Just War Principles and Humans as Fail-Safe Actors

Just war theory distinguishes between just and unjust ways for soldiers to fight in armed conflicts and provides moral criteria to judge warfare actions on this basis. These criteria prominently include the noncombatant's right to immunity and the proper moral balances between the means and the ends of military action.Footnote ²⁵ These pillars of just war theory found their way into international humanitarian law (IHL)—notably in the principles of distinction, proportionality, and precaution that are enshrined in the 1977 Additional Protocols to the Geneva Convention.

Compliance with IHL is a focal point of ethical and legal debates about AWS. In the early days of this debate, Ronald Arkin expressed his concern for the poor record of human compliance with norms governing the warfare conduct of belligerent parties. He suggested that “ethically restrained” AWS might abide “by the internationally agreed upon Laws of War” better than human war fighters have, as these machines may be programmed with more conservative engagement policies; may reduce battlefield victims by more precise targeting; and may dispense with fear, anger, frustration, and other mental strains conducive to human violations of IHL. However, Arkin signaled “daunting problems” that needed to be addressed before developing IHL-compliant AWS (such as “the development of effective perceptual algorithms capable of superior target discrimination capabilities”). And he did not take it for granted that “this venture will be successful.”Footnote ²⁶ Arkin's technology assessment entails that the current and foreseeable AWS fail to meet, in many warfare situations, the benchmark represented by properly trained and conscientious human soldiers.Footnote ²⁷

One cannot exclude, therefore, the idea that present and foreseeable AWS may incur violations of the IHL principle of distinction that trained and conscientious soldiers would hardly be prone to. Notably, systems developed by means of current machine-learning technologies were demonstrated by adversarial testing to be prone to unexpected, counterintuitive, and potentially catastrophic mistakes that a human operator would easily detect and avoid.Footnote ²⁸ Vivid examples are learning perceptual systems that were found by adversarial testing to mistake school buses (protected by the distinction principle) for ostriches and turtles for rifles.Footnote ²⁹ Contrary to what widespread recourse to anthropomorphic language may suggest, human and autonomous decision-making processes indeed remain qualitatively different and are likely to err in qualitatively different ways. The source of such qualitative differences lies in what AI experts call the “semantic gap.” This expression indicates the fact that machines do not perceive the world in the same way as humans.Footnote ³⁰ Accordingly, granting (for the sake of argument) that the overall performance of AWS will come to match or even statistically surpass the performance of human combatants still does not entail that this will occur in each and every situation. Even the most sophisticated weapon may commit (or be induced to commit) disastrous mistakes from an IHL perspective—mistakes that might have been avoided if a human operator had been substantively involved in the decision-making loop. In light of complementary strengths and weaknesses of human and machine capabilities, it is thus questionable whether the elimination of human judgment and supervision is compatible with the obligation to take all feasible precautions to prevent disproportionate damage to the civilian population.

The belief that AWS may violate the IHL principles of distinction and proportionality is regarded as a “serious possibility” across the wide spectrum of positions emerging from the AWS debate.Footnote ³¹ Indeed, its negation is not included, to the best of our knowledge, in the belief set of any qualified participant in this ethical and legal debate. This serious possibility in itself speaks in favor of maintaining MHC over AWS in order to avoid the occurrence of such IHL violations. Thus, humans involved in human-weapon shared control ought to play the role of fail-safe actors who take due care of situations that engineered fail-safe systems may not adequately deal with in the foreseeable technological future.Footnote ³²

Epistemic Uncertainties and War Crimes

A second cluster of issues in the AWS debate revolves around the so-called accountability (or responsibility) gap problem; in particular, around the question of whether the removal of human operators from the targeting decision-making processes would hinder responsibility ascriptions when AWS violate IHL.Footnote ³³ This concern, however, is not unanimously shared. Susanne Burri, while acknowledging as a serious possibility that AWS can cause violations of just war and IHL principles, suggests that this worry is properly defused when “a conscientious human commanding officer deploys [AWS] only in contexts where they are able to identify sufficient conditions for the morally permissible infliction of lethal harm.”Footnote ³⁴ Should a commander deploy an autonomous weapons system in a context where such a sufficiency condition is not fulfilled, she would be held responsible for unacceptable damages. Fulfilling this sufficiency condition presupposes, however, an epistemic assessment of AWS capabilities and action outcomes in each given battlefield situation on the part of commanding officers.

