka (NATO reporting name: Spiral-2) anti-tank guided missiles (ATGM), six ready-to-launch Shmel-M reactive flamethrowers. and a 7.62mm Kalashnikov PKT/PKTM coaxial machine gun mounted to the left side of the main armament. The Uran-9 can be also armed with four Igla surface-to-air missiles.
There are two Ataka missile launchers and three Shmel-M on each side of the turret. The Ataka missile has an operational range from 400 m to 6 km, and is capable of penetrating armour to a depth of 800mm behind explosive reactive armour (ERA).
The Uran-9 unmanned ground combat vehicle has the ability to resist firing of small arms ammunition and shell splinters. The steel armour plates of the hull offer protection for the vehicle suspension.
The robotic system is equipped with various remote-controlled sensor modules such as laser warning system, and electro-optic and thermal imaging cameras. It has an onboard fire control system, comprised of automatic target detection, identification and tracking devices, as well as a ballistic computer. The systems are able to detect and track targets at a distance of up to 6 km during the day and 3 km during the night.
The Uran-9 has two operation modes – autonomous and manual. In autonomous it can automatically identify, detect, track and defeat enemy targets based on the pre-programmed path set by the operator. The Uran-9 robot is manually controlled by a single operator from a mobile command and control station mounted on a 6×6 tactical truck from a safe distance of 3km.
The Uran-9 is powered by a diesel-electric power source, which provides a maximum speed of 35 km/h on a highway, and a max speed of 25 km/h cross-country. In off-road conditions it moves slow, at only 10 km/h. The robot’s tracked chassis offers increased cross-country mobility. The average specific ground pressure is 0.6kg/sq cm.
The Uran-9 was commissioned in the Russian Armed Forces in January 2019, whereas it was tested in Syria in 2018. It furthermore was used during the Vostok-2018 military exercise.
In June 2018, RIA Novosti reported that some shortcomings in the combat capability of the Uran-9 were established, while it was being used in Syria.
Military experts discovered flaws in the control, mobility, firepower, intelligence and surveillance functions of the robot. In addition, with the independent movement of Uran-9, a low reliability of the running gear – track rollers and guide rollers, as well as suspension springs were discovered.
The robot also showed the unstable operation of a 30-mm automatic gun, untimely triggering of the start circuits, and the failure of the thermal imaging channel of the optical sighting station.
In April 2019, Interfax cited the Deputy Chief of the General Staff of the RF Armed Forces, Chairman of the Military Scientific Committee of the Armed Forces, Lieutenant General Igor Makushev who said that the deficiencies in the robot were all removed by the development team.
In 2019, there were more issues with the Uran-9, it allegedly had problems with losing connection to the command post. Unlike flying drones, the control signal of a radio-controlled machine can be lost when passing through mountains, buildings and other objects. During tests in Syria, this led to a loss of the signal approximately 17 times for 1 minute, and twice the connection with the combat robot was lost for an hour and a half.
Reportedly, problems with rollers and suspension springs may occur in the Uran-9’s undercarriage, which is why the robot needs frequent repairs and cannot be used for a long time. But the biggest problem remains that the remote-control system reportedly works at a distance of no more than 300-400 meters instead of the promised 3 kilometers.
Upwards of 20 units of the Uran-9 have been constructed as of December 2019, and the deployment in Syria was generally regarded as positive and successful. Even if the reports of the issues were true, they could be rectified in short-term development.
There is no breakthrough in the development and deployment of unmanned systems. Nonetheless, the approach demonstrated by the Russian Armed Forces is interesting because the Russian side works on the development and deployment of not separate robotic systems, but rather groups of robotic systems controlled by a unified control system within a single intelligent network. The composition of these groups can be adapted depending on tasks that they had to achieve on the battlefield. Furthermore, significant efforts were and some successes was already achieved in the task of allowing these robotic systems to operate autonomously within the group to fulfill the assigned task. This is the first step on a long road of creating a swarm of fully autonomous robotic systems that can perform assigned tasks without a direct involvement of operators. The Kungas robotic complex and the Okhotnik heavy unmanned aerial vehicle are the most vocal examples of this approach.
Another point is the functionalism of the Russian projects. Instead of pushing ahead military robot dogs or tiny combat drones (all these directions have apparent issues taking into account the current technological progress), the Russian military chose straightforward and effective decisions employing relatively large tracked platforms that do not require non-existing engineering solutions. This allowed Moscow to focus on what really matters: the employment of robotic systems in combat conditions and the development of their fully autonomous solutions.
Testing new toys.
The problems with telecommunications show a lack of knowledge in both 5G, satellite tracking, and especially in metallurgy and AI. One does not need huge cell towers close by, not at ranges this robot will operate under, mobile towers will suffice such as what were used along China’s railroad and in mining operations worldwide for heavy equipment in rough terrain, and even driverless heavy duty haulers on twisted slightly developed roads. Israel leads world in all advanced tech, especially in the swarm and AI used in drone technology. What Russia actually has is not much more capable than a radio controlled toy, a big heavy over armed, lightly armored toy. While it seems it would be somewhat viable at close in urban contact that would mean close in unable to have its controller beacons pass through walls or through whole buildings requiring him to be in almost visible range of his target. Nothing said of the infrastructure such as how to transport, fuel, battery life, in field repair. The US already has small urban remote vehicles and although lightly armed and armored if used as strictly anti personell are very capable. In Afghanistan US largest military installation has replaced SO and operator controlled microwave weaponry that is capable of killing humans and disabling telecommunications and electrical systems of advancing by land and air enemy. It seems what is being presented is but a technological mule, test bed, for a behind the scenes of what real product is already in advanced stages of completion. There are numerous US, S. Korea, Japan and Chinese advanced Robotics with AI capabilities that use above 5 G telecommunication systems. The thing is none of those systems are totally reliable, imagine such as case as in Russian mini weapon you are unloading it and its machine gun decides to trigger, it is so slow a man walks faster and how does it know friend from foe or if it is justba dog peeing on it when operator cannot even find the damn thingand are very costly to produce.
Uran 9 replaces a platton of 9 soldiers( Atgm operator,assistant,sniper,assistant,watchman with binoculars,watchman with thermal vision,heavy machine gun operator, RPG operator,7,62 PK operator).. inside a trench during night waiting an incoming terrorist attack!….
The United States is playing into the hands of Russia by invading Syria and forcing Assad to seek the defense and protection from Russia. Now, the United States has provided a laboratory for the Russian defense industry to improve its weapons, and make them the best in the world tested and improved in battle conditions.
The U.S. is letting other nations deploy their systems first. This give the moral high-er ground of saying, “we’re just reacting.”
this time of the year, gifts are given…
What they need is to pair this with a drone in order to overcome the communication problems.
If a “com-drone” is flying around and above, but not right above, the transmission can be replaced using the drone as a hub. That drone can also have a high resolution camera for the operator to get a bird view of the battlefield and also the position of the robot.
I guess such a drone could also lock onto targets using laser for the robot to use for guidance as well?
A second drone could be in place to just counter any hostile takeover of the robots controls IF that happens and whereas the drone gives a signal to the robot that a new encryption key is now to be used and release and lock out its original communication system.
So a operator, robot and drone is the answer if you ask me… that said… A SWARM of drones is the real answer, so one draws the attention away from the robot using some very cheap drones and some very expensive ones with arms and what not, mixed up as a SWARM, but they all look the same.