U.S. Army Armored
Vehicle Developments in
the 21st Century
The Future Combat System gives way to Mobile Protected Firepower
On October 12, 1999, then acting Head of the Joint Chiefs of Staff, General Eric Shinseki, outlined his vision of the future of the U.S. Army when he stated that it must be, “light enough to deploy, lethal enough to fight and win, survivable enough to return safely home . . . and lean and efficient enough to sustain themselves whatever the mission.” His comments echoed the desire of Donald Rumsfeld, acting Secretary of Defense the following year, to totally transform the U.S. Military into a force that could deploy and fight faster than ever before, anywhere in the world, and that could leverage new technologies and information systems as force multipliers that would ensure that this lighter and more nimble force could prevail over existing conventional forces of adversarial nations. This concept and the $200 billion dollar defense acquisition program that would aim to bring it to reality were christened the “Future Combat System” (FCS).
The FCS was the most expensive and most ambitious, most transformative modernization program ever undertaken by the U.S. Army. A minority of voices at the time, both inside and outside of government, believed that the program was too ambitious, would cost far too much and provide a far smaller advantage over potential adversaries than hoped. Regardless of this opposition, the program moved forward and transformed the U.S. Army into the fighting force it is today. Some aspects of the FCS were a success, while others came up lacking in many respects. Many would argue that the FCS program created a U.S. Army that is able to deploy more rapidly (marginally), yet lacks the necessary power, both in terms of firepower and armored capability that is required to confront a viable conventional adversary. Military modernization programs in China and Russia did not remain in stasis while the U.S. pursued the FCS concept. Both nations endeavored to modernize and increase the lethality of their military forces during the same period, and took quite different tacks along the journey to supremacy.
In many ways the FCS program was both a success and a failure. On June 23rd, 2009, the FCS acquisition program was officially cancelled. The reasons for the failure of many of the goals of FCS are multi-faceted, yet the corruption and waste inherent in the U.S. military-industrial complex bear a high degree of blame, not to mention many overly ambitious goals not rooted in reality, nor in the established historic experience of military science. The Stryker armored combat vehicle was a notable success, though not entirely advancing the “18 + 1 + 1” concept that was a core requirement of FCS. As FCS was abandoned, the U.S. Army realized that the modern battlefield required different tools, and that the U.S. Army required greater mobile firepower. This firepower would have to be packaged in a highly mobile, yet survivable platform. In the bigger picture, the Stryker fails to provide either.
Recognizing the failures of FCS, how does the U.S. Army plan to meet the military challenges of the 21st century? How will it leverage and improve legacy systems, such as the M1 Abrams MBT, M2 Bradley IFV, Stryker, and various self-propelled artillery systems to ensure battlefield dominance? What new armored and artillery systems are being developed to fill the void left unfulfilled by FCS? The Army is currently pursuing both of these courses in parallel, wisely choosing to strengthen proven combat platforms, while attempting to develop new ones. The U.S. Army is currently soliciting the defense industry for new armored vehicles to fulfill the newly adopted Mobile Protected Firepower (MPF) program, and finally taking delivery of new armored vehicles based on procurement plans initiated years ago. Perhaps the greatest challenge that the U.S. Army faces in this endeavor is the failed monetary policy of the state and the inherent waste and misallocation of funds inherent in the military research and development and acquisition process that has plagued the United States Armed Services for many decades now.
It is often hypothesized that the U.S. experience in the first Gulf War of 1991 and that of Task Force Hawk in the NATO Kosovo intervention of 1999, led to the desire for a more rapidly deployable U.S. Army expeditionary force. The overall technological superiority experienced by the anti-Iraq coalition during Operation Desert Storm, and to a marginally lesser degree in Operation Allied Force (against enemies with an outdated and antiquated air defense network, communications and information technology capability, and minimal real-time intelligence gathering ability) reinforced an overblown confidence in high-tech “smart” weaponry, and an over-reliance on tactical air power.
When Donald Rumsfeld took over as Defense Secretary in 2000, upon the start of George W. Bush’s first term as President, he made it known that he desired a full transformation of the U.S. military. He fully embraced and endorsed FCS. In a nutshell, FCS envisioned a highly mobile new Army, light enough to be air-deployable, yet lethal enough to survive on the modern battlefield. This survivability would be provided through the leveraging of new technologies, as well as superior command and control capabilities that would tie together all the various armed forces in a seamless information sharing and communications network. The Army set very high deployment goals, which would prove to be unattainable. General Shinseki stated that the Army would strive to attain the ability to deploy a combat brigade anywhere in the world within 96 hours, a full division within 120 hours, and no less than five divisions in 30 days.
Obviously, one of the most, if not the most challenging aspect of FCS, was that posed to military logistics. Logistics has proven to be the Achilles heel to many a military adventure over the millennia of human conflict, and FCS seemed to laugh in the face of history. Even though FCS utilized the most high-tech IT systems, inventory and supply chain management systems, and RFID cargo tracking technology, the goals that General Shinseki set out were far from attainable. It must also be noted that it has been the plan to deploy the assets of the U.S. Army in coordination with allied forces in almost every major contingency plan developed by the Pentagon since NATO was established. All of the above aims of FCS were exacerbated by the need to include many different, independent armed forces of many differing nationalities in the all-encompassing command, control, and logistics management system. In light of past and present NATO military cooperative challenges, this seems like the height of folly.
