Ramsey–Cass–Koopmans model: Difference between revisions
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{{Short description|Neoclassical economic model}} |
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The '''Ramsey–Cass–Koopmans model''', or '''Ramsey growth model''', is a [[Neoclassical economics|neoclassical]] model of [[economic growth]] based primarily on the work of [[Frank P. Ramsey]],<ref>{{cite journal |first=Frank P. |last=Ramsey |title=A Mathematical Theory of Saving |journal=[[Economic Journal]] |volume=38 |issue=152 |year=1928 |pages=543–559 |doi= 10.2307/2224098|jstor=2224098 }}</ref> with significant extensions by [[David Cass]] and [[Tjalling Koopmans]].<ref>{{cite journal |first=David |last=Cass |title=Optimum Growth in an Aggregative Model of Capital Accumulation |journal=[[Review of Economic Studies]] |volume=32 |issue=3 |year=1965 |pages=233–240 |jstor=2295827 |doi=10.2307/2295827 }}</ref><ref>{{cite book |last=Koopmans |first=T. C. |year=1965 |chapter=On the Concept of Optimal Economic Growth |title=The Economic Approach to Development Planning |location=Chicago |publisher=Rand McNally |pages=225–287 }}</ref> The Ramsey–Cass–Koopmans model differs from the [[Solow–Swan model]] in that the choice of [[Consumption (economics)|consumption]] is explicitly [[Microfoundations|microfounded]] at a point in time and so endogenizes the [[saving|savings rate]]. As a result, unlike in the Solow–Swan model, the saving rate may not be constant along the transition to the long run [[steady state]]. Another implication of the model is that the outcome is [[Pareto efficiency|Pareto optimal]] or [[Pareto efficiency|Pareto efficient]].<ref group="note">This result is due not just to the endogeneity of the saving rate but also because of the infinite nature of the planning horizon of the agents in the model; it does not hold in other models with endogenous saving rates but more complex intergenerational dynamics, for example, in [[Paul Samuelson|Samuelson's]] or [[Peter Diamond|Diamond's]] [[overlapping generations model]]s.</ref> |
The '''Ramsey–Cass–Koopmans model''', or '''Ramsey growth model''', is a [[Neoclassical economics|neoclassical]] model of [[economic growth]] based primarily on the work of [[Frank P. Ramsey]],<ref>{{cite journal |first=Frank P. |last=Ramsey |title=A Mathematical Theory of Saving |journal=[[Economic Journal]] |volume=38 |issue=152 |year=1928 |pages=543–559 |doi= 10.2307/2224098|jstor=2224098 }}</ref> with significant extensions by [[David Cass]] and [[Tjalling Koopmans]].<ref>{{cite journal |first=David |last=Cass |title=Optimum Growth in an Aggregative Model of Capital Accumulation |journal=[[Review of Economic Studies]] |volume=32 |issue=3 |year=1965 |pages=233–240 |jstor=2295827 |doi=10.2307/2295827 }}</ref><ref>{{cite book |last=Koopmans |first=T. C. |year=1965 |chapter=On the Concept of Optimal Economic Growth |title=The Economic Approach to Development Planning |location=Chicago |publisher=Rand McNally |pages=225–287 }}</ref> The Ramsey–Cass–Koopmans model differs from the [[Solow–Swan model]] in that the choice of [[Consumption (economics)|consumption]] is explicitly [[Microfoundations|microfounded]] at a point in time and so endogenizes the [[saving|savings rate]]. As a result, unlike in the Solow–Swan model, the saving rate may not be constant along the transition to the long run [[steady state]]. Another implication of the model is that the outcome is [[Pareto efficiency|Pareto optimal]] or [[Pareto efficiency|Pareto efficient]].<ref group="note">This result is due not just to the endogeneity of the saving rate but also because of the infinite nature of the planning horizon of the agents in the model; it does not hold in other models with endogenous saving rates but more complex intergenerational dynamics, for example, in [[Paul Samuelson|Samuelson's]] or [[Peter Diamond|Diamond's]] [[overlapping generations model]]s.</ref> |
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==Mathematical description== |
==Mathematical description== |
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The Ramsey–Cass–Koopmans model starts with an [[aggregate production function]] that satisfies the [[Inada conditions]], often specified to be of [[Cobb–Douglas]] type, <math>F(K, L)</math>, with factors capital <math>K</math> and labour <math>L</math>. Since this production function is assumed to be [[Homogeneous function|homogeneous of degree 1]], one can express it in ''[[per capita]]'' terms, <math>F(K, L) = L\cdot F\left(\frac{K}{L}, 1\right) = L\cdot f(k)</math>. The amount of labour is equal to the population in the economy, and grows at a constant rate <math>n</math>, i.e. <math>L = L_{0} e^{nt}</math> where <math>L_{0} > 0</math> was the population in the initial period. |
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=== Model setup === |
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The first key equation of the Ramsey–Cass–Koopmans model is the state equation for capital accumulation: |
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In the usual setup, time is continuous starting, for simplicity, at <math>t=0</math> and continuing forever. By assumption, the only productive factors are capital <math>K</math> and labour <math>L</math>, both required to be nonnegative. The labour force, which makes up the entire population, is assumed to grow at a constant rate <math>n</math>, i.e. <math>\dot{L} = \tfrac{\mathrm{d} L}{\mathrm{d} t} = nL</math>, implying that <math>L = L_{0} e^{nt}</math> with initial level <math>L_{0} > 0</math> at <math>t = 0</math>. Finally, let <math>Y</math> denote aggregate production, and <math>C</math> denote aggregate consumption. |
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The variables that the Ramsey–Cass–Koopmans model ultimately aims to describe are <math>c = \frac CL</math>, the ''[[per capita]]'' (or more accurately, ''per labour'') consumption, as well as <math>k = \frac KL</math>, the so-called [[capital intensity]]. It does so by first connecting [[capital accumulation]], written <math>\dot{K} = \tfrac{\mathrm{d} K}{\mathrm{d} t}</math> in [[Newton's notation]], with consumption <math>C</math>, describing a consumption-investment trade-off. More specifically, since the existing capital stock decays by depreciation rate <math>\delta</math> (assumed to be constant), it requires [[investment]] of current-period production output <math>Y</math>. Thus, <math display="block">\dot K = Y - \delta K - cL</math> |
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The relationship between the productive factors and aggregate output is described by the [[aggregate production function]], <math>Y = F(K, L)</math>. A common choice is the [[Cobb–Douglas production function]] <math>F(K, L) = AK^{1-\alpha}L^\alpha</math>, but generally any production function satisfying the [[Inada conditions]] is permissible. Importantly, though, <math>F</math> is required to be [[Homogeneous function|homogeneous of degree 1]], which economically implies [[constant returns to scale]]. With this assumption, we can re-express aggregate output in ''per capita'' terms <math display="block">F(K, L) = L\cdot F\left(\frac{K}{L}, 1\right) = L\cdot f(k)</math> For example, if we use the Cobb–Douglas production function with <math>A = 1, \alpha = 0.5</math>, then <math>f(k) = k^{0.5}</math>. |