Clearly, the epistemic assessment that commanders must come up with need not exclude altogether the risk of undesired outcomes. As Johannes Himmelreich points out, a commander may have control only over a probabilistic outcome of her orders in general and of AWS actions in particular.Footnote ³⁵ Accordingly, Himmelreich introduces the notion of “robust tracking control” to capture the commander's control duties with their attending epistemic risks and responsibilities, suggesting that

One should be careful to note that in order to infer that outcome x of an AWS action is under their robust tracking control, commanders must be in the position to assert with a high level of confidence that the actual battlefield situation is similar in all relevant aspects to their own cognitive model of the battlefield situation and its predicted outcomes. Confidence in this similarity judgment is bound to decrease as the incompleteness and uncertainty characterizing the commander's cognitive model of the battlefield increases. In particular, cluttered and unstructured battlefield situations—involving, for example, sustained interactions among opposing groups of soldiers, AWS, and other artificial agents—are likely to admit only incomplete and uncertain representations.

In these scenarios, the critical autonomy of weapons systems becomes incompatible with the preservation of robust tracking control. Commanders may not be in the position to license the required epistemic assessment about fast interactions between complex AWS or rapid environmental changes impinging on even relatively simple loitering systems such as the Harpy NG. As noted earlier, the Harpy's extended loitering time and limited perceptual discrimination capacities raise substantive concerns about the sustained persistence in dynamic and unstructured warfare scenarios of conditions for morally permissible infliction of lethal harm. In such scenarios, civilians and civilian objects may suddenly appear and enemies may rapidly move mobile sources of radar signals from otherwise uninhabited locations to the vicinity of vulnerable locations like schools or hospitals.

The epistemic limitations on the commander's capability to make robust predictions about the behaviors of AWS are what drive the “accountability gap” problem, especially from the perspective of ICL.Footnote ³⁷ Suppose that an autonomous weapons system commits a material act that would be equivalent to a war crime should this act have been performed by human beings. In other words, the AWS targeting decisions, were they taken by human agents, would trigger individual criminal responsibility. Since the direct targeting decision was taken by the AWS, who should be held responsible for its conduct? If sufficiently stringent MHC conditions on the release and subsequent action of the AWS were not in place, commanders might complain that an interruption of their robust tracking control condition occurred due to unexpected epistemic predicaments, such as bizarre perceptual errors of the AI learning system embedded in the AWS or hostile interactions on the battleground. Under these circumstances, commanders could plausibly claim that their responsibility was mitigated, or altogether excluded, “due to epistemic constraints.”Footnote ³⁸ The list of potentially responsible persons in the decision-making chain includes those overseeing the AWS operation, manufacturers, robotics engineers, software programmers, and those who conducted the AWS weapons review. These persons may cast their defense against responsibility charges on account of their limited decision-making roles, the complexities of the AWS, or the difficulty of anticipating and testing weapons against all possible battlefield scenarios prior to their actual deployment. Cases may therefore occur where one cannot ascertain the existence of the mental element (intent or knowledge), which is required under ICL to ascribe and punish criminal responsibilities. Consequently, no one would be held criminally responsible, notwithstanding that the conduct at stake materially amounts to an international crime.

