Bertrand paradox (economics)

In economics and commerce, the Bertrand paradox — named after its creator, Joseph Bertrand^[1] — describes a situation in which two players (firms) reach a state of Nash equilibrium where both firms charge a price equal to marginal cost ("MC"). The paradox is that in models such as Cournot competition, an increase in the number of firms is associated with a convergence of prices to marginal costs. In these alternative models of oligopoly, a small number of firms earn positive profits by charging prices above cost. Suppose two firms, A and B, sell a homogeneous commodity, each with the same cost of production and distribution, so that customers choose the product solely on the basis of price. It follows that demand is infinitely price-elastic. Neither A nor B will set a higher price than the other because doing so would yield the entire market to their rival. If they set the same price, the companies will share both the market and profits.

On the other hand, if either firm were to lower its price, even a little, it would gain the whole market and substantially larger profits. Since both A and B know this, they will each try to undercut their competitor until the product is selling at zero economic profit. This is the pure-strategy Nash equilibrium. Recent work has shown that there may be an additional mixed-strategy Nash equilibrium with positive economic profits under the assumption that monopoly profits are infinite.^[2]^[3] For the case of finite monopoly profits, it has been shown that positive profits under price competition are impossible in mixed equilibria and even in the more general case of correlated equilibria.^[4]

The Bertrand paradox rarely appears in practice because real products are almost always differentiated in some way other than price (brand name, if nothing else); firms have limitations on their capacity to manufacture and distribute, and two firms rarely have identical costs.

Bertrand's result is paradoxical because if the number of firms goes from one to two, the price decreases from the monopoly price to the competitive price and stays at the same level as the number of firms increases further. This is not very realistic, as in reality, markets featuring a small number of firms with market power typically charge a price in excess of marginal cost. The empirical analysis shows that in most industries with two competitors, positive profits are made. Solutions to the Paradox attempt to derive solutions that are more in line with solutions from the Cournot model of competition, where two firms in a market earn positive profits that lie somewhere between the perfectly competitive and monopoly levels.

Some reasons the Bertrand paradox do not strictly apply:

Capacity constraints. Sometimes firms do not have enough capacity to satisfy all demand. This was a point first raised by Francis Edgeworth^[5] and gave rise to the Bertrand–Edgeworth model.
Integer pricing. Prices higher than MC are ruled out because one firm can undercut another by an arbitrarily small amount. If prices are discrete (for example have to take integer values) then one firm has to undercut the other by at least one cent. This implies that the price one cent above MC is now an equilibrium: if the other firm sets the price one cent above MC, the other firm can undercut it and capture the whole market, but this will earn it no profit. It will prefer to share the market 50/50 with the other firm and earn strictly positive profits.^[6]
Product differentiation. If products of different firms are differentiated, then consumers may not switch completely to the product with lower price.
Dynamic competition. Repeated interaction or repeated price competition can lead to the price above MC in equilibrium.^[7]
More money for higher price. It follows from repeated interaction: If one company sets their price slightly higher, then they will still get about the same amount of buys but more profit for each buy, so the other company will raise their price, and so on (only in repeated games, otherwise the price dynamics are in the other direction).
Oligopoly. If the two companies can agree on a price, it is in their long-term interest to keep the agreement: the revenue from cutting prices is less than twice the revenue from keeping the agreement and lasts only until the other firm cuts its own prices.^[8]
Effort to Purchase. If there is a difference in the effort it takes for a consumer to purchase one over the other based on the consumer's circumstances (such as a difference in travel time to stores that stock the products), this can cause consumers to prefer one product over the other even if the product itself is exactly the same.
Social Interdependence. If indifferent consumers are treated as having a strategic choice between products based on loyalty and the choices of others the firms can achieve a price equilibrium with positive profits without directly violating Bertrand's assumptions.^[9]
Goodwill. Even when confronted with otherwise identical products in a market of price competition the two companies are themselves inherently different entities which may influence a consumer's choice of product via brand goodwill.^[10]
Status Quo. Consumers have an observed bias for retaining status quo so even when a new firm with identical product enters a market, consumers are biased to continue to purchase from the original firm.^[11]
Customer Heterogeneity. While products may be homogenous, heterogenous consumers can still create a market in which two price competing firms achieve price equilibrium with positive profits.^[12]

References[edit]

