Tag The Evolution of Weapons and Warfare

Frickin’ Laser Beams

This is a fascinating short advertising video from British Aerospace Engineering Systems (BAE Systems) teasing the potential of laser beam weapons. It addresses the concept of using airborne lasers to create atmospheric lenses by temporarily heating and ionizing the atmosphere to enable long-range aerial surveillance and targeting. The same concept can also be used to counter anti-aircraft laser fire from ground platforms.

BAE Systems has been working on the military applications of lasers for a while, from laser tracking systems, aerial laser-guided rockets, and high energy lasers for shipborne point defense. The U.S. Army is working with General Dynamic to add lasers to its vehicles for point defense as well. Lasers have been used for military purposes for a long time and there is great anticipation for their potential. While the current state of laser technology may have its limitations, the future of warfare may well go pew-pew.

What Is The Relationship Between Rate of Fire and Military Effectiveness?

marine-firing-m240Over at his Best Defense blog, Tom Ricks recently posed an interesting question: Is rate of fire no longer a key metric in assessing military effectiveness?

Rate of fire doesn’t seem to be important in today’s militaries. I mean, everyone can go “full auto.” Rather, the problem seems to me firing too much and running out of ammunition.

I wonder if this affects how contemporary military historians look at the tactical level of war. Throughout most of history, the problem, it seems to me, was how many rocks, spears, arrows or bullets you could get off. Hence the importance of drill, which was designed to increase the volume of infantry fire (and to reduce people walking off the battlefield when they moved back to reload).

There are several ways to address this question from a historical perspective, but one place to start is to look at how rate of fire relates historically to combat.

Rate of fire is one of several measures of a weapon’s ability to inflict damage, i.e. its lethality. In the early 1960s, Trevor Dupuy and his associates at the Historical Evaluation Research Organization (HERO) assessed whether historical trends in increasing weapon lethality were changing the nature of combat. To measure this, they developed a methodology for scoring the inherent lethality of a given weapon, the Theoretical Lethality Index (TLI). TLI is the product of five factors:

  • rate of fire
  • targets per strike
  • range factor
  • accuracy
  • reliability

In the TLI methodology, rate of fire is defined as the number of effective strikes a weapon can deliver under ideal conditions in increments of one hour, and assumes no logistical limitation.

As measured by TLI, increased rates of fire do indeed increase weapon lethality. The TLI of an early 20th century semi-automatic rifle is nearly five times higher than a mid-19th century muzzle-loaded rifle due to its higher rate of fire. Despite having lower accuracy and reliability, a World War II-era machine gun has 10 times the TLI of a semi-automatic rifle due to its rate of fire. The rate of fire of small arms has not increased since the early-to-mid 20th century, and the assault rifle, adopted by modern armies following World War II, remains that standard infantry weapon in the early 21st century.

attrition-fig-11

Rate of fire is just but one of many factors that can influence a weapon’s lethality, however. Artillery has much higher TLI values than small arms despite lower rates of fire. This is for the obvious reasons that artillery has far greater range than small arms and because each round of ammunition can hit multiple targets per strike.

There are other methods for scoring weapon lethality but the TLI provides a logical and consistent methodology for comparing weapons to each other. Through the TLI, Dupuy substantiated the observation that indeed, weapons have become more lethal over time, particularly in the last century.

But if weapons have become more lethal, has combat become bloodier? No. Dupuy and his colleagues also discovered that, counterintuitively, the average casualty rates in land combat have been declining since the 17th century. Combat casualty rates did climb in the early and mid-19th century, but fell again precipitously from the later 19th century through the end of the 20th.

attrition-fig-13

The reason, Dupuy determined, was because armies have historically adapted to increases in weapon lethality by dispersing in greater depth on the battlefield, decentralizing tactical decision-making and enhancing mobility, and placing a greater emphasis on combined arms tactics. The area occupied by 100,000 soldiers increased 4,000 times between antiquity and the late 20th century. Average ground force dispersion increased by a third between World War II and the 1973 Yom Kippur War, and he estimated it had increased by another quarter by 1990.

attrition-fig-14

Simply put, even as weapons become more deadly, there are fewer targets on the battlefield for them to hit. Through the mid-19th century, the combination of low rates of fire and relatively shorter range required the massing of infantry fires in order to achieve lethal effect. Before 1850, artillery caused more battlefield casualties than infantry small arms. This ratio changed due to the increased rates of fire and range of rifled and breach loading weapons introduced in the 1850s and 1860s. The majority of combat casualties in  conflicts of the mid-to-late 19th century were inflicted by infantry small arms.

