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THE FUTURE OF EMPLOYMENT: HOW SUSCEPTIBLE ARE JOBS TO COMPUTERISATION?∗ Carl Benedikt Frey† and Michael A. Osborne‡ September 17, 2013 . Abstract We examine how susceptible jobs are to computerisation. To assess this, we begin by implementing a novel methodology to estimate the probability of computerisation for 702 detailed occupations, using a Gaussian process classifier. Based on these estimates, we examine expected impacts of future computerisation on US labour market outcomes, with the primary objective of analysing the number of jobs at risk and the relationship between an occupation’s probability of computerisation, wages and educational attainment. According to our estimates, about 47 percent of total

US

employment is at risk. We further provide evidence

that wages and educational attainment exhibit a strong negative relationship with an occupation’s probability of computerisation. Keywords: Occupational Choice, Technological Change, Wage Inequality, Employment, Skill Demand JEL

Classification: E24, J24, J31, J62, O33.

We thank the Oxford University Engineering Sciences Department and the Oxford Martin Programme on the Impacts of Future Technology for hosting the “Machines and Employment” Workshop. We are indebted to Stuart Armstrong, Nick Bostrom, Eris Chinellato, Mark Cummins, Daniel Dewey, David Dorn, Alex Flint, Claudia Goldin, John Muellbauer, Vincent Mueller, Paul Newman, Seán Ó hÉigeartaigh, Anders Sandberg, Murray Shanahan, and Keith Woolcock for their excellent suggestions. † Oxford Martin School, Programme on the Impacts of Future Technology, University of Oxford, Oxford, OX1 1PT, United Kingdom, [emailprotected]. ‡ Department of Engineering Science, University of Oxford, Oxford, OX1 3PJ, United Kingdom, [emailprotected].

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I.

I NTRODUCTION

In this paper, we address the question: how susceptible are jobs to computerisation? Doing so, we build on the existing literature in two ways. First, drawing upon recent advances in Machine Learning (ML) and Mobile Robotics (MR), we develop a novel methodology to categorise occupations according to their susceptibility to computerisation.1 Second, we implement this methodology to estimate the probability of computerisation for 702 detailed occupations, and examine expected impacts of future computerisation on US labour market outcomes. Our paper is motivated by John Maynard Keynes’s frequently cited prediction of widespread technological unemployment “due to our discovery of means of economising the use of labour outrunning the pace at which we can find new uses for labour” (Keynes, 1933, p. 3). Indeed, over the past decades, computers have substituted for a number of jobs, including the functions of bookkeepers, cashiers and telephone operators (Bresnahan, 1999; MGI, 2013). More recently, the poor performance of labour markets across advanced economies has intensified the debate about technological unemployment among economists. While there is ongoing disagreement about the driving forces behind the persistently high unemployment rates, a number of scholars have pointed at computercontrolled equipment as a possible explanation for recent jobless growth (see, for example, Brynjolfsson and McAfee, 2011).2 The impact of computerisation on labour market outcomes is well-established in the literature, documenting the decline of employment in routine intensive occupations – i.e. occupations mainly consisting of tasks following well-defined procedures that can easily be performed by sophisticated algorithms. For example, studies by Charles, et al. (2013) and Jaimovich and Siu (2012) emphasise that the ongoing decline in manufacturing employment and the disappearance of other routine jobs is causing the current low rates of employment.3 In ad1

We refer to computerisation as job automation by means of computer-controlled equipment. 2 This view finds support in a recent survey by the McKinsey Global Institute (MGI), showing that 44 percent of firms which reduced their headcount since the financial crisis of 2008 had done so by means of automation (MGI, 2011). 3 Because the core job tasks of manufacturing occupations follow well-defined repetitive procedures, they can easily be codified in computer software and thus performed by computers (Acemoglu and Autor, 2011).

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dition to the computerisation of routine manufacturing tasks, Autor and Dorn (2013) document a structural shift in the labour market, with workers reallocating their labour supply from middle-income manufacturing to low-income service occupations. Arguably, this is because the manual tasks of service occupations are less susceptible to computerisation, as they require a higher degree of flexibility and physical adaptability (Autor, et al., 2003; Goos and Manning, 2007; Autor and Dorn, 2013). At the same time, with falling prices of computing, problem-solving skills are becoming relatively productive, explaining the substantial employment growth in occupations involving cognitive tasks where skilled labour has a comparative advantage, as well as the persistent increase in returns to education (Katz and Murphy, 1992; Acemoglu, 2002; Autor and Dorn, 2013). The title “Lousy and Lovely Jobs”, of recent work by Goos and Manning (2007), thus captures the essence of the current trend towards labour market polarization, with growing employment in high-income cognitive jobs and low-income manual occupations, accompanied by a hollowing-out of middle-income routine jobs. According to Brynjolfsson and McAfee (2011), the pace of technological innovation is still increasing, with more sophisticated software technologies disrupting labour markets by making workers redundant. What is striking about the examples in their book is that computerisation is no longer confined to routine manufacturing tasks. The autonomous driverless cars, developed by Google, provide one example of how manual tasks in transport and logistics may soon be automated. In the section “In Domain After Domain, Computers Race Ahead”, they emphasise how fast moving these developments have been. Less than ten years ago, in the chapter “Why People Still Matter”, Levy and Murnane (2004) pointed at the difficulties of replicating human perception, asserting that driving in traffic is insusceptible to automation: “But executing a left turn against oncoming traffic involves so many factors that it is hard to imagine discovering the set of rules that can replicate a driver’s behaviour [. . . ]”. Six years later, in October 2010, Google announced that it had modified several Toyota Priuses to be fully autonomous (Brynjolfsson and McAfee, 2011). To our knowledge, no study has yet quantified what recent technological progress is likely to mean for the future of employment. The present study intends to bridge this gap in the literature. Although there are indeed existing 3

useful frameworks for examining the impact of computers on the occupational employment composition, they seem inadequate in explaining the impact of technological trends going beyond the computerisation of routine tasks. Seminal work by Autor, et al. (2003), for example, distinguishes between cognitive and manual tasks on the one hand, and routine and non-routine tasks on the other. While the computer substitution for both cognitive and manual routine tasks is evident, non-routine tasks involve everything from legal writing, truck driving and medical diagnoses, to persuading and selling. In the present study, we will argue that legal writing and truck driving will soon be automated, while persuading, for instance, will not. Drawing upon recent developments in Engineering Sciences, and in particular advances in the fields of ML, including Data Mining, Machine Vision, Computational Statistics and other sub-fields of Artificial Intelligence, as well as MR, we derive additional dimensions required to understand the susceptibility of jobs to computerisation. Needless to say, a number of factors are driving decisions to automate and we cannot capture these in full. Rather we aim, from a technological capabilities point of view, to determine which problems engineers need to solve for specific occupations to be automated. By highlighting these problems, their difficulty and to which occupations they relate, we categorise jobs according to their susceptibility to computerisation. The characteristics of these problems were matched to different occupational characteristics, using O∗NET data, allowing us to examine the future direction of technological change in terms of its impact on the occupational composition of the labour market, but also the number of jobs at risk should these technologies materialise. The present study relates to two literatures. First, our analysis builds on the labour economics literature on the task content of employment (Autor, et al., 2003; Goos and Manning, 2007; Autor and Dorn, 2013). Based on defined premises about what computers do, this literature examines the historical impact of computerisation on the occupational composition of the labour market. However, the scope of what computers do has recently expanded, and will inevitably continue to do so (Brynjolfsson and McAfee, 2011; MGI, 2013). Drawing upon recent progress in ML, we expand the premises about the tasks computers are and will be suited to accomplish. Doing so, we build on the task content literature in a forward-looking manner. Furthermore, whereas this literature has largely focused on task measures from the Dictionary of Occupational 4

Titles (DOT), last revised in 1991, we rely on the 2010 version of the DOT successor O∗NET – an online service developed for the US Department of Labor.4 Accordingly, O∗NET has the advantage of providing more recent information on occupational work activities. Second, our study relates to the literature examining the offshoring of information-based tasks to foreign worksites (Jensen and Kletzer, 2005; Blinder, 2009; Jensen and Kletzer, 2010; Oldenski, 2012; Blinder and Krueger, 2013). This literature consists of different methodologies to rank and categorise occupations according to their susceptibility to offshoring. For example, using O ∗ NET data on the nature of work done in different occupations, Blinder (2009) estimates that 22 to 29 percent of US jobs are or will be offshorable in the next decade or two. These estimates are based on two defining characteristics of jobs that cannot be offshored: (a) the job must be performed at a specific work location; and (b) the job requires face-to-face personal communication. Naturally, the characteristics of occupations that can be offshored are different from the characteristics of occupations that can be automated. For example, the work of cashiers, which has largely been substituted by self- service technology, must be performed at specific work location and requires face-to-face contact. The extent of computerisation is therefore likely to go beyond that of offshoring. Hence, while the implementation of our methodology is similar to that of Blinder (2009), we rely on different occupational characteristics. The remainder of this paper is structured as follows. In Section II, we review the literature on the historical relationship between technological progress and employment. Section III describes recent and expected future technological developments. In Section IV, we describe our methodology, and in Section V, we examine the expected impact of these technological developments on labour market outcomes. Finally, in Section VI, we derive some conclusions. II.

A HISTORY OF TECHNOLOGICAL REVOLUTIONS AND EMPLOYMENT

The concern over technological unemployment is hardly a recent phenomenon. Throughout history, the process of creative destruction, following technological inventions, has created enormous wealth, but also undesired disruptions. As stressed by Schumpeter (1962), it was not the lack of inventive ideas that 4

An exception is Goos, et al. (2009).

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set the boundaries for economic development, but rather powerful social and economic interests promoting the technological status quo. This is nicely illustrated by the example of William Lee, inventing the stocking frame knitting machine in 1589, hoping that it would relieve workers of hand-knitting. Seeking patent protection for his invention, he travelled to London where he had rented a building for his machine to be viewed by Queen Elizabeth I. To his disappointment, the Queen was more concerned with the employment impact of his invention and refused to grant him a patent, claiming that: “Thou aimest high, Master Lee. Consider thou what the invention could do to my poor subjects. It would assuredly bring to them ruin by depriving them of employment, thus making them beggars” (cited in Acemoglu and Robinson, 2012, p. 182f). Most likely the Queen’s concern was a manifestation of the hosiers’ guilds fear that the invention would make the skills of its artisan members obsolete.5 The guilds’ opposition was indeed so intense that William Lee had to leave Britain. That guilds systematically tried to weaken market forces as aggregators to maintain the technological status quo is persuasively argued by Kellenbenz (1974, p. 243), stating that “guilds defended the interests of their members against outsiders, and these included the inventors who, with their new equipment and techniques, threatened to disturb their members’ economic status.”6 As pointed out by Mokyr (1998, p. 11): “Unless all individuals accept the “verdict” of the market outcome, the decision whether to adopt an innovation is likely to be resisted by losers through non-market mechanism and political activism.” Workers can thus be expected to resist new technologies, insofar that they make their skills obsolete and irreversibly reduce their expected earnings. The balance between job conservation and technological progress therefore, to a large extent, reflects the balance of power in society, and how gains from technological progress are being distributed. The British Industrial Revolution illustrates this point vividly. While still widely present on the Continent, the craft guild in Britain had, by the time of 5

The term artisan refers to a craftsman who engages in the entire production process of a good, containing almost no division of labour. By guild we mean an association of artisans that control the practice of their craft in a particular town. 6 There is an ongoing debate about the technological role of the guilds. Epstein (1998), for example, has argued that they fulfilled an important role in the intergenerational transmission of knowledge. Yet there is no immediate contradiction between such a role and their conservative stand on technological progress: there are clear examples of guilds restraining the diffusion of inventions (see, for example, Ogilvie, 2004).

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the Glorious Revolution of 1688, declined and lost most of its political clout (Nef, 1957, pp. 26 and 32). With Parliamentary supremacy established over the Crown, legislation was passed in 1769 making the destruction of machinery punishable by death (Mokyr, 1990, p. 257). To be sure, there was still resistance to mechanisation. The “Luddite” riots between 1811 and 1816 were partly a manifestation of the fear of technological change among workers as Parliament revoked a 1551 law prohibiting the use of gig mills in the wool-finishing trade. The British government however took an increasingly stern view on groups attempting to halt technological progress and deployed 12,000 men against the rioters (Mantoux, 2006, p. 403-8). The sentiment of the government towards the destruction of machinery was explained by a resolution passed after the Lancashire riots of 1779, stating that: “The sole cause of great riots was the new machines employed in cotton manufacture; the country notwithstanding has greatly benefited from their erection [and] destroying them in this country would only be the means of transferring them to another [. . . ] to the detriment of the trade of Britain” (cited in Mantoux, 2006, p. 403). There are at least two possible explanations for the shift in attitudes towards technological progress. First, after Parliamentary supremacy was established over the Crown, the property owning classes became politically dominant in Britain (North and Weingast, 1989). Because the diffusion of various manufacturing technologies did not impose a risk to the value of their assets, and some property owners stood to benefit from the export of manufactured goods, the artisans simply did not have the political power to repress them. Second, inventors, consumers and unskilled factory workers largely benefited from mechanisation (Mokyr, 1990, p. 256 and 258). It has even been argued that, despite the employment concerns over mechanisation, unskilled workers have been the greatest beneficiaries of the Industrial Revolution (Clark, 2008).7 While there 7

Various estimations of the living standards of workers in Britain during the industrialisation exist in the literature. For example, Clark (2008) finds that real wages over the period 1760 to 1860 rose faster than GDP per capita. Further evidence provided by Lindert and Williamson (1983) even suggests that real wages nearly doubled between 1820 and 1850. Feinstein (1998), on the other hand, finds a much more moderate increase, with average working-class living standards improving by less than 15 percent between 1770 and 1870. Finally, Allen (2009a) finds that over the first half of the nineteenth century, the real wage stagnated while output per worker expanded. After the mid nineteenth century, however, real wages began to grow in line with productivity. While this implies that capital owners were the greatest beneficiaries of the Industrial Revolution, there is at the same time consensus that average living standards largely improved.

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is contradictory evidence suggesting that capital owners initially accumulated a growing share of national income (Allen, 2009a), there is equally evidence of growing real wages (Lindert and Williamson, 1983; Feinstein, 1998). This implies that although manufacturing technologies made the skills of artisans obsolete, gains from technological progress were distributed in a manner that gradually benefited a growing share of the labour force.8 An important feature of nineteenth century manufacturing technologies is that they were largely “deskilling” – i.e. they substituted for skills through the simplification of tasks (Braverman, 1974; Hounshell, 1985; James and Skinner, 1985; Goldin and Katz, 1998). The deskilling process occurred as the factory system began to displace the artisan shop, and it picked up pace as production increasingly mechanized with the adoption of steam power (Goldin and Sokoloff, 1982; Atack, et al., 2008a). Work that had previously been performed by artisans was now decomposed into smaller, highly specialised, sequences, requiring less skill, but more workers, to perform.9 Some innovations were even designed to be deskilling. For example, Eli Whitney, a pioneer of interchangeable parts, described the objective of this technology as “to substitute correct and effective operations of machinery for the skill of the artist which is acquired only by long practice and experience; a species of skill which is not possessed in this country to any considerable extent” (Habakkuk, 1962, p. 22). Together with developments in continuous-flow production, enabling workers to be stationary while different tasks were moved to them, it was identical interchangeable parts that allowed complex products to be assembled from mass produced individual components by using highly specialised machine tools to 8

The term skill is associated with higher levels of education, ability, or job training. Following Goldin and Katz (1998), we refer to technology-skill or capital-skill complementarity when a new technology or physical capital complements skilled labour relative to unskilled workers. 9 The production of plows nicely illustrates the differences between the artisan shop and the factory. In one artisan shop, two men spent 118 man-hours using hammers, anvils, chisels, hatchets, axes, mallets, shaves and augers in 11 distinct operations to produce a plow. By contrast, a mechanized plow factory employed 52 workers performing 97 distinct tasks, of which 72 were assisted by steam power, to produce a plow in just 3.75 man-hours. The degree of specialization was even greater in the production of men’s white muslin shirts. In the artisan shop, one worker spent 1439 hours performing 25 different tasks to produce 144 shirts. In the factory, it took 188 man-hours to produce the same quantity, engaging 230 different workers performing 39 different tasks, of which more than half required steam power. The workers involved included cutters, turners and trimmers, as well as foremen and forewomen, inspectors, errand boys, an engineer, a fireman, and a watchman (US Department of Labor, 1899).