As weapons systems become more autonomous in their targeting decisions, the role of individual criminal responsibility (and ICL more generally) becomes smaller in governing the use of armed violence. Despite what some have argued,Footnote ³⁹ one cannot balance waning international criminal responsibility by introducing some kind of collective strict liability that would oblige the deploying state to pay for all damages to civilians caused by AWS, independent of the fault of any commanders. Proposals of this kind rest on the incorrect assumption that the various responsibility regimes embraced by international law are ultimately replaceable among one another. This assumption neglects the “complementarity” among responsibility regimes, which is rooted in the distinction between the “predominantly reparational aspect of state responsibility and the punitive character of criminal law proceedings against individuals.”Footnote ⁴⁰ The latter, indeed, makes ICL unique in playing the crucial function of “pronounc[ing] the wrongfulness of actions that harm the interests of the international community as a whole.”Footnote ⁴¹ This is for the simple reason that, as famously affirmed by the Nuremberg Tribunal, international crimes “are committed by men, not by abstract entities, and only by punishing individuals who commit such crimes can the provisions of international law be enforced.”Footnote ⁴²

A sufficiently stringent MHC would enable one to meet this ICL normative requirement, so as to preserve the kind and degree of human control over the critical functions of selecting and engaging targets that is needed to justly ascribe individual criminal responsibility, instead of thwarting it. In this sense, shared control between humans and autonomous weapons should be conceived so as to ensure that humans always play the role of accountability attractors.

AWS as an Affront to Human Dignity

A third cluster of arguments against autonomy in weapons systems is grounded in the principle of human dignity protection, insofar as this principle dictates that decisions affecting the life, physical integrity, and property of human beings involved in an armed conflict should be reserved entirely to human operators and cannot be entrusted to an autonomous artificial agent.Footnote ⁴³

Burri, on the other hand, contends by analogy that “there is nothing unduly selfish or inconsiderate about a lion that hunts down its prey, just as there is nothing disrespectful or insensitive about an LAR (Lethal Autonomous Robot) that has decided to lethally engage an enemy combatant based on the algorithms that were programmed into it.”Footnote ⁴⁴ On our view, this stance belittles the moral implications of life-taking or life-sparing decisions, and reduces these decisions to verifications of legitimacy. Furthermore, Burri's analogy overlooks the difference between legitimate target assessment and moral evaluations prizing the value of human life. Elaborating on views originally advanced by Thomas Nagel,Footnote ⁴⁵ Sparrow tackles the question of AWS and respect for human dignity. Even in wartime, writes Sparrow, “it is essential that we acknowledge the personhood of those with whom we interact.” And in particular, he continues, “the decision to take another person's life must be compatible with such a relationship.” Hence, “when AWS decide to launch an attack the relevant interpersonal relationship is missing. Indeed, in some fundamental sense there is no one who decides whether the target of the attack should live or die. The absence of human intention here appears profoundly disrespectful.”Footnote ⁴⁶

From the MHC viewpoint, this argument implies that human control should ensure that AWS life-or-death decisions are traceable to human intentions. In other words, humans involved in shared control with autonomous weapons must play the role of moral agency enactors, ensuring that decisions affecting the life, physical integrity, and property of people involved in armed conflicts are not taken by artifacts that fail to qualify as moral agents. Establishing this form of control is likely to conflict with some forms of autonomy in weapons systems, such as those involving autonomous-targeting decisions taken by complex AWS operating in unstructured warfare scenarios and unchecked by human beings over extended temporal and spatial windows. Not invariably so, however, there are limited forms of autonomous targeting in weapons systems that appear to be consistent with human dignity protection requirements.

Each of the arguments examined here so far regarding the capabilities of AWS to select and engage targets is deontological in character, insofar as it makes an appeal to distinctive moral duties (such as the IHL-embedded duty to protect noncombatants, the ICL-embedded duty to preserve criminal responsibility ascriptions in warfare, and the duty to respect human dignity). In addition to these types of deontological arguments, consequentialist arguments have also played a central role in the debate concerning the ethical and legal acceptability of AWS. As noted earlier, Arkin emphasized possible consequentialist advantages of future AWS, such as fewer victims on the battlefield. Others have cautioned instead that AWS make wars easier to wage, thus leading to negative consequentialist appraisals in the wider context of preserving global peace and stability.Footnote ⁴⁷ Such appraisals, however, are comparatively less relevant than the deontological arguments we have outlined in this section in connection with the main problem that we are concerned with—the problem of shaping the contents of MHC. This relationship will be addressed in the concluding section. First, we turn to a normative framework for MHC.

