The emergence of autonomous security technologies

The defining aspect of AWS is their varying degree of autonomy – ultimately, independent ‘agency’. On a spectrum comprising a simple reactive mechanism at one end and human intelligence at the other end, AWS are gradually moving towards the latter.Footnote ¹⁸ In this sense, AWS are defined as ‘systems that, once activated, can track, identify and attack targets with violent force without further human intervention’.Footnote ¹⁹ Hence, AWS qualitatively surpass remote-controlled systems, such as drones, that are currently important security technologies.

How to define the autonomy of weapons systems is a matter of debate in two main ways. First, some scholars refine the conceptual understanding of autonomy by, for example, outlining its characteristic aspects such as independence, cognitive skills, and cognitive architecture.Footnote ²⁰ Heather Roff connects autonomy directly to four functions of weapons systems (trigger, targeting, navigation, mobility), allowing her to evaluate the extent to which weapons operate autonomously to different degrees.Footnote ²¹ In discussing autonomy, scholars emphasise that it should not be equated with human intelligence or ‘free will’, given the distinct nature of robot decision-making.Footnote ²² A second group of scholars debates levels of appropriate human supervisory control, focusing on human-machine interaction and the extent to which machine autonomy undermines human autonomy.Footnote ²³ Here, scholarship worries about the human role moving further and further away from immediate decision-making processes on the use of force, a concern underlined by the prominent image of the control ‘loop’. While humans are still ‘in the loop’, in manual control, with regard to drones, in the context of more autonomous systems, humans are projected to first become ‘on the loop’, only overseeing operations and having the formal ability to override machine’s decision, to eventually ‘out of the loop’, being completely absent from operating systems.Footnote ²⁴ The control loop image has been criticised for offering ‘a crude distinction’, because decision-making can be both immediate, that is, in an individual targeting situation, or a wider concept, that is, associated with programming.Footnote ²⁵

However, where decisions are taking place may be less decisive than what kind of control will be exercised. Humans will most likely keep elements of control and oversight in future targeting decisions of AWS, but will this control be formal rather than meaningful? Even meaningful human control,Footnote ²⁶ a concept that has gained currency in the debate on AWS, can indicate very different things. Noel Sharkey’s five levels of human supervisory control, for example, range from humans deliberating about specific targets before initiating an attack, via humans choosing from a list of targets suggested by a program, to programs selecting targets and allocating humans a time-restricted veto.Footnote ²⁷ The content of meaningful human control as well as the extent to which human decision-making will be replaced or pushed back to the programming stage is debatable and will arguably emerge in practice.

While we do not aim at predicting in what ways AWS will operate in the future and how human-machine interaction will be designed, we maintain that AWS represent qualitatively different weapons systems characterised by the emergence of non-human agency. To quote former UN Special Rapporteur Christof Heyns, a key agenda-setter for the topic at the UN:

The most controversial issue is the possibility that machines may make and execute the decision to end human life autonomously with severe effects on human dignity, a human right at the heart of contemporary international legal architecture.Footnote ²⁹ This is a crucial, qualitatively different feature of AWS in comparison to drones, for instance. Pressure to remove human decision-making in an immediate sense from target engagement and selection will potentially increase as the speed to which AWS are able to process information and execute actions autonomously grows and begins to represent an operational advantage, compared to the ‘slow’ response time of humans.Footnote ³⁰

The deployment of AWS is not a scenario for the distant future. AWS are currently developed, tested, and deployed by the United States, China, Israel, South Korea, and Russia, to name some key actors.Footnote ³¹ Since 2013, the international community is discussing AWS under the framework of the UN Convention on Certain Conventional Weapons (CCW). State parties to the CCW have held three informal meetings of experts since 2014. After little initial progress, the state parties agreed to formalise deliberations on AWS by creating a Group of Governmental Experts (GGE) in December 2016. While the GGE only has a discussion mandate, similar mechanisms have in the past eventually led to regulation agreements. Chaired by India, the Group has met for the first time in mid-November 2017, witnessing growing support among the CCW contracting parties for a ‘legally-binding instrument on fully autonomous weapons’.Footnote ³² As of November 2017, 22 countries called for a pre-emptive legal ban on AWS, a group that does not include any of the major actors developing such technologies.Footnote ³³ During the CCW’s fifth Review Conference in 2016, China released its first position on AWS, declaring that ‘China supports the development of a legally binding protocol on issues related to the use of AWS, similar to the Protocol on Blinding Laser Weapons, to fill the legal gap in this regard.’Footnote ³⁴ The reference to this Protocol is interesting as it instituted a pre-emptive ban. At the same time, China has not defined AWS, making it difficult to assess the specificity of its position.

