GCV Infantry Fighting Vehicle

Artist's impression of the GCV Infantry Fighting Vehicle

The Ground Combat Infantry Fighting Vehicle was an infantry fighting vehicle being developed for the U.S. Army. The program originated as the lead vehicle of the U.S. Army's Ground Combat Vehicle program coordinated by TACOM and spawned a parallel program coordinated by DARPA. The purpose of the program was to replace existing armored personnel carriers and infantry fighting vehicles in U.S. Army service. The DARPA project aims to have the vehicle designed by 2015.[1] Derivatives of the vehicle based on a common chassis—such as tanks and ambulances—were expected to be manufactured. It replaced the previous attempt at a next-generation infantry transport, the XM1206 Infantry Carrier Vehicle.[2] The Ground Combat Vehicle program was cancelled in February 2014.[3]

Design

The Army emphasized affordability, rapid deployment, and low risk technology for the GCV. The Army required that all aspects of the Ground Combat Vehicle be at technology readiness level 6.[4][5] The shortfalls of rapid deployment would be mitigated through an incremental addition of components as technology matures.[6] The Army provided details from the Manned Ground Vehicle effort to utilize on the GCV.[5] The GCV was required to have better protection than any vehicle in the military's inventory.[7]

General Peter W. Chiarelli said that the "four main fundamentals" of the vehicle were: The ability to carry 12 soldiers and operate in all forms of combat; have significant protection; and deliver the first production vehicle by 2018.[8]

The IFV would be modular and networked and offer improved survivability, mobility, and power management functions. The GCV family would use technologies pioneered with the IFV lead vehicle effort.[9]

The Mounted Soldier System will be standard wear for GCV crew members.

The Mounted Soldier System (MSS) was being developed for GCV crew members.[7] MSS worked as a force multiplier enhancing situation awareness, comfort, and safety.[10] Dismounted leaders will utilize the Ground Soldier Systems.[7]

Network

The IFV would be operable with the current Battle Command Control and Communications Suite but would gradually use a more revolutionary networked integration system. The system would support integration with unmanned systems, and dismounted soldiers, providing adaptive access points and connectivity.[11] The new network concept called for decentralization of decision making.[12]

The Mounted Soldier System was to enhance situational awareness through wireless communications and input from vehicle sensors and external sources such as other vehicles.[10]

Electrical power

The IFV would provide exportable electrical power, and battery charging capability for soldier systems.[11]

Mobility

The IFV must have been transportable by C-17 Globemaster III cargo aircraft, rail, and ship. The Army limited the vehicle to the dimensions of the C-17 rather than smaller aircraft such as the C-130 Hercules, which in the past restricted many designs. The Army required the IFV to be as logistically deployable as the current Stryker. The IFV was to have good cross-country mobility, with a baseline requirement of 30 miles per hour (48 km/h) off-road speed. A certain degree of the ability to ford and cross gaps was also required.[7] The IFV was to deliver improved maintainability and consume less fuel than the Bradley Fighting Vehicle or other vehicles of similar weight and power.[11]

In its standard configuration the IFV would have a crew of three and carry a squad of nine. The vehicle could be reconfigured to support casualty evacuation. The Army stated no preference as to whether the IFV should be tracked or wheeled but suggested that it be tracked due to the weight stemming from the requirements.[13][14]

Offensive capabilities

The Army wanted the vehicle to feature a commander’s weapons station, autocannon, coaxial weapon, and an anti-tank guided missile system. The weapons suite had to be manually operable when damaged and the commander's weapon station had to incorporate a shield.[7] Additionally, a dismountable anti-armor weapon would be carried on board.[7] The Army also stated that the weapon suite would emphasis modularity, be able to defeat other IFVs, and provide non-lethal capability to enable use in civilian environments.[6][11]

In May 2012, the Army's Project Manager for Maneuver Ammunition System (PM MAS) began to emphasize the need for munitions suppliers to begin readying for GCV IFV ammunition needs. Solutions ranged from 25 mm to 50 mm, but 30x173mm was identified as "the most likely" design to meet lethality and stowed kill requirements. Specific requirements were for airburst capability to defeat infantry targets (with high explosive incendiary recognized as a "less effective alternative"), armor-piercing rounds to defeat material threats, and training ammunition for each tactical round. Potential candidates included five U.S. produced and three foreign-made rounds. On 7 August 2013, a sources sought announcement was made for a Cooperative Research and Development Agreement for 30x173 mm ammunition: 2,700 rounds of Mk 238 Mod 1 High Explosive Incendiary-Tracer (HEI-T); 2,000 rounds of Mk 258 Armor Piercing Fin Stabilized Discarding Sabot-Tracer (APFSDS-T); 2,000 rounds of Mk 268 Armor Piercing Fin Stabilized Discarding Sabot-Tracer (APFSDS-T); and 2,000 rounds of Mk 317 Target Practice Discarding Sabot-Tracer (TPDS-T). The announcement called for the cartridges to be compatible with the Bushmaster III weapon system, such as XM813 and/or Mk 44 Mod 1. All interested participants had to provide the ammo quantities and associated information before the end of March 2015.[15]