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a non-linear differential equation akin to the [[Solow–Swan model]], where <math>k</math> is [[capital intensity]] (i.e., [[capital (economics)|capital]] per worker), <math>\dot{k} = \tfrac{\mathrm{d} k}{\mathrm{d} t}</math> is shorthand in [[Newton's notation]] for change in capital intensity over time, <math>c</math> is consumption per worker, <math>f(k)</math> is output per worker for a given <math>k</math>, and <math>\delta\,</math> is the [[Depreciation (economics)|depreciation]] rate of capital. Under the simplifying assumption that there is no population growth, this equation states that [[investment]], or increase in [[capital (economics)|capital]] per worker is that part of output which is not consumed, minus the rate of depreciation of capital. Investment is, therefore, the same as [[saving]]s. |
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To obtain the first key equation of the Ramsey–Cass–Koopmans model, the dynamic equation for the capital stock needs to be expressed in ''per capita'' terms. Noting the [[quotient rule]] for <math>\tfrac{\mathrm{d} }{\mathrm{d} t} \left( \tfrac KL \right)</math>, we have |
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a non-linear differential equation akin to the [[Solow–Swan model]]. |
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=== Maximizing welfare === |
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If we ignore the problem of how consumption is distributed, then the rate of utility <math>U</math> is a function of aggregate consumption. That is, <math>U = U(C, t)</math>. To avoid the problem of infinity, we [[Exponential discounting|exponentially discount]] future utility at a [[Intertemporal choice|discount rate]] <math>\rho \in (0,\infty)</math>. A high <math>\rho</math> reflects high [[time preference|impatience]]. |
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The [[social planner]]'s problem is maximizing the [[social welfare function]] <math>U_{0} = \int_{0}^{\infty} e^{-\rho t} U(C, t) \, \mathrm{d} t</math>. |
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⚫ | Assume that the economy is populated by identical immortal individuals with unchanging utility functions <math>u(c)</math> (a [[Agent (economics)|representative agent]]), such that the total utility is:<math display="block">U(C, t) = L u(c) = L_{0} e^{nt} u(c)</math>The utility function is assumed to be strictly increasing (i.e., there is no [[Bliss point (economics)|bliss point]]) and concave in <math>c</math>, with <math>\lim_{c \to 0} u_{c} = \infty</math>,<ref group="note">The assumption that <math>\lim_{c \to 0} u_{c} = \infty</math> is in fact crucial for the analysis. If <math>u_{c}(0) < \infty </math>, then for low values of <math> k </math> the optimal value of <math> c </math> is 0 and therefore if <math>k(0)</math> is sufficiently low there exists an initial time interval where <math>\dot{c} = 0</math> even if <math>f_{k} - \delta - \rho > 0 </math>, see {{Cite journal | doi = 10.1017/S1365100519000786| title = New Insights From The Canonical Ramsey–Cass–Koopmans Growth Model| journal = Macroeconomic Dynamics| year = 2019| last1 = Nævdal | first1 = E.| volume = 25| issue = 6| pages = 1569–1577| s2cid = 214268940}}</ref> where <math>u_{c}</math> is [[marginal utility]] of consumption <math>\tfrac{\partial u}{\partial c}</math>. |
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Thus we have the social planner's problem: |
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:<math>\text{subject to} \quad c = f(k) - (n + \delta)k - \dot{k}</math> |
:<math>\text{subject to} \quad c = f(k) - (n + \delta)k - \dot{k}</math> |
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where an initial non-zero capital stock <math>k(0) = k_{0} > 0</math> is given. |
where an initial non-zero capital stock <math>k(0) = k_{0} > 0</math> is given. |
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To ensure that the integral is well-defined, we impose <math>\rho > n</math>. |
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=== Solution === |
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The solution, usually found by using a [[Hamiltonian (control theory)|Hamiltonian function]],<ref group="note">The Hamiltonian for the Ramsey–Cass–Koopmans problem is |
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:<math>H = e^{-\rho t} u(c) + \mu \left[ f(k) - (n + \delta) k - c \right]</math> |
:<math>H = e^{-\rho t} u(c) + \mu \left[ f(k) - (n + \delta) k - c \right]</math> |
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where <math>\mu</math> is the [[Costate equation|costate variable]] usually economically interpreted as the [[shadow price]]. Because the terminal value of <math>k</math> is free but may not be negative, a [[Transversality (mathematics)|transversality condition]] <math>\lim_{t \to \infty} \mu \cdot k = 0</math> similar to the [[Karush–Kuhn–Tucker conditions|Karush–Kuhn–Tucker “complementary slackness” condition]] is required. From the first-order conditions for maximization of the Hamiltonian one can derive the equation of motion for consumption, see {{cite book | |
where <math>\mu</math> is the [[Costate equation|costate variable]] usually economically interpreted as the [[shadow price]]. Because the terminal value of <math>k</math> is free but may not be negative, a [[Transversality (mathematics)|transversality condition]] <math>\lim_{t \to \infty} \mu \cdot k = 0</math> similar to the [[Karush–Kuhn–Tucker conditions|Karush–Kuhn–Tucker “complementary slackness” condition]] is required. From the first-order conditions for maximization of the Hamiltonian one can derive the equation of motion for consumption, see {{cite book |first1=Brian S. |last1=Ferguson |first2=G. C. |last2=Lim |title=Introduction to Dynamic Economic Models |publisher=Manchester University Press |year=1998 |isbn=978-0-7190-4997-2 |pages=174–175 |url=https://books.google.com/books?id=RmCAmgEACAAJ&pg=PA174 |postscript=none }}, or {{cite book |first=Giancarlo |last=Gandolfo |author-link=Giancarlo Gandolfo |title=Economic Dynamics |location=Berlin |publisher=Springer |edition=3rd |year=1996 |isbn=978-3-540-60988-9 |pages=381–384 |url=https://books.google.com/books?id=ZMwXi67nhHQC&pg=PA381 }}</ref><ref group="note">The problem can also be solved with classical [[calculus of variations]] methods, see {{cite book |first1=G. |last1=Hadley |first2=M. C. |last2=Kemp |title=Variational Methods in Economics |location=New York |publisher=Elsevier |year=1971 |isbn=978-0-444-10097-9 |pages=50–71 |url=https://books.google.com/books?id=tqujBQAAQBAJ&pg=PA50 }} |
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</ref> is a |
</ref> is a differential equation that describes the optimal evolution of consumption, |
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{{Equation box 1 |
