Income and output $ Y $ as a function of (a) the capital-intensity $ kappa$, the efficiency of labor $ E $, the labor force $ L $, and the salience of capital accumulation in economic growth $ \theta $; or (b) the capital stock $ K $, the efficiency of labor $ E $, the labor force $ L $, and the capital elasticity of income $ \alpha $:
(1.1) $ Y = \kappa^\theta(EL) = K^{\alpha}(EL)^{1-\alpha} $
with:
(1.2) $ \theta = \alpha/(1-\alpha) $ (and $ \alpha = \theta/(1+\theta) $)
and with:
(1.3) $ \kappa = K/L $.
Capital-stock growth $ g_K $ as a function of the savings-investment share $ s $, income and output $ Y $, and the depreciation rate $ \delta $:
(1.4) $ \frac{dK/dt}{K} = \frac{d\ln(K)}{dt} = g_k = \frac{sY}{K} - \delta $
Efficiency of labor growth $ g $ as a function of the growth rate $ h $ of the useful-ideas stock, and of resource scarcity generated by labor force growth $ n $ in conjunction with an importance-of-ideas-relative-to-resources parameter $ \gamma $:
(1.5) $ \frac{dE/dt}{E} = \frac{d\ln(E)}{dt} = g = h - \frac{n}{\gamma} $
Income per worker (and, when divided by the ratio of the total to the working population, per capita):
(1.6) $ y = \frac{Y}{L} $
Labor force growth n as a function of a population growth elasticity with respect to Malthusian "fitness" $ \beta $, of income devoted to Malthusian "fitness" $ y/\phi $ (where $ \phi $ captures relative expenditure on "luxuries") and of the zero population growth "subsistence" level of income devoted to Malthusian "fitness" $ y^{sub} $:
(1.7) $ \frac{dL/dt}{L} = \frac{d\ln(L)}{dt} = n = \beta \left( \frac{y}{\phi y^{sub}}-1 \right) $
And note that the proportional rate of growth $ g_\kappa $ of capital-intensity $ \kappa $ is:
(1.8) $ \frac{d\ln(\kappa)}{dt} = g_\kappa = g_K - g_Y $
where $ g_Y $ is the proportional growth rate of total income and output $ Y $.
Sometimes we will replace the efficiency-of-labor equation (1.3) by:
(1.5') $ \frac{dE/dt}{E} = \frac{d\ln(E)}{dt} = g $
and the labor-force and population growth equation (1.4) by:
(1.6') $ \frac{dL/dt}{L} = \frac{d\ln(L)}{dt} = n $
These replacements transform the system from Solow-Malthus back to the standard Solow Growth Model.
Here, as always, we do what economists do: ruthlessly simplify. People control resources, and use this resources in ways that respond to incentives, and so the societal system moves forward. Economists write down very simple equations describing this: behavioral relationships (how people act), equilibrium conditions (what people's interactions entail), and identities (adding-up conditions. From those they derive how the societal system should have behaved or be behaving. It goes wrong. So economists then go back and complicate the model, and see what the complication entails. They then iterate, until they believe that they have gotten close enough to say that the final-stage model is a good-enough one.
Thus we start with the Solow Growth Model basic setup: income (and output) $ Y $ as a function of the capital stock $ K $, the labor force $ L $, the efficiency of labor $ E $, and the decreasing-returns parameter $ \alpha $ are determined according to (1.1). Growth rates of the capital stock, the efficiency of labor, and of the labor force are determined according to (1.2), (1.3'), and (1.4'). These entail that the growth rate of $ Y $, income and output, is: as functions of the savings-investment rate $ s $, the population and labor force growth rate $ n $, the efficiency-of-labor growth rate $ g $, and the depreciation rate $ \delta $:
(2.1) $ \frac{d\ln(Y)}{dt} = g_Y = \alpha g_K + (1-\alpha)n + (1-\alpha)g $
Now fix the parameters $ \alpha, \beta, s, g $, and look for a situation in which $ g_\kappa = 0 $: in which the capital stock $ K $ and production $ Y $ are growing at the same rate so that the capital-output ratio $ g_\kappa $ is constant.