This is characteristic of discussions at the CCW, which are hampered by diverging viewpoints on autonomy and the resulting lack of a conceptual consensus on AWS. While some member states lack even a working definition, those put forward by, for example, the US and the UK differ significantly. The US defines an AWS as ‘a weapon that, once activated, can select and engage targets without further intervention by a human operator’Footnote ³⁵ in Department of Defense (DoD) Directive 3000.09 that will be discussed further below. The Directive also includes a contested distinction between so-called semi-autonomous and autonomous weapons: semi-autonomous weapons can ‘employ autonomy’ for a full range of ‘engagement-related functions’ for ‘individual targets or specific target groups that have been selected by a human operator’.Footnote ³⁶ The utility of this distinction is contested as target selection, under-defined in the Directive, becomes the only marker to distinguish semi-autonomous from autonomous weapons systems,Footnote ³⁷ making it ‘a distinction without difference’.Footnote ³⁸

The UK differentiates between an ‘automated’ and an ‘autonomous system’: ‘an automated or automatic system is one that, in response to inputs from one or more sensors, is programmed to logically follow a predefined set of rules in order to provide an outcome. Knowing the set of rules under which it is operating means that its output is predictable.’Footnote ³⁹ In contrast, an autonomous system is defined as

This definition of autonomous systems departs distinctly from an earlier UK definitionFootnote ⁴¹ in including the qualifiers ‘higher-level intent and direction’, thereby arguably ‘defining away’ the challenges associated with short-term AWS.

Domestically, the US Directive 3000.09 ‘lays out guidelines for the development and use of autonomous and semi-autonomous weapon systems’.Footnote ⁴² The Campaign to Stop Killer Robots, an international NGO coalition advocating for a pre-emptive ban, has welcomed Directive 3000.09 because it represents the first national policy on AWS.Footnote ⁴³ Human Rights Watch has even characterised the policy as ‘the world’s first moratorium on lethal fully autonomous weapons’ due to the its attached ten-year expiration date and the restrictions on what it defines as AWS to use lethal force.Footnote ⁴⁴

However, as Mark Gubrud points out, this is a misreading:Footnote ⁴⁵ first, with reference to a DoD spokesperson, ‘the 10-year expiration date is routine for such directives’ rather than representing a moratorium.Footnote ⁴⁶ Second, Directive 3000.09 also outlines ways of waiving even the restrictions it places on the lethal use of AWS.Footnote ⁴⁷ It further explicitly notes that widely defined ‘semi-autonomous weapons systems … may be used to apply lethal or non-lethal, kinetic or non-kinetic force’.Footnote ⁴⁸ Therefore, Directive 3000.09 ‘signals to developers and vendors that the Pentagon is serious about AWS’.Footnote ⁴⁹ Further, codifying that ‘[a]utonomous and semi-autonomous weapon systems shall be designed to allow commanders and operators to exercise appropriate levels of human judgment over the use of force’ will be ‘ineffective and irrelevant’ with regard to technological advances and operational demands potentially leading to the emergence of fully autonomous weapons systems.Footnote ⁵⁰

Considering the various research programmes, initiatives, and tests that show to what extent AWS are developed, tested, and already in use, it becomes clear that the emergence of legal regulations lags behind, which increases the importance of moving beyond a legal perspective and considering how norms may emerge in practice.