Often referred to as “18+1+1”, FCS envisioned 20 different components integrated together to form the new warfighting system. Eighteen new manned and unmanned vehicles were planned, one computer network integrating all components, communications, information and services, and most importantly, the fighting soldier. The original concept is illustrated in the below diagram:
Although most of the manned and unmanned vehicles envisioned by FCS were never developed or adopted by the U.S. Army, a number of them were substituted by existing systems, while others are still being developed. In many ways, the adoption of a highly mobile Brigade Combat Team by the U.S. Army was an interim step in trying to achieve some aspects of FCS. The main armored vehicle utilized by the Brigade Combat Team (now the Stryker Brigade Combat Team) is the Stryker. Although the Stryker lacks heavy armor protection, and less mobility than a tracked vehicle, it has proven to be highly adaptable to a multitude of roles and provides soldiers with an advanced command, control and targeting suite in a highly reliable package.
The U.S. Army underwent a major transformation during the Neo-Conservative years of regime change and occupation that occurred during the Bush and Obama presidencies. Many aspects of this transformation were planned, and many were reactions to the challenges posed by occupied nations where militant forces of opposition continually confronted the U.S. military. Many hard lessons were learned, mainly in the areas of urban warfare, the countering of IEDs, modern battlefield medicine and the use of irregular or Special Forces. The use of unmanned vehicles, both armed and unarmed was greatly relied upon and expanded during this time.
In many ways, the U.S. Army was designed to work with an integrated, multi-national NATO conventional land force in Western Europe during the many decades of the Cold War. It was realized early on that the U.S. Army would lack both the manpower and the total number of armored vehicles and artillery that the Soviet Union could bring to bear if a conventional war on the European continent actually broke out. The United States had to leverage its technological edge to produce qualitatively superior weapons systems, information sharing, communications and electronic warfare systems, and the ability through space-based reconnaissance capabilities, to tip the balance in its favor.
The U.S. Army still relies overwhelmingly on armored vehicle systems that were developed in the 1970s. The M1 Abrams Main Battle Tank (MBT), M2 Bradley Infantry Fighting Vehicle (IFV), M113 Armored Personnel Carrier (APC), M109 Paladin Self Propelled Howitzer, M270 Multiple Launcher Rocket System (MLRS), and even the ubiquitous High Mobility Multipurpose Wheeled Vehicle (HMMWV or Hummer) were developed decades ago to fight a highly mobile war against a numerically superior Soviet military. All of these systems are still in service with the U.S. Army today. These systems proved their worth in the last decade of the 20th century and into the first decade of the 21st century. They have worked as originally intended and when employed in a conventional war of maneuver, such as the first Gulf War (Operation Desert Storm) they provided the tools the U.S. Army required to fight and win. This victory must; however, be judged in light of the state of the Iraqi military and its far inferior capabilities in all measurable respects. Although the U.S. Army was pleased with the performance of its equipment and soldiers in this campaign, it was not at all pleased with the time required to field the required units needed to prosecute a military conflict on such a scale as Operation Desert Storm. The slow pace of deployment and multifaceted failures in the logistics management and transportation side of the campaign leading up to the conduct of combat operations was one of the leading case studies that lead to the desire to develop FCS.
Fast forward twelve years and the U.S. was once again invading Iraqi territory, this time during Operation Iraqi Freedom. By this time the U.S. Army had partially realized some aspects of FCS, mainly in the area of rapidly deploying combat ready forces of the Brigade size. Operation Iraqi Freedom was envisioned as a rapid invasion utilizing highly mobile, self-contained, combined-arms combat teams supported by overwhelming airpower. The Iraqi military was far weaker in 2003 than it had been in 1991. It was a shadow of its former self and had been repeatedly targeted, especially its air-defense and command and control networks. A combined ground force of approximately 148,000 men was deployed and ready for offensive operations in approximately a month and a half. Ground operations of the invasion lasted from March 20th until May 1st, 2003. The initial victory was impressive, but it soon became quite obvious that there was no realistic and pragmatic plan to occupy the country and render aid to a stable and capable new government.
The proponents of FCS felt vindicated by the apparent success of quickly deployable, highly mobile Brigade Combat Teams supported by some armored elements and self-propelled artillery, and safe under an umbrella of overwhelming air supremacy. This reinforced the U.S. Army’s faith in the concept. The resultant occupation would have a further, more damaging influence on the priorities of the service, leading its planners to mistakenly put far too much emphasis on developing and investing tens of billions of dollars into an armed force more adept at occupation than at actually engaging a capable conventional enemy on the battlefield. The U.S. Army was mistaken in believing that it could win a major conflict against a modern and capable adversary like the PLA or the Armed Forces of the Russian Federation with a ground force composed of armored HMMWVs, MRAPS and Strykers. A decade and a half of the occupations of Afghanistan and Iraq (although no longer officially recognized as such) have transformed the U.S. Army into a force incapable of winning decisively against adversaries that have used the same decade and a half developing a technologically advanced and far more deadly conventional warfighting capability. The U.S. Army must find the leadership, direction and planning focus to develop new armored fighting vehicles that can not only stand their own against their Russian and Chinese equivalents, but once again achieve a competitive edge.
Like most militaries the world over, the United States Army has made due with what it has for many decades. The “legacy” systems that the U.S. Army has been using since the 1970s and 1980s (and in the case of the M113 APC, since the Vietnam War) have been repeatedly improved since their adoption into service. These improvements have consisted of improved engines and drivetrain, modernized communications equipment, targeting and sensory upgrades, improved armor and improved weapons loadout. All of the core armored vehicles currently utilized by the U.S. Army are legacy systems.