Substituting into (2.1):
(2.2) $ g_\kappa = g_K - \left( \alpha g_K + (1-\alpha)n + (1-\alpha)g \right) $
(2.3) $ g_\kappa - g_Y = (1-\alpha)\left( g_K - n - g \right) $
(2.4) $ g_\kappa = (1-\alpha)\left( \frac{sY}{K} - \delta - n - g \right) $
(2.5) $ n + g + \delta = \frac{sY}{K} $ whenever $ g_\kappa = 0 $
(2.6) $ \kappa = \frac{K}{Y} = \frac{s}{n + g + \delta} $ whenever $ g_\kappa = 0 $
So we define the steady-state growth equilibrium capital-output ratio:
(2.7) $ \kappa^* = \left( \frac{K}{Y} \right)^* = \frac{s}{n + g + \delta} $
Recall:
(2.8) $ \ln(Y) = \alpha\ln(K) + (1-\alpha)\left(\ln(E)+\ln(L)\right) $
from that derive:
(2.9) $ \ln(Y) = \alpha\left(\ln(\kappa) + \ln(Y) \right) + (1-\alpha)\left(\ln(E)+\ln(L)\right) $
(2.10) $ (1-\alpha)\ln(Y) = \alpha\ln(\kappa) + (1-\alpha)\left(\ln(E)+\ln(L)\right) $
(2.11) $ \ln(Y) = \left( \frac{\alpha}{1-\alpha} \right)\ln(\kappa) + \ln(L) + \ln(E) $
(2.12) $ \ln \left( \frac{Y}{L} \right) = \left( \frac{\alpha}{1-\alpha} \right)\ln(\kappa) + \ln(E) $
This is where we want to make things simpler by using $ \theta = \alpha/(1-\alpha) $:
(2.13) $ \ln \left( \frac{Y}{L} \right) = \theta\ln(\kappa) + \ln(E) $
And so we define steady-state growth-path production-per-worker as:
(2.14) $ \ln \left( \frac{Y}{L} \right)^* = \theta \ln(\kappa^*) =+ \ln(E) $
(2.15) $ \left(\frac{Y}{L}\right)^* = \left(\kappa^*\right)^\theta E $
(2.16) $ \left(\frac{Y}{L}\right)^* = \left( \frac{s}{n+g+\delta} \right)^\theta E $
(2.17) $ \frac{d}{dt} \left(\frac{Y}{L}\right)^* = g $
Along the steady-state growth path, production per worker $ Y/L $, capital per worker $ K/L $, and the efficiency of labor $ E $ both grow at the proportional rate $ g $; the population and labor force $ L $ grows at the proportional rate $ n $; total production $ Y $ and the capital stock $ K $ grow at the proportional rate $ n + g $; and the capital-output ratio $ \kappa = K/Y $ is constant.
An economy well-modeled by this Solow Growth Model heads for a balanced-growth equilibrium path on which there is a constant balanced-growth capital-output ratio $ \kappa^* = s/(n+g+\delta) $, a constant growth rate $ g $ of income (and production) and the capital stock per worker, a constant growth rate $ n $ of the labor force, and a constant growth rate $ n + g $ of total societal income (and production) and of the total capital stock.
How fast does this economy head for its balanced-growth equilibrium path? Recall (2.4):
(2.4) $ \frac{1}{\kappa}\frac{d\kappa}{dt} = g_\kappa = (1-\alpha)\left( \frac{s}{\kappa} - (n+g+\delta) \right) $
(2.18) $ \frac{d\kappa}{dt} = (1-\alpha)s -(1-\alpha)(n+g+\delta)\kappa $
(2.19) $ \frac{d\kappa}{dt} = -(1-\alpha)(n+g+\delta)(\kappa - \kappa^*) $
We have exponential convergence with a $ 1/e $ time of $ 1/[(1-\alpha)(n+g+\delta)] $.
But this is not the ancient economy. In the ancient economy $ g = 0 $, or is very close. The model is unsatisfactory in that it does not provide an explanation for why $ g $ is near zero. Hence we complicate the model by introducing Malthusian elements.
Now let's complicate the determinants of the efficiency of labor. Let's revert to (1.3): efficiency of labor growth $ g $ is a funciton of the rate $ h $ at which economically useful ideas are generated, but also of the rate of population and labor force growth $ n $ because a higher population makes resources per capita scarce, as determined by an effect-of-resource scarcity parameter $ \gamma $:
(1.3) $ \frac{dE/dt}{E} = \frac{d\ln(E)}{dt} = g = h - \frac{n}{\gamma} $
Thus:
(3.1) $ \frac{d}{dt} \left(\frac{Y}{L}\right)^* = 0 $ whenever $ h - \frac{n}{\gamma} = 0 $
(3.2) $ n^{*mal} = \gamma h $ is the population growth rate at which $ \frac{d}{dt} \left(\frac{Y}{L}\right)^* = 0 $
When population is growing at the rate $ n^{*mal} $, the efficiency of labor—and thus the steady-state growth-path level of production per worker $ Y/L $—is constant.
