the emergence of weak, despotic and inclusive states
TRANSCRIPT
The Emergence of Weak, Despotic and Inclusive States
Daron Acemoglu and James A Robinson
MIT & Chicago
July 2017.
Acemoglu Robinson (MIT & Chicago) States July 2017. 1 / 63
"Men who had acquired too much power ... were whi4led down by means of witchcra: accusa;ons. Nyambua was one of a regular series of movements to which Tiv poli;cal ac;on, with its distrust of power, gives rise to that the greater poli;cal ins;tu;ons -‐ the one based on the lineage system and a principle of egalitarianism – can be preserved" (Paul Bohannon, 1958)
“when the people are weak, the state is strong; hence the state that possesses the Way strives to weaken the people.”
Shang Yang
“At that ;me the custom was followed that no more than two general assemblies were to be held each year. All the important men, both clerics and laymen, a4ended this general assembly. .. and those of lower sta;on were present in order to hear the decisions and occasionally also to deliberate concerning them, and to confirm them not out of coercion but by their own understanding and agreement.” Hincmar of Rheims.
PREFACE TO THE SALIC LAWS: …Therefore four men, chosen out of many among them, stood out: Their
names were Wisogast, Arogast, Salegast and Widogast. They came from the villae of Bothem, Salehem and Widohem, beyond the Rhine.
Coming together in three legal assemblies, and discussing the origins
and cases carefully, they made judgement on each case as follows…
“The ruler is a boat; commoners are the water. The water can carry the boat; the water can capsize the boat.” The Xunzi
The Emergence of Weak, Despotic and Inclusive States Model
The Model
Consider a game with two types of players: civil society and an elitesynonymous with the state.
Let us assume that the game is played between non-overlappinggenerations of representatives of civil society and the state, and thuswithout forward-looking behavior.
At time t, the state variables inherited from the previous period are(xt−∆, st−∆) ∈ [0, 1]2, where the first element corresponds to thestrength (or conflict capacity) of civil society and the second to thestrength of the state controlled by the elite
We will take ∆ to be small so as to work with differential, rather thandifference equations.
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The Emergence of Weak, Despotic and Inclusive States Model
Investment Decisions
The players simultaneously make their investment decisions, ixt ≥ 0and i st ≥ 0 such that
xt = xt−∆ + ixt ∆− δ∆
andst = st−∆ + i st ∆− δ∆.
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The Emergence of Weak, Despotic and Inclusive States Model
Production
A state and society with strengths st and xt produces output/surplusgiven by
f (st , xt),
where f is assumed to be nondecreasing and differentiable. Let usfirst simplify the discussion by imposing:
Assumption 1 f (s, x) = 1 for all (x , s) ∈ [0, 1]2.
This assumption simplifies the treatment by making the state andcivil society symmetric as players.
Generalizations discussed below.
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The Emergence of Weak, Despotic and Inclusive States Model
Contests for Power
There is conflict over the division of production.
At date t, if the state and citizens decide to fight, then one side willwin and capture all of the output of the economy, and the other sidereceives zero. Winning probabilities are functions of relative strengths.In particular, the state will win if
st ≥ xt + σ,
where σ is drawn from the distribution H, and denote its density by h.
The existence of the shock captures the stochastic nature of winningthe conflict.
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The Emergence of Weak, Despotic and Inclusive States Model
Costs
The costs of investment of society and state are
Cx (ixt , xt−∆) =
{cx (ixt ) if xt−∆ > γx ,
cx (ixt ) + (γx − xt−∆) ixt if xt−∆ ≤ γx .
Cs(ist , st−∆) =
{cs(i st ) if st−∆ > γs ,
cs(i st ) + (γs − st−∆)ist if st−∆ ≤ γs .
The term γx > 0 captures the “increasing returns” nature of conflict:once one of the players stops making investments in its conflictcapacity, it faces greater costs to get started—capturing fixed costs ofsolving collective action and investing in bureaucracy or capacity.
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The Emergence of Weak, Despotic and Inclusive States Model
Assumptions
Assumption 2 1 cx and cs are continuously differentiable, strictlyincreasing and weakly convex over R+, and satisfylimx→∞ c ′x (x) = ∞ and lims→∞ c ′s(s) = ∞.
2
|c ′′s (δ)− c ′′x (δ)|min{c ′′s (δ), c ′′x (δ)]
<1
supz |h′(z)|3
c ′s(0) + γs ≥ c ′x (δ) and c ′x (0) + γx ≥ c ′s(δ).