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a sequence of operations.10 Yet while the first assembly-line was documented in 1804, it was not until the late nineteenth century that continuous-flow processes started to be adopted on a larger scale, which enabled corporations such as the Ford Motor Company to manufacture the T-Ford at a sufficiently low price for it to become the people’s vehicle (Mokyr, 1990, p. 137). Crucially, the new assembly line introduced by Ford in 1913 was specifically designed for machinery to be operated by unskilled workers (Hounshell, 1985, p. 239). Furthermore, what had previously been a one-man job was turned into a 29-man worker operation, reducing the overall work time by 34 percent (Bright, 1958). The example of the Ford Motor Company thus underlines the general pattern observed in the nineteenth century, with physical capital providing a relative complement to unskilled labour, while substituting for relatively skilled artisans (James and Skinner, 1985; Louis and Paterson, 1986; Brown and Philips, 1986; Atack, et al., 2004).11 Hence, as pointed out by Acemoglu (2002, p. 7): “the idea that technological advances favor more skilled workers is a twentieth century phenomenon.” The conventional wisdom among economic historians, in other words, suggests a discontinuity between the nineteenth and twentieth century in the impact of capital deepening on the relative demand for skilled labour. The modern pattern of capital-skill complementarity gradually emerged in the late nineteenth century, as manufacturing production shifted to increasingly mechanised assembly lines. This shift can be traced to the switch to electricity from steam and water-power which, in combination with continuous-process 10

These machines were sequentially implemented until the production process was completed. Over time, such machines became much cheaper relative to skilled labor. As a result, production became much more capital intensive (Hounshell, 1985). 11 Williamson and Lindert (1980), on the other hand, find a relative rise in wage premium of skilled labour over the period 1820 to 1860, which they partly attribute to capital deepening. Their claim of growing wage inequality over this period has, however, been challenged (Margo, 2000). Yet seen over the long-run, a more refined explanation is that the manufacturing share of the labour force in the nineteenth century hollowed out. This is suggested by recent findings, revealing a decline of middle-skill artisan jobs in favour of both high-skill white collar workers and low-skill operatives (Gray, 2013; Katz and Margo, 2013). Furthermore, even if the share of operatives was increasing due to organizational change within manufacturing and overall manufacturing growth, it does not follow that the share of unskilled labor was rising in the aggregate economy, because some of the growth in the share of operatives may have come at the expense of a decrease in the share of workers employed as low-skilled farm workers in agriculture (Katz and Margo, 2013). Nevertheless, this evidence is consistent with the literature showing that relatively skilled artisans were replaced by unskilled factory workers, suggesting that technological change in manufacturing was deskilling.

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and batch production methods, reduced the demand for unskilled manual workers in many hauling, conveying, and assembly tasks, but increased the demand for skills (Goldin and Katz, 1998). In short, while factory assembly lines, with their extreme division of labour, had required vast quantities of human operatives, electrification allowed many stages of the production process to be automated, which in turn increased the demand for relatively skilled blue-collar production workers to operate the machinery. In addition, electrification contributed to a growing share of white-collar nonproduction workers (Goldin and Katz, 1998). Over the course of the nineteenth century, establishments became larger in size as steam and water power technologies improved, allowing them to adopt powered machinery to realize productivity gains through the combination of enhanced division of labour and higher capital intensity (Atack, et al., 2008a). Furthermore, the transport revolution lowered costs of shipping goods domestically and internationally as infrastructure spread and improved (Atack, et al., 2008b). The market for artisan goods early on had largely been confined to the immediate surrounding area because transport costs were high relative to the value of the goods produced. With the transport revolution, however, market size expanded, thereby eroding local monopoly power, which in turn increased competition and compelled firms to raise productivity through mechanisation. As establishments became larger and served geographically expended markets, managerial tasks increased in number and complexity, requiring more managerial and clerking employees (Chandler, 1977). This pattern was, by the turn of the twentieth century, reinforced by electrification, which not only contributed to a growing share of relatively skilled blue-collar labour, but also increased the demand for white-collar workers (Goldin and Katz, 1998), who tended to have higher educational attainment (Allen, 2001).12 Since electrification, the story of the twentieth century has been the race between education and technology (Goldin and Katz, 2009). The US high school movement coincided with the first industrial revolution of the office (Goldin and Katz, 1995). While the typewriter was invented in the 1860s, it was not introduced in the office until the early twentieth century, when it entered a wave 12

Most likely, the growing share of white-collar workers increased the element of human interaction in employment. Notably, Michaels, et al. (2013) find that the increase in the employment share of interactive occupations, going hand in hand with an increase in their relative wage bill share, was particularly strong between 1880 and 1930, which is a period of rapid change in communication and transport technology.

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of mechanisation, with dictaphones, calculators, mimeo machines, address machines, and the predecessor of the computer – the keypunch (Beniger, 1986; Cortada, 2000). Importantly, these office machines reduced the cost of information processing tasks and increased the demand for the complementary factor – i.e. educated office workers. Yet the increased supply of educated office workers, following the high school movement, was associated with a sharp decline in the wage premium of clerking occupations relative to production workers (Goldin and Katz, 1995). This was, however, not the result of deskilling technological change. Clerking workers were indeed relatively educated. Rather, it was the result of the supply of educated workers outpacing the demand for their skills, leading educational wage differentials to compress. While educational wage differentials in the US narrowed from 1915 to 1980 (Goldin and Katz, 2009), both educational wage differentials and overall wage inequality have increased sharply since the 1980s in a number of countries (Krueger, 1993; Murphy, et al., 1998; Atkinson, 2008; Goldin and Katz, 2009). Although there are clearly several variables at work, consensus is broad that this can be ascribed to an acceleration in capital-skill complementarity, driven by the adoption of computers and information technology (Krueger, 1993; Autor, et al., 1998; Bresnahan, et al., 2002). What is commonly referred to as the Computer Revolution began with the first commercial uses of computers around 1960 and continued through the development of the Internet and e-commerce in the 1990s. As the cost per computation declined at an annual average of 37 percent between 1945 and 1980 (Nordhaus, 2007), telephone operators were made redundant, the first industrial robot was introduced by General Motors in the 1960s, and in the 1970s airline reservations systems led the way in selfservice technology (Gordon, 2012). During the 1980s and 1990s, computing costs declined even more rapidly, on average by 64 percent per year, accompanied by a surge in computational power (Nordhaus, 2007).13 At the same time, bar-code scanners and cash machines were spreading across the retail and financial industries, and the first personal computers were introduced in the early 1980s, with their word processing and spreadsheet functions eliminating copy typist occupations and allowing repetitive calculations to be automated (Gordon, 2012). This substitution for labour marks a further important reversal. 13

Computer power even increased 18 percent faster on annual basis than predicted by Moore’s Law, implying a doubling every two years (Nordhaus, 2007).

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The early twentieth century office machines increased the demand for clerking workers (Chandler, 1977; Goldin and Katz, 1995). In a similar manner, computerisation augments demand for such tasks, but it also permits them to be automated (Autor, et al., 2003). The Computer Revolution can go some way in explaining the growing wage inequality of the past decades. For example, Krueger (1993) finds that workers using a computer earn roughly earn 10 to 15 percent more than others, but also that computer use accounts for a substantial share of the increase in the rate of return to education. In addition, more recent studies find that computers have caused a shift in the occupational structure of the labour market. Autor and Dorn (2013), for example, show that as computerisation erodes wages for labour performing routine tasks, workers will reallocate their labour supply to relatively low-skill service occupations. More specifically, between 1980 and 2005, the share of US labour hours in service occupations grew by 30 percent after having been flat or declining in the three prior decades. Furthermore, net changes in US employment were U-shaped in skill level, meaning that the lowest and highest job-skill quartile expanded sharply with relative employment declines in the middle of the distribution. The expansion in high-skill employment can be explained by the falling price of carrying out routine tasks by means of computers, which complements more abstract and creative services. Seen from a production function perspective, an outward shift in the supply of routine informational inputs increases the marginal productivity of workers they are demanded by. For example, text and data mining has improved the quality of legal research as constant access to market information has improved the efficiency of managerial decision-making – i.e. tasks performed by skilled workers at the higher end of the income distribution. The result has been an increasingly polarised labour market, with growing employment in high-income cognitive jobs and low-income manual occupations, accompanied by a hollowing-out of middle-income routine jobs. This is a pattern that is not unique to the US and equally applies to a number of developed economies (Goos, et al., 2009).14 14

While there is broad consensus that computers substituting for workers in routine-intensive tasks has driven labour market polarisation over the past decades, there are, indeed, alternative explanations. For example, technological advances in computing have dramatically lowered the cost of leaving information-based tasks to foreign worksites (Jensen and Kletzer, 2005; Blinder, 2009; Jensen and Kletzer, 2010; Oldenski, 2012; Blinder and Krueger, 2013). The decline in

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How technological progress in the twenty-first century will impact on labour market outcomes remains to be seen. Throughout history, technological progress has vastly shifted the composition of employment, from agriculture and the artisan shop, to manufacturing and clerking, to service and management occupations. Yet the concern over technological unemployment has proven to be exaggerated. The obvious reason why this concern has not materialised relates to Ricardo’s famous chapter on machinery, which suggests that laboursaving technology reduces the demand for undifferentiated labour, thus leading to technological unemployment (Ricardo, 1819). As economists have long understood, however, an invention that replaces workers by machines will have effects on all product and factor markets. An increase in the efficiency of production which reduces the price of one good, will increase real income and thus increase demand for other goods. Hence, in short, technological progress has two competing effects on employment (Aghion and Howitt, 1994). First, as technology substitutes for labour, there is a destruction effect, requiring workers to reallocate their labour supply; and second, there is the capitalisation effect, as more companies enter industries where productivity is relatively high, leading employment in those industries to expand. Although the capitalisation effect has been predominant historically, our discovery of means of economising the use of labour can outrun the pace at which we can find new uses for labour, as Keynes (1933) pointed out. The reason why human labour has prevailed relates to its ability to adopt and acquire new skills by means of education (Goldin and Katz, 2009). Yet as computerisation enters more cognitive domains this will become increasingly challenging (Brynjolfsson and McAfee, 2011). Recent empirical findings are therefore particularly concerning. For example, Beaudry, et al. (2013) document a decline in the demand for skill over the past decade, even as the supply of workers with higher education has continued to grow. They show that high-skilled workers have moved down the occupational ladder, taking on jobs traditionally performed by low-skilled workers, pushing low-skilled workers even further down the occupational ladder and, to some extent, even out of the labour force. This the routine-intensity of employment is thus likely to result from a combination of offshoring and automation. Furthermore, there is evidence suggesting that improvements in transport and communication technology have augmented occupations involving human interaction, spanning across both cognitive and manual tasks (Michaels, et al., 2013). These explanations are nevertheless equally related to advance in computing and communications technology.

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raises questions about: (a) the ability of human labour to win the race against technology by means of education; and (b) the potential extent of technological unemployment, as an increasing pace of technological progress will cause higher job turnover, resulting in a higher natural rate of unemployment (Lucas and Prescott, 1974; Davis and Haltiwanger, 1992; Pissarides, 2000). While the present study is limited to examining the destruction effect of technology, it nevertheless provides a useful indication of the job growth required to counterbalance the jobs at risk over the next decades. III.

T HE TECHNOLOGICAL REVOLUTIONS OF THE TWENTY- FIRST CENTURY

The secular price decline in the real cost of computing has created vast economic incentives for employers to substitute labour for computer capital.15 Yet the tasks computers are able to perform ultimately depend upon the ability of a programmer to write a set of procedures or rules that appropriately direct the technology in each possible contingency. Computers will therefore be relatively productive to human labour when a problem can be specified – in the sense that the criteria for success are quantifiable and can readily be evaluated (Acemoglu and Autor, 2011). The extent of job computerisation will thus be determined by technological advances that allow engineering problems to be sufficiently specified, which sets the boundaries for the scope of computerisation. In this section, we examine the extent of tasks computer-controlled equipment can be expected to perform over the next decades. Doing so, we focus on advances in fields related to Machine Learning (ML), including Data Mining, Machine Vision, Computational Statistics and other sub-fields of Artificial Intelligence (AI), in which efforts are explicitly dedicated to the development of algorithms that allow cognitive tasks to be automated. In addition, we examine the application of ML technologies in Mobile Robotics (MR), and thus the extent of computerisation in manual tasks. Our analysis builds on the task categorisation of Autor, et al. (2003), which distinguishes between workplace tasks using a two-by-two matrix, with routine versus non-routine tasks on one axis, and manual versus cognitive tasks on the other. In short, routine tasks are defined as tasks that follow explicit rules that 15

We refer to computer capital as accumulated computers and computer-controlled equipment by means of capital deepening.

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can be accomplished by machines, while non-routine tasks are not sufficiently well understood to be specified in computer code. Each of these task categories can, in turn, be of either manual or cognitive nature – i.e. they relate to physical labour or knowledge work. Historically, computerisation has largely been confined to manual and cognitive routine tasks involving explicit rulebased activities (Autor and Dorn, 2013; Goos, et al., 2009). Following recent technological advances, however, computerisation is now spreading to domains commonly defined as non-routine. The rapid pace at which tasks that were defined as non-routine only a decade ago have now become computerisable is illustrated by Autor, et al. (2003), asserting that: “Navigating a car through city traffic or deciphering the scrawled handwriting on a personal check – minor undertakings for most adults – are not routine tasks by our definition.” Today, the problems of navigating a car and deciphering handwriting are sufficiently well understood that many related tasks can be specified in computer code and automated (Veres, et al., 2011; Plötz and Fink, 2009). Recent technological breakthroughs are, in large part, due to efforts to turn non-routine tasks into well-defined problems. Defining such problems is helped by the provision of relevant data: this is highlighted in the case of handwriting recognition by Plötz and Fink (2009). The success of an algorithm for handwriting recognition is difficult to quantify without data to test on – in particular, determining whether an algorithm performs well for different styles of writing requires data containing a variety of such styles. That is, data is required to specify the many contingencies a technology must manage in order to form an adequate substitute for human labour. With data, objective and quantifiable measures of the success of an algorithm can be produced, which aid the continual improvement of its performance relative to humans. As such, technological progress has been aided by the recent production of increasingly large and complex datasets, known as big data.16 For instance, with a growing corpus of human-translated digitalised text, the success of a machine translator can now be judged by its accuracy in reproducing observed translations. Data from United Nations documents, which are translated by hu16

Predictions by Cisco Systems suggest that the Internet traffic in 2016 will be around 1 zettabyte (1 × 1021 bytes) (Cisco, 2012). In comparison, the information contained in all books worldwide is about 480 terabytes (5 × 1014 bytes), and a text transcript of all the words ever spoken by humans would represent about 5 exabytes (5 × 1018 bytes) (UC Berkeley School of Information, 2003).

