Joint Bidding under Capacity Constraints

doi:10.4236/am.2011.210178

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Applied Mathematics, 2011, 2, 1279-1291

doi:10.4236/am.2011.210178 Published Online October 2011 (http://www.SciRP.org/journal/am)

Joint Bidding under Capacity Constraints

Beatriz De Otto-López

University of Oviedo, Oviedo, Spain

E-mail: bdeotto@uniovi.es

Received July 14, 201 1; revised August 30, 2011; accepted September 7, 201 1

Abstract

In this paper we analyze the anticompetitive effects of concentration of ownership in auction markets. We

compare two different auction formats with uniform price. In the first, the price equals the highest accepted

bid, whereas in the second the price equals the lowest rejected bid. For the former, and for a two-unit,

two-plants, two-firms model, we find an equilibrium where all plants (all firms) bid according to a common

bidding function. The concentration of the ownership has the same effect on the bidding behavior as elimi-

nating one plant. However, the expected price is lower than the one expected in such three independent plant

scenario. More surprisingly (and special to this 2 × 2 × 2 case), the equilibrium is efficient. In the latter, al-

ternative auction format, firms bids asymmetrically for its two plants. Hence, the equilibrium is inefficient.

Also, with this format, we show that the market price may be arbitrarily large. Thus, and contrary to some

plausible expectation base in received auction theory, a (sealed-bid) auction format in which the price for a

bidder is unrelated to his bid becomes less efficient than one in which the price may coincide with that bid-

der’s bid, when one admits that several bidders may coordinate (through ownership) their bids. The results

add to a literature that favors more winner’s-bid pricing rules.

Keywords: Uniform-Price Auction Formats, Capacity Constraints, Ownership Structure, Collusion

1. Introduction

The concentration of ownership in an industry—a

smaller number of firms, each of which owns a larger

size of capacity- increases market power, and this results

in price increases compared to a situation in which own-

ership is disperse. This has been well studied and docu-

mented in decentralized markets. The purpose of this

paper is to investigate whether the concentration has the

same anticompetitive effect in auction markets.

This paper is motivated by some experiences in the

reform of regulation of the electricity industry aiming at

introducing competition at the generation level, usually

characterized by a high degree of concentration. As an

example of such experiences, the Spanish electricity in-

dustry is dominated by two major generators, Iberdrola

and Endesa, which own most of the generation plants

and set the market price at the pool near 90 per cent of

the times. However, the bidding units in the pool are the

generation plants, which must submit their price asks

simultaneously. Obviously, the bids of the plants be-

longing to the same firm are not independent. In other

words, firms have the ability to strategically choose the

bids of their plants in a manner that can be different to

the one we could expect if each plant were owned by a

different firm. This ability allows the firms to increase

the market price relative to a situation in which the own-

ership is disperse. How large is this price increase de-

pends on the price formation rules of the mechanism.

In this paper we study a multi-unit auction mechan ism

for two units (the market demand), with four production

plants—the bidders-with one unit production capacities,

whose cost are independent draws of the same random

variable. The two pants that submit the lowest bids are

called to produce one unit each. We consider two differ-

ent uniform-price auction formats, one with price equal

to the bid of the last seller called to produce, and the oth-

er with price equal to the lowest unsuccessful bid.

We describe a concentrated ownership structure in

which two firms own two plants each. Thus, a given firm

decides on the bids of the two plants it owns. In principle,

a bidding strategy of a firm could consist on a pair of

bidding functions (one for each plant), each one depend-

ing on the costs of the two plants this firm owns. How-

ever, we show that at any symmetric eq uilibriu m, and for

either of the two auction formats, the bidding functions

1280 B. DE OTTO-LÓPEZ

are independent in the sense that its bid depend on its

cost (apart from its ranking among the plants of the same

firm), and not on the cost of other plants of the same

firm.

For the auction format with price equal to the highest

successful bid, we show that there exists a monotone

symmetric equilibrium in which the two types of pants

(the more and the less efficient ones belonging to the

same firm) use the same bidding function. Moreover,

such function is the symmetric equilibrium bidd ing func-

tion of an auction for two units with the same price for-

mation rules buy only three plants owned by independent

firms. It is easy to check that this function is everywh ere

above the symmetric equilibrium one for the case of four

independent plants. Thus, the concentration of the own-

ership induces the plants to bid higher compared to a

situation with disperse ownership. More precisely, they

bid as if there were just three plants in competition.

Hence, the concentration has the same effect on the bid-

ding behavior as eliminating one plant. As the plants bid

higher with concentrated ownership, the expected price

is greater than with four independent plants, but it is

lower than with three independent plants. Indeed, with

three plants, the price is set by the plant with the second

lowest of three realizations of the cost, whereas with

concentrated ownership, the price is set by the one with

the second lowest of four realizations. In other words, the

concentration of the ownership increases the price with

respect to a situation in which the plants belong to inde-

pendent firms, but not as much as eliminating one plant.

More surprisingly, this equilibrium is efficient, as all

plants bid according to a monotone increasing function,

and hence, by scheduling the lowest bidders, the mecha-

nism calls to produce the plants with the lowest costs.

For the auction format with price equal to the lowest

unsuccessful bid, Vickrey [1] has shown that bidding the

cost is a weakly dominant strategy when bidders can at

most be awarded with one unit (in our model, this is as to

say that ownership is disperse). Ausubel and Cramton [2]

and Engelbrecht-Wiggans and Kahn [3] analyze a me-

chanism in which (exchanging the roles of buyers and

sellers) bidder can win more than one unit of an indivisi-

ble good1. For a bidder that desires more than one unit

there is a positive probability that the bid for the second

or latter units determines the price paid for the other

units that he wins. Therefo re, there is an incentive to bid

truthfully on the first unit, but to shade the true valuation

of the second and subsequent ones, in order to decrease

the price of the unit it wins. Thus, there is a positive

probability that the mechanism result in ex post ineffi-

cient allocations. There is also a recently increasing re-

search analyzing alternative auction designs and pricing

rules for wholesale electricity markets (see, for instance,

Cramton et al. [5], Federico and Rahman [6], Fabra [7],

Cramton and Stoft [8], and Tierney et al. [9]).

