March 5th, 2015
A recent blogpost by the economist Diane Coyle quoted JK Galbraith as saying in 1952: “The modern industry of a few large firms is an excellent instrument for inducing technical change. It is admirably equipped for financing technical development and for putting it into use. The competition of the competitive world, by contrast, almost completely precludes technical development.” Coyle describes this as “complete nonsense” -“ big firms tend to do incremental innovation, while radical innovation tends to come from small entrants.” This is certainly conventional wisdom now – but it needs to be challenged.
As a point of historical fact, what Galbraith wrote in 1952 was correct – the great, world-changing innovations of the postwar years were indeed the products, not of lone entrepreneurs, but of the giant R&D departments of big corporations. What is true is that in recent years we’ve seen radical innovations in IT which have arisen from small entrants, of which Google’s search algorithm is the best known example. But we must remember two things. Digital innovations like these don’t exist in isolation – they only have an impact because they can operate on a technological substrate which isn’t digital, but physical. The fast, small and powerful computers, the world-wide communications infrastructure that digital innovations rely on were developed, not in small start-ups, but in large, capital intensive firms. And many of the innovations we urgently need – in areas like affordable low carbon energy, grid-scale energy storage, and healthcare for ageing populations – will not be wholly digital in character. Technologies don’t all proceed at the same pace (as I discussed in an earlier post – Accelerating change or innovation stagnation). In focusing on the digital domain, in which small entrants can indeed achieve radical innovations (as well as some rather trivial ones), we’re in danger of failing to support the innovation in the material and biological domains, which needs the long-term, well-resourced development efforts that only big organisations can mobilise. The outcome will be a further slowing of economic growth in the developed world, as innovation slows down and productivity growth stalls.
So what were the innovations that the sluggish big corporations of the post-war world delivered? Jet aircraft, antibiotics, oral contraceptives, transistors, microprocessors, Unix, optical fibre communications and mobile phones are just a few examples. Read the rest of this entry »
January 28th, 2015
The biggest current issue in the UK’s economic situation is the continuing slump in productivity. It’s this poor productivity performance that underlies slow or no real wage growth, and that also contributes to disappointing government revenues and consequent slow progress reducing the government deficit. Yet the causes of this poor productivity performance are barely discussed, let alone understood. In the long-term, productivity growth is associated with innovation and technological progress – have we stopped being able to innovate? The ONS has recently released a set of statistics which potentially throw some light on the issue. These estimates of total factor productivity – productivity controlled for inputs of labour and capital – make clear the seriousness of the problem.
Total factor productivity relative to 1994, whole economy, ONS estimates
Here are the figures for the whole economy. They show that, up to 2008, total factor productivity grew steadily at around 1% a year. Then it precipitously fell, losing more than a decade’s worth of growth, and it continues to fall. This means that each year since the financial crisis, on average we have had to work harder or put in more capital to achieve the same level of economic output. A simple-minded interpretation of this would be that, rather than seeing technological progress being reflected in economic growth, we’re going backwards, we’re technologically regressing, and the only economic growth we’re seeing is because we have a larger population working longer hours.
Of course, things are more complicated than this. Many different sectors contribute to the economy – in some, we see substantial innovation and technological progress, while in others the situation is not so good. It’s the overall shape of the economy, the balance between growing and stagnating sectors, that contributes to the whole picture. The ONS figures do begin to break down total factor productivity growth into different sectors, and this begins to give some real insight into what’s wrong with the UK’s economy and what needs to be done to right it. Before I come to those details, I need to say something more about what’s being estimated here.
Where does sustainable, long term economic growth come from? Read the rest of this entry »
January 5th, 2015
The UK government published a new Science and Innovation Strategy just before Christmas, in circumstances that have led to a certain amount of comment (see, for example, here and here). There’s a lot to be said about this strategy, but here I want to discuss just one aspect – the document’s extended references to the Haldane Principle. This principle is widely believed to define, in UK science policy, a certain separation between politics and science, taking detailed decisions about what science to fund out of the hands of politicians and entrusting them to experts in the Research Councils, at arms’ length from the government. The new strategy reaffirms an adherence to the Haldane Principle, but it does this in a way that will make some people worry that an attempt is being made to redefine it, to allow more direct intervention in science funding decisions by politicians in Whitehall. No-one doubts that the government of the day has, not just a right, but a duty, to set strategic directions and priorities for the science the government funds. What’s at issue are how to make the best decisions, underpinned by the best evidence, for what by definition are the uncertain outcomes of research.
The key point to recognize about the Haldane Principle is that it is – as the historian David Edgerton pointed out – an invented tradition. Read the rest of this entry »
November 16th, 2014
This long blogpost is based on a lecture I gave at UCL a couple of weeks ago, for which you can download the overheads here. It’s a bit of a rough cut but I wanted to write it down while it was fresh in my mind.