attrition-fig-19The lethality of modern small arms combined with machine guns led to further dispersion and the decentralization of tactical decision-making in early 20th century warfare. The increased destructiveness of artillery, due to improved range and more powerful ammunition, coupled with the invention of the field telephone and indirect fire techniques during World War I, restored the long arm to its role as king of the battlefield.

attrition-fig-35

Dupuy represented this historical relationship between lethality and dispersion on the battlefield by applying a dispersion factor to TLI values to obtain what he termed the Operational Lethality Index (OLI). By accounting for these effects, OLI values are a good theoretical approximation of relative weapon effectiveness.

npw-fig-2-5Although little empirical research has been done on this question, it seems logical that the trend toward greater use of precision-guided weapons is at least a partial response to the so-called “empty battlefield.” The developers of the Third Offset Strategy postulated that the emphasis on developing precision weaponry by the U.S. in the 1970s was a calculated response to offset the Soviet emphasis on mass firepower (i.e. the “second offset”). The goal of modern precision weapons is “one shot, one kill,” where a reduced rate of fire is compensated for by greater range and accuracy. Such weapons have become sufficiently lethal that the best way to survive on a modern battlefield is to not be seen.

At least, that was the conventional wisdom until recently. The U.S. Army in particular is watching how the Ukrainian separatist forces and their Russian enablers are making use of new artillery weapons, drone and information technology, and tactics to engage targets with mass fires. Some critics have alleged that the U.S. artillery arm has atrophied during the Global War on Terror and may no longer be capable of overmatching potential adversaries. It is not yet clear whether there will be a real competition between mass and precision fires on the battlefields of the near future, but it is possible that it signals yet another shift in the historical relationship between lethality, mobility, and dispersion in combat.

SOURCES

Trevor N. Dupuy, Attrition: Forecasting Battle Casualties and Equipment Losses in Modern War (Falls Church, VA: NOVA Publications, 1995)

_____., Understanding War: History and Theory of Combat (New York: Paragon House, 1987)

_____. The Evolution of Weapons and Warfare (Indianapolis, IN: The Bobbs-Merrill Company, Inc., 1980)

_____. Numbers, Predictions and War: Using History to Evaluate Combat Factors and Predict the Outcome of Battles (Indianapolis; New York: The Bobbs-Merrill Co., 1979)

Unmanned Ground Vehicles: Drones Are Not Just For Flying Anymore

The Remote Controlled Abrams Tank [Hammacher Schlemmer]
The Remote Controlled Abrams Tank [Hammacher Schlemmer]

Over at Defense One, Patrick Tucker reports that General Dynamics Land Systems has teamed up with Kairos Autonomi to develop kits that “can turn virtually anything with wheels or tracks into a remote-controlled car.” It is part of a business strategy “to meet the U.S. Army’s expanding demand for unmanned ground vehicles”

Kairos kits costing less than $30,000 each have been installed on disposable vehicles to create moving targets for shooting practice. According to a spokesman, General Dynamics has also adapted them to LAV-25 Light Armored Vehicles and M1126 Strykers.

Tucker quotes Lt. Gen. H.R. McMaster (who else?), director of the U.S. Army’s Capabilities Integration Center, as saying that,

[G]etting remotely piloted and unmanned fighting vehicles out into the field is “something we really want to move forward on. What we want to do is get that kind of capability into soldiers’ hands early so we can refine the tactics, techniques and procedures, and then also consider enemy countermeasures and then build into the design of units that are autonomy enabled, build in the counter to those counters.”

According to General Dynamics Land Systems, the capability to turn any vehicle into a drone would give the U.S. an advantage over Russia, which has signaled its intent to automate versions of its T-14 Armata tank.

Technology, Eggs, and Risk (Oh, My)

Tokyo, Japan --- Eggs in a basket --- Image by © JIRO/Corbis
Tokyo, Japan — Eggs in a basket — Image by © JIRO/Corbis

In my last post, on the potential for the possible development of quantum radar to undermine the U.S. technological advantage in stealth technology, I ended by asking this question:

The basic assumption behind the Third Offset Strategy is that the U.S. can innovate and adopt technological capabilities fast enough to maintain or even expand its current military superiority. Does the U.S. really have enough of a scientific and technological development advantage over its rivals to validate this assumption?