^ Bertrand, J. (1883). "Review of Theorie mathematique de la richesse sociale and of Recherches sur les principles mathematiques de la theorie des richesses". Journal des Savants. 67: 499–508.
^ Kaplan, T. R.; and Wettstein (2000). "The Possibility of Mixed-Strategy Equilibria with Constant-Returns-to-Scale Technology under Bertrand Competition". Spanish Economic Review. 2: 65–71. doi:10.1007/s101080050018. S2CID 18132017.
^ Baye, M. R.; Morgan, J. (1999). "A folk theorem for one-shot Bertrand games". Economics Letters. 65: 59–65. CiteSeerX 10.1.1.508.1579. doi:10.1016/s0165-1765(99)00118-4.
^ Jann, O.; Schottmüller, C. (2015). "Correlated equilibria in homogeneous good Bertrand competition". Journal of Mathematical Economics. 57: 31–37. doi:10.1016/j.jmateco.2015.01.005.
^ Edgeworth, Francis (1889) "The pure theory of monopoly". Reprinted in Collected Papers relating to Political Economy. Vol. 1. Macmillan. 1925.
^ Dixon, Huw David (July 1993). "Integer Pricing and Bertrand–Edgeworth Oligopoly with Strictly Convex Costs: Is It Worth More Than a Penny?". Bulletin of Economic Research. 45 (3): 257–68. doi:10.1111/j.1467-8586.1993.tb00570.x.
^ Bruttel, Lisa V. (2009-01-01). "Group dynamics in experimental studies—The Bertrand Paradox revisited". Journal of Economic Behavior & Organization. 69 (1): 51–63. doi:10.1016/j.jebo.2008.10.002. ISSN 0167-2681.
^ Maskin, Eric (1986). "The Existence of Equilibrium with Price-Setting Firms". The American Economic Review. 76 (2): 382–386. ISSN 0002-8282. JSTOR 1818801.
^ Soeiro, Renato; Adrego Pinto, Alberto (2 June 2019). "Social power as a solution to the Bertrand Paradox". Munich Personal RePEc Archive.
^ Kaimann, Daniel; Hoyer, Britta (2019-01-02). "Price competition and the Bertrand model: the paradox of the German mobile discount market". Applied Economics Letters. 26 (1): 54–57. doi:10.1080/13504851.2018.1436141. ISSN 1350-4851. S2CID 158758649.
^ Chernev, Alexander (2004-12-01). "Goal Orientation and Consumer Preference for the Status Quo". Journal of Consumer Research. 31 (3): 557–565. doi:10.1086/425090. ISSN 0093-5301. S2CID 17077046.
^ Jost, Peter‐J.; Ressi, Anna (2022-04-18). "What can I do for you? Optimal market segmentation in service markets". Production and Operations Management. 31 (7): 2838–2852. doi:10.1111/poms.13720. hdl:10419/265036. ISSN 1059-1478. S2CID 247605694.

[1] Bertrand, J. (1883). "Review of Theorie mathematique de la richesse sociale and of Recherches sur les principles mathematiques de la theorie des richesses". Journal des Savants. 67: 499–508.

[2] Kaplan, T. R.; and Wettstein (2000). "The Possibility of Mixed-Strategy Equilibria with Constant-Returns-to-Scale Technology under Bertrand Competition". Spanish Economic Review. 2: 65–71. doi:10.1007/s101080050018. S2CID 18132017.

[3] Baye, M. R.; Morgan, J. (1999). "A folk theorem for one-shot Bertrand games". Economics Letters. 65: 59–65. CiteSeerX 10.1.1.508.1579. doi:10.1016/s0165-1765(99)00118-4.

[4] Jann, O.; Schottmüller, C. (2015). "Correlated equilibria in homogeneous good Bertrand competition". Journal of Mathematical Economics. 57: 31–37. doi:10.1016/j.jmateco.2015.01.005.

[5] Edgeworth, Francis (1889) "The pure theory of monopoly". Reprinted in Collected Papers relating to Political Economy. Vol. 1. Macmillan. 1925.

[6] Dixon, Huw David (July 1993). "Integer Pricing and Bertrand–Edgeworth Oligopoly with Strictly Convex Costs: Is It Worth More Than a Penny?". Bulletin of Economic Research. 45 (3): 257–68. doi:10.1111/j.1467-8586.1993.tb00570.x.

[7] Bruttel, Lisa V. (2009-01-01). "Group dynamics in experimental studies—The Bertrand Paradox revisited". Journal of Economic Behavior & Organization. 69 (1): 51–63. doi:10.1016/j.jebo.2008.10.002. ISSN 0167-2681.

[8] Maskin, Eric (1986). "The Existence of Equilibrium with Price-Setting Firms". The American Economic Review. 76 (2): 382–386. ISSN 0002-8282. JSTOR 1818801.

[9] Soeiro, Renato; Adrego Pinto, Alberto (2 June 2019). "Social power as a solution to the Bertrand Paradox". Munich Personal RePEc Archive.

[10] Kaimann, Daniel; Hoyer, Britta (2019-01-02). "Price competition and the Bertrand model: the paradox of the German mobile discount market". Applied Economics Letters. 26 (1): 54–57. doi:10.1080/13504851.2018.1436141. ISSN 1350-4851. S2CID 158758649.

[11] Chernev, Alexander (2004-12-01). "Goal Orientation and Consumer Preference for the Status Quo". Journal of Consumer Research. 31 (3): 557–565. doi:10.1086/425090. ISSN 0093-5301. S2CID 17077046.

[12] Jost, Peter‐J.; Ressi, Anna (2022-04-18). "What can I do for you? Optimal market segmentation in service markets". Production and Operations Management. 31 (7): 2838–2852. doi:10.1111/poms.13720. hdl:10419/265036. ISSN 1059-1478. S2CID 247605694.

