1. UNIT III: COMPETITIVE STRATEGY
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UNIT III: COMPETITIVE STRATEGY
Monopoly
Oligopoly
Strategic Behavior
7/19

2. Market Structure Perfect Comp Oligopoly Monopoly
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Market Structure
Perfect Comp Oligopoly Monopoly
No. of Firms infinite (>)
Output MR = MC = P ??? MR = MC < P
Profit No ? Yes
Efficiency Yes ? ???

3. 4/17/2017
Oligopoly
We have no general theory of oligopoly. Rather, there are a variety of models, differing in assumptions about strategic behavior and information conditions.
All the models feature a tension between:
Collusion: maximize joint profits
Competition: capture a larger share of the pie
Firms have an interest to get together and discuss their profit maximizing decisions with one another, to collude; or even to form a cartel e.g., OPEC and set prices or production quotas.

4. Duopoly Models Cournot Duopoly Nash Equilibrium Leader/Follower Model
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Duopoly Models
Cournot Duopoly
Nash Equilibrium
Leader/Follower Model
Price Competition

5. Duopoly Models Cournot Duopoly Nash Equilibrium Stackelberg Duopoly
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Duopoly Models
Cournot Duopoly
Nash Equilibrium
Stackelberg Duopoly
Bertrand Duopoly

6. 4/17/2017
Monopoly
Cyberstax is the only supplier of Vidiot, a hot new computer game. The market for Vidiot is characterized by the following demand and cost conditions:
P = /6Q TC = Q
a) Find the equilibrium level of output, price and profits and draw a graph of your answer. What levels of consumer and total surplus would result?

7. Monopoly P = 30 - 1/6Q TC = 40 + 8Q P = TR – TC
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Monopoly
P = /6Q TC = Q
MR = /3Q MC = 8 => Q* = 66
P* = 19
P = TR – TC
= PQ – (40 + 8Q)
= (19)(66) – 40 -(8)(66)
P = 686 $ 30
P* = 19
So here’s a monopolist that looks at its cost conditions and its demand conditions, calculates its profit maximizing output and expects to earn profits of $ Now what happens when another firm arrives on the scene?
MC = 8
MR D
Q* = Q

8. 4/17/2017
Duopoly
Megacorp is thinking of moving into the Vidiot business with a clone which is indistinguishable from the original. It has access to the same production technology, reflected in the following total cost function:
TC2 = q2
Notation: I will use small q to refer to a firm’s output and capital Q for the industry output.
Will Megacorp enter the market for Vidiot? If it assumes Cyberstax’s output is given, how much will it produce and what will be the new market price? What level of profits will the two firms earn? Does this maximize their profits?
Will Megacorp enter the market?
What is its profit maximizing level of output?

9. 4/17/2017
Duopoly
If Megacorp (Firm 2) takes Cyberstax’s (Firm 1) output as given, its residual demand curve is
P = /6Q
Q = q1+ q2; q1 = 66
P = /6(q1+ q2)
P = /6q2 $ 30 19
q2 = 0
q1 = Q

10. 4/17/2017
Duopoly
P = /6q TC2 = q2
MR2 = /3q = MC2 = 8 => q2* = q1* = 66
P = 30 – 1/6(q1 + q2)
P* = $ P2 = 141.5
Before entry, P* = 19; P1 = 686
Now, P1’ = 323 ow, PC‘ = 297 $ 30 19
13.5
q2 = 0
MC2 = 8
q1*+q2* = Q

11. 4/17/2017
Duopoly
What will happen now that Cyberstax knows there is a competitor? Will it change its level of output?
How will Megacorp respond? Where will this process end?
We need to specify some behavioral or strategic assumption about how each firm will respond to the actions of the other.
What if Cyberstax were to reoptimize given qMega?
The Cournot model is based on the simplest strategic assumption.

12. 4/17/2017
Cournot Duopoly
Reaction curves (or best response curves) show each firm’s profit maximizing level of output as a function of the other firm’s output. q1 qm
R1: q1* = f(q2)
q2 q2

13. Cournot Duopoly P = 30 - 1/6(q1+q2) MR1 = 30 -1/3q1 - 1/6q2 = MC = 8
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Cournot Duopoly
To find R1, set MR = MC. Now, MR is a (-) function not only of q1 but also of q2:
P = /6(q1+q2)
TR1 = Pq1 = [30 - 1/6(q1+q2)]q1
= 30q1 - 1/6q12 - 1/6q2q1
MR1 = 30 -1/3q1 - 1/6q2 = MC = 8
R1: q1* = 66 – 1/2q2 q1 66
q1* Firm 1’s profit maximizing output as a function of Firm 2’s output.
132 q2