Countermeasures

Thermal management and acoustic noise reduction would be utilized to avoid detection. The vehicle would be able to avoid threats by laying obscurants. An array of hit avoidance systems would be leveraged and the Army offered the various active protection systems developed for the manned ground vehicle program.[7] The GCV enabled the detection and neutralization of mines at standoff ranges.[16] The vehicle was also to be equipped with an engagement detection system. The Army required the IFV to have the passive blast protection level equal to the MRAP.[11] The Army made available the composition of the armor of the manned ground vehicle program. A transparent armor shield would provide protection for the vehicle commander when exposed through the turret. Personnel would leverage harnesses and restraints to mitigate trauma. In addition, a Vehicle Health Management System would provide vehicle diagnostic monitoring systems for commanders. A fire suppression system and ammunition detonation protection would be utilized for damage control.[7]

The Mounted Soldier System would protect crew members from ballistic, thermal, and CBRN threats. The Mounted Soldier System incorporated fire retardant systems such as the Improved Combat Vehicle Crewman Coverall and undergarments, facewear, gloves, and footwear. Ballistic protection would come from the Combat Vehicle Crewman Helmet, eyewear, a maxillofacial shield, and improvements to body armor.[10] A secondary squad egress was to be provided for the squad to exit in emergencies.[7]

Tactics

The Infantry Fighting Vehicle variant was intended to fill the infantry transport role in Heavy Brigade Combat Teams replacing the aging M113 APC, M2 Bradley, and M1126 Infantry Carrier Vehicle.[2][6] It was the U.S. Army's intention that the IFV replace the M113 APC in the near term, and the M2 Bradley and M1126 ICV in the midterm.[6][17]

In the U.S. Army, as part of the ongoing restructuring, Heavy Brigade Combat Team Brigades would have an arsenal of 62 IFV's, battalions would have 29, and platoons would have 4.[12][18] Platoons were to be led by platoon leader GCV which would be accompanied by platoon medic, forward observer, Radio Transmission Operator, and other attachments and would command three other GCVs.[12]

The Army placed importance on the GCV's ability to carry a full nine-man squad. Numerous Army studies have concluded that a squad, containing two fireteams, should be composed of nine to eleven soldiers. These numbers allow the squad to accomplish the fire and maneuver doctrine, and for squad resilience, lethality, and leader span of control. The M2 Bradley cannot carry a complete squad from one vehicle, creating risk when transitioning from mounted to dismounted operations. The Bradley's lower carrying capacity was accepted for greater (than previous vehicles) mounted lethality and cost savings, leading to squads being broken apart for transport. A GCV with a nine-man squad would have allowed the squad leader to control and communicate with the squad while mounted, simplify the transition to dismounted operations in complex terrain, and allow the squad to conduct independent fire and maneuver immediately upon dismount. Replacing the Bradley on a one-for-one basis would have four GCVs per mechanized infantry platoon carrying one full nine-man squad in a single vehicle, with three vehicles carrying squads and one carrying the platoon's organic and attached enablers.[19]

Development

The Ground Combat Vehicle was envisioned to be a model of acquisition reform.[20] The initial program was canceled a year into development and was soon replaced with a new program better emphasizing affordability.

Initial program

IFV schedule as of January 2010
The German Puma is one of the best protected infantry fighting vehicles

In the initial plan, the first variant of the vehicle was to be prototyped in 2015 and fielded by 2017.[18] The U.S. military planned on procuring 1,450 IFVs at a total program cost of $40 billion.[21] The program was abruptly canceled in August 2010, before any contracts were awarded.[22]

Conception
Vice Chief of Staff of the U.S. Army General Peter Chiarelli hosts the second Industry Day meeting