Uniform Solutions

Several attempts have been made—by scholars, states, and NGOs—to define human-weapon shared control policies dictated by the MHC requirement. While significantly different from one another in many respects, these various proposals generally share a common feature: they aspire to capture optimal partnership using a one-size-fits-all formula that is supposed to apply uniformly to all kinds of weapons systems and all of their possible uses.

This feature is particularly evident in the so-called wider loop approach, advocated by the Dutch government: On this approach, MHC is regarded as having been satisfactorily exercised by human commanders at the planning stage of the targeting process.Footnote ⁵² This approach may have some limited applicability and relevance with regard to the deliberate targeting of military objectives, as long as these are known in advance to exist and can be mapped with reasonable certainty. It is, however, largely unhelpful with regard to dynamic targeting, which pursues targets of opportunity. Moreover, it allows for weapons to have unrestrained autonomy after deployment. In this way, the Dutch approach appears to be deeply problematic in scenarios populated by civilians: It drives a wedge between the state owing a duty of care to the civilian population and the actual ability to reliably comply with that duty by influencing the course of events through its agents.Footnote ⁵³ This is especially true for AWS endowed with the capability of loitering for sustained periods of time in search of enemy targets (like the above-mentioned Harpy NG). After all, the conditions licensing the activation of a loitering AWS by human operators may rapidly change in warfare scenarios characterized by erratic dynamics and surprise-seeking behaviors.

The uniform and overly permissive approach sketched out and advocated by the Dutch government is located at one end of the spectrum of MHC constructs. At the other end of the spectrum, one finds similarly uniform but overly restrictive approaches to defining MHC, whereby no autonomy whatsoever in weapons systems is permitted.Footnote ⁵⁴ While undoubtedly praiseworthy for their attention to humanitarian concerns, these attempts run the risks of (1) banning some weapons whose jus in bello admissibility has so far gone undisputed on ethical or legal grounds, and (2) requiring milder forms of human control to remove the troubling ethical and legal implications potentially ensuing from the autonomy of these weapons. Extant cases in point are the United States' Phalanx Defense Systems, Israel's Iron Dome, and the German NBS MANTIS, when they are used as intended—that is, as protective shields from incoming shells and missiles.

A reflection on these systems suggests that a “supervised autonomy,” or “human-on-the-loop,” policy that occupies a middle ground between the two extremes analyzed above might suffice to strip their autonomy of ethically and legally troubling traits.

As defined in the DoD directive, human-supervised AWS are designed “to provide human operators with the ability to intervene and terminate engagements, including in the event of a weapon system failure, before unacceptable levels of damage occur.”Footnote ⁵⁵ Notably, one may use these systems for defending manned installations and platforms from “attempted time-critical or saturation attacks,” provided that they do not select “humans as targets,”Footnote ⁵⁶ which is exactly the case for the defense systems mentioned earlier. While effective for these and similar warfare scenarios, supervised autonomy is not the silver bullet for every ethical and legal concern raised by AWS. To begin with, keeping humans on the loop does not prevent faster and faster offensive AWS from being developed, which will eventually reduce the role of human operators to a perfunctory supervision of decisions taken at superhuman speed, leaving only the illusion of meaningful human control. Moreover, “automation bias”—the human tendency to over trust machine decision-making—is demonstrably exacerbated when the human role consists solely of the ability to override decisions that have already been autonomously made by machines.Footnote ⁵⁷

In brief, any desire to grant even limited forms of critical autonomy to weapons systemsFootnote ⁵⁸ must be coupled with a principled approach to MHC that includes ethical and legal considerations for the fail-safe actor, accountability attractor, and moral agency enactor roles identified above. To this end, we suggest giving up the quest for a one-size-fits-all solutionFootnote ⁵⁹ to the concept of MHC in favor of a suitably differentiated approach, without relinquishing the demand that this solution be nonetheless principled.