14. 4/17/2017
Cournot Duopoly
The outcome (q1*, q2*) is an equilibrium in the following sense: neither firm can increase its profits by changing its behavior unilaterally.
R2: q2* = /2q1
R1: q1* = /2q2 q1
q1* = 44
For the case of identical firms
q1*, q2*: Each firm’s profit maximizing level of output, given the other’s profit maximizing output.
A Nash Equilibrium exists in an oligopolistic market, if each firm is basing its pmax output on a correct assumption (consistent) about the rivals’ behavior.
On Dynamics: We arrive at the NE in logical time not historical time. Convergence to the NE is not the result of a series of actions but a series of conjectures, or beliefs. I think-that you think-that I think …
[I]f game theory is to provide a unique solution to a game-theoretic problem then the solution must be a Nash equilibrium in the following sense. Suppose that game theory makes a unique prediction about the strategy each player will choose. In order for this prediction to be correct, it is necessary that each player be willing to choose the strategy predicted by the theory. Thus each player’s predicted strategy must be that player’s best response to the predicted strategies of the other players. Such a prediction could be called strategically stable or self-enforcing, because no single player wants to deviate from his or her predicted strategy (Gibbons: 8).
q2* = 44 q2

15. 4/17/2017
Nash Equilibrium
A Nash Equilibrium is a pair of “best responses,” such that q1* is a best response to q2* and q2* is a best response to q1*.
R2: q2* = /2q1
R1: q1* = /2q2 q1
q1* = 44
For the case of identical firms
A Nash Equilibrium exists in an oligopolistic market, if each firm is basing its pmax output on a correct assumption (consistent) about the rivals’ behavior.
On Dynamics: We arrive at the NE in logical time not historical time. Convergence to the NE is not the result of a series of actions but a series of conjectures, or beliefs. I think-that you think-that I think …
[I]f game theory is to provide a unique solution to a game-theoretic problem then the solution must be a Nash equilibrium in the following sense. Suppose that game theory makes a unique prediction about the strategy each player will choose. In order for this prediction to be correct, it is necessary that each player be willing to choose the strategy predicted by the theory. Thus each player’s predicted strategy must be that player’s best response to the predicted strategies of the other players. Such a prediction could be called strategically stable or self-enforcing, because no single player wants to deviate from his or her predicted strategy (Gibbons: 8).
q2* = 44 q2

16. 4/17/2017
Nash Equilibrium
A Nash Equilibrium is a pair of “best responses,” such that q1* is a best response to q2* and q2* is a best response to q1*. q1
q1*
Is this the best they can do?
If Firm 1 reduces its output while Firm 2 continues to produce q2*, the price rises and Firm 2’s profits increase.
q2* q2

17. 4/17/2017
Nash Equilibrium
A Nash Equilibrium is a pair of “best responses,” such that q1* is a best response to q2* and q2* is a best response to q1*. q1
q1*
Is this the best they can do?
If Firm 2 reduces its output while Firm 1 continues to produce q1*, the price rises and Firm 1’s profits increase.
q2* q2

18. 4/17/2017
Nash Equilibrium
A Nash Equilibrium is a pair of “best responses,” such that q1* is a best response to q2* and q2* is a best response to q1*. q1
q1*
Is this the best they can do?
If they can agree to restrict output, there are a range of outcomes to the SW that make both firms better off.
The duopolists have an incentive to collude: to restrict their output – below the NE level – and increase their profits.
What is socially optimal
q2* q2

19. 4/17/2017
Stackelberg Duopoly
Firm 1 is the dominant firm, or Leader, (e.g., GM) and moves first. Firm 2 is the subordinate firm, or Follower. q1
Firm 1 gets to search along Firm 2’s reaction curve to find the point that maximizes Firm 1’s profits.
p1 = ?
1934
Firm 1 knows Firm 2’s cost structure and hence can calculate its reaction curve R2.
p1 = ? R2 q2

20. 4/17/2017
Stackelberg Duopoly
Firm 1 is the dominant firm, or Leader, (e.g., GM) and moves first. Firm 2 is the subordinate firm, or Follower.
MR1 = MC1
TR1 = Pq1 = [30-1/6(q1+q2*)]q1
Find q2* from R2: q2* = /2q1
= [30-1/6(q1+66-1/2q1)]q1
= 30q1-1/6q12 -11q1+1/12q12
MR1 = 19 -1/6q1 = MC1 = 8
q1* = 66; q2* = 33 q1
q1* = 66 R2
q2* = q2