Now let's revert to (1.5): make the rate of growth of the population and labor force depend on the level of prosperity $ y = Y/L $; on the "subsistence" standard of living for necessities $y^{sub} $; and also on the fraction $ 1/\phi $ of production that is devoted to necessities, not conveniences and luxuries, and thus enters into reproductive and survival fitness:
(1.5) $ \frac{dL/dt}{L} = \frac{d\ln(L)}{dt} = n = \beta \left( \frac{y}{\phi y^{sub}}-1 \right) $
Then for population to be growing at its Malthusian rate:
(3.3) $ \gamma h = \beta \left(\frac{1}{\phi}\right) \left( \frac{y}{y^{sub}}- \phi \right) $
(3.4) $ \frac{\phi \gamma h}{\beta} = \left( \frac{y}{y^{sub}}- \phi \right) $
(3.5) $ \frac{y}{y^{sub}} = \phi \left( 1 + \frac{\gamma h}{\beta} \right) $
(3.6) $ y^{*mal} = \phi y^{sub} \left( 1 + \frac{ n^{*mal}}{\beta}\right) = \phi y^{sub} \left( 1 + \frac{ \gamma h}{\beta}\right) $
We can determine the log level $ E $ of the efficiency of labor:
(3.7) $ \ln(E) = \ln(H) - \frac{\ln(L)}{\gamma} $
Recall (24):
(2.16) $ y^* = \left( \frac{s}{n+g+\delta} \right)^\theta E $
Then:
(3.8) $ y^{*mal} = \left( \frac{s}{\gamma h +\delta} \right)^\theta E $
(3.9) $ \ln(\phi) + \ln\left( y^{sub} \right) + \ln\left(1 + \frac{\gamma h}{\beta} \right) = \theta \ln(s) - \theta \ln(\gamma h +\delta) + \ln(E) $
(3.10) $ \ln(y^{sub}) = \theta \ln(s) - \theta \ln(\gamma h +\delta) + \ln(H_t) - \frac{\ln(L_t)}{\gamma} - \ln(\phi) - \ln\left(1 + \frac{\gamma h}{\beta} \right) $
(3.11) $ \frac{\ln(L_t)}{\gamma} = \theta \ln(s) - \theta \ln(\gamma h +\delta) + \ln(H_t) - \ln(\phi) - \ln( y^{sub}) -ln\left(1 + \frac{\gamma h}{\beta} \right) $
Thus the population and labor force in the full Malthusian equilibrium will be:
(3.12) $ \ln(L_t^{*mal}) = \gamma \left[ \theta \ln(s) - \theta \ln(\gamma h +\delta) + \ln(H_t) - \ln(\phi) - \ln( y^{sub}) -ln\left(1 + \frac{\gamma h}{\beta} \right) \right] $
It might be worthwhile decomposing this into terms depending on: (1) the level and rate of growth of the stock of ideas; (2) the rule of law and thrift that drive investment; (3) luxuries (including urbanization and elites); and demography in form of sociological (and law-and-order) determinants of "subsistence":
(3.13) $ \ln(L_t^{*mal}) = \gamma \left[ \ln(H_t) - \ln( y^{sub}) \right] + \gamma \theta \left( \ln(s) - \ln(\delta) \right) - \gamma \ln(\phi) + \left( - \gamma \theta \ln(1 + \gamma h/\delta) -\gamma ln\left(1 + \frac{\gamma h}{\beta} \right) \right) $
or:
(3.14) $ L_t^{*mal} = \left[ \left( \frac{H_t}{y^{sub}} \right) \left( \frac{s}{\delta} \right)^\theta \left( \frac{1}{\phi} \right) \left[ \frac{1}{(1+\gamma h/\delta)^\theta} \frac{1}{(1+\gamma h/\beta)} \right] \right]^\gamma $
And recall the Malthusian equilibrium standard of living:
(3.8) $ y^{*mal} = \phi y^{sub} \left( 1 + \frac{ \gamma h}{\beta}\right) $
Plus for the rate of population growth:
(3.2) $ n^{*mal} = \gamma h $
Thus we have our equilibrium for the pre-industrial Malthusian economy:
Start with the rate $ h $ at which new economically-useful ideas are being generated and with the responsiveness $ \beta $ of population growth to increased prosperity.
From those derive the Malthusian rate of population growth: $ n^{*mal} = \gamma h $
Then the Malthusian standard of living is: $ y^{*mal} = \phi y^{sub} \left( 1 + \frac{ \gamma h}{\beta}\right) $
The Malthusian equilibrium standard of living is:
Production per worker and thus prosperity is determined by (a) true subsistence, (b) the wedge between prosperity and reproductive fitness produced by spending on conveniences and luxuries that do not impact reproductive success, and (c) the wedge above subsistence needed to generate population growth consonant with the advance of knowledge and population pressure's generation of resource scarcity.