An Army presentation in March revealed that TARDEC, ARL, and TRADOC - ARCIC had partnered to analyze the survivability of the army's "Ground Combat Vehicle".[23] Army Chief of Staff Robert Gates announced his intention of halting funding for the XM1206 Infantry Carrier Vehicle of the FCS manned ground vehicle program in April 2009.[24] In late May, Army and Department of Defense representatives outlined plans for the cancellation of Future Combat Systems and the initiation of the Ground Combat Vehicle program in its place.[25] On 15 and 16 June, a blue-ribbon panel convened in Washington D.C. to determine the requirements for the Ground Combat Vehicle.[26] It was concluded at this meeting that an Infantry Fighting Vehicle was to be the first vehicle variant fielded.[27] Defense contractors were not allowed to attend but at least six in attendance were employed by defense companies that eventually bid on the GCV contract.[28] On 23 June, Future Combat Systems was formally dissolved and many programs including the Manned Ground Vehicle program were canceled with it.[29] On 19 October, contractors turned up for a U.S. Army organized industry day event in Dearborn, Michigan to learn about the requirements.[30] In late October PEO Integration was established to oversee subsystems of BCT Modernization including the GCV.[31] On 24 November, a second industry day was held in Warren, Michigan.[32]

After much delay, reviews necessary for continuation were held throughout February, in Washington D.C.[33] The GCV review was officially passed on 25 February and a request for proposal (RfP) was issued the same day.[34] It was revealed in the RfP that the GCV would be a cost-plus contract.[35] Companies had 60 days to respond, but this offer was extended an additional 25 days.[34][36] In May, a "red team" was formed to curtail the GCVs 7-year development schedule.[37] By the 21 May deadline, four proposals were submitted.[38] On 1 July, management of the GCV was transferred from PEO Integration to PEO Ground Combat Systems with Andrew DiMarco as project manager.[39]

For fiscal year 2011, the U.S. Army intended to spend $934 million of the $2.5 billion allocated for BCT Modernization to develop the GCV.[40] Reportedly, $100 million was removed from the yet to be approved budget but the budget continued to reported as $934 million.[41]

On 25 August the Army retracted its request for proposals after the red team assembled in May recommended that the Army either upgrade the existing ground vehicle fleet or rewrite the requirements.[22]

Projections

The Technology Development Phase (or Milestone A) was to begin with the award of up to three vehicle contracts awarded in late Fiscal Year 2010 under the Technology Development Phase Contract. A Preliminary Design Review would follow in mid FY 2012.[18] The U.S. military planned to spend $7.6 billion during Milestone A.[42]

The Engineering and Manufacturing Development Phase (or Milestone B) was to begin with two prototype development contracts awarded in the beginning of Fiscal Year 2013 under the Engineering & Manufacturing Development Contract. Shortly thereafter, an Interim Critical Design Review would follow in Mid-FY 2013. After a nearly two-year manufacturing period the first prototypes would be manufactured Mid-FY 2015 after which a Critical Design Review and a Production Readiness Review would occur in FY 2015 and FY 2016 respectively.[18]

The Low Rate Initial Production Phase (or Milestone C) was to begin with a low-rate production contract awarded in mid Fiscal Year 2016 under the Low Rate Initial Production (LRIP) contract. Less than two years after the contract award LRIP would begin. After more testing a battalion-sized team would be attained in FY 2018 followed by a brigade-sized arsenal in FY 2019.[18]

If a Full-Rate Production Decision was attained, full-rate production would begin. The U.S. military planned on procuring 1,450 IFVs at a total program cost of $40 billion.[18][21]

Competitors

There were four known competing contractors for the Ground Combat Vehicle contract.

Concept image of BAE contender
  • BAE would provide general vehicle design, program management, integration of the vehicle components.
  • Northrop Grumman would provide technology pertaining to command, control, communications, intelligence, surveillance and reconnaissance.
  • QinetiQ would provide the electric drive propulsion system.
  • Saft would provide the energy storage system.
  • Features
  • Tracked with an E-X-Drive hybrid-electric engine.[45]
  • Baseline weight of 53 tons with a weight tolerance of 75 tons for modular armor.[48]
  • Manned turret.[48]
  • Leveraged a V-hull and Hard-Kill and Soft-Kill active protection systems.[49][50]
  • Wider and taller than a Bradley. All or most of the storage was internal accounting for the extra size.[49]
  • General Dynamics Land Systems led the team as systems integrator and was responsible for soldier interfaces and chassis.
  • Lockheed Martin would develop the turret and weaponry.
  • Detroit Diesel would develop the propulsion system.
  • Raytheon would develop the active protection systems, sensors.
  • Features
  • Used conventional diesel.[44]
  • Used active protection systems.[51]
  • Designers “paid a lot attention” to human accommodations.[52]
  • SAIC would lead the team as project manager.
  • Boeing would supply the weaponry.
  • Both Krauss-Maffei and Rheinmetall's roles were unknown.
  • Features
  • Larger, reconfigured Puma chassis.[53]
  • Used conventional diesel and a six-road-wheel configuration.[44]
  • ADVS led the team.
  • Had undisclosed subcontractors.
  • Features

