Heron's theorem

A triangle with sides a, b and c

The Heron's Formula is a theorem of elementary geometry , which, after the ancient mathematician Heron of Alexandria is named. The sentence describes a mathematical formula with the help of which the area of a triangle can be calculated from the three side lengths. The formula is also called Heron's formula or Heron's formula or also the Heron's formula .

Formulation of the sentence

The area of a triangle of the Euclidean plane with the side lengths , , and half circumference ${\ displaystyle A}$ ${\ displaystyle a}$ ${\ displaystyle b}$ ${\ displaystyle c}$

{\ displaystyle s \, = \, {\ frac {a + b + c} {2}}}

is

{\ displaystyle A = {\ sqrt {s \ cdot (sa) \ cdot (sb) \ cdot (sc)}}}

Other representations

This formula can also be expressed like this:

(V1)

{\ displaystyle A = {\ frac {1} {4}} \ cdot {\ sqrt {(a + b + c) \ cdot (-a + b + c) \ cdot (a-b + c) \ cdot ( a + bc)}}}

When multiplied one obtains:

(V2)

{\ displaystyle A = {\ frac {1} {4}} \ cdot {\ sqrt {2 \ cdot a ^ {2} \ cdot b ^ {2} +2 \ cdot b ^ {2} \ cdot c ^ { 2} +2 \ cdot c ^ {2} \ cdot a ^ {2} -a ^ {4} -b ^ {4} -c ^ {4}}}}

As a further representation of the Heronic formula, the following is also common:

(V3) ,

{\ displaystyle A = {\ frac {1} {4}} \ cdot {\ sqrt {4 \ cdot a ^ {2} \ cdot b ^ {2} - (a ^ {2} + b ^ {2} - c ^ {2}) ^ {2}}}}

which can be obtained from version (V1) by regrouping and using the binomial formulas with the following equations :

{\ displaystyle {\ begin {aligned} 16 \ cdot A ^ {2} & = {\ bigl (} ((a + b) + c) \ cdot ((a + b) -c) {\ bigr)} \ cdot {\ bigl (} (c + (ab)) \ ​​cdot (c- (ab)) {\ bigr)} \\ & = {\ bigl (} (a + b) ^ {2} -c ^ {2} {\ bigr)} \ cdot {\ bigl (} c ^ {2} - (ab) ^ {2} {\ bigr)} \\ & = {\ bigl (} a ^ {2} +2 \ cdot a \ cdot b + b ^ {2} -c ^ {2} {\ bigr)} \ cdot {\ bigl (} c ^ {2} -a ^ {2} +2 \ cdot a \ cdot bb ^ {2} { \ bigr)} \\ & = {\ bigl (} 2 \ cdot a \ cdot b + (a ^ {2} + b ^ {2} -c ^ {2}) {\ bigr)} \ cdot {\ bigl ( } 2 \ cdot a \ cdot b- (a ^ {2} + b ^ {2} -c ^ {2}) {\ bigr)} \\ & = 4 \ cdot a ^ {2} \ cdot b ^ { 2} - (a ^ {2} + b ^ {2} -c ^ {2}) ^ {2} \ end {aligned}}}

Finally, a representation with a determinant can be derived from the version (V3) :

(V4)

{\ displaystyle A = {\ frac {1} {4}} \ cdot {\ sqrt {- \ det \ left ({\ begin {matrix} 0 & 1 & 1 & 1 \\ 1 & 0 & a ^ {2} & b ^ {2} \\ 1 & a ^ {2} & 0 & c ^ {2} \\ 1 & b ^ {2} & c ^ {2} & 0 \ end {matrix}} \ right)}}}

This is a special case of the Cayley-Menger determinant , with which one can calculate the volume of a simplex , the generalization of triangles to any dimensions , for example a tetrahedron in three dimensions.

(V4) is obtained from (V3) using Laplace's expansion theorem and elementary matrix transformations as follows:

