Concavification

In mathematics, concavification is the process of converting a non-concave function to a concave function. A related concept is convexification – converting a non-convex function to a convex function. It is especially important in economics and mathematical optimization.^[1]

Concavification of a quasiconcave function by monotone transformation[edit]

An important special case of concavification is where the original function is a quasiconcave function. It is known that:

Every concave function is quasiconcave, but the opposite is not true.
Every monotone transformation of a quasiconcave function is also quasiconcave. For example, if $f:\mathbb {R} ^{n}\to \mathbb {R}$ is quasiconcave and $g:\mathbb {R} \to \mathbb {R}$ is a monotonically-increasing function, then $x\mapsto g(f(x))$ is also quasiconcave.

Therefore, a natural question is: given a quasiconcave function $f:\mathbb {R} ^{n}\to \mathbb {R}$ , does there exist a monotonically increasing $g:\mathbb {R} \to \mathbb {R}$ such that $x\mapsto g(f(x))$ is concave?

Example and Counter Example[edit]

As an example, consider the function $x\mapsto f(x)=x^{2}$ on the domain $x\geq 0$ . This function is quasiconcave, but it is not concave (in fact, it is strictly convex). It can be concavified, for example, using the monotone transformation $t\mapsto g(t)=t^{1/4}$ , since $x\mapsto g(f(x))={\sqrt {x}}$ is concave.

Not every concave function can be concavified in this way. A counter example was shown by Fenchel.^[2] His example is: $(x,y)\mapsto f(x,y):=y+{\sqrt {x+y^{2}}}$ . Fenchel proved that this function is quasiconcave, but there is no monotone transformation $g:\mathbb {R} \to \mathbb {R}$ such that $(x,y)\mapsto g(f(x,y))$ is concave.^[3]^: 7–9

Based on these examples, we define a function to be concavifiable if there exists a monotone transformation that makes it concave. The question now becomes: what quasiconcave functions are concavifiable?

Concavifiability[edit]

Yakar Kannai treats the question in depth in the context of utility functions, giving sufficient conditions under which continuous convex preferences can be represented by concave utility functions.^[4]

His results were later generalized by Connell and Rasmussen,^[3] who give necessary and sufficient conditions for concavifiability. They show that the function $(x,y)\mapsto f(x,y)=e^{e^{x}}\cdot y$ violates their conditions and thus is not concavifiable. They prove that this function is strictly quasiconcave and its gradient is non-vanishing, but it is not concavifiable.

References[edit]

^ Li, D.; Sun, X. L.; Biswal, M. P.; Gao, F. (2001-07-01). "Convexification, Concavification and Monotonization in Global Optimization". Annals of Operations Research. 105 (1–4): 213–226. doi:10.1023/A:1013313901854. ISSN 0254-5330. S2CID 7570136.
^ Fenchel (1953). Convex cones, sets and functions. Princeton University.
^ ^a ^b Connell, Christopher; Rasmusen, Eric Bennett (December 2017). "Concavifying the QuasiConcave". Journal of Convex Analysis. 24 (4): 1239–1262.
^ Kannai, Yakar (1977-03-01). "Concavifiability and constructions of concave utility functions". Journal of Mathematical Economics. 4 (1): 1–56. doi:10.1016/0304-4068(77)90015-5. ISSN 0304-4068.

[1] Li, D.; Sun, X. L.; Biswal, M. P.; Gao, F. (2001-07-01). "Convexification, Concavification and Monotonization in Global Optimization". Annals of Operations Research. 105 (1–4): 213–226. doi:10.1023/A:1013313901854. ISSN 0254-5330. S2CID 7570136.

[2] Fenchel (1953). Convex cones, sets and functions. Princeton University.

[Connell_2012-3] Connell, Christopher; Rasmusen, Eric Bennett (December 2017). "Concavifying the QuasiConcave". Journal of Convex Analysis. 24 (4): 1239–1262.

[4] Kannai, Yakar (1977-03-01). "Concavifiability and constructions of concave utility functions". Journal of Mathematical Economics. 4 (1): 1–56. doi:10.1016/0304-4068(77)90015-5. ISSN 0304-4068.

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