General motivation behind the ‘augmented Solow model’ ● Empirical analysis suggests that the elasticity of output Y with respect to capital implied by the Solow model (α ≈ 0.3) is too low to reconcile the model with empirical facts. ● For instance, the speed of convergence predicted by the model is far higher than observed in the data. ‐
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General motivation behind the ‘augmented Solow model’
● Empirical analysis suggests that the elasticity of output Y with respect to capital
implied by the Solow model (α ≈ 0.3) is too low to reconcile the model with
empirical facts.
● For instance, the speed of convergence predicted by the model is far higher than
observed in the data.
‐
The model
Remark:
according to MRW the technology to produce H and K are identical. Both
forms of capital result directly from investment of final output in the
accumulation of stocks.
Net investment in ‘education’ → h hY HsH
Net investment in ‘machinery’ → k kY KsK
Steady state in Solow:
1
1
*( )s
k tn g
1
*( )s
y tn g
1
*( ) ( )s
y t A tn g
1
*( ) ( )s
y t A tn g
log *( ) log ( ) log [ ]1 1
ky t A t n gs
/ / / / /1
kelasticity of y relative to s
Steady state in Augmented Solow:
1 1
*( ) ( ) k hs sy t A tn g n g
log *( ) log ( ) log log [ ]1 1 1
k hy t A t n gs s
/ / / / /1
kelasticity of y relative to s
/ / / / /1
helasticity of y relative to s
Remark: the augmented Solow model is a true generalization of Solow 1956: by
assuming β = 0, the last term vanishes and we are back in the Solow model.
● Countries differ in terms of technology Aj (t) saving rates sk, j and sh, j, and population growth rates nj.
Technology:
jA = εj A where ε is an exogenous technology shock
● This means initial technology jA is assumed uncorrelated to the exogenous
explanatory variables sk and sh .
● Focus on a world in which convergence to steady state has already taken place..
Solow versus H‐Augmented Solow
● the estimated equation for the Solow model is :
, ,log *( ) . log [ ]1 1
k j j t jj t const gy s n
constant = logA + gt is not country specific
country specific technology shocks are captured by the error term
Implied α
Findings on Solow
● As expected, the coefficients of ln(sk) and ln (n + g + ): ‐ have opposite sign
‐ their absolute size is in the same order of magnitude
● The main problem is that the implied α is far too large
● the estimated equation for the H‐augmented Solow model is :
Findings on H‐augmented Solow ● the implied α is now consistent with the evidence α ≈ 0.3
estimate of β is too large ● check predictions following from estimates of α and β against microeconometric evidence of earning and marginal productivity effects of education: ● If markets are competitive as assumed in the model, the marginal productivity effects of education should be reflected by the earnings of educated and non‐ educated workers. ● This provides a way of estimating the size of β from microeconomic evidence ● This check suggests that the MRW estimate of β is too large!
E. Prescott (1998) ● A calibration analysis by Edward Prescott 1998, is based on the ‘augmented Solow model’, and concludes:
1. On the assumption that ‘efficiency’ A is uniform across countries,
the neoclassical model with physical and human capital cannot explain per‐capita income differences as large as those registered between the richest and poorest countries.
2. What we need, it is a theory explaining why the level A of total factor productivity (TFP) differs across countries.
● Prescott’s ‘intangible capital’
Human capital is but one form of ‘intangible capital’ which is largely unmeasured and missing in government statistics. Intangible capital includes not only school training to population in working age, but also on the job training, firm specific learning by doing, organization capital, and various forms of unmeasured R&D investment. Unmeasured investments I in official statistics imply that there is also unmeasured output Y, because Y = C + I . The unconventional part of Prescott’s calibration exercise is addressed at dealing with this problem, but we skip this for simplicity.
Prescott’s argument
ln yj* = costant + (1−α−β)−1[αlnskj + βlnshj – (α + β)ln(n + g +)] +εj (18) ● According to IMF estimates physical capital investment as a share of GDP is about 20% for rich and poor countries after 1960. This implies
that, countries do not differ much in their investment ratios sk.
● To preserve the share sh in a plausible range for rich and poor countries, the burden of the explanation of per‐capita income differences falls on a high elasticity of output with respect to ‘intangible capital’ H, that is a high β.
● Suppose yR = 10 yP and country R and P differ in h (human capital) endowment, but are otherwise identical. In particular, AR = AP, and physical capital stocks per unit of efficiency are identical.
y = Akα hβ
yR / yP = 10 = AkRα hR
β / AkPα hP
β = (hR / hP )β
(hR / hP ) = 10 1 / β
MPHR / MPHP = β kRα hR
β – 1 / βkPα hP
β – 1 = (hR / hP)(β – 1)
MPHR / MPHP = 10(β – 1) / β MPHP / MPHR = 10
(1 − β) / β
MPHP / MPHR = 10(1 − β) / β
● Huge differences in rates of return to human capital are implied by
observed differences in per‐capita income between Rich and Poor, unless
β takes implausibly high values.
● Rates of return would be ‘too high’ in poor countries relative to rich
countries, and inconsistent with ‘the facts’ suggesting that human capital
does not flow from rich to poor, but the other way.
Prescott’s Conclusion:
● The burden of explaining per‐capita income differences must partly fall on understanding why the constant in equation (18) is NOT uniform across countries, that is, what is needed, is a theory of TFP. ● Prescott holds to the basic neoclassical assumption that technical
knowledge is transferable across countries at low cost: International
differences in total factor productivity must be explained through
institutionally based differences in work practices, not in useful
knowledge. These differences affect the level of A…
Why doesn’t capital [and human capital] flow from rich to poor countries?
(R. Lucas, 1990)
● Unlike in MRW, countries are not islands ● Financial capital and human capital flow across countries. ● If we assume that financial and human capital flow where returns are higher, we should expect a tendency towards the equalization of the rates on returns on both forms of capital. ● Neoclassical model with financial flows assumes perfect mobility of financial capital → equalization of rates of returns is instantaneous
● Lucas’ 1990 reply draws upon his 1988 human capital model. It is a two sector AK
model
Lucas 1988 assumes:
‐ Final output Y produced by human and physical capital (no raw labour) ‐ no exogenous technological progress ‐ human capital accumulation equation different from MRW
1
t t tt tu hY K L
(1)
(1 )t tt
u hh (2)
‐ A and are exogenous constants expressing total factor productivities in the output and h sector, respectively.
‐ h is per‐capita human capital ‐ u is fraction of time spent by h in final‐output sector ‐ L is population growing at the exponential rate n
Divide equation (1) by L, and define y = Y/L, k = K/L (capital per worker)
y = kα (uh)(1−α) (3)
(1 )t tt
u hh (3’)
endogenous growth is related to the linear structure of system (3), (3’)
In particular…
gh* = θ(1−u*)
Since human capital production is linear with respect to h input, the
steady state growth rate g* is determined by the steady state fraction of
time (1 u*) spent accumulating h. u* is a endogenous decision variable,