AWS in action

Although fully autonomous weapons systems, that is, systems with independent target selection, are not yet operational, their research and development is constantly proceeding. AWS can take many different forms, from singular entities to swarms, and they can operate on land, in air, and at sea. Many existing weapons platforms are arguably only a software update away from increasing autonomy. To give a few examples of current systems, in December 2016, the US Office of Naval research released a statement that autonomous unmanned swarming boats successfully performed a testing exercise, noting that

unmanned boats were given a large area of open water to patrol. As an unknown vessel entered the area, the group of swarmboats collaboratively determined which patrol boat would quickly approach the unknown vessel, classify it as harmless or suspicious, and communicate with other swarmboats to assist in tracking and trailing the unknown vessel while others continued to patrol the area.Footnote ⁵¹

In January 2017, the US DoD announced the successful test of a large micro-drone swarm in air, consisting of 103 ‘Perdix’ drones: ‘[t]he micro-drones demonstrated advanced swarm behaviors such as collective decision-making, adaptive formation flying, and self-healing.’Footnote ⁵² In this context, then US Secretary of Defense Ash Carter remarked that ‘[t]his is the kind of cutting-edge innovation that will keep us a step ahead of our adversaries. This demonstration will advance our development of autonomous systems.’Footnote ⁵³ These examples demonstrate that swarms of ‘smaller and smarter … systems would be able to make decisions and coordinate themselves without constant human supervision – perhaps without any contact at all’.Footnote ⁵⁴

While the above systems are so far mainly designed for defensive, surveillance, or reconnaissance purposes, developments also move towards offensive systems. The US Navy is further developing a submarine-hunting drone ship, the Sea Hunter, which has become operational in late 2016. While the Sea Hunter is still remotely controlled,

the progress of the platform’s technology, and the rapid advancements of algorithms enabling greater levels of autonomy, have inspired the Navy to begin thinking about additional missions … so that it can conduct surface warfare missions, fire weapons and launch electronic attacks.Footnote ⁵⁵

Developments are not confined to the US. In the 2000s, Israel has developed the Israel Aerospace Industries (IAI) HAROP, a loitering munition that has so far been operated by Israel, India, and Azerbaijan. The IAI note that ‘HAROP searches, finds, identifies, attacks and destroys targets, and performs battle damage assessment’ as an ‘autonomous platform operation’.Footnote ⁵⁶ HAROP is therefore able to engage targets autonomously and to destroy them via a self-destructing attack. According to media sources, Azerbaijan used HAROP for a deadly attack on a bus during the Nagorno-Karabakh conflict in April 2016.Footnote ⁵⁷

These examples also point to an important, shared characteristic of these weapons systems: they have different modes of operation, enabling switching between different modes at the interstice of automation and autonomy. South Korea’s SGR-A1, a stationary sentry robot developed in the 2000s that has been used at the Korean Demilitarized Zone, illustrates this observation. As it is equipped with heat and motion sensors and an auto-firing system,Footnote ⁵⁸ the system can theoretically detect, select, and engage a human target without human intervention. However, to what extent the SGR-A1 could be easily switched to and operated at an autonomous mode remains unclear. Table 1 provides an overview of some current weapons systems that operate without direct human intervention.Footnote ⁵⁹

Table 1 Sample AWS in development or operation.

Researching the normativity of AWS

Research on law and ethics asks how AWS challenge the implementation of fundamental international norms, to what extent they are governed by these norms, and whether discussions in the CCW will lead to the formulation of new fundamental normsFootnote ⁸⁰ governing their usage. Constructivist research on norm emergence and change mirrors these questions in two main ways: first, it concentrates almost exclusively on fundamental norms with regulative qualities and second, it only studies how new fundamental norms emerge or are contested in processes of deliberation.

First, fundamental norms are typically conceptualised as closely linked to international law. Second-wave constructivist models were thus concerned with analysing the emergence, internalisation, and effects of human rights as fundamental norms.Footnote ⁸¹ In the context of disarmament, Nina Tannenwald prominently analysed the ‘development of a normative prohibition against nuclear weapons’,Footnote ⁸² identified as one of the strongest, fundamental norms in International Relations. She defines a norm as ‘a shared expectation about behavior, a standard of right or wrong’,Footnote ⁸³ thereby linking norms to what is morally ‘right’. While this is certainly a key quality of norms, we argue for a broader understanding. Norms as standard of appropriateness can also comprise functional aspects such as efficiency and effectiveness in specific settings. A procedural norm in the military, for example, does not necessarily meet universal, public understandings of the morally ‘right’.

