2.1 Computers Gain a New Type of Cognitive Capacity

When computers became generally useful in the 1970s, automation crossed one cognitive threshold. Computerization allowed the automation of many tasks that previously had to be done by hand. The way today's robot arms in automobile assembly plants sense and interact with chassis as they pass down the line would look very much like magic to a 1950s worker – or at the very least like science fiction.

The range of tasks that could be automated is, even today, limited compared to the vast range of tasks done by workers in all occupations. Mostly, automation affected routine, repetitive, manual tasks such as those found in assembly line factories. Indeed, a very large share of industrial robots work in the automotive sector. Limited automation was not due to a lack of creativity on the part of factory designers – rather there was a very clear structural reason for the it.

Computers back then were just following an explicit set of logical steps called a computer program. Automation was limited because computers were limited by programming; they were strictly obedient to the computer code written by a human. Since the human could only program based on a type of thinking that people understand, the cognitive capabilities of computers were limited to a narrow range of human thinking. This cognitive limitation created Moravec's Paradox: computers were good at what humans found hard but bad at what humans found easy. The reason was all down to the nature of classical computer programming.

Humans taught computers to do things with computer programs, so computers could only perform mental tasks where humans understood precisely how we humans do the mental task. But as Marvin Minsky (Reference Minsky1986) put it, humans are: ‘least aware of what our minds do best’. Machine learning – which really came into its stride around 2016 – solved the paradox by skipping the programming. Daniel Kahneman (Reference Kahneman2011) characterized Minsky's distinction between the thinking we do best and the thinking we are aware of as ‘thinking slow and fast’.

With machine learning, computers started to be able to do some types of fast thinking as well as the slow thinking they had been doing since the beginning. With machine learning, computers could do some of the things that human brains do well, but where it was impossible to write a classic computer program because humans are unaware of how they perform the task (such as recognizing a cat in a photo). How is machine learning done?

It is significant that computer scientists use the word ‘training’ instead of the word ‘programming’ when they develop computer programmes to perform thinking-fast tasks. Machine learning ‘trains’ a very large statistical model that is designed to guess solutions to particular problems. This requires very large amounts of data and huge amounts of computing power to invert the matrices needed to ‘train’, i.e. estimate, the computer model.

With this new way of ‘programming’ computers, white-collar robots (i.e. artificial intelligence, or AI, software) can perform as well as humans in many new mental tasks, such as photo recognition, handwriting recognition, or language translation. This is one key reason that the present is different. Software robots can perform a whole range of mental tasks that they could not before 2016 or so. Of course, the breakthrough was incremental and based on advancing ICT (gathering, storing, process, and transmitting information), but the result was quite discrete. Most people in developing nations are using vastly more AI-enabled services without even knowing it.

As it turned out, many of the new mental capacities gained by computers are useful in the office and service jobs, and so many new service-sector tasks are automatable now, whereas before, they were not. This is one reason digital technology is more than just better ICT.

As far as development is concerned, the upshot is that many manufacturing tasks that previously required a human hand can now be automated with robot hands. And many office tasks involving information ‘assembly-line’ work can be automated by robotic process automation (RPA) suites, virtual assistants, and the like. This matters in offices, but it is also leading to factories that need very few manual workers.

2.2 Globalization and Automation Are also Affecting the Service Sector

To date, the gains and pains of globalization and automation have been mostly felt by the manufacturing sector or commodity-producing sectors – both in developed and developing nations. Going forwards, the gains and pains will be felt by professional and service-sector jobs. However, since most services are under-priced in developing nations compared to developed nations, it is likely that this will mostly be an export opportunity for developing nations and an import opportunity for developed nations. The basic point is that service jobs were shielded by high face-to-face costs. As digital technology tears down those barriers, the differences between the wages of accountants in, say, the UK, and in, say, Kenya, will narrow.

The next section considers in more depth how digitech is making manufacturing jobless and non-traded while making services freely traded.

3.1 Production-Cost Differences versus Trade Costs

We start from the simple proposition that goods will be traded if international differences in production costs (using a very broad definition of production costs) exceed international ‘separation’ costs, using a very broad definition of separation costs, i.e. the cost of moving goods, ideas, people, capital, and services from sellers in one nation to buyers in another. Operationalizing this point requires more specificity.

We conceptualize the cost of production of a given good or service as consisting of two components: the unit labour cost and the unit cost of all other inputs. The unit labour cost in sector i in a typical country compromises a unit labour input coefficient, a_i, and the wage, so that the unit labour cost is wa_i. The non-labour costs, which we denote as r_i, consists of machines, intermediate inputs, and the like. For simplicity, we assume labour is perfectly non-traded, but all non-labour factors are freely traded and so cost the same in all nations (thus r_i has no country subscript). The unit production cost for good or service ‘i’ in a typical nation is thus: $c_i^n = w^na_i^n + r_i$, where the ‘n’ denotes the nation under consideration (North in this case).

