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Introducing Advanced Macroeconomics: Chapter 3 – first lecture Growth and business cycles CAPITAL ACCUMULATION AND GROWTH: THE BASIC SOLOW MODEL ©The McGraw-Hill Companies, 2005 The basic Solow model • How can a nation become rich, i.e., initiate a growth process leading to higher GDP/consumption per capita in the long run. The basic Solow model provides some first answers: It predicts how the evolution and the long run levels of GDP and consumption per capita depend on structural parameters such as the rate of investment and the growth rate of the labour force. Key elements of the Solow model: • • – – – – In each period output is determined by the supplies of capital and labour through the production function Exogenous savings/investment rate, s, exogenous growth rate of labour force, n, and exogenous depreciation rate, δ. Explicit description of capital accumulation: Kt 1 Kt I t Kt Accumulation of capital is the main driving force for wealth. “Basic” model: No technological progress. ©The McGraw-Hill Companies, 2005 The ”micro world” of the Solow model • • • • Object: Closed economy. Time: A sequence of periods/years, t 0,1, 2,... Agents: Households and firms (and government). Commodities and markets: Output, capital services and labour services (one asset = physical capital). • The market for output: Supply = firms’ output, Yt. Demand from households for consumption and investment = Ct I t . Relative price = 1. – One-sector model: Output can be used either for consumption or for investment. ©The McGraw-Hill Companies, 2005 • The market for capital services: Consumers own the capital stock, K t , and rent its services to firms. Supply of capital services = K ts . Firms’ demand = K td – Relative price (in units of output) for renting one unit of capital for one period: rt = real rental rate for capital. – Real interest rate: t rt , where is the rate of depreciation. Or: rt t . (Alternative interpretation: The firms own the capital, borrow for the purchase of capital at an interest rate of t and bear the cost of depreciation themselfes). – User cost rt t . • Labour market: Households supply = Lt (= the labour force). Demand from firms = Ldt . Relative price: wt = the real wage rate. • Competitive markets: rt and wt adjust to equate supply and demand in all markets full (or natural) utilization of ressources. ©The McGraw-Hill Companies, 2005 The production side • … is modelled as if all production (all of GDP) comes from one profit maximizing firm that produces value added, Yt , from of capital services, K td (machineyears), and labour services, Ldt (man-years), according to the production function: Yt F K td ,Ldt 1. Constant returns to scale: F Ktd , Ldt F Ktd ,Ldt . The replication argument! 2. Positive marginal products: F ' K K d ,Ld 0, F ' L K d ,Ld 0. ©The McGraw-Hill Companies, 2005 3. Marginal products are decreasing in the amount of the factor used: '' '' FKK 0, FLL 0 (diminishing returns) and growing in the amount of the other factor used: '' '' FLK 0, FLK 0 • Profit maximization: Given rt and wt , the firm chooses Yt ,K td and Ldt to: max Yt rt Ktd wt Ldt , s.t . Yt F K td ,Ldt The ususal necessary conditions for an optimum: FK' K td ,Ldt rt , FL' K td ,Ldt wt (These two equations do not determine K td and Lt from given rt and wt , they only determine K td / Ldt ) d ©The McGraw-Hill Companies, 2005 • Competitive market clearing Ktd Kt and Ldt Lt , where K t and Lt are the supplies in period t: FK' Kt ,Lt rt , FL' K t ,Lt wt Since K t and Lt are predetermined in any given period, rt and wt are determined this way. K t and Lt predetermined: what does that mean? ©The McGraw-Hill Companies, 2005 The income distribution rt FK' K t ,Lt rt K t FK' K t ,Lt K t wt FL' K t ,Lt wt Lt FL' K t ,Lt Lt 1. No pure profits. Euler’s rule F Kt ,Lt FK' K t ,Lt K t FL' K t ,Lt Lt 0 2. The functional income distribution ' ' F K ,L K F rt Kt wt Kt K t t t L K t ,Lt Lt and Yt Yt F Kt ,Lt F Kt ,Lt The income share of each factor is the elasticity of the production function with respect to the factor in question. ©The McGraw-Hill Companies, 2005 According to empirics, labour’s share is relatively constant around 2/3 over long periods except for short run fluctuations: Labour’s share of domestic factor incomes ©The