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Explore the concept of non-convexities in microeconomics, their impact on efficiency, implementation, and market dynamics. Learn about related terms, efficiency implications, and welfare economics. Delve into the complexities of firm behavior, market failures, and competitive equilibrium.
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Prerequisites Almost essential Welfare: Efficiency Adverse selection Non-convexities MICROECONOMICS Principles and Analysis Frank Cowell August 2006
Introduction • What are non-convexities? • …awkward name • …crucial concept • Concerned with production… • drop the convenient divisibility assumption • potentially far-reaching consequences • Approach: • start with examination of economic issues • build a simple production model • examine efficiency implications • consider problems of implementation and policy • Terms other than “non-convexities” sometimes used… • …not always appropriately • but can give some insight on to the range of issues:
Other terms…? • “Increasing returns” • but increasing returns everywhere are not essential • “Natural monopoly” • but issue arises regardless of market form… • … not essentially one of industrial structure • “Public utilities” • but phenomenon is not necessarily in the public sector • None of these captures the concept exactly • We need to examine the economic issues more closely…
Non-convexities Overview... The issues Basic model The nature of non-convexities Efficiency Implementation
Issues: the individual firm • Consider supply by competitive firms • upward-sloping portion of MC curve • supply discontinuous if there is fixed cost • If there are lots of firms • average supply is approximately continuous • so we can get demand=supply at industry level • If there is in some sense a “natural monopoly” • perhaps very large fixed cost? • perhaps MC everywhere constant/falling? • no supply in competitive market? • In this case…. • how does the firm cover costs? • how “should” the firm behave? • how can it be induced to behave in the required manner?
Issues: efficient allocations • Related to the issue discussed for firm • Concerns implementation through the market • non-convexities seen an aspect of “market failure”? • consider reason for this… • …and a solution? • Relationship between CE and efficiency • fundamental to welfare economics • examine key questions of implementation • First a simple example of how it works…
f h q2 x2 f` h` q1` x1` Implementation through the market • Production possibilities Uh(xh) = Uh(x*h) • Firm f max profits • U contour • h min expenditure Ff(qf) = 0 p1 — p2 p1 — p2 q*f x*h now for the two key questions. • all f and h optimise at these prices such that • …for all pairs of goods MRS = MRT= price ratio
Efficiency and the market: key questions • Is a competitive equilibrium efficient? • Yes if all consumers are greedy, there is no hidden information, and there are no externalities • Can an arbitrary Pareto-efficient allocation be supported by a competitive equilibrium? • Yes if all consumers are greedy, there is no hidden information, there are no externalities and no non-convexities • If there are non-convexities the equilibrium price signals could take the economy away from the efficient allocation
Non-convexities Overview... The issues Basic model Back to the firm…. Efficiency Implementation
A model of indivisibility (1) • Take simplest model of production: • a single output (q)… • …from a single input (z) • The indivisibility: • A fixed amount of input required before you get any output • Otherwise production is conventional • q = f(z− k) , z≥ k • f(0) = 0, fz(∙) > 0, fzz(∙) ≤ 0 • q = 0, z< k • Given a required amount of output q > 0… • minimum amount of z required is: • f−1(q) + k
Case 1 Case 2 q q z z A model of indivisibility (2) • The minimum input requirement • fz(∙) > 0, fzz(∙) < 0 • Attainable set 0 k • The minimum input requirement • fz(∙) > 0, fzz(∙) = 0 • Attainable set 0 k
