reverse inequality - meaning and definition. What is reverse inequality
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What (who) is reverse inequality - definition

Triangular inequality; Triangular inequalities; Triangle inequality theorem; The triangle inequality; The Triangle Inequality; Segment addition postulate; Inverse Triangle Inequality; Triangle Inequality; Reverse triangle inequality; Segment Addition Postulate
  • The arc length of a curve is defined as the least upper bound of the lengths of polygonal approximations.
  • Euclid's construction for proof of the triangle inequality for plane geometry.
  • AC}}}} divided into two right triangles by an altitude drawn from one of the two base angles.
  • ''x'' + ''y''}}.
  • Triangle inequality for norms of vectors.

Poincaré inequality         
In mathematics, the Poincaré inequality is a result in the theory of Sobolev spaces, named after the French mathematician Henri Poincaré. The inequality allows one to obtain bounds on a function using bounds on its derivatives and the geometry of its domain of definition.
Grönwall's inequality         
THEOREM THAT GIVES BOUNDS ON INTEGRALS OF FUNCTIONS
Gronwall's lemma; Grönwall's lemma; Gronwall inequality; Gronwall lemma; Grönwall inequality; Grönwall lemma; Bellman-Gronwall inequality; Bellman-gronwall inequality; Groenwall's inequality; Groenwall inequality; Groenwall lemma; Groenwall's lemma; Gronwall–Bellman inequality; Gronwall's inequality; Gronwall-Bellman inequality
In mathematics, Grönwall's inequality (also called Grönwall's lemma or the Grönwall–Bellman inequality) allows one to bound a function that is known to satisfy a certain differential or integral inequality by the solution of the corresponding differential or integral equation. There are two forms of the lemma, a differential form and an integral form.
Samuelson's inequality         
INEQUALITY RELATING A SAMPLE MEAN AND STANDARD DEVIATION OF THAT SAMPLE
Laguerre–Samuelson inequality; Laguerre-Samuelson inequality; Laguerre-Samuelson Inequality; Samuelson Inequality; Samuelson inequality; Laguerre–Samuelson Inequality; Samuelson's Inequality; Samuelson–Laguerre Inequality; Samuelson–Laguerre inequality; Samuelson-Laguerre inequality; Samuelson-Laguerre Inequality
In statistics, Samuelson's inequality, named after the economist Paul Samuelson, also called the Laguerre–Samuelson inequality, after the mathematician Edmond Laguerre, states that every one of any collection x1, ..., xn, is within uncorrected sample standard deviations of their sample mean.

Wikipedia

Triangle inequality

In mathematics, the triangle inequality states that for any triangle, the sum of the lengths of any two sides must be greater than or equal to the length of the remaining side. This statement permits the inclusion of degenerate triangles, but some authors, especially those writing about elementary geometry, will exclude this possibility, thus leaving out the possibility of equality. If x, y, and z are the lengths of the sides of the triangle, with no side being greater than z, then the triangle inequality states that

z x + y , {\displaystyle z\leq x+y,}

with equality only in the degenerate case of a triangle with zero area. In Euclidean geometry and some other geometries, the triangle inequality is a theorem about distances, and it is written using vectors and vector lengths (norms):

x + y x + y , {\displaystyle \|\mathbf {x} +\mathbf {y} \|\leq \|\mathbf {x} \|+\|\mathbf {y} \|,}

where the length z of the third side has been replaced by the vector sum x + y. When x and y are real numbers, they can be viewed as vectors in R1, and the triangle inequality expresses a relationship between absolute values.

In Euclidean geometry, for right triangles the triangle inequality is a consequence of the Pythagorean theorem, and for general triangles, a consequence of the law of cosines. For the law of cosines to prove triangle-inequality, the angle in a triangle is lower bounded by zero, so the cosine term is at most one, and the side length of the third side follows. It may be proved without these theorems. The inequality can be viewed intuitively in either R2 or R3. The figure at the right shows three examples beginning with clear inequality (top) and approaching equality (bottom). In the Euclidean case, equality occurs only if the triangle has a 180° angle and two angles, making the three vertices collinear, as shown in the bottom example. Thus, in Euclidean geometry, the shortest distance between two points is a straight line.

In spherical geometry, the shortest distance between two points is an arc of a great circle, but the triangle inequality holds provided the restriction is made that the distance between two points on a sphere is the length of a minor spherical line segment (that is, one with central angle in [0, π]) with those endpoints.

The triangle inequality is a defining property of norms and measures of distance. This property must be established as a theorem for any function proposed for such purposes for each particular space: for example, spaces such as the real numbers, Euclidean spaces, the Lp spaces (p ≥ 1), and inner product spaces.