In addition to what’s in Anaconda, this lecture will need the following libraries:
!pip install quantecon
This lecture continues our analysis of the linear-quadratic (LQ) permanent income model of savings and consumption.
As we saw in our previous lecture on this topic, Robert Hall [Hall, 1978] used the LQ permanent income model to restrict and interpret intertemporal comovements of nondurable consumption, nonfinancial income, and financial wealth.
For example, we saw how the model asserts that for any covariance stationary process for nonfinancial income
Other applications use the same LQ framework.
For example, a model isomorphic to the LQ permanent income model has been used by Robert Barro [Barro, 1979] to interpret intertemporal comovements of a government’s tax collections, its expenditures net of debt service, and its public debt.
This isomorphism means that in analyzing the LQ permanent income model, we are in effect also analyzing the Barro tax smoothing model.
It is just a matter of appropriately relabeling the variables in Hall’s model.
In this lecture, we’ll
We’ll then use these characterizations to construct a simple model of cross-section wealth and consumption dynamics in the spirit of Truman Bewley [Bewley, 1986].
(Later we’ll study other Bewley models—see this lecture.)
The model will prove useful for illustrating concepts such as
Let’s start with some imports:
import matplotlib.pyplot as plt
plt.rcParams["figure.figsize"] = (11, 5) #set default figure size
import quantecon as qe
import numpy as np
import scipy.linalg as la
Let’s recall the basic features of the model discussed in the permanent income model.
Consumer preferences are ordered by
$$ E_0 \sum_{t=0}^\infty \beta^t u(c_t) \tag{65.1} $$
where $ u(c) = -(c - \gamma)^2 $.
The consumer maximizes (65.1) by choosing a consumption, borrowing plan $ \{c_t, b_{t+1}\}_{t=0}^\infty $ subject to the sequence of budget constraints
$$ c_t + b_t = \frac{1}{1 + r} b_{t+1} + y_t, \quad t \geq 0 \tag{65.2} $$
and the no-Ponzi condition
$$ E_0 \sum_{t=0}^\infty \beta^t b_t^2 < \infty \tag{65.3} $$
The interpretation of all variables and parameters are the same as in the previous lecture.
We continue to assume that $ (1 + r) \beta = 1 $.
The dynamics of $ \{y_t\} $ again follow the linear state space model
$$ \begin{aligned} z_{t+1} & = A z_t + C w_{t+1} \\ y_t & = U z_t \end{aligned} \tag{65.4} $$
The restrictions on the shock process and parameters are the same as in our previous lecture.
The LQ permanent income model of consumption is mathematically isomorphic with a version of Barro’s [Barro, 1979] model of tax smoothing.
In the LQ permanent income model
In the Barro tax smoothing model
If we set
then the two models are mathematically equivalent.
All characterizations of a $ \{c_t, y_t, b_t\} $ in the LQ permanent income model automatically apply to a $ \{T_t, G_t, B_t\} $ process in the Barro model of tax smoothing.
See consumption and tax smoothing models for further exploitation of an isomorphism between consumption and tax smoothing models.
For the purposes of this lecture, let’s assume $ \{y_t\} $ is a second-order univariate autoregressive process:
$$ y_{t+1} = \alpha + \rho_1 y_t + \rho_2 y_{t-1} + \sigma w_{t+1} $$We can map this into the linear state space framework in (65.4), as discussed in our lecture on linear models.
To do so we take
$$ z_t = \begin{bmatrix} 1 \\ y_t \\ y_{t-1} \end{bmatrix}, \quad A = \begin{bmatrix} 1 & 0 & 0 \\ \alpha & \rho_1 & \rho_2 \\ 0 & 1 & 0 \end{bmatrix}, \quad C= \begin{bmatrix} 0 \\ \sigma \\ 0 \end{bmatrix}, \quad \text{and} \quad U = \begin{bmatrix} 0 & 1 & 0 \end{bmatrix} $$Previously we solved the permanent income model by solving a system of linear expectational difference equations subject to two boundary conditions.
Here we solve the same model using LQ methods based on dynamic programming.
After confirming that answers produced by the two methods agree, we apply QuantEcon’s LinearStateSpace class to illustrate features of the model.
Why solve a model in two distinct ways?
Because by doing so we gather insights about the structure of the model.
Our earlier approach based on solving a system of expectational difference equations brought to the fore the role of the consumer’s expectations about future nonfinancial income.