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The Emergence of Weak, Despotic and Inclusive States Model
Assumptions (continued)
Assumption 3 h is differentiable, single-peaked and symmetric around zeroand satisfies for each z ∈ {x , s}:
c ′z (δ) > h(1)
andmin{h(0)− γz ; h(γz )} > c ′z (δ).
Single-peaked h matters greatly for our results—it implies thediscouragement effect, whereby investments are greater when thetwo parties are close to each other (see evidence inKovenock-Sheremeta, 2015, in experimental settings, and Aghion etal., 2005, in the context of innovation).
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The Emergence of Weak, Despotic and Inclusive States Model
Objective Functions
Under these assumptions at time t civil society maximizes
H(xt − st)− ∆ · Cx (xt , xt−∆)
while the state maximizes
H(st − xt)− ∆ · Cs(st , st−∆)
where we have used the investment equation to substitute in for thestate variables.
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The Emergence of Weak, Despotic and Inclusive States Model
Investment Decisions
Given Assumptions 1 and 2, the investment decisions of both stateand civil society are given by their respective first-order conditions.
Take the limit ∆→ 0, the optimality conditions for the state andsociety as
h(st − xt) ≤ c ′s(st + δ) + max{0; γs − st} if st = −δ or st = 0,h(st − xt) ≥ c ′s(st + δ) + max{0; γs − st} if st = 1,h(st − xt) = c ′s(st + δ) + max{0; γs − st} otherwise,
(1)h(xt − st) ≤ c ′x (xt + δ) + max{0; γx − xt} if xt = −δ or xt = 0,h(xt − st) ≥ c ′x (xt + δ) + max{0; γx − xt} if xt = 1,h(xt − st) = c ′x (xt + δ) + max{0; γx − xt} otherwise.
(2)
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The Emergence of Weak, Despotic and Inclusive States Model
The Main Result
Proposition
There are three locally asymptotically stable steady states
1 x∗ = s∗ = 1.
2 x∗ = 0 and s∗ ∈ (γs , 1).
3 x∗ ∈ (γx , 1) and s∗ = 0.
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The Emergence of Weak, Despotic and Inclusive States Model
The Main Result: Local Dynamics
Power of Society
Power of the State
0 1x0
1
sRegion I
Region II
Region III
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The Emergence of Weak, Despotic and Inclusive States Model
Interpretation
These three asymptotically stable steady states correspond to verydifferent types of states/governments
x∗ = s∗ = 1: here both state and society are strong and this resultsfrom a dynamic where each pushes the other in accumulating strength— this is the highest capacity.x∗ = 0 and s∗ ∈ (γs , 1): society is weak, but as a consequence thestate gives up and is weaker than the previous case — there is lowercapacity even if the state is dominant in society.x∗ ∈ (γx , 1) and s∗ = 0: society dominates the state which gives upthe fight.
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The Emergence of Weak, Despotic and Inclusive States Model
Red Queen Effect
We can see this from the dynamics of Region II.
Also, note that investment incentives are highest when
h(x − s) = h(s − x) ≈ h(0).
Both parties are discouraged from investment when there is a bigdifference between their strengths.
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The Emergence of Weak, Despotic and Inclusive States Model
Sketch of the Proof
Let us outlined the proof for the first part.
At x∗ = s∗ = 1, the marginal cost of investment for player z ∈ {x , s}is c ′z (δ), while the marginal benefit starting from this point is h(0).
Assumption 2 ⇒ marginal benefit > marginal cost, and thusx∗ = s∗ = 1 is a steady state.
For asymptotic stability, first note that the laws of motion of x and sin the neighborhood of x∗ = s∗ = 1 are given by
c ′x (x + δ) = h(x − s)
c ′s(s + δ) = h(s − x).
Why? We are away from the steady state and there cannot be animmediate jump and thus the first-order conditions have to hold inview of Assumption 1, and because we are in the neighborhood of thesteady state (1, 1), we must have x > γx and s > γs .
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The Emergence of Weak, Despotic and Inclusive States Model
Sketch of the Proof (continued)
This dynamical system can then be written as
x = (c ′x )−1(h(x − s))− δ (3)
s = (c ′s)−1(h(s − x))− δ.
Now to establish asymptotic stability, we will show that
L(x , s) =1
2(1− x)2 +
1
2(1− s)2
is a Lyapunov function in the neighborhood of the steady state (1, 1).
Indeed, L(x , s) is continuous and differentiable, and has a uniqueminimum at (1, 1).
We will next verify that in is sufficiently small neighborhood of (1, 1),L(x , s) is decreasing along solution trajectories of the dynamicalsystem given by (3).
