[slides for Part (b) of this topic here]

1. [slides for Part (b) of this topic here]

2. The golden rule • The golden rule level of capital accumulation k*gold • That level of steady-state capital which implies maximum steady-state consumption c*gold • In this version, given by MPK =  • All golden rule equilibria are steady-states, but... • not all steady-states are golden rules...

3. Solow Growth Model:The golden rule y = c + i y, k, i 0 k

4. Solow Growth Model:The golden rule y = c + i y, k, i y=f(k) 0 k

5. Solow Growth Model:The golden rule y = c + i y, k, i y=f(k) k 0 k

6. Solow Growth Model:The golden rule y = c + i y, k, i y=f(k) k MPK =  0 k k*gold

7. Solow Growth Model:The golden rule y = c + i y, k, i y=f(k) k MPK =  c*gold i*gold 0 k k*gold

8. Solow Growth Model:The golden rule y = c + i y, k, i y=f(k) k y*gold MPK =  c*gold i*gold 0 k k*gold

9. Solow Growth Model:The golden rule y = c + i y, k, i y=f(k) k y*gold MPK =  c*gold i = sgoldf(k) i*gold 0 k k*gold

10. Solow Growth Model:The golden rule y = c + i y, k, i y=f(k) k y*gold MPK =  c*gold i = sgoldf(k) i*gold 0 k k*1 k*gold

11. Solow Growth Model:The golden rule y = c + i y, k, i y=f(k) k y*gold MPK =  c*gold i = sgoldf(k) i*gold 0 k k*1 k*gold

12. Solow Growth Model:The golden rule y = c + i y, k, i y=f(k) k y*gold MPK =  c*gold i = sgoldf(k) c*1 i*gold 0 k k*1 k*gold

13. Solow Growth Model:The golden rule y = c + i y, k, i y=f(k) k y*gold MPK =  c*gold i = sgoldf(k) c*1 i*gold 0 k k*1 k*gold k*2

14. Solow Growth Model:The golden rule y = c + i y, k, i y=f(k) k c*2 y*gold MPK =  c*gold i = sgoldf(k) c*1 i*gold 0 k k*1 k*gold k*2

15. The Golden Rule: policy to get there • k*gold is that steady state k which maximises steady state c • Found where MPK =  • Consider when economy not at k*gold • Economy is dynamically inefficient • Two cases: • k* < k*gold • k* > k*gold • What sort of policy problem does the government face?

16. Getting to the golden rule:either from k*1 or from k*2 y = c + i y, k, i y=f(k) k c*2 y*gold MPK =  c*gold i = sgoldf(k) c*1 i*gold 0 k k*1 k*gold k*2

17. Solow Growth Model: Full Versionpopulation growth + technological change • Y = F(K, AL) • Y output • K capital • L labour • A the efficiency of labour • so AL = the effective labour force • Assume L/L = n • Assume A/A = g • both n and g are exogenous (rather than endogenous)

18. Solow Growth Model: Full Versionpopulation growth + technological change • Define y = Y/(AL) output per unit of effective labour • and k = K/(AL) …ditto for i and for c • Given constant returns to scale • y = f(k) • i = sf(k) • Fundamental equation of capital accumulation: k = i - (+ n + g)k or k = sf(k) - (+ n + g)k

19. Faculty of Arts Public Lecture Series • “In the Shadow of the Market” • Aidan Kane • 8.00pm Wednesday 23rd February • Lecture Hall ML150Millennium Arts Building • Free drink • (sortof)

20. a digression on growth rates • If P and Q grow at rates p and q: • (PQ) grows (approx.) at a rate (p + q) [product] • (P/Q) grows (approx.) at a rate (p - q) [quotient]

21. Solow Growth Model:Steady-state in the full version y, k, i 0 k

22. Solow Growth Model:Steady-state in the full version y, k, i y=f(k) 0 k

23. Solow Growth Model:Steady-state in the full version y, k, i y=f(k) i = sf(k) 0 k

24. Solow Growth Model:Steady-state in the full version y, k, i y=f(k) n + gk i = sf(k) 0 k

25. Solow Growth Model:Steady-state in the full version y, k, i y=f(k) n + gk i = sf(k) 0 k

26. Solow Growth Model:Steady-state in the full version y, k, i y=f(k) n + gk i = sf(k) 0 k k*

27. Solow Growth Model:Steady-state in the full version y, k, i y=f(k) n + gk i = sf(k) 0 k k*

28. Solow Growth Model:Steady-state in the full version y, k, i y=f(k) n + gk y* i = sf(k) 0 k k*

29. Solow growth modelSteady-state in the full version • y = Y/(AL) growing at rate 0 [from graph] • Given that A is growing at rate g.. • and L is growing at rate n [by assumption] • then, AL growing at rate n+g • and Y growing at rate n+g • [i.e. growth in total GDP] • so Y/L growing at rate (n+g)-n = g • i.e. technological progress only source of long-run growth in income per capita

30. The Solow Decomposition • Given constant returns to scale • and  = share of capital in income • Then, growth rate of GDP = • contribution of capital + contribution of labour + technological progress • Y/Y = K/K + (1-)L/L + A/A • Y, K, L,  observable • A/A Solow residual, total factor productivity

31. The Solow Decomposition United States 1960-90 GNP Capital Labour TFP 3.1% 0.9% 1.2% 1.1%

32. Newer models of growth • Failure of convergence hypothesis • Solow model over-simplifies technological progress • This key factor is exogenous to the model • Human capital • Endogenous growth • e.g. externalities • Institutional explanations