Introduction to Modern Economic Growth contrast equilibrium allocation to the Pareto optimal allocation.. We will start with this latter comparison in the next subsection.. Pareto Optima
Trang 1Introduction to Modern Economic Growth contrast equilibrium allocation to the Pareto optimal allocation We will start with this latter comparison in the next subsection
15.3.4 Pareto Optimal Allocations The analysis of Pareto optimal alloca-tion is very similar to the analysis of optimal growth in Chapter 13 For this reason,
we will present only a sketch of the argument As in that analysis, it is straightfor-ward to see that the social planner would not charge a markup on machines, thus
we have
xSL(ν, t) = pL(t)
1/β
L (1− β)1/β and x
S
H(ν, t) = pH(t)
1/β
H (1− β)1/β . Combining these with the production function and some algebra establish that net output, which can be used for consumption or research, is equal to (see Exercise 15.6):
(15.31) YS(t) = (1− β)−1/ββh
γε¡
NLS(t) L¢σ −1
σ + (1− γ)ε¡
NHS(t) H¢σ −1
σ i
In view of this, the current-value Hamiltonian for the social planner can be written as
H¡
NLS, NHS, ZLS, ZHS, CS, µL, µH¢
= C
S(t)1−θ − 1
1− θ +µL(t) ηLZ
S
L(t)+µH(t) ηHZHS (t) , subject to
CS(t) = (1− β)−1/βh
γε¡
NLS(t) L¢σ −1
σ + (1− γ)ε¡
NHS(t) H¢σ −1
σ i
− ZLS(t)− ZHS (t) The necessary conditions for this problem give the following characterization of the Pareto optimal allocation in this economy
Proposition 15.5 The stationary solution of the Pareto optimal allocation involves relative technologies given by (15.27) as in the decentralized equilibrium The stationary growth rate is higher than the equilibrium growth rate and is given by
gS = 1
θ
³ (1− β)−1/ββ£
(1− γ)ε(ηHH)σ−1+ γε(ηLL)σ−1¤ 1
σ −1
− ρ´
> g∗, where g∗ the BGP a clue brim growth rate given in (15.29)
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