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v t e Notable paradoxes
Philosophical	Analysis Buridan's bridge Dream argument Epicurean Fiction Fitch's knowability Free will Goodman's Hedonism Liberal Meno's Mere addition Moore's Newcomb's Nihilism Omnipotence Preface Rule-following Sorites Theseus' ship White horse Zeno's
Logical	Barber Berry Bhartrhari's Burali-Forti Court Crocodile Curry's Epimenides Free choice paradox Grelling–Nelson Kleene–Rosser Liar Card No-no Pinocchio Quine's Yablo's Opposite Day Paradoxes of set theory Richard's Russell's Socratic Hilbert's Hotel Temperature paradox Barbershop Catch-22 Chicken or the egg Drinker Entailment Lottery Plato's beard Raven Ross's Unexpected hanging "What the Tortoise Said to Achilles" Heat death paradox Olbers' paradox
Economic	Allais Antitrust Arrow information Bertrand Braess's Competition Income and fertility Downs–Thomson Easterlin Edgeworth Ellsberg European Gibson's Giffen good Icarus Jevons Leontief Lerner Lucas Mandeville's Mayfield's Metzler Plenty Productivity Prosperity Scitovsky Service recovery St. Petersburg Thrift Toil Tullock Value
Decision theory	Abilene Apportionment Alabama New states Population Arrow's Buridan's ass Chainstore Condorcet's Decision-making Downs Ellsberg Fenno's Fredkin's Green Hedgehog's Inventor's Kavka's toxin puzzle Morton's fork Navigation Newcomb's Parrondo's Preparedness Prevention Prisoner's dilemma Tolerance Willpower
List Category

v t e Topics in game theory
Definitions	Congestion game Cooperative game Determinacy Escalation of commitment Extensive-form game First-player and second-player win Game complexity Graphical game Hierarchy of beliefs Information set Normal-form game Preference Sequential game Simultaneous game Simultaneous action selection Solved game Succinct game
Equilibrium concepts	Bayes correlated equilibrium Bayesian Nash equilibrium Berge equilibrium Core Correlated equilibrium Epsilon-equilibrium Evolutionarily stable strategy Gibbs equilibrium Mertens-stable equilibrium Markov perfect equilibrium Nash equilibrium Pareto efficiency Perfect Bayesian equilibrium Proper equilibrium Quantal response equilibrium Quasi-perfect equilibrium Risk dominance Satisfaction equilibrium Self-confirming equilibrium Sequential equilibrium Shapley value Strong Nash equilibrium Subgame perfection Trembling hand
Strategies	Backward induction Bid shading Collusion Forward induction Grim trigger Markov strategy Dominant strategies Pure strategy Mixed strategy Strategy-stealing argument Tit for tat
Classes of games	Bargaining problem Cheap talk Global game Intransitive game Mean-field game Mechanism design n-player game Perfect information Large Poisson game Potential game Repeated game Screening game Signaling game Stackelberg competition Strictly determined game Stochastic game Symmetric game Zero-sum game
Games	Go Chess Infinite chess Checkers Tic-tac-toe Prisoner's dilemma Gift-exchange game Optional prisoner's dilemma Traveler's dilemma Coordination game Chicken Centipede game Lewis signaling game Volunteer's dilemma Dollar auction Battle of the sexes Stag hunt Matching pennies Ultimatum game Rock paper scissors Pirate game Dictator game Public goods game Blotto game War of attrition El Farol Bar problem Fair division Fair cake-cutting Cournot game Deadlock Diner's dilemma Guess 2/3 of the average Kuhn poker Nash bargaining game Induction puzzles Trust game Princess and monster game Rendezvous problem
Theorems	Arrow's impossibility theorem Aumann's agreement theorem Folk theorem Minimax theorem Nash's theorem Negamax theorem Purification theorem Revelation principle Sprague–Grundy theorem Zermelo's theorem
Key figures	Albert W. Tucker Amos Tversky Antoine Augustin Cournot Ariel Rubinstein Claude Shannon Daniel Kahneman David K. Levine David M. Kreps Donald B. Gillies Drew Fudenberg Eric Maskin Harold W. Kuhn Herbert Simon Hervé Moulin John Conway Jean Tirole Jean-François Mertens Jennifer Tour Chayes John Harsanyi John Maynard Smith John Nash John von Neumann Kenneth Arrow Kenneth Binmore Leonid Hurwicz Lloyd Shapley Melvin Dresher Merrill M. Flood Olga Bondareva Oskar Morgenstern Paul Milgrom Peyton Young Reinhard Selten Robert Axelrod Robert Aumann Robert B. Wilson Roger Myerson Samuel Bowles Suzanne Scotchmer Thomas Schelling William Vickrey
Miscellaneous	All-pay auction Alpha–beta pruning Bertrand paradox Bounded rationality Combinatorial game theory Confrontation analysis Coopetition Evolutionary game theory First-move advantage in chess Glossary of game theory List of game theorists List of games in game theory No-win situation Solving chess Topological game Tragedy of the commons Tyranny of small decisions

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References[edit]