Concave function

In mathematics, a concave function is one for which the value at any convex combination of elements in the domain is greater than or equal to the convex combination of the values at the endpoints. Equivalently, a concave function is any function for which the hypograph is convex. The class of concave functions is in a sense the opposite of the class of a convex functions. A concave function is also synonymously called concave downwards, concave down, convex upwards, convex cap, or upper convex.

Definition[edit]

A real-valued function $f$ on an interval (or, more generally, a convex set in vector space) is said to be concave if, for any $x$ and $y$ in the interval and for any $\alpha \in [0,1]$ ,^[1]

f((1-\alpha )x+\alpha y)\geq (1-\alpha )f(x)+\alpha f(y)

A function is called strictly concave if

f((1-\alpha )x+\alpha y)>(1-\alpha )f(x)+\alpha f(y)\,

for any $\alpha \in (0,1)$ and $x\neq y$ .

For a function $f:\mathbb {R} \to \mathbb {R}$ , this second definition merely states that for every $z$ strictly between $x$ and $y$ , the point $(z,f(z))$ on the graph of $f$ is above the straight line joining the points $(x,f(x))$ and $(y,f(y))$ .

A function $f$ is quasiconcave if the upper contour sets of the function $S(a)=\{x:f(x)\geq a\}$ are convex sets.^[2]

Properties[edit]

Functions of a single variable[edit]

A differentiable function $f$ is (strictly) concave on an interval if and only if its derivative function $f '$ is (strictly) monotonically decreasing on that interval, that is, a concave function has a non-increasing (decreasing) slope.^[3]^[4]
Points where concavity changes (between concave and convex) are inflection points.^[5]
If $f$ is twice-differentiable, then $f$ is concave if and only if $f ''$ is non-positive (or, informally, if the "acceleration" is non-positive). If $f ''$ is negative then $f$ is strictly concave, but the converse is not true, as shown by $f (x) = - x 4$ .
If $f$ is concave and differentiable, then it is bounded above by its first-order Taylor approximation:^[2] $f(y)\leq f(x)+f'(x)[y-x]$
A Lebesgue measurable function on an interval $C$ is concave if and only if it is midpoint concave, that is, for any $x$ and $y$ in $C$ $f\left({\frac {x+y}{2}}\right)\geq {\frac {f(x)+f(y)}{2}}$
If a function f is concave, and f(0) ≥ 0, then f is subadditive on $[0,\infty )$ $[0,\infty )$ . Proof:
- Since $f$ is concave and $1 \geq t \geq 0$ , letting $y = 0$ we have $f(tx)=f(tx+(1-t)\cdot 0)\geq tf(x)+(1-t)f(0)\geq tf(x).$
- For $a,b\in [0,\infty )$ : $f(a)+f(b)=f\left((a+b){\frac {a}{a+b}}\right)+f\left((a+b){\frac {b}{a+b}}\right)\geq {\frac {a}{a+b}}f(a+b)+{\frac {b}{a+b}}f(a+b)=f(a+b)$

Functions of n variables[edit]

A function $f$ is concave over a convex set if and only if the function $-f$ is a convex function over the set.
The sum of two concave functions is itself concave and so is the pointwise minimum of two concave functions, i.e. the set of concave functions on a given domain form a semifield.
Near a strict local maximum in the interior of the domain of a function, the function must be concave; as a partial converse, if the derivative of a strictly concave function is zero at some point, then that point is a local maximum.
Any local maximum of a concave function is also a global maximum. A strictly concave function will have at most one global maximum.

