Blackwell's contraction mapping theorem

Let ${\displaystyle T}$  be an operator defined over an ordered normed vector space ${\displaystyle X}$ . ${\displaystyle T:X\rightarrow X}$  is a contraction mapping with modulus ${\displaystyle \beta }$  if it satisfies

1. ${\displaystyle (monotonicity)\quad u\leq v\implies Tu\leq Tv}$ 
2. ${\displaystyle (discounting)\quad T(u+c)\leq Tu+\beta c.}$ 

For all ${\displaystyle u}$  and ${\displaystyle v\in X}$ , ${\displaystyle u\leq v+||v-u||}$ . Properties 1. and 2. imply that ${\displaystyle T(u)\leq T(v+||v-u||)\leq T(v)+\beta ||v-u||}$ , hence, ${\displaystyle T(u)-T(v)\leq \beta ||v-u||}$ . The symmetric follows from a similar argument and we prove that ${\displaystyle T}$  is a contraction mapping.

An agent has access to only one cake for its entire, infinite, life. It has to decide the optimal way to consume it. It evaluates a consumption plan, ${\displaystyle c_{t}}$ , by using a separable utility function, ${\displaystyle \sum _{t=0}^{\infty }\beta ^{t}{\frac {c_{t}^{1-\sigma }}{1-\sigma }}}$ , with discounting factor ${\displaystyle \beta \in (0,1)}$ . Its problem can be summarized as

${\displaystyle \max _{c_{t}}\sum _{t=0}^{\infty }\beta ^{t}{\frac {c_{t}^{1-\sigma }}{1-\sigma }}{\text{ subject to }}x_{t}=x_{t-1}-c_{t}{\text{, }}x_{-1}=0{\text{, }}c_{t}\geq 0{\text{ and }}x_{t}\geq 0\,\forall \,t\,\in \,\mathbb {Z} _{+}}$ . (1)

Applying Bellman's principle of optimality we find (1)'s corresponding Bellman equation

${\displaystyle V(c)=\max _{c'}{\frac {c^{1-\sigma }}{1-\sigma }}+\beta V(c')}$ . (2)

It can be proven that the solution to this functional equation, if it exists, is equivalent to the solution of (1)^[2]. To prove its existence we can resort to Blackwell's sufficient conditions.

Define the operator ${\displaystyle T(V(c))=\max _{c'}{\frac {c^{1-\sigma }}{1-\sigma }}+\beta V(c')}$ . A solution to (2) is equivalent to finding a fixed-point for our operator. If we prove that this operator is a contraction mapping then we can use Banach's fixed-point theorem, and conclude that there is indeed a solution to (1).

First note that ${\displaystyle T}$  is defined over the space of bounded functions since for all feasible consumption plans, ${\displaystyle \sum _{t=0}^{\infty }\beta ^{t}{\frac {c_{t}^{1-\sigma }}{1-\sigma }}\leq \sum _{t=0}^{\infty }\beta ^{t}{\frac {1^{1-\sigma }}{1-\sigma }}={\frac {1}{(1-\beta )(1-\sigma )}}<\infty }$ . Endowing it with the sup-norm we conclude that the domain and co-domain are ordered normed vector spaces. We are just left with verifying that the conditions for Blackwell's theorem are respected:

1. (monotonicity) ${\displaystyle {\text{if }}V(c)\geq U(c)\,\forall \,c\,\in \,[0,1]}$  then ${\displaystyle T(V(c))=\max _{c'}{\frac {c^{1-\sigma }}{1-\sigma }}+\beta V(c')\geq \max _{c'}{\frac {c^{1-\sigma }}{1-\sigma }}+\beta U(c')=T(U(c))}$ 
2. (discounting) ${\displaystyle T(V(c)+a)=\max _{c'}{\frac {c^{1-\sigma }}{1-\sigma }}+\beta (V(c')+a)\leq \max _{c'}{\frac {c^{1-\sigma }}{1-\sigma }}+\beta V(c')+\beta a=T(V(c))+\beta a}$  where ${\displaystyle a}$  is a constant function.