Our model of concentrated ownership, where the

plants bid for the right to supply the market demand, is

equivalent to auction models where the bidder wants

more than one unit. Thus, for the auction format where

the price equals the lowest rejected bid our results are in

line with those in Engelbrecht-Wiggans and Kahns’;

bidding the true cost of the first plant is a weakly domi-

nant strategy, but the bid of the second plant must be

above the cost. As in their model, inefficiencies arise as

there is a tendency towards disseminating the units

across firms more than what the relative costs would

indicate. Moreover, also in line with their results, we

show that there exists a continuum of monotone sym-

metric equilibria in which the market price is arbitrarily

large.

Certainly, the efficiency result for the alternative auc-

tion format is special to the 2 × 2 × 2 model we analyze

(although it is also true with some other special market

configurations). Nevertheless, it points to better effi-

ciency and revenues properties of an auction format that

is more similar to a “pay your bid” auction, as compared

to one more similar to second price auction2. Our claims

is that the auction format with price equal to the best

unsuccessful bid gives larger opportunities to tacit collu-

sion among the bidders than the format with price equal

to the worse successful bid. Indeed, in the former, all

equilibria are inefficient, and the b idders have the ability

to coordinate on “split award” equilibria at which they

can increase the price with no bound.

The rest of the paper is organized as follows. In Sec-

tion 2 we describe the model and we prove the inde-

pendence of the bidding functions. In Section 3 we ex-

amine the auction format with price equal to the highest

successful bid, and we show that there exists an equilib-

rium in which all the plants bid according to the same

bidding function. In Section 4 we analyze the auction

with price equal to the lowest unsuccessful bid, and we

show that there exists a collection of equ ilibria with price

arbitrarily large. Section 5 contains some of the con-

cluding remarks. The appendix contains some of the

proof.

2. The Model

There are two firms, which own two production plants

each. Each plant has production capacity for one unit.

1Also Brusco and Lopomo [4] analyze a multi-object version of the

English oral auction with heterogeneous objects that can be sold at

different prices. They find that the possibility of signaling trough the

bids allows the buyers to split the objects among them at low prices.

2This is yet another example of how intuitions based on single objects

auctions may be inadequate for multi-unit auctions; see for instance the

discussion in Ausubel and Cramt o n ( 1 9 9 8 ).

B. DE OTTO-LÓPEZ

1281

The unit costs of the plants are constant. They are inde-

pendent draws of a random variable with cumulative

density function F and distribution function f. The sup-

port of the distribution is





,cc . This is common

knowledge. The cost of a plant is private information to

the firm that owns the plant.

The market demand of the good is equal to two units

for any price.

The sellers compete in a pool mechanism for the right

to supply one unit of output. Each plant submits a bid

that represents the price at which this plant offers this

unit. The pool ranks the bids in ascending order and calls

the two plants which submit the two lowest bids to pro-

duce. The auction is a uniform price one. That means

that the two plants in the schedule are paid the same

price. However, we consider two auction formats which

differ in the manner this uniform price is determined. In

one case, the price is equal to the bid of the last plant

called to produce, that is, the highest successful bid. In

the second case, the market price is equal to the lowest

unsuccessful bid.

The Bidding Strategies

Each firm observes the costs of the plants it owns, that

we denote by 1 and 2, with 12

. Then, the firms

simultaneously submits two bids each, 1 and 2, with

. A bidding strategy for a firm is a pair of bidding

functions 2

and



cccb b

bb



bcc





212

, which determines

the bids of the two plants that the firm owns. It is

straightforward that at any equilibrium the lowest bid

must correspond to the plant with the lowest cost

cWe look for symmetric equilibria of these games. Our

first result, which applies to both au ction formats, greatly

simplifies this question.

Proposition 1. In any symmetric equilibrium, the bid-

ding functions are independent in the following sense:

conditional on that the cost of a given plant is greater

that (or less than) the cost of the other, its bid depends

only on its cost, and not on the cost of the other plant

owned by the firm. This holds for the two auction formats;

with price equal to the highest successful bid and with

price equal to the lowest unsuccessful bid.

Proof. See the appendix.

Thus, at any symmetric equilibrium any firm must

behave as follows. First, it must observe the costs of its

two plants in order to identify the one with the low cost

1. Then, the firm assigns a bidding function to each

plant, so that the plant with low cost bids according to

the function 1 (depending only on the cost of the first

plant), and the plant with the high cost bids according to

the function 2 (depending only on its cost), where

for any



 

bc b





,ccc.

The intuition behind this result is the following. Let us

consider first a mechanism in which the uniform price is

equal to the bid of the last plant called to produce. The

bid 1 can affect the profits of the firm as much as it

affects whether the first plant producer or not or if it af-

fects the price this plant obtains. In particular, it cannot

affect whether or not plant 2 produces or the price in the

market when it happens. Hence, the bid must depend

solely on .

Suppose now that the firm decreases 2 by



(with





still above1

b). The profits of the firm change

only if plant 2 is at the second position before and after

lowering 2 (then the profits are reduced by b2



, that is,

the reduction of the price times the number of units the

firm produces), or if plant 2 moves from the third to the

second position, in which case the profits increase by



. As before, the changes in the profit caused by a

change in 2 do not depend on the cost 1 of the other

plant. Therefore, the op timum bidding function does

not depend o n .

b c

Let us consider now a mechanism with price equal to

the highest unsuccessful bid. Again, a change in 1

cannot affect the revenues or costs accruing from plant 2.

Suppose now that the firm reduces 2 by



. This

change affects the profits only if plant 2 is at the third

position before and after (then the profits are reduced by



, as much as the market price), of if the change in 2

moves plant 2 from the third to the second position, in

which case plant 2 enters the production schedule and the

profits increase by 22



. Again, these changes do not

depend on 1, and therefore, the optimum bidding func-

tion for plant 2 must depend only on .