Second, the second and third wave of constructivist research focused on how norms emerge in processes of deliberation. In the second wave, actors, such as transnational advocacy networksFootnote ⁸⁴ or norm entrepreneurs, ‘attempt to convince a critical mass of states (norm leaders) to embrace new norms’.Footnote ⁸⁵ Third wave constructivist scholars criticise the sequential logic of these models by introducing more complexityFootnote ⁸⁶ and contestation.Footnote ⁸⁷ In stating that ‘norms are contested by default’,Footnote ⁸⁸ they argue for a diversity of normative meaning but these contestations still refer back to a deliberative expression of a shared norm, rather than its reconceptualisation in practice. Comprehensive regulation and stigmatisation of nuclear or chemical weapons only emerged after these weapons had been used in the First and Second World Wars, but the analytical focus of studies remains on public deliberations after usage rather than conceptualising in more detail how perceived ‘appropriate’ ways of using, later contested in deliberation, initially emerged in practices.Footnote ⁸⁹

Technological advances below and beyond the ‘radar’ of international legal regulation might therefore set de facto norms before debates have unfolded. This also challenges the prevalent constructivist perspective that ‘a norm … exists independently of the behavior that it guides or regulates’.Footnote ⁹⁰ In contrast, we argue that norms emerge in the context of practices. What kinds of new understandings of appropriateness emerge with the rise of AWS as security technologies in practice? As aforementioned, it is argued that ‘robotic weaponry will lower the psychological barriers to starting new wars’.Footnote ⁹¹ AWS may contribute to lowering thresholds for the use of force because they do not put the lives of their operators atFootnote risk.Footnote ⁹³ A ‘logic of consequences’, weighing the tactical-strategic and operational advantages of AWS, could spill into a ‘logic of appropriateness’.Footnote ⁹⁴ What appears to be useful and efficient in procedural terms and in a specific organisational context could therefore become the new standard of what is normatively ‘right’ and legitimate. These often-conflicting understandings of appropriateness might converge in some cases: protecting the lives of a country’s own troops would not only be considered as efficient, but also, publicly, as normatively appropriate and hence legitimate.

Building on these insights, we define norms broadly as standards of appropriateness for specific practices, resting on an inclusive understanding of norms. Here, Antje Wiener’s distinction between ‘fundamental norms’, ‘organizing principles’, and ‘standardized procedures’ is helpful as it points to what we call procedural norms.Footnote ⁹⁵ Wiener’s three types of norms are further specified based on three features: generalisation, specification, and contestation on ethical grounds (Table 2). Consequently, fundamental norms are considered as more general, less specific, and also as more contested on ethical grounds than the other types.

Table 2 Typology of norms.Footnote ⁹²

Despite drawing attention to different types of norms, Wiener’s typology is hierarchical and thereby still replicates the overall positive research bias towards fundamental norms in two ways. First, organising principles and/or standardised procedures merely implement fundamental norms. We argue that it is conceptually important to consider a reverse of this sequence through analysing how standardised procedures and/or organising principles may shape or define normativity. Second, the assumption of ‘ethical contestation’, in decreasing from fundamental norms to standardised procedures, suggests that the latter do not contain significant normative substance – an assumption we contest.

To gain an understanding of standardised procedures, what we call procedural norms, we suggest focusing on practices. We assume that these practices can construct new or different standards of appropriateness that turn into procedural norms when becoming widespread. Practices can therefore become decisive for studying both how procedural norms emerge and how these relate to fundamental norms.

Given that such procedural norms are subject to less ethical contestation and hence are also less in the public/academic focus than fundamental norms might make them even more relevant or powerful. Operating AWS is very much based on procedural norms – they are governed by an emerging established ‘way of doing things’. As mentioned previously, the US drone program shows how new standards of ‘appropriate’ warfare may emerge in international relations. These procedural norms are of high ethical, normative importance because overall, they are expected to conform to fundamental norms by implementing, respecting, or protecting them. How fundamental norms such as human rights influence practices, that is, what is procedurally legitimate as a ‘best practice’, is therefore often only defined via procedural norms, where operational standards of appropriateness are established.