Examples[edit]

The functions $f(x)=-x^{2}$ and $g(x)={\sqrt {x}}$ are concave on their domains, as their second derivatives $f''(x)=-2$ and ${\textstyle g''(x)=-{\frac {1}{4x^{3/2}}}}$ are always negative.
The logarithm function $f(x)=\log {x}$ is concave on its domain $(0,\infty )$ , as its derivative ${\frac {1}{x}}$ is a strictly decreasing function.
Any affine function $f(x)=ax+b$ is both concave and convex, but neither strictly-concave nor strictly-convex.
The sine function is concave on the interval $[0,\pi ]$ .
The function $f(B)=\log |B|$ , where $|B|$ is the determinant of a nonnegative-definite matrix B, is concave.^[6]

Applications[edit]

Rays bending in the computation of radiowave attenuation in the atmosphere involve concave functions.
In expected utility theory for choice under uncertainty, cardinal utility functions of risk averse decision makers are concave.
In microeconomic theory, production functions are usually assumed to be concave over some or all of their domains, resulting in diminishing returns to input factors.^[7]

References[edit]

^ Lenhart, S.; Workman, J. T. (2007). Optimal Control Applied to Biological Models. Mathematical and Computational Biology Series. Chapman & Hall/ CRC. ISBN 978-1-58488-640-2.
^ ^a ^b Varian, Hal R. (1992). Microeconomic analysis (3rd ed.). New York: Norton. p. 489. ISBN 0-393-95735-7. OCLC 24847759.
^ Rudin, Walter (1976). Analysis. p. 101.
^ Gradshteyn, I. S.; Ryzhik, I. M.; Hays, D. F. (1976-07-01). "Table of Integrals, Series, and Products". Journal of Lubrication Technology. 98 (3): 479. doi:10.1115/1.3452897. ISSN 0022-2305.
^ Hass, Joel (13 March 2017). Thomas' calculus. Heil, Christopher, 1960-, Weir, Maurice D.,, Thomas, George B. Jr. (George Brinton), 1914-2006. (Fourteenth ed.). [United States]. p. 203. ISBN 978-0-13-443898-6. OCLC 965446428.{{cite book}}: CS1 maint: location missing publisher (link)
^ Cover, Thomas M.; Thomas, J. A. (1988). "Determinant inequalities via information theory". SIAM Journal on Matrix Analysis and Applications. 9 (3): 384–392. doi:10.1137/0609033. S2CID 5491763.
^ Pemberton, Malcolm; Rau, Nicholas (2015). Mathematics for Economists: An Introductory Textbook. Oxford University Press. pp. 363–364. ISBN 978-1-78499-148-7.

Further References[edit]

Crouzeix, J.-P. (2008). "Quasi-concavity". In Durlauf, Steven N.; Blume, Lawrence E (eds.). The New Palgrave Dictionary of Economics (Second ed.). Palgrave Macmillan. pp. 815–816. doi:10.1057/9780230226203.1375. ISBN 978-0-333-78676-5.
Rao, Singiresu S. (2009). Engineering Optimization: Theory and Practice. John Wiley and Sons. p. 779. ISBN 978-0-470-18352-6.

[1] Lenhart, S.; Workman, J. T. (2007). Optimal Control Applied to Biological Models. Mathematical and Computational Biology Series. Chapman & Hall/ CRC. ISBN 978-1-58488-640-2.

[:0-2] Varian, Hal R. (1992). Microeconomic analysis (3rd ed.). New York: Norton. p. 489. ISBN 0-393-95735-7. OCLC 24847759.

[3] Rudin, Walter (1976). Analysis. p. 101.

[4] Gradshteyn, I. S.; Ryzhik, I. M.; Hays, D. F. (1976-07-01). "Table of Integrals, Series, and Products". Journal of Lubrication Technology. 98 (3): 479. doi:10.1115/1.3452897. ISSN 0022-2305.

[5] Hass, Joel (13 March 2017). Thomas' calculus. Heil, Christopher, 1960-, Weir, Maurice D.,, Thomas, George B. Jr. (George Brinton), 1914-2006. (Fourteenth ed.). [United States]. p. 203. ISBN 978-0-13-443898-6. OCLC 965446428.{{cite book}}: CS1 maint: location missing publisher (link)

[Cover_1988-6] Cover, Thomas M.; Thomas, J. A. (1988). "Determinant inequalities via information theory". SIAM Journal on Matrix Analysis and Applications. 9 (3): 384–392. doi:10.1137/0609033. S2CID 5491763.

[7] Pemberton, Malcolm; Rau, Nicholas (2015). Mathematics for Economists: An Introductory Textbook. Oxford University Press. pp. 363–364. ISBN 978-1-78499-148-7.