M1A2 SEP “Abrams” MBT
The U.S. Army operates approximately 800 to 900 M1A2 SEP (System Enhancement Package) MBTs which are a significant improvement over the M1A1 and M1A2 models. The latest improvement on the venerable design is the SEPv.3 (version 3). The SEPv.3 achieves notable improvements in its fire control system, ballistics computer and thermal imaging sights. The tank is capable of both tracking and engaging multiple targets simultaneously, and affords the tank commander real-time friend and foe recognition via an upgraded battle management system. The tank is equipped with the CROWS remotely controlled weapons station. Thus, a crewmember does not have to expose himself outside the tank to fire the 12.7mm machine gun located on the top of the turret. The SEPv.3 has been strengthened against IED attacks, and has additional layers of graphite coated depleted uranium added to its composite armor. It is considered one of the best protected MBTs in the world.
One weakness that should be remedied, however; is the absence of an Active Protection System (APS). The importance of such systems has been proven during the latest year of the Syrian conflict, where numerous cases of T-90 tanks surviving anti-tank guide missile tanks attributed to the Shtora soft-kill APS have been documented. APS have proven to be of added importance in open desert terrain, where it is much more difficult for tank crews to take advantage of terrain features to mask their movement and remain out of “line-of-sight” from anti-tank teams equipped with modern infantry-borne anti-tank guided missiles (ATGMs). It has been proposed that the M1A2 SEPv.3 could be retrofitted with the Israeli Trophy APS currently in service with the Israeli Defense Force (IDF), which has proven effective against ATGMs and RPG attacks. Raytheon is currently developing the Quick Kill APS, a hard-kill system much like Trophy. The U.S. Army is currently evaluating a number of APS systems, which it hopes to adopt in 2017.
M2A3 “Bradley” IFV
The M2A1 and M2A2 proved their worth in the first Gulf War at transporting infantry, and engaging enemy infantry and armored vehicles. The Bradley was responsible for destroying more Iraqi tanks during Operation Desert Storm than the M1A2 Abrams MBT. The platform also proved quite reliable and agile on the modern battlefield. One weakness that was exhibited, but was clearly understood within the specifications of its design, was its low level of armor protection. A number of remedies to reduce vulnerability in this regard were researched and adopted by the time the IFV was once again used in Operation Iraqi Freedom.
The M2A3 incorporates a number of upgrades which will theoretically extend its life span out to 2030. The M2A3 comes in a number of variants, including Fire Support, Engineer, and Command vehicles, however; the M2A3 IFV is the chief variant. Although the armaments of the vehicle have not changed, the improved fire control system, thermal sights and the ability to track and engage multiple targets simultaneously adds to their lethality. The situational awareness of the crew is improved through the use of a modern battle management system, and integrates digital satellite communications and an Inertial Navigation System so that friend and foe can be tracked beyond line-of-sight in real-time.
The greatest weakness of the vehicle design was remedied by additional armor, including roof fragmentation protection and mounts for additional armor for use against shaped charge anti-armor munitions. The Bradley Urban Survivability Kit (BUSK) was also developed by the manufacturer BAE Systems, so that the vehicle can be tailored to combat in urban environments. Most of the knowledge that went into the development of BUSK (and TUSK for the M1A2 Abrams as well) came from urban warfare experience gained in Iraq and Afghanistan.
First adopted in 1960 and first used in combat in 1962, during the Vietnam War, the M113 APC is the most numerous and widely used armored vehicle in the U.S. military. Over 15 different variants have been produced, some of which still form the backbone of the mechanized formations of the U.S. Army. The M113’s hull is constructed from aluminum, and is supposed to protect the crew from 7.62 mm caliber small arms fire and shrapnel/splinters; however, combat experience has proven the armor protection to be inadequate. Although replaced by the M2A3 Bradley and Stryker in most frontline combat roles, the M113 is still used in a number of functions in a support role. The Brigade Combat Team utilizes more M113s than M2A3 Bradleys when considering the units overall Table of Organization and Equipment (TO&E). Expected to be replaced by the U.S. Army’s Armored Multi-Purpose Vehicle (AMPV) program, it is still unknown when the M113 will be retired from active service.
M109A6 “Paladin” Self-Propelled Artillery
The most widely used self-propelled artillery vehicle in the U.S. Army inventory is the M109 Paladin 155mm howitzer. The M109 was developed in the 1960s. It is a fully tracked vehicle with a fully traversable turret. The hull and turret are constructed of aluminum, the armor protecting the crew against small arms up to a caliber of 7.62mm, as well as shell splinters and shrapnel. The most modern version of the M109 is the M109A6 variant. It carries the M284 155mm howitzer and a crew serviced .50 caliber machine gun for protection against infantry. The M109 is equipped with an automatic fire control system, ballistic computer, and inertial positioning system which allows for great accuracy out to a range of 30km. This range is extended out to 40km when Excalibur guided munitions are employed.
Further development of the M109A7 Paladin Integrated Management (PIM) by BAE Systems was presented to the U.S. Army and approved by the Defense Acquisition Board in 2013. This program envisions the reworking of the vehicle chassis to incorporate as many components of the M2A3 Bradley as possible, so as to achieve commonality across the two platforms. This will lower logistics, inventory and maintenance costs considerably.