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which is known as the [[Keynes–Ramsey rule]].<ref>{{cite book |first=Olivier Jean |last=Blanchard |first2=Stanley |last2=Fischer |title=Lectures on Macroeconomics |location=Cambridge |publisher=MIT Press |year=1989 |isbn=978-0-262-02283-5 |pages=41–43 |url=https://www.google.com/books/edition/_/j_zs7htz9moC?hl=en&gbpv=1&pg=PA41 }}</ref> The term <math>f_{k}(k) - \delta</math>, where <math>f_{k}</math> is short-hand notation for the [[marginal product of capital]] <math>\tfrac{\partial f}{\partial k}</math>, reflects the marginal return on [[net investment]]. The expression <math>- \left. u_{c}(c) \right/ c \cdot u_{cc}(c)</math> reflects the [[curvature]] of the utility function; its [[multiplicative inverse|reciprocal]] is known as the (intertemporal) [[elasticity of substitution]] and indicates how much the representative agent wishes to [[Consumption smoothing|smooth consumption]] over time. It is often assumed that this elasticity is a positive constant, i.e. <math>\sigma = - \left. c \cdot u_{cc}(c) \right/ u_{c}(c) > 0</math>. |
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the [[Keynes–Ramsey rule]].<ref>{{cite book |first1=Olivier Jean |last1=Blanchard |first2=Stanley |last2=Fischer |title=Lectures on Macroeconomics |location=Cambridge |publisher=MIT Press |year=1989 |isbn=978-0-262-02283-5 |pages=41–43 |url=https://books.google.com/books?id=j_zs7htz9moC&pg=PA41 }}</ref> |
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The term <math>f_k(k) - \delta - \rho</math>, where <math>f_{k} = \partial_k f</math> is the [[marginal product of capital]], reflects the marginal return on [[net investment]], accounting for capital depreciation and time discounting. |
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Here <math>\sigma(c)</math> is the [[elasticity of intertemporal substitution]], defined by<math display="block">\sigma(c) = - \frac{u_{c}(c)}{c \cdot u_{cc}(c)} = - \frac{d\ln c}{d\ln (u'(c))}</math>It is formally equivalent to the inverse of [[relative risk aversion]]. The quantity reflects the [[curvature]] of the utility function and indicates how much the representative agent wishes to [[Consumption smoothing|smooth consumption]] over time. If the agent has high relative risk aversion, then it has low EIS, and thus would be more willing to smooth consumption over time. |
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It is often assumed that <math>u</math> is strictly monotonically increasing and concave, thus <math>\sigma > 0</math>. In particular, if utility is logarithmic, then it is constant:<math display="block">u(c) = u_0 \ln c \implies \sigma(c) = 1 </math>We can rewrite the Ramsey rule as<math display="block">\underbrace{\frac{d}{dt} \ln c}_{\text{consumption delay rate}} = |
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\underbrace{\sigma(c)}_{\text{EIS at current consumption level}\quad} |
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\underbrace{[f_k(k) - \delta - \rho]}_{\text{marginal return on net investment}}</math>where we interpret <math>\frac{d}{dt}\ln c</math> as the "consumption delay rate", because if it is high, then it means the agent is consuming a lot less now compared to later, which is essentially what delayed consumption is about. |
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=== Graphical analysis in phase space === |
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[[File:Phase_diagram_of_the_Ramsey_model.svg|thumb|Phase diagram of the Ramsey model, for the case of <math>f(k) = k^{0.5}</math>, and <math>n, \delta, \rho, \sigma = 1,1,1.1, 1</math>.]] |
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[[File:Ramseypic.svg|thumb|300px|[[Phase space]] graph (or phase diagram) of the Ramsey model. The blue line represents the dynamic adjustment (or saddle) path of the economy in which all the constraints present in the model are satisfied. It is a stable path of the dynamic system. The red lines represent dynamic paths which are ruled out by the transversality condition. ]] |
[[File:Ramseypic.svg|thumb|300px|[[Phase space]] graph (or phase diagram) of the Ramsey model. The blue line represents the dynamic adjustment (or saddle) path of the economy in which all the constraints present in the model are satisfied. It is a stable path of the dynamic system. The red lines represent dynamic paths which are ruled out by the transversality condition. ]] |
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The two coupled differential equations for <math>k</math> and <math>c</math> form the Ramsey–Cass–Koopmans [[dynamical system]]. |
The two coupled differential equations for <math>k</math> and <math>c</math> form the Ramsey–Cass–Koopmans [[dynamical system]]. |
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{{Equation box 1 |
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|equation = <math>\begin{cases} |
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\dot{k} =f(k) - (n + \delta)k - c\\ |
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\dot{c} = \sigma(c) \left[ f_k(k) - \delta - \rho \right] \cdot c |
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\end{cases}</math> |
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A [[steady state]] <math>(k^{\ast}, c^{\ast})</math> for the system is found by setting <math>\dot k</math> and <math>\dot c</math> equal to zero. There are three solutions: |
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:<math> f_{k} \left( k^{\ast} \right) = \delta + \rho \quad \text{and} \quad c^{\ast} = f \left( k^{\ast} \right) - (n + \delta) k^{\ast}</math> |
:<math> f_{k} \left( k^{\ast} \right) = \delta + \rho \quad \text{and} \quad c^{\ast} = f \left( k^{\ast} \right) - (n + \delta) k^{\ast}</math> |
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:<math>(0, 0)</math> |
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:<math>f(k^*) = (n+\delta) k^*\text{ with }k^* > 0, c^* = 0</math> |
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The first is the only solution in the interior of the upper quadrant. It is a saddle point (as shown below). The second is a repelling point. The third is a degenerate stable equilibrium. |
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By default, the first solution is meant, although the other two solutions are important to keep track of. |
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Any optimal trajectory must follow the dynamical system. However, since the variable <math>c</math> is a control variable, at each capital intensity <math>k</math>, to find its corresponding optimal trajectory, we still need to find its starting consumption rate <math>c(0)</math>. As it turns out, the optimal trajectory is the unique one that converges to the interior equilibrium point. Any other trajectory either converges to the all-saving equilibrium with <math>k^* > 0, c^* = 0</math>, or diverges to <math>k \to 0, c \to \infty</math>, which means that the economy expends all its capital in finite time. Both achieve a lower overall utility than the trajectory towards the interior equilibrium point. |
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A qualitative statement about the [[Stability theory|stability of the solution]] <math>(k^{\ast}, c^{\ast})</math> requires a linearization by a first-order [[Taylor polynomial]] |
A qualitative statement about the [[Stability theory|stability of the solution]] <math>(k^{\ast}, c^{\ast})</math> requires a linearization by a first-order [[Taylor polynomial]] |
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:<math>\begin{bmatrix} \dot{k} \\ \dot{c} \end{bmatrix} \approx \mathbf{J}(k^{\ast}, c^{\ast}) \begin{bmatrix} (k - k^{\ast}) \\ (c - c^{\ast}) \end{bmatrix}</math> |
