November 3, 2014
"If the U.S. military is to maintain its technological edge, it will need to harness the advantages of the robotics revolution and build the swarm."
The U.S. military is at a crisis point. We are staring down the barrel of a future where U.S. military technological superiority may no longer be a given wherethe military strength that has undergirded global security since World War II may be in question. The technologies that have given the U.S. military its edge stealth, long-range sensors, communications networks and precision-guided weapons are proliferating to other actors. As a result, so-called “anti-access” challenges threaten traditional modes of power projection. While individual U.S. ships, planes and tanks remain more capable one-on-one, the pernicious “death spiral” of rising costs and shrinking procurement quantities means that the United States has increasingly fewer and fewer assets to bring to the fight. The U.S. military will have to fight significantly outnumbered, and even the qualitative advantages U.S. assets have will not be sufficient. Quality matters, but numbers matter too. At a certain point, U.S. aircraft and ships will simply run out of missiles.
In the face of this waning military advantage, Secretary Hagel has called for a renewed investment in military technological superiority. Deputy Secretary Bob Work has launched a long-range research and development planning programto identify new, potentially game-changing technologies. As the Department of Defense (DoD) begins to craft a new technology dominance strategy, a key component should be harnessing the advantages of the unfolding robotics revolution to field large numbers of low-cost systems.
Swarms of low-cost robotic systems can overwhelm enemies, saturating their defenses. Cooperatively, they can operate with greater coordination, intelligence and speed on the battlefield than manned systems. Perhaps most significantly, they can help to bend the cost curve downward, allowing the United States to field large quantities of systems that, in aggregate, retain qualitative superiority. Disaggregating complex, multimission systems into larger numbers of lower-cost systems is a potential way to increase resiliency, diversity and impose costs on adversaries—and to do so affordably. But harnessing the advantages of this approach will require a new paradigm for how we build next-generation military systems.
“Imposing Costs” on the Enemy, or on Us?
What DoD leaders are looking for is a technology dominance strategy that “imposes costs” on adversaries. If we put our minds to it, this shouldn’t be hard to do. The current U.S. defense system is excellent at imposing costs on ourselves. We have been steadily pricing ourselves out of the business of defense.
In 1984, Norm Augustine observed as one of “Augustine’s Laws” that the cost of military aircraft was growing exponentially, while the defense budget was only growing linearly. He humorously noted:
In the year 2054, the entire defense budget will purchase just one tactical aircraft. This aircraft will have to be shared by the Air Force and Navy 3½ days each per week except for leap year, when it will be made available to the Marines for the extra day.
We need not wait until 2054 for Augustine’s Law of rising costs to take its toll. The crisis in rising costs and shrinking quantities that he warned about is here today. A 2008 RAND Corporation study that analyzed a U.S.-China air war over Taiwan made the bold assumption that every air-to-air missile fired from a U.S. F-22 hit a Chinese fighter (100 percent kill rate) and that every Chinese missile missed the U.S. F-22s (0 percent kill rate). In their simulation, the United Statesstill lost the fight. The F-22s ran out of missiles and the Chinese fighters were able to go after vulnerable tankers and command and control aircraft. A far more detailed simulation the following year showed the same results. Even though U.S. F-22s were pegged with a 27-to-1 qualitative advantage over Chinese fighters, their diminished numbers and the fact that they had to fight from long range meant the Chinese had vastly superior numbers and won the fight.
These trends in rising costs and shrinking quantities aren’t new. Aircraft costs have been rising exponentially, predictably, since the 1950s. U.S. ship costs rose between 7-10 percent on an annual basis from 1950-2000. The current budget downturn only exacerbates a long-term trend in shrinking quantities. More money might delay the inevitable, but it won’t fix the problem. From 2001 to 2008, the Navy and Air Force base (nonwar) budgets grew 22 percent and 27percent, respectively, adjusted for inflation. At the same time, the number of combat ships declined by 10 percent and the number of combat aircraft declined by nearly 20 percent. Rising personnel and health-care costs are a part of what is squeezing the force, and must be brought to heel, but even if they are, rising platform costs alone will force an ever-shrinking fleet.
The U.S. defense establishment’s response to this challenge has been to double-down on the current approach. We make our weapon systems increasingly multimission, able to take on more and more roles to accommodate a shrinking force. As a result, requirements go up. Costs go up. Development timelines stretch, allowing more time for the bureaucracy to adjust the requirements. In fact, requirements are almost certain to be adjusted on a twenty-year development timeline: the threat environment will inevitably change. But that drives more cost increases. And procurement quantities are cut further. So the remaining systems need to do even more …
This is like fighting lung cancer by smoking harder. We need to quit.
The Enemy Is Us
The solution is not to stop modernizing or to retain legacy force structure at the expense of higher-quality systems. Instead, we need a new paradigm that allows the United States to field high-quality systems and in large quantities. And this strategy must work in the midst of a constrained fiscal environment. Accommodating rising costs through massive growth in the defense budget in perpetuity is neither feasible, nor responsible. But to kill the disease, we need to identify the root cause.