My colleague, Chris, has suggested that I expand on the thinking behind this. Here goes:

The lead times needed for developing advanced weapons and the costs involved in fielding them make betting on technological innovation as a strategy seem terribly risky. In his 1980 study of the patterns of weapon technology development, The Evolution of Weapons and Warfare, Trevor Dupuy noted that there is a clear historical pattern of a period of 20-30 years between the invention of a new weapon and its use in combat in a tactically effective way. For example, practical armored fighting vehicles were first developed in 1915 but they were not used fully effectively in battle until the late 1930s.

The examples I had in mind when I wrote my original post were the F-35 Joint Strike Fighter (JSF) and the Littoral Combat Ship (LCS), both of which derive much, if not most, of their combat power from being stealthy. If that capability were to be negated even partially by a technological breakthrough or counter by a potential adversary, then 20+ years of development time and hundreds of billions of dollars would have been essentially wasted. If either or both or weapons system were rendered ineffective in the middle of a national emergency, neither could be quickly retooled nor replaced. The potential repercussions could be devastating.

I reviewed the development history of the F-35 in a previous post. Development began in 2001 and the Air Force declared the first F-35 squadron combat operational (in a limited capacity) in August 2016 (which has since been stood down for repairs). The first fully combat-capable F-35s will not be ready until 2018 at the soonest, and the entire fleet will not be ready until at least 2023. Just getting the aircraft fully operational will have taken 15-22 years, depending on how one chooses to calculate it. It will take several more years after that to fully evaluate the F-35 in operation and develop tactics, techniques, and procedures to maximize its effectiveness in combat. The lifetime cost of the F-35 has been estimated at $1.5 trillion, which is likely to be another underestimate.

The U.S. Navy anticipated the need for ships capable of operating in shallow coastal waters in the late 1990s. Development of the LCS began in 2003 the first ships of two variants were launched in 2006 and 2008, respectively. Two of each design have been built so far. Since then, cost overruns, developmental problems, disappointing performances at sea, and reconsideration of the ship’s role led the Navy to scale back a planned purchase of 53 LCSs to 40 at the end of 2015 to allow money to be spent on other priorities. As of July 2016, only 26 LCSs have been programmed and the Navy has been instructed to select one of the two designs to complete the class. Initial program procurement costs were $22 billion, which have now risen to $39 billion. Operating costs for each ship is currently estimated at $79 million, which the Navy asserts will drop when simultaneous testing and operational use ends. The Navy plans to build LCSs until the 2040s, which includes replacements for the original ten after a service life of 25 years. Even at the annual operating cost of a current U.S. Navy frigate ($59 million), a back of the envelope calculation for a lifetime cost for the LCS is around $91 billion, all told; this is also likely an underestimate. This seems like a lot of money to spend on a weapon that the Navy intends to pull out of combat should it sustain any damage.

It would not take a technological breakthrough as singular as quantum radar to degrade the effectiveness of U.S. stealth technology, either. The Russians claim that they already possess radars that can track U.S. stealth aircraft. U.S. sources essentially concede this, but point out that tracking a stealth platform does not mean that it can be attacked successfully. Obtaining a track sufficient to target involves other technological capabilities that are susceptible to U.S. electronic warfare capabilities. U.S. stealth aircraft already need to operate in conjunction with existing EW platforms to maintain their cloaked status. Even if quantum radar proves infeasible, the game over stealth is already afoot.

Quantum Radar: Should We Be Putting All Our Eggs In The Technology Basket?

Corporal Walter "Radar" O'Reilly (Gary Burghoff) | M*A*S*H
Corporal Walter “Radar” O’Reilly (Gary Burghoff) | M*A*S*H

As reported in Popular Mechanics last week, Chinese state media recently announced that a Chinese defense contractor has developed the world’s first quantum radar system. Derived from the principles of quantum mechanics, quantum radar would be capable of detecting vehicles equipped with so-called “stealth” technology for defeating conventional radio-wave based radar systems.

The Chinese claim should be taken with a large grain of salt. It is not clear that a functional quantum radar can be made to work outside a laboratory, much less adapted into a functional surveillance system. Lockheed Martin patented a quantum radar design in 2008, but nothing more has been heard about it publicly.