At any date t, the Malthusian-equilibrium population is:
the current level $ H_t $ of the valuable ideas stock divided by the (sociologically determined, by, for example western European delayed female marriage patterns, or lineage-family control of reproduction by clan heads) Malthusian-subsistence income level $ y^{sub} $ consistent with a stable population on average, times
the ratio between the savings-investment rate $ s $ and the depreciation rate $ \delta $, raised to the parameter $ \theta $ which governs how much an increase in the capital-output ratio raises income—with a higher $ \theta $ the rule of law, imperial peace, and a culture of thrift and invetment matter more, and can generate "efflorescences"—times
one over the conveniences-and-luxuries parameter $ \phi $—it drives a wedge between prosperity and subsistence as spending is diverted categories that do not affect reproduction, such as middle-class luxuries, upper-class luxuries, but also the "luxury" of having an upper class, and the additional conveniences of living in cities and having trade networks that can spread plagues—times
two nuisance terms near zero, which depend on how much the level of population must fall below the true subsistence level at which population growth averages zero to generate the (small) average population growth rate that produces growing resource scarcity that offsets the (small) rate of growth of useful ideas. all this
raised to the power $ \gamma $ that describes how much more important ideas are than resources in generating human income and production.
(1) is the level of the stock of useful ideas relative to the requirements for subsistence. (2) depends on how the rule of law and the rewards to thrift and entrepeneurship drive savings and investment, and thus the divisio of labor. (3) depends on how society diverts itself from nutrition and related activities that aim at boosting reproductive fitness and, instead, devotes itself to conveniences and luxuries—including the "luxury" of having an upper class, and all the conveniences of urban life. (4) are constant, and are small. And (5) governs how productive potential is translated into resource scarcity-generating population under Malthusian conditions.
And the Malthusian-equilibrium population and labor force is growing at the rate $ n^{*mal} = \gamma h $.
Recall:
(1.7) $ \frac{dL/dt}{L} = \frac{d\ln(L)}{dt} = n = \beta \left( \frac{y}{\phi y^{sub}}-1 \right) $
(2.14) $ \ln(y) = \theta\ln(\kappa) + \ln(H) -\ln(L)/\gamma $
Substitute:
(4.1) $ \frac{1}{L}\frac{dL}{dt} = \frac{d\ln(L)}{dt} = n = \beta \left( \frac{\kappa^\theta H L^{-\gamma}}{\phi y^{sub}}-1 \right) $
(4.2) $ \frac{d\kappa}{dt} = -(1-\alpha)(h + (1-1/\gamma)n +\delta)\kappa + (1-\alpha)s $
Define ideas-adjusted-for-population $ I $:
(4.3) $ I = H L^{-1/\gamma} $
(4.4) $ i = h - n/\gamma $
(4.5) $ \frac{d\kappa}{dt} = -(1-\alpha)(\gamma h - (\gamma-1)i +\delta)\kappa + (1-\alpha)s $
(4.6) $ \frac{d\kappa}{dt} = (1-\alpha)s -(1-\alpha)(\gamma h +\delta)\kappa + (1-\alpha) (\gamma-1)i\kappa $
(4.7) $ \frac{1}{I}\frac{dI}{dt} = i = h - n/\gamma = h - \frac{\beta}{\gamma} \left( \frac{\kappa^\theta I}{\phi y^{sub}}-1 \right) $
Then we have two state variables—capital-intensity $ \kappa $, the capital-output ratio, and ideas-adjusted-for-population $ I $. We have two dynamic equations: The rate of change of ideas-adjusted-for-population $ I $ is a function of the capital-output ratio and itself. And the rate of change of capital-intensity $ \kappa $ is a function of itself and of the rate of change of ideas-adjusted-for-population $ I $.
The steady state is then:
(4.8) $ I^{*mal} = \frac{H}{L^{1/\gamma}} = \phi y^{sub}\left(\frac{\delta}{s}\right)^{\theta}\left(1+ \frac{\gamma h}{\delta}\right)^{\theta}\left( 1 + \gamma h/\beta \right) $
(4.9) $ \kappa^{*mal} = \frac{s}{\gamma h + \delta} $
Define:
(4.10) $ I = (1 + \xi) I^{*mal} $
(4.11) $ \kappa = (1 + k) \kappa^{*mal} = (1 + k) (s/(\delta + \gamma h)) $
(4.12) $ \frac{1}{1 + \xi}\frac{d\xi}{dt} = h - \frac{\beta}{\gamma} \left( \frac{(1+k)^\theta\left(\kappa^{*mal}\right)^\theta (1+\xi) I^{*mal}}{\phi y^{sub}}-1 \right) $
(4.13) $ \frac{1}{1+\xi}\frac{d\xi}{dt} = i = h - \frac{\beta}{\gamma} \left(( 1 + \gamma h/\beta )(1+k)^\theta (1+\xi) - 1 \right) $
(4.14) $ \frac{1}{1+\xi}\frac{d\xi}{dt} = i = h - \left(( h + \frac{\beta}{\gamma})(1+k)^\theta (1+\xi) - \frac{\beta}{\gamma} \right) $
Using the approximation:
$ 1 + \theta k = (1+k)^{\theta} $
(4.15) $ \frac{1}{1+\xi}\frac{d\xi}{dt} = h - h - \frac{\beta}{\gamma} - h \theta k - \frac{\theta \beta}{\gamma}k - h \xi - \frac{ \beta}{\gamma}\xi + \frac{\beta}{\gamma} $
(4.16) $ \frac{d\xi}{dt} = \left[ h - h - \frac{\beta}{\gamma} - h \theta k - \frac{\theta \beta}{\gamma}k - h \xi - \frac{ \beta}{\gamma}\xi + \frac{\beta}{\gamma} \right](1+\xi) $
(4.17) $ \frac{d\xi}{dt} = -(h \theta + \theta \beta / \gamma)k - (h + \beta/\gamma)\xi $
This is our linearized exponential-convergence equation for the deviation of ideas-adjusted-for-the-population $ \xi $.