The line the U.S. defense establishment has told itself is that the rising costs are not our fault, that costs have gone up because it just costs that much to make modern weapons. Complexity, we are told, is behind the cost increases. To build a system as complex as the ones we are building today, it takes decades and costs billions. They have millions of lines of code!
That sounds convincing and contains an element of truth. Detailed studies of root causes behind aircraft and ship cost increases have identified complexity as a major factor. However, it confuses a symptom with the disease. Increasing complexity does not automatically lead to exponential increases in costs.
A modern military aircraft is no more complex, when measured in number of parts and lines of code, than a high-end automobile. The Joint Strike Fighter has 24 million lines of code. A high-end automobile has on the order of 100 million. The Joint Strike Fighter costs more because it is a fighter aircraft, of course. But the key difference is the trends in cost growth. Automobile costs have not risen exponentially as they have become more complex. Instead, they have remained relatively flat in real dollars. Cars are able to harness greater economies of scale, but that doesn’t explain the difference in rates of cost growth.
The key difference is time. Cars are developed on timelines measured in just a few years, while most modern military systems take twenty to thirty years to come to fruition. As a result, cars are built incrementally based on mature technology, holding down risk. New models are not built from scratch, but rather improve on what already exists. The need to go to market on time constrains the pursuit of overly complex or expensive technologies. If an upgrade is not yet ready, or not yet cost-effective, it can be delayed for release in the next year’s model.
Conversely, long development timelines in DoD create a perfect storm of methods for cost increases. Long timelines incentivize gold-plated requirements divorced from an understanding of technology risk. Requirements for next-generation weapons often include capabilities that are not yet technologically feasible, on the assumption that over the ensuing decades, the technology will be created. Sometimes it can be, but sometimes it can’t, or not without exorbitant costs. Lengthy development timelines virtually ensure requirements will shift over time, either because the threat changes or because there is simply more opportunity to tinker with them. In the worst cases, even with shifting requirements, platforms are unable to keep pace with adversary or commercial-sector innovation and risk being obsolete before they are even fielded.
Cost restraint is another difference. Automobile costs are limited by what consumers will buy and by competition, forcing trade-offs between the value additional features add and what they cost. Too often DoD has pursued a whatever-it-costs approach to its next-generation weapon systems, as though a capability is required no matter the price. But no innovation is priceless. Higher costs lead to reduced quantities, and that means less capability for the force as a whole. Senior DoD leaders have undertaken important reforms to constrain costs. They may well be for naught, however, if DoD still finds itself saddled with too-big-to-fail systems and no viable options if costs creep upward. For example, DoD officials have insisted the next-generation bomber will cost only $550 million a copy (in 2010 dollars). But what if it doesn’t? Will it be cancelled, delaying a much-needed capability? How would DoD fill the genuine need for long-range strike without a bomber? What would the alternative be?
Perhaps worst of all, many platforms are often created as unique, integrated systems with proprietary software. When a new weapon system is created, too often it is designed wholly new, rather than leveraging existing technologies and building incrementally. This increases costs and increases technology risk. As a result, DoD tends to build “Death Stars:” exceedingly complex, expensive wonder-weapons (in limited numbers) that too often have a lurking hidden vulnerability.
Simplify, Simplify, Simplify
If the enemy is long timelines and complexity, then the solution is short timelines and simplicity. The cancer can be killed by breaking systems down into smaller components developed on shorter timelines, disaggregating their functionality and controlling technology risk.
One typical way in which this is done is to disaggregate modernization across time by building modular platforms with incremental improvements in each procurement “block.” Each procurement “block” builds on the last, incorporating new technologies as they mature, reducing technology risk and cost.
There are tremendous benefits to modularity, and for major platforms like ships, aircraft or ground vehicles that have long service lives, modularity is key to ensuring they can maintain technological relevance over time. This is particularly relevant for staying ahead in rapidly advancing information technology, where technology changes in months and the latest software can mean the difference between survivability and defeat. Major platforms must be viewed as “trucks,” valuing payloads over platforms, and software over payloads.
Another approach is to disaggregate a system spatially into many components, adopting a family of systems approach. A family of systems consists of a number of single-mission systems optimized for specific roles working together to accomplish a task, rather than a single, exquisite multimission system. Because single-mission systems are required to do less than multimission systems, they can be produced with lower technology risk and at lower cost. In addition, provided that network architectures are designed with sufficient interoperability up front, such an approach is inherently modular. Concerns about size, weight and power that traditionally bedevil modular design approaches no longer matter when combat functions are disaggregated spatially among many platforms. Provided it can plug into the network, new systems are inherently “plug and play.”
Enter the Swarm
Disaggregating complex, multimission systems into a family of lower cost single-mission systems has not been particularly appealing to-date, because,without automation, any major platform must be ultimately controlled by a human operator, either physically onboard the platform or remotely. People cost money, and rising personnel costs have placed steady downward pressure on end-strength for all of the military Services. In a world where the military will have fewer aircraft, ships and ground vehicles anyway because there are fewer people to control them, making those vehicles as capable as possible makes sense.