M270 MLRS Self-Propelled Rocket Artillery
The M270 Multiple Launch Rocket System (MLRS) is a 12 rocket, surface-to-surface rocket artillery system based on the M270 tracked chassis. The M270 tracked chassis is based on an elongated M2 Bradley vehicle. The fully tracked chassis provides good off-road mobility, allowing an MLRS battery to position itself, fire and relocate quickly with minimal restrictions due to terrain or obstacles. The MLRS system was used to great effect during both Iraq campaigns. Its high volume of fire, accuracy and rapid movement challenged the Iraqi military, who had no way to counter the threat with no operational airpower. With a far superior range to traditional artillery counter-battery fire, at up to 165km., the MLRS units could fire and reposition at will.
The M270A1 upgrade incorporates an improved fire control system, which can be programmed to be fired automatically, allowing a single crewmember to load and operate a launcher. The system can fire in salvo of one to twelve rockets, with the fire control system automatically re-calibrating and re-aiming each salvo if required in a matter of seconds. Its improved mechanics system allows for aiming within 16 seconds and the time required for reloading has been improved to three minutes. Lockheed Martin has produced two different munitions for the MLRS that offer increased range and accuracy over the initial ordinance. The M270 can launch the entire family of Army Tactical Missile System (ATACMS) missiles, some out to a range of 165km. Lockheed Martin developed the GMLRS (Guided MLRS) in 2002 and it is now a standard armament for the system. The GLMRS utilizes a GPS and inertial guidance system fitted in the nose of the XM30 rocket, which turns the rocket into a guided projectile. The XM30 also has an increased range of 70km.
MIM-104F “Patriot” and FIM-92 “Stinger” SP Air Defense
The main U.S. Army mobile air defense artillery systems are the short range FIM-92 Stinger and the long range MIM-104 Patriot. Both systems were developed in the 1970s and have been modernized and improved in the intervening decades. Both systems are highly mobile, and are flexible enough to be fielded in a number of different configurations. Although not normally mounted on armored vehicles, both systems are capable of being mounted to existing armored platforms. The Stinger has been mounted on the M2 Bradley IFV. This vehicle was designated the M6 Linebacker, and only 99 units were produced before orders were halted sighting the absence of airborne threats encountered in recent conflicts.
The most common vehicle mounted manifestation of the FIM-92 is the Avenger, which consists of a fully autonomous air defense package equipped with 8 missiles in two quad launchers in a turreted housing called the Pedestal Mounted Stinger (PMS). The PMS is mounted on a HMMWV. The PMS, which has an automated fire control system equipped with an optical tracker and forward looking infra-red system for target acquisition, can be removed from the vehicle and utilized separately. A full reload of 8 missiles is carried.
When the United States Army adopted FCS, it was realized early on that the armored vehicles that were called for to fulfill the eight manned systems of the “18+1+1” complement were not in existence, and would have to be designed, developed and produced. No legacy systems were considered, as the envisioned vehicles were supposed to all be from an entirely new, homogenous yet adaptable pattern. Although the M2 Bradley might have been easily adaptable to a number of roles, it lacked the desired air-portable weight, combat range, and lower operating cost desired by the FCS planners. In the interim, how did the U.S. Army hope to move along the path demanded by FCS for the rapid deployment of potent combat formations, equipped with both lethal and nimble armored vehicles?
It was clear that an Interim Armored Vehicle (IAV) was required. The U.S. Army issued an RFP (Request for Proposal) in early 2000, and in November of 2000, General Dynamics-General Motors Defense Canada (the Canadian subsidiary of the U.S. company) was awarded the contract to fulfill the U.S. Army’s contract to provide a new family of armored vehicles based on their existing LAV III vehicle. Originally based on the Swiss Piranha III 8×8, the Canadian LAV III was modified to meet the requirements of the initial contract, and since its adoption by the U.S. Army, continues to be modified and improved. Indeed, it has proven to be a very flexible and adaptable armored vehicle design. From the year 2000 to the present, almost 4,500 Strykers of all variants have been produced for the U.S. Army.
The Stryker has served the U.S. Army as a front line combat vehicle for approximately 16 years, and has been modified and improved periodically over that time span. The vehicle has had many supporters and detractors, both from within the military and the Congress. It must be acknowledged that the vehicle has performed its duties well beyond what was originally intended, as it was only supposed to fill in as a stop gap until purpose-designed FCS vehicles could be designed and acquired. The Stryker will most likely perform front line combat duties for many years to come, as future armored vehicle procurement programs such as Mobile Protected Firepower (MPF), Armored Multi-Purpose Vehicle (AMPV), and Joint Light Tactical Vehicle (JLTV) are yet incapable of supplying the needed vehicles.
There are eleven different variants of the Stryker, with a variant to cover all eight of the manned vehicle systems envisioned by FCS; however, the “Non-Line of Sight Cannon vehicle” was substituted by the M1128 Stryker Mobile Gun System (MGS). The M1128 mounts a 105mm M68A1E4 cannon, which is a light weight version of the original gun utilized in the M1A1 Abrams and M60 MBTs. The lightweight gun is equipped with a muzzle break to reduce recoil (which is quite important when utilizing a chassis as light as the M1128) and autoloader to improve rate of fire and to keep crew size minimal. Although incapable of non-line of sight supporting fire, the MGS offers the Brigade Combat Team direct line of sight supporting fire which can be targeted against defensive strong points and enemy armored vehicles.
