# Difference between revisions of "Dual basis"

### From Online Dictionary of Crystallography

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− | <font color = "blue">Base duale </font>(''Fr''): <font color="black"> Base duale </font>(''It''); <font color="purple"> | + | <font color = "blue">Base duale </font>(''Fr''): <font color="black"> Base duale </font>(''It''); <font color="purple">双対基底</font> (''Ja''). |

== Definition == | == Definition == | ||

## Revision as of 09:07, 14 April 2017

Base duale (*Fr*): Base duale (*It*); 双対基底 (*Ja*).

## 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 **e _{i}** spanning the direct space

*E*, and a vector

^{n}**x**=

*x*

^{ i}**e**, let us consider the

_{i}*n*quantities defined by the scalar products of

**x**with the basis vectors,

**e**:

_{i}*x _{i}* =

**x**.

**e**=

_{i}*x*

^{ j}**e**.

_{j}**e**=

_{i}*x*,

^{ j}g_{ji}where the *g _{ji}* 's are the doubly covariant components of the metric tensor.

By solving these equations in terms of *x ^{ j}*, one gets:

*x ^{ j}* =

*x*

_{i}g^{ij}where the matrix of the *g ^{ij}* 's is inverse of that of the

*g*'s (

_{ij}*g*= δ

^{ik}g_{jk}^{i}

_{j}). The development of vector

**x**with respect to basis vectors

**e**can now also be written:

_{i}**x** = *x ^{ i}*

**e**=

_{i}*x*

_{i}g^{ij}**e**

_{j}The set of *n* vectors **e ^{i}** =

*g*

^{ij}**e**that span the space

_{j}*E*forms a basis since vector

^{n}**x**can be written:

**x** = *x _{i}*

**e**

^{i}This basis is the *dual basis* and the *n* quantities *x _{i}* 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:

**e _{i}** =

*g*

_{ij}**e**

^{j}The scalar products of the basis vectors of the dual and direct bases are:

*g ^{i}_{j}* =

**e**.

^{i}**e**=

_{j}*g*

^{ik}**e**.

_{k}**e**=

_{j}*g*= δ

^{ik}g_{jk}^{i}

_{j}.

One has therefore, since the matrices *g ^{ik}* and

*g*are inverse:

_{ij}*g ^{i}_{j}* =

**e**.

^{i}**e**= δ

_{j}^{i}

_{j}.

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}** =

*A*

_{j}^{i}**e**;

_{i}*x'*=

^{j}*B*

_{i}^{ j}*x*,

^{i}where *A _{j}^{i}* and

*B*are transformation matrices, transpose of one another, the dual basis vectors

_{i}^{ j}**e**and the coordinates

^{i}*x*transform according to:

_{i}**e' ^{j} ** =

*B*

_{i}^{ j}**e**;

^{i}*x'*=

_{j}*A*.

_{j}^{i}x_{i}The coordinates of a vector in reciprocal space are therefore *covariant* and the dual basis vectors (or reciprocal vectors) *contravariant*.

## See also

- metric tensor
- reciprocal space
- The Reciprocal Lattice (Teaching Pamphlet of the
*International Union of Crystallography*) - Section 1.1.2 of
*International Tables of Crystallography, Volume D*