Revised program

In September, Alion Science and Technology was awarded a $23,828,000 contract modification for the development of systems supporting GCV development. This contract was tendered by the U.S. Air Force and $2,180,000 in funds was obligated at the time of the award.[55] An industry day was held 1 October in Dearborn, Michigan.[56] The Army reduced its requested FY 2011 budget to $462 million.[8] Advanced Defense Vehicle Systems, General Dynamics Land Systems, and BAE Systems announced their intention of re-competing soon after the cancellation.[1][57] A revised RfP was to be issued around 27 October 2010.[58] Military officials met on 20 October to discuss delaying the RfP to allow leaders time to deliberate about requirements. The panel recommended releasing the RfP without delay but George Casey said he would need time to commit to a decision. Senior leaders at the meeting felt that the 27 October target could be met.[59] The National Commission on Fiscal Responsibility and Reform suggested deferring development of the GCV until after 2015.[60]

Wikinews has related news: U.S. Army revives next-generation Ground Combat Vehicle program

The revised RfP was issued on 30 November. ADVS announced its decision to not submit a proposal. ADVS decision not to compete was stated to be that the vehicle's slow procurement timeline was not suited to "ADVS’ rapid development and fielding capabilities".[61]

Up to three cost-plus contracts were to be awarded nine months after the RfP was released.[22][58] An acquisition decision memorandum on 17 August allowed the program to award technology development contracts. It also initiated two reviews of alternatives including a revised analysis of alternatives and an analysis of non-developmental vehicles.[62] The 18 August, the Army awarded technology development contracts to only BAE and GDLS. BAE was awarded $450 million while GDLS was awarded $440 million.[63] SAIC followed up with a bid protest on 26 August further delaying GCV development.[64] It believed the evaluations process was flawed and the evaluation took factors into consideration that were not stated in the request for proposal.[65]

Projections

$884 million was requested by the U.S. Army to fund the GCV in FY 2012.[66] The technology development phase was to be a 24 months long, 3 months shorter than the previous plan.[67] The Engineering and Manufacturing Development phase was to be 48 months long.[68] The Army planned on acquiring 1,874 GCVs to replace Bradleys in 16 active and 8 National Guard Heavy Brigade Combat Teams.[69]

Milestone A
Namer APC during Non-Developmental Vehicle assessment.
A CV-9035 demonstrator vehicle for the Non-Developmental Vehicle assessment.

Testing of commercially available combat vehicles began in May 2012 at Fort Bliss and White Sands Missile Range to prepare the Army for Milestone B. The Non-Developmental Vehicle analysis assessed five vehicles, the M2A3 Bradley, Namer, CV-9035, a double v-hulled M1126 Infantry Carrier Vehicle and a turretless Bradley. The tests, completed on May 25, were carried out to determine what vehicle variants and configurations fulfill the Army's needs.[70] The Army found that although the vehicles assessed met some GCV requirements, no currently fielded vehicle met enough without needing significant redesign.[71]

Competitors

There were three known competing contractors for the Ground Combat Vehicle contract.

  • Work breakdown
  • Features
  • Hybrid-electric drive
  • Work breakdown
  • Features
  • Work breakdown
  • Features
Milestone C

A Milestone C decision could have been made in 2019.[72]

Weight issues

In November 2012, estimates of the GCV's weight, depending on armor packages, put the General Dynamics entry vehicle at 64–70 tons, and the BAE Systems entry vehicle at 70–84 tons. This made the planned infantry fighting vehicle designs heavier than the M1 Abrams tank. The reason was the vehicle had to have enough armor to protect a squad of nine troops from all battlefield threats, from rocket-propelled grenades to IEDs, as good as or better than other vehicles can protect against specific threats individually. This worked against the vehicle; as weight increases, cost goes up and maneuverability goes down. The contractors worked to bring the weight down.[73] The Army maintained that heavy armor was needed to protect the squad from acceleration forces that come with an underside blast, and that thicker underbelly plates and V-shaped hulls do not give enough protection. More armor would come from the vehicle being larger for more internal space for the soldiers, and to allow for features such as floating floors for blast deflection and extra headroom. The Army also said heavy weight would not affect deployability because the Bradley it was planned replace already requires strategic airlift transport aircraft.[72]