21. 4/17/2017
Stackelberg Duopoly
Firm 1 is the dominant firm, or Leader, (e.g., GM) and moves first. Firm 2 is the subordinate firm, or Follower.
Firm 1 has a first mover advantage: by committing itself to produce q1, it constraints Firm 2’s output decision.
Firm 1 can employ excess capacity to deter entry by a potential rival. q1
q1* = 66 R2
q2* = q2

22. 4/17/2017
Bertrand Duopoly
Under Bertrand duopoly, firms compete on the basis of price, not quantity (as in Cournot and Stackelberg).
If P1 > P2 => q1 = 0
If P1 = P2 => q1 = q2 = ½ Q
If P1 < P2 => q2 = 0 P P2 d1 q1

23. 4/17/2017
Bertrand Duopoly
Under Bertrand duopoly, firms compete on the basis of price, not quantity (as in Cournot and Stackelberg).
Eventually, price will be competed down to the perfect competition level.
Not very interesting model (so far). P P2 d1 q1

24. 4/17/2017
Duopoly Models
If we compare these results, we see that qualitatively different outcomes arise out of the finer-grained assumptions of the models: P
15.3
13.5 8 c
P = /6Q
TC = q
Cournot
Stackelberg
Bertrand Q

25. 4/17/2017
Duopoly Models
If we compare these results, we see that qualitatively different outcomes arise out of the finer-grained assumptions of the models: P Pc Ps
Pb=Ppc c
Qc < Qs < Qb
Pc > Ps > Pb
p1s > p1c >p1b
p2c > p2s >p2b
Cournot
Stackelberg
Bertrand
Qc Qs Qb = Qpc Q

26. Duopoly Models Summary
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Duopoly Models
Summary
Oligopolistic markets are underdetermined by theory. Outcomes depend upon specific assumptions about strategic behavior.
Nash Equilibrium is strategically stable or self-enforcing, b/c no single firm can increase its profits by deviating.
In general, we observe a tension between
Collusion: maximize joint profits
Competition: capture a larger share of the pie
Examples of Collusion

27. Game Theory Game Trees and Matrices Games of Chance v. Strategy
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Game Theory
Game Trees and Matrices
Games of Chance v. Strategy
The Prisoner’s Dilemma
Dominance Reasoning
Best Response and Nash Equilibrium
Mixed Strategies

28. 4/17/2017
Games of Chance
Player 1
You are offered a fair gamble to purchase a lottery ticket that pays $1000, if your number is drawn. The ticket costs $1.
Buy Don’t Buy
(1000) (-1) (0) (0)
Chance
E.g., Lottery, roulette.
What would you do?

29. 4/17/2017
Games of Chance
Player 1
You are offered a fair gamble to purchase a lottery ticket that pays $1000, if your number is drawn. The ticket costs $1.
The chance of your number being chosen is independent of your decision to buy the ticket.
Buy Don’t Buy
(1000) (-1) (0) (0)
Chance
E.g., Lottery, roulette.

30. Games of Strategy Player 2 chooses the winning number.
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Games of Strategy
Player 1
Player 2 chooses the winning number.
What are Player 2’s payoffs?
Buy Don’t Buy
(1000,-1000) (-1,1) (0,0) (0,0)
Player 2
E.g., Lottery, roulette.

31. 4/17/2017
Games of Strategy
Firm 1
Duopolists deciding to advertise. Firm 1 moves first. Firm 2 observes Firm 1’s choice and then makes its own choice.
How should the game be played?
Advertise Don’t
Advertise
A D A D
(10,5) (15,0) (6,8) (20,2)
Firm 2
Backwards-induction

32. 4/17/2017
Games of Strategy
Firm 1
Duopolists deciding to advertise. The 2 firms move simultaneously. (Firm 2 does not see Firm 1’s choice.)
Imperfect Information.
Advertise Don’t
Advertise
A D A D
(10,5) (15,0) (6,8) (20,2)
Information set
Firm 2
Extensive Form Games

33. Matrix Games 10, 5 15, 0 6, 8 20, 2 A D A D Firm 1 Advertise Don’t
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Matrix Games
Firm 1
A D A D
10, , 0
6, , 2
Advertise Don’t
Advertise
A D A D
(10,5) (15,0) (6,8) (20,2)
Firm 2

34. Games of Strategy Games of strategy require at least two players.
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Games of Strategy
Games of strategy require at least two players.
Players choose strategies and get payoffs. Chance is not a player!
In games of chance, uncertainty is probabilistic, random, subject to statistical regularities.
In games of strategy, uncertainty is not random; rather it results from the choice of another strategic actor.
Thus, game theory is to games of strategy as probability theory is to games of chance.

