Converting d(γmu) to du: A Relativity Integration Simplification

[sparkle123]

I simply don't understand this conversion. I've only worked with du, dx, dy, etc. before. How do you change a d(γmu) into some kind of du?
(This is in the contest of relativity, although this info is not essential i think)

Thanks! :)

 

[SammyS]

I simply don't understand this conversion. I've only worked with du, dx, dy, etc. before. How do you change a d(γmu) into some kind of du?
(This is in the contest of relativity, although this info is not essential i think)

Thanks! :)

What is \displaystyle \frac{d}{du}\left(\frac{mu}{\sqrt{1-u^2/c^2}}\right)\ ?

 

[dimension10]

I simply don't understand this conversion. I've only worked with du, dx, dy, etc. before. How do you change a d(γmu) into some kind of du?
(This is in the contest of relativity, although this info is not essential i think)

Thanks! :)

Let x = \frac{{mu}}{{\sqrt {1 - \frac{{{u^2}}}{{c_{0}^2}}} }}

Then solve for u.

 

[sparkle123]

Figured it out thanks!

 

[sparkle123]

Wait dimension10, how do you solve it your way, after getting u = x/sqrt(m^2+x^2/c^2)?

 

[dimension10]

Wait dimension10, how do you solve it your way, after getting u = x/sqrt(m^2+x^2/c^2)?

\begin{array}{l}<br /> {x^2} = \frac{{{m^2}{u^2}}}{{1 - \frac{{{u^2}}}{{{c_0}^2}}}}\\<br /> {x^2} = \frac{{{m^2}}}{{\frac{1}{{{u^2}}} - \frac{1}{{{c_0}^2}}}}\\<br /> \frac{{{m^2}}}{{{x^2}}} + \frac{1}{{c_0^2}} = \frac{1}{{{u^2}}}\\<br /> {u^2} = \frac{1}{{\frac{{{m^2}}}{{{x^2}}} + \frac{1}{{c_0^2}}}}\\<br /> {u^2} = \frac{{c_0^2{x^2}}}{{{m^2}c_0^2 + {x^2}}}\\<br /> u = \frac{{{c_0}x}}{{\sqrt {{m^2}c_0^2 + {x^2}} }}\\<br /> ...\\<br /> \int {\frac{{{c_0}x}}{{\sqrt {{m^2}c_0^2 + {x^2}} }}{\rm{d}}x} = \int {m{{\left( {1 - \frac{{{x^2}}}{{c_0^2}}} \right)}^{ - \frac{3}{2}}}x{\rm{ d}}u} = \int {m{{\left( {1 - \frac{{{u^2}}}{{c_0^2}}} \right)}^{ - \frac{3}{2}}}u{\rm{ d}}u} <br /> \end{array}

 

[sparkle123]

Thanks a lot!