Next we describe the conditions which define any

strictly monotone symmetric equilibrium strategies for

each of the two different price mechanisms we have con-

sidered.

3. When the Highest Successful Bid

Sets the Price

Let us consider first the case in which the price is equal

to the bid of the last plant called to produce. Think of a

firm with plants 1 and 2, whose costs are 1 and 2

respectively, which bids 1 and 2

b. Suppose that the

rival firm bids according to some strictly increasing (and

hence invertible) and differentiable functions and

with

c c









bc bc for any c.

If both plant 1 and plant 2 are called to produce, the

price is set by the second one and hence equal to 2.

Then, the profits of the firm are 212

. This oc-

curs when the lowest rival bid is higher than

2bcc





,

and hence, with probability

B. DE OTTO-LÓPEZ

1282



1.Fb b









If plant 1 is the first one in the ranking and plant 2 is

off the production schedule, then the price is equal to the

lowest rival bid. The expected profits conditional on 1

being the first on the ranking and being strictly

above the second position are

 



 



21 d.

21 d

bzcFzfz z

Fzfz z















The denominator in this expression is the probability

that the lowest rival bid is between and .

1 2

Finally, if plant 1 is the second lowest bidder, that is,

the one that sets the price, then the profits of the firm are



. This occurs when the lowest cost of the rival firm

is less than





, and the highest is greater than





1

(notice that





21 11

bb bb







), and hence with

probability

 



 



21 d

21 d,

Fbbfz z

Fzfz z

















or equivalently,

 

11 1

11 1121

2.Fb bFb bFb b

 



  





  

Summarizing, the expected profits of a firm with costs

and bidding and are

b b

  



 

12122 1 21211

111

11 111121

,,, 2121d

bbccbccFbbbzcFzf zz

bcFb bFb bFbb







 









 









 (1)

Setting the partial derivative with respect to equal to zero for





111

bbc and we obtain



222

bbc

 



 



111

1121111 1211211211

22FcFcFbbcbccFbbcfbbcDbbc



 

 

 

 

 



(2)

where 1 represents the deri vat ive of t he f unction 1

2 2

Dbb



. Second, if plant 1 was the second one in the ranking

before raising the bid and moves to the third position (off

the schedule) by increasing 1. Then, the profits de-

crease by b





11 1

bcc



. This occurs with probability

The intuition behind this condition is the following.

Suppose that the firm slightly increases 1. This affects

the profits of the firm only in two cases. First, if plant 1

is the second in the ranking before and after raising the

bid, in which case the profits increase as much as the bid

(the market price). This occurs with probability

















111

211211 211

bbcfbbc Dbbc







Similarly, we obtain the F.O.C. with respect to 2 by

setting the partial derivative of the profit function with

respect to this variable equal to zero. That is

 



11211

2FcFcFb bc











 



111

12222 2122122122

21 210FbbcbccFbbcfbbcDbbc





 







 

 1



(3)

To understand this expression, again, suppose that the

firm increases 2 by an infinitesimal amount (say b



Then, its profits change only in two cases. First, if plant

2 is at the second position in the ranking before and after

raising the bid. In this case, the market price increases by



, and hence, the profits of the firm increase by 2



(notice that in this situation the two plants of the firm are

called to produce). This occurs with probability

These two effect must balance at the optimum bid





bc. This is what the second F.O.C. represents.

The initial conditions that complete the differential

system which defines the symmetric equilibrium bidding

strategies are





 

bc bcc

bc bc



 (4)



122

1Fbb c









Second, if the plant moves from the second to the third

position by increasing 2. Then, the profits of the firm

fall by . This occurs with probability



22 2

bc c



111

122122122

bbcfbbc Dbbc











The later condition is a usual one in asymmetric auc-

tions when the support of the distribution of the cost is

the same for the two type of bidders. Indeed, the differ-

ential system above and the boundary conditions define a

problem which is very similar to that of an asymmetric

auction with two type of bidders. In our case, each firm

owns one plant of each type; the plant with the low cost

B. DE OTTO-LÓPEZ

1283

for a given firm is of one type, say type 1, and the other

is of type 2.

In our case, we know that



bc must be less or

equal to



bc, so that a plant of type 1 with cost c is

called to produce with probability one. Suppose that



bc is strictly less than





bc. Then, the price paid

to plant 1 is less than



bc with some positive prob-

ability (the probability that the cost of the rival plant of

type 1 is between c and



bbc







. Plant 1 could,

instead, bid exactly



bc. By doing so the probability

that the plant enters into operation remains unchanged,

since the other firm never bids below



bc for its

second plant, but the market price may raise at least to



with probability one. So this would be a profitable

deviation. Hence,





must be no less than





Let us now explain the first initial condition above.

We need to show first that





bc must be no less than

c. Otherwise, a plant of type 1 and cost c would be at

the second position with some positive probability (recall

that for any

c and, in particular,

 

bc bc









2 and, hence, there could be some plant of type 2

whose bid is greater or equal to



bc). In this case,

plant 1 with cost c would make negative profits, as

price would be less than the cost c. If, instead, plant 1

bids exactly c, it would make zero profits with prob-

ability one.

Now, we need to show that at any symmetric mono-

tone equilibrium



bc must be equal to





bc. Sup-

pose not, that is,

 

bc bc, and think of a plant of

type 2 with cost slightly below c, say c



, bidding

something between



bc and



bc (by the continu-

ity of the function 2

b, there must exist a cost c





such that





 is between



bc and





bc).

As the two plans of type 1 bid less than



bc, the plant

bidding





 is called to produce with probability

zero. If, instead, this plant submits a bid between c





and



bc (this is possible as long as



bc c), it

would be the marginal plant with positive probability,

making positive profits.

Finally,



bc must be equal to c. Suppose that



bc c. Then plant 1 with cost c is off the schedule

with probability one (recall that

 

bc bc). If, in-

stead, this plant submits a bid between c and c, it

would be called to produce with positive probability at

some price above c, and its expected profits would be

positive.