:<math>\begin{bmatrix} \dot{k} \\ \dot{c} \end{bmatrix} \approx \mathbf{J}(k^{\ast}, c^{\ast}) \begin{bmatrix} (k - k^{\ast}) \\ (c - c^{\ast}) \end{bmatrix}</math> |
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where <math>\mathbf{J}(k^{\ast}, c^{\ast})</math> is the [[Jacobian matrix and determinant|Jacobian matrix]] evaluated at steady state,<ref group="note">The Jacobian matrix of the Ramsey–Cass–Koopmans system is |
where <math>\mathbf{J}(k^{\ast}, c^{\ast})</math> is the [[Jacobian matrix and determinant|Jacobian matrix]] evaluated at steady state,<ref group="note">The Jacobian matrix of the Ramsey–Cass–Koopmans system is |
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:<math>\mathbf{J} \left( k, c \right) = \begin{bmatrix} \frac{\partial \dot{k}}{\partial k} & \frac{\partial \dot{k}}{\partial c} \\ \frac{\partial \dot{c}}{\partial k} & \frac{\partial \dot{c}}{\partial c} \end{bmatrix} = \begin{bmatrix} f_{k}(k) - (n + \delta) & -1 \\ \frac{1}{\sigma} f_{kk}(k) \cdot c & \frac{1}{\sigma} \left[ f_{k}(k) - \delta - \rho \right] \end{bmatrix}</math> |
:<math>\mathbf{J} \left( k, c \right) = \begin{bmatrix} \frac{\partial \dot{k}}{\partial k} & \frac{\partial \dot{k}}{\partial c} \\ \frac{\partial \dot{c}}{\partial k} & \frac{\partial \dot{c}}{\partial c} \end{bmatrix} = \begin{bmatrix} f_{k}(k) - (n + \delta) & -1 \\ \frac{1}{\sigma} f_{kk}(k) \cdot c & \frac{1}{\sigma} \left[ f_{k}(k) - \delta - \rho \right] \end{bmatrix}</math> |
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See {{cite book | |
See {{cite book |first1=Oscar |last1=Afonso |first2=Paulo B. |last2=Vasconcelos |title=Computational Economics : A Concise Introduction |location=New York |publisher=Routledge |year=2016 |page=163 |isbn=978-1-138-85965-4 |url=https://books.google.com/books?id=fN5zCgAAQBAJ&pg=PA163 }}</ref> given by |
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:<math>\mathbf{J} \left( k^{\ast}, c^{\ast} \right) = \begin{bmatrix} \rho - n & -1 \\ \frac{1}{\sigma} f_{kk}(k) \cdot c^{\ast} & 0 \end{bmatrix}</math> |
:<math>\mathbf{J} \left( k^{\ast}, c^{\ast} \right) = \begin{bmatrix} \rho - n & -1 \\ \frac{1}{\sigma} f_{kk}(k) \cdot c^{\ast} & 0 \end{bmatrix}</math> |
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which has [[determinant]] <math>\left| \mathbf{J} \left( k^{\ast}, c^{\ast} \right) \right| = \frac{1}{\sigma} f_{kk}(k) \cdot c^{\ast} < 0</math> since <math>c</math> |
which has [[determinant]] <math>\left| \mathbf{J} \left( k^{\ast}, c^{\ast} \right) \right| = \frac{1}{\sigma} f_{kk}(k) \cdot c^{\ast} < 0</math> since <math>c^* > 0</math> , <math>\sigma</math> is positive by assumption, and <math>f_{kk} < 0</math> since <math>f</math> is [[Concave function|concave]] (Inada condition). Since the determinant equals the product of the [[Eigenvalues and eigenvectors|eigenvalues]], the eigenvalues must be real and opposite in sign.<ref>{{cite book |first1=Brian |last1=Beavis |first2=Ian |last2=Dobbs |title=Optimization and Stability Theory for Economic Analysis |location=New York |publisher=Cambridge University Press |year=1990 |isbn=978-0-521-33605-5 |page=157 |url=https://books.google.com/books?id=L7HMACFgnXMC&pg=PA157 }}</ref> |
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Hence by the [[stable manifold theorem]], the equilibrium is a [[saddle point]] and there exists a unique stable arm, or “saddle path”, that converges on the equilibrium, indicated by the blue curve in the phase diagram. |
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⚫ | The system is called “saddle path stable” since all unstable trajectories are ruled out by the “no [[Ponzi scheme]]” condition:<ref>{{cite book |first1=Terry L. |last1=Roe |first2=Rodney B. W. |last2=Smith |first3=D. Sirin |last3=Saracoglu |title=Multisector Growth Models: Theory and Application |location=New York |publisher=Springer |year=2009 |isbn=978-0-387-77358-2 |page=48 |url=https://books.google.com/books?id=-NzlllN-OAIC&pg=PA48 }}</ref> |
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:<math>\lim_{t \to \infty} k \cdot e^{- \int_{0}^{t} \left( f_{k} - n - \delta \right) \mathrm{d} s } \geq 0</math> |
:<math>\lim_{t \to \infty} k \cdot e^{- \int_{0}^{t} \left( f_{k} - n - \delta \right) \mathrm{d} s } \geq 0</math> |
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implying that the [[present value]] of the capital stock cannot be negative.<ref group="note">It can be shown that the “no Ponzi scheme” condition follows from the transversality condition on the Hamiltonian, see {{cite book |first1= Robert J. |last1= Barro |author-link1=Robert J. Barro |first2= Xavier |author-link2= Xavier Sala-i-Martin |last2= Sala-i-Martin |title=Economic Growth |location=New York |publisher=McGraw-Hill |year=2004 |edition=Second |isbn=978-0-262-02553-9 |url=https:// |
implying that the [[present value]] of the capital stock cannot be negative.<ref group="note">It can be shown that the “no Ponzi scheme” condition follows from the transversality condition on the Hamiltonian, see {{cite book |first1= Robert J. |last1= Barro |author-link1=Robert J. Barro |first2= Xavier |author-link2= Xavier Sala-i-Martin |last2= Sala-i-Martin |title=Economic Growth |location=New York |publisher=McGraw-Hill |year=2004 |edition=Second |isbn=978-0-262-02553-9 |url=https://books.google.com/books?id=jD3ASoSQJ-AC&pg=PA91 |pages=91–92 }}</ref> |
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{{undue|section|date=December 2017}} |
{{undue|section|date=December 2017}} |
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Spear and Young re-examine the history of optimal growth during the 1950s and 1960s,<ref>{{Cite journal | doi = 10.1017/S1365100513000291| title = Optimum Savings and Optimal Growth: The Cass–Malinvaud–Koopmans Nexus| journal = Macroeconomic Dynamics| volume = 18| issue = 1| pages = 215–243| year = 2014| last1 = Spear | first1 = S. E.| last2 = Young | first2 = W.}}</ref> focusing in part on the veracity of the claimed simultaneous and independent development of Cass' "Optimum growth in an aggregative model of capital accumulation" (published in 1965 in the ''[[Review of Economic Studies]]''), and Tjalling Koopman's "On the concept of optimal economic growth" (published in Study Week on the Econometric Approach to Development Planning, 1965, Rome: Pontifical Academy of Science). |
Spear and Young re-examine the history of optimal growth during the 1950s and 1960s,<ref>{{Cite journal | doi = 10.1017/S1365100513000291| title = Optimum Savings and Optimal Growth: The Cass–Malinvaud–Koopmans Nexus| journal = Macroeconomic Dynamics| volume = 18| issue = 1| pages = 215–243| year = 2014| last1 = Spear | first1 = S. E.| last2 = Young | first2 = W.| s2cid = 1340808| url = https://figshare.com/articles/journal_contribution/6707300}}</ref> focusing in part on the veracity of the claimed simultaneous and independent development of Cass' "Optimum growth in an aggregative model of capital accumulation" (published in 1965 in the ''[[Review of Economic Studies]]''), and Tjalling Koopman's "On the concept of optimal economic growth" (published in Study Week on the Econometric Approach to Development Planning, 1965, Rome: Pontifical Academy of Science). |