However, the history of military innovation has demonstrated that every technological advance has eventually resulted in a counter, either through competing weapons development or by the adoption of strategies or tactics to minimize the impact of the new capabilities. The United States has invested hundreds of billions of dollars in air and naval stealth capabilities and built its current and future strategies and tactics around its effectiveness. Much of the value of this investment could be wiped out with a single technological breakthrough by its potential adversaries.

The basic assumption behind the Third Offset Strategy is that the U.S. can innovate and adopt technological capabilities fast enough to maintain or even expand its current military superiority. Does the U.S. really have enough of a scientific and technological development advantage over its rivals to validate this assumption?

XM-25 “Punisher”: Not Dead Yet

"Bring out your dead!" Monty Python and the Holy Grail (1975)
“Bring out your dead!” Monty Python and the Holy Grail (1975)

As I mentioned recently, the U.S. Army is in the process of deciding whether or not to proceed with the XM-25 Counter Defilade Target Engagement System, a precision targeted, shoulder-fired 25mm grenade launcher. The Defense Department’s Inspector General’s office released a pointedly critical evaluation of the weapon nicknamed “the Punisher” in August. Among the negative reviews the report cited was one from the Army Capabilities and Integration Center, directed by Lieutenant General H.R. McMaster. McMaster’s office has had a change of heart about the XM-25 since that evaluation, however.

“My initial assessment from 2013 did not reflect 30 additional months of testing and improvements to the XM25 Counter Defilade Target Engagement System,” McMaster told Military.com in an email.

“The Army has worked closely with the system’s prime contractor to address the safety issues on the XM25 through engineering design changes and improvements to the system. Prototypes employed during two Forward Operational Assessments allowed the Army to learn from and correct system shortcomings, and feedback has been positive.”

The XM25 is not a simple grenade launcher, McMaster maintains. The sight has an integrated day/thermal sight, a laser range finder, and a ballistic computer working in unison to allow the shooter to effectively engage enemy targets under cover.

The weapon is semi-automatic with a five-round magazine that ensures effective fires and rapid re-engagement, as necessary, in all operational environments — jungle, urban, day/night, woodland, subterranean and desert, McMaster said.

“Worldwide urbanization, coupled with the extensive proliferation of rocket propelled grenades and machine guns, allowed our enemies to exploit our desire to end engagements with minimal collateral damage,” McMaster said.

“The XM25 provides an innovative capability that mitigates this vulnerability and minimizes operational risks facing our soldiers, limiting collateral damage in the surrounding area while allowing our dismounted squads to decisively end firefights.”

The Army has indicated that it will make a determination on the XM-25’s future by the end of September.

The Saga of the F-35: Too Big To Fail?

Lockheed Upbeat Despite F-35 Losing Dogfight To Red Baron (Image by DuffelBlog)
Lockheed Upbeat Despite F-35 Losing Dogfight To Red Baron (Image by DuffelBlog)

Dan Grazier and Mandy Smithberger provide a detailed run down of the current status of the F-35 Joint Strike Fighter (JSF) over at the Center for Defense Information at the Project On Government Oversight (POGO). The Air Force recently declared its version, the F-35A, combat ready, but Grazer and Smithberger make a detailed case that this pronouncement is “wildly premature.”

The Pentagon’s top testing office warns that the F-35 is in no way ready for combat since it is “not effective and not suitable across the required mission areas and against currently fielded threats.”

As it stands now, the F-35 would need to run away from combat and have other planes come to its rescue, since it “will need support to locate and avoid modern threats, acquire targets, and engage formations of enemy fighter aircraft due to outstanding performance deficiencies and limited weapons carriage available (i.e., two bombs and two air-to-air missiles).”

In several instances, the memo rated the F-35A less capable than the aircraft we already have.

The F-35’s prime contractor, Lockheed Martin, is delivering progressively upgraded versions of the aircraft in blocks, but the first fully-combat operational block will not be delivered until 2018. There are currently 175 operational F-35s with limited combat capability, with 80 more scheduled for delivery in 2017 and 100 in 2018. However, the Government Accountability Office estimates that it will cost $1.7 billion to retroactively upgrade these 335 initial F-35s to full combat ready status. Operational testing and evaluation of those rebuilt aircraft won’t be completed until 2021 and they will remain non-combat capable until 2023 at the earliest, which means that the original 355 F-35s won’t really be fully operational for at least seven more years, or 22 years after Lockheed was awarded the development and production contract in 2001. And this is only if the JSF Program and Lockheed manage to hit their current targets with a program—estimated at $1.5 trillion over its operational life, the most expensive weapon in U.S. history—characterized by delays and cost overruns.