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man experts into six languages, allow Google Translate to monitor and improve the performance of different machine translation algorithms (Tanner, 2007). Further, ML algorithms can discover unexpected similarities between old and new data, aiding the computerisation of tasks for which big data has newly become available. As a result, computerisation is no longer confined to routine tasks that can be written as rule-based software queries, but is spreading to every non-routine task where big data becomes available (Brynjolfsson and McAfee, 2011). In this section, we examine the extent of future computerisation beyond routine tasks. III.A. Computerisation in non-routine cognitive tasks With the availability of big data, a wide range of non-routine cognitive tasks are becoming computerisable. That is, further to the general improvement in technological progress due to big data, algorithms for big data are rapidly entering domains reliant upon storing or accessing information. The use of big data is afforded by one of the chief comparative advantages of computers relative to human labor: scalability. Little evidence is required to demonstrate that, in performing the task of laborious computation, networks of machines scale better than human labour (Campbell-Kelly, 2009). As such, computers can better manage the large calculations required in using large datasets. ML algorithms running on computers are now, in many cases, better able to detect patterns in big data than humans. Computerisation of cognitive tasks is also aided by another core comparative advantage of algorithms: their absence of some human biases. An algorithm can be designed to ruthlessly satisfy the small range of tasks it is given. Humans, in contrast, must fulfill a range of tasks unrelated to their occupation, such as sleeping, necessitating occasional sacrifices in their occupational performance (Kahneman, et al., 1982). The additional constraints under which humans must operate manifest themselves as biases. Consider an example of human bias: Danziger, et al. (2011) demonstrate that experienced Israeli judges are substantially more generous in their rulings following a lunch break. It can thus be argued that many roles involving decision-making will benefit from impartial algorithmic solutions. Fraud detection is a task that requires both impartial decision making and the ability to detect trends in big data. As such, this task is now almost com16

pletely automated (Phua, et al., 2010). In a similar manner, the comparative advantages of computers are likely to change the nature of work across a wide range of industries and occupations. In health care, diagnostics tasks are already being computerised. Oncologists at Memorial Sloan-Kettering Cancer Center are, for example, using IBM’s Watson computer to provide chronic care and cancer treatment diagnostics. Knowledge from 600,000 medical evidence reports, 1.5 million patient records and clinical trials, and two million pages of text from medical journals, are used for benchmarking and pattern recognition purposes. This allows the computer to compare each patient’s individual symptoms, genetics, family and medication history, etc., to diagnose and develop a treatment plan with the highest probability of success (Cohn, 2013). In addition, computerisation is entering the domains of legal and financial services. Sophisticated algorithms are gradually taking on a number of tasks performed by paralegals, contract and patent lawyers (Markoff, 2011). More specifically, law firms now rely on computers that can scan thousands of legal briefs and precedents to assist in pre-trial research. A frequently cited example is Symantec’s Clearwell system, which uses language analysis to identify general concepts in documents, can present the results graphically, and proved capable of analysing and sorting more than 570,000 documents in two days (Markoff, 2011). Furthermore, the improvement of sensing technology has made sensor data one of the most prominent sources of big data (Ackerman and Guizzo, 2011). Sensor data is often coupled with new ML fault- and anomaly-detection algorithms to render many tasks computerisable. A broad class of examples can be found in condition monitoring and novelty detection, with technology substituting for closed-circuit TV (CCTV) operators, workers examining equipment defects, and clinical staff responsible for monitoring the state of patients in intensive care. Here, the fact that computers lack human biases is of great value: algorithms are free of irrational bias, and their vigilance need not be interrupted by rest breaks or lapses of concentration. Following the declining costs of digital sensing and actuation, ML approaches have successfully addressed condition monitoring applications ranging from batteries (Saha, et al., 2007), to aircraft engines (King, et al., 2009), water quality (Osborne, et al., 2012) and intensive care units (ICUs) (Clifford and Clifton, 2012; Clifton, et al., 2012). Sensors can 17

equally be placed on trucks and pallets to improve companies’ supply chain management, and used to measure the moisture in a field of crops to track the flow of water through utility pipes. This allows for automatic meter reading, eliminating the need for personnel to gather such information. For example, the cities of Doha, São Paulo, and Beijing use sensors on pipes, pumps, and other water infrastructure to monitor conditions and manage water loss, reducing leaks by 40 to 50 percent. In the near future, it will be possible to place inexpensive sensors on light poles, sidewalks, and other public property to capture sound and images, likely reducing the number of workers in law enforcement (MGI, 2013). Advances in user interfaces also enable computers to respond directly to a wider range of human requests, thus augmenting the work of highly skilled labour, while allowing some types of jobs to become fully automated. For example, Apple’s Siri and Google Now rely on natural user interfaces to recognise spoken words, interpret their meanings, and act on them accordingly. Moreover, a company called SmartAction now provides call computerisation solutions that use ML technology and advanced speech recognition to improve upon conventional interactive voice response systems, realising cost savings of 60 to 80 percent over an outsourced call center consisting of human labour (CAA, 2012). Even education, one of the most labour intensive sectors, will most likely be significantly impacted by improved user interfaces and algorithms building upon big data. The recent growth in MOOCs (Massive Open Online Courses) has begun to generate large datasets detailing how students interact on forums, their diligence in completing assignments and viewing lectures, and their ultimate grades (Simonite, 2013; Breslow, et al., 2013). Such information, together with improved user interfaces, will allow for ML algorithms that serve as interactive tutors, with teaching and assessment strategies statistically calibrated to match individual student needs (Woolf, 2010). Big data analysis will also allow for more effective predictions of student performance, and for their suitability for post-graduation occupations. These technologies can equally be implemented in recruitment, most likely resulting in the streamlining of human resource (HR) departments. Occupations that require subtle judgement are also increasingly susceptible to computerisation. To many such tasks, the unbiased decision making of an algorithm represents a comparative advantage over human operators. In the most 18

challenging or critical applications, as in ICUs, algorithmic recommendations may serve as inputs to human operators; in other circumstances, algorithms will themselves be responsible for appropriate decision-making. In the financial sector, such automated decision-making has played a role for quite some time. AI algorithms are able to process a greater number of financial announcements, press releases, and other information than any human trader, and then act faster upon them (Mims, 2010). Services like Future Advisor similarly use AI to offer personalised financial advice at larger scale and lower cost. Even the work of software engineers may soon largely be computerisable. For example, advances in ML allow a programmer to leave complex parameter and design choices to be appropriately optimised by an algorithm (Hoos, 2012). Algorithms can further automatically detect bugs in software (Hangal and Lam, 2002; Livshits and Zimmermann, 2005; Kim, et al., 2008), with a reliability that humans are unlikely to match. Big databases of code also offer the eventual prospect of algorithms that learn how to write programs to satisfy specifications provided by a human. Such an approach is likely to eventually improve upon human programmers, in the same way that human-written compilers eventually proved inferior to automatically optimised compilers. An algorithm can better keep the whole of a program in working memory, and is not constrained to human-intelligible code, allowing for holistic solutions that might never occur to a human. Such algorithmic improvements over human judgement are likely to become increasingly common. Although the extent of these developments remains to be seen, estimates by MGI (2013) suggests that sophisticated algorithms could substitute for approximately 140 million full-time knowledge workers worldwide. Hence, while technological progress throughout economic history has largely been confined to the mechanisation of manual tasks, requiring physical labour, technological progress in the twenty-first century can be expected to contribute to a wide range of cognitive tasks, which, until now, have largely remained a human domain. Of course, many occupations being affected by these developments are still far from fully computerisable, meaning that the computerisation of some tasks will simply free-up time for human labour to perform other tasks. Nonetheless, the trend is clear: computers increasingly challenge human labour in a wide range of cognitive tasks (Brynjolfsson and McAfee, 2011).

19

III.B.

Computerisation in non-routine manual tasks

Mobile robotics provides a means of directly leveraging ML technologies to aid the computerisation of a growing scope of manual tasks. The continued technological development of robotic hardware is having notable impact upon employment: over the past decades, industrial robots have taken on the routine tasks of most operatives in manufacturing. Now, however, more advanced robots are gaining enhanced sensors and manipulators, allowing them to perform non-routine manual tasks. For example, General Electric has recently developed robots to climb and maintain wind turbines, and more flexible surgical robots with a greater range of motion will soon perform more types of operations (Robotics-VO, 2013). In a similar manner, the computerisation of logistics is being aided by the increasing cost-effectiveness of highly instrumented and computerised cars. Mass-production vehicles, such as the Nissan LEAF, contain on-board computers and advanced telecommunication equipment that render the car a potentially fly-by-wire robot.17 Advances in sensor technology mean that vehicles are likely to soon be augmented with even more advanced suites of sensors. These will permit an algorithmic vehicle controller to monitor its environment to a degree that exceeds the capabilities of any human driver: they have the ability to simultaneously look both forwards and backwards, can natively integrate camera, GPS and LIDAR data, and are not subject to distraction. Algorithms are thus potentially safer and more effective drivers than humans. The big data provided by these improved sensors are offering solutions to many of the engineering problems that had hindered robotic development in the past. In particular, the creation of detailed three dimensional maps of road networks has enabled autonomous vehicle navigation; most notably illustrated by Google’s use of large, specialised datasets collected by its driverless cars (Guizzo, 2011). It is now completely feasible to store representations of the entire road network on-board a car, dramatically simplifying the navigation problem. Algorithms that could perform navigation throughout the changing seasons, particularly after snowfall, have been viewed as a substantial challenge. However, the big data approach can answer this by storing records from the last time snow fell, against which the vehicle’s current environment can be compared (Churchill and Newman, 2012). ML approaches have also been 17

A fly-by-wire robot is a robot that is controllable by a remote computer.

20

developed to identify unprecedented changes to a particular piece of the road network, such as roadworks (Mathibela, et al., 2012). This emerging technology will affect a variety of logistics jobs. Agricultural vehicles, forklifts and cargo-handling vehicles are imminently automatable, and hospitals are already employing autonomous robots to transport food, prescriptions and samples (Bloss, 2011). The computerisation of mining vehicles is further being pursued by companies such as Rio Tinto, seeking to replace labour in Australian mine-sites.18 With improved sensors, robots are capable of producing goods with higher quality and reliability than human labour. For example, El Dulze, a Spanish food processor, now uses robotics to pick up heads of lettuce from a conveyor belt, rejecting heads that do not comply with company standards. This is achieved by measuring their density and replacing them on the belt (IFR, 2012a). Advanced sensors further allow robots to recognise patterns. Baxter, a 22,000 USD general-purpose robot, provides a well-known example. The robot features an LCD display screen displaying a pair of eyes that take on different expressions depending on the situation. When the robot is first installed or needs to learn a new pattern, no programming is required. A human worker simply guides the robot arms through the motions that will be needed for the task. Baxter then memorises these patterns and can communicate that it has understood its new instructions. While the physical flexibility of Baxter is limited to performing simple operations such as picking up objects and moving them, different standard attachments can be installed on its arms, allowing Baxter to perform a relatively broad scope of manual tasks at low cost (MGI, 2013). Technological advances are contributing to declining costs in robotics. Over the past decades, robot prices have fallen about 10 percent annually and are expected to decline at an even faster pace in the near future (MGI, 2013). Industrial robots, with features enabled by machine vision and high-precision dexterity, which typically cost 100,000 to 150,000 USD, will be available for 50,000 to 75,000 USD in the next decade, with higher levels of intelligence and additional capabilities (IFR, 2012b). Declining robot prices will inevitably place them within reach of more users. For example, in China, employers are increasingly incentivised to substitute robots for labour, as wages and living standards 18

Rio Tinto’s computerisation efforts are advertised at http://www.mineofthefuture.com.au.

21

are rising – Foxconn, a Chinese contract manufacturer that employs 1.2 million workers, is now investing in robots to assemble products such as the Apple iPhone (Markoff, 2012). According to the International Federation of Robotics, robot sales in China grew by more than 50 percent in 2011 and are expected to increase further. Globally, industrial robot sales reached a record 166,000 units in 2011, a 40 percent year-on-year increase (IFR, 2012b). Most likely, there will be even faster growth ahead as low-priced general-purpose models, such as Baxter, are adopted in simple manufacturing and service work. Expanding technological capabilities and declining costs will make entirely new uses for robots possible. Robots will likely continue to take on an increasing set of manual tasks in manufacturing, packing, construction, maintenance, and agriculture. In addition, robots are already performing many simple service tasks such as vacuuming, mopping, lawn mowing, and gutter cleaning – the market for personal and household service robots is growing by about 20 percent annually (MGI, 2013). Meanwhile, commercial service robots are now able to perform more complex tasks in food preparation, health care, commercial cleaning, and elderly care (Robotics-VO, 2013). As robot costs decline and technological capabilities expand, robots can thus be expected to gradually substitute for labour in a wide range of low-wage service occupations, where most US job growth has occurred over the past decades (Autor and Dorn, 2013). This means that many low-wage manual jobs that have been previously protected from computerisation could diminish over time. III.C.

The task model revisited

The task model of Autor, et al. (2003) has delivered intuitive and accurate predictions in that: (a) computers are more substitutable for human labour in routine relative to non-routine tasks; and (b) a greater intensity of routine inputs increases the marginal productivity of non-routine inputs. Accordingly, computers have served as a substitute for labour for many routine tasks, while exhibiting strong complementarities with labour performing cognitive non-routine tasks.19 Yet the premises about what computers do have recently expanded. Computer capital can now equally substitute for a wide range of tasks commonly defined as non-routine (Brynjolfsson and McAfee, 2011), meaning that 19

The model does not predict any substantial substitution or complementarity with nonroutine manual tasks.

22

the task model will not hold in predicting the impact of computerisation on the task content of employment in the twenty-first century. While focusing on the substitution effects of recent technological progress, we build on the task model by deriving several factors that we expect will determine the extent of computerisation in non-routine tasks. The task model assumes for tractability an aggregate, constant-returns-toscale Cobb-Douglas production function of the form,

(1)

Q = (LS + C)1−β LβNS ,

β ∈ [0, 1],

where LS and LNS are susceptible and non-susceptible labor inputs and C is computer capital. Computer capital is supplied perfectly elastically at market price per efficiency unit, where the market price is falling exogenously with time due to technological progress. It further assumes income-maximizing workers, with heterogeneous productivity endowments in both susceptible and non-susceptible tasks. Their task supply will respond elastically to relative wage levels, meaning that workers will reallocate their labour supply according to their comparative advantage as in Roy (1951). With expanding computational capabilities, resulting from technological advances, and a falling market price of computing, workers in susceptible tasks will thus reallocate to nonsusceptible tasks. The above described simple model differs from the task model of Autor, et al. (2003), in that LNS is not confined to routine labour inputs. This is because recent developments in ML and MR, building upon big data, allow for pattern recognition, and thus enable computer capital to rapidly substitute for labour across a wide range of non-routine tasks. Yet some inhibiting engineering bottlenecks to computerisation persist. Beyond these bottlenecks, however, we argue that it is largely already technologically possible to automate almost any task, provided that sufficient amounts of data are gathered for pattern recognition. Our model thus predicts that the pace at which these bottlenecks can be overcome will determine the extent of computerisation in the twenty-first century. Hence, in short, while the task model predicts that computers for labour substitution will be confined to routine tasks, our model predicts that comput23

erisation can be extended to any non-routine task that is not subject to any engineering bottlenecks to computerisation. These bottlenecks thus set the boundaries for the computerisation of non-routine tasks. Drawing upon the ML and MR literature, and a workshop held at the Oxford University Engineering Sciences Department, we identify several engineering bottlenecks, corresponding to three task categories. According to these findings, non-susceptible labor inputs can be described as,

(2)