The proportional difference between the production cost of i in two nations (denoted by the superscripts ‘n’ and ‘s’) is:

(1)$$\matrix{ {\displaystyle{{c_i^n -c_i^s } \over {c_i^n }} = \theta _L\left({1-\displaystyle{{w^sa_i^s } \over {w^na_i^n }}} \right)} \cr } $$

where θ _L is the labour-cost share in the North. In words, this equation says that the cost difference depends upon the relative labour cost in the two nations and the importance of labour in total costs. A good or service is traded if the proportional production-cost differences exceed the proportional separation cost. In the extreme, a labour-cost share of 0 would imply a 0 production-cost differential across countries since all other factors of production are freely traded.

The endogeneity of tradability, and how digitech changes it, requires us to look across all goods and services. To this end, we employ a modified version of the Dornbusch et al. (Reference Dornbusch, Fisher and Samuelson1977) analysis.

3.2 Comparative Advantage and Trade Costs in a Simple Diagram

Comparative advantage analysis starts with a comparison of nations’ sector-by-sector competitiveness and we limit ourselves to two nations, North and South, to keep the analysis simple. We assume North is at the technological frontier while South is not in the sense that Northern labour is more productive in every sector. We also assume that North's technological edge is greater in some sectors than others. Since North labour is more productive in every sector, the Northern wage, in equilibrium, exceeds the Southern wage (measured in terms of the numeraire).

As is well-known from standard comparative advantage analysis, equilibrium wages will be such that the North's comparative-advantage sectors are those where its technological strengths are most marked. For the South, its comparative-advantage sectors are those where its technological weaknesses are the least telling. A simple way to illustrate this is to plot the proportional production–cost difference for each sector, namely (c^s–cⁿ)/c^s, having labelled the sectors so that the differences are declining as in Figure 1.

Figure 1. Endogenous tradeability diagram

Source: Authors’ elaboration.

The horizontal axis of the diagram lists the sectors – denoted by the shorthand A, B, C, etc., recalling that the sectors are labelled such that the North's cost advantage over the South's is highest in A and lowest in H. North exports the goods/services where its technology edge outweighs its higher wage; South exports the other sectors. As a matter of convention, we assume that there is no production cost difference in Sector E. Note that the North–South wage ratio is endogenous and not addressed in the diagram. We know, however, that in equilibrium, the wages must adjust such that North exports some goods and South exports others. Since the point of this conceptualization is to examine the determinants of tradability, we introduce trade costs.

Even in today's world, trade costs are quite substantial for most manufactured goods. One often-cited estimate by Anderson and Van Wincoop (Reference Anderson and Van Wincoop2004) puts the ad valorem cost at 170% on average. More recent work indicates that these costs have fallen. Allowing for trade cost is simple to add to the figure in the form of the ‘no trade bands’.

This setup allows us to focus on two determinants of tradability – the trade costs and the labour-cost share. Automation is rapidly lowering the latter for manufactured goods, and digital technology is rapidly lowering trade cost for services.

3.3 Digitech Drives Manufacturing Automation and Lowers Service-Trade CostsFootnote ²

All around the world – including in developing nations – machines are taking over tasks that used to be performed by workers. The result has been a significant drop in the number of workers involved in manufacturing and thus a drop in the labour-cost share (see, for example, Dauth et al., Reference Dauth, Findeisen, Suedekum and Woessner2018). Whereas jobs in developing countries still are less exposed to automation, this is changing (Das and Hilgenstock, Reference Das and Hilgenstock2022). The resulting reduction in labour-cost shares dampens comparative advantage based on international differences in technology and wages.

A core premise in this paper is the claim that advancing digitech is lowering trade costs and lowering labour-cost shares in both goods and services, but not at the same pace. For services, digitech is radically lowering trade costs, but lowering the labour-cost share only marginally (since robotic automation is still mostly focused on manufacturing). For manufactured goods, digitech is only marginally lowering trade costs (the big steps came with containerization and air cargo), but radically lowering the labour-cost share via robotics.

We simplify to clarify by positing extreme assumptions. We assume that digitech's advance has no effect on the cost of trading goods, but a big effect on labour-cost share in goods production. For services, we assume the opposite. The effects are shown in Figure 1. In the left panel, the no-trade band narrows, so more services become tradeable; specifically, sectors D and F switch from non-traded to traded. In the right panel, which represents digitech's impact on goods sectors, the reduced labour-cost shares rotate the relative cost-competitiveness line counter clockwise (the fact that it rotates on sector E was chosen as a matter of convenience). The obvious impact is that additional goods-producing sectors switch from traded to non-traded, specifically sectors B, C, and G.