Proposition 2. At any symmetric, strictly monotone

equilibrium of the auction with price equal to the highest

successful bid, the bidding functions 1 and 2

b must sat-

isfy the boundary conditions (4) and also it must hold that

  



11 1

cbbzfzz

bc Fc









Proof. See the appendix.

As is everywhere above 2, it must hold that

b b





bbz z











for any





,zcc. Thus, at any sym-

metric equilibrium, it must hold that

  



 

11 1

bbzfzz

bc Fc

zf zzbc













 (5)

where the function b is a symmetric equilibrium bidding

function in an auction for two objects (two units of de-

mand) and three independent bidders, with price equal to

the highest successful bid. The following proposition

shows that there is a symmetric equilibrium with con-

centrated ownership in which the four plants bids ac-

cording to the same bidding function and they all bid as

if there were just three plants owned by independent

firms.

Proposition 3. Bidding , where

 

bc bcbc

 



czfzz





constitutes an equilibrium when the price equals the

highest successful bid. That is, with this auction format

there exists an efficient equilibrium for the two firms, two

units, two plants case.

Proof. See the appendix.

Notice that





bc coincides with the bidding strategy

of three independent bidders competing for two units

when the price is the highest successful bid.

The intuition behind this result is simple. The bid 1

affects the profits of the firm only in case that plant 1

bidding 1 is the marginal plant. And if so, plant 2 is

off the schedule with probability o ne. That is, at the mar-

ginal position, the competitors of plant 1 are the two rival

plants which behave as independent bidders using a

common bidding strategy b. This is the same situation as

if there were just three plants in competition for the first

and second positions in the ranking.

Now consider the bid 2. As before, 2 affects the

profits of the firm only in case that plant 2 is the mar-

ginal one. If so, plant 1 is th e first in the ranking and the

firm produces two units. The gains from a higher price

following an increase in 2 is now twice as much as the

ones corresponding to higher . However, the “compe-

tition” faced when increasing 2 is also twice (two ex-

tramarginal rival plants, instead of one), and hence the

probability of incurring in loses is also twice higher.

Thus, the incentive of higher are exactly the same as

B. DE OTTO-LÓPEZ

1284

the incentives for higher .

Remark. Notice that this result hinges on the fact that

the number of competing plants for the less efficient

plant of a firm equals the number of plants of that firm.

A similar result holds for some other special market

configurations. Suppose that there are N firms that own

m plants each, which bid in an auction for k units with

unit price equal to the lowest bid. Then , it is easy to

check that if





1mN k



, then there exists a symmet-

ric equilibrium with all the plants bidding according to

the highest successful bid and bidders. In

other words, the plants bid as if the other plants of the

same firm where not real competitors. For a brief outlin e

of the proof, consider the first order condition for th e bid

of the plant with the lowest cost 1, given that all the

plants bid according to the same function b, that is,



11mN





 



 



111 11

111

mN k

cmNFcFcf c

cF cF c











 

 



 























(6)

Here, the right hand side represents the gains from

increasing the bid if the plant is at the marginal position

before and after the change, and the left hand side is the

reduction of the profits if by increasing the bid the plant

moves from the marginal to the position. This

condition above coincides with the first order condition

of an auction for k and independent bid-

ders and price equal to the lowest bid.

1th

k



11mN

Analogously, the first order cond itio n for the bid of the

plant with cost h, the lowest cost of the firm,

given that they all bid according to the same function







 



 



mNkh

hhh hh

mNk h

hhh

cmNFcFcfc

cF cFc











 

 



 















hDb

where the expression after in the right hand

side is the probability that the plant with cost h bid-

ding is the lowest bidder. Notice that this

implies that the plants with costs 1

, that bid

less than , are among the first positions in

the ranking, and hence, they produce one unit each. Thus,

if the plant is the bidder after and before in-

creasing its bid, the profits of the firm change by h times

the price increase.



hDb c

1k



k,,,







Corolla ry . The expected market price in the symmet-

ric equilibrium defined by proposition 3 is below that of

a symmetric equilibrium in the auction with just three

independent bidders and above the price when all four

plants are independent.

Summarizing, in an auction with uniform price equal

to the highest successful bid, the concentration of the

ownership affects the bidding behaviour of the plants in

the same manner as eliminating one plant. In other words,

a single plant that belongs to a larger firm does not con-

sider the other plant of the same firm as a real competitor.

Hence, it is true that the concentration increases the ex-

pected market price relative to a situation with disperse

ownership, but not as much as eliminating all but one of

the plants that are merged. With four plants bidding as

they were only three, the price is set by the plant whose

cost is the second lowest of four independent draws of

the same random variable, whereas when there are only

three plants in competition, the cost of the marginal plant

is the second lowest of three realizations of that random

variable. To illustrate this point, when the random proc-

ess is uniform in the interval





0,1 , the expected price

with four independent plants is 0.6, whereas with con-

centrated ownership is 0.7 and with three independent

The condition above coincides with (6) when



1mNk, that is, when the number of units to be

sold is equal to the production capacity of 1N



firms.

Notice that when there are just two firms this condition

stipulates that the demand must coincide with the capac-

ity of a single firm.

The fact that at the equilibrium defined by proposition

3 all the plants bid according to a common and monotone

bidding function greatly simplifies the comparisons be-

tween the expected prices with concentrated and with

disperse ownership. In addition, the fact that there is a

unique and monotone function from costs to bids has a

desirable consequence in terms of efficiency; by sched-

uling the lowest bidders, the mechanism calls to produce

the plants with the lowest costs.

B. DE OTTO-LÓPEZ

1285

plants is 0.75.

4. When the Lowest Unsuccessful

Bid Sets the Price

Consider now a price mechanism in which the market

price is equal to the bid of the plant at the third position

in the ranking, that is, the lowest unsuccessful bid. Con-

sider a firm with two plants and costs 1 and 2

(12

c), that bids 1 for plant 1 and 2 for plant 2.