LNS =

n X

LPM,i + LC,i + LSI,i

i=1

where LPM , LC and LSI are labour inputs into perception and manipulation tasks, creative intelligence tasks, and and social intelligence tasks. We note that some related engineering bottlenecks can be partially alleviated by the simplification of tasks. One generic way of achieving this is to reduce the variation between task iterations. As a prototypical example, consider the factory assembly line, turning the non-routine tasks of the artisan shop into repetitive routine tasks performed by unskilled factory workers. A more recent example is the computerisation of non-routine manual tasks in construction. On-site construction tasks typically demand a high degree of adaptability, so as to accommodate work environments that are typically irregularly laid out, and vary according to weather. Prefabrication, in which the construction object is partially assembled in a factory before being transported to the construction site, provides a way of largely removing the requirement for adaptability. It allows many construction tasks to be performed by robots under controlled conditions that eliminate task variability – a method that is becoming increasingly widespread, particularly in Japan (Barlow and Ozaki, 2005; Linner and Bock, 2012). The extent of computerisation in the twenty-first century will thus partly depend on innovative approaches to task restructuring. In the remainder of this section we examine the engineering bottlenecks related to the above mentioned task categories, each in turn. Perception and manipulation tasks. Robots are still unable to match the depth and breadth of human perception. While basic geometric identification is reasonably mature, enabled by the rapid development of sophisticated sensors 24

and lasers, significant challenges remain for more complex perception tasks, such as identifying objects and their properties in a cluttered field of view. As such, tasks that relate to an unstructured work environment can make jobs less susceptible to computerisation. For example, most homes are unstructured, requiring the identification of a plurality of irregular objects and containing many cluttered spaces which inhibit the mobility of wheeled objects. Conversely, supermarkets, factories, warehouses, airports and hospitals have been designed for large wheeled objects, making it easier for robots to navigate in performing non-routine manual tasks. Perception problems can, however, sometimes be sidestepped by clever task design. For example, Kiva Systems, acquired by Amazon.com in 2012, solved the problem of warehouse navigation by simply placing bar-code stickers on the floor, informing robots of their precise location (Guizzo, 2008). The difficulty of perception has ramifications for manipulation tasks, and, in particular, the handling of irregular objects, for which robots are yet to reach human levels of aptitude. This has been evidenced in the development of robots that interact with human objects and environments. While advances have been made, solutions tend to be unreliable over the myriad small variations on a single task, repeated thousands of times a day, that many applications require. A related challenge is failure recovery – i.e. identifying and rectifying the mistakes of the robot when it has, for example, dropped an object. Manipulation is also limited by the difficulties of planning out the sequence of actions required to move an object from one place to another. There are yet further problems in designing manipulators that, like human limbs, are soft, have compliant dynamics and provide useful tactile feedback. Most industrial manipulation makes uses of workarounds to these challenges (Brown, et al., 2010), but these approaches are nonetheless limited to a narrow range of tasks. The main challenges to robotic computerisation, perception and manipulation, thus largely remain and are unlikely to be fully resolved in the next decade or two (Robotics-VO, 2013). Creative intelligence tasks. The psychological processes underlying human creativity are difficult to specify. According to Boden (2003), creativity is the ability to come up with ideas or artifacts that are novel and valuable. Ideas, in a broader sense, include concepts, poems, musical compositions, scientific theo25

ries, cooking recipes and jokes, whereas artifacts are objects such as paintings, sculptures, machinery, and pottery. One process of creating ideas (and similarly for artifacts) involves making unfamiliar combinations of familiar ideas, requiring a rich store of knowledge. The challenge here is to find some reliable means of arriving at combinations that “make sense.” For a computer to make a subtle joke, for example, would require a database with a richness of knowledge comparable to that of humans, and methods of benchmarking the algorithm’s subtlety. In principle, such creativity is possible and some approaches to creativity already exist in the literature. Duvenaud, et al. (2013) provide an example of automating the core creative task required in order to perform statistics, that of designing models for data. As to artistic creativity, AARON, a drawingprogram, has generated thousands of stylistically-similar line-drawings, which have been exhibited in galleries worldwide. Furthermore, David Cope’s EMI software composes music in many different styles, reminiscent of specific human composers. In these and many other applications, generating novelty is not particularly difficult. Instead, the principal obstacle to computerising creativity is stating our creative values sufficiently clearly that they can be encoded in an program (Boden, 2003). Moreover, human values change over time and vary across cultures. Because creativity, by definition, involves not only novelty but value, and because values are highly variable, it follows that many arguments about creativity are rooted in disagreements about value. Thus, even if we could identify and encode our creative values, to enable the computer to inform and monitor its own activities accordingly, there would still be disagreement about whether the computer appeared to be creative. In the absence of engineering solutions to overcome this problem, it seems unlikely that occupations requiring a high degree of creative intelligence will be automated in the next decades. Social intelligence tasks. Human social intelligence is important in a wide range of work tasks, such as those involving negotiation, persuasion and care. To aid the computerisation of such tasks, active research is being undertaken within the fields of Affective Computing (Scherer, et al., 2010; Picard, 2010), and Social Robotics (Ge, 2007; Broekens, et al., 2009). While algorithms and robots can now reproduce some aspects of human social interaction, the real26

time recognition of natural human emotion remains a challenging problem, and the ability to respond intelligently to such inputs is even more difficult. Even simplified versions of typical social tasks prove difficult for computers, as is the case in which social interaction is reduced to pure text. The social intelligence of algorithms is partly captured by the Turing test, examining the ability of a machine to communicate indistinguishably from an actual human. Since 1990, the Loebner Prize, an annual Turing test competition, awards prizes to textual chat programmes that are considered to be the most human-like. In each competition, a human judge simultaneously holds computer-based textual interactions with both an algorithm and a human. Based on the responses, the judge is to distinguish between the two. Sophisticated algorithms have so far failed to convince judges about their human resemblance. This is largely because there is much ‘common sense’ information possessed by humans, which is difficult to articulate, that would need to be provided to algorithms if they are to function in human social settings. Whole brain emulation, the scanning, mapping and digitalising of a human brain, is one possible approach to achieving this, but is currently only a theoretical technology. For brain emulation to become operational, additional functional understanding is required to recognise what data is relevant, as well as a roadmap of technologies needed to implement it. While such roadmaps exist, present implementation estimates, under certain assumptions, suggest that whole brain emulation is unlikely to become operational within the next decade or two (Sandberg and Bostrom, 2008). When or if they do, however, the employment impact is likely to be vast (Hanson, 2001). Hence, in short, while sophisticated algorithms and developments in MR, building upon with big data, now allow many non-routine tasks to be automated, occupations that involve complex perception and manipulation tasks, creative intelligence tasks, and social intelligence tasks are unlikely to be substituted by computer capital over the next decade or two. The probability of an occupation being automated can thus be described as a function of these task characteristics. As suggested by Figure I, the low degree of social intelligence required by a dishwasher makes this occupation more susceptible to computerisation than a public relation specialist, for example. We proceed to examining the susceptibility of jobs to computerisation as a function of the above described non-susceptible task characteristics. 27

Public Event Relations Planner 0 0 100 Social Intelligence

1 Court Clerk

0 Biologist 0

1

Fashion Designer

Creativity

100

Probability of Computerisation

Dishwasher

Probability of Computerisation

Probability of Computerisation

1

Telemarketer Boilermaker

0 0

Surgeon 100

Perception and manipulation

F IGURE I. A sketch of how the probability of computerisation might vary as a function of bottleneck variables.

IV.

M EASURING THE EMPLOYMENT IMPACT OF COMPUTERISATION IV.A. Data sources and implementation strategy

To implement the above described methodology, we rely on O∗NET, an online service developed for the US Department of Labor. The 2010 version of O∗NET contains information on 903 detailed occupations, most of which correspond closely to the Labor Department’s Standard Occupational Classification (SOC). The O∗NET data was initially collected from labour market analysts, and has since been regularly updated by surveys of each occupation’s worker population and related experts, to provide up-to-date information on occupations as they evolve over time. For our purposes, an important feature of O∗NET is that it defines the key features of an occupation as a standardised and measurable set of variables, but also provides open-ended descriptions of specific tasks to each occupation. This allows us to: (a) objectively rank occupations according to the mix of knowledge, skills, and abilities they require; and (b) subjectively categorise them based on the variety of tasks they involve. The close SOC correspondence of O∗NET allows us to link occupational characteristics to 2010 Bureau of Labor Statistics (BLS) employment and wage data. While the O∗NET occupational classification is somewhat more detailed, distinguishing between Auditors and Accountants, for example, we aggregate these occupations to correspond to the six-digit 2010 SOC system, for which employment and wage figures are reported. To obtain unique O∗NET variables corresponding to the six-digit SOC classification, we used the mean of the O∗NET aggregate. In addition, we exclude any six-digit SOC occupations

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for which O∗NET data was missing.20 Doing so, we end up with a final dataset consisting of 702 occupations. To assess the employment impact of the described technological developments in ML, the ideal experiment would provide two identical autarkic economies, one facing the expanding technological capabilities we observe, and a secular decline in the price of computerisation, and the other not. By comparison, it would be straightforward to examine how computerisation reshapes the occupational composition of the labour market. In the absence of this experiment, the second preferred option would be to build on the implementation strategy of Autor, et al. (2003), and test a simple economic model to predict how demand for workplace tasks responds to developments in ML and MR technology. However, because our paper is forward-looking, in the sense that most of the described technological developments are yet to be implemented across industries on a broader scale, this option was not available for our purposes. Instead, our implementation strategy builds on the literature examining the offshoring of information-based tasks to foreign worksites, consisting of different methodologies to rank and categorise occupations according to their susceptibility to offshoring (Blinder, 2009; Jensen and Kletzer, 2005, 2010). The common denominator for these studies is that they rely on O∗NET data in different ways. While Blinder (2009) eyeballed the O∗NET data on each occupation, paying particular attention to the job description, tasks, and work activities, to assign an admittedly subjective two-digit index number of offshorability to each occupation, Jensen and Kletzer (2005) created a purely objective ranking based on standardised and measurable O∗NET variables. Both approaches have obvious drawbacks. Subjective judgments are often not replicable and may result in the researcher subconsciously rigging the data to conform to a certain set of beliefs. Objective rankings, on the other hand, are not subject to such drawbacks, but are constrained by the reliability of the variables that are being used. At this stage, it shall be noted that O∗NET data was not gathered to specifically measure the offshorability or automatability of jobs. Accordingly, Blinder (2009) 20

The missing occupations consist of “All Other” titles, representing occupations with a wide range of characteristics which do not fit into one of the detailed O∗NET-SOC occupations. O ∗ NET data is not available for this type of title. We note that US employment for the 702 occupations we considered is 138.44 million. Hence our analysis excluded 4.628 million jobs, equivalent to 3 percent of total employment.

29

finds that past attempts to create objective offshorability rankings using O∗NET data have yielded some questionable results, ranking lawyers and judges among the most tradable occupations, while classifying occupations such as data entry keyers, telephone operators, and billing clerks as virtually impossible to move offshore. To work around some of these drawbacks, we combine and build upon the two described approaches. First, together with a group of ML researchers, we subjectively hand-labelled 70 occupations, assigning 1 if automatable, and 0 if not. For our subjective assessments, we draw upon a workshop held at the Oxford University Engineering Sciences Department, examining the automatability of a wide range of tasks. Our label assignments were based on eyeballing the O∗NET tasks and job description of each occupation. This information is particular to each occupation, as opposed to standardised across different jobs. The hand-labelling of the occupations was made by answering the question “Can the tasks of this job be sufficiently specified, conditional on the availability of big data, to be performed by state of the art computer-controlled equipment”. Thus, we only assigned a 1 to fully automatable occupations, where we considered all tasks to be automatable. To the best of our knowledge, we considered the possibility of task simplification, possibly allowing some currently non-automatable tasks to be automated. Labels were assigned only to the occupations about which we were most confident. Second, we use objective O∗NET variables corresponding to the defined bottlenecks to computerisation. More specifically, we are interested in variables describing the level of perception and manipulation, creativity, and social intelligence required to perform it. As reported in Table I, we identified nine variables that describe these attributes. These variables were derived from the O ∗ NET survey, where the respondents are given multiple scales, with “importance” and “level” as the predominant pair. We rely on the “level” rating which corresponds to specific examples about the capabilities required of computercontrolled equipment to perform the tasks of an occupation. For instance, in relation to the attribute “Manual Dexterity”, low (level) corresponds to “Screw a light bulb into a light socket”; medium (level) is exemplified by “Pack oranges in crates as quickly as possible”; high (level) is described as “Perform open-heart surgery with surgical instruments”. This gives us an indication of the level of “Manual Dexterity” computer-controlled equipment would require 30

TABLE I. O∗NET variables that serve as indicators of bottlenecks to computerisation. Computerisation bottleneck

O ∗ NET

Perception and Manipulation

Finger Dexterity

The ability to make precisely coordinated movements of the fingers of one or both hands to grasp, manipulate, or assemble very small objects.

Manual Dexterity

The ability to quickly move your hand, your hand together with your arm, or your two hands to grasp, manipulate, or assemble objects.

Cramped Work Space, Awkward Positions

How often does this job require working in cramped work spaces that requires getting into awkward positions?

Originality

The ability to come up with unusual or clever ideas about a given topic or situation, or to develop creative ways to solve a problem.

Fine Arts

Knowledge of theory and techniques required to compose, produce, and perform works of music, dance, visual arts, drama, and sculpture.

Social Perceptiveness

Being aware of others’ reactions and understanding why they react as they do.

Negotiation

Bringing others together and trying to reconcile differences.

Persuasion

Persuading others to change their minds or behavior.

Assisting and Caring for Others

Providing personal assistance, medical attention, emotional support, or other personal care to others such as coworkers, customers, or patients.

Creative Intelligence

Social Intelligence

Variable

O ∗ NET

Description

to perform a specific occupation. An exception is the “Cramped work space” variable, which measures the frequency of unstructured work. Hence, in short, by hand-labelling occupations, we work around the issue that O∗NET data was not gathered to specifically measure the automatability of jobs in a similar manner to Blinder (2009). In addition, we mitigate some of the subjective biases held by the researchers by using objective O∗NET variables to correct potential hand-labelling errors. The fact that we label only 70 of the full 702 occupations, selecting those occupations whose computerisation label we are highly confident about, further reduces the risk of subjective bias affecting our analysis. To develop an algorithm appropriate for this task, we turn to probabilistic classification.

31

IV.B. Classification method We begin by examining the accuracy of our subjective assessments of the automatability of 702 occupations. For classification, we develop an algorithm to provide the label probability given a previously unseen vector of variables. In the terminology of classification, the O∗NET variables form a feature vector, denoted x ∈ R9 . O∗NET hence supplies a complete dataset of 702 such feature vectors. A computerisable label is termed a class, denoted y ∈ {0, 1}. For our problem, y = 1 (true) implies that we hand-labelled as computerisable the occupation described by the associated nine O∗NET variables contained in x ∈ R9 . Our training data is D = (X, y), where X ∈ R70×9 is a matrix of variables and y ∈ {0, 1}70 gives the associated labels. This dataset contains information about how y varies as a function of x: as a hypothetical example, it may be the case that, for all occupations for which x1 > 50, y = 1. A probabilistic classification algorithm exploits patterns existent in training data to return the probability P (y∗ = 1 | x∗ , X, y) of a new, unlabelled, test datum with features x∗ having class label y∗ = 1. We achieve probabilistic classification by introducing a latent function f : x 7→ R, known as a discriminant function. Given the value of the discriminant f∗ at a test point x∗ , we assume that the probability for the class label is given by the logistic (3)

P (y∗ = 1 | f∗ ) =

1 , 1 + exp(−f∗ )

and P (y∗ = 0 | f∗ ) = 1 − P (y∗ = 1 | f∗ ). For f∗ > 0, y∗ = 1 is more probable than y∗ = 0. For our application, f can be thought of as a continuousvalued ‘automatability’ variable: the higher its value, the higher the probability of computerisation. We test three different models for the discriminant function, f , using the best performing for our further analysis. Firstly, logistic (or logit) regression, which adopts a linear model for f , f (x) = w⊺ x, where the un-known weights w are often inferred by maximising their probability in light of the training data. This simple model necessarily implies a simple monotonic relationship between features and the probability of the class taking a particular value. Richer models are provided by Gaussian process classifiers (Rasmussen and

32

Williams, 2006). Such classifiers model the latent function f with a Gaussian process (GP): a non-parametric probability distribution over functions. A GP is defined as a distribution over the functions f : X → R such that the distribution over the possible function values on any finite subset of X (such as X) is multivariate Gaussian. For a function f (x), the prior distribution over its values f on a subset x ⊂ X are completely specified by a covariance matrix K (4)

p(f | K) = N (f ; 0, K) = √

1 1 exp − f ⊺ K −1 f . 2 det 2πK

The covariance matrix is generated by a covariance function κ : X × X 7→ R; that is, K = κ(X, X). The GP model is expressed by the choice of κ; we consider the exponentiated quadratic (squared exponential) and rational quadratic. Note that we have chosen a zero mean function, encoding the assumption that P (y∗ = 1) = 12 sufficiently far from training data. Given training data D, we use the GP to make predictions about the function values f∗ at input x∗ . With this information, we have the predictive equations (5)

p(f∗ | x∗ , D) = N f∗ ; m(f∗ | x∗ , D), V (f∗ | x∗ , D) ,

where (6)

m(f∗ | x∗ , D) = K(x∗ , X)K(X, X)−1 y

(7)

V (f∗ | x∗ , D) = K(x∗ , x∗ ) − K(x∗ , X)K(X, X)−1 K(X, x∗ ) .