{\ displaystyle {\ begin {aligned} 4 \ times a ^ {2} \ times b ^ {2} - (a ^ {2} + b ^ {2} -c ^ {2}) ^ {2} & = 4 \ cdot a ^ {2} \ cdot b ^ {2} - (c ^ {2} -a ^ {2} -b ^ {2}) ^ {2} \\ & = \ det \ left ({\ begin {matrix} -2 \ cdot a ^ {2} & c ^ {2} -a ^ {2} -b ^ {2} \\ c ^ {2} -a ^ {2} -b ^ {2} & -2 \ cdot b ^ {2} \ end {matrix}} \ right) \\ & = \ det \ left ({\ begin {matrix} 1 & a ^ {2} & b ^ {2} \\ 0 & -2 \ cdot a ^ {2} & c ^ {2} -a ^ {2} -b ^ {2} \\ 0 & c ^ {2} -a ^ {2} -b ^ {2} & - 2 \ cdot b ^ {2 } \ end {matrix}} \ right) \\ & = \ det \ left ({\ begin {matrix} 1 & a ^ {2} & b ^ {2} \\ 1 & -a ^ {2} & c ^ {2} - a ^ {2} \\ 1 & c ^ {2} -b ^ {2} & - b ^ {2} \ end {matrix}} \ right) \\ & = - \ det \ left ({\ begin {matrix} 0 & 1 & 0 & 0 \\ 1 & 0 & a ^ {2} & b ^ {2} \\ 1 & a ^ {2} & - a ^ {2} & c ^ {2} -a ^ {2} \\ 1 & b ^ {2} & c ^ {2} -b ^ {2} & - b ^ {2} \ end {matrix}} \ right) \\ & = - \ det \ left ({\ begin {matrix} 0 & 1 & 1 & 1 \\ 1 & 0 & a ^ {2} & b ^ {2 } \\ 1 & a ^ {2} & 0 & c ^ {2} \\ 1 & b ^ {2} & c ^ {2} & 0 \ end {matrix}} \ right) \ end {aligned}}}

Numerical example

A triangle with the sides , and half the circumference . Inserted into the formula you get the area ${\ displaystyle a = 4}$ ${\ displaystyle b = 13}$ ${\ displaystyle c = 15}$ ${\ displaystyle s = {\ frac {a + b + c} {2}} = {\ frac {4 + 13 + 15} {2}} = 16}$

{\ displaystyle A = {\ sqrt {s \ cdot (sa) \ cdot (sb) \ cdot (sc)}} = {\ sqrt {16 \ cdot (16-4) \ cdot (16-13) \ cdot ( 16-15)}} = {\ sqrt {16 \ times 12 \ times 3 \ times 1}} = {\ sqrt {576}} = 24}

Another representation of the formula gives

{\ displaystyle A = {\ frac {1} {4}} \ cdot {\ sqrt {(a + b + c) \ cdot (-a + b + c) \ cdot (a-b + c) \ cdot ( a + bc)}} = {\ frac {1} {4}} \ cdot {\ sqrt {(4 + 13 + 15) \ cdot (-4 + 13 + 15) \ cdot (4-13 + 15) \ cdot (4 + 13-15)}} = {\ frac {1} {4}} \ cdot {\ sqrt {32 \ cdot 24 \ cdot 6 \ cdot 2}} = {\ frac {1} {4}} \ cdot {\ sqrt {9216}} = {\ frac {1} {4}} \ cdot 96 = 24}

In this example, the side lengths and the area are whole numbers . Therefore a triangle with sides 4, 13 and 15 is a Heronian triangle .

Connection with quadrilateral tendons

As a borderline case , the formula can be obtained from the formula for the area of a chordal quadrilateral if two of the corner points merge so that one of the sides of the quadrilateral has a length of zero. The Brahmagupta formula applies to the area of a quadrilateral tendon

{\ displaystyle A = {\ sqrt {(sa) \ cdot (sb) \ cdot (sc) \ cdot (sd)}}}

,

here half the circumference

{\ displaystyle s = {\ frac {a + b + c + d} {2}}}

is.

proof

Proof with the Pythagorean theorem

According to the Pythagorean theorem , and (see figure). Subtraction gives , so ${\ displaystyle b ^ {2} = h ^ {2} + d ^ {2}}$ ${\ displaystyle a ^ {2} = h ^ {2} + (cd) ^ {2}}$ ${\ displaystyle a ^ {2} -b ^ {2} = c ^ {2} -2 \ cdot c \ cdot d}$

{\ displaystyle d = {\ frac {-a ^ {2} + b ^ {2} + c ^ {2}} {2 \ cdot c}}}

The following applies to the height of the triangle . Substituting the last equation yields ${\ displaystyle h}$ ${\ displaystyle h ^ {2} = b ^ {2} -d ^ {2}}$