Now on to the capital-instensity. Recall:
from our definition of $ k $ we get:
(4.18) $ \frac{d\kappa}{dt} = \frac{dk}{dt}\kappa^{*mal} $
(4.19) $ \kappa^{*mal}\frac{dk}{dt} = (1-\alpha)s -(1-\alpha)(\gamma h +\delta)(1+k)\kappa^{*mal} + (1-\alpha) (\gamma-1)i(1+k)\kappa^{*mal} $
(4.20) $ \kappa^{*mal}\frac{dk}{dt} = (1-\alpha)s -(1-\alpha)(\gamma h +\delta)\kappa^{*mal} -(1-\alpha)(\gamma h +\delta)k\kappa^{*mal} + (1-\alpha) (\gamma-1)i(1+k)\kappa^{*mal} $
(4.21) $ \kappa^{*mal}\frac{dk}{dt} = -(1-\alpha)(\gamma h +\delta)k\kappa^{*mal} + (1-\alpha) (\gamma-1)i(1+k)\kappa^{*mal} $
(4.22) $ \kappa^{*mal}\frac{dk}{dt} = -(1-\alpha)sk - (1-\alpha) (\gamma -1)(h\theta + \theta \beta / \gamma)k + (h + \beta/\gamma)\xi)\kappa^{*mal} $
(4.23) $ \frac{dk}{dt} = -(1-\alpha)(\delta + \gamma h)k - (1-\alpha) (\gamma-1)(h\theta + \theta \beta / \gamma)k - (1-\alpha) (\gamma-1)(h + \beta/\gamma)\xi$
(4.24) $ \frac{dk}{dt} = -(1-\alpha)\left[\delta + \gamma h + (\gamma-1)(h\theta + \theta \beta / \gamma) \right]k - (1-\alpha) (\gamma-1)( h + \beta/\gamma)\xi$
Thus our linearized exponential-convergence system for the deviation of ideas-adjusted-for-the-population $ \xi $ and the deviation of capital-intensity $ k $ from steady-state Malthusian equilibrium is:
(4.24) $ \frac{dk}{dt} = -(1-\alpha)\left[\delta + \gamma h + (\gamma-1)(h\theta + \theta \beta / \gamma) \right]k - (1-\alpha) (\gamma-1)( h + \beta/\gamma)\xi$
(4.17) $ \frac{d\xi}{dt} = -(h \theta + \theta \beta / \gamma)k - (h + \beta/\gamma)\xi $
# DEFINING CLASS MALTHUSIAN
#
# kept in delong_classes
#
# in general use:
# import delong_classes
#
# m = delong_classes.malthusian
#
# memo:
# .__init__ :: initialize
# .update :: calculate the next year's values
# .gen_seq :: return time series of selected variable
# .steady_state ::calculate the steady state
#
# starting parameter values: no technological progress (h=0)
# savings-investment rate (s=0.15) and depreciation rate
# (δ=0.05) so steady-state capital intensity (κ*=3)
import matplotlib.pyplot as plt
%matplotlib inline
import numpy as np
class malthusian:
"""
Implements the Malthusian Model with:
1. population growth
n = β*(y/(ϕ ysub)-1)
2. growth of efficiency-of-labor
g = h-n/γ
"""
def __init__(self,
L = 1, # initial labor force
E = 1/3, # initial efficiency of labor
K = 3.0, # initial capital stock
# determinants of n (population growth):
β = 0.025, # responsiveness of population growth to increased prosperity.