The Stryker is a light armored vehicle, with all of the inherent benefits and drawbacks of such a vehicle. Although constructed of hardened steel, providing all around protection from 7.62mm small arms fire, and 14.5mm caliber in the front hull and glacis, the Stryker can be fitted with both slat armor and explosive reactive tiles for added protection. The addition of armor decreases the mobility of the vehicle by adding weight and overall size. The Stryker is an 8 wheeled vehicle, and although the tire pressure can be altered at will by the driver, and the vehicle can operate in 4×8 or 8×8 drive modes, it is inherently less maneuverable on all off-road terrain than a fully tracked vehicle. Its high center of gravity presents a roll-over threat at higher speeds, yet its ample ground clearance offers protection to the crew from casualties due to IEDs and land mines that strike with upward explosive force.
Although the M1128 MGS and M1134 ATGM (equipped with a TOW-2 dual launcher) offer Stryker equipped Brigade Combat Teams with an added anti-armor capability, the M1126 ICV is lightly armed. The M1126 ICV is equipped with a 12.7mm or 7.62mm machine gun, or a Mk19 40mm grenade launcher. The U.S. Army is currently planning to equip a small number of Strykers with the Orbital ATK XM813 variant of the Mk44 Bushmaster 30mm autocannon. The cannon will be mounted in a modified Kongsberg Medium Caliber Remote Weapons Station (MCRWS) and will provide greater offensive capability against light armored vehicles, structures and infantry.
Mobile Protected Firepower (MPF)
After the cancellation of the overly ambitious FCS program in 2009, the U.S. Army had not pursued the acquisition of a new armored combat vehicle until late this year. In the first half of August of 2016, the U.S. Army Training and Doctrine Command (TRADOC) located at Fort Benning, Georgia, invited almost 200 representatives from the defense industry to a meeting to discuss the desire to acquire a whole new type of vehicle. Dubbed “Mobile Protected Firepower” (MPF), the acquisition program is almost 180 degrees removed from past U.S. Army procurement failures. The U.S Army has decided to dispense with its overly bureaucratic acquisition system of past decades, and has instead had the TRADOC, the command that is most knowledgeable of what the Army requires, sit down directly with industry professionals from the very start to design a vehicle that takes existing technologies and capabilities to design a workable solution at minimal cost. Apparently, the U.S. Army has learned something from past failed programs such as FCS, AGV and the AGS.
In many respects the MPF project resembles the Armored Gun System (AGS) project that was cancelled in 1996. The AGS program resulted in the XM8 prototype, which was a lightly armored and fully tracked vehicle mounting a 105mm rifled tank gun. The XM8 was light and small enough to be air-dropped from a C-130 cargo aircraft. Indeed, the XM8 was slated to replace the M551 Sheridan light airborne tank used by the 18th Airborne Corps. The 18th Airborne Corps currently lacks an air droppable light tank or IFV, as the M551 was retired in 1996.
In concept, the MPF is seen as a highly mobile vehicle that is able to accompany and support Stryker Brigade Combat Teams and mobile and mechanized infantry formations, and aid reconnaissance-in-force missions. The MPF will be a fully tracked armored vehicle light and small enough to negotiate urban areas, and traverse poor roads and bridges in underdeveloped regions of the globe. Armor will be designed to protect against guns of .50 caliber or 14.5mm, and protection against shaped charge AT RPGs and ATGM is being considered. Main armament will most likely be a gun capable of destroying second or third generation MBTs, and equally effective in targeting and destroying defensive structures.
General Dynamics has already proposed the use of the chassis of its Ajax vehicle, being produced as an armored recon vehicle for the British Army, as a possible starting point for an acceptable MPF prototype. Named the Griffin, the vehicle mounts the XM-360 light weight 120mm rifled tank gun in a fully enclosed turret on the Chassis of the Ajax. The XM-360 gun was originally designed during the height of the FCS program. It is about 800 pounds lighter than the gun mounted on the M1 Abrams tank, is fitted with a muzzle break to reduce recoil, and is equipped with an autoloader to reduce the crew requirement by one man. Although still in the early stages of prototype development, the U.S. Army hopes to field an MPF vehicle by the mid-2020s.
Armored Multi-Purpose Vehicle (AMPV)
The U.S. Army has been in need of a replacement for the venerable M113 APC for quite some time now. First seeing combat during the Vietnam War, the M113 is still the backbone of the U.S. Army’s mechanized units. The Armored Multi-Purpose Vehicle (AMPV) program was initiated in March of 2013. BAE Systems was awarded the contract to supply the new vehicle in December of 2014. Just this month, BAE Systems unveiled the first production example of the AMPV General Purpose vehicle.
The AMPV is based on the M2 Bradley family of vehicle, and thus now shares many components with the Bradley and newly designed M6 Paladin. The increased commonality of vehicles will further reduce logistics costs, including maintenance, inventory and transport. Training and familiarization of crews and troops will also be simplified. Cost savings is a very big consideration in an atmosphere of increased scrutiny of massive cost overruns in many Department of Defense weapons programs. The AMPV program actually came in on schedule and on budget, a rarity in U.S. defense contracts in recent decades.
An M2 Bradley based vehicle to replace the M113 was extremely logical and offers many benefits over the older design. The new vehicle is much larger than the M113, offering 78% more internal volume. This is an important consideration when one considers the intended roles of the vehicle. Five variants are being produced as follows:
Probably the most important procurement program of the last quarter of a century for the U.S. Army, the AMPV will modernize the lifeblood of the services mechanized units. The first 3,000 units will be supplied to the active armored brigades over the next decade, while support and National Guard units may have to wait fifteen to twenty years to have their M113s replaced. It is often befuddling to try and find any reasoning in the priorities of military spending in the spider web of congressional spending bills, defense lobbying and general government bureaucracy. A modest reduction of spending in either of the failed F-35 Lightning Joint Strike Fighter or Littoral Combat Ship programs would greatly shorten the AMPV procurement timetable. The procurement of APMVs of all variants should be elevated in priority, considering the nature of the program. It is literally providing the workhorse vehicle to the U.S. Army.