Both contractors claimed their designs were below the 70–84 tons expectation of what the GCV will weigh. BAE's vehicle weighed 60–70 tons, based on modular armor package, and a 20 percent margin for weight increase the Army had planned for future upgrades would bring it up to 84 tons. General Dynamic's vehicle with a diesel engine weighed 62 tons in its most heavily armored configuration, which increased to 76 tons with the 20 percent future upgrade margin. Removing protection for easier air transportation would have reduced it to 56 tons. The Army's consideration to slow down the GCV development program gave time to the companies to refine their designs and reduce weight. One way would have been to reduce squad size. A nine-man squad has been identified as best for being able to fight with the possibility of taking casualties with single-vehicle transportability. With a three-man crew, the GCV had to carry 12 men. A greater number of lighter IFVs that carry fewer soldiers would have similar carrying capacity and combined costs and weight to planned GCV numbers. Another way would be an advance in armor designs. Lighter and stronger armor materials had not made radical progressions in recent history, and domestic active protection intercept systems were not yet mature. Foreign systems like the Israeli Trophy had seen combat but cannot yet intercept tank shells. The GCV program originally included an APS, but was then delayed as a feature for later upgrades. The last effort to replace the Bradley was with Future Combat Systems, which developed a vehicle that relied on sensors to avoid danger and an APS in place of heavy armor. It was too ambitious for the time and the vehicle's weight had grown from 19 tons to 30 tons by the time it was cancelled.[74]

DARPA

Concept image

The TACOM project spawned a parallel program by DARPA called Fast Adaptable Next-Generation (FANG) GCV. The contest utilizes crowdsourcing to engineer several IFVs.[75] The program will occur in three phases. The Mobility/Drivetrain Challenge lasts nine months and begins in mid-2012. A prize of $0.5-1 million for winning design or designs will be awarded. The Chassis/Integrated Survivability Challenge lasts nine months and begins in the beginning of 2013 concurrent to the Mobility/Drivetrain Challenge. A prize of $0.5-1 million for winning design or designs will be awarded. The Total Platform Challenge lasts 15 months and begins in late 2013.[76] A prototype would be completed and this could potentially compete with TACOM's GCV.[77] The vehicle's design itself would be open source.[78]

CBO

The Congressional Budget Office had questioned the affordability of the GCV and suggested that Bradleys be modernized instead.[79] Industry leaders and the Army criticized the CBO report, saying it did not account for changes in the program and unfairly weighted requirements against each other.[71]

Vehicles

BAE GCV

The BAE Systems Ground Combat Vehicle design had a 3-man crew and could carry a squad of nine troops. It had a steel-core hull and an integrated electronic network capability with embedded intelligence, surveillance, and reconnaissance equipment. Its turret was unmanned. The centerpiece of the vehicle was its simplified drive train. It was propelled by a Hybrid Electric Drive (HED), which was developed by Northrop Grumman, that produced 1,100 kW of electricity. Advantages to it are fewer components and lower volume and weight compared to current power plants. The transmission was 40 percent smaller and the drive train had half the moving parts. The hybrid drive train cost 5 percent more than a mechanical system, but had a 20 percent reduction in life-cycle cost. The electric drive allows for smoother low-speed operation and less noise. The vehicle burned 20 percent less fuel while running, with 4.61 gallons (17.45 liters) per hour used while stationary. It had a top speed of 43 mph (70 km/h), could go from 0 to 20 mph (32.18 km/hr) in 7.8 seconds, and had a range of 186 mi (299 km) with a 255-gallon fuel capacity. Disadvantages to the BAE design included a weight of 70 tons and fuel efficiency of only 0.73 mpg. It was argued that big, heavy vehicles are not practical in urban combat and that the infrastructure of urban and third-world countries should limit the vehicle's weight to 45 tons. Others said that urban warfare tactics have become so lethal that only vehicles of this size can survive.[69][80] BAE integrated the Artis Iron Curtain active protection system to defeat incoming rockets and missiles before they can hit the vehicle. The Army conducted tests on the system in April 2013, and the it successfully passed all tests.[81] A prototype system for the vehicle to drive in low visibility conditions was also tested. A Humvee with blacked-out windows drove through a smoke-filled mock town with the system safely, even though visibility was completely obscured.[82] In August 2013, the BAE GCV's hybrid electric drive completed 2,000 miles of testing on a fully integrated “Hotbuck” mobility platform. The Hotbuck is a stationary test stand that simulates real-life environments and terrain and puts actual miles on the HED system. Under BAE's own timeline, the testing was completed four months ahead of schedule. Developing and testing actual hardware was not a program requirement for the Technology Development (TD) phase, but BAE Systems chose to demonstrate the fuel efficiency and performance of a hybrid system.[83]