Suppose that the rival firm bids according to some

strictly increasing and differentiable functions 1 (for

the plant of type 1) and 2 (for the plant of type 2),

where is everywhere below .

c c

c

B B

1 2

If plants 1 and 2 are called to produce, the price is

equal to the lowest rival bid. Hence, the expected profits

of the firm conditional on its two plants operating are

 



 



112

221 ,

21 d

BzccFzfz z

Fzfz z



 











where the denominator is the probability of this event.

If only plant 1 is operative (at the first or second posi-

tion in the ranking) and plant is at the fourth position,

then the price is set by the plant with the highest cost of

the rival firm, which bids according to . Hence, the

conditional expected profits are 2





 



Bz cFzfzz

Fzfz z









Again, the denominator is the probability of this event.

Finally, if plant 1 is called to run and plant 2 sets the

price, the profits of the firm are 21

. This occurs

whenever the lowest cost of the rival is below

Bc







and the highest is above , and hence with

probability









 



21 d

BB fzz

zfzz















or equivalently,

 

111

1212 22

2FB BFB BFB B







 







 





Summarizing, the expected profits of a firm with costs

1 and 2 bidding and , given that the rival

firm bids according to and are

c c1

 









 

1 1

12 21

121211221

111

21121222

,,,221d2 d

cBB

BB BB

BBccBzccFzfz zBzcFzfzz

BcFB BFBBFBB



 



  

 



 

 

 









As before, the equilibrium bidding functions must sat-

isfy the F.O.C. of the problem. Setting the partial deriva-tive of



with respect to equal to zero at





we have

















111

1112112 11211

20Bc cFBBcfBBcDBBc





 

 

  (7)

where represents the derivative of the function

DB

B

From the F.O.C. above it is clear that either

for any or



11 1

Bc c1



211 0FB Bc













10Bc









. On

the one hand, 11 1

for any 1 means that the

plants of type 1 bid their true costs. This bidding function

would be a dominant strategy if the four plants were in-

dependent (if each one were owned by a different firm).

On the other hand, holds if, for

any 1,





Bc c

1





211

BBc









 does not belong to the support





,cc , as it occurs if the plants of type 2 always bid

above the maximum bid of the plants of type 1. That is,

if the bidding function is everywhere above





Bc.

Consider first the case that for any 1

Then, by the second F.O.C. (setting equal to zero the

partial derivative with respect to 2 at



11 1

Bc c





Bc) and

taking into account that is the identity function, we

have 1

 

22 2222222222

212 0Bc cFBcfBcFBcFBcFc

 

 

 

 



(8)

The intuition behind this condition is the following.

By changing 2 the firm may reduce its profits by

(if plant 2 was the second plant in the rank-

ing and becomes the third one after the change) or in-

crease the profits as much as the market price (the bid

2) in case that plant 2 is at the third position before and

after raising its bid. The optimum bidding function

must balance this trade off for any cost .



22 2

Bc cB

1286 B. DE OTTO-LÓPEZ

Proposition 4. For the auction with concentrated

ownership and price equal to the lowest unsuccessful bid,

the following conditions







  

 







11 11

2222 2

22 2

22 22

Bccc cc

FB cFB cFc

Bc cFB cfB c

ccc

Bc c













 

  









(9)

define a strictly monotone symmetric equilibrium at

which for any c in



222

Bc c2



,cc .

Proof. The first order condition for is an imme-

diate consequence of (8). 2

First, we need to prove that for any



22 2

Bc c2





,cc . Think of a plan t with cost 2 bidding 2

cBc



By bidding 2

c instead of B, the profits of the firm

change only in two cases. First, if the plant was the sec-

ond in the ranking and moves to the third position. If this

was the case, the price before the change was below 2

and plant of type 2 was produ cing one unit at some price

below its cost. By increasing the bid, the plant increases

the market price for the plant of type 1 (which was -and

still is- operative) and, moreover, stops making losses

with its plant of type 2. And second, if the plant of type 2

was setting the price before the change. Then, by in-

creasing the bid, the plant makes the market price in-

crease (no matter the position of the plant after the

change) and, hence, the profits accruing from the plant of

type 1 increase too. Then,





22 2

c



Bc c

Bc for any .

Now, we have to show that for any 2

222



,cc



0

. Let 2 be such that . Then, by

condition (8), we have



Bc2

 

22222

221FcFc FcFcFc  

 

Thus, for this co st , either and



20Fc 2







21Fc  and 2

cc.

It only remains to prove that



2. Suppose not,

and let Bc c



2.Bc c Then, by the continuity of 2, there

is some cost at the left of B

c (say c



) for which



2.Bc c



 By condition (8), and taking into ac-

count that







20fBc fc



 

 and

 

21FB cFc



 

 , we have







20,Fc

that is,



21Fc



 and ,cc





 what is not pos-

sible. Hence,





Bc must be exactly equal to c.

Corollary. At any symmetric equilibrium defined by,

(9) the market price is higher than in the unique domi-

nant strategy equilibrium with four independent plants

with probability one. Also, the equilibrium is inefficient.

The equilibrium is inefficient in the sense that there is

a positive probability that the plants that are called to

produce are not the ones with the lowest cost; if the plant

that sets the price is of type 2, it can occur that its cost is

less than the most efficient rival plant which is scheduled.

Moreover, in this case the market price is, with certainty,

higher than when the four plants are independent–in

which case the price is the third lowest cost, whereas

with concentrated ownership, when a plant of type 2 sets

the price it is because either it is the third most efficient

one, bidding now above its cost, or either it is the second

most efficient one, but bidding now above the three low-

est costs. When a plant of type 1 sets the price, the allo-

cation is efficient—the cost of the plant of type 2 that

does produce is lower than the cost of that of type 1 th at

sets the price, as otherwise it would not have bid below

that quantity, and the price is the same that would have

prevailed with disperse ownership, as it is set by the third

most efficient one which is of type 1 and, hence, bids its

cost.