Joint Light Tactical Vehicle
Although the Joint Light Tactical Vehicle (JLTV) is meant to replace a majority of the U.S. Army’s HUMMWVs, at least those in front line combat units, the new vehicle is quite different in function and purpose than the one it is meant to replace. The JLTV combines the utility of the HMMWV with increased mobility, armament, multiple modular armor protection packages, and the best IED defeating qualities of a Mine Resistant Ambush Protected vehicle (MRAP).
Oshkosh Defense, who produces the M-ATV for the U.S. military, was awarded the JLTV contract in the summer of 2015. The contract is worth an estimated $6.7 billion USD, and involves the delivery of 17,000 of the vehicles to both the U.S. Army and the U.S. Marine Corps. Both services plan on further procurement of JLTVs, 49,100 for the Army and 5,500 for the USMC, with a total estimated cost of over $30 billion USD. This level of procurement theoretically replaces roughly a third of the HMMWV fleets of both services.
The JLTV balances mobility, utility and protection in a proven combination of existing technologies. Although much more expensive to build and maintain than the HMMWV, the new vehicle will be much more capable, and will provide more options to battlefield commanders. At the core of the JLTV is the Banks 6.6 liter diesel engine, which can produce up to 360 horsepower, correcting one of the many faults of the HMMWV, which was powered by a 6.2 liter diesel that produced only 190 horsepower. Power to weight ratio; however, suffers when the 17,000lb. weight of the JTLV is considered. The JLTV is equipped with a 570 amp alternator that is not belt driven, instead being fitted between the engine and transmission, and less prone to failure. A high electric power output is required to run all of the sensory and communications equipment, allowing the crew to be tied to other units via real-time data networking. These systems provide greater, more accurate situational awareness and will help dissipate the fog of war, reducing costly decision making errors that could cost lives and lead to tactical mistakes.
The advances in armored vehicle design and procurement by the U.S. Army do not exist in a vacuum. What the U.S. Army likes to call “Near-Peer Nations”, which can be interpreted to mean Russia and China, have been at the cutting edge of modern military vehicle design. While Russia has been one of the greatest innovators of armored vehicle design since the 1930s, especially in the area of tank and self-propelled artillery systems, China has only come into prominence in the past two decades. Russia experienced great social and economic upheaval following the dissolving of the Soviet Union, but was able to achieve stability and a new reassertion of sovereignty under the leadership of Vladimir Putin. Putin reformed the country, and its military structures to a great degree, although there are still many inefficiencies and institutionalized weaknesses yet to be corrected. A more capitalist, free-market approach to weapons design and procurement has led to greater technological innovation and the realization of cost effective and efficient weapon systems. In comparison to Western nations, Russia gets far more “bang for its buck” in defense spending. This is not only due to a uniquely Russian view on warfare and weapons design, but is also the result of a conservative monetary policy and responsible national economic policy.
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China is classified as the second largest economy in the world, a title that is a bit misleading. China has a population of over 1.3 billion people, exports more than any other nation on earth, and its nominal GDP is second only to the United States, and by only a narrow margin. According to the International Monetary Fund (IMF), it is the largest economy when considering purchasing power parity. China has used a significant percentage of its economic power to invest in reinventing the Peoples’ Liberation Army (PLA). The force has been streamlined, professionalized, and modernized. China has finally started reaching some aspects of military power parity with Western nations. While China has increased military spending annually for the past ten years, this spending is still a tenth of that spent by the United States.
Russia officially unveiled the Armata Universal Combat Platform family of vehicles during the Victory Day parade of 2015. These vehicles are based on a totally new design, not a legacy system such as the T-72, T-90, BTR or BMP series of tracked and wheeled armored vehicles. The Armata will be the basis of the new MBT T-14, IFV T-15, APC, self-propelled artillery, engineer, armored recovery, and a number of other new armored military vehicles. Where the United States have chosen to build highly mobile, lightly armored vehicles as the basis of new weapons platforms, the Russian military has opted for a fully tracked, more heavily armored design.
The Bumerang 8×8 wheeled APC and IFV is the exception, and seems more in line with the Stryker than its predecessor, the BTR-80/82. The all new Kurganets-25 series vehicle, meant to replace the BMP in Russian front line service, follows the same pattern of a preference for fully tracked and heavily armored vehicles. The APC is equipped with an APS, and both vehicles appear to utilize explosive reactive armor modules that are also designed to counter shaped charged AT projectiles. Both wheeled and tracked vehicles are fully amphibious, adding to their mobility.
China has spent a great deal of its military expenditures on its strategic missile forces and navy, yet the PLA has also been able to modernize its front line armored vehicles. The Type 96A and Type 99A2 MBTs, PLZ05 SP 155mm howitzer, and ZBD05 and ZLT05 series amphibious assault vehicles are all examples of China’s growing technological achievement in the area of mobile land combat systems. Although still behind the curve compared to Russia and the United States, China is rapidly closing the gap.