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v t e Calculus
Precalculus	Binomial theorem Concave function Continuous function Factorial Finite difference Free variables and bound variables Graph of a function Linear function Radian Rolle's theorem Secant Slope Tangent
Limits	Indeterminate form Limit of a function One-sided limit Limit of a sequence Order of approximation (ε, δ)-definition of limit
Differential calculus	Derivative Second derivative Partial derivative Differential Differential operator Mean value theorem Notation Leibniz's notation Newton's notation Rules of differentiation linearity Power Sum Chain L'Hôpital's Product General Leibniz's rule Quotient Other techniques Implicit differentiation Inverse functions and differentiation Logarithmic derivative Related rates Stationary points First derivative test Second derivative test Extreme value theorem Maximum and minimum Further applications Newton's method Taylor's theorem Differential equation Ordinary differential equation Partial differential equation Stochastic differential equation
Integral calculus	Antiderivative Arc length Riemann integral Basic properties Constant of integration Fundamental theorem of calculus Differentiating under the integral sign Integration by parts Integration by substitution trigonometric Euler Tangent half-angle substitution Partial fractions in integration Quadratic integral Trapezoidal rule Volumes Washer method Shell method Integral equation Integro-differential equation
Vector calculus	Derivatives Curl Directional derivative Divergence Gradient Laplacian Basic theorems Line integrals Green's Stokes' Gauss'
Multivariable calculus	Divergence theorem Geometric Hessian matrix Jacobian matrix and determinant Lagrange multiplier Line integral Matrix Multiple integral Partial derivative Surface integral Volume integral Advanced topics Differential forms Exterior derivative Generalized Stokes' theorem Tensor calculus
Sequences and series	Arithmetico-geometric sequence Types of series Alternating Binomial Fourier Geometric Harmonic Infinite Power Maclaurin Taylor Telescoping Tests of convergence Abel's Alternating series Cauchy condensation Direct comparison Dirichlet's Integral Limit comparison Ratio Root Term
Special functions and numbers	Bernoulli numbers e (mathematical constant) Exponential function Natural logarithm Stirling's approximation
History of calculus	Adequality Brook Taylor Colin Maclaurin Generality of algebra Gottfried Wilhelm Leibniz Infinitesimal Infinitesimal calculus Isaac Newton Fluxion Law of Continuity Leonhard Euler Method of Fluxions The Method of Mechanical Theorems
Lists	Differentiation rules List of integrals of exponential functions List of integrals of hyperbolic functions List of integrals of inverse hyperbolic functions List of integrals of inverse trigonometric functions List of integrals of irrational functions List of integrals of logarithmic functions List of integrals of rational functions List of integrals of trigonometric functions Secant Secant cubed List of limits Lists of integrals
Miscellaneous topics	Complex calculus Contour integral Differential geometry Manifold Curvature of curves of surfaces Tensor Euler–Maclaurin formula Gabriel's horn Integration Bee Proof that 22/7 exceeds π Regiomontanus' angle maximization problem Steinmetz solid

v t e Convex analysis and variational analysis
Basic concepts	Convex combination Convex function Convex set
Topics (list)	Choquet theory Convex geometry Convex metric space Convex optimization Duality Lagrange multiplier Legendre transformation Locally convex topological vector space Simplex
Maps	Convex conjugate Concave (Closed K- Logarithmically Proper Pseudo- Quasi-) Convex function Invex function Legendre transformation Semi-continuity Subderivative
Main results (list)	Carathéodory's theorem Ekeland's variational principle Fenchel–Moreau theorem Fenchel-Young inequality Jensen's inequality Hermite–Hadamard inequality Krein–Milman theorem Mazur's lemma Shapley–Folkman lemma Robinson–Ursescu Simons Ursescu
Sets	Convex hull (Orthogonally, Pseudo-) Convex set Effective domain Epigraph Hypograph John ellipsoid Lens Radial set/Algebraic interior Zonotope
Series	Convex series related ((cs, lcs)-closed, (cs, bcs)-complete, (lower) ideally convex, (Hx), and (Hwx))
Duality	Dual system Duality gap Strong duality Weak duality
Applications and related	Convexity in economics