A Differentiated, Principled, and Prudential Framework for MHC

In order to actually implement the various elements that constitute MHC, we need rules to bridge the gap between ethical and legal principles, on the one hand, and specific weapon systems and uses thereof, on the other. These “bridge rules” should be able to express the fail-safe, accountability, and moral agency conditions for exercising MHC over weapons systems in context.

Schematically, these rules may be conceived of as “if-then” statements. Their “if” part should include properties concerning what mission the weapon system is involved with, where the system will be deployed, and how it will perform its tasks. The “what properties” must specify operational goals (defensive vs. offensive); the targeting modes (deliberate vs. dynamic); and the nature of targets to be engaged (human combatants, human-occupied vehicles, and/or inhabited military objects vs. uninhabited vehicles and military objects). The “where properties” must concern dynamic features of the environment, including interactions with hostile autonomous artificial agents, and have special regard for the presence of civilians, civilian objects, and friendly forces. The “how properties” must concern information-processing and sensory-motor capabilities that the system puts to work in its mission and that affect its overall controllability and predictability. Learned decision-making and “swarm intelligence” abilities (which may increasingly characterize future AWS), jointly with loitering capabilities, are significant cases of “how properties” raising concerns from an MHC perspective.Footnote ⁶⁰

The “then” part of the bridge rules should establish what kind of human-machine shared control would be legally required on each use of a given weapons system. Following (and only slightly modifying) a taxonomy proposed by Noel Sharkey,Footnote ⁶¹ one may consider five basic levels (Ls) of human-machine interactions to fill in the then part of the bridge rules. These are ordered according to decreasing levels of human control and increasing levels of machine control in connection with target selection and engagement tasks.

On these assumptions, an if-then rule may—for instance—assume the following form: “IF the weapons system is programmed to perform an exclusively antimateriel defensive function (what property) AND is deployed in a sufficiently structured scenario (where property), THEN (L4) human operators must be put in charge of supervising the weapon's selection of targets and be given the power to override its choices.”

As noted by Heather Roff and Richard Moyes, it “may be difficult in detailed terms” to specify what is the appropriate level of control needed to establish MHC for each use of a weapons system, as too many contextual factors may come into play.Footnote ⁶² However, within the wide space of “differentiated” and “principled” solutions to the MHC problem, we argue for a solution that is also “prudential,” in the sense of taking every reasonable precaution to preserve the fail-safe, accountability, and moral agency contents of MHC, thereby minimizing the risk of IHL breaches, accountability gaps, or affronts to human dignity, described in “The Ethical and Legal Case for Meaningful Human Control” section of this article.Footnote ⁶³ Against the background of L1–L5, the gist of a differentiated, principled, and prudential solution to MHC is specifiable by means of (1) a general default policy and (2) exceptions formulated as specific bridge rules. The default policy would require that higher levels of human control (L1 and L2) should be applied, unless the given autonomous weapons system is an exception that the international community of states has agreed to handle by means of specific bridge rules allowing for lower levels of human control.

Bridge rules for internationally agreed-upon exceptions should specify what level of interaction (L1–L5) is required to ensure the threefold role of MHC (fail-safe actor, accountability attractor, moral agency enactor) as a function of suitable combinations of the what, where, and how properties. Deviations from the general default policy should be crafted by taking into account the following observations:

1. 1. The L4 human supervision and veto level might be deemed acceptable only for AWS with exclusively anti-materiel defensive functions (what property).

2. 2. Deliberate targeting (what property) by AWS may be pursued at L3. Since targeting decisions have actually been taken by humans at the planning stage, operators have only to confirm that no changes occurred in the battle space that may affect the lawfulness of the operation.

