Military Unmanned Vehicles – New Forms of Combat

In modern warfare, military unmanned vehicles (Unmanned Vehicles) are gradually changing traditional combat methods. During the Russia-Ukraine war, the widespread use of drones and other unmanned vehicles proved that these technologies are indispensable on the battlefield. Unmanned vehicles not only improve combat efficiency but also significantly reduce the risk of casualties, making them a core component of modern military forces.

The Role of Drones

Reconnaissance and Surveillance

Drones excel in reconnaissance and surveillance missions. Traditional reconnaissance missions required manned aircraft or troops to venture deep into enemy territory, risking significant danger to gather intelligence. Drones have changed this dynamic. Equipped with high-resolution cameras, infrared sensors, and radar systems, drones can monitor enemy movements in real-time from a safe distance. Additionally, these drones can operate in harsh weather conditions, ensuring all-weather surveillance capabilities.

Drones can not only transmit high-definition images and videos in real-time but also quickly relay the collected information to command centers through data links, enabling decision-makers to respond swiftly to changes on the battlefield. During the Russia-Ukraine war, both sides used drones to monitor enemy troop movements, identify command centers, supply lines, and other critical targets. This information provided crucial support for planning offensive operations.

Precision Strikes

Another significant advantage of drones lies in their precision strike capability. Unlike traditional bombers, drones can carry precision-guided weapons, such as laser-guided bombs or missiles, to directly target high-value targets.

Psychological Warfare and Propaganda

Drones are not only tools for strikes and reconnaissance but also important means of psychological warfare and propaganda. Videos and images captured by drones can be quickly disseminated through social media, showcasing the effectiveness of one’s strikes to the enemy, thereby weakening enemy morale while boosting the morale of one’s soldiers and citizens.

Suicide Drones

Suicide drones, also known as loitering munitions, have recently become a new type of unmanned combat tool. These drones hover over target areas and conduct self-destructive attacks upon detecting enemy targets. Compared to traditional missiles or bombs, suicide drones are more flexible and can adjust their attack targets in flight based on real-time intelligence. Due to their small size and low flight altitude, they are difficult to detect and intercept by enemy radar, making them highly effective on the modern battlefield.

Electronic Warfare

Drones also play a crucial role in electronic warfare. Electronic warfare drones can carry electronic jamming equipment to disrupt enemy communications, radar, and navigation systems, thereby weakening enemy command and combat capabilities. They can also conduct electronic reconnaissance missions, intercepting enemy electromagnetic signals to gather important intelligence.

The Principles of Drones

Flight Control and Navigation Systems

The flight control system is a core component of drones. It integrates data from multiple sensors (such as gyroscopes, accelerometers, and GPS) to maintain the drone’s stability and flight path. The navigation system is responsible for route planning and positioning. Military drones typically use multiple navigation systems, including GPS, Inertial Navigation Systems (INS), and other satellite navigation systems, to ensure accurate navigation in various complex environments. In some advanced drones, Artificial Intelligence (AI) technology is also utilized, allowing the drone to autonomously plan flight paths and adjust flight parameters without human intervention, even autonomously avoiding obstacles. This high level of automation in flight control and navigation enables drones to carry out more complex and dangerous missions on the battlefield.

Communication and Control Links

The communication system is crucial for drone operation, especially in military drones. Through encrypted communication links, ground operators can control the drone’s flight direction, speed, and mission execution in real-time. Modern military drones typically employ two-way data links, not only transmitting commands to the drone but also receiving real-time intelligence data collected by the drone back to the command center. To ensure communication stability in environments with strong electromagnetic interference from the enemy, military drones often use encrypted communication protocols and multi-band communication technologies. Additionally, some advanced drones are equipped with autonomous operation capabilities, allowing them to autonomously return to base or continue executing pre-set missions if communication links are disrupted.

Reconnaissance and Surveillance

Reconnaissance and surveillance are core functions of drones. Equipped with multispectral cameras, infrared sensors, and synthetic aperture radar (SAR), drones can conduct reconnaissance missions in various environments, capturing high-resolution battlefield images and videos. These images and videos are not only used for real-time monitoring but can also be analyzed by intelligent algorithms to automatically identify and mark targets. Some advanced drones are also equipped with data fusion technology, which can comprehensively analyze multi-source data (such as optical, infrared, and radar data) to provide more comprehensive intelligence. This capability greatly enhances the reconnaissance effectiveness of drones, allowing them to maintain efficient intelligence collection even in complex battlefield environments.

Weaponry and Strike Capabilities

Modern military drones possess multiple strike capabilities, able to carry missiles, bombs, or other guided weapons to execute precision strikes. The strike capability of drones is not only reflected in their accuracy but also in their flexibility and low cost. Unlike manned fighter jets, drones can loiter in the air for extended periods, waiting for the right moment to strike, thereby reducing the risk of collateral damage. The strike capabilities of drones are further enhanced by their advanced sensors and guidance systems. These systems can lock onto targets in real-time and automatically adjust the trajectory to ensure strike precision. In some cases, drones can also conduct multi-target attacks, significantly boosting battlefield effectiveness.