Although dramatic funding cuts for the GCV program in January 2014 put the very completion of the acquisition effort in jeopardy, funding remained for research on a hybrid-electric propulsion system. The BAE GCV's hybrid-electric engine is more fuel efficient, has fewer moving parts, and has faster acceleration than ordinary engines. While powering a vehicle concept that reached 70 tons proved impractical, its benefits of providing power for onboard electronics, silent overwatch, and short, stealthy movements are still promising. BAE has pledged to support future Army developmental efforts with technologies from their GCV entry.[84] On 18 July 2014, BAE Systems was awarded a $7.9 million study contract for technical, cost, and risk assessments to utilize the GCV TD phase integrated hybrid-electric propulsion and mobility subsystems Automotive Test Rig (ATR) and the hybrid-electric integrated propulsion subsystem (Hotbuck) for the Future Fighting Vehicle (FFV) effort.[85][86]

General Dynamics GCV

On 31 October 2013, General Dynamics successfully completed a preliminary design review of their GCV IFV design. Subsystem and component design reviews were held from August to October of that year and led to the four-day PDR. General Dynamics demonstrated their vehicle met Tier 1 affordability, reliability, and other requirements. The success of the PDR meant that the General Dynamics GCV IFV could be expected to be operationally effective and suitable.[87]