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Over their lifetimes, neither Cass nor Koopmans ever suggested that their results characterizing optimal growth in the one-sector, continuous-time growth model were anything other than "simultaneous and independent". That the issue of priority ever became a discussion point was due only to the fact that in the published version of Koopmans' work, he cited the chapter from Cass' thesis that later became the ''RES'' paper. In his paper, Koopmans states in a footnote that Cass independently obtained conditions similar to what Koopmans finds, and that Cass also considers the limiting case where the discount rate goes to zero in his paper. For his part, Cass notes that "after the original version of this paper was completed, a very similar analysis by Koopmans came to our attention. We draw on his results in discussing the limiting case, where the effective social discount rate goes to zero". In the interview that Cass gave to ''Macroeconomic Dynamics'', he credits Koopmans with pointing him to Frank Ramsey's previous work, claiming to have been embarrassed not to have known of it, but says nothing to dispel the basic claim that his work and Koopmans' were in fact independent. |
Over their lifetimes, neither Cass nor Koopmans ever suggested that their results characterizing optimal growth in the one-sector, continuous-time growth model were anything other than "simultaneous and independent". That the issue of priority ever became a discussion point was due only to the fact that in the published version of Koopmans' work, he cited the chapter from Cass' thesis that later became the ''RES'' paper. In his paper, Koopmans states in a footnote that Cass independently obtained conditions similar to what Koopmans finds, and that Cass also considers the limiting case where the discount rate goes to zero in his paper. For his part, Cass notes that "after the original version of this paper was completed, a very similar analysis by Koopmans came to our attention. We draw on his results in discussing the limiting case, where the effective social discount rate goes to zero". In the interview that Cass gave to ''Macroeconomic Dynamics'', he credits Koopmans with pointing him to Frank Ramsey's previous work, claiming to have been embarrassed not to have known of it, but says nothing to dispel the basic claim that his work and Koopmans' were in fact independent. |
||
Spear and Young dispute this history, based upon a previously overlooked working paper version of Koopmans' paper,<ref>{{cite |
Spear and Young dispute this history, based upon a previously overlooked working paper version of Koopmans' paper,<ref>{{cite journal |last=Koopmans |first=Tjalling |title=On the Concept of Optimal Economic Growth |journal=Cowles Foundation Discussion Paper 163 |date=December 1963 |url=http://cowles.econ.yale.edu/P/cd/d01b/d0163.pdf }}</ref> which was the basis for Koopmans' oft-cited presentation at a conference held by the [[Pontifical Academy of Sciences]] in October 1963.<ref>{{cite book |last=McKenzie |first=Lionel |author-link=Lionel McKenzie |chapter=Some Early Conferences on Growth Theory |pages=3–18 |title=Essays in Economic Theory, Growth and Labor Markets |editor1-first=George |editor1-last=Bitros |editor2-first=Yannis |editor2-last=Katsoulacos |location=Cheltenham |publisher=Edward Elgar |year=2002 |isbn=978-1-84064-739-6 }}</ref> In this Cowles Discussion paper, there is an error. Koopmans claims in his main result that the Euler equations are both necessary and sufficient to characterize optimal trajectories in the model because any solutions to the Euler equations which do not converge to the optimal steady-state would hit either a zero consumption or zero capital boundary in finite time. This error was apparently presented at the Vatican conference, although at the time of Koopmans' presenting it, no participant commented on the problem. This can be inferred because the discussion after each paper presentation at the Vatican conference is preserved verbatim in the conference volume. |
||
In the Vatican volume discussion following the presentation of a paper by [[Edmond Malinvaud]], the issue does arise because of Malinvaud's explicit inclusion of a so-called "transversality condition" (which Malinvaud calls Condition I) in his paper. At the end of the presentation, Koopmans asks Malinvaud whether it is not the case that Condition I simply guarantees that solutions to the Euler equations that do not converge to the optimal steady-state hit a boundary in finite time. Malinvaud replies that this is not the case, and suggests that Koopmans look at the example with log utility functions and Cobb-Douglas production functions. |
In the Vatican volume discussion following the presentation of a paper by [[Edmond Malinvaud]], the issue does arise because of Malinvaud's explicit inclusion of a so-called "transversality condition" (which Malinvaud calls Condition I) in his paper. At the end of the presentation, Koopmans asks Malinvaud whether it is not the case that Condition I simply guarantees that solutions to the Euler equations that do not converge to the optimal steady-state hit a boundary in finite time. Malinvaud replies that this is not the case, and suggests that Koopmans look at the example with log utility functions and Cobb-Douglas production functions. |
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From the ''Macroeconomic Dynamics'' interview with Cass, it is clear that Koopmans met with Cass' thesis advisor, [[Hirofumi Uzawa]], at the winter meetings of the [[Econometric Society]] in January 1964, where Uzawa advised him that his student [Cass] had solved this problem already. Uzawa must have then provided Koopmans with the copy of Cass' thesis chapter, which he apparently sent along in the guise of the IMSSS Technical Report that Koopmans cited in the published version of his paper. The word "guise" is appropriate here, because the TR number listed in Koopmans' citation would have put the issue date of the report in the early 1950s, which it clearly was not. |
From the ''Macroeconomic Dynamics'' interview with Cass, it is clear that Koopmans met with Cass' thesis advisor, [[Hirofumi Uzawa]], at the winter meetings of the [[Econometric Society]] in January 1964, where Uzawa advised him that his student [Cass] had solved this problem already. Uzawa must have then provided Koopmans with the copy of Cass' thesis chapter, which he apparently sent along in the guise of the IMSSS Technical Report that Koopmans cited in the published version of his paper. The word "guise" is appropriate here, because the TR number listed in Koopmans' citation would have put the issue date of the report in the early 1950s, which it clearly was not. |
||
In the published version of Koopmans' paper, he imposes a new Condition Alpha in addition to the Euler equations, stating that the only admissible trajectories among those satisfying the Euler equations is the one that converges to the optimal steady-state equilibrium of the model. This result is derived in Cass' paper via the imposition of a transversality condition that Cass deduced from relevant sections of a book by [[Lev Pontryagin]].<ref>{{cite book | |
