Empirical Applications of “Neoclassical” Growth Models
(The Solow model and the Ramsey-Cass-Koopmans model are
neoclassical)
1. Level differences accounted for by differences in factor accumulation.
i. Savings rates and their determinants
ii. Population growth
2. Growth rate differences mainly a transitory phenomenon.
Countries are in different positions relative to their eventual balanced
growth path (steady-state).
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Empirical focus on two types of questions:
1. Do differences in accumulation account well for differences in per capita
income?
2. Do countries “converge” in terms of either income levels or growth rates?
In order to address these questions, we have to be more explicit about what
is meant by “accumulation”.
So far, endogenous factor accumulation has been limited to saving.
This contributes to the accumulation of physical capital: machines, vehicles,
buildings, etc..
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But people also acquire skills and knowledge
This contributes to the accumulation of human capital.
Human and physical capital differ in a number of ways:
1. Human capital cannot typically be bought and sold.
An implication of this is that it typically cannot be used as collateral for
debt.
2. The two types of capital may “depreciate” differently.
3. Human capital may be more difficult to measure because it is not
observable in the same sense as, say, a factory building.
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Human and physical capital are also alike in some key aspects:
1. Both can be accumulated through investment activities.
2. Both take time to accumulate.
We will think of the primary input to human capital accumulation as time.
Time spent in school or in learning on the job.
• Time in school is time is not spend working and earning income that can
either be consumed or saved.
• Workers who are learning on the job are typically less productive than
regular workers.
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Mankiw, Romer, and Weil (1992):
Add human capital to the Solow model:
Y = Kα(AH)1−α (79)
•: Y , K , A: just as before.
•: H = eψuL: human capital/skilled labour
u: time devoted to acquiring skills
ψ: effectiveness of the schooling function:
ψ =d lnH
du(80)
L: As before; hours devoted to work
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Physical capital is accumulated in the usual way:
K = sKY − dK,
sK : savings rate (rate of capital accumulation)
Proceeding as before:
Y = Kα(AH)1−α
y = kα(Ah)1−α where h = eψu (81)
y =y
Ah= kα (82)
All that has changed is the definition of effective labour units.
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The capital accumulation equation is completely unchanged by the addition
of human capital:
˙k = sK y − (n+ g + d)k (83)
We can again represent the model:
˙k = sK kα − (n+ d+ g)k (84)
Along the balanced growth path k = 0, so we can solve:
sK kα = (n+ d+ g)k (85)
for the steady-state level of capital per unit of effective labour:
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k =
[sK
n+ d+ g
] 1
1−α
(86)
y =
[sK
n+ d+ g
] α
1−α
(87)
y(t) = yhA(t) =
[sK
n+ d+ g
] α
1−α
eψuA0egt (88)
The last equation gives the time path for income per capita along the
balanced growth path.
From it we can see that the growth rate is equal to g (the rate of
technological progress), and that the level of y(t) depends on several
factors:
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1. The parameters α, sK , n, d, and g all have the same effects as in the
basic Solow model.
2. Income per capita is increasing in the initial technology level, A0.
3. Income per capita is increasing in both:
u: the effort devoted to acquiring human capital (schooling time?)
ψ: the effectiveness of that effort (education quality?)
We now want to ask to what extent this model can account for observed
differences in both levels and growth rates across countries.
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It is useful to express variables relative to those of a base country (Jones
uses the U.S.):
y =y
yUS=
[sK
n+g+d
] α
1−α
eψuA(t)[
sUS
K
(n+d+g)US
] α
1−α
(eψu)USA(t)US
(89)
=
[sKx
] α
1−α
hA(t) (90)
where x = n+ d+ g and all variables are measured relative to their U.S.
counterparts.
We now use data on all the variables on the right-hand side of this equation
to construct measures of per capita income relative to that of the U.S. that
are predicted by the model.
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We then compare them to actual per capita income for each of these
countries.
Assumptions:
1. Symmetry across countries except with regard to sK , n, and u.
Differences explained by differences in saving, population growth, and
schooling.
2. α = .33
Physical capital’s share of national income is one-third.
3. g + d = .075, A = 1
Both growth and the state of technology equal across countries.
4. ψ = .1
An additional year of schooling raises a worker’s wage by 10%102
In Figure 3.1:
The main failure is that the model predicts poor countries to be richer than
they actually are.
Perhaps the assumption of equal technology levels across countries has
something to do with this:
Y = Kα(AH)1−α
= Kα(AhL)1−α (91)
y = kα(Ah)1−α (92)
Solve this for A(t):
A(t) =[y
k
] α
α−1 y(t)
h. (93)
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Overall this version of the neoclassical growth model correctly predicts:
1. Countries that accumulate both physical and human capital at a high rate
are relatively rich.
2. Countries that use these inputs productively (that is, have a high level of
technology or total factor productivity) are rich.
But, the model does not explain why these countries accumulate so much
or are so productive.
The main overall problem with the model is that it predicts that poor
countries will be richer than they are.
Another way to look at this is to say that the model over-predicts these
countries levels of total factor productivity.106
Differences in Growth Rates and “Convergence”
According to the model, countries at a low level of per capita income (having
low levels of both physical and human capita) should tend to accumulate
factors quickly and grow at a rapid pace in the short-run.
Over time, they will converge to the rich countries:
1. in growth rates (to the common rate of technological progress, g).
2. in levels conditional on all the parameter differences (as we have seen).
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• Convergence appears to be taking place among the rich countries of the
world (OECD countries).
• But, the poor countries are not catching up to the rich ones.
Poor and rich countries may, however, be converging conditionally. That is,
they may be converging in growth rates and to very different steady-states.
According to the model, a poor country with a low level of k will grow at a
lower rate than a rich country with a high k if it is closer to its steady-state:
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.06
.08
.12
.15
.18
.21
Mar
gina
l pro
duct
and
n+
d+g
1 1.5 2.22 3 4
Capital per unit of effecitve labour (k/A)
Pop. growth, depr., and tech prog. Marginal product 1Marginal Product 2
Growth equals red minus blueThe Solow Model
Another way to look at the issue of convergence is to consider the evolution
of the world-wide income distribution.
By some measures, this suggests convergence; by others it doesn’t
Overall, the neoclassical growth model appears to do a fairly good job of
accounting for differences in both levels of per capita income across
countries and different countries growth experiences.
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Fig. 3.10
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