See also

Vehicles
Legislation

Notes

  1. 1 2 3 Chad Halcom (26 September 2010). "Contractors to resubmit bids for revamped military vehicle program". Crain Communications Inc. Retrieved 27 September 2010.
  2. 1 2 "Army Partially Terminates FCS Manned Ground Vehicle". asdnews.com. July 21, 2009. Retrieved January 27, 2010.
  3. US Army, Marines Struggle With Infantry Vehicle Replacements - Defensenews.com, 6 April 2014
  4. Greg Grant (March 5, 2010). "Army Wants Tough GCV Battle". Military Advantage. Retrieved 11 August 2010.
  5. 1 2 "Ground Combat Vehicle Infantry Fighting Vehicle Statement of Work" (PDF). United States Army. March 15, 2009. Retrieved April 7, 2010.
  6. 1 2 3 4 "The ground combat vehicle strategy: Optimizing for the future" (PDF). U.S. Army. Retrieved December 14, 2009.
  7. 1 2 3 4 5 6 7 8 9 MT Kash. "Industry day #1". Retrieved 19 September 2010.
  8. 1 2 Kate Brannen (22 September 2010). "Fewer FCS Technologies for GCV Round Two". Army Times Publishing Company. Retrieved 23 September 2010.
  9. "U.S. Army Defines Ground Combat Vehicles (GCV) Priorities". Defense Update. Retrieved March 29, 2010.
  10. 1 2 3 "Mounted Soldier System (MSS)" (PDF). May 2010. Retrieved 9 August 2010.
  11. 1 2 3 4 5 "U.S. Army Outlines Ground Combat Vehicles Priorities". Defense update. Retrieved January 26, 2010.
  12. 1 2 3 "The Ground Combat Vehicle In the Conduct of Future Operational Concepts" (PDF). August 2010. Retrieved 17 August 2010.
  13. Chavanne, Bettina (December 4, 2009). "New Combat Vehicle for U.S. Army". Aviationweek. Retrieved January 25, 2010.
  14. Matthew Cox (21 June 2010). "Casey: Make Ground Combat Vehicle lighter". Army Times Publishing Company. Retrieved 16 August 2010.
  15. Army Refines 30mm Ammunition Efforts for GCV - Defensemedianetwork.com, 18 August 2013
  16. "Towards a Comprehensive Vehicle Strategy" (PDF). 13 October 2009.
  17. Cox, Matthew (September 10, 2009). "U.S. Army Details Ground Combat Vehicle Plans". Defense News. Army Times Publishing Company. Retrieved December 13, 2009.
  18. 1 2 3 4 5 6 "GCV PROGRAM PLAN" (PDF). 29 January 2010. Retrieved 5 August 2010.
  19. Understanding Why a Ground Combat Vehicle That Carries Nine Dismounts Is Important to the Army - Rand.org, 11 June 2013
  20. "Ground Combat Requires an Adaptable, Versatile Vehicle" (PDF). August 2010. Retrieved 17 August 2010.
  21. 1 2 Megan Scully (4 August 2010). "Panel rejects bid to divert funds for Bradley upgrades". NATIONAL JOURNAL GROUP, INC. Retrieved 4 August 2010.
  22. 1 2 3 John T. Bennett; Kate Brannen (26 August 2010). "Army delays Ground Combat Vehicle". Army Times Publishing Company. Retrieved 26 August 2010.
  23. "Advanced Planning Briefing to Industry" (PDF). 19 March 2009. Retrieved 26 October 2010.
  24. Marc Heller (10 April 2009). "McHugh nervous about changes". Watertown Daily Times. Retrieved 9 August 2010.
  25. Daniel Wasserbly (28 May 2009). "US Army outlines how it will 'devolve' FCS". IHS Global Limited. Retrieved 9 August 2010.
  26. Cavallaro, Gina (June 11, 2009). "Panel to discuss new ground combat vehicle". Army Times. Army Times Publishing Company. Retrieved December 14, 2009.
  27. Matthew Cox (10 June 2009). "U.S. Army Details Ground Combat Vehicle Plans". Army Times Publishing Company. Retrieved 20 August 2010.
  28. Bryan Bender (26 December 2010). "Home / News / Nation The Boston Globe From the Pentagon to the private sector". NY Times Co. Retrieved 26 December 2010.
  29. "Future Combat System (FCS) Program Transitions to Army Brigade Combat Team Modernization", US DoD, 23 June 2009.
  30. "U.S. Army Announces Ground Combat Vehicle Industry Day" (PDF). US Army. US Army. October 2009. Retrieved October 2009. Check date values in: |access-date= (help)
  31. Jimmie Cummings (2 October 2009). "Army Establishes Program Executive Office Integration to Support Modernization". Retrieved 11 August 2010.
  32. Nelson, Margaret (November 25, 2009). "U.S. Army meets with industry representatives to conceive a ground combat vehicle". US Army. US Army. Retrieved November 2009. Check date values in: |access-date= (help)
  33. Brannen, Kate (February 11, 2010). "DoD Postpones Ground Combat Vehicle Review". Defense News. Retrieved February 11, 2010.
  34. 1 2 Brannen, Kate (February 25, 2010). "Army to issue Ground Combat Vehicle RfP today". Defense News. Retrieved February 25, 2010.
  35. Kate Brannen (26 February 2010). "Army launches Ground Combat Vehicle contest". Army Times Publishing Company. Retrieved 1 October 2010.
  36. White, Andrew (19 April 2010). "US Army delays GCV deadline". Shephard. Shephard Group Limited. Retrieved 19 April 2010.
  37. Kate Brannen (10 May 2010). "Experts Study U.S. Army's GCV Plans, Schedule". Army Times Publishing Company. Retrieved 11 November 2010.
  38. 1 2 3 Kate Brannen. "U.S. Army GCV Protest Not Expected to Cause Delay". Army Times Publishing Company. Retrieved 23 June 2010.
  39. Lori Grein (July 27, 2010). "The future of ground combat vehicles resides with PEO Ground Combat Systems". GlobalSecurity.org. Retrieved 11 August 2010.
  40. Cox, Matthew (February 1, 2010). "No more Humvees in 2011 procurement plan". Army Times. Army Times Publishing Company. Retrieved February 2, 2010.
  41. Roxana Tiron (27 July 2010). "House panel risks veto by supporting funds for second F-35 fighter engine". Capitol Hill Publishing Corp. Retrieved 28 July 2010.