In the published version of Koopmans' paper, he imposes a new Condition Alpha in addition to the Euler equations, stating that the only admissible trajectories among those satisfying the Euler equations is the one that converges to the optimal steady-state equilibrium of the model. This result is derived in Cass' paper via the imposition of a transversality condition that Cass deduced from relevant sections of a book by [[Lev Pontryagin]].<ref>{{cite book |last1=Pontryagin |first1=Lev |last2=Boltyansky |first2=Vladimir |last3=Gamkrelidze |first3=Revaz |last4=Mishchenko |first4=Evgenii |title=The Mathematical Theory of Optimal Processes |location=New York |publisher=John Wiley |year=1962 }}</ref> Spear and Young conjecture that Koopmans took this route because he did not want to appear to be "borrowing" either Malinvaud's or Cass' transversality technology. |
||
Based on this and other examination of Malinvaud's contributions in 1950s—specifically his intuition of the importance of the transversality condition—Spear and Young suggest that the neo-classical growth model might better be called the Ramsey–Malinvaud–Cass model than the established Ramsey–Cass–Koopmans honorific. |
Based on this and other examination of Malinvaud's contributions in 1950s—specifically his intuition of the importance of the transversality condition—Spear and Young suggest that the neo-classical growth model might better be called the Ramsey–Malinvaud–Cass model than the established Ramsey–Cass–Koopmans honorific. |
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==Further reading== |
==Further reading== |
||
* {{cite book |first=Daron |last=Acemoglu|author-link=Daron Acemoglu |chapter=The Neoclassical Growth Model |title=Introduction to Modern Economic Growth |location=Princeton |publisher=Princeton University Press |year=2009 |isbn=978-0-691-13292-1 |chapter-url=https:// |
* {{cite book |first=Daron |last=Acemoglu|author-link=Daron Acemoglu |chapter=The Neoclassical Growth Model |title=Introduction to Modern Economic Growth |location=Princeton |publisher=Princeton University Press |year=2009 |isbn=978-0-691-13292-1 |chapter-url=https://books.google.com/books?id=DsPH5fWNdrsC&pg=PA287 |pages=287–326 }} |
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* {{cite book |first1= Robert J. |last1= Barro |author-link1=Robert J. Barro |first2= Xavier |author-link2= Xavier Sala-i-Martin |last2= Sala-i-Martin |chapter=Growth Models with Consumer Optimization |title=Economic Growth |location=New York |publisher=McGraw-Hill |year=2004 |edition=Second |isbn=978-0-262-02553-9 |chapter-url=https:// |
* {{cite book |first1= Robert J. |last1= Barro |author-link1=Robert J. Barro |first2= Xavier |author-link2= Xavier Sala-i-Martin |last2= Sala-i-Martin |chapter=Growth Models with Consumer Optimization |title=Economic Growth |location=New York |publisher=McGraw-Hill |year=2004 |edition=Second |isbn=978-0-262-02553-9 |chapter-url=https://books.google.com/books?id=jD3ASoSQJ-AC&pg=PA85 |pages=85–142 }} |
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* {{cite book |first=Jean-Pascal |last=Bénassy |author-link=Jean-Pascal Bénassy |chapter=The Ramsey Model |title=Macroeconomic Theory |location=New York |publisher=Oxford University Press |year=2011 |isbn=978-0-19-538771-1 |pages=145–160 |chapter-url=https:// |
* {{cite book |first=Jean-Pascal |last=Bénassy |author-link=Jean-Pascal Bénassy |chapter=The Ramsey Model |title=Macroeconomic Theory |location=New York |publisher=Oxford University Press |year=2011 |isbn=978-0-19-538771-1 |pages=145–160 |chapter-url=https://books.google.com/books?id=8SHtW0BCK2AC&pg=PA145 }} |
||
* {{cite book | |
* {{cite book |first1=Olivier Jean |last1=Blanchard |author-link=Olivier Blanchard |first2=Stanley |last2=Fischer |author-link2=Stanley Fischer |chapter=Consumption and Investment: Basic Infinite Horizon Models |title=Lectures on Macroeconomics |location=Cambridge |publisher=MIT Press |year=1989 |isbn=978-0-262-02283-5 |chapter-url=https://books.google.com/books?id=j_zs7htz9moC&pg=PA37 |pages=37–89 }} |
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* {{cite book |first=Jianjun |last=Miao |author-link=Jianjun Miao |chapter=Neoclassical Growth Models |title=Economic Dynamics in Discrete Time |location=Cambridge |publisher=MIT Press |year=2014 |isbn=978-0-262-02761-8 |chapter-url=https:// |
* {{cite book |first=Jianjun |last=Miao |author-link=Jianjun Miao |chapter=Neoclassical Growth Models |title=Economic Dynamics in Discrete Time |location=Cambridge |publisher=MIT Press |year=2014 |isbn=978-0-262-02761-8 |chapter-url=https://books.google.com/books?id=mByEBAAAQBAJ&pg=PA353 |pages=353–364 }} |
||
* {{cite book | |
* {{cite book |first1=Alfonso |last1=Novales |author-link=Alfonso Novales |first2=Esther |last2=Fernández |first3=Jesús |last3=Ruíz |chapter=Optimal Growth: Continuous Time Analysis |title=Economic Growth: Theory and Numerical Solution Methods |location=Berlin |publisher=Springer |year=2009 |isbn=978-3-540-68665-1 |chapter-url=https://books.google.com/books?id=EpZzFRa3exgC&pg=PA101 |pages=101–154 }} |
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* {{cite book |first=David |last=Romer |author-link=David Romer |chapter=Infinite-Horizon and Overlapping-Generations Models |title=Advanced Macroeconomics |edition=Fourth |location=New York |publisher=McGraw-Hill |year=2011 |pages=49–77 |isbn=978-0-07-351137-5 }} |
* {{cite book |first=David |last=Romer |author-link=David Romer |chapter=Infinite-Horizon and Overlapping-Generations Models |title=Advanced Macroeconomics |edition=Fourth |location=New York |publisher=McGraw-Hill |year=2011 |pages=49–77 |isbn=978-0-07-351137-5 }} |
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{{DEFAULTSORT:Ramsey-Cass-Koopmans model}} |
{{DEFAULTSORT:Ramsey-Cass-Koopmans model}} |
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[[Category:Economics models]] |
[[Category:Economics models]] |
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[[Category:Differential equations]] |
Latest revision as of 21:39, 6 May 2024
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The Ramsey–Cass–Koopmans model, or Ramsey growth model, is a neoclassical model of economic growth based primarily on the work of Frank P. Ramsey,[1] with significant extensions by David Cass and Tjalling Koopmans.[2][3] The Ramsey–Cass–Koopmans model differs from the Solow–Swan model in that the choice of consumption is explicitly microfounded at a point in time and so endogenizes the savings rate. As a result, unlike in the Solow–Swan model, the saving rate may not be constant along the transition to the long run steady state. Another implication of the model is that the outcome is Pareto optimal or Pareto efficient.[note 1]
Originally Ramsey set out the model as a social planner's problem of maximizing levels of consumption over successive generations.[4] Only later was a model adopted by Cass and Koopmans as a description of a decentralized dynamic economy with a representative agent. The Ramsey–Cass–Koopmans model aims only at explaining long-run economic growth rather than business cycle fluctuations, and does not include any sources of disturbances like market imperfections, heterogeneity among households, or exogenous shocks. Subsequent researchers therefore extended the model, allowing for government-purchases shocks, variations in employment, and other sources of disturbances, which is known as real business cycle theory.