Summarizing, it the two plants of one firm are called

to produce, the result of the auction process is the same

that would have appeared with four independent plants.

But is the mechanism calls to produce to one plant of

each firm, then the price is, with certainty, higher than

when ownership is disperse and, moreover, there is a

positive probability that the allocation is inefficient.

Exchanging the roles of buyers and sellers, Vickrey

(1962) showed that when a single bidder can obtain at

most one unit (in our case this is as to say that the own-

ership is disperse), bidding the true valuation (the cost) is

a weakly dominant strategy in this multi-unit auction

where the price is determined by the best rejected bid.

When a single bidder can obtain up to two units, Engel-

brecht-W iggans and Khan (1998) find an incen tive to b id

truthfully for the first unit (the first plant) but to shade

the bid of the second one. The reason is that, with some

positive probability, the second bid determines the price

for the units he obtains. Our findings are in the same

direction; the bid for the first plant coincides with its cost,

but the second plant bid s above its cost. Thus, if th e plan t

that sets the price is of type 2, the price is greater than

with disperse ownership. Moreover, there is a positive

probability that the cost of this plant setting the price-that

is, off the schedule- is less than the cost of the last plant

called to run. Hence, at this equilibrium inefficient allo-

cations arise with positive probability.

Let us go back to the first F.O.C. (7). As we have seen

before, this condition holds if 1

Bis the identity function

or, else, if the function 2

B is bounded below by some

upper bound of 1

B. In fact, we will show that there is a

collection of symmetric equilibria in which the plants of

type 1 bid according to some bounded function 1

B and

plants of type 2 bid some upper bound M of 1

atever the cost of the plant.

the

B. DE OTTO-LÓPEZ

1287

Think of a firm with plants 1 and 2 with costs 1 and

2 whose rival firm bids according to a function 1

bounded above by 1 for its plant of type 1, and sub-

mits a bid

c B

B for its plant of type 2. Then, by bid-

ding anyth ing less th an M for plant 1 the firm makes sure

that its plant will be called to run, and the market price

will be M or the bid this firm submits for plant 2 if it is

below M. The firm has no incentive to submit a bid

greater than M for its first plant unless its cost 1 is

greater than M. So let us suppose that c

c. It is clear

that any bid greater or equal to M for plant 2 is equally

profitable for the firm. Moreover, if M is large enough,

the firm should bid exaclty M for plant 2. On the other

hand, the firm should not bid anything between 1 and

M, since this would reduce the market price below M

without making plant 2 enter the production Schedule.

By bidding less than 1, say



, plant 2 is called to

run with some positive probability, and in this case the

market price p is between 1





and 1. Suppose that

this is the case. Then the profits corresponding to plant 2

increase by 2, and the ones accruing from decrease

by the price reduction

pc

p. If M is large enough,

bidding less than1

B (and hence than M) for the plant of

type 2 would reduce the profits of the firm.



Proposition 5. For the auction with concentrated

ownership and price equal to the lowest unsuccessful bid,

the following conditions











11 11

22 2

and 2

BcBc cc

BcMccc

cMB





c

(10)

define a symmetric equilibrium strategy. At this equilib-

rium the market price is M.

Proof. Any function 1 bounded above by B

c

is equally profitable for the plants of type 1. If plant 2

with cost 2 bids c1



 instead of M, there is some

positive probability that this plant is scheduled. This oc-

curs when the lowest rival bid is some value p between



 and . In this case the profits of the firm

change by



p

Hence, for M to be more profitable than any bid less

than for any cost , it must hold that

2.Mpc M 

pc





2,.ccc

As 2 is less than 2pc12

2Bc, the above condi-

tion holds for any whenever M is greater or equal to

Notice that any equilibrium of this type is equally in-

efficient; with probability 1/3 the cost of one of the

plants of type 2, which are never scheduled, is below the

cost of one of the plants called to produce. This is the

probability that the two plants with the lowest costs of

the industry belong to the same firm. The expected effi-

ciency losses are, then, 1/3 times the expected value of

the difference between the third and the second lowest of

four realizations of the random variable c. When c is

uniformly distributed on

2Bc.





0,1 , the expected efficiency

loses are 1/15.

At the most favourable equilibrium of this type, the

market price M is exactly c. Suppose that





11 0Bc



for any cost 1

c, and





Bc c for any 2. A firm

has not any incentive to bid more than zero for its first

plant. By bidding anything less than

c this plant is

scheduled with probability one, and the price is c or

the bid of its second plant if less than c. And there are

not incentives to bid less than c for the second plant, as

this will only reduce the price for the first plant below c

and the second plant is unable to enter into operation

unless it submits a bid equal to zero.

To sum up, the concentration of the ownership is more

harmful under this auction format with price equal to the

lowest unsuccessful bid than with price equal to the low-

est successful bid, both in terms of efficiency and price.

Indeed, the price is, at any equilibrium of the type de-

scribed by (10) in the former, with certainty, no less than

the upper bound for the price in the later. To illustrate the

different effects of the concentration on the price across

the auction formats, when the random process is uniform





0,1 , the price in the most favourable equilibria de-

scribed by (10) is 1, whereas the expected price when it

is set equal to the lowest successful bid it is 0.7. This

means that in the first case, the expected price is a 66 per

cent higher than with disperse ownership, whereas in the

later the increment is of 16 per cent.

5. Conclusions

The concentration of the ownership in auction markets

implies that a single bidder submits bids for the different

units offered, and it may win more than one unit. It is

already known (see, for instance, Ausubel and Cramton

(1998)) that when a bidder can be awarded with more

than one unit, uniform-price auctions for multiple units

do not inherit the desirable efficiency and revenue prop-

erties of the auctions for a single object, except in very

particular settings (as, for instance, with pure common

values). The reason is that in these multi-unit auctions

the bidders have an incentive to shade their true cost (or

valuation), as their bid for one unit affects with positive

probability the price of the other units they win.