McGraw-Hill Companies, 2005 Is there a production function that fulfills all of our assumptions and has fixed output elasticities independently of K t and Lt ? Yes, the Cobb-Douglas production function: F Kt ,Lt Bt Kt L1t , Bt 0, 0 1, where Bt is total-factor-productivity (TFP). Check: It follows that 1 Kt Kt ' rt FK Bt and wt FL 1 Bt Lt Lt rt K t wt Lt and 1 Yt Yt ' The Cobb-Douglas function seems as a realistic long run assumption. We even have reason to believe that 1 / 3. ©The McGraw-Hill Companies, 2005 Households • The number of households in period t is Lt , which is predetermined. Household behaviour: 1. Each supplies one unit of labour inelastically. Total supply Lt . 2. Own the capital stock, K t , which is predetermined in period t . Supply = K t (as long as rt 0 ). 3. The representative household decides Ct given Yt , and hence St Yt Ct . The intertemporal budget constraint: Kt 1 Kt St Kt , 0 1 We assume that the result of the consumer’s considerations is: 4. ”Biology”: St sYt . Lt 1 1 n Lt , n 1 ©The McGraw-Hill Companies, 2005 The complete model Yt BK t L1t 1 Kt rt B Lt Kt wt 1 B Lt St sYt Kt 1 Kt St Kt Lt 1 1 n Lt , • Parameters: B, ,s, and n . NB: No subscript t on B: ”Basic” Solow model. • Endogenous variables: Yt , Kt , Lt , rt , wt and St of which Kt and Lt are state variables: ©The McGraw-Hill Companies, 2005 • Given K0 and L0 the model determines Yt , Kt , Lt ... • Government in the model? Yes, simply interpret St as private plus government savings. • We viewed the capital accumulation equation: Kt 1 Kt St Kt as the household’s budget constraint. ©The McGraw-Hill Companies, 2005 Alternatively: By definition we have that Kt 1 Kt It Kt () The condition for equilibrium in the output market, or the national accounting identity, is: Yt Ct It , and by St Yt .CHence definition: t It St ( ) Combining () and ( ) gives the capital accumulation equation again: s is the savings rate and the investment rate. ©The McGraw-Hill Companies, 2005 Analysing the basic Solow model 1. Define: yt Yt / Lt and kt Kt / Lt . 2. From Yt BK t L1t we get the per capita production function: y Bk , 0 1 t t y k ln y ln y ln k ln k g g Note: t t 1 t t 1 t t ©The McGraw-Hill Companies, 2005 3. Insert St sYt into Kt 1 Kt St Kt to get: Kt 1 Kt sYt 1 Kt 4. Divide by Lt 1 1 n Lt on both sides to find that: kt 1 1 syt 1 kt 1 n 5. Insert yt Bkt to get the transition equation: 1 kt 1 sBk t 1 kt 1 n 6. Subtracting kt from both sides of the transition equation gives the Solow equation: 1 sBkt n kt kt 1 kt 1 n ”technical term” appearing because of discrete time savings per capita syt Replacement investment to compensate for depreciation ©The McGraw-Hill and growth of labour force Companies, 2005 The transition diagram sBk dk 1 t 1 kt t 1 kt 1 sBkt 1 kt . 1 n dkt 1 n ©The McGraw-Hill Companies, 2005 • About the slope, dkt 1 / dkt : – It is everywhere strictly positive – It goes to infinity as kt goes to zero – It goes to 1 / 1 n as kt , and 1 / 1 n 1 n 0 . Indeed we assume that n (realistic!) • The figure shows that kt k in the long run. Hence 1 yt y* B k* , ct c* 1 s y* and rt r* B k * etc. * * • The values k , y etc. define the ”steady state”. * ©The McGraw-Hill Companies, 2005 The Solow diagram 1 kt 1 kt sBkt n kt 1 n (n + )kt sBkt k* kt Why does growth in kt and yt have to stop? Diminishing returns! ©The McGraw-Hill Companies, 2005 Steady state • The long run levels k * , y* etc. depend on parameters. How? What makes a nation rich? • Look at the Solow equation: kt 1 kt 1 sBkt n kt 1 n In steady state kt 1 kt 0. Insert this to find sB k n k * k B * 1 1 y B k * s n * B * 1 1 1 1 s n 1 ©The McGraw-Hill Companies, 2005 • Some sharp predictions of the Solow model: 1 lny* B lns ln n . 1 1 1 * The elasticity of y wrt. s is 1 2 (since we believe 1 that 3 ): an increase in s of 10%, e.g. from 20 to * y 22%, should give an increase in of 5%! 1 1 2 The elasticity of y wrt. n and wrt. B are 1 3 and 1 2 , respectively. Why is the latter not one? Capital accumulation! * • We have reached empirically testable hypotheses! Empirics: ©The McGraw-Hill Companies, 2005 Real GDP per worker against the average investment share across 85 countries ©The McGraw-Hill Companies, 2005 Real GDP per worker against the average annual labour force growth rate across 85 countries ©The McGraw-Hill Companies, 2005