A focus on procedural norms opens up a connection to practice theories, a diverse and dynamic theoretical programme in IR.Footnote ⁹⁶ Understood as patterned actions in social context,Footnote ⁹⁷ practices can act as sensitising conceptsFootnote ⁹⁸ to study concrete empirical phenomena, such as the emergence of normative standards. Due to their micro-orientation, practice theory can cast light on how norms may emerge on the procedural level and therefore make the processes constitutive of the wider normative international order visible.

The emergence of a technical, autonomous ‘agency’ that comes with AWS adds another element of complexity to this. Theoretically motivated studies of drones already argue for the emergence of ‘“technological agency” [that] shapes the evolving “field” of legal expertise (who counts as a legal expert and on what basis)’.Footnote ⁹⁹ The agency of AWS can significantly surpass this technological agency in not only shaping but eventually replacing human decision-making in the immediate sense of the term. In that, the problem emerging from ‘the anthropomorphic logic of technology’ that considers drones ‘as moral agents that can “act” rationally, dispassionately and – at least in principle – ethically’Footnote ¹⁰⁰ is intensified in the case of AWS. Varying degrees of autonomy and agency of machines play a significant role in constituting procedural norms that are usually expected to translate or follow preprogrammed parameters supposed to comply with fundamental norms. However, what happens when AWS define standards of procedural appropriateness as constitutive of normative meaning that do not match their programmers’ or decision-makers’ initial intentions? This is in line with general assumptions of actor-network theory and the ‘sociology of translation’,Footnote ¹⁰¹ but the more sophisticated agency of AWS opens a new chapter in this regard. The autonomous agency of AWS can potentially ‘break’ the conventional network of human and technological agency. A deeper theoretical discussion of this matter is beyond the scope of this article. But, in the context of AWS, we must ask whether we move from the co-constitution of a human decision and its material execution, which is based on the assumed prevalence of human control, to a sequence where technologies become the dominant constitutive, decision-making element. Furthermore, the absence of an ethical consciousness of machines in the human sense makes them particularly relevant for ethical contestations because their norm-setting qualities as fully autonomous actors will not be linked to human decisions, as was the case to date.

Based on this discussion, we propose studying AWS in the context of two different, but interrelated normative spheres: the legal-public sphere – the primary realm of fundamental norms; and the procedural-organisational sphere – the primary realm of procedural norms. While these spheres are not independent from each other, we use them to examine a broader notion of appropriateness: (1) legal-public appropriateness, and (2) procedural-organisational appropriateness.

Legal-public appropriateness represents fundamental norms, including public expectations in terms of (political) accountability, lawfulness, or transparency. In contrast, procedural-organisational appropriateness represents procedural norms, considerations of appropriateness in specific organisational settings, such as the armed forces, or in specific situations of warfare. Here, appropriateness is concerned with functional legitimacy, specific regulations, and accountability hierarchies, such as a chain of command. In this sense, appropriateness is linked to following clear procedural structures regardless of their content. In representing different contexts of appropriateness, this model accounts for diverging, interplaying layers of appropriate actions. A comprehensive research framework on the normativity of AWS should therefore consider both legal-public and procedural-organisational appropriateness (Table 3).

Table 3 Normative categories and examples of substance.

In sum, the category of legal-public appropriateness comprises fundamental norms such as human rights, international legal standards (international humanitarian and human rights law, jus ad bellum standards of the UN Charter), principles such as the pacific settlement of disputes and non-intervention, but also legitimacy expectations of the public in terms of political accountability and responsible conduct. This category hence combines legality with legitimacy. Procedural-organisational appropriateness comprises procedural norms relevant for specific organisational settings and practices. These are procedural efficiency, effectiveness, or standards in the military context such as obedience to orders, survival, or defeating the enemy. Table 3 provides examples of norms that might be relevant when studying AWS – however, it is important to emphasise that neither fundamental nor procedural norms are fixed in content. The precise importance of specific norms is only perceivable when analysing practices. In the following section, we consider how different types of appropriateness interrelate in the context of AWS and may lead to the emergence of new normativity.

AWS and procedural norms

Research on AWS provides rich summaries of how their development relates to fundamental norms of legal-public appropriateness (see earlier section on this). Yet norms of procedural-operational appropriateness are constituted by conflicting factors. Procedural norms may emerge around perceived operational advantages associated with practices surrounding AWS.