On the other hand, formulating the model in terms of an LQ dynamic programming problem reminds us that
Recall from our lecture on LQ theory that the optimal linear regulator problem is to choose a decision rule for $ u_t $ to minimize
$$ \mathbb E \sum_{t=0}^\infty \beta^t \{x'_t R x_t+ u'_t Q u_t\}, $$subject to $ x_0 $ given and the law of motion
$$ x_{t+1} = \tilde A x_t+ \tilde B u_t+ \tilde C w_{t+1}, \qquad t\geq 0, \tag{65.5} $$
where $ w_{t+1} $ is IID with mean vector zero and $ \mathbb E w_t w'_t= I $.
The tildes in $ \tilde A, \tilde B, \tilde C $ are to avoid clashing with notation in (65.4).
The value function for this problem is $ v(x) = - x'Px - d $, where
The optimal policy is $ u_t = -Fx_t $, where $ F := \beta (Q+\beta \tilde B'P \tilde B)^{-1} \tilde B'P \tilde A $.
Under an optimal decision rule $ F $, the state vector $ x_t $ evolves according to $ x_{t+1} = (\tilde A-\tilde BF) x_t + \tilde C w_{t+1} $.
To map into the LQ framework, we’ll use
$$ x_t := \begin{bmatrix} z_t \\ b_t \end{bmatrix} = \begin{bmatrix} 1 \\ y_t \\ y_{t-1} \\ b_t \end{bmatrix} $$as the state vector and $ u_t := c_t - \gamma $ as the control.
With this notation and $ U_\gamma := \begin{bmatrix} \gamma & 0 & 0 \end{bmatrix} $, we can write the state dynamics as in (65.5) when
$$ \tilde A := \begin{bmatrix} A & 0 \\ (1 + r)(U_\gamma - U) & 1 + r \end{bmatrix} \quad \tilde B := \begin{bmatrix} 0 \\ 1 + r \end{bmatrix} \quad \text{and} \quad \tilde C := \begin{bmatrix} C \\ 0 \end{bmatrix} w_{t+1} $$Please confirm for yourself that, with these definitions, the LQ dynamics (65.5) match the dynamics of $ z_t $ and $ b_t $ described above.
To map utility into the quadratic form $ x_t' R x_t + u_t'Q u_t $ we can set
However, there is one problem remaining.
We have no direct way to capture the non-recursive restriction (65.3) on the debt sequence $ \{b_t\} $ from within the LQ framework.
To try to enforce it, we’re going to use a trick: put a small penalty on $ b_t^2 $ in the criterion function.
In the present setting, this means adding a small entry $ \epsilon > 0 $ in the $ (4,4) $ position of $ R $.
That will induce a (hopefully) small approximation error in the decision rule.
We’ll check whether it really is small numerically soon.
Let’s write some code to solve the model.
One comment before we start is that the bliss level of consumption $ \gamma $ in the utility function has no effect on the optimal decision rule.
We saw this in the previous lecture permanent income.
The reason is that it drops out of the Euler equation for consumption.
In what follows we set it equal to unity.
First, we create the objects for the optimal linear regulator
# Set parameters
α, β, ρ1, ρ2, σ = 10.0, 0.95, 0.9, 0.0, 1.0
R = 1 / β
A = np.array([[1., 0., 0.],
[α, ρ1, ρ2],
[0., 1., 0.]])
C = np.array([[0.], [σ], [0.]])
G = np.array([[0., 1., 0.]])
# Form LinearStateSpace system and pull off steady state moments
μ_z0 = np.array([[1.0], [0.0], [0.0]])
Σ_z0 = np.zeros((3, 3))
Lz = qe.LinearStateSpace(A, C, G, mu_0=μ_z0, Sigma_0=Σ_z0)
μ_z, μ_y, Σ_z, Σ_y, Σ_yx = Lz.stationary_distributions()
# Mean vector of state for the savings problem
mxo = np.vstack([μ_z, 0.0])
# Create stationary covariance matrix of x -- start everyone off at b=0
a1 = np.zeros((3, 1))
aa = np.hstack([Σ_z, a1])
bb = np.zeros((1, 4))
sxo = np.vstack([aa, bb])