People talk about innovation now in two, contradictory, ways. The prevailing view is that innovation is accelerating. In everyday life, the speed with which our electronic gadgets become outdated seems to provide supporting evidence for this view, which, taken to the extreme, leads to the view of Kurzweil and his followers that we are approaching a technological singularity. Rapid technological change always brings losers as well as unanticipated and unwelcome consequences. The question then is whether it is possible to innovate in a way that minimises these downsides, in a way that’s responsible. But there’s another narrative about innovation that’s growing in traction, prompted by the dismally poor economic growth performance of the developed economies since the 2008 financial crisis. In this view – perhaps most cogently expressed by economic Tyler Cowen – slow economic growth is reflecting a slow-down in technological innovation – a Great Stagnation. A slow-down in the rate of technological change may reassure conservatives worried about the downsides of rapid innovation. But we need technological innovation to help us overcome our many problems, many of them caused in the first place by the unforeseen consequences of earlier waves of innovation. So our failure to innovate may itself be irresponsible.
What irresponsible innovation looks like
What could we mean by irresponsible innovation? We all have our abiding cultural image of a mad scientist in a dungeon laboratory recklessly pursuing some demonic experiment with a world-consuming outcome. In nanotechnology, the idea of grey goo undoubtedly plays into this archetype. What if a scientist were to succeed in making self-replicating nanobots, which on escaping the confines of the laboratory proceeded to consume the entire substance of the earth’s biosphere as they reproduced, ending human and all other life on earth for ever? I think we can all agree that this outcome would be not wholly desirable, and that its perpetrators might fairly be accused of irresponsibility. But we should also ask ourselves how likely such a scenario is. I think it is very unlikely in the coming decades, which leaves for me questions about whose purposes are served by this kind of existential risk discourse.
We should worry about the more immediate implications of genetic modification and synthetic biology, for example in their potential to make existing pathogens more dangerous, to recreate historical pathogenic strains, or even to create entirely new ones. Read the rest of this entry »
November 12th, 2014
I have a new post up at the Sheffield Political Economy Research Institute’s blog – Rebuilding the UK’s innovation economy. It’s a more tightly edited version of my earlier post on Soft Machines with the same title.
July 18th, 2014
The UK’s innovation system is currently under-performing; the amount of resource devoted to private sector R&D has been too low compared to competitors for many years, and the situation shows no sign of improving. My last post discussed the changes in the UK economy that have led us to this situation, which contributes to the deep-seated problems of the UK economy of very poor productivity performance and persistent current account deficits. What can we do to improve things? Here I suggest three steps.
1. Stop making things worse.
Firstly, we should recognise the damage that has been done to the countries innovative capacity by the structural shortcomings of our economy and stop making things worse. R&D capacity – including private sector R&D – is a national asset, and we should try and correct the perverse incentives that lead to its destruction. Read the rest of this entry »
June 24th, 2014
What’s wrong with the UK’s innovation system is not that we don’t have a strong science base, or even that there isn’t the will to connect the science base to the companies and entrepreneurs who might want to use its outputs. The problem is that our economy isn’t assigning enough resource to pulling through the fruits of the science base into technological innovations, the innovation that will create new products and services, bring economic growth, and help solve some of the biggest social problems we face. The primary symptom of the problem is the UK’s very poor performance at business funded research and development R&D. This is the weak link in the UK’s national innovation system, and it is part of a bigger picture of short-termism and under-investment which underlie the UK economy’s serious long-term problems.
For context, it’s worth highlighting two particular features of the UK economy. The first is its very poor productivity growth: currently on one measure (annualised 6 year growth in productivity) we’re seeing the worst peace-time performance for the last 150 years. Without productivity growth, there will be no growth in average living standards, and that’s going to lead to an increasingly sour political scene.
The second is the huge current account deficit, which at 5.4% of GDP is worse than in the crisis years of the mid-1970s. Now, as then, the UK is unable to pay its way in the world. Unlike the 1970′s, though, there’s no immediate political crisis, no humiliating appeals to the IMF for a bail-out. This time round, overseas investors are happy to finance this deficit by buying UK assets. But this isn’t cost-free. An influx of overseas capital is what is currently driving a price bubble for domestic and commercial property in London, severely unbalancing the economy and leading to a growing gulf between the capital and the regions. The assets being bought include the nation’s key infrastructure in energy and transport; there will be an inevitable loss of control and sovereignty as more of this infrastructure falls into overseas ownership. Chinese money will be paying for any new generation of nuclear power stations that will be built; that will give the UK very little leverage in insisting that some of that investment is spent to create jobs in the UK, and it will be paid for by what will effectively be a tax on everyone’s electricity bills, guaranteed for 35 years.
These are long-term problems, and so is the decline in business R&D intensity. The last thirty years has seen this drop from 1.48% in 1981, to 1.09% now (measured as a percentage of GDP) Read the rest of this entry »