A main perceived advantage of granting full autonomy to AWS lies in their ‘superior’ ability to process a large quantity of information in contrast to humans who run the risk of facing a ‘potential cognitive overload’.Footnote ¹⁰² Furthermore, AWS would have the operational advantage of having agency ‘on the battlefield’, while remote-controlled weapons are steered from a remotely positioned ‘decision-making human’. AWS could therefore collect relevant information much more comprehensively but face a double interaction problem if not used in a fully autonomous mode, that is, with the human out of the immediate decision-making loop. If functioning with a human ‘on the loop’, involved in decision-making in an immediate sense, information that is collected and processed is then transmitted to a human actor. This actor must make a decision and communicate it back to the AWS that executes the command. Both remotely-controlled weapons systems and AWS with a human ‘on the loop’ therefore normally operate at a much lower speed than fighter jets for instance. This makes them vulnerable to countermeasures, while their communication link is also susceptible to interference.Footnote ¹⁰³ Having a human involved therefore may be perceived to slow down the process not only by separating the decision-making and executing actors, but also by technological restrictions in terms of transmission speed.

As Thomas K. Adams notes:

Not only do we have to question the quality of meaningful human control of humans ‘on the loop’ in this context, but we should also note the pressure towards giving AWS more decision-making agency due to reasons of efficiency and perceived military advantage. As Denise Garcia puts it: ‘The USA is pursuing killer robots because it can.’Footnote ¹⁰⁵ In other words, norms of procedural-organisational appropriateness set demands for not falling behind possible adversaries and allies alike, as highlighted by the UK’s Ministry of Defence: ‘Our conceptual thinking lags behind the art of the currently possible, never mind what lies in the future.’Footnote ¹⁰⁶ This increases the pressure towards proceeding with research and developing AWS ahead of any legal or political-legitimacy considerations.

Scholars have also cited budget pressures as operational advantages for AWS:Footnote ¹⁰⁷ while they require investing considerable financial resources from development to testing and training, they are projected to turn out cheaper than humans in the long run. This may become a future push factor, considering that, for example, the US Department of Veteran Affairs alone has spent an estimated US $213 billion in medical and disability payments during the ‘War on Terror’ (2001–16) and is expected to spend another US $1 trillion until 2053.Footnote ¹⁰⁸

Further, if the argument were validated that using AWS could decrease civilian casualties compared to the status quo, they would be perceived as procedurally, organisationally, and legally appropriate. It still remains questionable whether the public would accept AWS deciding about life and death as legitimate. Initial research on public opinion shows that support for AWS differs but may be affected when it comes to protecting the life of own troops and countering the risk of foreign powers developing AWS.Footnote ¹⁰⁹ Clearly, we should also consider what kind of normativity emerges here. Although the deadly use of force by AWS is not yet a pervasive reality, the way AWS kill is constructed by some as a norm of ‘humane’ future warfare. We can easily imagine how this implicit definition of appropriateness diffuses from the procedural-organisational to the legal-public dimension.

It could be argued at this point that the norm-setting qualities of AWS are strictly limited because they are designed to execute programmed commands within a narrowly defined operational range. In this sense, the autonomous agency of machines will never equate human consciousness and awareness, typically used as a maximum definition of autonomy by states. However, the phenomenon of agency through emergent behaviour, as noted by AI scholars, questions this assumption. It refers to behaviour that is not programmed but arises out of complexity.Footnote ¹¹⁰ This is also related to the potential misinterpretation of human signals by AWS, both in terms of the person ‘on the loop’ and those that the machine encounters in operational scenarios:

This means that the actions of AWS are unpredictable to a certain extent in unstructured, complex environments and decision situations such as battlefields, a point also highlighted by Noel Sharkey: discussing various AWS under development, he notes that all work with ‘clean’ scenarios, that is, scenarios containing only military targets and no civilian populations, which is far from many real life situations.Footnote ¹¹²

