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Difference between revisions of "Dual basis"

From Online Dictionary of Crystallography

m (Lang (Ar))
(Tidied translations and added German and Spanish (U. Mueller))
 
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<font color = "blue">Base duale </font>(''Fr''); <font color="black"> Base duale </font>(''It''); <font color="purple">双対基底</font> (''Ja''); <font color="orange">أساس مزدوج</font> (''Ar'').
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<font color="orange">أساس مزدوج</font> (''Ar''). <font color = "blue">Base duale</font> (''Fr''). <font color="red">Duale Basis</font> (''Ge''). <font color="black">Base duale</font> (''It''). <font color="purple">双対基底</font> (''Ja''). <font color="green">Base dual</font> (''Sp'').
  
 
== Definition ==
 
== Definition ==

Latest revision as of 13:56, 10 November 2017

أساس مزدوج (Ar). Base duale (Fr). Duale Basis (Ge). Base duale (It). 双対基底 (Ja). Base dual (Sp).

Definition

The dual basis is a basis associated to the basis of a vector space. In three-dimensional space, it is isomorphous to the basis of the reciprocal lattice. It is mathematically defined as follows.

Given a basis of n vectors ei spanning the direct space En, and a vector x = x i ei, let us consider the n quantities defined by the scalar products of x with the basis vectors, ei:

xi = x . ei = x j ej . ei = x j gji,

where the gji 's are the doubly covariant components of the metric tensor.

By solving these equations in terms of x j, one gets

x j = xi gij

where the matrix of the gij 's is inverse of that of the gij 's (gikgjk = δij). The development of vector x with respect to basis vectors ei can now also be written

x = x i ei = xi gij ej.

The set of n vectors ei = gij ej that span the space En forms a basis since vector x can be written

x = xi ei.

This basis is the dual basis and the n quantities xi defined above are the coordinates of x with respect to the dual basis. In a similar way one can express the direct basis vectors in terms of the dual basis vectors:

ei = gij ej.

The scalar products of the basis vectors of the dual and direct bases are

gij = ei . ej = gik ek . ej = gikgjk = δij.

One has therefore, since the matrices gik and gij are inverse,

gij = ei . ej = δij.

These relations show that the dual basis vectors satisfy the definition conditions of the reciprocal vectors. In a three-dimensional space the dual basis and the basis of reciprocal space are identical.

Change of basis

In a change of basis where the direct basis vectors and coordinates transform like

e'j = Aji ei; x'j = Bi j xi,

where Aji and Bi j are transformation matrices, transpose of one another, the dual basis vectors ei and the coordinates xi transform according to

e'j = Bi j ei; x'j = Ajixi.

The coordinates of a vector in reciprocal space are therefore covariant and the dual basis vectors (or reciprocal vectors) contravariant.

See also