ϕ = 1, # luxuries parameter
ysub = 1, # subsistence level
# determinants of g(efficiency-of-labor growth):
h = 0, # rate at which useful ideas are generated
γ = 2.0, # effect-of-resource scarcity parameter
s = 0.15, # savings-investment rate
α = 0.5, # orientation-of-growth-toward-capital parameter
δ = 0.05, # deprecation rate on capital parameter
):
self.L, self.E, self.K, self.h, self.γ, self.s, self.α, self.δ = L, E, K, h, γ, s, α, δ
self.β, self.ϕ, self.ysub = β, ϕ, ysub
# production (or output)
self.Y = self.K**self.α*(self.E*self.L)**(1-self.α)
self.y = self.Y/self.L
# capital-output ratio
self.κ = self.K/self.Y
# population growth
self.n = self.β*((self.y/(self.ϕ*self.ysub)) - 1)
# growth rate of efficiency-of-labor
self.g = self.h-self.n/self.γ
# store initial data
self.initdata = vars(self).copy()
def update(self):
"Calculate the next year's values"
# unpack parameters
K, s, Y, δ, L, n, E, g, α =self.K, self.s, self.Y, self.δ, self.L, self.n, self.E, self.g, self.α
β, ϕ, ysub, h, γ = self.β, self.ϕ, self.ysub, self.h, self.γ
#update variables
K = s*Y + (1-δ)*K
L = L*np.exp(n)
E = E*np.exp(g)
Y = K**α*(E*L)**(1-α)
y = Y/L
κ = K/Y
n = β*(y/(ϕ*ysub)-1)
g = h-n/γ
#store variables
self.K, self.s, self.Y, self.δ, self.L, self.n, self.E, self.g, self.α = K, s, Y, δ, L, n, E, g, α
self.κ, self.y = κ, y
def gen_seq(self, t, var = 'κ', init = True, log = False):
"Generate and return time series of selected variable. Variable is κ by default."
path = []
# initialize data
if init == True:
for para in self.initdata:
setattr(self, para, self.initdata[para])
for i in range(t):
path.append(vars(self)[var])
self.update()
if log == False:
return path
else:
return np.log(np.asarray(path))
def steady_state(self, disp = True):
"Calculate variable values in the steady state"
#unpack parameters
s, γ, h, δ, ϕ, ysub, β, α= self.s, self.γ, self.h, self.δ, self.ϕ, self.ysub, self.β, self.α
self.mal_κ = s/(γ*h+δ)
# malthusian rate of population growth
self.mal_n = γ*h
# malthusian standard of living
self.mal_y = ϕ*(ysub+γ*h/β)
self.mal_E = self.mal_y*((γ*h+δ)/s)**(α/(1-α))
if display == True:
return(f'steady-state capital-output ratio κ: {self.mal_κ:.2f}')
return(f'Malthusian rate of population growth n: {self.mal_n: .2f}')
return(f'Malthusian standard of living y: {self.mal_y:.2f}')
return(f'steady-state efficiency-of-labor E: {self.mal_E:.2f}')
else:
return(self.mal_κ,self.mal_n,self.mal_y,self.mal_E)
# TESTING THE MALTHUSIAN CLASS
#
# No idea stock growth (h = 0)
import numpy as np
import matplotlib.pyplot as plt
%matplotlib inline
import delong_classes
T = 1000
m_base = delong_classes.malthusian(K=3.0)
m_base.scenario = "base scenario"
m_alt = delong_classes.malthusian(K=3.0)
m_alt.scenario = "alt scenario"
figcontents = {
(0,0):('κ','Capital-Output Ratio', False),
(0,1):('E','Efficiency of Labor', False),
(1,0):('L','Log Labor Force', True),
(1,1):('K','Log Capital Stock', True),
(2,0):('Y','Log Output', True),
(2,1):('y','Output-per-worker', False)
}
num_rows, num_cols = 3,2
fig, axes = plt.subplots(num_rows, num_cols, figsize=(12, 12))
for i in range(num_rows):
for j in range(num_cols):
for m in m_base, m_alt:
lb = f'{m.scenario}: initial κ = {m.initdata["κ"]:.2f}'
axes[i,j].plot(m.gen_seq(T, var = figcontents[i,j][0], log = figcontents[i,j][2]),'o-', lw=2, alpha=0.5, label=lb)
axes[i,j].set(title=figcontents[i,j][1])
# global legend
axes[(0,0)].legend(loc='upper center', bbox_to_anchor=(1.1,1.3))
plt.suptitle('Malthusian Model: Simulation Run', size = 20)
plt.show()
