Diagonalizing a constant metric tensor $g_{munu}$ at a point

Question

I read that the following regarding the diagonalisation of the metric tensor $g_{munu}$ at a point P:

The constant metric tensor $g_{munu}$ at point $P$ can be diagonalised to the principal axes (with length adjusted correctly) so that it becomes the standard flat space metric $eta_{munu}$ at that point.

Is there an explicit example that shows how this work? Does this diagonalisation involve a change of coordinate system?

mike stone · Accepted Answer

Let's diagonalize $$ 
dtau^2 =-dt^2- 6dx,dt +17dx^2.
$$
By completing the square we have
$$
-dt^2- 6dx,dt +17dx^2
= - (dt +3dx)^2 +9 dx^2 +17 dx^2
= - (dt +3dx)^2 +26dx^2.
$$
Choose new coordinates $T= t+3x$, $X= sqrt {26}x$.
Then
$$
dtau^2= [d(x+3t)]^2-(d[sqrt{26}])^2=-dT^2 +dX^2.
$$
By repeatedly completing the square you can diagonalize any quadratic form ${bf x}^TM{bf x}to (A{bf y})^TM(A{bf y})={bf y}^TD{bf y}$ where $D=A^TMA$ is diagonal. There may be many ways to do this, but as @N.Steinle says, Sylvester's law of inertia says that you will always get a diagonal metric with the same signature.
Here is an example with more variables.
Consider, for example, the quadratic
form
$$
Q= x^2-y^2-z^2 +2xy-4xz +6yz
=
left(matrix{x,&!!!!y,&!!!!z}right)
left(matrix{{phantom -}1&{phantom -}1&-2cr
              {phantom -}1&-1& {phantom -}3cr
	      -2&{phantom -}3 & -1}right)
left(matrix{xcr ycr z}right).
$$
We complete the square involving $x$:
$$
Q=(x+y-2z)^2 -2y^2+10yz-5z^2,
$$
where the terms outside the squared group no longer involve
$x$.
We now complete the square in  $y$:
$$  
Q= (x+y-2z)^2 -(sqrt 2 y - frac 5{sqrt 2} z)^2 +frac
{15}{2}z^2,$$
so that the remaining  term no longer contains $y$.
Thus, on  setting
$$
xi = x+y-2z,nonumber
eta= sqrt 2 y - frac 5{sqrt 2} z,nonumber
zeta = sqrt {frac{15}{2}}z,nonumber
$$
we have
$$
Q= xi^2 -eta^2 +zeta^2 =
left(matrix{xi,&!!!!eta,&!!!!zeta}right)
left(matrix{1&{phantom -}0&0cr
              0&-1& 0cr
	     0&{phantom -}0 & 1}right)
left(matrix{xicr etacr zeta}right).
$$

Eli · Answer

you can also use the eigen vectors to diagonalized the metric:
Example @mike stone
$$ds^2=-{{it dt}}^{2}-6,{it dx},{it dt}+17,{{it dx}}^{2}$$
thus the metric is:
$$boldsymbol G=left[ begin {array}{cc} -1&-3 -3&17end {array}
 right] 
$$
the eigen values are
$$lambda_1=8+3,sqrt {10}~,lambda_2=8-3,sqrt {10}$$
and the eigen vectors are:
$$ T= left[ begin {array}{cc} {frac {1}{sqrt {1+ left( -3-sqrt {10}
 right) ^{2}}}}&{frac {1}{sqrt {1+ left( -3+sqrt {10} right) ^{2
}}}} {frac {-3-sqrt {10}}{sqrt {1+ left( -3-
sqrt {10} right) ^{2}}}}&{frac {-3+sqrt {10}}{sqrt {1+ left( -3+
sqrt {10} right) ^{2}}}}end {array} right]
$$
$Rightarrow$
$$boldsymbol T^{T},boldsymbol G,boldsymbol T=begin{bmatrix}
  lambda_1 & 0 
  0 & lambda_2 
end{bmatrix}$$
thus your line element $ds^2$  is now :
$$ds^2mapsto lambda_1,dT^2+lambda_2,dX^2$$

Diagonalizing a constant metric tensor $g_{munu}$ at a point

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