35. A Brief History of Game Theory
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A Brief History of Game Theory
Minimax Theorem
Theory of Games & Economic Behavior
Nash Equilibrium
Prisoner’s Dilemma
The Evolution of Cooperation
Nobel Prize: Harsanyi, Selten & Nash

36. The Prisoner’s Dilemma
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The Prisoner’s Dilemma
The pair of
dominant
strategies
(Confess, Confess)
is a Nash Eq.
In years in jail Player 2
Confess Don’t
Confess
Player 1
Don’t
-10, -10 0, -20
-20, 0 -1, -1
GAME 1.

37. The Prisoner’s Dilemma
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The Prisoner’s Dilemma
Each player has a dominant strategy. Yet the outcome (-10, -10) is pareto inefficient.
Is this a result of imperfect information? What would happen if the players could communicate?
What would happen if the game were repeated? A finite number of times? An infinite or unknown number of times?
What would happen if rather than 2, there were many players?

38. Dominance S1 S1 S2 S2 S3 S3 0,2 4,3 3,3 0,2 4,3 3,3 (S2,T2) (S2,T3)
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Dominance
Definition
Dominant Strategy: a strategy that is best no matter what the opponent(s) choose(s).
T T T T T T3 S1 S2 S3
0,2 4,3 3,3
4,0 5,4 5,3
3,5 3,5 2,3 S1 S2 S3
0,2 4,3 3,3
4,0 5,4 5,6
3,5 3,5 2,3
(S2,T2)
(S2,T3)
Sure Thing Principle: If you have a dominant strategy, use it!

39. Nash Equilibrium S1 S1 S2 S2 S3 S3 (S3,T3) T1 T2 T3 0,4 4,0 5,3
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Nash Equilibrium
Definitions
Best Response Strategy: a strategy, s*, is a best response strategy, iff the payoff to (s*,t) is at least as great as the payoff to (s,t) for all s.
T1 T2 T3 S1 S2 S3
0,4 4,0 5,3
4,0 0,4 5,3
3,5 3,5 6,6
Nash Equilibrium: a set of best response strategies (one for
each player), (s*, t*)
such that s* is a best
response to t* and
t* is a b.r. to s*.
(S3,T3) S1 S2 S3
Now let me pause and see if there are any questions.

40. Nash Equilibrium S1 S1 S2 S2 S3 S3 T1 T2 T3
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Nash Equilibrium
T1 T2 T3
Nash equilibrium need not be
Efficient. S1 S2 S3
4,4 2,3 1,5
3,2 1,1 0,0
5,1 0,0 3,3 S1 S2 S3
This is similar to the PD, but w/o dominant strategies.

41. Nash Equilibrium S1 S1 S2 S2 S3 S3 T1 T2 T3
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Nash Equilibrium
T1 T2 T3
Nash equilibrium need not be
unique.
A COORDINATION PROBLEM S1 S2 S3
1,1 0,0 0,0
0,0 1,1 0,0
0,0 0,0 1,1 S1 S2 S3
GC PS TS
A relatively simple problem to solve, if the players can communicate.

42. Nash Equilibrium S1 S1 S2 S2 S3 S3 T1 T2 T3 Multiple and Inefficient
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Nash Equilibrium
T1 T2 T3
Multiple and Inefficient
Nash Equilibria. S1 S2 S3
1,1 0,0 0,0
0,0 1,1 0,0
0,0 0,0 3,3 S1 S2 S3
(S1,T1) and (S2,T2) remain NE, despite the appeal (salience) pf (S3,T3)

43. Nash Equilibrium S1 S1 S2 S2 S3 S3 T1 T2 T3 Multiple and Inefficient
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Nash Equilibrium
T1 T2 T3
Multiple and Inefficient
Nash Equilibria.
Is it always advisable to play
a NE strategy?
What do we need to know
about the other player? S1 S2 S3
1,1 0,0 0,-100
0,0 1,1 0,0
-100,0 0,0 3,3 S1 S2 S3
We need to assume the other player is rational.
Let’s pause for questions.
Nash Equilibrium has an important property (strategic stability) but it is not necessarily unique nor efficient. Indeed, other solution concepts have been proposed, but Nash wins out for generality.
In 1950, Nash proved that every finite game has an equilibrium point.
For along time it was thought that these sort of I-think that you think – t hat I think … chains of reasoning led to infinite regress, but (first von Neumann for zerosum games and then …)
In 1950, Nash proved that every finite game has an equilibrium point, a way to truncate the infinite regress and arrive at a course of action that should be chosen by rational decision-makers.

44. Next Time 7/21 Strategic Competition Pindyck and Rubenfeld, Ch 13.
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Next Time
7/21 Strategic Competition
Pindyck and Rubenfeld, Ch 13.
Besanko, Ch. 14.