Triangle inequality

Shapes of the triangle inequality

Triangle inequality for triangles

After the triangle is in the triangle , the sum of the lengths of two sides and always at least as great as the length of the third side . This means formally: ${\ displaystyle a}$${\ displaystyle b}$${\ displaystyle c}$

${\ displaystyle c \ leq a + b}$

One can also say that the distance from A to B is always at most as large as the distance from A to C and from C to B combined, or to put it in a popular way: "The direct route is always the shortest."

The equals sign only applies if and sections are from - one also speaks of the triangle being "degenerate". ${\ displaystyle a}$${\ displaystyle b}$${\ displaystyle c}$

Since, for reasons of symmetry, the following also applies, it follows , analogously, that the total is ${\ displaystyle a \ leq c + b}$${\ displaystyle from \ leq c}$${\ displaystyle ba \ leq c}$

${\ displaystyle \ left | ab \ right | \ leq c \ leq a + b}$.

The triangle inequality characterizes distance and magnitude functions . It is therefore used as an axiom of the abstract distance function in metric spaces .

Triangle inequality for real numbers

For real numbers the following applies:${\ displaystyle | a + b | \ leq | a | + | b |.}$

proof

Because both sides of the inequality are not negative, squaring is an equivalence transformation :

${\ displaystyle a ^ {2} {+} 2ab {+} b ^ {2} \ \ leq \ a ^ {2} {+} 2 {| ab |} {+} b ^ {2}.}$

By deleting identical terms, we arrive at the equivalent inequality

${\ displaystyle 2ab \ leq 2 | ab |.}$

This inequality holds because for any${\ displaystyle x \ leq {| x |}}$${\ displaystyle x \ in \ mathbb {R}.}$

Inverse triangle inequality

As with the triangle, an inverse triangle inequality can be derived:

There is a substitution of there ${\ displaystyle | a + b | - | b | \ leq | a |.}$${\ displaystyle a: = x + y, \ b: = - y}$

${\ displaystyle | x | - | y | \ leq | x + y |,}$

if you set it instead, it results ${\ displaystyle b: = - x}$

${\ displaystyle | y | - | x | \ leq | x + y |,}$

so together (because for any real numbers and with and also applies ) ${\ displaystyle u}$${\ displaystyle c}$${\ displaystyle u \ leq c}$${\ displaystyle -u \ leq c}$${\ displaystyle | u | \ leq c}$

${\ displaystyle {\ Big |} | x | - | y | {\ Big |} \ leq | x + y | \ leq | x | + | y ​​|.}$

If you replace with so you also get ${\ displaystyle y}$${\ displaystyle -y,}$

${\ displaystyle {\ Big |} | x | - | y | {\ Big |} \ leq | xy | \ leq | x | + | y ​​|.}$

So overall

${\ displaystyle {\ Big |} | x | - | y | {\ Big |} \ leq | x \ pm y | \ leq | x | + | y ​​|}$ for all ${\ displaystyle x, \, y \ in \ mathbb {R}.}$

Triangle inequality for complex numbers

The following applies to complex numbers :

${\ displaystyle | z_ {1} {} + z_ {2} | \ leq | z_ {1} | {+} | z_ {2} |.}$

proof

As in the real case, this inequality also follows

${\ displaystyle {\ Big |} | z_ {1} | {-} | z_ {2} | {\ Big |} \ leq | z_ {1} {\ pm} z_ {2} | \ leq | z_ {1 } | {+} | z_ {2} |}$ for all ${\ displaystyle z_ {1}, \, z_ {2} \ in \ mathbb {C}.}$

Triangle inequality of absolute value functions for bodies

Along with other demands, an amount function for a body is also given by the ${\ displaystyle K}$

Triangle inequality

${\ displaystyle \ varphi (x + y) \ leq \ varphi (x) + \ varphi (y)}$

For non-Archimedean amounts, the

tightened triangle inequality

${\ displaystyle \ varphi (x + y) \ leq \ max (\ varphi (x), \ varphi (y)).}$

It makes the amount an ultrametric . Conversely, any ultrametric amount is non-Archimedean.

Triangle inequality for sums and integrals

Repeated application of the triangle inequality or complete induction results

${\ displaystyle \ left | \ sum _ {i = 1} ^ {n} x_ {i} \ right | \ leq \ sum _ {i = 1} ^ {n} \ left | x_ {i} \ right |}$

for real or complex numbers . This inequality also applies when integrals are considered instead of sums: ${\ displaystyle x_ {i} \;}$

${\ displaystyle \ left | \ int _ {I} f (x) \, dx \ right | \ leq \ int _ {I} | f (x) | \, dx}$.