Inefficiency is not a result of this shading per se, but

rather a consequence of differential bid shading; for a

bidder, the incentives to shade are different for the dif-

ferent units. As there is not a monotone mapping from

costs (or valuations) to bids, inefficient outcomes arise

with positive probability.

B. DE OTTO-LÓPEZ

1288

The auction format with price equal to the best unsuc-

cessful bid has been well studied by Ausubel and Cram-

ton (1998) and Engelbrecht-Wiggans and Khan (1998),

among others. In line with their results, and exchanging

the roles of buyers and sellers, differential bid shading

appears in our model as bidders have not an incentive to

shade their first bid, since it cannot affect the price that

this bidder gets. But there is a positive probability that

the bid for the second unit determines the price of the

first. Hence, the bidders increase this second bid in an

attempt to increases the price they receive for the first

unit. Indeed, in equilibrium, they can increase it with no

bound.

In the auction format with price equal to the worst suc-

cessful bid, we find that the incentives for bid shading

are stronger when the ownership is concentrated than

when each plant is an independent firm. This causes that

the expected price is higher when ownership is concen-

trated.

More surprisingly, there are some special markets con-

figurations for which we find bid shading, but not dif-

ferential bid shading. In our 2 × 2 × 2 case (two units,

two firms and two plants each) there exists a symmetric

equilibrium in which all the plants bid according to the

same bidding function. More precisely, they bid as in a

symmetric equilibrium for this auction format with three

bidders that can win up to one unit. Of course, this func-

tion lies everywhere above the symmetric equilibrium

bidding function for the case with disperse ownership,

and this implies that the expected price is higher, but not

as much as it would with three independent plants. Sym-

metry and monotonicity guarantee efficient outcomes.

Summarizing, the two auction formats we analyze

create incentives to strategic bid shading when a single

bidder can win several units, but, at least for this 2 × 2 ×

2 and some other special market configurations, the auc-

tion format with price equal to the highest successful bid

dominates any equilibrium of the former, alternative

uniform-price auction format both in terms of price and

in terms of efficiency.

6. References

[1] W. Vickrey, “Auctions and Bidding Games,” Recent

Advances in Game Theory, Princeton University Con-

ference, 1962, pp. 15-29.

[2] L. Ausubel and P. Cramton, “Demand Reduction and

Inefficiency in Multi-Unit Auctions,” Mimeo, University

of Maryland, Baltimore, 1998.

[3] R. Engelbrecht-Wiggans and C. M. Khan, “Multi-Unit

Auctions with Uniform Prices,” Economic Theory, Vol.

12, No. 2, 1998, pp. 227-258.

doi:10.1007/s001990050220

[4] S. Brusco and G. Lopomo, “Collusion via Signaling in

Simultaneous Ascending Bid Auctions with Multiple

Objects and Complementarities,” The Review of Eco-

nomic Studies, Vol. 69, No. 2, 2002, pp. 407-436.

doi:10.1111/1467-937X.00211

[5] P. Cramton, A. E. Kahn, R. H. Porter and R. D. Tabors,

“Uniform Pricing or Pay-as-Bid Pricing: A Dilemma for

California and Beyond,” Electricity Journal, Vol. 14, No.

6, 2001, pp. 70-79.

[6] G. Federico and D. Rahman, “Bidding in an Electricity

Pay-as-Bid Auction,” Journal of Regulatory Economics,

Vol. 24, No. 2, 2003, pp. 175-211.

doi:10.1023/A:1024738128115

[7] N. Fabra, “Tacit Collusion in Repeated Auctions: Uni-

form versus Discriminatory,” Journal of Industrial Eco-

nomics, Vol. 51, No. 3, 2003, pp. 271-293.

doi:10.1111/1467-6451.00201

[8] P. Cramton and S. Stoft, “Why We Need to Stick with

Uniform-Price Auctions in Electricity Markets,” Electric-

ity Journal, Vol. 20, No. 1, 2007, pp. 26-37.

doi:10.1016/j.tej.2006.11.011

[9] S. Tierney, “Pay-as-Bid vs. Uniform Pricing: Discrimi-

natory Auctions Promote Strategic Bidding and Market

Manipulation,” Public Utilities Fortnightly, Vol. 146, No.

3, 2008, pp. 40-48.

B. DE OTTO-LÓPEZ

1289

Appendix

Proof of Proposition 1

Consider first an auction with price equal to the highest

successful bids. Think of a firm bidding 1 and 2

b for

its plants 1 and 2 with costs 1 and 2

c respectively.

Suppose that the rival firm bids according to some bid-

ding functions 1

b and 2 which depend both on the

costs of the plants this firm owns.

When the two plants of the firm bidding 1 and 2

are called to run, then the market price is set by the plant

bidding 2. Hence, the expected profits of the firm con-

ditional on that the two plants are called into operation

are 212

. This occurs whenever the two rival

plants bid above 2. That is, when the costs of the rival,

1 and , are such that . Or equivalently,

if where





2c



121 2

,tt ub





112 2

,btt b

 













1212112 2

,,, ,ubttcc ccbttb

This is the upper set corresponding to the value of

the function . In general, 2

 













12 12

,,, ,

ukttcc ccbttk

Thus, the firm bidding and will produce two units

with probability







dd,

ub 2

zf zz

 z where





represents the double integral over the set .



If the plant with cost 1 is the first in the ranking and

the one of type 2 is at the third of fourth position, the

price is set by the rival plant of type 1, that bids accord-

ing to 1. This occurs when the lowest rival bid is below

2 and above 1. That is, if



b b







12121 1

,ttlb ub,

where 2

is the lower set corresponding to the

value of the function . In general,



 













12 12

,,, ,

lkttcc ccbttk 



Hence, the expected profits of the firm conditional on

that the price is set by the lowest rival bid are

 

 



 

12 11

112112 12

1212

lb ub

bzzc fzfzzz

fz fzzz









The denominator in this expression is the probability

that the lowest rival bid is between and .