This analysis puts aside a whole range of important factors. Perhaps the most important is the endogeneity of the relative wages. A massive reshuffling of tradability of goods and services would surely have a massive impact on relative wages. We do not account for that in this diagram, but it would be simple to include, as shown in Baldwin and Dingel (Reference Baldwin and Dingel2021).

4.1 Factors Driving Telemigration

There are four factors suggesting that telemigration will grow faster than most think in almost all sectors. Perhaps the most remarkable is how fast digitech is lowering the language barrier. Machine translation now rivals average human translation for language pairs where large, hand-translated datasets are available. According to Google research, which uses humans to score machine translations on a scale from 0 (complete nonsense) to 6 (perfect), in 2015 Google Translate got a grade of 3.6 – far worse than the average human translator who gets scores such as 5.1; by 2016, Google Translate hit numbers like 5, and it is widely used. Google does a billion translations a day for online users. Instant and free-spoken translation is also possible with the Skype Translator add-on option.

Computing power and massive new datasets are the reasons why machine translation got so good, so fast. Machine-learning trained AI-systems can now recognize language patterns well enough to do human-level translation – the real constraint is the lack of human-translated sentences. For the language pairs where data are available, the translation is good; for others it is poor.

Machine translation will fundamentally alter the global supply of service workers. About 400 million people speak English as their first language, and, including good second-language speakers, there are something like a billion people who could sell services in English online. It would seem that machine translation might multiply this number by two or three, creating a tidal wave of online talent.

4.2 Work Reorganization and Telecoms

Another factor that is accelerating the trend towards remote work is the way in which US and European companies are reorganizing themselves to make it easier to slot in telecommuting workers. They are using new collaborative platforms – such as Business Skype, Slack, Trello, Basecamp, and more – that help organize communication among team members. The changes induced by the Covid-19 pandemic have accelerated these changes.

One telecommunication technology that is coming on fast uses augmented reality – that is, the projection of a digital image on to reality via a headset or glasses, or even a smartphone screen. The two key technologies are augmented reality (AR) and virtual reality (VR). Many companies, both start-ups and giants like IBM, are using AR and VR to improve remote collaboration. They are redefining what it means to work side-by-side with someone. They are going a long way towards taking the ‘remote’ out of remote work.

There are other forms of telecommunication technology in testing stages, such as ‘holographic telepresence’. This projects real-time, three-dimensional images of people (along with audio) in a way that makes it seem as if the remote person is right next to you. This is the stuff of science fiction, but it is not unimaginable – having been used in the 2017 French presidential election and the 2014 Indian election.

6.1 How Are Services Different?

There are two critical shifts in thinking when it comes to service-led development that we can summarize in two pithy aphorisms.

• • Stop thinking capital equipment and technology and start thinking people and training.

The key to industrialization was to get the right equipment and the right technology in place and to line up the factories with sufficiently large customer bases. In the traditional development strategy, labour in the manufacturing sector is not viewed as a relevant constraint. It is a bit of a sideshow since one of the great features of manufacturing is that workers can, almost, walk out of the rice fields into a factory and start being productive with very little preparation. This is not true of modern services.

When it comes to modern services, the people are the ‘capital equipment’, so to speak. And the people do not come with embedded technology, unlike a robot welder from Germany. Foreign know-how may be important but for many types of export services – say coding, copyediting, or project management – the technology is a bit of a sideshow. The skill and experience of the people, the service providers, are the real constraint.

Joining the service value-added chains require less of a great push than the development of an industrial base, but the accumulation of human capital may take a longer time than the accumulation of physical capital.

Secondly,

• • Stop thinking factories and start thinking of cities as productive platforms.

Cities are where people meet and form local networks for face-to-face connections and exchanges, where people exchange ideas, and competition among ideas plays out. Cities facilitate matching between service workers and service firms. As the economic geographer Enrico Moretti puts it, cities become ‘brain hubs’ (Moretti, Reference Moretti2013). Workers and firms implicitly benefit from each other's knowledge creation via face-to-face interaction and social networking. This point is not new.

In 2010, the Netherlands Bureau for Economic Policy Analysis wrote a study of how the Netherlands could future-proof its economy and the answer was: cities. Cities should not be thought of as mere collections of people, but rather as complex work spaces that generate new ideas and new ways of doing things (Ter Weel, van der Horst, and Gelauff, Reference Ter Weel, van der Horst and Gelauff2010).

Governments should start thinking of cities as production hubs, not just living quarters. Cities should be conceptualized as geographic centres for face-to-face interactions that foster the production of export-oriented services. Winning cities will attract high-quality jobs and lock them in with agglomeration forces.

Another change in thinking is actually a continuation of the thinking about manufacturing. We are all by now familiar with the notion of the role of the second unbundling in manufacturing-led development. The idea that there is a value chain that a developing nation can join is clear. The same thing is true in services.