This also applies to complex-valued functions , cf. Then there is a complex number such that ${\ displaystyle f \ colon I \ to \ mathbb {C}}$${\ displaystyle \ alpha \;}$

${\ displaystyle \ alpha \ int _ {I} f (x) \, dx = \ left | \ int _ {I} f (x) \, dx \ right |}$and .${\ displaystyle | \ alpha | = 1 \;}$

There

${\ displaystyle \ left | \ int _ {I} f (x) \, dx \ right | = \ alpha \ int _ {I} f (x) \, dx = \ int _ {I} \ alpha \, f (x) \, dx = \ int _ {I} \ operatorname {Re} (\ alpha f (x)) \, dx + i \, \ int _ {I} \ operatorname {Im} (\ alpha f (x )) \, dx}$

is real, must be zero. Also applies ${\ displaystyle \ int _ {I} \ operatorname {Im} (\ alpha f (x)) \, dx}$

${\ displaystyle \ operatorname {Re} (\ alpha f (x)) \ leq | \ alpha f (x) | = | f (x) |}$,

so overall

${\ displaystyle \ left | \ int _ {I} f (x) \, dx \ right | = \ int _ {I} \ operatorname {Re} (\ alpha f (x)) \, dx \ leq \ int _ {I} | f (x) | \, dx}$.

Triangle inequality for vectors

The following applies to vectors :

${\ displaystyle \ left | {\ vec {a}} + {\ vec {b}} \ right | \ leq \ left | {\ vec {a}} \ right | + \ left | {\ vec {b}} \ right |}$.

The validity of this relationship can be seen by squaring it

${\ displaystyle \ left | {\ vec {a}} + {\ vec {b}} \ right | ^ {2} = \ left \ langle {\ vec {a}} + {\ vec {b}}, { \ vec {a}} + {\ vec {b}} \ right \ rangle = \ left | {\ vec {a}} \ right | ^ {2} +2 \ left \ langle {\ vec {a}}, {\ vec {b}} \ right \ rangle + \ left | {\ vec {b}} \ right | ^ {2} \ leq \ left | {\ vec {a}} \ right | ^ {2} +2 \ left | {\ vec {a}} \ right | \ left | {\ vec {b}} \ right | + \ left | {\ vec {b}} \ right | ^ {2} = \ left (\ left | {\ vec {a}} \ right | + \ left | {\ vec {b}} \ right | \ right) ^ {2}}$,

using the Cauchy-Schwarz inequality :

${\ displaystyle \ langle {\ vec {a}}, {\ vec {b}} \ rangle \ leq \ left | {\ vec {a}} \ right | \ cdot \ left | {\ vec {b}} \ right |}$.

Here, too, it follows as in the real case

${\ displaystyle {\ Big |} \ left | {\ vec {a}} \ right | - \ left | {\ vec {b}} \ right | \, \, {\ Big |} \ leq \ left | { \ vec {a}} \ pm {\ vec {b}} \ right | \ leq \ left | {\ vec {a}} \ right | + \ left | {\ vec {b}} \ right |}$

such as

${\ displaystyle \ left | \ sum _ {i = 1} ^ {n} {\ vec {a_ {i}}} \ right | \ leq \ sum _ {i = 1} ^ {n} \ left | {\ vec {a_ {i}}} \ right |.}$

Triangle inequality for spherical triangles

Two spherical triangles

However, it applies if you limit yourself to Eulerian triangles, i.e. those in which each side is shorter than half a great circle.

In the adjacent figure, the following applies

${\ displaystyle \ left | ab \ right | \ leq c_ {1} \ leq a + b,}$

however is . ${\ displaystyle c_ {2}> a + b}$

Triangle inequality for normalized spaces

In a normalized space , the triangle inequality becomes in the form ${\ displaystyle \ left (X, \ | {\ cdot} \ | \ right)}$

${\ displaystyle \ | x + y \ | \ leq \ | x \ | + \ | y \ |}$

required as one of the properties that the standard must meet for everyone . In particular, it also follows here ${\ displaystyle x, y \ in X \;}$

${\ displaystyle {\ Big |} \ | x \ | - \ | y \ | {\ Big |} \ leq \ | x \ pm y \ | \ leq \ | x \ | + \ | y \ |}$

such as

${\ displaystyle \ left \ | \ sum _ {i = 1} ^ {n} x_ {i} \ right \ | \ leq \ sum _ {i = 1} ^ {n} \ | x_ {i} \ |}$for everyone .${\ displaystyle x_ {i} \ in X \;}$

Triangle inequality for metric spaces

${\ displaystyle d (x, y) \ leq d (x, z) + d (z, y)}$

is fulfilled for all . In every metric space, the triangle inequality applies by definition. From this it can be deduced that in a metric space also the reverse triangle inequality ${\ displaystyle x, y, z \ in X}$

${\ displaystyle \ left | d (x, z) -d (z, y) \ right | \ leq d (x, y)}$

applies to all . In addition, the inequality holds for any${\ displaystyle x, y, z \ in X}$${\ displaystyle x_ {i} \ in X \;}$

${\ displaystyle d (x_ {0}, x_ {n}) \ leq \ sum _ {i = 1} ^ {n} d (x_ {i-1}, x_ {i})}$.

See also

• Inequalities in quadrilaterals

Individual evidence

1. ↑ Harro Heuser: Textbook of Analysis, Part 1. 8th edition. BG Teubner, Stuttgart 1990, ISBN 3-519-12231-6 . Theorem 85.1
2. ^ Walter Rudin: Real and Complex Analysis . MacGraw-Hill, 1986, ISBN 0-07-100276-6 . Theorem 1.33