Mathematical description
[edit]Model setup
[edit]In the usual setup, time is continuous starting, for simplicity, at and continuing forever. By assumption, the only productive factors are capital and labour , both required to be nonnegative. The labour force, which makes up the entire population, is assumed to grow at a constant rate , i.e. , implying that with initial level at . Finally, let denote aggregate production, and denote aggregate consumption.
The variables that the Ramsey–Cass–Koopmans model ultimately aims to describe are , the per capita (or more accurately, per labour) consumption, as well as , the so-called capital intensity. It does so by first connecting capital accumulation, written in Newton's notation, with consumption , describing a consumption-investment trade-off. More specifically, since the existing capital stock decays by depreciation rate (assumed to be constant), it requires investment of current-period production output . Thus,
The relationship between the productive factors and aggregate output is described by the aggregate production function, . A common choice is the Cobb–Douglas production function , but generally any production function satisfying the Inada conditions is permissible. Importantly, though, is required to be homogeneous of degree 1, which economically implies constant returns to scale. With this assumption, we can re-express aggregate output in per capita terms For example, if we use the Cobb–Douglas production function with , then .
To obtain the first key equation of the Ramsey–Cass–Koopmans model, the dynamic equation for the capital stock needs to be expressed in per capita terms. Noting the quotient rule for , we have
a non-linear differential equation akin to the Solow–Swan model.
Maximizing welfare
[edit]If we ignore the problem of how consumption is distributed, then the rate of utility is a function of aggregate consumption. That is, . To avoid the problem of infinity, we exponentially discount future utility at a discount rate . A high reflects high impatience.
The social planner's problem is maximizing the social welfare function .
Assume that the economy is populated by identical immortal individuals with unchanging utility functions (a representative agent), such that the total utility is:The utility function is assumed to be strictly increasing (i.e., there is no bliss point) and concave in , with ,[note 2] where is marginal utility of consumption .
Thus we have the social planner's problem:
where an initial non-zero capital stock is given.
To ensure that the integral is well-defined, we impose .
Solution
[edit]The solution, usually found by using a Hamiltonian function,[note 3][note 4] is a differential equation that describes the optimal evolution of consumption,
The term , where is the marginal product of capital, reflects the marginal return on net investment, accounting for capital depreciation and time discounting.
Here is the elasticity of intertemporal substitution, defined byIt is formally equivalent to the inverse of relative risk aversion. The quantity reflects the curvature of the utility function and indicates how much the representative agent wishes to smooth consumption over time. If the agent has high relative risk aversion, then it has low EIS, and thus would be more willing to smooth consumption over time.
It is often assumed that is strictly monotonically increasing and concave, thus . In particular, if utility is logarithmic, then it is constant:We can rewrite the Ramsey rule aswhere we interpret as the "consumption delay rate", because if it is high, then it means the agent is consuming a lot less now compared to later, which is essentially what delayed consumption is about.
Graphical analysis in phase space
[edit]The two coupled differential equations for and form the Ramsey–Cass–Koopmans dynamical system.
A steady state for the system is found by setting and equal to zero. There are three solutions:
The first is the only solution in the interior of the upper quadrant. It is a saddle point (as shown below). The second is a repelling point. The third is a degenerate stable equilibrium.
By default, the first solution is meant, although the other two solutions are important to keep track of.
Any optimal trajectory must follow the dynamical system. However, since the variable is a control variable, at each capital intensity , to find its corresponding optimal trajectory, we still need to find its starting consumption rate . As it turns out, the optimal trajectory is the unique one that converges to the interior equilibrium point. Any other trajectory either converges to the all-saving equilibrium with , or diverges to , which means that the economy expends all its capital in finite time. Both achieve a lower overall utility than the trajectory towards the interior equilibrium point.
A qualitative statement about the stability of the solution requires a linearization by a first-order Taylor polynomial
where is the Jacobian matrix evaluated at steady state,[note 5] given by
which has determinant since , is positive by assumption, and since is concave (Inada condition). Since the determinant equals the product of the eigenvalues, the eigenvalues must be real and opposite in sign.[6]
Hence by the stable manifold theorem, the equilibrium is a saddle point and there exists a unique stable arm, or “saddle path”, that converges on the equilibrium, indicated by the blue curve in the phase diagram.
The system is called “saddle path stable” since all unstable trajectories are ruled out by the “no Ponzi scheme” condition:[7]
implying that the present value of the capital stock cannot be negative.[note 6]
History
[edit]This section has multiple issues. Please help improve it or discuss these issues on the talk page. (Learn how and when to remove these messages)
|
Spear and Young re-examine the history of optimal growth during the 1950s and 1960s,[8] focusing in part on the veracity of the claimed simultaneous and independent development of Cass' "Optimum growth in an aggregative model of capital accumulation" (published in 1965 in the Review of Economic Studies), and Tjalling Koopman's "On the concept of optimal economic growth" (published in Study Week on the Econometric Approach to Development Planning, 1965, Rome: Pontifical Academy of Science).
Over their lifetimes, neither Cass nor Koopmans ever suggested that their results characterizing optimal growth in the one-sector, continuous-time growth model were anything other than "simultaneous and independent". That the issue of priority ever became a discussion point was due only to the fact that in the published version of Koopmans' work, he cited the chapter from Cass' thesis that later became the RES paper. In his paper, Koopmans states in a footnote that Cass independently obtained conditions similar to what Koopmans finds, and that Cass also considers the limiting case where the discount rate goes to zero in his paper. For his part, Cass notes that "after the original version of this paper was completed, a very similar analysis by Koopmans came to our attention. We draw on his results in discussing the limiting case, where the effective social discount rate goes to zero". In the interview that Cass gave to Macroeconomic Dynamics, he credits Koopmans with pointing him to Frank Ramsey's previous work, claiming to have been embarrassed not to have known of it, but says nothing to dispel the basic claim that his work and Koopmans' were in fact independent.
Spear and Young dispute this history, based upon a previously overlooked working paper version of Koopmans' paper,[9] which was the basis for Koopmans' oft-cited presentation at a conference held by the Pontifical Academy of Sciences in October 1963.[10] In this Cowles Discussion paper, there is an error. Koopmans claims in his main result that the Euler equations are both necessary and sufficient to characterize optimal trajectories in the model because any solutions to the Euler equations which do not converge to the optimal steady-state would hit either a zero consumption or zero capital boundary in finite time. This error was apparently presented at the Vatican conference, although at the time of Koopmans' presenting it, no participant commented on the problem. This can be inferred because the discussion after each paper presentation at the Vatican conference is preserved verbatim in the conference volume.
In the Vatican volume discussion following the presentation of a paper by Edmond Malinvaud, the issue does arise because of Malinvaud's explicit inclusion of a so-called "transversality condition" (which Malinvaud calls Condition I) in his paper. At the end of the presentation, Koopmans asks Malinvaud whether it is not the case that Condition I simply guarantees that solutions to the Euler equations that do not converge to the optimal steady-state hit a boundary in finite time. Malinvaud replies that this is not the case, and suggests that Koopmans look at the example with log utility functions and Cobb-Douglas production functions.