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The Emergence of Weak, Despotic and Inclusive States Model
Sketch of the Proof (continued)
Since L is differentiable, for x ∈ (γx , 1) and s ∈ (γs , 1), we can write
dL(x , s)
dt= −(1− x)x − (1− s)s.
First note that since h(x − s) > c ′x (δ) and h(s − x) > c ′s(δ) for xand s in a sufficiently small neighborhood of (1, 1), we have bothx > 0 and s > 0.
This implies that, in this range, both terms in dL(x ,s)dt are negative,
and thus dL(x ,s)dt < 0.
Moreover, the same conclusion applies when x = 1 (respectively when
s = 1), with the only modification that dL(x ,s)dt will not only have the
s (respectively the x) term, which continues to be strictly negative.
Then the asymptotic stability of (1, 1) follows from LaSalle’sTheorem (which takes care of the fact that our steady state is on theboundary of the domain of the dynamical system in question).
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The Emergence of Weak, Despotic and Inclusive States Model
Sketch of the Proof (continued)
The argument for the existence and local stability of the other steadystates is analogous.
To show that there are no other locally stable steady states, weconsider all different types of steady states, and either show that theydo not exist or that they cannot be locally stable even if they existed.
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The Emergence of Weak, Despotic and Inclusive States Model
Global Dynamics
These local dynamics can be extended to some degree to understandglobal dynamics:
Power of Society
Power of the State
0 1x
x(s)
0
1
ss(x)
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The Emergence of Weak, Despotic and Inclusive States Model
Numerical Results on Global Dynamics
Consider the following example:
cx (i) = 3.25× i2 and cs(i) = 3× i2.
and in addition set the values of parameters as γx = 0.35, γs = 0.4,and δ = 0.1. H is a raised cosine distribution over [−1, 1]. Then
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x
0
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The Emergence of Weak, Despotic and Inclusive States Model
Conditional Effects of Change in Initial Conditions
Consider an increase in the capacity of the state. The implications ofthis will be very different depending on which we can we start in.
0 1x0
1
s
Proposition
The effects of changes in the initial conditions (x0, s0) on equilibriumdynamics and the long-run outcome of the society are conditional in thesense that these depend on which region we move out of and into.
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The Emergence of Weak, Despotic and Inclusive States Forward-Looking Model
Forward-Looking Model
Let us now consider forward-looking players.
To maximize the parallel with the model with short-lived players, weassume that both players again correspond to sequence ofnon-overlapping generations, but each generation has anexponentially-distributed lifetime or equivalently, a Poisson end datewith parameter β = e−ρ∆.
We assume that this random end date is the only source ofdiscounting.
Clearly, as the period length ∆ shrinks, discounting between periodswill also decline (and the discount factor will approach 1).
Again to maximize the parallel with our static model, we also assumethat there is an expectation one conflict between the two playersduring the lifetime of each generation. Since with this Poissonspecification, the expected lifetime of his generation is 1/(1− β),this implies that a conflict arrives at the rate 1− β.
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The Emergence of Weak, Despotic and Inclusive States Forward-Looking Model
Main Result
Proposition
Suppose Assumptions 1, 2 and 3 hold. Then there exists a discount ratesρ ≥ ρ > 0 such that for all ρ > ρ, there are three (locally) asymptoticallystable steady states:
1 x∗ = s∗ = 1.
2 x∗ = 0 and s∗ ∈ (γs , 1).
3 x∗ ∈ (γx , 1) and s∗ = 0.
Moreover, for all ρ < ρ, there exists a unique globally stable steady statex∗ = s∗ = 1.
Therefore, with sufficient discounting, all of the same insights apply.
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The Emergence of Weak, Despotic and Inclusive States Forward-Looking Model
Value Functions
Now the maximization problem of each player is a solution to arecursive, dynamic programming problem, written as
Vx (xt−∆, st−∆) = maxxt≥0
[(1− β)H(xt − st)
−∆ · Cx (xt , xt−∆) + βVx (xt , s∗∆(xt−∆, st−∆))],
and
Vs(xt−∆, st−∆) = maxst≥0
[(1− β)H(st − xt)
−∆ · Cs (st , st−∆) + βVs(x∗∆(xt−∆, st−∆), st).
Because these value functions are continuous in β, the main result isestablished using Berge’s maximum theorem and considering the limitβ→ 0.
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The Emergence of Weak, Despotic and Inclusive States Forward-Looking Model
Continuous-Time Approximations
As ∆→ 0, the value functions Vx (x , s) and Vs(x , s) (implicitlyfunctions of ∆) converge to their continuous time limits Vx (x , s) andVs(x , s), and the policy functions x ′∗∆ (x , s) and s ′∗∆ (x , s) converge totheir limits x ′∗(x , s) and s ′∗(x , s).