A model of indivisibility (3) • Suppose units of input can be bought for w • What is cost of output q? • clearly C(w, 0) = 0 and • C(w,q) = v(w,q) + C0, for q > 0, • where variable cost is v(w,q) = wf−1(q) • and fixed cost is C0 = wk • Therefore: • marginal cost: w / fz(f−1(q)) • average cost: wf−1(q) / q + C0 / q • In the case where is f a linear function • f−1(q) = aq • marginal cost: aw • average cost: aw+ C0 / q • Marginal cost is constant or increasing • Average cost is initially decreasing
Case 1 Case 2 p p q q A model of indivisibility (4) • Average cost • Marginal cost • Supply of competitive firm 0 • Average cost • Marginal cost • Supply of competitive firm 0
“Natural Monopoly” • Subadditivity • C(w, q + q) < C(w, q) + C(w, q) • Natural monopoly • Apply the above inequality… • C(w, 2q) < 2C(w, q) • And for any integer N > :1 • C(w, Nq) < NC(w, q) • Cheaper to produce in a single plant rather than two identical plants • But subadditivity consistent with U-shaped average cost • Does not imply IRTS
Non-convexity: the economy • Now transfer this idea to the economy as a whole • Use the same type of production model • An economy with two goods • Good 1. A good with substantial setup costs • Rail network • Gas supply system • Electricity grid • Good 2. All other goods • Assume: • a given endowment of all good 2 • good 1 is not essential for survival • Consider consumption possibilities of two goods x1, x2
x2 x1 Fundamental non-convexity (1) • Endowment of good 2 • Fixed set-up cost to produce good 1 • Possibilities once fixed-cost has been incurred • x° • Attainable set is shaded area + “spike” • Endowment point x° is technically efficient 0
x2 x1 Fundamental non-convexity (2) • Endowment of good 2 • Fixed set-up cost to produce good 1 • Possibilities once fixed-cost has been incurred • x° • MRT is everywhere constant • Again endowment point x° is technically efficient 0
Non-convexities Overview... The issues Basic model An extension of the basic rules of thumb Efficiency Implementation
Competitive “Failure” and Efficiency Requires a modification of first-order conditions • Characterisation problem: Implementation problem: Involves intervention in, or replacement of, the market Usually achieved through some “public” institution or economic mechanism
Efficiency: characterisation • Two basic questions: • Should good 1 be produced at all? • If so, how much should be produced? • The answer depends on agents’ preferences • assume… • …these represented by conventional utility function • …all consumers are identical • Method: • use the simple production model • examine efficiency in two cases… • …that differ only in representative agent’s preferences
x2 x1 Efficiency characterisation: case 1 • Attainable set as before • Reservation indifference curve • Indifference map • Point where MRS=MRT • x° • Efficient point • Attainable set is shaded area + “spike” • x′ • In this case MRS=MRT is not sufficient • Utility is higher if x1 = 0 0
x2 x1 Efficiency characterisation: case 2 • Attainable set as before • Indifference map • Consumption if none of good 1 is produced • x° • The efficient point • x′ 0
Non-convexities Overview... The issues Basic model The market and alternatives Efficiency • Full information • Asymmetric information Implementation
Efficiency: implementation • Move on from describing the efficient allocation • What mechanism could implement the allocation? • Consider first the competitive market: • Assume given prices… • …profit-maximising firm(s) • Then consider a discriminating monopoly • Allow nonlinear fee schedule • Then consider equivalent regulatory model • Maximise social welfare… • … by appropriate choice of regulatory régime
x2 • x° • x′ x1 0 Nonconvexity: effect of the competitive market • Efficient to produce where MRS=MRT • Iso-profit-line • Profit-maximisation over the attainable set p1 — p2
x2 x1 Nonconvexity: efficient fee schedule • Efficient to produce at x' • MRS=MRT • Fixed charge • x° • Variable charge • x′ p1 — p2 0
Implementation: problem • Situation • U(x′)> U(x°) : x′ is optimal • Prices at x′ given by MRS • Competitive “solution”: • Firms maximise profits by producing x1 = 0 at these prices. • Goodbye Railways? • Simple monopoly: • Clearly inefficient… • …monopoly would force price of good 1 above MC • Discriminating monopoly • A combination of fixed charge… • …plus linear variable charge • How to implement this?
