Acceptance set

In financial mathematics, acceptance set is a set of acceptable future net worth which is acceptable to the regulator. It is related to risk measures.

Mathematical Definition[edit]

Given a probability space $(\Omega ,{\mathcal {F}},\mathbb {P} )$ , and letting $L^{p}=L^{p}(\Omega ,{\mathcal {F}},\mathbb {P} )$ be the Lp space in the scalar case and $L_{d}^{p}=L_{d}^{p}(\Omega ,{\mathcal {F}},\mathbb {P} )$ in d-dimensions, then we can define acceptance sets as below.

Scalar Case[edit]

An acceptance set is a set $A$ satisfying:

$A\supseteq L_{+}^{p}$
$A\cap L_{--}^{p}=\emptyset$ such that $L_{--}^{p}=\{X\in L^{p}:\forall \omega \in \Omega ,X(\omega )<0\}$
$A\cap L_{-}^{p}=\{0\}$
Additionally if $A$ $A$ is convex then it is a convex acceptance set
1. And if $A$ is a positively homogeneous cone then it is a coherent acceptance set^[1]

Set-valued Case[edit]

An acceptance set (in a space with $d$ assets) is a set $A\subseteq L_{d}^{p}$ satisfying:

$u\in K_{M}\Rightarrow u1\in A$ with $1$ denoting the random variable that is constantly 1 $\mathbb {P}$ -a.s.
$u\in -\mathrm {int} K_{M}\Rightarrow u1\not \in A$
$A$ is directionally closed in $M$ with $A+u1\subseteq A\;\forall u\in K_{M}$
$A+L_{d}^{p}(K)\subseteq A$

Additionally, if $A$ is convex (a convex cone) then it is called a convex (coherent) acceptance set. ^[2]

Note that $K_{M}=K\cap M$ where $K$ is a constant solvency cone and $M$ is the set of portfolios of the $m$ reference assets.

Relation to Risk Measures[edit]

An acceptance set is convex (coherent) if and only if the corresponding risk measure is convex (coherent). As defined below it can be shown that $R_{A_{R}}(X)=R(X)$ and $A_{R_{A}}=A$ .^{[citation needed]}

Risk Measure to Acceptance Set[edit]

If $\rho$ is a (scalar) risk measure then $A_{\rho }=\{X\in L^{p}:\rho (X)\leq 0\}$ is an acceptance set.
If $R$ is a set-valued risk measure then $A_{R}=\{X\in L_{d}^{p}:0\in R(X)\}$ is an acceptance set.

Acceptance Set to Risk Measure[edit]

If $A$ is an acceptance set (in 1-d) then $\rho _{A}(X)=\inf\{u\in \mathbb {R} :X+u1\in A\}$ defines a (scalar) risk measure.
If $A$ is an acceptance set then $R_{A}(X)=\{u\in M:X+u1\in A\}$ is a set-valued risk measure.

Examples[edit]

Superhedging price[edit]

The acceptance set associated with the superhedging price is the negative of the set of values of a self-financing portfolio at the terminal time. That is

A=\{-V_{T}:(V_{t})_{t=0}^{T}{\text{ is the price of a self-financing portfolio at each time}}\}

.

Entropic risk measure[edit]

The acceptance set associated with the entropic risk measure is the set of payoffs with positive expected utility. That is

A=\{X\in L^{p}({\mathcal {F}}):E[u(X)]\geq 0\}=\{X\in L^{p}({\mathcal {F}}):E\left[e^{-\theta X}\right]\leq 1\}

where $u(X)$ is the exponential utility function.^[3]

References[edit]

^ Artzner, Philippe; Delbaen, Freddy; Eber, Jean-Marc; Heath, David (1999). "Coherent Measures of Risk". Mathematical Finance. 9 (3): 203–228. doi:10.1111/1467-9965.00068. S2CID 6770585.
^ Hamel, A. H.; Heyde, F. (2010). "Duality for Set-Valued Measures of Risk". SIAM Journal on Financial Mathematics. 1 (1): 66–95. CiteSeerX 10.1.1.514.8477. doi:10.1137/080743494.
^ Follmer, Hans; Schied, Alexander (October 8, 2008). "Convex and Coherent Risk Measures" (PDF). Retrieved July 22, 2010. {{cite journal}}: Cite journal requires |journal= (help)

[1] Artzner, Philippe; Delbaen, Freddy; Eber, Jean-Marc; Heath, David (1999). "Coherent Measures of Risk". Mathematical Finance. 9 (3): 203–228. doi:10.1111/1467-9965.00068. S2CID 6770585.

[2] Hamel, A. H.; Heyde, F. (2010). "Duality for Set-Valued Measures of Risk". SIAM Journal on Financial Mathematics. 1 (1): 66–95. CiteSeerX 10.1.1.514.8477. doi:10.1137/080743494.

[FS10-3] Follmer, Hans; Schied, Alexander (October 8, 2008). "Convex and Coherent Risk Measures" (PDF). Retrieved July 22, 2010. {{cite journal}}: Cite journal requires |journal= (help)

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