Autonomous, uninhabited systems offer the potential for a different approach. They can be used to augment existing human-inhabited systems, putting additional sensors and missiles into the fight at relatively low cost. This is possible because a variety of cost-savings advantages of uninhabited and autonomous systems: Greater endurance means that fewer platforms are needed in the force to sustain the same number forward in the fight. Increased automation reduces the need to train human operators for some tasks, and is particularly attractive for expensive training like pilot flying hours. Survivability can be balanced against cost, building larger numbers of systems and replacing the concept of platform survivability with swarm resiliency.
Swarms have other advantages. A larger number of assets imposes costs on adversaries, dramatically expanding the number of targets an enemy must strike. Distributing assets can not only make them harder to target, but more resilient in combat. If some are destroyed, the remainder can carry on the mission, allowing graceful degradation of combat capability, rather than risk the catastrophic loss of a single expensive platform. Distributing functionality among heterogeneous mixes of systems also increases resiliency against vulnerabilities or failures in any one system and imposes additional costs on adversaries, as they must counter multiple diverse approaches. Finally, large numbers of cooperative systems can harness the advantages of swarm intelligence for greater coordination and speed on the battlefield.
Human-Machine Teaming
Uninhabited systems need not be able to perform every function of a human-inhabited vehicle in order to replace them for some missions. Indeed, the point is that they would not! Rather, a diverse mix of lower-cost, single-mission systems, built in large numbers to be attributable in combat and controlled by smaller numbers of personnel, could accomplish some tasks better and at lower cost. In many cases, this will be in conjunction with manned platforms, supplementing their combat power. Uninhabited “loyal wingman” aircraft could augment manned fighter aircraft with additional sensors and missiles. Robotic ground vehicles could act as long-range scouts, conduct feints and deception maneuvers, or form the front line of a movement to contact. And uninhabited arsenal ships, on the sea surface or undersea, could massively expand the striking capacity of existing surface combatants and submarines.
Uninhabited systems could be sent deep into enemy terrain on dangerous or even suicidal missions that would be impossible for human-inhabited systems. Swarms of expendable vehicles, like the miniature air-launched decoy (MALD), could create an electronic storm of jamming, decoys and high-powered microwaves. Small air vehicles could autonomously fly down roads searching for mobile missiles and, once found, relay their coordinates back to human controllers for attack. Networks of air, sea surface and undersea vehicles could track enemy ships and submarines. And robotic ground vehicles could be air-dropped behind enemy lines, like D-Day’s “little groups of paratroopers,” to sow confusion and wreak havoc on an enemy. These systems need not be capable alone of winning the fight, but merely of augmenting human-inhabited systems, giving the force as a whole greater range and persistence, daring, mass, coordination, intelligence and speed.
Commanding the Swarm
Just as uninhabited vehicles need not perform every function of human-inhabited ones in order to be useful, automation need not be intelligent enough to replace human operators entirely in order to save costs. Many tasks in warfare require judgment based on context and ambiguous information, and will be difficult to automate at best. Instead, onboard automation need merely be sufficient to reduce the cognitive load for a human controller such that he or she can control many vehicles at one time, thereby expanding the number of vehicles a person can control. This breaks the current relationship between people and platforms, and allows a force small in personnel to field and control potentially a very large force in platforms.
Multivehicle control has already been demonstrated in limited forms. In August of 2014, the Navy demonstrated a swarm of thirteen small boats operating under the control of a single sailor. The Air Force has used multiaircraft control in very limited operational settings, although it is not common practice. By harnessing the power of swarming, a military can field and control large numbers of systems, bringing mass to the fight in a significant way, even with constrained personnel end-strength.
Flooding the Zone
As the United States begins to grapple with possible responses to the anti-access challenge, a “flood the zone” approach should be an option in the U.S. toolkit. Large numbers of low-cost, uninhabited and autonomous systems can overwhelm enemy defenses and act as decoys, scouts and “missile trucks” for human-inhabited systems. Because of their greater persistence, uninhabited systems could be seeded into the battlespace weeks or months ahead of time where they lurk unseen, allowing an early toehold in gaining access.
Swarms of uninhabited and autonomous systems will open up new ways of fighting, and new doctrine, training and organization will be needed. Uninhabited and autonomous systems need not replace every function of a human or human-inhabited system in order to be useful. Rather, they can help warfighters perform their missions better by absorbing some tasks, so that warfighters can focus on what only humans can do. In some cases, this may mean some military jobs are eliminated or changed beyond recognition, just like we no longer field archers today, and infantrymen, sailors and cavalrymen all look very different from their counterparts of old who shared the same names. While this may generate some discomfort, there is an imperative to moving quickly. Much of the innovation in robotics comes from the commercial sector, and will be widely available. If the U.S. military is to maintain its technological edge, it will need to harness the advantages of the robotics revolution and build the swarm.
Paul Scharre is a fellow and Director of the 20YY Warfare Initiative at the Center for a New American Security. He is a former infantryman in the 75th Ranger Regiment and has served in Iraq and Afghanistan. This article is adapted from CNAS’ recent report, “Robotics on the Battlefield Part II: The Coming Swarm.”
Image: Courtesy of Raytheon
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