Classical treatment of tensors

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Note: The following is a component-based "classical" treatment of tensors. See Component-free treatment of tensors for a modern abstract treatment, and Intermediate treatment of tensors for an approach which bridges the two.
This article uses Einstein notation. For help, refer to the table of mathematical symbols.

A tensor is a generalization of the concepts of vectors and matrices. Tensors allow one to express physical laws in a form that applies to any coordinate system. For this reason, they are used extensively in continuum mechanics and the theory of relativity.

A tensor is an invariant multi-dimensional transformation, one that takes forms in one coordinate system into another. It takes the form:

T^{\left[i_1,i_2,i_3,...i_n\right]}_{\left[j_1,j_2,j_3,...j_m\right]}

The new coordinate system is represented by being 'barred'(\bar{x}^i), and the old coordinate system is unbarred(xi).

The upper indices [i1,i2,i3,...in] are the contravariant components, and the lower indices [j1,j2,j3,...jn] are the covariant components.

Contents

[edit] Contravariant and covariant tensors

A contravariant tensor of order 1(Ti) is defined as:

\bar{T}^i = T^r\frac{\partial \bar{x}^i}{\partial x^r}.

A covariant tensor of order 1(Ti) is defined as:

\bar{T}_i = T_r\frac{\partial x^r}{\partial \bar{x}^i}.

[edit] General tensors

A multi-order (general) tensor is simply the tensor product of single order tensors:

T^{\left[i_1,i_2,...i_p\right]}_{\left[j_1,j_2,...j_q\right]} = T^{i_1} \otimes T^{i_2} ... \otimes T^{i_p} \otimes T_{j_1} \otimes T_{j_2} ... \otimes T_{j_q}

such that:

\bar{T}^{\left[i_1,i_2,...i_p\right]}_{\left[j_1,j_2,...j_q\right]} = 
T^{\left[r_1,r_2,...r_p\right]}_{\left[s_1,s_2,...s_q\right]}
\frac{\partial \bar{x}^{i_1}}{\partial x^{r_1}}
\frac{\partial \bar{x}^{i_2}}{\partial x^{r_2}}
...
\frac{\partial \bar{x}^{i_p}}{\partial x^{r_p}}
\frac{\partial x^{s_1}}{\partial \bar{x}^{j_1}}
\frac{\partial x^{s_2}}{\partial \bar{x}^{j_2}}
...
\frac{\partial x^{s_q}}{\partial \bar{x}^{j_q}}.

This is sometimes termed the tensor transformation law.

[edit] See also

[edit] Further reading

  • Schaum's Outline of Tensor Calculus
  • Synge and Schild, Tensor Calculus, Toronto Press: Toronto, 1949
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