b. Suppose that the production function is given by Y = K1/2 N1
1/2. Assume that the size of the
population, the participation rate, and the unemployment rate are all constant.(Should writen mathetically)
i)
Is this production function characterized by constant returns to scale? Explain.
ii) Transform the production function into a relationship between output per worker and capital per
worker.
iii) Derive the steady state level of capital per worker in terms of the saving rate (s) and the
depreciation rate ( δ ).
iv) Derive the equations for steady-state output per worker and steady-state consumption per worker
in terms of s and δ .
v) Let δ= 08.0 and s = 0.16. Calculate the steady-state output per worker, capital per worker, and
consumption per worker.
vi) Let δ= 08.0 and s = 0.32. Calculate the steady-state output per worker, capital per worker, and
consumption per worker.
1 answer
Y' = (λK)^(1/2) (λN)^(1/2)
= λ^(1/2) λ^(1/2) K^(1/2) N^(1/2)
= λK^(1/2) N^(1/2)
= λY
Since Y' = λY, the production function exhibits constant returns to scale.
ii) To transform the production function into a relationship between output per worker (Y/N) and capital per worker (K/N), divide both sides of the production function by N:
(Y/N) = (K/N)^(1/2) N^(1/2)
= (K/N)^(1/2) √N
= (K/N)^(1/2) N^(1/2)
iii) To derive the steady state level of capital per worker (K/N), we set the saving rate (s) equal to the depreciation rate (δ):
s = δ
iv) To derive the equations for steady-state output per worker (Y/N) and steady-state consumption per worker (C/N) in terms of s and δ, we substitute the steady-state capital per worker (K/N) into the production function:
(Y/N) = (K/N)^(1/2) N^(1/2)
= (s/δ)^(1/2) N^(1/2)
Since consumption per worker (C/N) is equal to output per worker minus investment per worker, we have:
(C/N) = (1 - s) (Y/N)
= (1 - s) [(s/δ)^(1/2) N^(1/2)]
v) Given δ = 0.8 and s = 0.16, we can calculate the steady-state output per worker, capital per worker, and consumption per worker:
(Y/N) = (s/δ)^(1/2) N^(1/2)
= (0.16/0.8)^(1/2) N^(1/2)
= (0.2)^(1/2) N^(1/2)
= 0.447N^(1/2)
(K/N) = s/δ
= 0.16/0.8
= 0.2
(C/N) = (1 - s) [(s/δ)^(1/2) N^(1/2)]
= (1 - 0.16) [(0.16/0.8)^(1/2) N^(1/2)]
= 0.84 * 0.2^(1/2) N^(1/2)
= 0.168N^(1/2)
vi) Given δ = 0.8 and s = 0.32, we can calculate the steady-state output per worker, capital per worker, and consumption per worker using the same equations as in part v:
(Y/N) = (s/δ)^(1/2) N^(1/2)
= (0.32/0.8)^(1/2) N^(1/2)
= (0.4)^(1/2) N^(1/2)
= 0.632N^(1/2)
(K/N) = s/δ
= 0.32/0.8
= 0.4
(C/N) = (1 - s) [(s/δ)^(1/2) N^(1/2)]
= (1 - 0.32) [(0.32/0.8)^(1/2) N^(1/2)]
= 0.68 * 0.4^(1/2) N^(1/2)
= 0.272N^(1/2)