{\ displaystyle {\ begin {aligned} h ^ {2} & = b ^ {2} - \ left ({\ frac {-a ^ {2} + b ^ {2} + c ^ {2}} {2 \ cdot c}} \ right) ^ {2} \\ & = \ left ({\ frac {2 \ cdot b \ cdot c} {2 \ cdot c}} \ right) ^ {2} - \ left ({ \ frac {-a ^ {2} + b ^ {2} + c ^ {2}} {2 \ cdot c}} \ right) ^ {2} \\ & = {\ frac {(2 \ cdot b \ cdot c + (- a ^ {2} + b ^ {2} + c ^ {2})) \ cdot (2 \ cdot b \ cdot c - (- a ^ {2} + b ^ {2} + c ^ {2}))} {4 \ cdot c ^ {2}}} \\ & = {\ frac {((b + c) ^ {2} -a ^ {2}) \ cdot (a ^ {2} - (bc) ^ {2})} {4 \ cdot c ^ {2}}} \\ & = {\ frac {((b + c) + a) \ cdot ((b + c) -a) \ cdot (a + (bc)) \ cdot (a- (bc))} {4 \ cdot c ^ {2}}} \\ & = {\ frac {2 \ cdot s \ cdot 2 \ cdot (sa) \ cdot 2 \ cdot (sc) \ cdot 2 \ cdot (sb)} {4 \ cdot c ^ {2}}} \\ & = {\ frac {4 \ cdot s \ cdot (sa) \ cdot (sb) \ cdot (sc)} {c ^ {2}}} \ end {aligned}}}

Applying the square root on both sides yields

{\ displaystyle h = {\ frac {2} {c}} \ cdot {\ sqrt {s \ cdot (sa) \ cdot (sb) \ cdot (sc)}}}

From this follows for the area of the triangle

{\ displaystyle {\ begin {aligned} A & = {\ frac {c \ cdot h} {2}} \\ & = {\ frac {c} {2}} \ cdot {\ frac {2} {c}} \ cdot {\ sqrt {s \ cdot (sa) \ cdot (sb) \ cdot (sc)}} \\ & = {\ sqrt {s \ cdot (sa) \ cdot (sb) \ cdot (sc)}} \ end {aligned}}}

Proof with the law of cosines

According to the cosine law ,

{\ displaystyle \ cos \ gamma = {\ frac {a ^ {2} + b ^ {2} -c ^ {2}} {2 \ cdot a \ cdot b}}}

Inserted into the trigonometric Pythagoras it follows

{\ displaystyle \ sin \ gamma = {\ sqrt {1- \ cos ^ {2} \ gamma}} = {\ sqrt {\ left ({\ frac {2 \ cdot a \ cdot b} {2 \ cdot a \ cdot b}} \ right) ^ {2} - \ left ({\ frac {a ^ {2} + b ^ {2} -c ^ {2}} {2 \ cdot a \ cdot b}} \ right) ^ {2}}} = {\ frac {1} {2 \ cdot a \ cdot b}} \ cdot {\ sqrt {(2 \ cdot a \ cdot b) ^ {2} - (a ^ {2} + b ^ {2} -c ^ {2}) ^ {2}}}}

The height of the triangle on the side is the length . Substituting the last equation yields ${\ displaystyle a}$ ${\ displaystyle b \ cdot \ sin \ gamma}$

{\ displaystyle {\ begin {aligned} A & = {\ frac {a \ cdot b \ cdot \ sin \ gamma} {2}} \\ & = {\ frac {1} {4}} \ cdot {\ sqrt { (2 \ cdot a \ cdot b) ^ {2} - (a ^ {2} + b ^ {2} -c ^ {2}) ^ {2}}} \\ & = {\ frac {1} { 4}} \ cdot {\ sqrt {(2 \ cdot a \ cdot b + (a ^ {2} + b ^ {2} -c ^ {2})) \ cdot (2 \ cdot a \ cdot b- (a ^ {2} + b ^ {2} -c ^ {2}))}} \\ & = {\ frac {1} {4}} \ cdot {\ sqrt {((a + b) ^ {2} -c ^ {2}) \ cdot (c ^ {2} - (ab) ^ {2})}} \\ & = {\ frac {1} {4}} \ cdot {\ sqrt {((a + b) + c) \ cdot ((a + b) -c) \ cdot (c + (ab)) \ ​​cdot (c- (ab))}} \\ & = {\ frac {1} {4}} \ cdot {\ sqrt {(a + b + c) \ cdot (-a + b + c) \ cdot (a-b + c) \ cdot (a + bc)}} \\ & = {\ sqrt {s \ cdot (sa) \ cdot (sb) \ cdot (sc)}} \ end {aligned}}}

Proof with the cotangent theorem

The Inkreisradius of the triangle is . With the help of the cotangent theorem can be obtained for the area ${\ displaystyle r}$

{\ displaystyle {\ begin {aligned} A & = r \ cdot ((sa) + (sb) + (sc)) \\ & = r ^ {2} \ cdot \ left ({\ frac {sa} {r} } + {\ frac {sb} {r}} + {\ frac {sc} {r}} \ right) \\ & = r ^ {2} \ cdot \ left (\ cot {\ frac {\ alpha} { 2}} + \ cot {\ frac {\ beta} {2}} + \ cot {\ frac {\ gamma} {2}} \ right) \ end {aligned}}}