Inferring the label posterior p(y∗ | x∗ , D) is complicated by the non-Gaussian form of the logistic (3). In order to effect inference, we use the approximate Expectation Propagation algorithm (Minka, 2001). We tested three Gaussian process classifiers using the GPML toolbox (Rasmussen and Nickisch, 2010) on our data, built around exponentiated quadratic, rational quadratic and linear covariances. Note that the latter is equivalent to logistic regression with a Gaussian prior taken on the weights w. To validate these classifiers, we randomly selected a reduced training set of half the available data D; the remaining data formed a test set. On this test set, we evaluated how closely the algorithm’s classifications matched the hand labels according to two metrics (see e.g. Murphy (2012)): the area under the receiver operat-

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TABLE II. Performance of various classifiers; best performances in bold.

classifier model exponentiated quadratic rational quadratic linear (logit regression)

AUC

log-likelihood

0.894 0.893 0.827

−163.3 −163.7 −205.0

ing characteristic curve (AUC), which is equal to one for a perfect classifier, and one half for a completely random classifier, and the log-likelihood, which should ideally be high. This experiment was repeated for one hundred random selections of training set, and the average results tabulated in Table II. The exponentiated quadratic model returns (narrowly) the best performance of the three (clearly outperforming the linear model corresponding to logistic regression), and was hence selected for the remainder of our testing. Note that its AUC score of nearly 0.9 represents accurate classification: our algorithm successfully managed to reproduce our hand-labels specifying whether an occupation was computerisable. This means that our algorithm verified that our subjective judgements were systematically and consistently related to the O∗NET variables. Having validated our approach, we proceed to use classification to predict the probability of computerisation for all 702 occupations. For this purpose, we introduce a new label variable, z, denoting whether an occupation is truly computerisable or not: note that this can be judged only once an occupation is computerised, at some indeterminate point in the future. We take, again, a logistic likelihood, (8)

P (z∗ = 1 | f∗ ) =

1 . 1 + exp(−f∗ )

We implicitly assumed that our hand label, y, is a noise-corrupted version of the unknown true label, z. Our motivation is that our hand-labels of computerisability must necessarily be treated as such noisy measurements. We thus acknowledge that it is by no means certain that a job is computerisable given our labelling. We define X∗ ∈ R702×9 as the matrix of O∗NET variables for all 702 occupations; this matrix represents our test features. We perform a final experiment in which, given training data D, consisting 34

50

60

60

40 20

0.5 1 Probability of Computerisation 100

50

50

0.5 1 Probability of Computerisation

20 0

Cramped work space

Finger dexterity

40

60 40 20 0

1 0.5 Probability of Computerisation

0.5 1 Probability of Computerisation

0.5 1 Probability of Computerisation

60 40 20

0.5 1 Probability of Computerisation

80

60

0.5 1 Probability of Computerisation

0 0

80

80

0 0

20

0.5 1 Probability of Computerisation

Originality

100

40

0 0

Fine arts

Social perceptiveness

80

0 0

Manual dexterity

80 Negotiation

Persuasion

Assisting and caring for others

100

0.5 1 Probability of Computerisation

100

50

F IGURE II. The distribution of occupational variables as a function of probability of computerisation; each occupation is a unique point.

35

of our 70 hand-labelled occupations, we aim to predict z ∗ for our test features X∗ . This approach firstly allows us to use the features of the 70 occupations about which we are most certain to predict for the remaining 632. Further, our algorithm uses the trends and patterns it has learned from bulk data to correct for what are likely to be mistaken labels. More precisely, the algorithm provides a smoothly varying probabilistic assessment of automatability as a function of the variables. For our Gaussian process classifier, this function is non-linear, meaning that it flexibly adapts to the patterns inherent in the training data. Our approach thus allows for more complex, non-linear, interactions between variables: for example, perhaps one variable is not of importance unless the value of another variable is sufficiently large. We report P (z ∗ | X∗ , D) as the probability of computerisation henceforth (for a detailed probability ranking, see Appendix). Figure II illustrates that this probability is non-linearly related to the nine O∗NET variables selected. V.

E MPLOYMENT IN THE TWENTY- FIRST CENTURY

In this section, we examine the possible future extent of at-risk job computerisation, and related labour market outcomes. The task model predicts that recent developments in ML will reduce aggregate demand for labour input in tasks that can be routinised by means of pattern recognition, while increasing the demand for labour performing tasks that are not susceptible to computerisation. However, we make no attempt to forecast future changes in the occupational composition of the labour market. While the 2010-2020 BLS occupational employment projections predict US net employment growth across major occupations, based on historical staffing patterns, we speculate about technology that is in only the early stages of development. This means that historical data on the impact of the technological developments we observe is unavailable.21 We therefore focus on the impact of computerisation on the mix of jobs that existed in 2010. Our analysis is thus limited to the substitution effect of future computerisation. Turning first to the expected employment impact, reported in Figure III, we distinguish between high, medium and low risk occupations, depending on their 21

It shall be noted that the BLS projections are based on what can be referred to as changes in normal technological progress, and not on any breakthrough technologies that may be seen as conjectural.

36

Management, Business, and Financial Computer, Engineering, and Science Education, Legal, Community Service, Arts, and Media Healthcare Practitioners and Technical Service Sales and Related Office and Administrative Support Farming, Fishing, and Forestry Construction and Extraction Installation, Maintenance, and Repair Production Transportation and Material Moving 400M ←−−− Low −−−→ 33% Employment

←−−− Medium −−−→ 19% Employment

←−−− High −−−→ 47% Employment

Employment

300M

200M

100M

0M 0

0.2

0.4 0.6 Probability of Computerisation

0.8

1

F IGURE III. The distribution of BLS 2010 occupational employment over the probability of computerisation, along with the share in low, medium and high probability categories. Note that the total area under all curves is equal to total US employment.

37

probability of computerisation (thresholding at probabilities of 0.7 and 0.3). According to our estimate, 47 percent of total US employment is in the high risk category, meaning that associated occupations are potentially automatable over some unspecified number of years, perhaps a decade or two. It shall be noted that the probability axis can be seen as a rough timeline, where high probability occupations are likely to be substituted by computer capital relatively soon. Over the next decades, the extent of computerisation will be determined by the pace at which the above described engineering bottlenecks to automation can be overcome. Seen from this perspective, our findings could be interpreted as two waves of computerisation, separated by a “technological plateau”. In the first wave, we find that most workers in transportation and logistics occupations, together with the bulk of office and administrative support workers, and labour in production occupations, are likely to be substituted by computer capital. As computerised cars are already being developed and the declining cost of sensors makes augmenting vehicles with advanced sensors increasingly cost-effective, the automation of transportation and logistics occupations is in line with the technological developments documented in the literature. Furthermore, algorithms for big data are already rapidly entering domains reliant upon storing or accessing information, making it equally intuitive that office and administrative support occupations will be subject to computerisation. The computerisation of production occupations simply suggests a continuation of a trend that has been observed over the past decades, with industrial robots taking on the routine tasks of most operatives in manufacturing. As industrial robots are becoming more advanced, with enhanced senses and dexterity, they will be able to perform a wider scope of non-routine manual tasks. From a technological capabilities point of view, the vast remainder of employment in production occupations is thus likely to diminish over the next decades. More surprising, at first sight, is that a substantial share of employment in services, sales and construction occupations exhibit high probabilities of computerisation. Yet these findings are largely in line with recent documented technological developments. First, the market for personal and household service robots is already growing by about 20 percent annually (MGI, 2013). As the comparative advantage of human labour in tasks involving mobility and dexterity will diminish over time, the pace of labour substitution in service occupations is likely to increase even further. Second, while it seems counterintuitive 38

that sales occupations, which are likely to require a high degree of social intelligence, will be subject to a wave of computerisation in the near future, high risk sales occupations include, for example, cashiers, counter and rental clerks, and telemarketers. Although these occupations involve interactive tasks, they do not necessarily require a high degree of social intelligence. Our model thus seems to do well in distinguishing between individual occupations within occupational categories. Third, prefabrication will allow a growing share of construction work to be performed under controlled conditions in factories, which partly eliminates task variability. This trend is likely to drive the computerisation of construction work. In short, our findings suggest that recent developments in ML will put a substantial share of employment, across a wide range of occupations, at risk in the near future. According to our estimates, however, this wave of automation will be followed by a subsequent slowdown in computers for labour substitution, due to persisting inhibiting engineering bottlenecks to computerisation. The relatively slow pace of computerisation across the medium risk category of employment can thus partly be interpreted as a technological plateau, with incremental technological improvements successively enabling further labour substitution. More specifically, the computerisation of occupations in the medium risk category will mainly depend on perception and manipulation challenges. This is evident from Table III, showing that the “manual dexterity”, “finger dexterity” and “cramped work space” variables exhibit relatively high values in the medium risk category. Indeed, even with recent technological developments, allowing for more sophisticated pattern recognition, human labour will still have a comparative advantage in tasks requiring more complex perception and manipulation. Yet with incremental technological improvements, the comparative advantage of human labour in perception and manipulation tasks could eventually diminish. This will require innovative task restructuring, improvements in ML approaches to perception challenges, and progress in robotic dexterity to overcome manipulation problems related to variation between task iterations and the handling of irregular objects. The gradual computerisation of installation, maintenance, and repair occupations, which are largely confined to the medium risk category, and require a high degree of perception and manipulation capabilities, is a manifestation of this observation. Our model predicts that the second wave of computerisation will mainly 39

TABLE III. Distribution (mean and standard deviation) of values for each variable.

Variable

Assisting and caring for others Persuasion Negotiation Social perceptiveness Fine arts Originality Manual dexterity Finger dexterity Cramped work space

Probability of Computerisation Low

Medium

High

48±20 48±7.1 44±7.6 51±7.9 12±20 51±6.5 22±18 36±10 19±15

41±17 35±9.8 33±9.3 41±7.4 3.5±12 35±12 34±15 39±10 37±26

34±10 32±7.8 30±8.9 37±5.5 1.3±5.5 32±5.6 36±14 40±10 31±20

depend on overcoming the engineering bottlenecks related to creative and social intelligence. As reported in Table III, the “fine arts”, “originality”, “negotiation”, “persuasion”, “social perceptiveness”, and “assisting and caring for others”, variables, all exhibit relatively high values in the low risk category. By contrast, we note that the “manual dexterity”, “finger dexterity” and “cramped work space” variables take relatively low values. Hence, in short, generalist occupations requiring knowledge of human heuristics, and specialist occupations involving the development of novel ideas and artifacts, are the least susceptible to computerisation. As a prototypical example of generalist work requiring a high degree of social intelligence, consider the O∗NET tasks reported for chief executives, involving “conferring with board members, organization officials, or staff members to discuss issues, coordinate activities, or resolve problems”, and “negotiating or approving contracts or agreements.” Our predictions are thus intuitive in that most management, business, and finance occupations, which are intensive in generalist tasks requiring social intelligence, are largely confined to the low risk category. The same is true of most occupations in education, healthcare, as well as arts and media jobs. The O∗NET tasks of actors, for example, involve “performing humorous and serious interpretations of emotions, actions, and situations, using body movements, facial expressions, and gestures”, and “learning about characters in scripts and their relationships to each other in order to develop role interpretations.” While these tasks are 40

Bachelor’s degree or better

Average median wage (USD)

80k 60k 40k 20k 0

0.5

1

60%

average weighted by employment

40%

unweighted

20% 0% 0

Probability of Computerisation

0.5

1

Probability of Computerisation

F IGURE IV. Wage and education level as a function of the probability of computerisation; note that both plots share a legend.

very different from those of a chief executive, they equally require profound knowledge of human heuristics, implying that a wide range of tasks, involving social intelligence, are unlikely to become subject to computerisation in the near future. The low susceptibility of engineering and science occupations to computerisation, on the other hand, is largely due to the high degree of creative intelligence they require. The O∗NET tasks of mathematicians, for example, involve “developing new principles and new relationships between existing mathematical principles to advance mathematical science” and “conducting research to extend mathematical knowledge in traditional areas, such as algebra, geometry, probability, and logic.” Hence, while it is evident that computers are entering the domains of science and engineering, our predictions implicitly suggest strong complementarities between computers and labour in creative science and engineering occupations; although it is possible that computers will fully substitute for workers in these occupations over the long-run. We note that the predictions of our model are strikingly in line with the technological trends we observe in the automation of knowledge work, even within occupational categories. For example, we find that paralegals and legal assistants – for which computers already substitute – in the high risk category. At the same time, lawyers, which rely on labour input from legal assistants, are in the low risk category. Thus, for the work of lawyers to be fully automated, engineering bottlenecks to creative and social intelligence will need to be overcome, implying that the computerisation of legal research will complement the work of lawyers in the medium term. 41

To complete the picture of what recent technological progress is likely to mean for the future of employment, we plot the average median wage of occupations by their probability of computerisation. We do the same for skill level, measured by the fraction of workers having obtained a bachelor’s degree, or higher educational attainment, within each occupation. Figure IV reveals that both wages and educational attainment exhibit a strong negative relationship with the probability of computerisation. We note that this prediction implies a truncation in the current trend towards labour market polarization, with growing employment in high and low-wage occupations, accompanied by a hollowing-out of middle-income jobs. Rather than reducing the demand for middle-income occupations, which has been the pattern over the past decades, our model predicts that computerisation will mainly substitute for low-skill and low-wage jobs in the near future. By contrast, high-skill and high-wage occupations are the least susceptible to computer capital. Our findings were robust to the choice of the 70 occupations that formed our training data. This was confirmed by the experimental results tabulated in Table II: a GP classifier trained on half of the training data was demonstrably able to accurately predict the labels of the other half, over one hundred different partitions. That these predictions are accurate for many possible partitions of the training set suggests that slight modifications to this set are unlikely to lead to substantially different results on the entire dataset. V.A. Limitations It shall be noted that our predictions are based on expanding the premises about the tasks that computer-controlled equipment can be expected to perform. Hence, we focus on estimating the share of employment that can potentially be substituted by computer capital, from a technological capabilities point of view, over some unspecified number of years. We make no attempt to estimate how many jobs will actually be automated. The actual extent and pace of computerisation will depend on several additional factors which were left unaccounted for. First, labour saving inventions may only be adopted if the access to cheap labour is scarce or prices of capital are relatively high (Habakkuk, 1962).22 We 22

For example, case study evidence suggests that mechanisation in eighteenth century cotton production initially only occurred in Britain because wage levels were much higher relative to

42

do not account for future wage levels, capital prices or labour shortages. While these factors will impact on the timeline of our predictions, labour is the scarce factor, implying that in the long-run wage levels will increase relative to capital prices, making computerisation increasingly profitable (see, for example, Acemoglu, 2003). Second, regulatory concerns and political activism may slow down the process of computerisation. The states of California and Nevada are, for example, currently in the process of making legislatory changes to allow for driverless cars. Similar steps will be needed in other states, and in relation to various technologies. The extent and pace of legislatory implementation can furthermore be related to the public acceptance of technological progress.23 Although resistance to technological progress has become seemingly less common since the Industrial Revolution, there are recent examples of resistance to technological change.24 We avoid making predictions about the legislatory process and the public acceptance of technological progress, and thus the pace of computerisation. Third, making predictions about technological progress is notoriously difficult (Armstrong and Sotala, 2012).25 For this reason, we focus on near-term technological breakthroughs in ML and MR, and avoid making any predictions about the number of years it may take to overcome various engineering bottlenecks to computerisation. Finally, we emphasise that since our probability estimates describe the likelihood of an occupation being fully automated, we do not capture any within-occupation variation resulting from the computerisaprices of capital than in other countries (Allen, 2009b). In addition, recent empirical research reveals a causal relationship between the access to cheap labour and mechanisation in agricultural production, in terms of sustained economic transition towards increased mechanisation in areas characterised by low-wage worker out-migration (Hornbeck and Naidu, 2013). 23 For instance, William Huskisson, former cabinet minister and Member of Parliament for Liverpool, was killed by a steam locomotive during the opening of the Liverpool and Manchester Railway. Nonetheless, this well-publicised incident did anything but dissuade the public from railway transportation technology. By contrast, airship technology is widely recognised as having been popularly abandoned as a consequence of the reporting of the Hindenburg disaster. 24 Uber, a start-up company connecting passengers with drivers of luxury vehicles, has recently faced pressure from from local regulators, arising from tensions with taxicab services. Furthermore, in 2011 the UK Government scrapped a 12.7 billion GBP project to introduce electronic patient records after resistance from doctors. 25 Marvin Minsky famously claimed in 1970 that “in from three to eight years we will have a machine with the general intelligence of an average human being”. This prediction is yet to materialise.

43

tion of tasks that simply free-up time for human labour to perform other tasks. Although it is clear that the impact of productivity gains on employment will vary across occupations and industries, we make no attempt to examine such effects. VI.