# TESTING THE MALTHUSIAN CLASS
#
# Adding idea stock growth fast enough that
# (with salience of ideas parameter γ=2)
# population will double every 700 years
# (h=0.0005)
#
# Starting the economy at the h=0 steady-state...
import numpy as np
import matplotlib.pyplot as plt
%matplotlib inline
import delong_classes
T = 1000
m_base = delong_classes.malthusian(h=.0005)
m_base.scenario = "base scenario"
m_alt = delong_classes.malthusian(h=.0005)
m_alt.scenario = "alt scenario"
figcontents = {
(0,0):('κ','Capital-Output Ratio', False),
(0,1):('E','Efficiency of Labor', False),
(1,0):('L','Log Labor Force', True),
(1,1):('K','Log Capital Stock', True),
(2,0):('Y','Log Output', True),
(2,1):('y','Output-per-worker', False)
}
num_rows, num_cols = 3,2
fig, axes = plt.subplots(num_rows, num_cols, figsize=(12, 12))
for i in range(num_rows):
for j in range(num_cols):
for m in m_base, m_alt:
lb = f'{m.scenario}: initial κ = {m.initdata["κ"]:.2f}'
axes[i,j].plot(m.gen_seq(T, var = figcontents[i,j][0], log = figcontents[i,j][2]),'o-', lw=2, alpha=0.5, label=lb)
axes[i,j].set(title=figcontents[i,j][1])
# global legend
axes[(0,0)].legend(loc='upper center', bbox_to_anchor=(1.1,1.3))
plt.suptitle('Malthusian Model: Simulation Run', size = 20)
plt.show()
Notice that the steady state is not affected by where we start.
# USEFUL IDEAS GROWTH STOPS IN YEAR 250
#
# h=0.0005 initially, with economy in Malthusian
# steady state
#
#
import numpy as np
import matplotlib.pyplot as plt
%matplotlib inline
import delong_classes
m = delong_classes.malthusian(h=0.0005, E=0.354, K=3.06)
# generate and store sequences before the change:
T1 = 250 # time before change
T2 = 250 # time after change
figcontents = {
(0,0):('κ','Capital-Output Ratio', False),
(0,1):('E','Efficiency of Labor', False),
(1,0):('L','Log Labor Force', True),
(1,1):('K','Log Capital Stock', True),
(2,0):('Y','Log Output', True),
(2,1):('y','Output-per-worker', False)
}
num_rows, num_cols = 3,2
fig, axes = plt.subplots(num_rows, num_cols, figsize=(12, 12))
for i in range(num_rows):
for j in range(num_cols):
for scenario in {'base', 'with shock'}:
seq = m.gen_seq(T1, var = figcontents[i,j][0], log = figcontents[i,j][2])
lb = f'{scenario}'
if scenario == 'with shock':
m.h = 0
seq = np.append(seq, m.gen_seq(T2, var = figcontents[i,j][0], log = figcontents[i,j][2], init = False))
axes[i,j].plot(seq,'o-', lw=2, alpha=0.5, label=lb)
axes[i,j].set(title=figcontents[i,j][1])
axes[(0,0)].legend(loc='upper center', bbox_to_anchor=(1.1,1.3))
plt.suptitle('Malthusian Model: Simulation Run with Negative Ideas Growth Rate Shock in Year 250', size = 18)
plt.show()
# THE COMING OF AN IMPERIAL PEACE IN YEAR 250
#
# an imperial peace raises consumption of luxuries and of
# urbananization, so parameter φ jumps: φ = 1 --> 1.25
# simultaneously, law and order boost savoings-investment,
# so the parameter s jumps: s = 0.15 --> 0.25
import numpy as np
import matplotlib.pyplot as plt
import delong_classes
m = delong_classes.malthusian(h=0.0005, E=0.354, K=3.06)
# generate and store sequences before the change:
T1 = 250 # time before change
T2 = 250 # time after change
figcontents = {
(0,0):('κ','Capital-Output Ratio', False),
(0,1):('E','Efficiency of Labor', False),
(1,0):('L','Log Labor Force', True),
(1,1):('K','Log Capital Stock', True),
(2,0):('Y','Log Output', True),
(2,1):('y','Output-per-worker', False)
}
num_rows, num_cols = 3,2
fig, axes = plt.subplots(num_rows, num_cols, figsize=(12, 12))
for i in range(num_rows):
for j in range(num_cols):
for scenario in {'base', 'with shock'}:
seq = m.gen_seq(T1, var = figcontents[i,j][0], log = figcontents[i,j][2])
lb = f'{scenario}'
if scenario == 'with shock':
m.φ = 1.25
m.s = 0.25
seq = np.append(seq, m.gen_seq(T2, var = figcontents[i,j][0], log = figcontents[i,j][2], init = False))
axes[i,j].plot(seq,'o-', lw=2, alpha=0.5, label=lb)
axes[i,j].set(title=figcontents[i,j][1])
axes[(0,0)].legend(loc='upper center', bbox_to_anchor=(1.1,1.3))
plt.suptitle('Malthusian Model: Simulation Run with Coming of Imperial Peace in Year 250', size = 18)
plt.show()