# These choices will initialize the state vector of an individual at zero
# debt and the ergodic distribution of the endowment process. Use these to
# create the Bewley economy.
mxbewley = mxo
sxbewley = sxo
The next step is to create the matrices for the LQ system
A12 = np.zeros((3,1))
ALQ_l = np.hstack([A, A12])
ALQ_r = np.array([[0, -R, 0, R]])
ALQ = np.vstack([ALQ_l, ALQ_r])
RLQ = np.array([[0., 0., 0., 0.],
[0., 0., 0., 0.],
[0., 0., 0., 0.],
[0., 0., 0., 1e-9]])
QLQ = np.array([1.0])
BLQ = np.array([0., 0., 0., R]).reshape(4,1)
CLQ = np.array([0., σ, 0., 0.]).reshape(4,1)
β_LQ = β
Let’s print these out and have a look at them
print(f"A = \n {ALQ}")
print(f"B = \n {BLQ}")
print(f"R = \n {RLQ}")
print(f"Q = \n {QLQ}")
Now create the appropriate instance of an LQ model
lqpi = qe.LQ(QLQ, RLQ, ALQ, BLQ, C=CLQ, beta=β_LQ)
We’ll save the implied optimal policy function soon compare them with what we get by employing an alternative solution method
P, F, d = lqpi.stationary_values() # Compute value function and decision rule
ABF = ALQ - BLQ @ F # Form closed loop system
In our first lecture on the infinite horizon permanent income problem we used a different solution method.
The method was based around
Expressed in state space notation, the solution took the form
$$ \begin{aligned} z_{t+1} & = A z_t + C w_{t+1} \\ b_{t+1} & = b_t + U [ (I -\beta A)^{-1} (A - I) ] z_t \\ y_t & = U z_t \\ c_t & = (1-\beta) [ U (I-\beta A)^{-1} z_t - b_t ] \end{aligned} $$Now we’ll apply the formulas in this system
# Use the above formulas to create the optimal policies for b_{t+1} and c_t
b_pol = G @ la.inv(np.eye(3, 3) - β * A) @ (A - np.eye(3, 3))
c_pol = (1 - β) * G @ la.inv(np.eye(3, 3) - β * A)
# Create the A matrix for a LinearStateSpace instance
A_LSS1 = np.vstack([A, b_pol])
A_LSS2 = np.eye(4, 1, -3)
A_LSS = np.hstack([A_LSS1, A_LSS2])
# Create the C matrix for LSS methods
C_LSS = np.vstack([C, np.zeros(1)])
# Create the G matrix for LSS methods
G_LSS1 = np.vstack([G, c_pol])
G_LSS2 = np.vstack([np.zeros(1), -(1 - β)])
G_LSS = np.hstack([G_LSS1, G_LSS2])
# Use the following values to start everyone off at b=0, initial incomes zero
μ_0 = np.array([1., 0., 0., 0.])
Σ_0 = np.zeros((4, 4))
A_LSS calculated as we have here should equal ABF calculated above using the LQ model
ABF - A_LSS
Now compare pertinent elements of c_pol and F
print(c_pol, "\n", -F)
We have verified that the two methods give the same solution.
Now let’s create instances of the LinearStateSpace class and use it to do some interesting experiments.
To do this, we’ll use the outcomes from our second method.
In the spirit of Bewley models [Bewley, 1986], we’ll generate panels of consumers.
The examples differ only in the initial states with which we endow the consumers.
All other parameter values are kept the same in the two examples
In the first example, consumers’ nonfinancial income paths display pronounced transients early in the sample
Those transient effects will not be present in the second example.
We use methods affiliated with the LinearStateSpace class to simulate the model.
We generate 25 paths of the exogenous non-financial income process and the associated optimal consumption and debt paths.
In the first set of graphs, darker lines depict a particular sample path, while the lighter lines describe 24 other paths.
A second graph plots a collection of simulations against the population distribution that we extract from the LinearStateSpace instance LSS.
Comparing sample paths with population distributions at each date $ t $ is a useful exercise—see our discussion of the laws of large numbers
lss = qe.LinearStateSpace(A_LSS, C_LSS, G_LSS, mu_0=μ_0, Sigma_0=Σ_0)
In the code below, we use the LinearStateSpace class to
def income_consumption_debt_series(A, C, G, μ_0, Σ_0, T=150, npaths=25):
"""
This function takes initial conditions (μ_0, Σ_0) and uses the
LinearStateSpace class from QuantEcon to simulate an economy
npaths times for T periods. It then uses that information to
generate some graphs related to the discussion below.
