Farkas' lemma is a result in mathematics

Mathematics

Mathematics is the study of quantity, space, structure, and change. Mathematicians seek out patterns and formulate new conjectures. Mathematicians resolve the truth or falsity of conjectures by mathematical proofs, which are arguments sufficient to convince other mathematicians of their validity...

 stating that a vector is either in a given convex cone

Cone (linear algebra)

In linear algebra, a cone is a subset of a vector space that is closed under multiplication by positive scalars. In other words, a subset C of a real vector space V is a cone if and only if λx belongs to C for any x in C and any positive scalar λ of V .A cone is said...

 or that there exists a (hyper)plane

Hyperplane

A hyperplane is a concept in geometry. It is a generalization of the plane into a different number of dimensions.A hyperplane of an n-dimensional space is a flat subset with dimension n − 1...

 separating the vector from the cone, but not both. It was originally proved by the Hungarian mathematician Gyula Farkas

Gyula Farkas (natural scientist)

Farkas Gyula, or Julius Farkas was a Hungarian mathematician and physicist.He attended the gymnasium at Győr , and studied law and philosophy at Budapest...

 . It is used amongst other things in the proof of the Karush–Kuhn–Tucker theorem in nonlinear programming

Nonlinear programming

In mathematics, nonlinear programming is the process of solving a system of equalities and inequalities, collectively termed constraints, over a set of unknown real variables, along with an objective function to be maximized or minimized, where some of the constraints or the objective function are...

.

Farkas' lemma is an example of a theorem of the alternative; a theorem stating that of two systems, one or the other has a solution, but not both or none.

Statement of the lemma

Let A be an m × n matrix

Matrix (mathematics)

In mathematics, a matrix is a rectangular array of numbers, symbols, or expressions. The individual items in a matrix are called its elements or entries. An example of a matrix with six elements isMatrices of the same size can be added or subtracted element by element...

 and b an m-dimensional vector

Vector space

A vector space is a mathematical structure formed by a collection of vectors: objects that may be added together and multiplied by numbers, called scalars in this context. Scalars are often taken to be real numbers, but one may also consider vector spaces with scalar multiplication by complex...

. Then, exactly one of the following two statements is true:

1. There exists an x ∈ Rⁿ such that Ax = b and x ≥ 0.
2. There exists a y ∈ R^m such that A^Ty ≥ 0 and b^Ty < 0.

Here, the notation x ≥ 0 means that all components of the vector x are nonnegative.

There are a number of slightly different (but equivalent) formulations of the Lemma in the literature. The one given here is due to Gale

David Gale

David Gale was a distinguished American mathematician and economist. He was a Professor Emeritus at University of California, Berkeley, affiliated with departments of Mathematics, Economics, and Industrial Engineering and Operations Research...

, Kuhn and Tucker

Albert W. Tucker

Albert William Tucker was a Canadian-born American mathematician who made important contributions in topology, game theory, and non-linear programming....

 in 1951.

Geometric interpretation

Let a₁, …, a_n ∈ R^m denote the columns of A. In terms of these vectors, Farkas' lemma states that exactly one of the following two statements is true:

1. There exist non-negative coefficients x₁, …, x_n ∈ R such that b = x₁a₁ + ··· + x_na_n.
2. There exists a vector y ∈ R^m such that a_i · y ≥ 0 for i = 1, …, n and b · y < 0.

The vectors x₁a₁ + ··· + x_na_n with nonnegative coefficients constitute the convex cone

Convex cone

In linear algebra, a convex cone is a subset of a vector space over an ordered field that is closed under linear combinations with positive coefficients.-Definition:...

 of the set {a₁, …, a_n} so the first statement says that b is in this cone.

The second statement says that there exists a vector y such that the angle of y with the vectors a_i is at most 90° while the angle of y with the vector b is more than 90°. The hyperplane normal to this vector has the vectors a_i on one side and the vector b on the other side. Hence, this hyperplane separates the vectors in the cone of {a₁, …, a_n} and the vector b.

For example, let n,m=2 and a₁ = (1,0)^T and a₂ = (1,1)^T. The convex cone spanned by a₁ and a₂ can be seen as a wedge-shaped slice of the first quadrant in the x-y plane. Now, suppose b = (0,1). Certainly, b is not in the convex cone a₁x₁+a₂x₂. Hence, there must be a separating hyperplane. Let y = (1,−1)^T. We can see that a₁ · y = 1, a₂ · y = 0, and b · y = −1. Hence, the hyperplane with normal y indeed separates the convex cone a₁x₁+a₂x₂ from b.

Farkas' lemma can thus be interpreted geometrically as follows: Given a convex cone and a vector, either the vector is in the cone or there is a hyperplane separating the vector from the cone, but not both.

Further implications

Farkas' lemma can be varied to many further theorems of alternative by simple modifications, such as Gordan's theorem: Either has a solution x, or has a nonzero solution y with y ≥ 0.

A particularly suggestive and easy-to-remember version is the following: if a set of inequalities has no solution, then a contradiction can be produced from it by linear combination with nonnegative coefficients. In formulas: if ≤ is unsolvable then , ,
≥ has a solution. (Note that is a combination of the left hand sides, a combination of the right hand side of the inequalities. Since the positive combination produces a zero vector on the left and a −1 on the right, the contradiction is apparent.)