Friday, August 30, 2019
Microeconomics â⬠Summary Essay
Linear demand curve: Q = a ââ¬â bP Elasticity: E d = (ÃâQ/ÃâP)/(P/Q) = -b(P/Q)E d = -1 in the middle of demand curve (up is more elastic) Total revenue and Elasticity:Elastic: Ed < -1ââ âPââ âââ âR (ââ âP by 15%ââ âââ âQ by 20%) Inelastic: 0 > Ed > -1ââ âPââ âââ âR (ââ âP by 15%ââ âââ âQ by 3%) Unit elastic: Ed = -1R remains the same (ââ âP by 15%ââ âââ âQ by 15%) MR: positive expansion effect (P(Q) ââ¬â sell of additional units) + price reduction effect (reduces revenues because of lower price (ÃâP/ÃâQ)/Q) 1. Monopoly ââ¬â maximizes profit by setting MC = MR Monopolistââ¬â¢s Markup = price-cost margin = Lerner index: (P-MC)/P = -1/ Ed (the less elastic demand, the greater the markup over marginal cost) 2. Price Discrimination Perfect price discrimination ââ¬â the firm sets the price to each individual consumer equal to his willingness to payMR=P(Q)=demand (without the price reduction effect), no consumer surplus,find profit from graph Two-part Tariffs ââ¬â a fixed fee (= consumer surplus) + a separate per-unit price for each unit they buy (P = MC) 2 groups of customers ââ¬â with discrimination: inverse demand function for individual demands ââ â MR ââ â MR=MC * without discrimination: sum of not-inverse demand functions = one option for aggregate demand. Other option is the ââ¬Å"richâ⬠people demand function. Compare profits to find Qagg. * max fixed payment F (enabling discrimination) = âËâ Ãâ¬; max d added to MC1 = âËâ Ãâ¬/q1 (with discrimination) Quantity-dependent pricing ââ¬â one price for first X units and a cheaper price for units above quantity X. profit function = Ã⬠= Pa*Qa+Pb(Qb-Qa)-2Qb Qb includes Qa, so the additional units sold are Qb-Qa. Example: P=20-Q. Firm offers a quantity discount. Setting a price for Qa (Pa) and a price for additional units Qb-Qa (Pb). Pa=20-Qa Pb=20-Qb. à =(20-Qa)Qa + (20-Qb)(Qb-Qa) -2Qb = 18Qb-Qa^2 ââ¬â Qb^2 +QaQb derive Ãâ¬Ã¢â¬â¢a=-2Qa+Qb Ãâ¬Ã¢â¬â¢b=18-2Qb+Qa compare to 0. 2Qa=Qb. Plug into second function: 18-2(2Qa)+Qa=0. So Qa=6 Qb=12 3. Cost and Production Technologies Fixed costs: avoidable ââ¬â not incurred if the production level = 0; unavoidable/sunk ââ¬â incurred even if production level = 0, donââ¬â¢t exist in theà long run, for the short run typical Efficient scale of production ââ¬â min AC: derivative of AC = 0; MC = AC Production technologies ââ¬â production method is efficient it there is no other way to produce more output using the same amounts of inputs Minimization problem ââ¬â objective function: min(wL+rK), constraint: subject to Q=f(K,L) ââ â express K as a function of L, Q (from production function)ââ â plug the expression into objective function (instead of K)ââ â derive with respect to L = 0 ââ â express L (demand for labor) ââ â plug demand for labor into K function ââ â express K (demand for capital) ââ â TC=wL+rK Marginal product ratio rule ââ¬â for f(K,L)=KaLb ââ¬â at the optimum: MPL/w = MPK/r : find MPL, MPK from production function ââ â find relationship bet ween K,L using marginal product ratio rule ââ â plug K/L into production function ââ â find K/L for desired level of production ââ¬â for f(K,L)=aK+bL: compare MPL/w, MPK/r ââ â use production factor with higher marginal value, if equal ââ¬â use any combination 4. Perfect Competition Short run ââ¬â 1. Quantity rule ââ¬â basic condition: MR = P = MC ââ â 2. Shut-down rule: P(Q) ÃÆ' AC(Q) produce MR=MC, P(Q) Ãâ AC(Q) shut down, P(Q) = AC(Q) ââ¬â profit = 0 for both options * shut-down quantity and price: min AC (derivative of AC = 0); AC=P=MC (profit = 0) * when computing AC ignore unavoidable/sunk fixed costs (not influenced by our decision) ââ¬â market equilibrium: multiply individual supply functions (from P=MC example TC = 4q^2 so MC = 8q compare to p so 8q=p so q=p/8) by number of firms = aggregate supply function Qs ââ â Qs=Qd (demand function) ââ â equilibrium price and quantity Long run ââ¬â profits = 0 ââ â P=AC, equilibrium: MR=P=MC=ACmin * in the long run, unavoidable/sunk cost donââ¬â¢t exist ââ â fixed costs are avoidable ââ â take them into account ââ¬â market equilibrium: find individual supply function (MC=P), quantity produced by 1 firm (MC=AC =price ââ â plug price into demand function ââ â total quantity demanded ââ â number of firms in the market = total quantity demanded/quantity produced by 1 firm 5. Oligopolistic Markets Game Theory ââ¬â Nash Equilibrium: each firm is making a profit-maximizing choice given the actions of its rivals (cannot increase profit by changing P or Q); best response = a firmââ¬â¢s most profitable choice given the actions of its rivals Bertrand Model ââ¬â setting prices simultaneously; 1 interaction:à theoretically max joint profit when charging monopoly price (MC=MR) but undercutting prices ââ â P=MC, Ãâ¬= 0; infinitely repeated: explicit x tacit collusion (when r is not too high) Cournot Model ââ¬â choosing quantity (based on beliefs on the other firmââ¬â¢s production) simultaneously ââ â market price ââ¬â market equilibrium: residual demand for firm 1 from the inverse demand function ââ â profit 1 as a function of q1, q2 ââ â derivative = 0 ââ â best response function for firm 1 ââ â same steps for firm 2 ââ â find q1, q2, market quantity ââ â price, profits Stackelberg Model ââ¬â choosing quantities sequentially ; firm 1 not on its best response function ââ â higher profit, firm 2 is ââ¬â market equilibrium: find best response function of firm 2 ââ â plug into profit function of firm 1 ââ â derivative = 0 ââ â q1, q2 (from BR2 function) ââ â price, profits
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