With over $400 billion in sunk costs already, the F-35 program may have become “too big to fail,” with all the implications that phrase connotes. Countless electrons have been spun assessing and explaining this state of affairs. It is possible that the problems will be corrected and the F-35 will fulfill the promises made on its behalf. The Air Force continues to cast it as the centerpiece of its warfighting capability 20 years from now.

Moreover, the Department of Defense has doubled-down on the technology-driven Revolution in Military Affairs paradigm with its Third Offset Strategy, which is premised on the proposition that advanced weapons and capabilities will afford the U.S. continued military dominance into the 21st century. Time will tell if the long, painful saga of the F-35 will be a cautionary tale or a bellwether.

Will This Weapon Change Infantry Warfare Forever? [UPDATE]

XM-25 Counter-Defilade Engagement SystemIt appears that the Army’s XM-25 Counter-Defilade Target Engagement System, a shoulder-fired 25mm grenade launcher, may not get the opportunity to fulfill its destiny as the Weapon That Will Change Infantry Warfare Forever after all.

Military.com reports that the Department of Defense’s Inspector General’s Office has recommended that the Assistant Secretary of the Army, Acquisition, Logistics and Technology, Katrina McFarland, “determine whether to proceed with or cancel the XM25 program after reviewing the results of the 2016 Governmental testing,” which will be completed this fall. The Army has indicated that it concurs with the recommendation.

The Army delayed acquisition funding and extended the XM-25’s development phase in 2014 in response to problems encountered during field testing and critiques of the weapon by the 75th Ranger Regiment and the Army’s Maneuver Center of Excellence. During a live-fire exercise in 2013, an XM-25 “experienced a double feed and an unintentional primer ignition of one of the 25mm high explosive rounds,” which fortunately, caused only minor injuries to the soldier testing it, but potentially could have been much worse.

More consequentially for the XM-25 program, the Rangers found that infantry squad soldiers assigned to wield it could not also carry a rifle due to the extra weight. This limited the ability of the XM-25 bearer to perform battle drills and deprived the squad of a rifle in close range combat. The XM-25 also quickly depleted all of its 36 rounds in action. As a result, the Rangers declined to use an XM-25 in an assault on a fortified compound in Afghanistan in 2013, on the grounds that the weapon’s limited utility did not justify leaving out an M4A1 carbine.

The DOD IG criticized the Army for not specifying the exact costs of the extended development and for declining to state how many XM-25s it is considering initially procuring. Stay tuned…

So You Still Think You Want A Revolution In Military Affairs?

The Paladin M109A7 next-generation artillery system being manufactured by BAE Systems is a significant upgrade to the combat-proven M109A6 Paladin cannon artillery system. [www.army-technology.com]
Even as the U.S. Army examines ongoing “hybrid” conflicts and tries to conceptualize what wars of the near future are going to be like, it’s leaders continue to believe that a technology-driven Revolution in Military Affairs remains in the cards.

“I think we are on the cusp of a fundamental change in the character of ground warfare,” U.S. Army chief of staff Gen. Mark Milley told an audience at the Center for Strategic and International Studies in Washington, D.C., on June 23. “It will be of such significance that it will be like the rifling of a musket or the introduction of a machine gun or it will have such significance impact as the change from horse to mechanized vehicles.”

Revolutionary new technologies such as nanotechnology, robotics and artificial intelligence will drive that fundamental change. But while Milley said that a revolution is coming, how exactly the character of ground warfare will shape up remains an open question. “Exactly what that’s going to look like, I don’t know,” Milley said. “I just know that we’re there. We’re on the leading edge of it. I think we’ve got a few years to figure it out—probably less than ten. But I think by 2025, you’re going to see armies—not only the American Army but armies around the world—will be fundamentally and substantively different than they are today.”

Whether technological change will radically change the nature of warfare remains to be seen. The Army is nevertheless pushing forward with changes in training and force structure to adapt to new tactics and technologies already being used by other combatants.