Stealth and Survivability

To survive on modern battlefields, military drones often adopt stealth designs. By using radar-absorbent materials and optimizing the airframe structure, drones can significantly reduce their radar cross-section, thus minimizing the likelihood of detection by enemy radar. Additionally, some drones feature low infrared signatures, making them less visible to infrared detectors. Besides stealth design, military drones typically possess robust self-defense capabilities, such as electronic countermeasures and automatic evasive systems. When attacked, these systems can automatically execute evasive maneuvers, such as deploying decoys or rapidly changing flight paths to avoid enemy air defenses.

Automation and Intelligence

With the development of artificial intelligence, more and more drones are equipped with autonomous operation and intelligent decision-making capabilities. Modern military drones can not only fly autonomously but also dynamically adjust mission execution based on real-time battlefield conditions. For example, drones can automatically identify new targets during a mission and decide whether to engage. The intelligence of drones is also reflected in their swarm capabilities. Through network communication and collaborative algorithms, multiple drones can form a combat group, working together to complete complex tasks with minimal human intervention.

Types of Unmanned Vehicles

In modern military operations, unmanned vehicles are not limited to aerial Unmanned Aerial Vehicles (UAVs). There are various other forms of unmanned vehicles, each playing significant roles in ground, surface, and underwater combat.

Unmanned Aerial Vehicles (UAVs)

UAVs are the most common type of unmanned vehicles, widely used for reconnaissance, strikes, surveillance, and communication relay missions. Depending on the operational requirements, UAVs can be designed as fixed-wing, rotary-wing, or hybrid-wing configurations.

  • Fixed-wing UAVs: For example, the MQ-9 “Reaper” drone has long loiter times, making it suitable for wide-area reconnaissance and surveillance missions. It has long endurance and flight range.
  • Rotary-wing UAVs: Such as the “Predator” drone, capable of vertical takeoff and landing, making them ideal for close-range combat and operations in complex terrain, offering high flexibility and adaptability.
  • Hybrid-wing UAVs: These combine the advantages of both fixed-wing and rotary-wing designs, capable of vertical takeoff and landing while also having long endurance, making them suitable for a variety of missions.

Unmanned Ground Vehicles (UGVs)

Unmanned Ground Vehicles are primarily used for land-based operations such as reconnaissance, mine clearance, logistics transport, and battlefield support. They can perform tasks in high-risk environments, reducing the exposure of personnel to danger.

  • Reconnaissance UGVs: Equipped with multiple sensors and cameras for ground reconnaissance and surveillance missions. They can navigate complex terrain autonomously and transmit real-time reconnaissance data.
  • Mine Clearance UGVs: Specifically designed to detect and neutralize mines and explosives, such as the “MAARS” robot, capable of clearing battlefield hazards without endangering personnel.
  • Battlefield Support UGVs: For example, the “Mule” unmanned vehicle, capable of transporting ammunition, supplies, and medical equipment to support frontline combat personnel.

Unmanned Surface Vehicles (USVs)

Unmanned Surface Vehicles are mainly used for operations in oceans and inland waters, including maritime reconnaissance, mine countermeasures, anti-submarine warfare, and electronic warfare. They can patrol dangerous waters for extended periods and perform tasks without the need for onboard crew.

  • Reconnaissance USVs: Equipped with radar, sonar, and optical sensors for maritime surveillance and reconnaissance, capable of maintaining stable reconnaissance capabilities even in harsh sea conditions.
  • Mine Countermeasure USVs: For example, the “Sea Hunter” unmanned vessel, used to detect and neutralize mines, ensuring the safe passage of waterways.
  • Anti-Submarine USVs: Equipped with sonar and torpedo systems to detect and attack enemy submarines, protecting friendly maritime territories.

Unmanned Underwater Vehicles (UUVs)

Unmanned Underwater Vehicles are used for reconnaissance, search and rescue, oceanographic research, and anti-submarine warfare in deep-sea and shallow water environments. UUVs can perform tasks underwater that traditional surface vessels cannot accomplish.

  • Reconnaissance UUVs: Equipped with sonar and cameras for underwater reconnaissance and surveillance, capable of collecting data in deep-sea environments.
  • Search and Rescue UUVs: Used to locate and recover missing underwater objects or personnel, commonly employed in maritime rescue missions.
  • Anti-Submarine UUVs: Armed with torpedoes or other weapon systems specifically designed to hunt enemy submarines, conducting covert anti-submarine operations.

Conclusion

As an essential part of modern military power, unmanned vehicles continue to drive the evolution of combat strategies. Their comprehensive application in air, ground, surface, and underwater operations provides modern armies with diverse tactical options and combat capabilities. As technology advances, unmanned vehicles will play an increasingly critical role in future military operations, further shifting the balance of power on the battlefield.