For other uses of the word rhombus, see Rhombus (disambiguation)

In geometry, a rhombus (also known as a rhomb/Rho.) is a quadrilateral in which all of the sides are of equal length, i.e., it is an equilateral quadrangle. More colloquially it may be described as a diamond or lozenge shape.

In any rhombus, opposite sides will be parallel. Thus, the rhombus is a special case of the parallelogram. One suggestive analogy is that the rhombus is to the parallelogram as the square is to the rectangle. If all the angles of a rhombus are right angles, it is then a rectangle and a square.

The rhombus has the same symmetry as the rectangle (with symmetry group D₂, the Klein four-group) and is its dual: the vertices of one correspond to the sides of the other.

A rhombus in the plane has five degrees of freedom: one for the shape, one for the size, one for the orientation, and two for the position.

The diagonals of a rhombus are perpendicular to each other. Hence, by joining the midpoints of each side, a rectangle can be produced.

One of the five 2D lattice types is the rhombic lattice, also called centered rectangular lattice.

Consecutive angles of a rhombus are supplementary.

Proof

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The diagonals are perpendicular.

Let A, B, C and D be the vertices of the rhombus, named in agreement with the figure (higher on this page). Using $\backslash overrightarrow\{AB\}$ to represent the vector from A to B, one notices that
$\backslash overrightarrow\{AC\}\; =\; \backslash overrightarrow\{AB\}\; +\; \backslash overrightarrow\{BC\}$
$\backslash overrightarrow\{BD\}\; =\; \backslash overrightarrow\{BC\}+\; \backslash overrightarrow\{CD\}=\; \backslash overrightarrow\{BC\}-\; \backslash overrightarrow\{AB\}$.
The last equality comes from the parallelism of CD and AB. Taking the inner product,

since the norms of AB and BC are equal and since the inner product is bilinear and symmetric. The inner product of the diagonals is zero if and only if they are perpendicular.

Area

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The area of any rhombus is one half the product of the lengths of its diagonals:
$A=\backslash frac\{D\_1\; \backslash times\; D\_2\}\{2\}$
Because the rhombus is a parallelogram with four equal sides, the area also equals the length of a side (B) multiplied by the perpendicular distance between two opposite sides(H):
$A=B\; \backslash times\; H$

Origin

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The origin of the word rhombus is from the Greek word for something that spins. Euclid uses the word ρομβος; and in his translation Heath says it is apparently drawn from the Greek word ρεμβω, to turn round and round. He also points out that Archimedes used the term solid rhombus for two right circular cones sharing a common base. For more on the origin of the word, see rhombus at the MathWords web page.

External links

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• Rhombus definition. Math Open Reference With interactive applet.
• Rhombus area. Math Open Reference Shows three different ways to compute the area of a rhombus, with interactive applet.

Quadrilaterals

Ромб | Rombe | Rombe | Raute | Rombo | Losange | Rombo | Rombo | מעוין | Lozanj | Roet | Rombusz | Ruit (meetkunde) | Rombe | Ruut | Romb | Losango | Ромб | Romb | 菱形