In related news, the Army’s Paladin Integrated Management program to upgrade 133 M109A6 Paladin self-propelled howitzers to M109A7’s to improve the weapon’s reliability, maintainability, performance, responsiveness, and lethality has run into problems. The Department of Defense Inspector General found the M109A7 failed to meet maximum rate-of-fire requirements in tests and requires additional fire extinguisher capabilities in crew compartments. Army observers have warned of recent advances in Russian artillery technology and the need for effective countering capabilities. Former Secretary of Defense Donald Rumsfeld cancelled the Army’s proposed next-generation XM2001 Crusader self-propelled howitzer in 2002.

 

Mass Fires vs. Precision Fires on the Battlefield of Tomorrow

Photograph of Russian T-90 tank following a hit by a U.S.-made TOW missile in Syria. [War Is Boring.com]
Photograph of Russian T-90 tank following a hit by a U.S.-made TOW missile in Syria. [War Is Boring.com]

For anyone paying attention, it is no surprise that the U.S. Army is intently watching Russia’s military operations in the Ukraine. What they have seen is sobering. Defense One’s Patrick Tucker recently highlighted the preliminary findings of The Russia New Generation Warfare study directed by Lieutenant General H.R. McMaster, who heads the Army’s Capabilities Integration Center.

According to McMaster, “the Russians have superior artillery firepower, better combat vehicles, and have learned sophisticated use of UAVs for tactical effect. Should U.S. forces find themselves in a land war with Russia, he said, they would be in for a rude, cold awakening.”

The Army evidently envisions a future clash between U.S. and Russian or Russian-backed forces will begin with long-range missile exchanges.

“We spend a long time talking about winning long-range missile duels,” said McMaster. But long-range missiles only get you through the front door. The question then becomes what will you do when you get there.

The tactics of Russian-backed irregular forces in the Ukraine have demonstrated effective leveraging of the new technological capabilities.

“Look at the enemy countermeasures,” [McMaster] said, noting Russia’s use of nominally semi-professional forces who are capable of “dispersion, concealment, intermingling with civilian populations…the ability to disrupt our network strike capability, precision navigation and timing capabilities.”

The implication of this, McMaster contends, would be that “you’re probably going to have a close fight… Increasingly, close combat overmatch is an area we’ve neglected, because we’ve taken it for granted.”

One big reason for the perceived Russian overmatch is a due to an advantage in artillery, both in terms of range and in power.

[Phil] Karber, the president of the Potomac Foundation, went on a fact-finding mission to Ukraine last year, and returned with the conclusion that the United States had long overemphasized precision artillery on the battlefield at the expense of mass fires. Since the 1980s, he said last October, at an Association for the United States Army event, the U.S. has given up its qualitative edge, mostly by getting rid of cluster munitions.

Munitions have advanced incredibly since then. One of the most terrifying weapons that the Russians are using on the battlefield are thermobaric warheads, weapons that are composed almost entirely of fuel and burn longer and with more intensity than other types of munitions.

“In a 3-minute period…a Russian fire strike wiped out two mechanized battalions [with] a combination of top-attack munitions and thermobaric warheads,” said Karber. “If you have not experienced or seen the effects of thermobaric warheads, start taking a hard look. They might soon be coming to a theater near you.”

McMaster believes that the combination of heavier, longer-ranged artillery abetted by the targeting capabilities afforded by hordes of unmanned aerial vehicles (UAVs) provides the Russians with a significant battlefield advantage.

“We’re out-ranged by a lot of these systems and they employ improved conventional munitions, which we are going away from. There will be a 40- to 60-percent reduction in lethality in the systems that we have,” he said. “Remember that we already have fewer artillery systems. Now those fewer artillery systems will be less effective relative to the enemy. So we need to do something on that now.”

One potential solution is to develop more flexibility in existing U.S. Army fires capabilities.

To remedy that, McMaster is looking into a new area called “cross domain fires,” which would outfit ground units to hit a much wider array of targets. “When an Army fires unit arrives somewhere, it should be able to do surface-to-air, surface-to-surface, and shore-to-ship capabilities. We are developing that now and there are some really promising capabilities,” he said.

It remains to be seen how pervasive and permanent these new Russian military capabilities are and whether they will result in changes in the existing system for modern conventional combat. The advantages the Russians derive from mass fires would appear to directly challenge the U.S.’s investment in precision guided munitions and strike capabilities going back to World War II. Precision strike, networked capabilities, and information warfare were fundamental aspects of the technology-driven Revolution in Military Affairs concept that dominated U.S. military thinking in the 1990s and early 2000s. Leveraging technology is also a foundational aspect of the Defense Department’s current Third Offset Strategy.