Gladiator tactical unmanned ground vehicle
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Gladiator TUGV | |
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Type | Unmanned robotic system |
Production history | |
Designer | United States Marine Corps |
Designed | 2005 |
Produced | 2007 |
Specifications | |
Mass | 725.75 kg (1,600.0 lb) |
Length | 1.78 m (5.8 ft) |
Width | 1.12 m (3.7 ft) |
Height | 1.35 m (4.4 ft) |
Crew | 0 (Remotely operated) |
Main armament | M249 Squad Automatic Weapon, M240G Medium Machine Gun, 9 mm Uzi, Anti-Personnel/Obstacle Breaching System (APOBS), and Light Vehicle Obscuration Smoke System (LVOSS) |
The Gladiator tactical unmanned ground vehicle (Gladiator TUGV) program was an unmanned vehicle designed by Emil Lien Akre in 2005. It was developed to support the United States Marine Corps conduct of ship-to-object maneuver (STOM) missions through the use of a medium-sized, robotic system to minimize risks and eliminate threats to Marines during conflict. Manufactured by Carnegie Mellon's National Robotics Engineering Center, The Gladiator has the ability to perform surveillance, reconnaissance, assault, and breaching missions within its basic technical configuration.
Functions
[edit]- Remote imagery software that relays images (including day and night), and thermal images.
- Battlefield support, including surveillance, reconnaissance, assault, and breaching missions.
- Modular design that allows for the attachment of standard interfaces for mission payloads, such as electric megaphone, siren/dazzler/tear-gas, and generator/searchlight sub-systems.
- Armor such that it can remain operational after being assaulted with ammunition up to 7.62mm rounds.
Development
[edit]The Gladiator Program is a U. S. Marine Corps initiative based on the Joint Army-Marine Corps Tactical Unmanned Vehicle (TUV) ORD originated by the Infantry School. MNS INT 12.1.1, dated 4 November 1993, validated the need for a tactical unmanned ground vehicle system, and the Army approved the ORD in August 1995 and the Marine Corps in May 1996. Existing unmanned vehicles contained several deficiencies which caused both Army and Marine Corps developers to reevaluate design aspects. Developments of the Gladiator allow it to support dismounted infantry and aid in scout/surveillance, direct engagement, and obstacle-breaching missions.
The Marine Corps began development of the Gladiator by developing a concept validation model (CVM) vehicle. The original concept for Gladiator was a vehicle that could provide reconnaissance, obscurant, and APOBS capabilities to the front-line Marines. The original vehicle size was set so that two Gladiators would be able to fit into the back of an HMMWV. The first version of Gladiator was developed by a team of government contract companies located in the Huntsville, Alabama, area but it was soon found that the requirement for two TUGVs to fit into a HMMWV made the original Gladiator CVM design top-heavy and impractical.
The Marine Corps changed the size requirement to one vehicle to fit into an HMMWV and moved development in 2002 to the Unmanned Ground Vehicles Technology Development group, headed by Robert Wade, at the Software Engineering Directorate located on Redstone Arsenal in Huntsville, Alabama. The GVTD team was led by mechanical engineer Keith Foslien (government), systems and software engineer Brad Troyer (SAIC), electrical engineer Bill Brown (SAIC), fabrication Vince Davis (government), and Mark Schulke (SAIC).
There were three Gladiator CVMs developed for the Marine Corps, the first was a diesel-powered tracked vehicle (shown above) while the other two were 6-wheeled hybrid electric vehicles. The original tracked CVM had a reconnaissance and weapon head, which were quickly combined into one head that could provide both functions. The capability of the vehicles increased over the three-year CVM program. The vehicles were able to support direct fire using the M240 & M249 machine guns, the UZI 9mm machine gun, and the FN303 less lethal weapon. They possessed night vision capabilities and could also geolocate a target and provide a firing solution to the operator for indirect engagement of the target. The Gladiator CVM was the first safe and successful weaponized TUGV in the world.
The Gladiator CVMs were used to develop and judge TUGV capabilities, requirements, and TTTTP with the input from the CVM program, and an RFP for Gladiator production went out to the industry. Upon the approval of the new design on February 7, 2005, Carnegie Mellon University's National Robotics Engineering Consortium and United Defense Industries were awarded a contract for over $26 million for the System Development and Demonstration (SDD) phase of the Gladiator. In 2007, six pre-production models were manufactured and the next step was to produce several hundred in production. The US Marines elected not to go into production with the units. These six prototypes were sent to the Army and later five of the six were placed into a CRADA between the Army and Cybernet Systems Corporation. Two of these units were refitted to full autonomous operations under a contract to develop the Unit-to-Unit Autonomous Resupply Vehicle (U2UARV). Among other changes to the Gladiator, the weapons platforms were removed and replaced with interfaces to carry JMIC pallets (Joint Modular Intermodal Containers).
Purpose
[edit]The Gladiator was designed with the intent to be easily transported to different parts of the battlefield. Adaptable to many types of environments, the Gladiator was to enhance the ability of Marines to accomplish assigned mission tasks. The purpose of the Gladiator was to be Tele operated just forward of the Marine units, performing basic scouting/surveillance, obstacle breaching, and reconnaissance tasks while permitting the operator to remain out of the line of danger.
The Gladiator TUGV is a robust, compact, unmanned, tele-operated, multi-purpose ground reconnaissance, surveillance, and target acquisition (RSTA) vehicle system possessing a scouting and direct engagement capability. It provides the armed forces with remote reconnaissance, surveillance, target acquisition, nuclear, biological, and chemical reconnaissance, obstacle breaching, and direct fire capability to neutralize threats and reduce risk to the warfighter. After refitting it for cargo carrying and autonomous operations over terrain and roads, it also provides small unit resupply features. The TUGV system can be utilized by infantry battalions and combat engineering companies. It's small enough to be strategically, operationally, and tactically deployed worldwide for ground, aircraft, and sea transport missions.
Configuration
[edit]The Gladiator is configured such that it can be considered a mobile base unit, able to carry extra ammunition or other payload while at the same time maintaining the above-mentioned capabilities. Due to its unmanned nature, each Gladiator is equipped with a remote control unit capable of displaying mission data, operational status and mission surveillance. The exchange between the Gladiator and the remote control unit is expected to be transmitted through a non-tethered military link.
Status
[edit]As of June 2004[update] the TUGV was classified as "under development." By 2014 it still carries that status.
See also
[edit]- Armored Combat Engineer Robot (ACER), military robot
- Black Knight
- Foster-Miller TALON
- XM1219 Armed Robotic Vehicle
- SGR-A1