At this point, Koopmans obviously recognizes he has a problem, but, based on a confusing appendix to a later version of the paper produced after the Vatican conference, he seems unable to decide how to deal with the issue raised by Malinvaud's Condition I.
From the Macroeconomic Dynamics interview with Cass, it is clear that Koopmans met with Cass' thesis advisor, Hirofumi Uzawa, at the winter meetings of the Econometric Society in January 1964, where Uzawa advised him that his student [Cass] had solved this problem already. Uzawa must have then provided Koopmans with the copy of Cass' thesis chapter, which he apparently sent along in the guise of the IMSSS Technical Report that Koopmans cited in the published version of his paper. The word "guise" is appropriate here, because the TR number listed in Koopmans' citation would have put the issue date of the report in the early 1950s, which it clearly was not.
In the published version of Koopmans' paper, he imposes a new Condition Alpha in addition to the Euler equations, stating that the only admissible trajectories among those satisfying the Euler equations is the one that converges to the optimal steady-state equilibrium of the model. This result is derived in Cass' paper via the imposition of a transversality condition that Cass deduced from relevant sections of a book by Lev Pontryagin.[11] Spear and Young conjecture that Koopmans took this route because he did not want to appear to be "borrowing" either Malinvaud's or Cass' transversality technology.
Based on this and other examination of Malinvaud's contributions in 1950s—specifically his intuition of the importance of the transversality condition—Spear and Young suggest that the neo-classical growth model might better be called the Ramsey–Malinvaud–Cass model than the established Ramsey–Cass–Koopmans honorific.
Notes
[edit]- ^ This result is due not just to the endogeneity of the saving rate but also because of the infinite nature of the planning horizon of the agents in the model; it does not hold in other models with endogenous saving rates but more complex intergenerational dynamics, for example, in Samuelson's or Diamond's overlapping generations models.
- ^ The assumption that is in fact crucial for the analysis. If , then for low values of the optimal value of is 0 and therefore if is sufficiently low there exists an initial time interval where even if , see Nævdal, E. (2019). "New Insights From The Canonical Ramsey–Cass–Koopmans Growth Model". Macroeconomic Dynamics. 25 (6): 1569–1577. doi:10.1017/S1365100519000786. S2CID 214268940.
- ^ The Hamiltonian for the Ramsey–Cass–Koopmans problem is
- ^ The problem can also be solved with classical calculus of variations methods, see Hadley, G.; Kemp, M. C. (1971). Variational Methods in Economics. New York: Elsevier. pp. 50–71. ISBN 978-0-444-10097-9.
- ^ The Jacobian matrix of the Ramsey–Cass–Koopmans system is
- ^ It can be shown that the “no Ponzi scheme” condition follows from the transversality condition on the Hamiltonian, see Barro, Robert J.; Sala-i-Martin, Xavier (2004). Economic Growth (Second ed.). New York: McGraw-Hill. pp. 91–92. ISBN 978-0-262-02553-9.
References
[edit]- ^ Ramsey, Frank P. (1928). "A Mathematical Theory of Saving". Economic Journal. 38 (152): 543–559. doi:10.2307/2224098. JSTOR 2224098.
- ^ Cass, David (1965). "Optimum Growth in an Aggregative Model of Capital Accumulation". Review of Economic Studies. 32 (3): 233–240. doi:10.2307/2295827. JSTOR 2295827.
- ^ Koopmans, T. C. (1965). "On the Concept of Optimal Economic Growth". The Economic Approach to Development Planning. Chicago: Rand McNally. pp. 225–287.
- ^ Collard, David A. (2011). "Ramsey, saving and the generations". Generations of Economists. London: Routledge. pp. 256–273. ISBN 978-0-415-56541-7.
- ^ Blanchard, Olivier Jean; Fischer, Stanley (1989). Lectures on Macroeconomics. Cambridge: MIT Press. pp. 41–43. ISBN 978-0-262-02283-5.
- ^ Beavis, Brian; Dobbs, Ian (1990). Optimization and Stability Theory for Economic Analysis. New York: Cambridge University Press. p. 157. ISBN 978-0-521-33605-5.
- ^ Roe, Terry L.; Smith, Rodney B. W.; Saracoglu, D. Sirin (2009). Multisector Growth Models: Theory and Application. New York: Springer. p. 48. ISBN 978-0-387-77358-2.
- ^ Spear, S. E.; Young, W. (2014). "Optimum Savings and Optimal Growth: The Cass–Malinvaud–Koopmans Nexus". Macroeconomic Dynamics. 18 (1): 215–243. doi:10.1017/S1365100513000291. S2CID 1340808.
- ^ Koopmans, Tjalling (December 1963). "On the Concept of Optimal Economic Growth" (PDF). Cowles Foundation Discussion Paper 163.
- ^ McKenzie, Lionel (2002). "Some Early Conferences on Growth Theory". In Bitros, George; Katsoulacos, Yannis (eds.). Essays in Economic Theory, Growth and Labor Markets. Cheltenham: Edward Elgar. pp. 3–18. ISBN 978-1-84064-739-6.
- ^ Pontryagin, Lev; Boltyansky, Vladimir; Gamkrelidze, Revaz; Mishchenko, Evgenii (1962). The Mathematical Theory of Optimal Processes. New York: John Wiley.
Further reading
[edit]- Acemoglu, Daron (2009). "The Neoclassical Growth Model". Introduction to Modern Economic Growth. Princeton: Princeton University Press. pp. 287–326. ISBN 978-0-691-13292-1.
- Barro, Robert J.; Sala-i-Martin, Xavier (2004). "Growth Models with Consumer Optimization". Economic Growth (Second ed.). New York: McGraw-Hill. pp. 85–142. ISBN 978-0-262-02553-9.
- Bénassy, Jean-Pascal (2011). "The Ramsey Model". Macroeconomic Theory. New York: Oxford University Press. pp. 145–160. ISBN 978-0-19-538771-1.
- Blanchard, Olivier Jean; Fischer, Stanley (1989). "Consumption and Investment: Basic Infinite Horizon Models". Lectures on Macroeconomics. Cambridge: MIT Press. pp. 37–89. ISBN 978-0-262-02283-5.
- Miao, Jianjun (2014). "Neoclassical Growth Models". Economic Dynamics in Discrete Time. Cambridge: MIT Press. pp. 353–364. ISBN 978-0-262-02761-8.
- Novales, Alfonso; Fernández, Esther; Ruíz, Jesús (2009). "Optimal Growth: Continuous Time Analysis". Economic Growth: Theory and Numerical Solution Methods. Berlin: Springer. pp. 101–154. ISBN 978-3-540-68665-1.
- Romer, David (2011). "Infinite-Horizon and Overlapping-Generations Models". Advanced Macroeconomics (Fourth ed.). New York: McGraw-Hill. pp. 49–77. ISBN 978-0-07-351137-5.