C ONCLUSIONS

While computerisation has been historically confined to routine tasks involving explicit rule-based activities (Autor, et al., 2003; Goos, et al., 2009; Autor and Dorn, 2013), algorithms for big data are now rapidly entering domains reliant upon pattern recognition and can readily substitute for labour in a wide range of non-routine cognitive tasks (Brynjolfsson and McAfee, 2011; MGI, 2013). In addition, advanced robots are gaining enhanced senses and dexterity, allowing them to perform a broader scope of manual tasks (IFR, 2012b; Robotics-VO, 2013; MGI, 2013). This is likely to change the nature of work across industries and occupations. In this paper, we ask the question: how susceptible are current jobs to these technological developments? To assess this, we implement a novel methodology to estimate the probability of computerisation for 702 detailed occupations. Based on these estimates, we examine expected impacts of future computerisation on labour market outcomes, with the primary objective of analysing the number of jobs at risk and the relationship between an occupation’s probability of computerisation, wages and educational attainment. We distinguish between high, medium and low risk occupations, depending on their probability of computerisation. We make no attempt to estimate the number of jobs that will actually be automated, and focus on potential job automatability over some unspecified number of years. According to our estimates around 47 percent of total US employment is in the high risk category. We refer to these as jobs at risk – i.e. jobs we expect could be automated relatively soon, perhaps over the next decade or two. Our model predicts that most workers in transportation and logistics occupations, together with the bulk of office and administrative support workers, and labour in production occupations, are at risk. These findings are consistent with recent technological developments documented in the literature. More surprisingly, we find that a substantial share of employment in service occupations,

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where most US job growth has occurred over the past decades (Autor and Dorn, 2013), are highly susceptible to computerisation. Additional support for this finding is provided by the recent growth in the market for service robots (MGI, 2013) and the gradually diminishment of the comparative advantage of human labour in tasks involving mobility and dexterity (Robotics-VO, 2013). Finally, we provide evidence that wages and educational attainment exhibit a strong negative relationship with the probability of computerisation. We note that this finding implies a discontinuity between the nineteenth, twentieth and the twenty-first century, in the impact of capital deepening on the relative demand for skilled labour. While nineteenth century manufacturing technologies largely substituted for skilled labour through the simplification of tasks (Braverman, 1974; Hounshell, 1985; James and Skinner, 1985; Goldin and Katz, 1998), the Computer Revolution of the twentieth century caused a hollowing-out of middle-income jobs (Goos, et al., 2009; Autor and Dorn, 2013). Our model predicts a truncation in the current trend towards labour market polarisation, with computerisation being principally confined to low-skill and low-wage occupations. Our findings thus imply that as technology races ahead, low-skill workers will reallocate to tasks that are non-susceptible to computerisation – i.e., tasks requiring creative and social intelligence. For workers to win the race, however, they will have to acquire creative and social skills. R EFERENCES Acemoglu, D. (2002). Technical change, inequality, and the labor market. Journal of Economic Literature, vol. 40, no. 1, pp. 7–72. Acemoglu, D. (2003). Labor- and capital-augmenting technical change. Journal of the European Economic Association, vol. 1, no. 1, pp. 1–37. Acemoglu, D. and Autor, D. (2011). Skills, tasks and technologies: Implications for employment and earnings. Handbook of labor economics, vol. 4, pp. 1043–1171. Acemoglu, D. and Robinson, J. (2012). Why nations fail: the origins of power, prosperity, and poverty. Random House Digital, Inc.

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A PPENDIX The table below ranks occupations according to their probability of computerisation (from least- to most-computerisable). Those occupations used as training data are labelled as either ‘0’ (not computerisable) or ‘1’ (computerisable), respectively. There are 70 such occupations, 10 percent of the total number of occupations. Computerisable Rank

Probability

1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39.

0.0028 0.003 0.003 0.0031 0.0033 0.0035 0.0035 0.0035 0.0036 0.0036 0.0039 0.0039 0.004 0.0041 0.0042 0.0042 0.0043 0.0044 0.0044 0.0044 0.0045 0.0046 0.0046 0.0047 0.0048 0.0049 0.0055 0.0055 0.0061 0.0063 0.0064 0.0065 0.0067 0.0068 0.0071 0.0073 0.0074 0.0075 0.0077

Label

SOC

code

29-1125 49-1011 11-9161 21-1023 29-1181 29-1122 29-2091 21-1022 29-1022 33-1021 29-1031 11-9081 27-2032 41-9031 29-1060 25-9031 19-3039 33-1012 29-1021 25-2021 19-1042 11-9032 29-1081 19-3031 21-1014 51-6092 27-1027 11-3121 39-9032 11-3131 29-1127 15-1121 11-9151 25-4012 29-9091 11-9111 25-2011 25-9021 19-3091

Occupation Recreational Therapists First-Line Supervisors of Mechanics, Installers, and Repairers Emergency Management Directors Mental Health and Substance Abuse Social Workers Audiologists Occupational Therapists Orthotists and Prosthetists Healthcare Social Workers Oral and Maxillofacial Surgeons First-Line Supervisors of Fire Fighting and Prevention Workers Dietitians and Nutritionists Lodging Managers Choreographers Sales Engineers Physicians and Surgeons Instructional Coordinators Psychologists, All Other First-Line Supervisors of Police and Detectives Dentists, General Elementary School Teachers, Except Special Education Medical Scientists, Except Epidemiologists Education Administrators, Elementary and Secondary School Podiatrists Clinical, Counseling, and School Psychologists Mental Health Counselors Fabric and Apparel Patternmakers Set and Exhibit Designers Human Resources Managers Recreation Workers Training and Development Managers Speech-Language Pathologists Computer Systems Analysts Social and Community Service Managers Curators Athletic Trainers Medical and Health Services Managers Preschool Teachers, Except Special Education Farm and Home Management Advisors Anthropologists and Archeologists

57

Computerisable Rank

Probability

40. 41.

0.0077 0.0078

42. 43. 44. 45. 46. 47. 48. 49. 50. 51. 52. 53. 54. 55. 56. 57. 58. 59. 60. 61. 62. 63. 64. 65. 66. 67. 68. 69. 70. 71. 72. 73. 74. 75. 76. 77. 78. 79. 80. 81. 82. 83. 84. 85. 86. 87.

0.0081 0.0081 0.0085 0.0088 0.009 0.0094 0.0095 0.0095 0.01 0.01 0.01 0.011 0.012 0.012 0.012 0.012 0.013 0.013 0.014 0.014 0.014 0.014 0.014 0.014 0.015 0.015 0.015 0.015 0.015 0.015 0.015 0.016 0.016 0.016 0.016 0.017 0.017 0.017 0.018 0.018 0.018 0.018 0.019 0.02 0.021 0.021

Label

SOC

code

25-2054 25-2031 0

0 0

21-2011 19-1032 21-1012 25-2032 29-1111 21-1015 25-3999 19-4092 39-5091 17-2121 11-9033 17-2141 29-1051 13-1081 19-1022 19-3032 27-2022 11-2022 19-2043 11-2021 21-1013 17-2199 13-1151 43-1011 19-1029 11-2031 27-1014 15-1111 11-1011 11-9031 27-2041 51-1011 41-3031 19-1031 25-2053 17-2041 11-9041 17-2011 11-9121 17-2081 17-1011 31-2021 17-2051 29-1199 19-1013 19-2032

Occupation Special Education Teachers, Secondary School Secondary School Teachers, Except Special and Career/Technical Education Clergy Foresters Educational, Guidance, School, and Vocational Counselors Career/Technical Education Teachers, Secondary School Registered Nurses Rehabilitation Counselors Teachers and Instructors, All Other Forensic Science Technicians Makeup Artists, Theatrical and Performance Marine Engineers and Naval Architects Education Administrators, Postsecondary Mechanical Engineers Pharmacists Logisticians Microbiologists Industrial-Organizational Psychologists Coaches and Scouts Sales Managers Hydrologists Marketing Managers Marriage and Family Therapists Engineers, All Other Training and Development Specialists First-Line Supervisors of Office and Administrative Support Workers Biological Scientists, All Other Public Relations and Fundraising Managers Multimedia Artists and Animators Computer and Information Research Scientists Chief Executives Education Administrators, Preschool and Childcare Center/Program Music Directors and Composers First-Line Supervisors of Production and Operating Workers Securities, Commodities, and Financial Services Sales Agents Conservation Scientists Special Education Teachers, Middle School Chemical Engineers Architectural and Engineering Managers Aerospace Engineers Natural Sciences Managers Environmental Engineers Architects, Except Landscape and Naval Physical Therapist Assistants Civil Engineers Health Diagnosing and Treating Practitioners, All Other Soil and Plant Scientists Materials Scientists

58

Computerisable Rank

Probability

Label

88. 89. 90. 91. 92. 93. 94. 95. 96. 97. 98. 99. 100. 101. 102. 103.

0.021 0.021 0.021 0.021 0.022 0.022 0.023 0.023 0.025 0.025 0.025 0.027 0.027 0.028 0.028 0.028

104. 105.

0.029 0.029

17-2112 53-1031

106. 107. 108. 109. 110. 111. 112. 113. 114. 115. 116. 117. 118. 119. 120. 121. 122. 123. 124. 125. 126. 127. 128. 129. 130. 131. 132. 133. 134.

0.029 0.03 0.03 0.03 0.03 0.03 0.032 0.033 0.033 0.035 0.035 0.035 0.035 0.037 0.037 0.037 0.038 0.038 0.039 0.039 0.04 0.04 0.041 0.041 0.042 0.042 0.043 0.045 0.045

29-2056 11-3051 17-3026 15-1142 15-1141 11-3061 25-1000 19-2041 21-1011 23-1011 27-1012 15-2031 11-3021 27-1021 17-2031 13-1121 29-1131 27-3043 11-2011 19-3094 13-2071 19-3099 19-2011 53-5031 15-1132 27-1013 29-2053 17-1012 21-1091

0 0

SOC

code

17-2131 27-1022 29-1123 27-4021 27-2012 27-1025 29-1023 27-1011 33-1011 21-2021 17-2072 19-1021 29-1011 31-2011 21-1021 17-2111

Occupation Materials Engineers Fashion Designers Physical Therapists Photographers Producers and Directors Interior Designers Orthodontists Art Directors First-Line Supervisors of Correctional Officers Directors, Religious Activities and Education Electronics Engineers, Except Computer Biochemists and Biophysicists Chiropractors Occupational Therapy Assistants Child, Family, and School Social Workers Health and Safety Engineers, Except Mining Safety Engineers and Inspectors Industrial Engineers First-Line Supervisors of Transportation and Material-Moving Machine and Vehicle Operators Veterinary Technologists and Technicians Industrial Production Managers Industrial Engineering Technicians Network and Computer Systems Administrators Database Administrators Purchasing Managers Postsecondary Teachers Environmental Scientists and Specialists, Including Health Substance Abuse and Behavioral Disorder Counselors Lawyers Craft Artists Operations Research Analysts Computer and Information Systems Managers Commercial and Industrial Designers Biomedical Engineers Meeting, Convention, and Event Planners Veterinarians Writers and Authors Advertising and Promotions Managers Political Scientists Credit Counselors Social Scientists and Related Workers, All Other Astronomers Ship Engineers Software Developers, Applications Fine Artists, Including Painters, Sculptors, and Illustrators Psychiatric Technicians Landscape Architects Health Educators

59

Computerisable Rank

Probability

135. 136. 137. 138. 139. 140. 141. 142. 143. 144. 145. 146. 147. 148. 149. 150. 151. 152. 153. 154. 155. 156. 157. 158. 159. 160. 161. 162. 163. 164. 165. 166. 167. 168. 169. 170. 171. 172. 173. 174. 175. 176. 177. 178. 179. 180. 181. 182. 183.

0.047 0.047 0.047 0.048 0.049 0.055 0.055 0.055 0.057 0.058 0.059 0.06 0.061 0.064 0.066 0.066 0.067 0.069 0.07 0.071 0.074 0.075 0.076 0.077 0.08 0.08 0.082 0.083 0.084 0.085 0.091 0.097 0.098 0.099 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.11 0.11 0.11 0.13 0.13 0.13 0.13 0.13

Label

0 0

SOC

code

15-2021 27-1023 11-9013 33-2022 29-2041 27-3041 29-1024 29-9799 39-7012 29-2061 19-3041 23-1022 19-1011 39-9041 53-1011 29-1126 27-3021 11-3031 17-2161 11-9021 27-2042 41-1012 39-1021 19-1012 13-1041 33-3031 27-1024 11-9051 39-9011 39-9031 11-9071 49-9051 33-3051 41-3041 35-1011 39-2011 27-3011 17-2071 19-2031 29-2054 19-2012 39-5012 27-3022 53-2021 27-2031 29-2033 15-1133 13-1111 29-2051

Occupation Mathematicians Floral Designers Farmers, Ranchers, and Other Agricultural Managers Forest Fire Inspectors and Prevention Specialists Emergency Medical Technicians and Paramedics Editors Prosthodontists Healthcare Practitioners and Technical Workers, All Other Travel Guides Licensed Practical and Licensed Vocational Nurses Sociologists Arbitrators, Mediators, and Conciliators Animal Scientists Residential Advisors Aircraft Cargo Handling Supervisors Respiratory Therapists Broadcast News Analysts Financial Managers Nuclear Engineers Construction Managers Musicians and Singers First-Line Supervisors of Non-Retail Sales Workers First-Line Supervisors of Personal Service Workers Food Scientists and Technologists Compliance Officers Fish and Game Wardens Graphic Designers Food Service Managers Childcare Workers Fitness Trainers and Aerobics Instructors Gaming Managers Electrical Power-Line Installers and Repairers Police and Sheriff’s Patrol Officers Travel Agents Chefs and Head Cooks Animal Trainers Radio and Television Announcers Electrical Engineers Chemists Respiratory Therapy Technicians Physicists Hairdressers, Hairstylists, and Cosmetologists Reporters and Correspondents Air Traffic Controllers Dancers Nuclear Medicine Technologists Software Developers, Systems Software Management Analysts Dietetic Technicians

60

Computerisable Rank

Probability

Label

184. 185. 186. 187. 188. 189. 190. 191. 192. 193. 194. 195. 196. 197. 198. 199. 200.

0.13 0.13 0.13 0.13 0.14 0.14 0.14 0.15 0.15 0.16 0.16 0.16 0.17 0.17 0.17 0.17 0.17

19-3051 21-1093 25-3021 27-4014 29-1041 17-2151 29-1071 25-2012 47-2111 17-2171 43-9031 11-1021 29-9011 33-2011 13-2061 47-1011 25-2022

201. 202. 203. 204. 205.

0.18 0.18 0.18 0.18 0.19

27-3031 49-9092 49-9095 53-2011 25-3011

206. 207. 208.

0.2 0.2 0.21

19-1041 39-4831 15-1179

209. 210. 211. 212. 213. 214. 215. 216. 217. 218. 219. 220. 221. 222. 223. 224. 225. 226. 227.

0.21 0.21 0.21 0.22 0.22 0.22 0.23 0.23 0.23 0.23 0.23 0.24 0.24 0.25 0.25 0.25 0.25 0.25 0.25

15-2011 33-9011 39-6012 15-1799 15-2041 17-2061 19-3022 13-1199 13-2051 29-2037 29-2031 13-1011 17-3029 19-3092 29-9012 21-1092 17-3025 11-9199 53-3011

228.

0.25

SOC

code

41-4011

Occupation Urban and Regional Planners Social and Human Service Assistants Self-Enrichment Education Teachers Sound Engineering Technicians Optometrists Mining and Geological Engineers, Including Mining Safety Engineers Physician Assistants Kindergarten Teachers, Except Special Education Electricians Petroleum Engineers Desktop Publishers General and Operations Managers Occupational Health and Safety Specialists Firefighters Financial Examiners First-Line Supervisors of Construction Trades and Extraction Workers Middle School Teachers, Except Special and Career/Technical Education Public Relations Specialists Commercial Divers Manufactured Building and Mobile Home Installers Airline Pilots, Copilots, and Flight Engineers Adult Basic and Secondary Education and Literacy Teachers and Instructors Epidemiologists Funeral Service Managers, Directors, Morticians, and Undertakers Information Security Analysts, Web Developers, and Computer Network Architects Actuaries Animal Control Workers Concierges Computer Occupations, All Other Statisticians Computer Hardware Engineers Survey Researchers Business Operations Specialists, All Other Financial Analysts Radiologic Technologists and Technicians Cardiovascular Technologists and Technicians Agents and Business Managers of Artists, Performers, and Athletes Engineering Technicians, Except Drafters, All Other Geographers Occupational Health and Safety Technicians Probation Officers and Correctional Treatment Specialists Environmental Engineering Technicians Managers, All Other Ambulance Drivers and Attendants, Except Emergency Medical Technicians Sales Representatives, Wholesale and Manufacturing, Technical and Scientific Products

61

Computerisable Rank

Probability

Label

229. 230. 231. 232. 233. 234. 235. 236. 237. 238. 239. 240. 241. 242. 243. 244. 245. 246. 247. 248. 249. 250. 251. 252. 253.