We should also note that AWS come with operational disadvantages in procedural terms. As an organisation and albeit not a monolith, the military is structured around control, which makes the idea of ceding it to AWS highly contested. The history of developing AWS in the US military, for example, includes various programs that were cancelled despite considerable investmentFootnote ¹¹³ and even lead to identifying ‘a cultural disinclination to turn attack decisions over to software algorithms’.Footnote ¹¹⁴ The targeting software included in AWS exceeds human capacities in processing large datasets and other quantitative tasks, but they are disadvantaged compared to humans when it comes to deliberative reasoning, interpreting qualitative data, or accurately judging complex social situations and interactions.Footnote ¹¹⁵ For example, in identifying targets, AWS would be unable to make qualified judgements based on interpreting facial expressions or body language in the same way humans can. Judging situations also concerns crucial assessments, such as whether an armed attack has occurred. This can be underlined by a famous 1983 incident involving Stanislav Petrov, a Soviet officer who disregarded an incoming nuclear missile strike, actually wrongly identified by the early-warning system, as a false alarm, deciding not to report it to superiors who would have retaliated with a nuclear attack.Footnote ¹¹⁶ An autonomous system working within preprogrammed parameters would have not been able to ‘feel’ that something was suspicious about incoming data points.

Therefore, there are also procedural norms working against AWS on an operational level. Yet we consider that the current development and deployment trajectories point towards AWS with disastrous consequences for use of force thresholds. Further, once introduced by one actor, their (future perceived) procedural advantages will shape new norms of procedural appropriateness, putting pressure on other actors to follow suit.

Conclusion: the normative consequences of AWS

This article addressed the emergence of procedural norms through evolving AWS and resulting challenges to constructivist approaches in IR. It outlined that fundamental norms enshrined in international law are expected to govern the usage of AWS in the same way as other technologies of warfare. But can technologies such as AWS be simply regulated by a set of predefined rules or do standards of appropriateness also emerge in practices? In addressing this question, we criticised first, how constructivist approaches privilege the deliberative over the practical emergence of norms and second, how they overemphasise fundamental norms to the detriment of procedural norms. We argue that procedural norms emanating from practices play an un-examined role in emerging normative structures. Instead of merely focusing on how norms regulate or govern AWS, we therefore suggest reversing the perspective and considering how AWS may construct and define norms in practice. In this, we map out a new programme for research both for constructivist scholars interested in norm emergence and scholars of AWS.

Existing research on AWS asks some central questions: can or do AWS conform to international law? How do AWS affect fundamental norms embedded in international law, such as human rights? How do autonomous technologies relate to expectations of political accountability and responsibility? Should AWS be pre-emptively banned? But research neglects that normativity may already emerge from their development, testing and deployment on the procedural, practical level. How AWS may set novel understandings of appropriate action remains understudied. To capture this dynamic analytically, our theoretical approach differentiates between two sets of norms: fundamental norms that define legal-public appropriateness and procedural norms that define procedural-organisational appropriateness. This understanding stands in contrast to the primary focus on fundamental norms present in constructivist norms research. We argue that understandings of what is procedurally appropriate in a specific organisational environment are often in conflict with expectations of legal-public appropriateness.

This is an important change of perspective as neither specialised literature on AWS, international/domestic law, nor constructivist research on norms has yet developed a substantial normative foundation for assessing the implications of AWS. As a normative consequence of this gap, current practices surrounding the development and usage of AWS effectively define ‘normal’ action in international relations. A similar development is already underway in the deployment and proliferation of drones as major instruments of contemporary counterterrorism. The US drone program has set novel precedents for how ending human life is ‘appropriate’ – not because these practices specifically comply with international law or adhere to domestic norms, but because they satisfy procedural-organisational appropriateness and partly coincide with publicly accepted legitimacy of the ‘War on Terror’. It will be difficult to return to a status quo before this new normality was created because other actors can now potentially exploit this room of maneuver at their discretion.

In this regard, the problem of agreeing on a general, pre-emptive ban of AWS lies in their elusiveness. Scholars continue to debate definitions of autonomy, agency, technical features, operational aspects, and appropriate human supervisory control in the context of AWS. Finding state-based consensus for a definition of AWS at the CCW that could become the basis for negotiating a regulative legal framework proves to hamper the process. Regardless of whether a ban will or will not be imposed, the practice of AWS will already shape understandings of what is appropriate and thereby take the place of a more profound societal-political debate on what is normatively acceptable. We need to be aware of these normative consequences of AWS in order to assess the role they will play in future security policies and international relations in general.