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UPF Macroeconomics I. LECTURE SLIDES SET 6 Professor Antonio Ciccone. Ideas and Economic Growth. Producing output versus ideas. Ideas: non-rival, accumulable input Ideas: may be excludable (patents, secrecy) or not Ideas: producing them lowers current, but increases future output.
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UPF Macroeconomics I LECTURE SLIDES SET 6 Professor Antonio Ciccone
Producing output versus ideas • Ideas: non-rival, accumulable input • Ideas: may be excludable (patents, secrecy) or not • Ideas: producing them lowers current, but increases future output
Producing output versus ideas • Question 1: what is the growth process for a given allocation of inputs between producing output and producing ideas? Characterize the join evolution of ideas and output in the “spirit” of Solow
Producing output versus ideas • Question 2: how much of inputs is allocated to producing ideas in decentralized equilibrium? • Difficulties: • In these models there are at least 3 inputs: capital, labor, and ideas • Holding ideas constant, our “reproduction argument” implies that there are at least constant returns to capital (K) and labor (L) • HENCE, there are increasing returns to K,L, and ideas! • It took quite a while to develop a set of models (“toolbox”) where the decentralized dynamic general equilibrium could be characterized
1. A FRAMEWORK FOR ANALYZING GROWTH WITH RESEARCH AND DEVELOPMENT Quantity of output produced fraction of total capital stock used in production fraction of total labor force used in production taken to be exogenous; in the “spirit” of Solow
= level of technology = stock of ideas ideas: non-rival inputs = new ideas, which are created by using capital, labor, and old ideas in the RESEARCH AND DEVELOPMENT (R&D) process
Production of new ideas • Research and Development (R&D) technology fraction of total capital stock used in R&D fraction of total labor force used in R&D taken to be exogenous; this is in the “spirit” of Solow
Returns to scale to K and L in production of IDEAS could be increasing or decreasing: • DECREASING: replicating inputs could lead to same discoveries being made twice • INCREASING: doubling inputs could lead to more than twice the discoveries because of interactions among researchers (“the whole is more than sum of its parts”)
Also, what is the link between stock of ideas and new ideas? • presumably : OLD ideas are useful for developing new ideas • : doubling stock, doubles discoveries holding inputs L and K constant • : effect of stock of ideas on creation less than proportional • : effect of stock of ideas on creation more than proportional
q=1: ideas keep growing at same rate even if resources allocated to R&D constant • q>1: growth of ideas accelerates when resources allocated to R&D constant • q<1: to keep growth of ideas constant, more and more resources must be allocated to R&D
2. GROWTH WITH RESEARCH AND DEVELOPMENT: THE CASE WITHOUT CAPITAL Quantity of output produced Production of new ideas Population growth (exogenous):
CASE 1: Balanced (constant) growth path
Is the BGP stable? • Graph on the vertical axis against on the horizontal axis • Check that is increasing when below and decreasing when above
Note that implies that a faster population growth n translates into faster growth of ideas in the balanced growth path. Is there empirical support for the positive relationship between n and the long run growth rate? Hard to test as we need long time series for that; but Michael Kremer 1993, QJE used population growth data going back to 1 Million B.C.
Why does an increase in not raise the long run growth rate? • Reason analogous to why increase in savings rate s in the Solow model does not increase long run growth: “Decreasing returns” • Note that yielded • Increase in al increase the short-run growth rate of ideas • But when q<1 we get that maintaining the same growth rate of ideas becomes harder and harder as the stock of idea increases (“fishing out the pond effect”) • In the long-run we get a level effect only The fraction of resources allocated to R&D is IRRELEVANT for long-run growth rate !!
IMPORTANT TO NOTE: Balanced growth path growth rate: • there can only be long run growth of ideas and output if: n>0 • if n=0, there is NO long run growth
R&D and endognous growth • Hence, there can be long run growth even without exogenous technological progress • BUT the growth rate is linked to population growth, which we don’t usually think of as a “policy parameter”
CASE 2: Hence implies ever accelerating growth
In this case, a small increase in ends up having a very large effect on the stock of ideas in the long run An increase in implies • short term increase in growth of ideas (as before) • these additional ideas further increase the growth of ideas when for any future time t, the growth rate will be higher after the increase in
CASE 3: • NOW, there is long run growth even if n=0!!!
3. GROWTH WITH RESEARCH AND DEVELOPMENT: THE CASE WITH CAPITAL Quantity of output produced Production of new ideas
+ standard assumptions of Solow model: • constant savings rate s • constant population growth rate n • no depreciation of capital
CASE 1: (i.e. or ) -ISOCLINE ( ) • Above this line: falls • Below this line: increases
-ISOCLINE ( ) • Above this line: falls • Below this line: increases
DYNAMICS 0
DYNAMICS plus INITIAL CONDITION STARTING POINT 0
Starting point of dynamical system is GIVEN by INITIAL capital, technology, and labor force
IMPORTANT TO NOTE: • there can only be long run growth of ideas, capital, and output if: n>0 • if n=0, there is NO long run growth
CASE 2: • we are interested in whether IN THIS CASE there will be long run growth even if n=0 • hence ALSO assume n=0
-ISOCLINE • HENCE: • The two isoclines lie on top of each other • NOW, there is long run growth even if n=0!!!
Michael Kremer's model "Population Growth and Technological Change One Million B.C. to 1990",Q.J.E. 1993 • Michael Kremer's intuition was that in a Malthusian world, i.e. a world in which population is just big enough to survive, there is a link between the state and technology and the amount of population: If everyone consumes just a "subsistence"amount, societies with more advanced technology (say, better agriculture) will be able to support larger populations • Hence, we could infer from the level of
The framework Assume the following production function: where: • indicates the level of technological progress • is population • is land At least for a pre-industrial society, it may make sense to have only labour and land as production inputs. Note that the production function has constant returns to scale: the replication argument is valid! (ie, double the amounts of input, and you double output)
Malthusian case Now express the production function in per-capita terms: and assume that population increases when is above some subsistence level . This will reduce output per capita, so that it is reasonable to assume - if population growth reacts fast enough - that population will constantly adjust such that always holds.
Malthusian case We can solve for the population level that corresponds to What does it mean? • In the absence of changes in , population will be constant • Ceteris paribus, population will be proportional to land area • If separate regions have different levels of technology , population or population density will be increasing in
Technological progress Now: enter technological progress. Assume that What does this imply for population growth? Take logs and derivatives of and obtain • population will grow at a constant rate. True?
More than exponential growth So population growth appears to be increasing in population. This implies faster than exponential growth, which is what you would achieve with • Why? Key insight: Each person has a constant probability of inventing a new technology. But because "ideas" (insights, designs. . . ) are nonrival, the whole society should profit from it.