"""
lss = qe.LinearStateSpace(A, C, G, mu_0=μ_0, Sigma_0=Σ_0)
# Simulation/Moment Parameters
moment_generator = lss.moment_sequence()
# Simulate various paths
bsim = np.empty((npaths, T))
csim = np.empty((npaths, T))
ysim = np.empty((npaths, T))
for i in range(npaths):
sims = lss.simulate(T)
bsim[i, :] = sims[0][-1, :]
csim[i, :] = sims[1][1, :]
ysim[i, :] = sims[1][0, :]
# Get the moments
cons_mean = np.empty(T)
cons_var = np.empty(T)
debt_mean = np.empty(T)
debt_var = np.empty(T)
for t in range(T):
μ_x, μ_y, Σ_x, Σ_y = next(moment_generator)
cons_mean[t], cons_var[t] = μ_y[1], Σ_y[1, 1]
debt_mean[t], debt_var[t] = μ_x[3], Σ_x[3, 3]
return bsim, csim, ysim, cons_mean, cons_var, debt_mean, debt_var
def consumption_income_debt_figure(bsim, csim, ysim):
# Get T
T = bsim.shape[1]
# Create the first figure
fig, ax = plt.subplots(2, 1, figsize=(10, 8))
xvals = np.arange(T)
# Plot consumption and income
ax[0].plot(csim[0, :], label="c", color="b")
ax[0].plot(ysim[0, :], label="y", color="g")
ax[0].plot(csim.T, alpha=.1, color="b")
ax[0].plot(ysim.T, alpha=.1, color="g")
ax[0].legend(loc=4)
ax[0].set(title="Nonfinancial Income, Consumption, and Debt",
xlabel="t", ylabel="y and c")
# Plot debt
ax[1].plot(bsim[0, :], label="b", color="r")
ax[1].plot(bsim.T, alpha=.1, color="r")
ax[1].legend(loc=4)
ax[1].set(xlabel="t", ylabel="debt")
fig.tight_layout()
return fig
def consumption_debt_fanchart(csim, cons_mean, cons_var,
bsim, debt_mean, debt_var):
# Get T
T = bsim.shape[1]
# Create percentiles of cross-section distributions
cmean = np.mean(cons_mean)
c90 = 1.65 * np.sqrt(cons_var)
c95 = 1.96 * np.sqrt(cons_var)
c_perc_95p, c_perc_95m = cons_mean + c95, cons_mean - c95
c_perc_90p, c_perc_90m = cons_mean + c90, cons_mean - c90
# Create percentiles of cross-section distributions
dmean = np.mean(debt_mean)
d90 = 1.65 * np.sqrt(debt_var)
d95 = 1.96 * np.sqrt(debt_var)
d_perc_95p, d_perc_95m = debt_mean + d95, debt_mean - d95
d_perc_90p, d_perc_90m = debt_mean + d90, debt_mean - d90
# Create second figure
fig, ax = plt.subplots(2, 1, figsize=(10, 8))
xvals = np.arange(T)
# Consumption fan
ax[0].plot(xvals, cons_mean, color="k")
ax[0].plot(csim.T, color="k", alpha=.25)
ax[0].fill_between(xvals, c_perc_95m, c_perc_95p, alpha=.25, color="b")
ax[0].fill_between(xvals, c_perc_90m, c_perc_90p, alpha=.25, color="r")
ax[0].set(title="Consumption/Debt over time",
ylim=(cmean-15, cmean+15), ylabel="consumption")
# Debt fan
ax[1].plot(xvals, debt_mean, color="k")
ax[1].plot(bsim.T, color="k", alpha=.25)
ax[1].fill_between(xvals, d_perc_95m, d_perc_95p, alpha=.25, color="b")
ax[1].fill_between(xvals, d_perc_90m, d_perc_90p, alpha=.25, color="r")
ax[1].set(xlabel="t", ylabel="debt")
fig.tight_layout()
return fig
Now let’s create figures with initial conditions of zero for $ y_0 $ and $ b_0 $
out = income_consumption_debt_series(A_LSS, C_LSS, G_LSS, μ_0, Σ_0)
bsim0, csim0, ysim0 = out[:3]
cons_mean0, cons_var0, debt_mean0, debt_var0 = out[3:]
consumption_income_debt_figure(bsim0, csim0, ysim0)
plt.show()
consumption_debt_fanchart(csim0, cons_mean0, cons_var0,
bsim0, debt_mean0, debt_var0)
plt.show()
Here is what is going on in the above graphs.
For our simulation, we have set initial conditions $ b_0 = y_{-1} = y_{-2} = 0 $.
Because $ y_{-1} = y_{-2} = 0 $, nonfinancial income $ y_t $ starts far below its stationary mean $ \mu_{y, \infty} $ and rises early in each simulation.