0.26 0.27 0.27 0.27 0.28 0.28 0.28 0.29 0.29 0.3 0.3 0.3 0.3 0.31 0.31 0.31 0.33 0.34 0.34 0.34 0.35 0.35 0.35 0.36 0.36

254.

0.36

49-2022

255. 256. 257. 258. 259. 260. 261.

0.37 0.37 0.37 0.37 0.37 0.37 0.38

51-9051 53-7061 39-4021 47-5081 27-2011 53-7111 49-2095

262. 263. 264. 265. 266. 267. 268. 269. 270. 271. 272. 273. 274.

0.38 0.38 0.38 0.38 0.39 0.39 0.39 0.39 0.39 0.4 0.4 0.4 0.41

0 0

1

SOC

code

25-2023 53-5021 31-2012 49-9062 41-1011 27-2021 39-1011 39-5094 13-1022 19-4021 31-9092 19-1023 35-2013 13-1078 33-9021 27-4032 13-2099 33-3021 29-2055 29-1124 47-2152 53-2031 29-2032 33-3011 51-4012

17-1022 17-3027 53-7064 27-3091 31-1011 51-6093 47-4021 43-3041 25-9011 23-1023 49-3042 29-2799 45-2041

Occupation Career/Technical Education Teachers, Middle School Captains, Mates, and Pilots of Water Vessels Occupational Therapy Aides Medical Equipment Repairers First-Line Supervisors of Retail Sales Workers Athletes and Sports Competitors Gaming Supervisors Skincare Specialists Wholesale and Retail Buyers, Except Farm Products Biological Technicians Medical Assistants Zoologists and Wildlife Biologists Cooks, Private Household Human Resources, Training, and Labor Relations Specialists, All Other Private Detectives and Investigators Film and Video Editors Financial Specialists, All Other Detectives and Criminal Investigators Surgical Technologists Radiation Therapists Plumbers, Pipefitters, and Steamfitters Flight Attendants Diagnostic Medical Sonographers Bailiffs Computer Numerically Controlled Machine Tool Programmers, Metal and Plastic Telecommunications Equipment Installers and Repairers, Except Line Installers Furnace, Kiln, Oven, Drier, and Kettle Operators and Tenders Cleaners of Vehicles and Equipment Funeral Attendants Helpers–Extraction Workers Actors Mine Shuttle Car Operators Electrical and Electronics Repairers, Powerhouse, Substation, and Relay Surveyors Mechanical Engineering Technicians Packers and Packagers, Hand Interpreters and Translators Home Health Aides Upholsterers Elevator Installers and Repairers Gaming Cage Workers Audio-Visual and Multimedia Collections Specialists Judges, Magistrate Judges, and Magistrates Mobile Heavy Equipment Mechanics, Except Engines Health Technologists and Technicians, All Other Graders and Sorters, Agricultural Products

62

Computerisable Rank

Probability

Label

SOC

275. 276. 277.

0.41 0.41 0.41

1

51-2041 23-1012 49-2094

278. 279.

0.42 0.42

19-4093 53-1021

280. 281. 282. 283. 284. 285. 286. 287. 288. 289. 290. 291. 292. 293. 294. 295. 296. 297. 298. 299. 300. 301. 302. 303. 304. 305. 306. 307. 308. 309. 310. 311. 312. 313. 314. 315. 316. 317. 318. 319. 320. 321.

0.43 0.43 0.43 0.44 0.45 0.46 0.47 0.47 0.47 0.48 0.48 0.48 0.48 0.48 0.49 0.49 0.49 0.49 0.49 0.5 0.5 0.5 0.51 0.51 0.52 0.52 0.53 0.53 0.54 0.54 0.54 0.54 0.54 0.55 0.55 0.55 0.55 0.56 0.57 0.57 0.57 0.57

39-3093 19-2099 19-3011 19-3093 51-9082 43-4031 13-1141 31-1013 29-2012 33-2021 17-3021 27-1026 47-5031 15-1131 33-9091 17-2021 47-5061 49-9052 43-5031 53-7033 49-9799 23-2091 41-9011 31-9091 51-6041 17-3011 47-5012 47-4041 39-4011 47-5041 39-1012 31-9011 41-3011 49-3022 53-2012 43-4051 27-4011 25-9041 45-1011 19-4031 47-3015 13-1051

1

code

Occupation Structural Metal Fabricators and Fitters Judicial Law Clerks Electrical and Electronics Repairers, Commercial and Industrial Equipment Forest and Conservation Technicians First-Line Supervisors of Helpers, Laborers, and Material Movers, Hand Locker Room, Coatroom, and Dressing Room Attendants Physical Scientists, All Other Economists Historians Medical Appliance Technicians Court, Municipal, and License Clerks Compensation, Benefits, and Job Analysis Specialists Psychiatric Aides Medical and Clinical Laboratory Technicians Fire Inspectors and Investigators Aerospace Engineering and Operations Technicians Merchandise Displayers and Window Trimmers Explosives Workers, Ordnance Handling Experts, and Blasters Computer Programmers Crossing Guards Agricultural Engineers Roof Bolters, Mining Telecommunications Line Installers and Repairers Police, Fire, and Ambulance Dispatchers Loading Machine Operators, Underground Mining Installation, Maintenance, and Repair Workers, All Other Court Reporters Demonstrators and Product Promoters Dental Assistants Shoe and Leather Workers and Repairers Architectural and Civil Drafters Rotary Drill Operators, Oil and Gas Hazardous Materials Removal Workers Embalmers Continuous Mining Machine Operators Slot Supervisors Massage Therapists Advertising Sales Agents Automotive Glass Installers and Repairers Commercial Pilots Customer Service Representatives Audio and Video Equipment Technicians Teacher Assistants First-Line Supervisors of Farming, Fishing, and Forestry Workers Chemical Technicians Helpers–Pipelayers, Plumbers, Pipefitters, and Steamfitters Cost Estimators

63

Computerisable Rank

Probability

Label

322. 323.

0.57 0.57

33-3052 37-1012

324. 325. 326. 327. 328. 329. 330. 331. 332. 333. 334. 335. 336. 337. 338. 339. 340. 341. 342.

0.58 0.59 0.59 0.59 0.59 0.59 0.59 0.6 0.6 0.6 0.61 0.61 0.61 0.61 0.61 0.61 0.61 0.61 0.61

13-2052 49-9044 25-4013 47-5042 11-3071 49-3092 49-3023 33-3012 27-4031 51-3023 49-2096 31-2022 39-3092 13-1161 43-4181 51-8031 19-4099 51-3093 51-4122

343. 344. 345. 346. 347. 348. 349. 350. 351. 352. 353. 354. 355. 356. 357. 358. 359. 360. 361. 362. 363. 364. 365. 366. 367. 368.

0.62 0.62 0.62 0.63 0.63 0.63 0.63 0.63 0.64 0.64 0.64 0.64 0.64 0.64 0.65 0.65 0.65 0.65 0.65 0.65 0.65 0.66 0.66 0.66 0.66 0.66

1

1

SOC

code

53-5022 47-2082 47-2151 19-2042 49-9012 31-9799 35-1012 47-4011 51-9031 49-9071 23-1021 43-5081 51-8012 47-2132 19-4061 51-4041 15-1150 25-4021 49-2097 49-9021 53-7041 37-2021 51-9198 43-9111 37-2011 49-3051

Occupation Transit and Railroad Police First-Line Supervisors of Landscaping, Lawn Service, and Groundskeeping Workers Personal Financial Advisors Millwrights Museum Technicians and Conservators Mine Cutting and Channeling Machine Operators Transportation, Storage, and Distribution Managers Recreational Vehicle Service Technicians Automotive Service Technicians and Mechanics Correctional Officers and Jailers Camera Operators, Television, Video, and Motion Picture Slaughterers and Meat Packers Electronic Equipment Installers and Repairers, Motor Vehicles Physical Therapist Aides Costume Attendants Market Research Analysts and Marketing Specialists Reservation and Transportation Ticket Agents and Travel Clerks Water and Wastewater Treatment Plant and System Operators Life, Physical, and Social Science Technicians, All Other Food Cooking Machine Operators and Tenders Welding, Soldering, and Brazing Machine Setters, Operators, and Tenders Motorboat Operators Tapers Pipelayers Geoscientists, Except Hydrologists and Geographers Control and Valve Installers and Repairers, Except Mechanical Door Healthcare Support Workers, All Other First-Line Supervisors of Food Preparation and Serving Workers Construction and Building Inspectors Cutters and Trimmers, Hand Maintenance and Repair Workers, General Administrative Law Judges, Adjudicators, and Hearing Officers Stock Clerks and Order Fillers Power Distributors and Dispatchers Insulation Workers, Mechanical Social Science Research Assistants Machinists Computer Support Specialists Librarians Electronic Home Entertainment Equipment Installers and Repairers Heating, Air Conditioning, and Refrigeration Mechanics and Installers Hoist and Winch Operators Pest Control Workers Helpers–Production Workers Statistical Assistants Janitors and Cleaners, Except Maids and Housekeeping Cleaners Motorboat Mechanics and Service Technicians

64

Computerisable Rank

Probability

369. 370. 371. 372. 373.

0.67 0.67 0.67 0.67 0.67

374. 375. 376. 377. 378. 379. 380. 381. 382. 383. 384. 385. 386. 387. 388. 389. 390. 391. 392. 393. 394. 395. 396. 397. 398. 399. 400. 401. 402. 403. 404. 405. 406. 407. 408. 409. 410. 411. 412. 413. 414. 415. 416.

0.67 0.68 0.68 0.68 0.68 0.68 0.69 0.69 0.69 0.7 0.7 0.7 0.7 0.71 0.71 0.71 0.71 0.71 0.71 0.72 0.72 0.72 0.72 0.72 0.72 0.72 0.73 0.73 0.73 0.73 0.73 0.74 0.74 0.74 0.74 0.75 0.75 0.75 0.75 0.75 0.75 0.76 0.76

Label

1

1 0

1

SOC

code

51-9196 51-4071 19-2021 53-3021 33-9092 49-9041 43-5052 47-5071 47-2011 17-3013 29-2021 53-3033 37-2012 51-9122 43-4061 49-3093 51-3092 49-2091 49-3011 53-2022 51-8093 47-4799 29-2081 51-6011 39-3091 31-9095 47-3016 53-7121 49-9031 47-2031 27-3012 51-6063 11-3011 47-2121 51-2021 49-3031 49-2011 39-9021 27-4012 47-3013 11-9131 47-2044 47-2141 53-6061 17-3022 49-3041 25-4011 51-9011

Occupation Paper Goods Machine Setters, Operators, and Tenders Foundry Mold and Coremakers Atmospheric and Space Scientists Bus Drivers, Transit and Intercity Lifeguards, Ski Patrol, and Other Recreational Protective Service Workers Industrial Machinery Mechanics Postal Service Mail Carriers Roustabouts, Oil and Gas Boilermakers Mechanical Drafters Dental Hygienists Light Truck or Delivery Services Drivers Maids and Housekeeping Cleaners Painters, Transportation Equipment Eligibility Interviewers, Government Programs Tire Repairers and Changers Food Batchmakers Avionics Technicians Aircraft Mechanics and Service Technicians Airfield Operations Specialists Petroleum Pump System Operators, Refinery Operators, and Gaugers Construction and Related Workers, All Other Opticians, Dispensing Laundry and Dry-Cleaning Workers Amusement and Recreation Attendants Pharmacy Aides Helpers–Roofers Tank Car, Truck, and Ship Loaders Home Appliance Repairers Carpenters Public Address System and Other Announcers Textile Knitting and Weaving Machine Setters, Operators, and Tenders Administrative Services Managers Glaziers Coil Winders, Tapers, and Finishers Bus and Truck Mechanics and Diesel Engine Specialists Computer, Automated Teller, and Office Machine Repairers Personal Care Aides Broadcast Technicians Helpers–Electricians Postmasters and Mail Superintendents Tile and Marble Setters Painters, Construction and Maintenance Transportation Attendants, Except Flight Attendants Civil Engineering Technicians Farm Equipment Mechanics and Service Technicians Archivists Chemical Equipment Operators and Tenders

65

Computerisable Rank

Probability

Label

417. 418. 419. 420. 421. 422. 423. 424. 425. 426. 427.

0.76 0.76 0.77 0.77 0.77 0.77 0.77 0.77 0.77 0.78 0.78

428. 429. 430.

0.78 0.78 0.79

43-9011 51-8092 43-5053

431. 432. 433. 434. 435. 436. 437. 438. 439. 440. 441. 442. 443. 444. 445.

0.79 0.79 0.79 0.79 0.79 0.79 0.79 0.79 0.8 0.8 0.81 0.81 0.81 0.81 0.81

53-3032 39-5093 47-2081 49-9098 49-3052 51-2011 45-4022 47-2042 39-5011 47-5011 35-2011 43-9022 17-3012 17-3024 51-9192

446. 447. 448. 449. 450. 451. 452. 453. 454. 455. 456. 457. 458. 459. 460. 461. 462.

0.81 0.81 0.81 0.82 0.82 0.82 0.82 0.82 0.82 0.82 0.83 0.83 0.83 0.83 0.83 0.83 0.83

1 0

1 1

1

SOC

code

49-2092 45-4021 19-4091 49-9094 37-3013 35-3011 13-1023 35-9021 45-3021 31-9093 51-4031

11-9141 43-6013 51-6021 51-2031 49-2098 49-9045 39-2021 47-2211 47-2072 47-2021 45-3011 47-2221 53-4021 53-4031 35-2012 53-5011 51-9023

Occupation Electric Motor, Power Tool, and Related Repairers Fallers Environmental Science and Protection Technicians, Including Health Locksmiths and Safe Repairers Tree Trimmers and Pruners Bartenders Purchasing Agents, Except Wholesale, Retail, and Farm Products Dishwashers Hunters and Trappers Medical Equipment Preparers Cutting, Punching, and Press Machine Setters, Operators, and Tenders, Metal and Plastic Computer Operators Gas Plant Operators Postal Service Mail Sorters, Processors, and Processing Machine Operators Heavy and Tractor-Trailer Truck Drivers Shampooers Drywall and Ceiling Tile Installers Helpers–Installation, Maintenance, and Repair Workers Motorcycle Mechanics Aircraft Structure, Surfaces, Rigging, and Systems Assemblers Logging Equipment Operators Floor Layers, Except Carpet, Wood, and Hard Tiles Barbers Derrick Operators, Oil and Gas Cooks, Fast Food Word Processors and Typists Electrical and Electronics Drafters Electro-Mechanical Technicians Cleaning, Washing, and Metal Pickling Equipment Operators and Tenders Property, Real Estate, and Community Association Managers Medical Secretaries Pressers, Textile, Garment, and Related Materials Engine and Other Machine Assemblers Security and Fire Alarm Systems Installers Refractory Materials Repairers, Except Brickmasons Nonfarm Animal Caretakers Sheet Metal Workers Pile-Driver Operators Brickmasons and Blockmasons Fishers and Related Fishing Workers Structural Iron and Steel Workers Railroad Brake, Signal, and Switch Operators Railroad Conductors and Yardmasters Cooks, Institution and Cafeteria Sailors and Marine Oilers Mixing and Blending Machine Setters, Operators, and Tenders

66

Computerisable Rank

Probability

Label

463.

0.83

47-3011

464. 465. 466. 467. 468. 469. 470. 471. 472. 473. 474. 475. 476. 477.

0.83 0.83 0.83 0.83 0.83 0.83 0.83 0.83 0.83 0.84 0.84 0.84 0.84 0.84

47-4091 47-2131 51-5112 53-6031 47-4071 39-6011 41-2012 51-4023 47-2071 51-4111 17-3023 47-2161 51-4192 51-4034

478. 479. 480. 481. 482. 483. 484.

0.84 0.84 0.84 0.84 0.84 0.85 0.85

33-9032 51-6052 53-7073 43-9081 33-3041 53-7062 41-4012

485. 486. 487. 488. 489. 490. 491. 492. 493. 494. 495. 496. 497. 498. 499. 500. 501. 502. 503. 504. 505. 506. 507. 508.