The Type 99A2, although based on the Russian T-72, has been so heavily altered and improved as to render it a new tank design. It is considered a third generation MBT, and due to its high costs relative to older PLA tanks, it has been fielded in limited numbers, with less than 1000 units of the Type99 of all variants in active service. Type 99A2 model MBTs currently number between 200 and 250 units. With no combat experience to analyze and compare, it is estimated that the Type 99A2 is comparable in capabilities to the M1A2 Abrams, T-90 and Leopard 2A4.
One of the most overlooked developments in Chinese military modernization, is the expansion of the PLA’s amphibious warfare capability. The ZBD05 amphibious assault vehicles provide increased flexibility and mobility to Chinese military planners, especially in regard to possible military conflicts over Taiwan and islands in the East and South China Seas. The ZBD05 is the fastest amphibious assault vehicle in the world, capable of speeds of 45kph (28 mph) in the water. By contrast, the U.S. Marine Corps has been struggling to acquire a next generation amphibious assault vehicle to replace its aging AAV7, with one problem being the requirement for high sustained speed at sea. The ZBD05 series vehicles are in service with the four Amphibious Mechanized Infantry Divisions (AMID) of the PLA, and the two PLA Marine Corps Brigades. The ZBD05 is troop carrying AAV, while the ZLT05 is basically an amphibious light tank armed with a 105mm rifled cannon.
Another interesting development in Chinese armored vehicle design is the official unveiling of a new light tank, the ZT5. Although the manufacturer, NORINCO, has stated that the vehicle was produced for the export market exclusively, this is rather hard to believe. The PLA used the old Soviet designed PT-76 amphibious light tank extensively for decades, and is retiring it from service. The PLA could benefit greatly from a highly mobile armored vehicle such as the ZT5, for all of the same reasons that the U.S. Army desires the MPF vehicle. The tank is armed with a fully stabilized 105mm main gun and advanced fire control system, is equipped with a passive protection system and laser detector to combat ATGMs, and weighs in at between 33 and 36 tons. The vehicle is air-portable in large military cargo aircraft.
The military conflicts in the Middle East and the Eastern Ukraine over the past four years have given military commanders, strategists and analysts a great deal to think about. A number of lessons should be learned, or more accurately put, re-learned regarding the proper utilization of tanks and light armored vehicles in both urban and open terrain. In many respects, some lessons that were learned during the global conflict of the Second World War have apparently been forgotten. Technology will advance, creating more mobile, protected and lethal armored fighting vehicles. As true as this fact is, technology will also advance in lock step in the area of infantry transportable anti-armor weapons. Most importantly of all, no new technology can ever replace the understanding and adherence to sound tactical doctrine regarding both competing forms of warfare on the battlefield.
The conflicts in Syria, Yemen, and Iraq have shown the continued vulnerability of all types of modern armored vehicles, including second and third generation main battle tanks. The destruction of M1A2 Abrams, M60T Sabra, T-72s and most recently Leopard 2A3 tanks, have all been witnessed and documented over the past two years. Most tank casualties came at the hands of small teams of infantry or insurgents utilizing ATGM systems that were designed decades ago. U.S. made TOW, Russian Fagot, Konkurs and Kornet, and Chinese HJ-8 ATGMs have been widely used in the Syrian conflict. The proliferation of these easy to use systems across the region is evident in their use in the conflicts ongoing in Yemen and Iraq as well.
While the ease at which the older generation ATGMs have defeated modern MBTs has been surprising to some, their success only verifies the competence of the engineers that designed them and the armor-defeating concepts by which they achieve their effectiveness. Any student of military science and history can find parallels in the tank vs. infantry duels of the last year of WWII when the combatants of all sides struggled to invent countermeasures for the increasingly effective rocket-propelled, shaped charge anti-tank weapons hiding around every urban corner, hedgerow or slit trench.
The only effective countermeasures were disciplined fire and movement by tankers, and the accompaniment of infantry with armor in urban areas, or any terrain that greatly restricted vehicle movement. In addition, in open terrain, vigilant reconnaissance by infantry scouts and light vehicles in both short and longer distances from armored formations helped to locate and liquidate infantry tank-killer teams. In most cases of main battle tanks lost in Syria and Yemen, the success of the attacks were more dependent on the targeted force not practicing the above countermeasures. No amount of high tech equipment will ever be a substitute for highly trained and experienced soldiers that can put proven combat doctrine into practice.
Armored battles in the eastern Ukraine involved Soviet designed tanks, mostly T-64 and T-72 variants. Large numbers of BMP, BTR, BRDM, and MTLB armored vehicles have been fielded by both sides in the conflict. The DPR and LPR militias were very successful in isolating and destroying Ukrainian tanks with small teams armed with RPGs and Konkurs and Kornet ATGMs. Some Ukrainian armored formations were decimated by accurately spotted artillery barrages. In many cases, UAVs were used to help aid in targeting for the artillery batteries. Militia tankers were far more successful at practicing proper fire and movement doctrine, and experienced fewer losses than their adversaries in the heavy encirclement battles of Ilovaisk and Debaltseve. The militias were trained increasingly by Russian military advisers and Russian volunteers with past military experience in Afghanistan and Chechnya. The Russians obviously still understand how to best utilize armor and minimize threats, and at the same time how best to hunt and kill armor with infantry tank-killer teams. This has been exhibited for all the world to see in the combat results of the Ukraine in 2014 and 2015.
