In mathematics, the field trace is a particular function defined with respect to a finite field extension L/K, which is a K-linear map from L onto K.
Let K be a field and L a finite extension (and hence an algebraic extension) of K. L can be viewed as a vector space over K. Multiplication by α, an element of L,
m\alpha:L\toLgivenbym\alpha(x)=\alphax
For α in L, let σ(α), ..., σ(α) be the roots (counted with multiplicity) of the minimal polynomial of α over K (in some extension field of K). Then
\operatorname{Tr}L/K(\alpha)=
| n\sigma | |
| [L:K(\alpha)]\sum | |
| j(\alpha). |
More particularly, if L/K is a Galois extension and α is in L, then the trace of α is the sum of all the Galois conjugates of α, i.e.,
\operatorname{Tr}L/K(\alpha)=\sum\sigma\in\operatorname{Gal(L/K)}\sigma(\alpha),
Let
L=Q(\sqrt{d})
Q
L/Q
\{1,\sqrt{d}\}.
\alpha=a+b\sqrt{d}
m\alpha
\left[\begin{matrix}a&bd\ b&a\end{matrix}\right]
\operatorname{Tr}L/Q(\alpha)=[L:Q(\alpha)]\left(\sigma1(\alpha)+\sigma2(\alpha)\right) =1 x \left(\sigma1(\alpha)+\overline{\sigma1}(\alpha)\right) =a+b\sqrt{d}+a-b\sqrt{d}=2a
Several properties of the trace function hold for any finite extension.
The trace is a K-linear map (a K-linear functional), that is
\operatorname{Tr}L/K(\alphaa+\betab)=\alpha\operatorname{Tr}L/K(a)+\beta\operatorname{Tr}L/K(b)forall\alpha,\beta\inK
If then
\operatorname{Tr}L/K(\alpha)=[L:K]\alpha.
Additionally, trace behaves well in towers of fields: if M is a finite extension of L, then the trace from M to K is just the composition of the trace from M to L with the trace from L to K, i.e.
\operatorname{Tr}M/K=\operatorname{Tr}L/K\circ\operatorname{Tr}M/L
Let L = GF(qn) be a finite extension of a finite field K = GF(q). Since L/K is a Galois extension, if α is in L, then the trace of α is the sum of all the Galois conjugates of α, i.e.
\operatorname{Tr}L/K(\alpha)=\alpha+\alphaq+ … +
| qn-1 | |
| \alpha |
.
In this setting we have the additional properties:
\operatorname{Tr}L/K(aq)=\operatorname{Tr}L/K(a)fora\inL
\alpha\inK
qn-1
b\inL
\operatorname{Tr}L/K(b)=\alpha
Theorem. For b ∈ L, let Fb be the map
a\mapsto\operatorname{Tr}L/K(ba).
When K is the prime subfield of L, the trace is called the absolute trace and otherwise it is a relative trace.
A quadratic equation, with a ≠ 0, and coefficients in the finite field
\operatorname{GF}(q)=Fq
Consider the quadratic equation with coefficients in the finite field GF(2h). If b = 0 then this equation has the unique solution
x=\sqrt{
| c | |
| a |
y2+y+\delta=0,where\delta=
| ac | |
| b2 |
.
\operatorname{Tr}GF(q)/GF(2)(\delta)=0.
\operatorname{Tr}GF(q)/GF(2)(k)=1.
y=s=k\delta2+(k+k2)\delta4+\ldots+(k+k2+\ldots+
| 2h-2 | |
| k |
| 2h-1 | |
| )\delta |
.
y=s=\delta+
| 22 | |
| \delta |
+
| 24 | |
| \delta |
+\ldots+
| 22m | |
| \delta |
.
When L/K is separable, the trace provides a duality theory via the trace form: the map from to K sending to Tr(xy) is a nondegenerate, symmetric bilinear form called the trace form. If L/K is a Galois extension, the trace form is invariant with respect to the Galois group.
The trace form is used in algebraic number theory in the theory of the different ideal.
The trace form for a finite degree field extension L/K has non-negative signature for any field ordering of K. The converse, that every Witt equivalence class with non-negative signature contains a trace form, is true for algebraic number fields K.[1]
If L/K is an inseparable extension, then the trace form is identically 0.[2]