# greater consumption of luxuries and of urban life initally
# puts downward pressure on the population, but in less than
# a generation the productivity and division-of-labor benefits
# from higher savings-investment more than compensate
#
# the economy heads for an imperial peace steady state with
# higher capital-intensity κ = 3 --> 4.9; a lower efficiency
# of labor due to heightened resource scarcity E = 0.353 --> 0.27,
# and a higher labor force
#
# output per capita rises, overshoots its new steady-state value,
# and peaks about two generations after the coming of the imperial
# peace:
# THE COLLAPSE OF AN EMPIRE IN YEAR 250
#
# an imperial collapse reduces consumption of luxuries
# and of urbananization, so parameter φ falls: φ = 1.25 --> 1;
# simultaneously, the anarchy lowers savoings-investment, so
# the parameter s falls: s = 0.25 --> 0.15
import numpy as np
import matplotlib.pyplot as plt
import delong_classes
m = delong_classes.malthusian(h=0.0005, E=0.27, K=6.5, φ = 1.25, s = 0.25)
# generate and store sequences before the change:
T1 = 250 # time before change
T2 = 250 # time after change
figcontents = {
(0,0):('κ','Capital-Output Ratio', False),
(0,1):('E','Efficiency of Labor', False),
(1,0):('L','Log Labor Force', True),
(1,1):('K','Log Capital Stock', True),
(2,0):('Y','Log Output', True),
(2,1):('y','Output-per-worker', False)
}
num_rows, num_cols = 3,2
fig, axes = plt.subplots(num_rows, num_cols, figsize=(12, 12))
for i in range(num_rows):
for j in range(num_cols):
for scenario in {'base', 'with shock'}:
seq = m.gen_seq(T1, var = figcontents[i,j][0], log = figcontents[i,j][2])
lb = f'{scenario}'
if scenario == 'with shock':
m.φ = 1.0
m.s = 0.15
seq = np.append(seq, m.gen_seq(T2, var = figcontents[i,j][0], log = figcontents[i,j][2], init = False))
axes[i,j].plot(seq,'o-', lw=2, alpha=0.5, label=lb)
axes[i,j].set(title=figcontents[i,j][1])
axes[(0,0)].legend(loc='upper center', bbox_to_anchor=(1.1,1.3))
plt.suptitle('Malthusian Model: Simulation Run with Empire Fall', size = 20)
plt.show()
# the collapse in demand for luxuries and for urban life initally
# allows an upward jump in the population, but in less than
# a generation the productivity and division-of-labor costs
# from lower savings-investment more than compensate
#
# the economy heads for a post-collapse steady state with
# lower capital-intensity κ = 4.9 --> 3 ; a higher efficiency
# of labor due to reduced resource scarcity E = 0.27 --> 0.353,
# and a lower labor force
#
# output per capita falls, undershoots its new steady-state value,
# and troughs out about two generations after the collapse of the
# empire:
The plague decreased the total population (and thus labor force) by 1/3.
# IMPACT OF A PLAGUE IN YEAR 250
#
# the plague carries off 1/3 of the population
#
# the efficiency of labor immediately jumps up
# because of reduced resource scarcity
#
#
import numpy as np
import matplotlib.pyplot as plt
import delong_classes
m = delong_classes.malthusian(h=0.0005, E=0.354, K=3.06)
# generate and store sequences before the change:
T1 = 250 # time before change
T2 = 250 # time after change
figcontents = {
(0,0):('κ','Capital-Output Ratio', False),
(0,1):('E','Efficiency of Labor', False),
(1,0):('L','Log Labor Force', True),
(1,1):('K','Log Capital Stock', True),
(2,0):('Y','Log Output', True),
(2,1):('y','Output-per-worker', False)
}
num_rows, num_cols = 3,2
fig, axes = plt.subplots(num_rows, num_cols, figsize=(12, 12))
for i in range(num_rows):
for j in range(num_cols):
for scenario in {'base', 'with plague'}:
seq = m.gen_seq(T1, var = figcontents[i,j][0], log = figcontents[i,j][2])
lb = f'{scenario}'
if scenario == 'with plague':
m.L = 2/3*m.L
m.E = m.E*(2/3)**(-1/m.γ)
seq = np.append(seq, m.gen_seq(T2, var = figcontents[i,j][0], log = figcontents[i,j][2], init = False))
axes[i,j].plot(seq,'o-', lw=2, alpha=0.5, label=lb)
axes[i,j].set(title=figcontents[i,j][1])
axes[(0,0)].legend(loc='upper center', bbox_to_anchor=(1.1,1.3))
plt.suptitle('Malthusian Model: Simulation Run with Plague in 250', size = 20)
plt.show()
# the population recvoeres about halfway back to steady-state
# in each generation
#
# the dynamics of the capital-intensity show a little bit of
# cyclicality: the capital-output ratio undershoots its steady-
# state value by a bit, and then climbs back up:
To summarize, the shock on idea development will change the steady state and the development path, while a plague would not change the steady state.