With the equation for triangles (see Trigonometry formula collection ) it follows ${\ displaystyle \ cot {\ frac {\ alpha} {2}} + \ cot {\ frac {\ beta} {2}} + \ cot {\ frac {\ gamma} {2}} = \ cot {\ frac {\ alpha} {2}} \ cdot \ cot {\ frac {\ beta} {2}} \ cdot \ cot {\ frac {\ gamma} {2}}}$

{\ displaystyle {\ begin {aligned} A & = r ^ {2} \ cdot \ left (\ cot {\ frac {\ alpha} {2}} \ cdot \ cot {\ frac {\ beta} {2}} \ cdot \ cot {\ frac {\ gamma} {2}} \ right) \\ & = r ^ {2} \ cdot \ left ({\ frac {sa} {r}} \ cdot {\ frac {sb} { r}} \ cdot {\ frac {sc} {r}} \ right) \\ & = {\ frac {(sa) \ cdot (sb) \ cdot (sc)} {r}} \ end {aligned}} }

In addition, (see illustration). The multiplication of these equations gives ${\ displaystyle A = {\ frac {r \ cdot (a + b + c)} {2}} = r \ cdot s}$

{\ displaystyle A ^ {2} = s \ cdot (sa) \ cdot (sb) \ cdot (sc)}

and from it Heron's theorem.

literature

Hermann Athens, Jörn Bruhn (ed.): Lexicon of school mathematics and related areas . tape 2 , F-K. Aulis Verlag Deubner, Cologne 1977, ISBN 3-7614-0242-2 .
Anna Maria Fraedrich: The sentence group of the Pythagoras (= textbooks and monographs on didactics of mathematics . Volume 29 ). BI-Wissenschaftsverlag, Mannheim / Leipzig / Vienna / Zurich 1994, ISBN 3-411-17321-1 .
György Hajós : Introduction to Geometry . BG Teubner Verlag, Leipzig (Hungarian: Bevezetés A Geometriába . Translated by G. Eisenreich [Leipzig, also editing]).
Max Koecher , Aloys Krieg : level geometry . 3rd, revised and expanded edition. Springer Verlag, Berlin (inter alia) 2007, ISBN 978-3-540-49327-3 .
Theophil Lambacher , Wilhelm Schweizer (Ed.): Lambacher-Schweizer . Mathematical teaching material for higher schools. Geometry. Edition E. Part 2 . 13th edition. Ernst Klett Verlag, Stuttgart 1965.

Web links

Wikibooks: Archive of Evidence: Geometry: Planimetry: Triangle: Heron's Theorem - Learning and teaching materials

Eric W. Weisstein : Theorem of Heron . In: MathWorld (English).
Elementary proof
Proof using the cosine theorem (German) (PDF; 88 kB)
Walter Fendt: The Heronian formula for the triangular surface (PDF; 82 kB) - proof and conclusions

Individual evidence

↑ For detailed evidence see also Wikibooks evidence archive .
↑ Please note that the roles of the side lengths can be interchanged as desired. ${\ displaystyle a, b, c}$
^ György Hajós : Introduction to Geometry . BG Teubner Verlag, Leipzig, p. 380–381 (Hungarian: Bevezetés A Geometriába . Translated by G. Eisenreich [Leipzig, also editorial]).
↑ Max Koecher , Aloys Krieg : level geometry . 3rd, revised and expanded edition. Springer Verlag, Berlin (among others) 2007, ISBN 978-3-540-49327-3 , p. 111 .
↑ Here, too, the roles of the side lengths can be swapped, which leads to an equivalent, but correspondingly modified representation. ${\ displaystyle a, b, c}$

[1] For detailed evidence see also Wikibooks evidence archive .

[2] Please note that the roles of the side lengths can be interchanged as desired. ${\ displaystyle a, b, c}$

[3] György Hajós : Introduction to Geometry . BG Teubner Verlag, Leipzig, p. 380–381 (Hungarian: Bevezetés A Geometriába . Translated by G. Eisenreich [Leipzig, also editorial]).

[4] Max Koecher , Aloys Krieg : level geometry . 3rd, revised and expanded edition. Springer Verlag, Berlin (among others) 2007, ISBN 978-3-540-49327-3 , p. 111 .

[5] Here, too, the roles of the side lengths can be swapped, which leads to an equivalent, but correspondingly modified representation. ${\ displaystyle a, b, c}$