Border's theorem

In auction theory and mechanism design, Border's theorem gives a necessary and sufficient condition for interim allocation rules (or reduced form auctions) to be implementable via an auction.

It was first proven by Kim Border in 1991,^[1] expanding on work from Steven Matthews,^[2] Eric Maskin and John Riley.^[3] A similar version with different hypotheses was proven by Border in 2007.^[4]

Auctions are a mechanism designed to allocate an indivisible good among ${\displaystyle N}$ bidders with private valuation for the good – that is, when the auctioneer has incomplete information on the bidders' true valuation and each bidder knows only their own valuation.

Formally, this uncertainty is represented by a family of probability spaces ${\displaystyle (T_i,{𝒯}_i,{\lambda }_i)}$ for each bidder ${\displaystyle i=1,...,N}$, in which each ${\displaystyle t_i\in T_i}$ represents a possible type (valuation) for bidder ${\displaystyle i}$ to have, ${\displaystyle {𝒯}_i}$ denotes a σ-algebra on ${\displaystyle T_i}$, and ${\displaystyle {\lambda }_i}$ a prior and common knowledge probability distribution on ${\displaystyle T_i}$, which assigns the probability ${\displaystyle {\lambda }_i(t_i)}$ that a bidder ${\displaystyle i}$ is of type ${\displaystyle t_i}$. Finally, we define ${\displaystyle 𝑻={\displaystyle \prod _{i=1}^N}{T}_i}$ as the set of type profiles, and ${\displaystyle {𝑻}_{-i}=\prod _{j\ne i}{T}_i}$ the set of profiles ${\displaystyle t_{-i}=(t_1,...,t_{i-1},t_{i+1},...,t_N)}$.

Bidders simultaneously report their valuation of the goodTemplate:R, and an auction assigns a probability that they will receive it. In this setting, an auction is thus a function ${\displaystyle q:𝑻\to [0,1{]}^N}$ satisfying, for every type profile ${\displaystyle t\in 𝑻}$

${\displaystyle {\displaystyle \sum _{i=1}^N}{q}_i(t)\le 1}$

where ${\displaystyle q_i}$ is the ${\displaystyle i}$-th component of ${\displaystyle q=(q_1,q_2,...,q_N)}$. Intuitively, this only means that the probability that some bidder will receive the good is no greater than 1.

From the point of view of each bidder ${\displaystyle i}$, every auction ${\displaystyle q}$ induces some expected probability that they will win the good given their type, which we can compute as

${\displaystyle Q_i(t_i)=\underset{T_{-i}}{\int }{q}_i(t)d{\lambda }_i(t_{-i}|t_i)}$

where ${\displaystyle {\lambda }_i(t_{-i}|t_i)}$ is conditional probability of other bidders having profile type ${\displaystyle t_{-i}}$ given that bidder ${\displaystyle i}$ is of type ${\displaystyle t_i}$. We refer to such probabilites ${\displaystyle Q_i}$ as interim allocation rules, as they give the probability of winning the auction in the interim period: after each player knowing their own type, but before the knowing the type of other bidders.

The function ${\displaystyle 𝑸:𝑻\to [0,1{]}^N}$ defined by ${\displaystyle 𝑸(t)=(Q_1(t_1),...,Q_N(t_N))}$ is often referred to as a reduced form auction. Working with reduced form auctions is often much more analytically tractable for revenue maximization.^[3]

Taken on its own, an allocation rule ${\displaystyle 𝑸:T\to [0,1{]}^N}$ is called implementable if there exists an auction ${\displaystyle q:𝑻\to [0,1{]}^N}$ such that

${\displaystyle Q_i(t_i)=\underset{T_{-i}}{\int }{q}_i(t)d{\lambda }_i(t_{-i}|t_i)}$

for every bidder ${\displaystyle i}$ and type ${\displaystyle t_i\in T_i}$.

Border proved two main versions of the theorem, with different restrictions on the auction environment.^[1][4]

The auction environment is i.i.d if the probability spaces ${\displaystyle (T_i,{𝒯}_i,{\lambda }_i)=(T,𝒯,\lambda )}$ are the same for every bidder ${\displaystyle i}$, and types ${\displaystyle t_i}$ are independent. In this case, one only needs to consider symmetric auctionsTemplate:R,^[3] and thus ${\displaystyle Q_i=Q}$ also becomes the same for every ${\displaystyle i}$. Border's theorem in this setting thus states:^[1]

Proposition: An interim allocation rule ${\displaystyle Q:T\to [0,1]}$ is implementable by a symmetric auction if and only if for each measurable set of types ${\displaystyle A\in 𝒯}$, one has the inequality

${\displaystyle N\underset{A}{\int }Q(t)d\lambda (t)\le 1-\lambda (A^c{)}^N}$

Intuitively, the right-hand side represents the probability that the winner of the auction is of some type ${\displaystyle t\in A}$, and the left-hand side represents the probability that there exists some bidder with type ${\displaystyle t\in A}$. The fact that the inequality is necessary for implementability is intuitive; it being sufficient means that this inequality fully characterizes implementable auctions, and represents the strength of the theorem.

If all the sets ${\displaystyle T_i}$ are finite, the restriction to the i.i.d case can be dropped. In the more general environment developed above, Border thus proved:^[4][5]

Proposition: An interim allocation rule ${\displaystyle 𝑸:𝑻\to [0,1{]}^N}$ is implementable by an auction if and only if for each measurable sets of types ${\displaystyle A_1\in {𝒯}_1,A_2\in {𝒯}_2,...,A_N\in {𝒯}_N}$, one has the inequality

${\displaystyle {\displaystyle \sum _{i=1}^N}\underset{A_i}{\int }{Q}_i(t_i)d{\lambda }_i(t_i)\le 1-{\displaystyle \prod _{i=1}^N}(1-\sum _{t_i\in A_i}{\lambda }_i(t_i))}$

The intuition of the i.i.d case remains: the right-hand side represents the probability that the winner of the auction is some bidder ${\displaystyle i}$ with type ${\displaystyle t_i\in A_i}$, and the left-hand side represents the probability that there exists some bidder ${\displaystyle i}$ with type ${\displaystyle t_i\in A_i}$. Once again, the strength of the result comes from it being sufficient to characterize implementable interim allocation rules.

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