Continuous-time HJB equations an be obtained as
ρVx (x , s) = ρH(x − s)
+ maxx≥−δ
{−Cx (x , x) +
∂Vx (x , s)
∂xx
}+
∂Vx (x , s)
∂ss∗(x , s).
and
ρVs(x , s) = ρH(s − x)
+ maxs≥−δ
{−Cs(s, s) +
∂Vs(x , s)
∂ss
}+
∂Vs(x , s)
∂xx∗(x , s).
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The Emergence of Weak, Despotic and Inclusive States Forward-Looking Model
Optimality Conditions
The first-order optimality conditions for civil society are given by
∂Cx (x , x)
∂x=
∂Vx (x , s)
∂xif − δ < x(x , s), and x ∈ (0, 1),
∂Cx (x , x)
∂x≤ ∂Vx (x , s)
∂xif x = 1, (4)
∂Cx (x , x)
∂x≥ ∂Vx (x , s)
∂xif x(x , s) = −δ or x = 0.
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The Emergence of Weak, Despotic and Inclusive States Forward-Looking Model
Dynamical System with Forward-Looking Players
In the first case where we have an interior solution, we can also write
x =
(c ′x )−1(
∂Vx (x ,s)∂x − γx + x
)if x ≤ γx
(c ′x )−1(
∂Vx (x ,s)∂x
)if x > γx
.
The first-order conditions for state are also similar, and for interiorsolution, they yield
s =
(c ′s)−1(
∂Vs (x ,s)∂s − γs + s
)if s ≤ γs
(c ′s)−1(
∂Vs (x ,s)∂s
)if s > γs
.
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The Emergence of Weak, Despotic and Inclusive States Forward-Looking Model
Numerical Results for the Forward-Looking Model
Same parameters as above, and the discount rate ρ ≥ 60. Then thedynamics are identical to before:
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x
0
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The Emergence of Weak, Despotic and Inclusive States Forward-Looking Model
Numerical Results for the Forward-Looking Model(continued)
Instead, with a discount factor of ρ = 30, we have
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The Emergence of Weak, Despotic and Inclusive States Comparative Statics
Comparative Statics: Main Idea
Just as with initial conditions, comparative statics with respect toparameters are conditional—they depend exactly where a society isand to which region it is being shifted by changes in parameters.
Mathematically, we relax Assumption .
Assumption 1′ f (x , s) = φ0 + φxx + φss, where φ0 > 0, φx > 0 andφs > 0.
In addition, we modify Assumptions 2 and 3 in minor ways, inparticular, ensuring that at x = s = 1 the marginal benefit ofinvestment exceeds the cost for both parties.
Then, all of the results so far generalize.
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The Emergence of Weak, Despotic and Inclusive States Comparative Statics
Comparative Statics
For comparative statics, let us also adopt:
Assumption 4 h(y)(φ0 + φzy) +H(y)φz is a decreasing function of y forz ∈ {s, x} and for y ≥ 0.
A sufficient condition for this is that the elasticity of the h function isgreater than 1/2.Then, we can show that:
1 A small increase in φs has no impact on the steady states with s = 1and s = 0, and increases the level of state strength in the steady statewith s = s.This implies that we can think of Paper Leviathan is a situation inwhich φs is very low, while the Despotic Leviathan is one in which it ishigh.
2 A small increase in φx has analogous effects.3 Changes in cost functions also have similar effects.
Furthermore, all of these parameter changes shift the boundaries ofthe basins of attraction.
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The Emergence of Weak, Despotic and Inclusive States Comparative Statics
Changes in the Basins of Attraction
With an increase in φx , x increases, and its basin of attraction,Region III, expands. Region I tends to contract.
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The Emergence of Weak, Despotic and Inclusive States Comparative Statics
General Payoff Function
The results are very similar if f is concave. For example, whenf (x , s) = 0.5x0.8 + 0.5s0.8, with the other parameters the same asabove, we have:
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x
0
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Conclusions
Conclusions
Much evidence that state capacity is critical for economicdevelopment.
But much remains to be understood about how state capacityemerges and how it rests on the ‘capacity’ of civil society.
We have argued that to successfully study state capacity one mustunderstand how the state interacts with society.
A state has capacity not because—or at the very least not justbecause—elites have decided to solve some top-down engineeringproblem.
Much more important is the competition from a capable civil society.
This perspective naturally leads to divergent paths of state-societyrelations and state capacity, and explains why structural factors oftenappear to have limited explanatory power for different developmentpaths of the state.
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