The U.S. Army has been plagued with costly acquisition failures in recent decades, chief amongst them the FCS program. This $200 billion USD program initiated in 2000, failed to produce results on so many levels and was abandoned by 2009. The AGV and AGS programs also wasted tens of billions of dollars before being cancelled without achieving their intended goals. These programs were chiefly defeated by an overly bureaucratic Army acquisition system, and the fact that the Army had asked for far too much from the defense industry, demanding many new and unproven technological advancements.
The U.S. Army seemed to acknowledge its own failures in recent years, and revised its acquisition process in a number of key areas. The AMPV, JLTV and MPS programs illustrate a more pragmatic approach, aiming for more realistic goals and relying on improving upon existing, proven technology. However, over two decades were lost on pouring vast amounts of money into failed programs. That investment is gone forever, and the U.S. Army is playing catch-up to acquire the armored vehicles desperately required to replace aged and outdated fleets. With the first units of the AMPV finally being delivered this December, thousands of vehicles are needed to replace the M113 series in all of the U.S. Army’s mechanized units. The JLTV vehicle has also entered production, but tens of thousands of these vehicles are required to replace the HMMWVs in front line combat units. It remains to be seen how financial constraints will effect these programs, as a new Trump administration, which has vowed to strengthen and rebuild the U.S. military, takes over executive functions in January of 2017.
The leadership of the U.S. Army is faced with the challenge of maintaining a material and technological edge over its “Near-Peer” challengers, Russia and China. Although the defense strategies of both these nations seem far more focused on developing Anti-Access/ Area Denial (A2/AD) capabilities to guard their sovereignty and protect their national interests, both have developed impressive armored vehicles during the years when the U.S. Army was throwing money down the drain. The battlefield accomplishments of the Russian T-90 MBT and TOS-1 Self-Propelled Rocket Artillery have been demonstrated in Syria, with the T-90 being the only advanced tank in theater proven to survive ATGM attacks on more than one occasion. New Chinese armored vehicles, though unproven in combat, are surely drawing the interested attention of the U.S. defense industry and the U.S. Army top leadership.
It appears that the U.S. Army has finally turned the page on its failed acquisition efforts, and is progressing in the right direction; however, it must rely on updated legacy systems for at least another decade before new vehicles start making their presence felt in significant numbers. These legacy systems are combat proven, albeit against non-peer opponents, but their capabilities cannot be denied. The soldiers and officers of the U.S. Army can take comfort in this fact, yet must also now face the reality of a modern battlefield filled with vast numbers of ATGMs (thanks in part to the actions of their own government) and men versed in the successful employment of such weapons. In many respects, the last actions of the Obama administration in waiving restrictions on the proliferation of advanced arms to non-state actors in the Middle East, has only made the future battlefields the U.S. Army may be called to fight upon a much more dangerous place.
The Death Star weapon is here! Japan fires world's most powerful laser to produce energy equal to 1,000 times the planet's power consumption
Japan claims to have fired the most powerful laser ever created.
Researchers in Osaka were able to produce a 2-petawatt laser beam using a device known as the Laser for Fast Ignition Experiment (LFEX).
The power of the 'Death Star'-like beam is equivalent to 1,000 times the world's total electricity consumption, the scientists claim.
The 328ft (100 metre)-long LFEX device has strategically-placed glass panels that are used to amplify the laser beam. The team were able to produce such a high output by concentrating the power to 1 pico-second, or around a trillionth of a second
While it produced a huge amount of power, the energy required for the beam itself is equivalent to that needed to power a microwave for two seconds.
The team were able to produce such a high output from low energy by only firing the laser beam for 1 pico-second, or a trillionth of a second.
To amplify the beam's power, energy was applied to strategically-placed glass panels along the 328ft (100 metre)-long LFEX device.
These glass lamps were able focus the beam to boost its energy as it passed through.
In the experiment, energy was applied to glass sections using devices similar to fluorescent lamps. These glass lamps were used to boost the energy of the beam as it passed through
HOW POWERFUL IS IT?
The device produced a 2-petawatt - or 2 quadrillion-watt - laser beam.
This is equivalent to 1,000 times the world's electricity consumption.
To put that in context, Rheinmetall Defense was recently able to shoot a drone down a mile away using a 50kW laser.
The 50kW laser was 10 billion times less powerful that the one used in Japan.
Up until today's announcement, the world has only ever within a 1-pettawatt laser created by the University of Texas, Austin.
'With heated competition in the world to improve the performance of lasers, our goal now is to increase our output to 10 petawatts,' said the institute's Junji Kawanaka, an associate professor of electrical engineering at the university
To put that into context, according to Popular Science, a 50,000 watt laser successfully took down a drone just a mile away.
That 50kW laser was 10 billion times less powerful that the one used in Japan.
Up until today's announcement, the world has only ever witnessed a 1-pettawatt laser created by the University of Texas, Austin.
Not only did the Japanese laser generate twice as much power, but the team says it also has 100 times as much energy as its Texas rival.
The laser, liked to the Death Star laser in Star Wars, is currently mainly of scientific interest rather than having any real-world purpose.
Details of the experiment have been published in the journal Plasma Physics and Controlled Fusion.
Researchers in Osaka were able to produce a 2-petawatt - or 2 quadrillion-watt - laser beam using the Laser for Fast Ignition Experiments (LFEX). This is equivalent to 1,000 times the world's electricity consumption, causing the laser to be compared to that on the Death Star in Star Wars (pictured)
Thursday, April 20, 2017
Armored off-roader is capable of withstanding blasts from ballistic missiles:The Death Star weapon is here! equal to 1,000 times the planet's power consumption
Posted by ASC at 12:41 PM