Implementation: analysis • Set up as a problem of regulating the firm • produces output q of good 1 • values denominated in terms of good 2 • Regulator can: • observe quantity of output • grant a subsidy of F • F is raised from consumers • through non-distortionary taxation? • Criterion for regulator • a measure of consumer welfare • the firm’s profits • Take case where regulator is fully informed
Regulation model: the firm • There is a single firm – regulated monopoly • Firm chooses output q, given • price-per unit of output p(q) allowed by regulator • fixed payment F • costs C(q) • The firm’s revenue is given by • R = p(q) q+ F • Firm’s profits are • P= R C(q) • Firm seeks to maximise P subject to regime fixed by regulator
Regulation model: the regulator • Regulator can fix • price per unit p • fixed payment to firms F • But, given the action of the firm • revenue is R = p(q) q+ F • choosing q to max profits • …fixing p(∙) and F is equivalent to fixing • firm’s output q • firm’s revenue R • So transform problem to one of regulator choosing (q, R)
Regulation model: objectives • Assume consumers are identical • take a single representative consumer • consumes x1 = q • Assume zero income effects • so take consumer’s surplus (CS) as a measure of welfare q • CS(q, R) = ∫0 p(x) dx R • Note properties of CS(∙): • CSq(q, R) = p(q) • CSR(q, R) = 1 • Social valuation taken a combination of welfare and profits: • V(R, q) = CS(q, R) + b [R C(q)] • b < 1 • Note derived properties of V(∙): • Vq(q, R) = p(q) bCR(q) • VqR(q, R) = 1 + b
Regulation model: solution • Problem is choose (q, R) to max V (q, R) subject to R C(q) ≥ 0 • Lagrangean is • V(q, R) + l [R C(q) ] • If “*” denote maximising values, first-order conditions are • Vq(q*, R*) −l*Cq(q*) = 0 • VR(R*, q*) + l* = 0 • l* [R C(q*)] = 0 • Evaluate using the derivatives of V: • 1− b + l* = 0 • p(q*) bCR(q*) −l*Cq(q*) = 0 • Clearly l* = 1− b > 0 and from the FOCs • R*= C(q*) • p(q*) = CR(q*) • So the (q* , R *)programme induces a zero-profit, efficient outcome
Provisional summary supplement the MRS = MRT rule by a "global search" rule for the optimum. • Characterisation problem: Implementation problem: Set user prices equal to marginal cost Cover losses (from fixed cost) with non-distortionary transfer Don't leave it to the unregulated market....
Non-convexities Overview... The issues Basic model Regulation… Efficiency • Full information • Asymmetric information Implementation
The issue • By hypothesis there is only room for only one firm • The efficient payment schedule requires • A per-unit payment such that P = MC • A fixed amount required to ensure break-even • However, implementation of this is demanding • requires detailed information about firm’s costs • by hypothesis, there isn't a pool of firms to provide estimates • To see the issues, let’s take a special case • Two possible types of firm • Known probability of high-cost/low-cost type
' x1 Low-cost type • Preferences x2 • Efficient to produce where MRS=MRT • Amount of good 1 produced • x° F' • Efficient payment schedule • q =x1' is the amount that the regulator wants the low-cost type to produce • x' • F' is the (small) fixed charge allowed to the low-cost type by the regulator p • p is the variable charge allowed to low-cost type by the regulator (=MC) x1 0
'' x1 High-cost type • Preferences x2 • Efficient to produce where MRS=MRT • Amount of good 1 produced • x° F'' • Efficient payment schedule • Essentially same story as before • But regulator allows the high-cost type the large fixed charge F'' • x'' x1 0
'' ' x1 x1 Misrepresentation • Production possibilities and solution for low-cost type x2 • Production possibilities and solution for high-cost type • Outcome if low-cost type masquerades as high-cost type • High-cost type is allowed higher fixed charge than low-cost type • x' • x'' • Low-cost type would like to get deal offered to high-cost type x1 0
Second-best regulation: problem • Regulator is faced with an informational problem • Must take into account incentive compatibility • Design the regime such that two constraints are satisfied • Participation constraint • firm of either type will actually want to produce positive output • must at least break even • Incentive compatibility constraint • neither firm type should want to masquerade as the other… • …in order to profit from a more favourable treatment • each type must be allowed to make as much profit as if it were mimicking the other type • Requires a standard adaptation of the optimisation problem
Second-best regulation: solution • Model basics • low-cost firm is a-type – cost function Ca(∙) • high-cost firm is b-type – cost function Cb(∙) • probability of getting an a-type is p • objective is EV(q, R) = pV(qa, Ra) + [1−p]V(q, Rb) • Regulator chooses (qa, qb, Ra, Rb) to max EV(q, R) s.t. Rb Cb(qb) ≥ 0 Ra Ca(qa) ≥Rb Ca(qb) • Lagrangean is pV(qa, Ra) + [1−p]V(q, Rb) + l [Rb Cb(qb) ] + m [Ra Ca(qb) Rb + Ca(qa) ] • Get standard second-best results: • type a: price = MC, makes positive profits • type b: price > MC, makes zero profits
Conclusion • May give rise to inefficiency if we leave everything to the market • if there are non-convexities,,, • …separation result does not apply • So the goods may be produced in the public sector • but they are not “public goods” in the conventional sense • public utilities? • Could private firms implement efficient allocation? • for certain goods – a monopoly with entrance fee • may be able to implement through pubic regulation • but may have to accept second-best outcome