1 2

Finally, if the plant that bids 1 is the one that sets

the price, this is the only plant of the firm which is called

to run. The profits of the firm are with probabil-

ity

b b

bc





 

11 21

121

lbu b2

zfz zz





This is the probability that the bid 1 is between the

two rival bids, and hence, at the second position in the

ranking.

Summarizing, the expected profits of a firm with cost

1 and 2 bidding 1 and 2, given that the rival

firm bids according to the functions and are

ccb b











 

 

 

 

12 11

11 21

12122 1 21212

112112 12

111212

,,, 2dd

,dd

lb ub

bbccbccf zf zzz

bzzc fzfzzz

bcfzfz zz















Differentiating with respect to 1 and setting this de-

rivative equal to zero we get the first F.O.C. of the prob-

lem, which his





 



 





 

12 11

11 21

112112 12

1212

11 1

lb ub

lbu b

bzzc fzfzzz

fz fzzz

bc b











 







Clearly, this condition does not depend on 2 neither

on 2 (notice that, although the integral in the second

term of the expected profits depends on 2, its deriva-

tive with respect to 1 does not, as the only frontier that

changes when 1 changes is that of the set





ub).

Thus, the bidding function 1 for the plant of type 1

depends only on the co st of this p lan t, and not o n th e cost

of the second plant of the firm.

Taking this into account, and setting the derivative of

the expected profits with respect to equal to zero we

have the second F.O.C., which is 2

















 



 

12 11

1212

121

212 2

1112 12

1212

2dd

lb ub

fz fzzz

zfz zz

bccb

bz fzfzzz

fz fzzz



















B. DE OTTO-LÓPEZ

1290

As and the interior of are complementary sets, it holds that









 

1212 11

1212 121

dd dd

ublb ub2

zfz zzfzfz zz







 



Also, as the frontier of the set is













,cccbcb2

, we have that

 

 









 



 

12 1112 11

12 11

111212 121

112

2 2

1212

dd dd

lb ublb ub

lb ub

bz fzfzzzfz fzzz

bccc bcb

fz fzzz











 



 







 



 



 

 

21 22

12 22

1212

1121 21212

212112 12

211212

,,,

2, dd

UB LB

LBU B

BBcc

Bzzccfz fzzz

Bzzc fzfzzz

Bcfzfz zz



















Thus, we can rewrite the second F.O.C. as









1212

121

22 2

2dd

fz fzzz

zfz zz

bc b



 





where U and L represent the upper and lower sets of the

functions 1 and 2. Setting the derivative with re-

spect to equal to zero, we have that

Now, and similarly to before, this condition defines

the bidding function as depending solely on .

2 2

The proof for the auction format with price equal to

the lowest unsuccessful bid is analogous. In this case, the

expected profits of a firm with costs 1 and 2 bid-

ding 1 and 2, given that the rival firm bid according

to some functions 1 and 2 (which, in principle,

depend on the two costs of the firm) are

b c

 



21 22

212112 12

UB LB

Bzzc fzfzzz



 d









c c

BB B BSimilarly to before, as the frontier of





UB is the

set













122 121

,,ttB ttB, this is equivalent to



 





 

21222122

1212 1212

212 2121111

ddd d

,, 0

UB LBUB LB

fz fzzzfz fzzd

BttBttBcBc





  







 



Again, the function only depends on the cost of

the plant of type 1. 1

BSetting now the derivative of the expected profits with

respect to equal to zero, we have

 











 



 





 

12 21 22

12 22

112 121212212 11212

2 2

1212

1212212

2,dd, dd

UBUB LB

LBU B

Bzz ccfzfzzzBzz cfzfzzz

fz fzzz

fz fzdzdzBcB

 

 







 



 





That is,









 

12 22

1212

221 212

dd 0

LBU B

fz fzzz

Bcfzfz zz













and depends on and not on the cost of the plant of type 1.

B. DE OTTO-LÓPEZ

1291





Proof of Proposition 2

Consider the F.O.C (3)



 



111

12222 2122122122

21 210FbbcbccFbbcfbbcDbbc





 







 



As the bidding functions 1 and 2 cross at the upper

and lower bound of the support of the distribution (see

the boundary conditions of this problem), for any given

cost c there is a cost 2 such that

b b







221

bc bc



bc



. The

condition above at this cost is



cb

 









1121

1DbcFcbcfcbbcfc



  

 

Integrating this expression in the interval





,cc we have

  



cbbzfzz

bc Fc









as we wanted to prove.

Proof of Proposition 3

Suppose that one of the firms uses the same bidding

function b for its two plants, and this function b is de-

fined by

 



czf zz





By setting in (1), the expected

profits of a firm with costs and bidding and

, we have

 

bc bcbc



 



 

12122 1 22

11 11

,,,21

bbccbc cFbb

bzcFzf zdz

bc FbbFbb























 







The first F.O.C. of this problem (setting equal to zero

the partial derivative with respect to ) is

 

 

111

11111

Fb bFbb

bcFbb fbbDbb























Or equivalently, the optimum for cost must

satisfy 1

 

111 1

bb bcfbbDbb





 



 

 

(12)

By the expression which defines the function b, we

know that

 

cbczfzz





Differentiating this expression,







 



cDbcbc f ccfc







cb b









, and taking into account that



Db bDbb b

1











, we have









111

11 11

bbbbb fbbDbb











Substituting this expression in the first F.O.C. above, it

must hold that





111

bbb bc

1



, that is,





.bbc







(11)

Hence, the optimum bid 1 for the cost 1 is given

by the bidding function b. Or, in other words, if a given

firm bids according to b for its two plants, then, the other

firm must bid likewise for its low cost plant.

Consider now the second first order condition which

we obtain by setting equal to zero the differential of the

expected profits (11). That is,

 

111

22222 2

21 210FbbbcFbb fbbDbb





 



 

 1



or equivalently,

 

2222

bb bcfbbDbb





 



 

 

This expression is equivalent to (12) for the bid .

Hence, the rest of the proof is analogous. 2