0.85 0.85 0.85 0.85 0.85 0.86 0.86 0.86 0.86 0.86 0.86 0.86 0.86 0.86 0.86 0.86 0.87 0.87 0.87 0.87 0.87 0.87 0.87 0.87

1

1

SOC

code

43-5041 51-8013 51-8091 47-5021 19-4051 43-6011 51-8099 35-3041 51-7041 53-4041 31-9096 51-9032 41-9022 51-4011 49-9043 43-4021 45-2090 45-4011 51-4052 47-2041 47-2142 13-1021 51-7021 35-2021

Occupation Helpers–Brickmasons, Blockmasons, Stonemasons, and Tile and Marble Setters Segmental Pavers Insulation Workers, Floor, Ceiling, and Wall Printing Press Operators Automotive and Watercraft Service Attendants Septic Tank Servicers and Sewer Pipe Cleaners Baggage Porters and Bellhops Gaming Change Persons and Booth Cashiers Rolling Machine Setters, Operators, and Tenders, Metal and Plastic Paving, Surfacing, and Tamping Equipment Operators Tool and Die Makers Electrical and Electronics Engineering Technicians Plasterers and Stucco Masons Layout Workers, Metal and Plastic Lathe and Turning Machine Tool Setters, Operators, and Tenders, Metal and Plastic Security Guards Tailors, Dressmakers, and Custom Sewers Wellhead Pumpers Proofreaders and Copy Markers Parking Enforcement Workers Laborers and Freight, Stock, and Material Movers, Hand Sales Representatives, Wholesale and Manufacturing, Except Technical and Scientific Products Meter Readers, Utilities Power Plant Operators Chemical Plant and System Operators Earth Drillers, Except Oil and Gas Nuclear Technicians Executive Secretaries and Executive Administrative Assistants Plant and System Operators, All Other Food Servers, Nonrestaurant Sawing Machine Setters, Operators, and Tenders, Wood Subway and Streetcar Operators Veterinary Assistants and Laboratory Animal Caretakers Cutting and Slicing Machine Setters, Operators, and Tenders Real Estate Sales Agents Computer-Controlled Machine Tool Operators, Metal and Plastic Maintenance Workers, Machinery Correspondence Clerks Miscellaneous Agricultural Workers Forest and Conservation Workers Pourers and Casters, Metal Carpet Installers Paperhangers Buyers and Purchasing Agents, Farm Products Furniture Finishers Food Preparation Workers

67

Computerisable Rank

Probability

Label

509. 510. 511. 512. 513. 514. 515. 516. 517.

0.87 0.87 0.87 0.88 0.88 0.88 0.88 0.88 0.88

518.

0.88

51-6091

519. 520. 521. 522. 523. 524. 525. 526. 527. 528. 529. 530. 531. 532. 533. 534. 535. 536. 537. 538. 539. 540. 541. 542. 543. 544. 545. 546. 547. 548.

0.88 0.88 0.88 0.89 0.89 0.89 0.89 0.89 0.89 0.89 0.89 0.89 0.89 0.9 0.9 0.9 0.9 0.9 0.9 0.9 0.9 0.9 0.9 0.9 0.9 0.91 0.91 0.91 0.91 0.91

47-2053 51-4194 49-3043 51-3011 31-9094 47-2022 53-3022 27-3042 49-9096 47-4061 51-8021 51-6031 53-3041 43-4161 29-2011 47-2171 47-2181 53-7021 53-6041 53-6051 51-4062 51-9195 13-2021 53-7072 49-9097 39-3012 49-9063 39-7011 49-9011 51-3091

549. 550. 551.

0.91 0.91 0.91

53-7071 29-2071 51-9121

552.

0.91

51-4081

1

1

1

1 1 1

SOC

code

47-2043 53-6021 47-4051 47-2061 43-5061 51-9141 17-1021 51-4051 51-9012

Occupation Floor Sanders and Finishers Parking Lot Attendants Highway Maintenance Workers Construction Laborers Production, Planning, and Expediting Clerks Semiconductor Processors Cartographers and Photogrammetrists Metal-Refining Furnace Operators and Tenders Separating, Filtering, Clarifying, Precipitating, and Still Machine Setters, Operators, and Tenders Extruding and Forming Machine Setters, Operators, and Tenders, Synthetic and Glass Fibers Terrazzo Workers and Finishers Tool Grinders, Filers, and Sharpeners Rail Car Repairers Bakers Medical Transcriptionists Stonemasons Bus Drivers, School or Special Client Technical Writers Riggers Rail-Track Laying and Maintenance Equipment Operators Stationary Engineers and Boiler Operators Sewing Machine Operators Taxi Drivers and Chauffeurs Human Resources Assistants, Except Payroll and Timekeeping Medical and Clinical Laboratory Technologists Reinforcing Iron and Rebar Workers Roofers Crane and Tower Operators Traffic Technicians Transportation Inspectors Patternmakers, Metal and Plastic Molders, Shapers, and Casters, Except Metal and Plastic Appraisers and Assessors of Real Estate Pump Operators, Except Wellhead Pumpers Signal and Track Switch Repairers Gaming and Sports Book Writers and Runners Musical Instrument Repairers and Tuners Tour Guides and Escorts Mechanical Door Repairers Food and Tobacco Roasting, Baking, and Drying Machine Operators and Tenders Gas Compressor and Gas Pumping Station Operators Medical Records and Health Information Technicians Coating, Painting, and Spraying Machine Setters, Operators, and Tenders Multiple Machine Tool Setters, Operators, and Tenders, Metal and Plastic

68

Computerisable Rank

Probability

Label

553. 554.

0.91 0.91

53-4013 49-2093

555. 556.

0.91 0.91

35-9011 51-4191

557. 558. 559. 560.

0.91 0.91 0.91 0.91

19-4041 49-3021 51-7032 51-4021

561. 562. 563. 564. 565. 566. 567. 568. 569.

0.92 0.92 0.92 0.92 0.92 0.92 0.92 0.92 0.92

43-9071 29-2052 43-4131 53-7031 41-3021 51-7011 51-9123 47-4031 51-4193

570. 571. 572. 573. 574. 575. 576. 577. 578. 579. 580. 581. 582. 583. 584.

0.92 0.92 0.92 0.92 0.93 0.93 0.93 0.93 0.93 0.93 0.93 0.93 0.93 0.93 0.93

41-2031 35-3021 51-9399 47-3012 51-9193 51-2091 47-5013 53-7011 49-3053 53-4012 53-7063 51-4061 49-2021 51-3021 51-9041

585. 586. 587. 588. 589. 590.

0.93 0.93 0.93 0.93 0.94 0.94

591. 592. 593. 594. 595.

0.94 0.94 0.94 0.94 0.94

1 1 1

SOC

code

53-7081 13-2081 51-4022 53-7051 13-2011 51-4032 43-9051 35-3031 51-3022 13-2031 47-2051

Occupation Rail Yard Engineers, Dinkey Operators, and Hostlers Electrical and Electronics Installers and Repairers, Transportation Equipment Dining Room and Cafeteria Attendants and Bartender Helpers Heat Treating Equipment Setters, Operators, and Tenders, Metal and Plastic Geological and Petroleum Technicians Automotive Body and Related Repairers Patternmakers, Wood Extruding and Drawing Machine Setters, Operators, and Tenders, Metal and Plastic Office Machine Operators, Except Computer Pharmacy Technicians Loan Interviewers and Clerks Dredge Operators Insurance Sales Agents Cabinetmakers and Bench Carpenters Painting, Coating, and Decorating Workers Fence Erectors Plating and Coating Machine Setters, Operators, and Tenders, Metal and Plastic Retail Salespersons Combined Food Preparation and Serving Workers, Including Fast Food Production Workers, All Other Helpers–Carpenters Cooling and Freezing Equipment Operators and Tenders Fiberglass Laminators and Fabricators Service Unit Operators, Oil, Gas, and Mining Conveyor Operators and Tenders Outdoor Power Equipment and Other Small Engine Mechanics Locomotive Firers Machine Feeders and Offbearers Model Makers, Metal and Plastic Radio, Cellular, and Tower Equipment Installers and Repairs Butchers and Meat Cutters Extruding, Forming, Pressing, and Compacting Machine Setters, Operators, and Tenders Refuse and Recyclable Material Collectors Tax Examiners and Collectors, and Revenue Agents Forging Machine Setters, Operators, and Tenders, Metal and Plastic Industrial Truck and Tractor Operators Accountants and Auditors Drilling and Boring Machine Tool Setters, Operators, and Tenders, Metal and Plastic Mail Clerks and Mail Machine Operators, Except Postal Service Waiters and Waitresses Meat, Poultry, and Fish Cutters and Trimmers Budget Analysts Cement Masons and Concrete Finishers

69

Computerisable Rank

Probability

596. 597. 598. 599. 600. 601. 602. 603. 604. 605. 606.

0.94 0.94 0.94 0.94 0.94 0.94 0.94 0.94 0.94 0.94 0.94

607. 608. 609. 610. 611. 612. 613. 614. 615. 616. 617. 618. 619. 620.

0.94 0.94 0.94 0.95 0.95 0.95 0.95 0.95 0.95 0.95 0.95 0.95 0.95 0.95

621. 622. 623. 624.

0.95 0.95 0.95 0.95

625. 626. 627. 628. 629. 630. 631. 632. 633. 634.

0.95 0.95 0.96 0.96 0.96 0.96 0.96 0.96 0.96 0.96

635. 636. 637.

0.96 0.96 0.96

638. 639.

0.96 0.96

Label

1

1

1

1

SOC

code

49-3091 49-9091 51-4121 43-5021 43-4111 35-2015 53-7032 47-3014 43-4081 51-9197 41-9091 37-1011 45-2011 23-2011 39-5092 43-5111 51-6062 43-3011 51-8011 33-9031 43-4121 47-2073 51-5113 45-2021 51-4072 51-2022 51-9191 37-3011 51-4033 43-5051 51-9071 43-5032 43-4171 43-9061 11-3111 43-2011 35-3022 47-5051 43-6014 17-3031 51-7031 51-6064

1

53-4011 39-3011

Occupation Bicycle Repairers Coin, Vending, and Amusement Machine Servicers and Repairers Welders, Cutters, Solderers, and Brazers Couriers and Messengers Interviewers, Except Eligibility and Loan Cooks, Short Order Excavating and Loading Machine and Dragline Operators Helpers–Painters, Paperhangers, Plasterers, and Stucco Masons Hotel, Motel, and Resort Desk Clerks Tire Builders Door-to-Door Sales Workers, News and Street Vendors, and Related Workers First-Line Supervisors of Housekeeping and Janitorial Workers Agricultural Inspectors Paralegals and Legal Assistants Manicurists and Pedicurists Weighers, Measurers, Checkers, and Samplers, Recordkeeping Textile Cutting Machine Setters, Operators, and Tenders Bill and Account Collectors Nuclear Power Reactor Operators Gaming Surveillance Officers and Gaming Investigators Library Assistants, Clerical Operating Engineers and Other Construction Equipment Operators Print Binding and Finishing Workers Animal Breeders Molding, Coremaking, and Casting Machine Setters, Operators, and Tenders, Metal and Plastic Electrical and Electronic Equipment Assemblers Adhesive Bonding Machine Operators and Tenders Landscaping and Groundskeeping Workers Grinding, Lapping, Polishing, and Buffing Machine Tool Setters, Operators, and Tenders, Metal and Plastic Postal Service Clerks Jewelers and Precious Stone and Metal Workers Dispatchers, Except Police, Fire, and Ambulance Receptionists and Information Clerks Office Clerks, General Compensation and Benefits Managers Switchboard Operators, Including Answering Service Counter Attendants, Cafeteria, Food Concession, and Coffee Shop Rock Splitters, Quarry Secretaries and Administrative Assistants, Except Legal, Medical, and Executive Surveying and Mapping Technicians Model Makers, Wood Textile Winding, Twisting, and Drawing Out Machine Setters, Operators, and Tenders Locomotive Engineers Gaming Dealers

70

Computerisable Rank

Probability

640. 641. 642. 643. 644. 645. 646. 647. 648. 649. 650. 651. 652.

0.96 0.96 0.96 0.96 0.97 0.97 0.97 0.97 0.97 0.97 0.97 0.97 0.97

653. 654. 655. 656. 657. 658. 659. 660. 661. 662. 663. 664. 665. 666. 667. 668. 669. 670. 671. 672. 673. 674. 675. 676. 677. 678.

0.97 0.97 0.97 0.97 0.97 0.97 0.97 0.97 0.97 0.97 0.97 0.97 0.97 0.97 0.97 0.97 0.98 0.98 0.98 0.98 0.98 0.98 0.98 0.98 0.98 0.98

679. 680. 681. 682. 683. 684. 685. 686.

0.98 0.98 0.98 0.98 0.98 0.98 0.98 0.98

Label

1

1

1

1

1 1

1

SOC

code

49-9093 35-2014 39-3031 43-3021 53-6011 51-7042 51-2092 51-6042 51-2023 13-1074 51-6061 51-9081 51-9021 51-9022 37-3012 45-4023 51-9083 41-2011 49-9061 39-3021 51-5111 41-2021 43-4071 41-9021 43-2021 19-4011 43-3051 43-4041 35-9031 41-9012 51-9061 43-3031 43-6012 27-4013 53-3031 13-1031 41-2022 13-2041 51-4035 43-5071 43-3061 51-9111 51-9194 43-3071 27-2023 13-1032 13-2072

Occupation Fabric Menders, Except Garment Cooks, Restaurant Ushers, Lobby Attendants, and Ticket Takers Billing and Posting Clerks Bridge and Lock Tenders Woodworking Machine Setters, Operators, and Tenders, Except Sawing Team Assemblers Shoe Machine Operators and Tenders Electromechanical Equipment Assemblers Farm Labor Contractors Textile Bleaching and Dyeing Machine Operators and Tenders Dental Laboratory Technicians Crushing, Grinding, and Polishing Machine Setters, Operators, and Tenders Grinding and Polishing Workers, Hand Pesticide Handlers, Sprayers, and Applicators, Vegetation Log Graders and Scalers Ophthalmic Laboratory Technicians Cashiers Camera and Photographic Equipment Repairers Motion Picture Projectionists Prepress Technicians and Workers Counter and Rental Clerks File Clerks Real Estate Brokers Telephone Operators Agricultural and Food Science Technicians Payroll and Timekeeping Clerks Credit Authorizers, Checkers, and Clerks Hosts and Hostesses, Restaurant, Lounge, and Coffee Shop Models Inspectors, Testers, Sorters, Samplers, and Weighers Bookkeeping, Accounting, and Auditing Clerks Legal Secretaries Radio Operators Driver/Sales Workers Claims Adjusters, Examiners, and Investigators Parts Salespersons Credit Analysts Milling and Planing Machine Setters, Operators, and Tenders, Metal and Plastic Shipping, Receiving, and Traffic Clerks Procurement Clerks Packaging and Filling Machine Operators and Tenders Etchers and Engravers Tellers Umpires, Referees, and Other Sports Officials Insurance Appraisers, Auto Damage Loan Officers

71

Computerisable Rank

Probability

687. 688. 689. 690. 691. 692. 693. 694. 695. 696. 697. 698. 699. 700. 701. 702.

0.98 0.98 0.98 0.98 0.99 0.99 0.99 0.99 0.99 0.99 0.99 0.99 0.99 0.99 0.99 0.99

Label

1

1

SOC

code

43-4151 43-4011 43-9041 51-2093 43-9021 25-4031 43-4141 51-9151 13-2082 43-5011 49-9064 13-2053 15-2091 51-6051 23-2093 41-9041

Occupation Order Clerks Brokerage Clerks Insurance Claims and Policy Processing Clerks Timing Device Assemblers and Adjusters Data Entry Keyers Library Technicians New Accounts Clerks Photographic Process Workers and Processing Machine Operators Tax Preparers Cargo and Freight Agents Watch Repairers Insurance Underwriters Mathematical Technicians Sewers, Hand Title Examiners, Abstractors, and Searchers Telemarketers

72

[PDF] THE FUTURE OF EMPLOYMENT: HOW SUSCEPTIBLE ARE JOBS TO COMPUTERISATION? - Free Download PDF (2024)
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