Recall from the previous lecture that we can represent the optimal decision rule for consumption in terms of the co-integrating relationship
$$ (1-\beta) b_t + c_t = (1-\beta) E_t \sum_{j=0}^\infty \beta^j y_{t+j} \tag{65.6} $$
So at time $ 0 $ we have
$$ c_0 = (1-\beta) E_0 \sum_{t=0}^\infty \beta^j y_{t} $$This tells us that consumption starts at the income that would be paid by an annuity whose value equals the expected discounted value of nonfinancial income at time $ t=0 $.
To support that level of consumption, the consumer borrows a lot early and consequently builds up substantial debt.
In fact, he or she incurs so much debt that eventually, in the stochastic steady state, he consumes less each period than his nonfinancial income.
He uses the gap between consumption and nonfinancial income mostly to service the interest payments due on his debt.
Thus, when we look at the panel of debt in the accompanying graph, we see that this is a group of ex-ante identical people each of whom starts with zero debt.
All of them accumulate debt in anticipation of rising nonfinancial income.
They expect their nonfinancial income to rise toward the invariant distribution of income, a consequence of our having started them at $ y_{-1} = y_{-2} = 0 $.
The following figure plots realizations of the left side of (65.6), which, as discussed in our last lecture, is called the cointegrating residual.
As mentioned above, the right side can be thought of as an annuity payment on the expected present value of future income $ E_t \sum_{j=0}^\infty \beta^j y_{t+j} $.
Early along a realization, $ c_t $ is approximately constant while $ (1-\beta) b_t $ and $ (1-\beta) E_t \sum_{j=0}^\infty \beta^j y_{t+j} $ both rise markedly as the household’s present value of income and borrowing rise pretty much together.
This example illustrates the following point: the definition of cointegration implies that the cointegrating residual is asymptotically covariance stationary, not covariance stationary.
The cointegrating residual for the specification with zero income and zero debt initially has a notable transient component that dominates its behavior early in the sample.
By altering initial conditions, we shall remove this transient in our second example to be presented below
def cointegration_figure(bsim, csim):
"""
Plots the cointegration
"""
# Create figure
fig, ax = plt.subplots(figsize=(10, 8))
ax.plot((1 - β) * bsim[0, :] + csim[0, :], color="k")
ax.plot((1 - β) * bsim.T + csim.T, color="k", alpha=.1)
ax.set(title="Cointegration of Assets and Consumption", xlabel="t")
return fig
cointegration_figure(bsim0, csim0)
plt.show()
When we set $ y_{-1} = y_{-2} = 0 $ and $ b_0 =0 $ in the preceding exercise, we make debt “head north” early in the sample.
Average debt in the cross-section rises and approaches the asymptote.
We can regard these as outcomes of a “small open economy” that borrows from abroad at the fixed gross interest rate $ R = r+1 $ in anticipation of rising incomes.
So with the economic primitives set as above, the economy converges to a steady state in which there is an excess aggregate supply of risk-free loans at a gross interest rate of $ R $.
This excess supply is filled by “foreigner lenders” willing to make those loans.
We can use virtually the same code to rig a “poor man’s Bewley [Bewley, 1986] model” in the following way
This rigs a closed economy in which people are borrowing and lending with each other at a gross risk-free interest rate of $ R = \beta^{-1} $.
Across the group of people being analyzed, risk-free loans are in zero excess supply.
We have arranged primitives so that $ R = \beta^{-1} $ clears the market for risk-free loans at zero aggregate excess supply.
So the risk-free loans are being made from one person to another within our closed set of agents.
There is no need for foreigners to lend to our group.
Let’s have a look at the corresponding figures
out = income_consumption_debt_series(A_LSS, C_LSS, G_LSS, mxbewley, sxbewley)
bsimb, csimb, ysimb = out[:3]
cons_meanb, cons_varb, debt_meanb, debt_varb = out[3:]
consumption_income_debt_figure(bsimb, csimb, ysimb)
plt.show()
consumption_debt_fanchart(csimb, cons_meanb, cons_varb,
bsimb, debt_meanb, debt_varb)
plt.show()
The graphs confirm the following outcomes:
But now there is some initial dispersion because there is ex-ante heterogeneity in the initial draws of $ \begin{bmatrix} y_{-1} \\ y_{-2} \end{bmatrix} $.
Let’s have a look at the cointegration figure
cointegration_figure(bsimb, csimb)
plt.show()