  42. Roxana Tiron (6 August 2010). "Contractors vie for lucrative vehicle work". Capitol Hill Publishing Corp. Retrieved 6 August 2010.
  43. "BAE, Northrop to develop new ground combat vehicle". The Associated Press. March 1, 2010. Retrieved March 2010. Check date values in: |access-date= (help)
  44. 1 2 3 Sydney J. Freedberg Jr. "BAE Offers Hybrid-Electric Combat Vehicle". National Journal Group Inc. Retrieved 18 June 2010.
  45. 1 2 3 "BAE, Northrop expand team to bid on Army contract". Bloomberg L.P. 26 July 2010. Retrieved 27 July 2010.
  46. 1 2 Scott R. Gourley (August 2010). "Ground Combat Vehicle" (PDF). AUSA. Retrieved 21 August 2010.
  47. Andrea Shalal-Esa (22 October 2010). "Army sees new rules for combat vehicles soon". Thomson Reuters. Retrieved 23 October 2010.
  48. 1 2 Kate Brannen (26 July 2010). "Firm wants Army to use hybrid technology on GCV". Army Times Publishing Company. Retrieved 27 July 2010.
  49. 1 2 Michael Fabey (28 July 2010). "BAE-Northrop GCV Hybrid Drive A Gamble". The McGraw-Hill Companies, Inc. Retrieved 28 July 2010.
  50. Colin Clark (28 July 2010). "BAE's GCV Weighs 53 Tons, Hybrid". Military Advantage.
  51. 1 2 3 "General Dynamics Team Submits Army Ground Combat Vehicle Proposal". PR Newswire Association LLC. Retrieved 21 May 2010.
  52. Paul Mcleary (28 October 2010). "Waiting for the Ground Combat Vehicle". Retrieved 3 November 2010.
  53. 1 2 3 White, Andrew. "GCV shortlist revealed". Shephard Group Limited. Retrieved 21 May 2010.
  54. "Michigan Company Protests Rejection Of Its Wheeled GCV Bid". Inside Washington Publishers. June 28, 2010. Retrieved 6 August 2010.
  55. "Contracts". 29 September 2010. Retrieved 30 September 2010.
  56. Kate Brannen (5 October 2010). "U.S. Army to Set Out Tiered Requirements for GCV". Army Times Publishing Company. Retrieved 26 October 2010.
  57. Chad Halcom (27 August 2010). "Military vehicle maker drops protest, will try again for government contracts". Crain Communications Inc. Retrieved 30 August 2010.
  58. 1 2 "10--Ground Combat Vehicle Technology Development Phase Solicitation". 8 October 2010. Retrieved 16 October 2010.
  59. Kate Brannen (25 October 2010). "U.S. Army Aiming to Release GCV Request". Army Times Publishing Company. Retrieved 13 November 2010.
  60. "$200 BILLION IN ILLUSTRATIVE SAVINGS" (PDF). 10 October 2010. Retrieved 11 November 2010.
  61. Kate Brannen (18 January 2011). "4th GCV team withdraws from competition". Gannett Government Media Corporation. Retrieved 19 January 2011.
  62. Kate Brannen (18 August 2011). "GCV moves ahead, but more studies ordered". Gannett Government Media Corporation. Retrieved 11 September 2011.
  63. Kate Brannen (18 August 2011). "BAE, GD awarded Ground Combat Vehicle contracts". Gannett Government Media Corporation. Retrieved 11 September 2011.
  64. Roxana Tiron and Brendan McGarry (26 August 2011). "SAIC-Led Team Protests U.S. Army Combat Vehicle Contracts". Bloomberg L.P. Retrieved 11 September 2011.
  65. Paul McLeary (29 August 2011). "U.S. Ground Combat Vehicle Work Put On Hold". Bloomberg L.P. Retrieved 11 September 2011.
  66. Kate Brannen (15 February 2011). "Army seeks 30 percent less for overseas ops". Gannett Government Media Corporation. Retrieved 15 February 2011.
  67. Kate Brannen (22 September 2010). "U.S. Army To Host GCV Industry Day Oct. 1". Army Times Publishing Company. Retrieved 22 September 2010.
  68. "GCV Industry Day" (PDF). 1 October 2010. Retrieved 13 November 2010.
  69. 1 2 BAE offers 70-ton GCV - Armytimes.com, March 27, 2012
  70. Ashley Piper (21 May 2012). "Army assesses current vehicles as part of Ground Combat Vehicle development process". Army News. Retrieved 8 June 2012.
  71. 1 2 Army, industry slam CBO’s scathing GCV report - DoDBuzz.com, April 4, 2013
  72. 1 2 Cox, Matt (February 21, 2013). "Army: GCV Needs to Be Big and Tracked". DefenseTech. Retrieved February 26, 2013.
  73. "Bradley Offspring, GCV, May Top 84 Tons, Heavier Than M1 Tank", Defense, AOL, November 8, 2012.
  74. "BAE, GD: We Can Cut Weight From Army's GCV", Breaking defense, 27 November 2013.
  75. "DARPA-SN-10-67 Proposers' Day Announcement Adaptive Vehicle Make Program Portfolio". 17 August 2010. Retrieved 23 August 2010.
  76. "Adaptive Vehicle Make (AVM)" (PDF). 7 October 2010. p. 39. Retrieved 28 October 2010.
  77. "Adaptive Vehicle Make". 7 October 2010. Retrieved 28 October 2010.
  78. "Adaptive Vehicle Make". 28 October 2010. Retrieved 28 October 2010.
  79. "U.S. Army’s Top Vehicle Program Gets Another Black Eye."
  80. BAE Systems releases details of hybrid tank - Gizmag.com, November 22, 2012
  81. "Iron Curtain Successful in Firing Tests". Defense Update. April 29, 2013. Retrieved 2013-05-08.
  82. Undeterred By Possible Delays, BAE Continues Ground Combat Vehicle Development - Nationaldefensemagazine.org, 28 August 2013
  83. BAE Systems Ground Combat Vehicle Hybrid Electric Drive successfully completed 2000 miles testing - Armyrecognition.com, 27 August 2013
  84. Hopes Dim for BAE’s ‘Green’ Combat Vehicle - DoDBuzz.com, 22 January 2014
  85. Army Attempts to Salvage GCV Technology Advances - Defensemedianetwork.com, 25 July 2014
  86. Army asks BAE Systems and General Dynamics to recycle GCV vetronics for Future Fighting Vehicle - Militaryaerospace.com, 18 August 2014
  87. General Dynamics completed Preliminary Design Review of Ground Combat Vehicle design - Armyrecognition.com, 9 November 2013
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