3. 3. One may allow human control at L3 for AWS programmed to engage human or humanly inhabited targets (what property) when activated in fully structured scenarios (where property), such as in the high seas or deserts where civilians and civilian objects are not present. Unlike L4, L3 ensures that a human on the attacking end can verify whether there are persons hors de combat and take appropriate denial or granting measures. An example of AWS potentially operating in a fully structured environment is the legacy South Korean robotic sentry Super aEgis II, which patrols the Korean demilitarized zone and is reportedly able to function in full autonomous mode.Footnote ⁶⁴

4. 4. Capabilities that may reduce the predictability of weapon systems’ behavior, such as loitering, learned decision-making, and swarming (how properties), should in principle be treated as factors pushing toward the application of higher levels of human control (L1 and L2).

5. 5. The full autonomy of L5 should be considered incompatible with the MHC requirement. While it is true that operational constraints set at the planning or activation stages may play an important role in limiting weapons’ autonomy, this “boxed autonomy” alone is insufficient to ensure MHC,Footnote ⁶⁵ unless operational space and time frames are so severely circumscribed as to make targeting decisions reliably traceable to human operators.

The latter exclusion is suitably illustrated by reference to homing fire-and-forget munitions; that is, precision-guided munitions that use passive sensors or active seekers to track onto moving targets. Most fire-and-forget munitions simply lock on targets preselected by human operators, thereby meeting the highest human control level (L1). Those involving mutual coordination to avoid hitting the same target can be fired in a salvo to simultaneously attack multiple targets that are close to one another and previously identified by human operators. In this case, each munition might be said, prima facie, to select and engage targets on its own based on mission goals defined by human operators, which would be an L5 degree of human control. On closer scrutiny, however, the mission is so precisely defined (for example, “Destroy that specific line of enemy tanks”) that nobody would question the conclusion that those targeting decisions are collectively attributable to the human launching the attack and thus fall under L1 human control.

The same conclusion does not hold for fire-and-forget munitions, like the Brimstone, enabled to search for and hit targets within a “kill box” designated by a human operator. Although the lack of loitering capabilities requires the operator to be convinced that there are valid targets within the box (otherwise the missile would be wasted),Footnote ⁶⁶ a missing link is detectable in the decision-making chain, with the consequence that targeting decisions appear in fact to be taken by the weapon system, not by the human user. While this is admittedly a borderline case to be treated with caution, the existence of this missing link speaks against including this functionality of fire-and-forget munitions among candidate exceptions to the general default policy.

In this respect, the history of the Brimstone is particularly instructive. A previous version of the Brimstone, solely operating in the “autonomous” mode, was deemed incompatible with the rules of engagement of the Afghanistan campaign, which prompted the U.K.'s Royal Air Force to issue an urgent operation requirement in 2007, aimed at modifying the existing missiles and enabling human selection of targets through laser guidance (“a man-in-the-loop capability,” in the manufacturer's own wording).Footnote ⁶⁷ Contrary to what is sometimes maintained, therefore, the ethical and legal acceptability of offensive autonomy—even in such a limited form—is far from undisputed, even among the primary users of these weapons systems.

The Quality of Human Involvement: Design and Training

The MHC requirement is compatible, as the above observations suggest, with various forms of human-weapon partnerships in critical target selection and engagement functions. The MHC requirement is also compatible—in limited circumstances—with the preservation of the critical autonomy of some weapons systems. Nevertheless, the incompatibility of MHC with L5 means that human operators retain some exclusive control privileges throughout, notably the power to approve at L3 or veto at L4 machine targeting decisions. In all these cases, it is crucial to ensure a proper quality of human involvement, so that human control privileges are meaningfully exerted. This requires intervention at both the design and training stages of AWS life cycles.Footnote ⁶⁸

AWS should be designed to provide human operators and commanders with sufficient humanly understandable information about machine data processing, thus achieving adequate situational awareness (“interpretability” requirement); and to obtain an account of the reasons why the machine suggests or intends to take a certain targeting decision (“explainability” requirement). Moreover, military personnel training should foster awareness of both established and likely limits in the proper functioning of weapons systems and related predicaments in the capability to predict and control their behavior.Footnote ⁶⁹